Stockfish 6

Stockfish bench signature is: 8918745
Stockfish 6 Release Candidate 3
2026-05-20 06:17:49 +00:00 · 2015-01-27 20:27:38 +00:00 · 2015-01-25 22:03:57 +00:00 · 2015-01-25 21:57:13 +00:00 · 2015-01-25 21:51:09 +00:00 · 2015-01-25 09:36:05 +01:00
53 changed files with 9980 additions and 10957 deletions
@@ -0,0 +1,64 @@
 # Generated with git shortlog -sn | cut -c8-', which sorts by commits (manually moved Tord to top)
 Tord Romstad
 Marco Costalba
 Joona Kiiski
 Gary Linscott
 Lucas Braesch
 Reuven Peleg
 Chris Caino
 homoSapiensSapiens
 Jean-Francois Romang
 jundery
 Arjun Temurnikar
 Uri Blass
 Ralph Stößer
 Stefan Geschwentner
 Tom Vijlbrief
 Daylen Yang
 Henri Wiechers
 Leonid Pechenik
 mstembera
 Eelco de Groot
 Jerry Donald
 Jörg Oster
 Ryan Schmitt
 mcostalba
 Alexander Kure
 Dan Schmidt
 H. Felix Wittmann
 Justin Blanchard
 Linus Arver
 RyanTaker
 ceebo
 Joseph H Ellis
 Stephane Nicolet
 Ajith
 Andy Duplain
 Auguste Pop
 Balint Pfliegel
 Chris Cain
 Dariusz Orzechowski
 Gregor Cramer
 Hiraoka Takuya
 Hongzhi Cheng
 Jonathan Calovski
 Joseph R. Prostko
 Kelly Wilson
 Kojirion
 Matt Sullivan
 Matthew Sullivan
 Michel Van den Bergh
 Mysseno
 Pablo Vazquez
 Raminder Singh
 Richard Lloyd
 Ron Britvich
 Ronald de Man
 Ryan Takker
 Thanar2
 kinderchocolate
 pellanda
 renouve
 shane31
 thaspel
@@ -0,0 +1,112 @@
 ### Overview
 Stockfish is a free UCI chess engine derived from Glaurung 2.1. It is
 not a complete chess program and requires some UCI-compatible GUI
 (e.g. XBoard with PolyGlot, eboard, Arena, Sigma Chess, Shredder, Chess
 Partner or Fritz) in order to be used comfortably. Read the
 documentation for your GUI of choice for information about how to use
 Stockfish with it.
 This version of Stockfish supports up to 128 cores. The engine defaults
 to one search thread, so it is therefore recommended to inspect the value of
 the *Threads* UCI parameter, and to make sure it equals the number of CPU
 cores on your computer.
 This version of Stockfish has support for Syzygybases.
 ### Files
 This distribution of Stockfish consists of the following files:
  * Readme.md, the file you are currently reading.
  * Copying.txt, a text file containing the GNU General Public License.
  * src, a subdirectory containing the full source code, including a Makefile
    that can be used to compile Stockfish on Unix-like systems.
 ### Syzygybases
 **Configuration**
 Syzygybases are configured using the UCI options "SyzygyPath",
 "SyzygyProbeDepth", "Syzygy50MoveRule" and "SyzygyProbeLimit".
 The option "SyzygyPath" should be set to the directory or directories that
 contain the .rtbw and .rtbz files. Multiple directories should be
 separated by ";" on Windows and by ":" on Unix-based operating systems.
 **Do not use spaces around the ";" or ":".**
 Example: `C:\tablebases\wdl345;C:\tablebases\wdl6;D:\tablebases\dtz345;D:\tablebases\dtz6`
 It is recommended to store .rtbw files on an SSD. There is no loss in
 storing the .rtbz files on a regular HD.
 Increasing the "SyzygyProbeDepth" option lets the engine probe less
 aggressively. Set this option to a higher value if you experience too much
 slowdown (in terms of nps) due to TB probing.
 Set the "Syzygy50MoveRule" option to false if you want tablebase positions
 that are drawn by the 50-move rule to count as win or loss. This may be useful
 for correspondence games (because of tablebase adjudication).
 The "SyzygyProbeLimit" option should normally be left at its default value.
 **What to expect**  
 If the engine is searching a position that is not in the tablebases (e.g.
 a position with 7 pieces), it will access the tablebases during the search.
 If the engine reports a very large score (typically 123.xx), this means
 that it has found a winning line into a tablebase position.
 If the engine is given a position to search that is in the tablebases, it
 will use the tablebases at the beginning of the search to preselect all
 good moves, i.e. all moves that preserve the win or preserve the draw while
 taking into account the 50-move rule.
 It will then perform a search only on those moves. **The engine will not move
 immediately**, unless there is only a single good move. **The engine likely
 will not report a mate score even if the position is known to be won.**
 It is therefore clear that behaviour is not identical to what one might
 be used to with Nalimov tablebases. There are technical reasons for this
 difference, the main technical reason being that Nalimov tablebases use the
 DTM metric (distance-to-mate), while Syzygybases use a variation of the
 DTZ metric (distance-to-zero, zero meaning any move that resets the 50-move
 counter). This special metric is one of the reasons that Syzygybases are
 more compact than Nalimov tablebases, while still storing all information
 needed for optimal play and in addition being able to take into account
 the 50-move rule.
 ### Compiling it yourself
 On Unix-like systems, it should be possible to compile Stockfish
 directly from the source code with the included Makefile.
 Stockfish has support for 32 or 64-bit CPUs, the hardware POPCNT
 instruction, big-endian machines such as Power PC, and other platforms.
 In general it is recommended to run `make help` to see a list of make
 targets with corresponding descriptions. When not using the Makefile to
 compile (for instance with Microsoft MSVC) you need to manually
 set/unset some switches in the compiler command line; see file *types.h*
 for a quick reference.
 ### Terms of use
 Stockfish is free, and distributed under the **GNU General Public License**
 (GPL). Essentially, this means that you are free to do almost exactly
 what you want with the program, including distributing it among your
 friends, making it available for download from your web site, selling
 it (either by itself or as part of some bigger software package), or
 using it as the starting point for a software project of your own.
 The only real limitation is that whenever you distribute Stockfish in
 some way, you must always include the full source code, or a pointer
 to where the source code can be found. If you make any changes to the
 source code, these changes must also be made available under the GPL.
 For full details, read the copy of the GPL found in the file named
 *Copying.txt*
@@ -1,88 +0,0 @@
 1. Introduction
 ---------------
 Stockfish is a free UCI chess engine derived from Glaurung 2.1. It is
 not a complete chess program, but requires some UCI compatible GUI
 (like XBoard with PolyGlot, eboard, Josè, Arena, Sigma Chess, Shredder,
 Chess Partner, or Fritz) in order to be used comfortably.  Read the
 documentation for your GUI of choice for information about how to use
 Stockfish with your GUI.
 This version of Stockfish supports up to 32 CPUs, but has not been
 tested thoroughly with more than 4.  The program tries to detect the
 number of CPUs on your computer and set the number of search threads
 accordingly, but please be aware that the detection is not always
 correct.  It is therefore recommended to inspect the value of the
 "Threads" UCI parameter, and to make sure it equals the number of CPU
 cores on your computer. If you are using more than four threads, it
 is recommended to raise the value of "Minimum Split Depth" UCI parameter
 to 6.
 2. Files
 --------
 This distribution of Stockfish consists of the following files:
  * Readme.txt, the file you are currently reading.
  * Copying.txt, a text file containing the GNU General Public
    License.
  * src/, a subdirectory containing the full source code, including a
    Makefile that can be used to compile Stockfish on Unix-like
    systems.  For further information about how to compile Stockfish
    yourself, read section 4 below.
  * polyglot.ini, for using Stockfish with Fabien Letouzey's PolyGlot
    adapter.
 3. Opening books
 ----------------
 This version of Stockfish has support for PolyGlot opening books.
 For information about how to create such books, consult the PolyGlot
 documentation.  The book file can be selected by setting the UCI
 parameter "Book File".
 4. Compiling it yourself
 ------------------------
 On Unix-like systems, it should usually be possible to compile
 Stockfish directly from the source code with the included Makefile.
 For big-endian machines like Power PC you need to enable the proper
 flag changing from -DNBIGENDIAN to -DBIGENDIAN in the Makefile.
 Stockfish has POPCNT instruction runtime detection and support. This can
 give an extra speed on Core i7 or similar systems. To enable this feature
 compile with 'make icc-profile-popcnt'
 On 64 bit systems the 'bsfq' assembly instruction will be used for bit
 counting. Detection is automatic at compile time, but in case you experience
 compile problems you can comment out #define USE_BSFQ line in types.h
 In general is recommended to run 'make help' to see a list of make targets
 with corresponding descriptions.
 5. Terms of use
 ---------------
 Stockfish is free, and distributed under the GNU General Public License
 (GPL).  Essentially, this means that you are free to do almost exactly
 what you want with the program, including distributing it among your
 friends, making it available for download from your web site, selling
 it (either by itself or as part of some bigger software package), or
 using it as the starting point for a software project of your own.
 The only real limitation is that whenever you distribute Stockfish in
 some way, you must always include the full source code, or a pointer
 to where the source code can be found.  If you make any changes to the
 source code, these changes must also be made available under the GPL.
 For full details, read the copy of the GPL found in the file named
 Copying.txt.
@@ -1,39 +0,0 @@
 [PolyGlot]
 EngineDir = .
 EngineCommand = ./stockfish
 Book = false
 BookFile = book.bin
 Log = false
 LogFile = stockfish.log
 Resign = true
 ResignScore = 600
 [Engine]
 Hash = 128
 Threads = 1
 OwnBook = false
 Book File = book.bin
 Best Book Move = false
 Use Search Log = false
 Search Log Filename = SearchLog.txt
 Mobility (Middle Game) = 100
 Mobility (Endgame) = 100
 Passed Pawns (Middle Game) = 100
 Passed Pawns (Endgame) = 100
 Space = 100
 Aggressiveness = 100
 Cowardice = 100
 Minimum Split Depth = 4
 Maximum Number of Threads per Split Point = 5
 Use Sleeping Threads = false
 Skill Level = 20
 Emergency Move Horizon = 40
 Emergency Base Time = 200
 Emergency Move Time = 70
 Minimum Thinking Time = 20
@@ -1,6 +1,6 @@
 # Stockfish, a UCI chess playing engine derived from Glaurung 2.1
 # Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-# Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+# Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
 #
 # Stockfish is free software: you can redistribute it and/or modify
 # it under the terms of the GNU General Public License as published by
@@ -20,6 +20,9 @@
 ### Section 1. General Configuration
 ### ==========================================================================
 ### Establish the operating system name
 UNAME = $(shell uname)
 ### Executable name
 EXE = stockfish
@@ -28,12 +31,12 @@ PREFIX = /usr/local
 BINDIR = $(PREFIX)/bin
 ### Built-in benchmark for pgo-builds
-PGOBENCH = ./$(EXE) bench 32 1 10 default depth
+PGOBENCH = ./$(EXE) bench 16 1 1000 default time
 ### Object files
-OBJS = benchmark.o bitbase.o bitboard.o book.o endgame.o evaluate.o main.o \
+OBJS = benchmark.o bitbase.o bitboard.o endgame.o evaluate.o main.o \
-	material.o misc.o move.o movegen.o movepick.o pawns.o position.o \
+	material.o misc.o movegen.o movepick.o pawns.o position.o \
-	search.o thread.o timeman.o tt.o uci.o ucioption.o
+	search.o thread.o timeman.o tt.o uci.o ucioption.o syzygy/tbprobe.o
 ### ==========================================================================
 ### Section 2. High-level Configuration
@@ -42,148 +45,92 @@ OBJS = benchmark.o bitbase.o bitboard.o book.o endgame.o evaluate.o main.o \
 # flag                --- Comp switch --- Description
 # ----------------------------------------------------------------------------
 #
-# debug = no/yes      --- -DNDEBUG    --- Enable/Disable debug mode
+# debug = yes/no      --- -DNDEBUG         --- Enable/Disable debug mode
 # optimize = yes/no   --- (-O3/-fast etc.) --- Enable/Disable optimizations
-# arch = (name)       --- (-arch)     --- Target architecture
+# arch = (name)       --- (-arch)          --- Target architecture
-# os = (name)         ---             --- Target operating system
+# bits = 64/32        --- -DIS_64BIT       --- 64-/32-bit operating system
-# bits = 64/32        --- -DIS_64BIT  --- 64-/32-bit operating system
+# prefetch = yes/no   --- -DUSE_PREFETCH   --- Use prefetch x86 asm-instruction
-# bigendian = no/yes  --- -DBIGENDIAN --- big/little-endian byte order
+# bsfq = yes/no       --- -DUSE_BSFQ       --- Use bsfq x86_64 asm-instruction (only
-# prefetch = no/yes   --- -DUSE_PREFETCH  --- Use prefetch x86 asm-instruction
+#                                              with GCC and ICC 64-bit)
-# bsfq = no/yes       --- -DUSE_BSFQ  --- Use bsfq x86_64 asm-instruction
+# popcnt = yes/no     --- -DUSE_POPCNT     --- Use popcnt x86_64 asm-instruction
-#                                     --- (Works only with GCC and ICC 64-bit)
+# sse = yes/no        --- -msse            --- Use Intel Streaming SIMD Extensions
-# popcnt = no/yes     --- -DUSE_POPCNT --- Use popcnt x86_64 asm-instruction
+# pext = yes/no       --- -DUSE_PEXT       --- Use pext x86_64 asm-instruction
 #
 # Note that Makefile is space sensitive, so when adding new architectures
 # or modifying existing flags, you have to make sure there are no extra spaces
 # at the end of the line for flag values.
-### 2.1. General
+### 2.1. General and architecture defaults
 debug = no
 optimize = yes
 debug = no
 bits = 32
 prefetch = no
 bsfq = no
 popcnt = no
 sse = no
 pext = no
 ### 2.2 Architecture specific
 # General-section
 ifeq ($(ARCH),general-64)
 	arch = any
 	os = any
 	bits = 64
 	bigendian = no
 	prefetch = no
 	bsfq = no
 	popcnt = no
 endif
 ifeq ($(ARCH),general-32)
 	arch = any
 	os = any
 	bits = 32
 	bigendian = no
 	prefetch = no
 	bsfq = no
 	popcnt = no
 endif
 ifeq ($(ARCH),bigendian-64)
 	arch = any
 	os = any
 	bits = 64
 	bigendian = yes
 	prefetch = no
 	bsfq = no
 	popcnt = no
 endif
 ifeq ($(ARCH),bigendian-32)
 	arch = any
 	os = any
 	bits = 32
 	bigendian = yes
 	prefetch = no
 	bsfq = no
 	popcnt = no
 endif
 # x86-section
 ifeq ($(ARCH),x86-64)
 	arch = x86_64
 	os = any
 	bits = 64
 	bigendian = no
 	prefetch = yes
 	bsfq = yes
 	popcnt = no
 endif
 ifeq ($(ARCH),x86-64-modern)
 	arch = x86_64
 	os = any
 	bits = 64
 	bigendian = no
 	prefetch = yes
 	bsfq = yes
 	popcnt = yes
 endif
 ifeq ($(ARCH),x86-32)
 	arch = i386
 	os = any
 	bits = 32
 	bigendian = no
 	prefetch = yes
 	bsfq = no
 	popcnt = no
 endif
 ifeq ($(ARCH),x86-32-old)
 	arch = i386
 	os = any
 	bits = 32
 	bigendian = no
 	prefetch = no
 	bsfq = no
 	popcnt = no
 endif
-# osx-section
+ifeq ($(ARCH),x86-32)
-ifeq ($(ARCH),osx-ppc-64)
+	arch = i386
-	arch = ppc64
+	prefetch = yes
-	os = osx
+	sse = yes
 endif
 ifeq ($(ARCH),general-64)
 	arch = any
 	bits = 64
 	bigendian = yes
 	prefetch = no
 	bsfq = no
 	popcnt = no
 endif
-ifeq ($(ARCH),osx-ppc-32)
+ifeq ($(ARCH),x86-64)
 	arch = ppc
 	os = osx
 	bits = 32
 	bigendian = yes
 	prefetch = no
 	bsfq = no
 	popcnt = no
 endif
 ifeq ($(ARCH),osx-x86-64)
 	arch = x86_64
 	os = osx
 	bits = 64
 	bigendian = no
 	prefetch = yes
 	bsfq = yes
-	popcnt = no
+	sse = yes
 endif
-ifeq ($(ARCH),osx-x86-32)
+ifeq ($(ARCH),x86-64-modern)
-	arch = i386
+	arch = x86_64
-	os = osx
+	bits = 64
 	bits = 32
 	bigendian = no
 	prefetch = yes
-	bsfq = no
+	bsfq = yes
-	popcnt = no
+	popcnt = yes
 	sse = yes
 endif
 ifeq ($(ARCH),x86-64-bmi2)
 	arch = x86_64
 	bits = 64
 	prefetch = yes
 	bsfq = yes
 	popcnt = yes
 	sse = yes
 	pext = yes
 endif
 ifeq ($(ARCH),armv7)
 	arch = armv7
 	prefetch = yes
 	bsfq = yes
 endif
 ifeq ($(ARCH),ppc-32)
 	arch = ppc
 endif
 ifeq ($(ARCH),ppc-64)
 	arch = ppc64
 	bits = 64
 endif
@@ -192,66 +139,72 @@ endif
 ### ==========================================================================
 ### 3.1 Selecting compiler (default = gcc)
 CXXFLAGS += -Wall -Wcast-qual -fno-exceptions -fno-rtti $(EXTRACXXFLAGS)
 LDFLAGS += $(EXTRALDFLAGS)
 ifeq ($(COMP),)
 	COMP=gcc
 endif
 ifeq ($(COMP),mingw)
 	comp=mingw
 	CXX=g++
 	profile_prepare = gcc-profile-prepare
 	profile_make = gcc-profile-make
 	profile_use = gcc-profile-use
 	profile_clean = gcc-profile-clean
 endif
 ifeq ($(COMP),gcc)
 	comp=gcc
 	CXX=g++
 	CXXFLAGS += -ansi -pedantic -Wno-long-long -Wextra -Wshadow
 endif
 ifeq ($(COMP),mingw)
 	comp=mingw
 	CXX=g++
 	CXXFLAGS += -Wextra -Wshadow
 	LDFLAGS += -static-libstdc++ -static-libgcc
 endif
 ifeq ($(COMP),icc)
 	comp=icc
 	CXX=icpc
 	CXXFLAGS += -diag-disable 1476,10120 -Wcheck -Wabi -Wdeprecated -strict-ansi
 endif
 ifeq ($(COMP),clang)
 	comp=clang
 	CXX=clang++
 	CXXFLAGS += -pedantic -Wno-long-long -Wextra -Wshadow
 endif
 ifeq ($(comp),icc)
 	profile_prepare = icc-profile-prepare
 	profile_make = icc-profile-make
 	profile_use = icc-profile-use
 	profile_clean = icc-profile-clean
 else
 	profile_prepare = gcc-profile-prepare
 	profile_make = gcc-profile-make
 	profile_use = gcc-profile-use
 	profile_clean = gcc-profile-clean
 endif
-ifeq ($(COMP),icc)
+ifeq ($(UNAME),Darwin)
-	comp=icc
+	CXXFLAGS += -arch $(arch) -mmacosx-version-min=10.6
-	CXX=icpc
+	LDFLAGS += -arch $(arch) -mmacosx-version-min=10.6
 	profile_prepare = icc-profile-prepare
 	profile_make = icc-profile-make
 	profile_use = icc-profile-use
 	profile_clean = icc-profile-clean
 endif
-### 3.2 General compiler settings
+### On mingw use Windows threads, otherwise POSIX
-CXXFLAGS = -g -Wall -Wcast-qual -fno-exceptions -fno-rtti $(EXTRACXXFLAGS)
+ifneq ($(comp),mingw)
-
+	# On Android Bionic's C library comes with its own pthread implementation bundled in
-ifeq ($(comp),gcc)
+	ifneq ($(arch),armv7)
-	CXXFLAGS += -ansi -pedantic -Wno-long-long -Wextra -Wshadow
+		# Haiku has pthreads in its libroot, so only link it in on other platforms
-endif
+		ifneq ($(UNAME),Haiku)
-
+			LDFLAGS += -lpthread
-ifeq ($(comp),mingw)
+		endif
-	CXXFLAGS += -Wextra -Wshadow
+	endif
 endif
 ifeq ($(comp),icc)
 	CXXFLAGS += -wd383,981,1418,1419,10187,10188,11505,11503 -Wcheck -Wabi -Wdeprecated -strict-ansi
 endif
 ifeq ($(os),osx)
 	CXXFLAGS += -arch $(arch)
 endif
 ### 3.3 General linker settings
 LDFLAGS = -lpthread $(EXTRALDFLAGS)
 ifeq ($(os),osx)
 	LDFLAGS += -arch $(arch)
 endif
 ### 3.4 Debugging
 ifeq ($(debug),no)
 	CXXFLAGS += -DNDEBUG
 else
 	CXXFLAGS += -g
 endif
 ### 3.5 Optimization
@@ -260,7 +213,7 @@ ifeq ($(optimize),yes)
 	ifeq ($(comp),gcc)
 		CXXFLAGS += -O3
-		ifeq ($(os),osx)
+		ifeq ($(UNAME),Darwin)
 			ifeq ($(arch),i386)
 				CXXFLAGS += -mdynamic-no-pic
 			endif
@@ -268,6 +221,10 @@ ifeq ($(optimize),yes)
 				CXXFLAGS += -mdynamic-no-pic
 			endif
 		endif
 		ifeq ($(arch),armv7)
 			CXXFLAGS += -fno-gcse -mthumb -march=armv7-a -mfloat-abi=softfp
 		endif
 	endif
 	ifeq ($(comp),mingw)
@@ -275,10 +232,27 @@ ifeq ($(optimize),yes)
 	endif
 	ifeq ($(comp),icc)
-		ifeq ($(os),osx)
+		ifeq ($(UNAME),Darwin)
 			CXXFLAGS += -fast -mdynamic-no-pic
 		else
-			CXXFLAGS += -O3
+			CXXFLAGS += -fast
 		endif
 	endif
 	ifeq ($(comp),clang)
 		CXXFLAGS += -O3
 		ifeq ($(UNAME),Darwin)
 			ifeq ($(pext),no)
 				CXXFLAGS += -flto
 				LDFLAGS += $(CXXFLAGS)
 			endif
 			ifeq ($(arch),i386)
 				CXXFLAGS += -mdynamic-no-pic
 			endif
 			ifeq ($(arch),x86_64)
 				CXXFLAGS += -mdynamic-no-pic
 			endif
 		endif
 	endif
 endif
@@ -288,36 +262,66 @@ ifeq ($(bits),64)
 	CXXFLAGS += -DIS_64BIT
 endif
-### 3.7 Endianess
+### 3.7 prefetch
 ifeq ($(bigendian),yes)
 	CXXFLAGS += -DBIGENDIAN
 endif
 ### 3.8 prefetch
 ifeq ($(prefetch),yes)
-	CXXFLAGS += -msse
+	ifeq ($(sse),yes)
-	DEPENDFLAGS += -msse
+		CXXFLAGS += -msse
 		DEPENDFLAGS += -msse
 	endif
 else
 	CXXFLAGS += -DNO_PREFETCH
 endif
-### 3.9 bsfq
+### 3.8 bsfq
 ifeq ($(bsfq),yes)
 	CXXFLAGS += -DUSE_BSFQ
 endif
-### 3.10 popcnt
+### 3.9 popcnt
 ifeq ($(popcnt),yes)
-	CXXFLAGS += -DUSE_POPCNT
+	ifeq ($(comp),icc)
 		CXXFLAGS += -msse3 -DUSE_POPCNT
 	else
 		CXXFLAGS += -msse3 -mpopcnt -DUSE_POPCNT
 	endif
 endif
 ### 3.10 pext
 ifeq ($(pext),yes)
 	CXXFLAGS += -DUSE_PEXT
 	ifeq ($(comp),$(filter $(comp),gcc clang mingw))
 		CXXFLAGS += -mbmi -mbmi2
 	endif
 endif
 ### 3.11 Link Time Optimization, it works since gcc 4.5 but not on mingw.
 ### This is a mix of compile and link time options because the lto link phase
 ### needs access to the optimization flags.
 ifeq ($(comp),gcc)
 	ifeq ($(optimize),yes)
 	ifeq ($(debug),no)
 		GCC_MAJOR := `$(CXX) -dumpversion | cut -f1 -d.`
 		GCC_MINOR := `$(CXX) -dumpversion | cut -f2 -d.`
 		ifeq (1,$(shell expr \( $(GCC_MAJOR) \> 4 \) \| \( $(GCC_MAJOR) \= 4 \& $(GCC_MINOR) \>= 5 \)))
 			CXXFLAGS += -flto
 			LDFLAGS += $(CXXFLAGS)
 		endif
 	endif
 	endif
 endif
 ### 3.12 Android 5 can only run position independent executables. Note that this
 ### breaks Android 4.0 and earlier.
 ifeq ($(arch),armv7)
 	CXXFLAGS += -fPIE
 	LDFLAGS += -fPIE -pie
 endif
 ### ==========================================================================
 ### Section 4. Public targets
 ### ==========================================================================
 default:
 	$(MAKE) ARCH=$(ARCH) COMP=$(COMP) build
 help:
 	@echo ""
 	@echo "To compile stockfish, type: "
@@ -326,45 +330,39 @@ help:
 	@echo ""
 	@echo "Supported targets:"
 	@echo ""
-	@echo "build                > Build unoptimized version"
+	@echo "build                   > Standard build"
-	@echo "profile-build        > Build PGO-optimized version"
+	@echo "profile-build           > PGO build"
-	@echo "popcnt-profile-build > Build PGO-optimized version with optional popcnt-support"
+	@echo "strip                   > Strip executable"
-	@echo "strip                > Strip executable"
+	@echo "install                 > Install executable"
-	@echo "install              > Install executable"
+	@echo "clean                   > Clean up"
 	@echo "clean                > Clean up"
 	@echo "testrun              > Make sample run"
 	@echo ""
 	@echo "Supported archs:"
 	@echo ""
-	@echo "x86-64               > x86 64-bit"
+	@echo "x86-64                  > x86 64-bit"
-	@echo "x86-64-modern        > x86 64-bit with runtime support for popcnt-instruction"
+	@echo "x86-64-modern           > x86 64-bit with popcnt support"
-	@echo "x86-32               > x86 32-bit excluding very old hardware without SSE-support"
+	@echo "x86-64-bmi2             > x86 64-bit with pext support"
-	@echo "x86-32-old           > x86 32-bit including also very old hardware"
+	@echo "x86-32                  > x86 32-bit with SSE support"
-	@echo "osx-ppc-64           > PPC-Mac OS X 64 bit"
+	@echo "x86-32-old              > x86 32-bit fall back for old hardware"
-	@echo "osx-ppc-32           > PPC-Mac OS X 32 bit"
+	@echo "ppc-64                  > PPC 64-bit"
-	@echo "osx-x86-64           > x86-Mac OS X 64 bit"
+	@echo "ppc-32                  > PPC 32-bit"
-	@echo "osx-x86-32           > x86-Mac OS X 32 bit"
+	@echo "armv7                   > ARMv7 32-bit"
-	@echo "general-64           > unspecified 64-bit"
+	@echo "general-64              > unspecified 64-bit"
-	@echo "general-32           > unspecified 32-bit"
+	@echo "general-32              > unspecified 32-bit"
 	@echo "bigendian-64         > unspecified 64-bit with bigendian byte order"
 	@echo "bigendian-32         > unspecified 32-bit with bigendian byte order"
 	@echo ""
-	@echo "Supported comps:"
+	@echo "Supported compilers:"
 	@echo ""
-	@echo "gcc                  > Gnu compiler (default)"
+	@echo "gcc                     > Gnu compiler (default)"
-	@echo "icc                  > Intel compiler"
+	@echo "mingw                   > Gnu compiler with MinGW under Windows"
-	@echo "mingw                > Gnu compiler with MinGW under Windows"
+	@echo "clang                   > LLVM Clang compiler"
-	@echo ""
+	@echo "icc                     > Intel compiler"
 	@echo "Non-standard targets:"
 	@echo ""
 	@echo "make hpux           >  Compile for HP-UX. Compiler = aCC"
 	@echo ""
 	@echo "Examples. If you don't know what to do, you likely want to run: "
 	@echo ""
-	@echo "make profile-build ARCH=x86-64    (This is for 64-bit systems)"
+	@echo "make build ARCH=x86-64    (This is for 64-bit systems)"
-	@echo "make profile-build ARCH=x86-32    (This is for 32-bit systems)"
+	@echo "make build ARCH=x86-32    (This is for 32-bit systems)"
 	@echo ""
 .PHONY: build profile-build
 build:
 	$(MAKE) ARCH=$(ARCH) COMP=$(COMP) config-sanity
 	$(MAKE) ARCH=$(ARCH) COMP=$(COMP) all
@@ -376,47 +374,19 @@ profile-build:
 	$(MAKE) ARCH=$(ARCH) COMP=$(COMP) $(profile_prepare)
 	@echo ""
 	@echo "Step 1/4. Building executable for benchmark ..."
-	@touch *.cpp *.h
+	@touch *.cpp *.h syzygy/*.cpp syzygy/*.h
 	$(MAKE) ARCH=$(ARCH) COMP=$(COMP) $(profile_make)
 	@echo ""
 	@echo "Step 2/4. Running benchmark for pgo-build ..."
 	@$(PGOBENCH) > /dev/null
 	@echo ""
 	@echo "Step 3/4. Building final executable ..."
-	@touch *.cpp
+	@touch *.cpp *.h syzygy/*.cpp syzygy/*.h
 	$(MAKE) ARCH=$(ARCH) COMP=$(COMP) $(profile_use)
 	@echo ""
 	@echo "Step 4/4. Deleting profile data ..."
 	$(MAKE) ARCH=$(ARCH) COMP=$(COMP) $(profile_clean)
 popcnt-profile-build:
 	$(MAKE) ARCH=$(ARCH) COMP=$(COMP) config-sanity
 	@echo ""
 	@echo "Step 0/6. Preparing for profile build."
 	$(MAKE) ARCH=$(ARCH) COMP=$(COMP) $(profile_prepare)
 	@echo ""
 	@echo "Step 1/6. Building executable for benchmark (popcnt disabled)..."
 	@touch *.cpp *.h
 	$(MAKE) ARCH=x86-64 COMP=$(COMP) $(profile_make)
 	@echo ""
 	@echo "Step 2/6. Running benchmark for pgo-build (popcnt disabled)..."
 	@$(PGOBENCH) > /dev/null
 	@echo ""
 	@echo "Step 3/6. Building executable for benchmark (popcnt enabled)..."
 	@touch *.cpp *.h
 	$(MAKE) ARCH=x86-64-modern COMP=$(COMP) $(profile_make)
 	@echo ""
 	@echo "Step 4/6. Running benchmark for pgo-build (popcnt enabled)..."
 	@$(PGOBENCH) > /dev/null
 	@echo ""
 	@echo "Step 5/6. Building final executable ..."
 	@touch *.cpp *.h
 	$(MAKE) ARCH=$(ARCH) COMP=$(COMP) $(profile_use)
 	@echo ""
 	@echo "Step 6/6. Deleting profile data ..."
 	$(MAKE) ARCH=$(ARCH) COMP=$(COMP) $(profile_clean)
 	@echo ""
 strip:
 	strip $(EXE)
@@ -426,10 +396,10 @@ install:
 	-strip $(BINDIR)/$(EXE)
 clean:
-	$(RM) $(EXE) $(EXE).exe *.o .depend *~ core bench.txt *.gcda
+	$(RM) $(EXE) $(EXE).exe *.o .depend *~ core bench.txt *.gcda ./syzygy/*.o ./syzygy/*.gcda
-testrun:
+default:
-	@$(PGOBENCH)
+	help
 ### ==========================================================================
 ### Section 5. Private targets
@@ -443,12 +413,12 @@ config-sanity:
 	@echo "debug: '$(debug)'"
 	@echo "optimize: '$(optimize)'"
 	@echo "arch: '$(arch)'"
 	@echo "os: '$(os)'"
 	@echo "bits: '$(bits)'"
 	@echo "bigendian: '$(bigendian)'"
 	@echo "prefetch: '$(prefetch)'"
 	@echo "bsfq: '$(bsfq)'"
 	@echo "popcnt: '$(popcnt)'"
 	@echo "sse: '$(sse)'"
 	@echo "pext: '$(pext)'"
 	@echo ""
 	@echo "Flags:"
 	@echo "CXX: $(CXX)"
@@ -460,14 +430,14 @@ config-sanity:
 	@test "$(debug)" = "yes" || test "$(debug)" = "no"
 	@test "$(optimize)" = "yes" || test "$(optimize)" = "no"
 	@test "$(arch)" = "any" || test "$(arch)" = "x86_64" || test "$(arch)" = "i386" || \
-	 test "$(arch)" = "ppc64" || test "$(arch)" = "ppc"
+	 test "$(arch)" = "ppc64" || test "$(arch)" = "ppc" || test "$(arch)" = "armv7"
 	@test "$(os)" = "any" || test "$(os)" = "osx"
 	@test "$(bits)" = "32" || test "$(bits)" = "64"
 	@test "$(bigendian)" = "yes" || test "$(bigendian)" = "no"
 	@test "$(prefetch)" = "yes" || test "$(prefetch)" = "no"
 	@test "$(bsfq)" = "yes" || test "$(bsfq)" = "no"
 	@test "$(popcnt)" = "yes" || test "$(popcnt)" = "no"
-	@test "$(comp)" = "gcc" || test "$(comp)" = "icc" || test "$(comp)" = "mingw"
+	@test "$(sse)" = "yes" || test "$(sse)" = "no"
 	@test "$(pext)" = "yes" || test "$(pext)" = "no"
 	@test "$(comp)" = "gcc" || test "$(comp)" = "icc" || test "$(comp)" = "mingw" || test "$(comp)" = "clang"
 $(EXE): $(OBJS)
 	$(CXX) -o $@ $(OBJS) $(LDFLAGS)
@@ -477,17 +447,21 @@ gcc-profile-prepare:
 gcc-profile-make:
 	$(MAKE) ARCH=$(ARCH) COMP=$(COMP) \
-	EXTRACXXFLAGS='-fprofile-generate' \
+	EXTRACXXFLAGS='-fprofile-arcs' \
 	EXTRALDFLAGS='-lgcov' \
 	all
 gcc-profile-use:
 # Deleting corrupt ucioption.gc* profile files is necessary to avoid an 
 # "internal compiler error" for gcc versions 4.7.x
 	@rm -f ucioption.gc*
 	$(MAKE) ARCH=$(ARCH) COMP=$(COMP) \
-	EXTRACXXFLAGS='-fprofile-use' \
+	EXTRACXXFLAGS='-fbranch-probabilities' \
 	EXTRALDFLAGS='-lgcov' \
 	all
 gcc-profile-clean:
-	@rm -rf *.gcda *.gcno bench.txt
+	@rm -rf *.gcda *.gcno syzygy/*.gcda syzygy/*.gcno bench.txt
 icc-profile-prepare:
 	$(MAKE) ARCH=$(ARCH) COMP=$(COMP) icc-profile-clean
@@ -511,15 +485,3 @@ icc-profile-clean:
 -include .depend
 ### ==========================================================================
 ### Section 6. Non-standard targets
 ### ==========================================================================
 hpux:
 	$(MAKE) \
 	CXX='/opt/aCC/bin/aCC -AA +hpxstd98 -DBIGENDIAN -mt +O3 -DNDEBUG -DNO_PREFETCH' \
 	CXXFLAGS="" \
 	LDFLAGS="" \
 	all
@@ -1,7 +1,7 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
@@ -17,20 +17,27 @@
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
 #include <algorithm>
 #include <fstream>
 #include <iostream>
 #include <istream>
 #include <vector>
 #include "misc.h"
 #include "position.h"
 #include "search.h"
-#include "ucioption.h"
+#include "thread.h"
 #include "tt.h"
 #include "uci.h"
 using namespace std;
-static const string Defaults[] = {
+namespace {
 const char* Defaults[] = {
  "rnbqkbnr/pppppppp/8/8/8/8/PPPPPPPP/RNBQKBNR w KQkq - 0 1",
-  "r3k2r/p1ppqpb1/bn2pnp1/3PN3/1p2P3/2N2Q1p/PPPBBPPP/R3K2R w KQkq -",
+  "r3k2r/p1ppqpb1/bn2pnp1/3PN3/1p2P3/2N2Q1p/PPPBBPPP/R3K2R w KQkq - 0 10",
-  "8/2p5/3p4/KP5r/1R3p1k/8/4P1P1/8 w - -",
+  "8/2p5/3p4/KP5r/1R3p1k/8/4P1P1/8 w - - 0 11",
  "4rrk1/pp1n3p/3q2pQ/2p1pb2/2PP4/2P3N1/P2B2PP/4RRK1 b - - 7 19",
  "rq3rk1/ppp2ppp/1bnpb3/3N2B1/3NP3/7P/PPPQ1PP1/2KR3R w - - 7 14",
  "r1bq1r1k/1pp1n1pp/1p1p4/4p2Q/4Pp2/1BNP4/PPP2PPP/3R1RK1 w - - 2 14",
@@ -44,110 +51,125 @@ static const string Defaults[] = {
  "r1q2rk1/2p1bppp/2Pp4/p6b/Q1PNp3/4B3/PP1R1PPP/2K4R w - - 2 18",
  "4k2r/1pb2ppp/1p2p3/1R1p4/3P4/2r1PN2/P4PPP/1R4K1 b - - 3 22",
  "3q2k1/pb3p1p/4pbp1/2r5/PpN2N2/1P2P2P/5PP1/Q2R2K1 b - - 4 26",
-  ""
+  "6k1/6p1/6Pp/ppp5/3pn2P/1P3K2/1PP2P2/3N4 b - - 0 1",
  "3b4/5kp1/1p1p1p1p/pP1PpP1P/P1P1P3/3KN3/8/8 w - - 0 1",
  "2K5/p7/7P/5pR1/8/5k2/r7/8 w - - 0 1",
  "8/6pk/1p6/8/PP3p1p/5P2/4KP1q/3Q4 w - - 0 1",
  "7k/3p2pp/4q3/8/4Q3/5Kp1/P6b/8 w - - 0 1",
  "8/2p5/8/2kPKp1p/2p4P/2P5/3P4/8 w - - 0 1",
  "8/1p3pp1/7p/5P1P/2k3P1/8/2K2P2/8 w - - 0 1",
  "8/pp2r1k1/2p1p3/3pP2p/1P1P1P1P/P5KR/8/8 w - - 0 1",
  "8/3p4/p1bk3p/Pp6/1Kp1PpPp/2P2P1P/2P5/5B2 b - - 0 1",
  "5k2/7R/4P2p/5K2/p1r2P1p/8/8/8 b - - 0 1",
  "6k1/6p1/P6p/r1N5/5p2/7P/1b3PP1/4R1K1 w - - 0 1",
  "1r3k2/4q3/2Pp3b/3Bp3/2Q2p2/1p1P2P1/1P2KP2/3N4 w - - 0 1",
  "6k1/4pp1p/3p2p1/P1pPb3/R7/1r2P1PP/3B1P2/6K1 w - - 0 1",
  "8/3p3B/5p2/5P2/p7/PP5b/k7/6K1 w - - 0 1",
  // 5-man positions
  "8/8/8/8/5kp1/P7/8/1K1N4 w - - 0 1",     // Kc2 - mate
  "8/8/8/5N2/8/p7/8/2NK3k w - - 0 1",      // Na2 - mate
  "8/3k4/8/8/8/4B3/4KB2/2B5 w - - 0 1",    // draw
  // 6-man positions
  "8/8/1P6/5pr1/8/4R3/7k/2K5 w - - 0 1",   // Re5 - mate
  "8/2p4P/8/kr6/6R1/8/8/1K6 w - - 0 1",    // Ka2 - mate
  "8/8/3P3k/8/1p6/8/1P6/1K3n2 b - - 0 1",  // Nd2 - draw
  // 7-man positions
  "8/R7/2q5/8/6k1/8/1P5p/K6R w - - 0 124", // Draw
 };
 } // namespace
 /// benchmark() runs a simple benchmark by letting Stockfish analyze a set
-/// of positions for a given limit each.  There are five parameters; the
+/// of positions for a given limit each. There are five parameters: the
 /// transposition table size, the number of search threads that should
-/// be used, the limit value spent for each position (optional, default
+/// be used, the limit value spent for each position (optional, default is
-/// is ply 12), an optional file name where to look for positions in fen
+/// depth 13), an optional file name where to look for positions in FEN
-/// format (default are the BenchmarkPositions defined above) and the type
+/// format (defaults are the positions defined above) and the type of the
-/// of the limit value: depth (default), time in secs or number of nodes.
+/// limit value: depth (default), time in millisecs or number of nodes.
 /// The analysis is written to a file named bench.txt.
-void benchmark(int argc, char* argv[]) {
+void benchmark(const Position& current, istream& is) {
-  vector<string> fenList;
+  string token;
-  SearchLimits limits;
+  Search::LimitsType limits;
-  int64_t totalNodes;
+  vector<string> fens;
  int time;
  // Load default positions
  for (int i = 0; !Defaults[i].empty(); i++)
      fenList.push_back(Defaults[i]);
  // Assign default values to missing arguments
-  string ttSize  = argc > 2 ? argv[2] : "128";
+  string ttSize    = (is >> token) ? token : "16";
-  string threads = argc > 3 ? argv[3] : "1";
+  string threads   = (is >> token) ? token : "1";
-  string valStr  = argc > 4 ? argv[4] : "12";
+  string limit     = (is >> token) ? token : "13";
-  string fenFile = argc > 5 ? argv[5] : "default";
+  string fenFile   = (is >> token) ? token : "default";
-  string valType = argc > 6 ? argv[6] : "depth";
+  string limitType = (is >> token) ? token : "depth";
-  Options["Hash"].set_value(ttSize);
+  Options["Hash"]    = ttSize;
-  Options["Threads"].set_value(threads);
+  Options["Threads"] = threads;
-  Options["OwnBook"].set_value("false");
+  TT.clear();
  if (limitType == "time")
      limits.movetime = atoi(limit.c_str()); // movetime is in ms
  else if (limitType == "nodes")
      limits.nodes = atoi(limit.c_str());
  else if (limitType == "mate")
      limits.mate = atoi(limit.c_str());
  // Search should be limited by nodes, time or depth ?
  if (valType == "nodes")
      limits.maxNodes = atoi(valStr.c_str());
  else if (valType == "time")
      limits.maxTime = 1000 * atoi(valStr.c_str()); // maxTime is in ms
  else
-      limits.maxDepth = atoi(valStr.c_str());
+      limits.depth = atoi(limit.c_str());
-  // Do we need to load positions from a given FEN file ?
+  if (fenFile == "default")
-  if (fenFile != "default")
+      fens.assign(Defaults, Defaults + 37);
  else if (fenFile == "current")
      fens.push_back(current.fen());
  else
  {
      string fen;
-      ifstream f(fenFile.c_str());
+      ifstream file(fenFile.c_str());
-      if (f.is_open())
+      if (!file.is_open())
      {
-          fenList.clear();
+          cerr << "Unable to open file " << fenFile << endl;
-
+          return;
          while (getline(f, fen))
              if (!fen.empty())
                  fenList.push_back(fen);
          f.close();
      }
      else
      {
          cerr << "Unable to open FEN file " << fenFile << endl;
          exit(EXIT_FAILURE);
      }
      while (getline(file, fen))
          if (!fen.empty())
              fens.push_back(fen);
      file.close();
  }
-  // Ok, let's start the benchmark !
+  uint64_t nodes = 0;
-  totalNodes = 0;
+  Search::StateStackPtr st;
-  time = get_system_time();
+  Time::point elapsed = Time::now();
-  for (size_t i = 0; i < fenList.size(); i++)
+  for (size_t i = 0; i < fens.size(); ++i)
  {
-      Move moves[] = { MOVE_NONE };
+      Position pos(fens[i], Options["UCI_Chess960"], Threads.main());
      Position pos(fenList[i], false, 0);
-      cerr << "\nBench position: " << i + 1 << '/' << fenList.size() << endl;
+      cerr << "\nPosition: " << i + 1 << '/' << fens.size() << endl;
-      if (valType == "perft")
+      if (limitType == "perft")
-      {
+          nodes += Search::perft<true>(pos, limits.depth * ONE_PLY);
          int64_t cnt = perft(pos, limits.maxDepth * ONE_PLY);
          totalNodes += cnt;
          cerr << "\nPerft " << limits.maxDepth << " nodes counted: " << cnt << endl;
      }
      else
      {
-          if (!think(pos, limits, moves))
+          Threads.start_thinking(pos, limits, st);
-              break;
+          Threads.wait_for_think_finished();
-
+          nodes += Search::RootPos.nodes_searched();
          totalNodes += pos.nodes_searched();
      }
  }
-  time = get_system_time() - time;
+  elapsed = std::max(Time::now() - elapsed, Time::point(1)); // Avoid a 'divide by zero'
-  cerr << "\n==============================="
+  dbg_print(); // Just before to exit
       << "\nTotal time (ms) : " << time
       << "\nNodes searched  : " << totalNodes
       << "\nNodes/second    : " << (int)(totalNodes / (time / 1000.0)) << endl << endl;
-  // MS Visual C++ debug window always unconditionally closes when program
+  cerr << "\n==========================="
-  // exits, this is bad because we want to read results before.
+       << "\nTotal time (ms) : " << elapsed
-  #if (defined(WINDOWS) || defined(WIN32) || defined(WIN64))
+       << "\nNodes searched  : " << nodes
-  cerr << "Press any key to exit" << endl;
+       << "\nNodes/second    : " << 1000 * nodes / elapsed << endl;
  cin >> time;
  #endif
 }
@@ -1,7 +1,7 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
@@ -18,267 +18,158 @@
 */
 #include <cassert>
 #include <vector>
 #include "bitboard.h"
 #include "types.h"
 namespace {
-  enum Result {
+  // There are 24 possible pawn squares: the first 4 files and ranks from 2 to 7
-    RESULT_UNKNOWN,
+  const unsigned MAX_INDEX = 2*24*64*64; // stm * psq * wksq * bksq = 196608
    RESULT_INVALID,
    RESULT_WIN,
    RESULT_LOSS,
    RESULT_DRAW
  };
  struct KPKPosition {
    void from_index(int index);
    bool is_legal() const;
    bool is_immediate_draw() const;
    bool is_immediate_win() const;
    Bitboard wk_attacks()   const { return StepAttacksBB[WK][whiteKingSquare]; }
    Bitboard bk_attacks()   const { return StepAttacksBB[BK][blackKingSquare]; }
    Bitboard pawn_attacks() const { return StepAttacksBB[WP][pawnSquare]; }
    Square whiteKingSquare, blackKingSquare, pawnSquare;
    Color sideToMove;
  };
  // The possible pawns squares are 24, the first 4 files and ranks from 2 to 7
  const int IndexMax = 2 * 24 * 64 * 64; // color * wp_sq * wk_sq * bk_sq
  // Each uint32_t stores results of 32 positions, one per bit
-  uint32_t KPKBitbase[IndexMax / 32];
+  uint32_t KPKBitbase[MAX_INDEX / 32];
-  Result classify_wtm(const KPKPosition& pos, const Result bb[]);
+  // A KPK bitbase index is an integer in [0, IndexMax] range
-  Result classify_btm(const KPKPosition& pos, const Result bb[]);
+  //
-  int compute_index(Square wksq, Square bksq, Square wpsq, Color stm);
+  // Information is mapped in a way that minimizes the number of iterations:
-}
+  //
-
+  // bit  0- 5: white king square (from SQ_A1 to SQ_H8)
-
+  // bit  6-11: black king square (from SQ_A1 to SQ_H8)
-uint32_t probe_kpk_bitbase(Square wksq, Square wpsq, Square bksq, Color stm) {
+  // bit    12: side to move (WHITE or BLACK)
-
+  // bit 13-14: white pawn file (from FILE_A to FILE_D)
-  int index = compute_index(wksq, bksq, wpsq, stm);
+  // bit 15-17: white pawn RANK_7 - rank (from RANK_7 - RANK_7 to RANK_7 - RANK_2)
-
+  unsigned index(Color us, Square bksq, Square wksq, Square psq) {
-  return KPKBitbase[index / 32] & (1 << (index & 31));
+    return wksq | (bksq << 6) | (us << 12) | (file_of(psq) << 13) | ((RANK_7 - rank_of(psq)) << 15);
 }
 void init_kpk_bitbase() {
  Result bb[IndexMax];
  KPKPosition pos;
  bool repeat;
  // Initialize table
  for (int i = 0; i < IndexMax; i++)
  {
      pos.from_index(i);
      bb[i] = !pos.is_legal()          ? RESULT_INVALID
             : pos.is_immediate_draw() ? RESULT_DRAW
             : pos.is_immediate_win()  ? RESULT_WIN : RESULT_UNKNOWN;
  }
-  // Iterate until all positions are classified (30 cycles needed)
+  enum Result {
-  do {
+    INVALID = 0,
-      repeat = false;
+    UNKNOWN = 1,
    DRAW    = 2,
    WIN     = 4
  };
-      for (int i = 0; i < IndexMax; i++)
+  inline Result& operator|=(Result& r, Result v) { return r = Result(r | v); }
          if (bb[i] == RESULT_UNKNOWN)
          {
              pos.from_index(i);
-              bb[i] = (pos.sideToMove == WHITE) ? classify_wtm(pos, bb)
+  struct KPKPosition {
                                                : classify_btm(pos, bb);
              if (bb[i] != RESULT_UNKNOWN)
                  repeat = true;
          }
-  } while (repeat);
+    KPKPosition(unsigned idx);
    operator Result() const { return result; }
    Result classify(const std::vector<KPKPosition>& db)
    { return us == WHITE ? classify<WHITE>(db) : classify<BLACK>(db); }
-  // Map 32 position results into one KPKBitbase[] entry
+  private:
-  for (int i = 0; i < IndexMax / 32; i++)
+    template<Color Us> Result classify(const std::vector<KPKPosition>& db);
-      for (int j = 0; j < 32; j++)
+
-          if (bb[32 * i + j] == RESULT_WIN || bb[32 * i + j] == RESULT_LOSS)
+    Color us;
-              KPKBitbase[i] |= (1 << j);
+    Square bksq, wksq, psq;
    Result result;
  };
 } // namespace
 bool Bitbases::probe(Square wksq, Square wpsq, Square bksq, Color us) {
  assert(file_of(wpsq) <= FILE_D);
  unsigned idx = index(us, bksq, wksq, wpsq);
  return KPKBitbase[idx / 32] & (1 << (idx & 0x1F));
 }
 void Bitbases::init() {
  unsigned idx, repeat = 1;
  std::vector<KPKPosition> db;
  db.reserve(MAX_INDEX);
  // Initialize db with known win / draw positions
  for (idx = 0; idx < MAX_INDEX; ++idx)
      db.push_back(KPKPosition(idx));
  // Iterate through the positions until none of the unknown positions can be
  // changed to either wins or draws (15 cycles needed).
  while (repeat)
      for (repeat = idx = 0; idx < MAX_INDEX; ++idx)
          repeat |= (db[idx] == UNKNOWN && db[idx].classify(db) != UNKNOWN);
  // Map 32 results into one KPKBitbase[] entry
  for (idx = 0; idx < MAX_INDEX; ++idx)
      if (db[idx] == WIN)
          KPKBitbase[idx / 32] |= 1 << (idx & 0x1F);
 }
 namespace {
- // A KPK bitbase index is an integer in [0, IndexMax] range
+  KPKPosition::KPKPosition(unsigned idx) {
 //
 // Information is mapped in this way
 //
 // bit     0: side to move (WHITE or BLACK)
 // bit  1- 6: black king square (from SQ_A1 to SQ_H8)
 // bit  7-12: white king square (from SQ_A1 to SQ_H8)
 // bit 13-14: white pawn file (from FILE_A to FILE_D)
 // bit 15-17: white pawn rank - 1 (from RANK_2 - 1 to RANK_7 - 1)
-  int compute_index(Square wksq, Square bksq, Square wpsq, Color stm) {
+    wksq   = Square((idx >>  0) & 0x3F);
    bksq   = Square((idx >>  6) & 0x3F);
    us     = Color ((idx >> 12) & 0x01);
    psq    = make_square(File((idx >> 13) & 0x3), RANK_7 - Rank((idx >> 15) & 0x7));
    result = UNKNOWN;
-    assert(square_file(wpsq) <= FILE_D);
+    // Check if two pieces are on the same square or if a king can be captured
    if (   distance(wksq, bksq) <= 1
        || wksq == psq
        || bksq == psq
        || (us == WHITE && (StepAttacksBB[PAWN][psq] & bksq)))
        result = INVALID;
-    int p = int(square_file(wpsq)) + 4 * int(square_rank(wpsq) - 1);
+    else if (us == WHITE)
    int r = int(stm) + 2 * int(bksq) + 128 * int(wksq) + 8192 * p;
    assert(r >= 0 && r < IndexMax);
    return r;
  }
  void KPKPosition::from_index(int index) {
    int s = (index / 8192) % 24;
    sideToMove = Color(index % 2);
    blackKingSquare = Square((index / 2) % 64);
    whiteKingSquare = Square((index / 128) % 64);
    pawnSquare = make_square(File(s % 4), Rank(s / 4 + 1));
  }
  bool KPKPosition::is_legal() const {
    if (   whiteKingSquare == pawnSquare
        || whiteKingSquare == blackKingSquare
        || blackKingSquare == pawnSquare)
        return false;
    if (sideToMove == WHITE)
    {
-        if (   bit_is_set(wk_attacks(), blackKingSquare)
+        // Immediate win if a pawn can be promoted without getting captured
-            || bit_is_set(pawn_attacks(), blackKingSquare))
+        if (   rank_of(psq) == RANK_7
-            return false;
+            && wksq != psq + DELTA_N
            && (   distance(bksq, psq + DELTA_N) > 1
                ||(StepAttacksBB[KING][wksq] & (psq + DELTA_N))))
            result = WIN;
    }
-    else if (bit_is_set(bk_attacks(), whiteKingSquare))
+    // Immediate draw if it is a stalemate or a king captures undefended pawn
-        return false;
+    else if (  !(StepAttacksBB[KING][bksq] & ~(StepAttacksBB[KING][wksq] | StepAttacksBB[PAWN][psq]))
-
+             || (StepAttacksBB[KING][bksq] & psq & ~StepAttacksBB[KING][wksq]))
-    return true;
+        result = DRAW;
  }
-  bool KPKPosition::is_immediate_draw() const {
+  template<Color Us>
  Result KPKPosition::classify(const std::vector<KPKPosition>& db) {
-    if (sideToMove == BLACK)
+    // White to Move: If one move leads to a position classified as WIN, the result
    // of the current position is WIN. If all moves lead to positions classified
    // as DRAW, the current position is classified as DRAW, otherwise the current
    // position is classified as UNKNOWN.
    //
    // Black to Move: If one move leads to a position classified as DRAW, the result
    // of the current position is DRAW. If all moves lead to positions classified
    // as WIN, the position is classified as WIN, otherwise the current position is
    // classified as UNKNOWN.
    const Color Them = (Us == WHITE ? BLACK : WHITE);
    Result r = INVALID;
    Bitboard b = StepAttacksBB[KING][Us == WHITE ? wksq : bksq];
    while (b)
        r |= Us == WHITE ? db[index(Them, bksq, pop_lsb(&b), psq)]
                         : db[index(Them, pop_lsb(&b), wksq, psq)];
    if (Us == WHITE && rank_of(psq) < RANK_7)
    {
-        Bitboard wka = wk_attacks();
+        Square s = psq + DELTA_N;
-        Bitboard bka = bk_attacks();
+        r |= db[index(BLACK, bksq, wksq, s)]; // Single push
-        // Case 1: Stalemate
+        if (rank_of(psq) == RANK_2 && s != wksq && s != bksq)
-        if ((bka & ~(wka | pawn_attacks())) == EmptyBoardBB)
+            r |= db[index(BLACK, bksq, wksq, s + DELTA_N)]; // Double push
            return true;
        // Case 2: King can capture pawn
        if (bit_is_set(bka, pawnSquare) && !bit_is_set(wka, pawnSquare))
            return true;
    }
    if (Us == WHITE)
        return result = r & WIN  ? WIN  : r & UNKNOWN ? UNKNOWN : DRAW;
    else
-    {
+        return result = r & DRAW ? DRAW : r & UNKNOWN ? UNKNOWN : WIN;
        // Case 1: Stalemate (possible pawn files are only from A to D)
        if (   whiteKingSquare == SQ_A8
            && pawnSquare == SQ_A7
            && (blackKingSquare == SQ_C7 || blackKingSquare == SQ_C8))
            return true;
    }
    return false;
  }
-  bool KPKPosition::is_immediate_win() const {
+} // namespace
    // The position is an immediate win if it is white to move and the
    // white pawn can be promoted without getting captured.
    return   sideToMove == WHITE
          && square_rank(pawnSquare) == RANK_7
          && whiteKingSquare != pawnSquare + DELTA_N
          && (   square_distance(blackKingSquare, pawnSquare + DELTA_N) > 1
              || bit_is_set(wk_attacks(), pawnSquare + DELTA_N));
  }
  Result classify_wtm(const KPKPosition& pos, const Result bb[]) {
    // If one move leads to a position classified as RESULT_LOSS, the result
    // of the current position is RESULT_WIN. If all moves lead to positions
    // classified as RESULT_DRAW, the current position is classified RESULT_DRAW
    // otherwise the current position is classified as RESULT_UNKNOWN.
    bool unknownFound = false;
    Bitboard b;
    Square s;
    Result r;
    // King moves
    b = pos.wk_attacks();
    while (b)
    {
        s = pop_1st_bit(&b);
        r = bb[compute_index(s, pos.blackKingSquare, pos.pawnSquare, BLACK)];
        if (r == RESULT_LOSS)
            return RESULT_WIN;
        if (r == RESULT_UNKNOWN)
            unknownFound = true;
    }
    // Pawn moves
    if (square_rank(pos.pawnSquare) < RANK_7)
    {
        s = pos.pawnSquare + DELTA_N;
        r = bb[compute_index(pos.whiteKingSquare, pos.blackKingSquare, s, BLACK)];
        if (r == RESULT_LOSS)
            return RESULT_WIN;
        if (r == RESULT_UNKNOWN)
            unknownFound = true;
        // Double pawn push
        if (   square_rank(s) == RANK_3
            && s != pos.whiteKingSquare
            && s != pos.blackKingSquare)
        {
            s += DELTA_N;
            r = bb[compute_index(pos.whiteKingSquare, pos.blackKingSquare, s, BLACK)];
            if (r == RESULT_LOSS)
                return RESULT_WIN;
            if (r == RESULT_UNKNOWN)
                unknownFound = true;
        }
    }
    return unknownFound ? RESULT_UNKNOWN : RESULT_DRAW;
  }
  Result classify_btm(const KPKPosition& pos, const Result bb[]) {
    // If one move leads to a position classified as RESULT_DRAW, the result
    // of the current position is RESULT_DRAW. If all moves lead to positions
    // classified as RESULT_WIN, the current position is classified as
    // RESULT_LOSS. Otherwise, the current position is classified as
    // RESULT_UNKNOWN.
    bool unknownFound = false;
    Bitboard b;
    Square s;
    Result r;
    // King moves
    b = pos.bk_attacks();
    while (b)
    {
        s = pop_1st_bit(&b);
        r = bb[compute_index(pos.whiteKingSquare, s, pos.pawnSquare, WHITE)];
        if (r == RESULT_DRAW)
            return RESULT_DRAW;
        if (r == RESULT_UNKNOWN)
            unknownFound = true;
    }
    return unknownFound ? RESULT_UNKNOWN : RESULT_LOSS;
  }
 }
@@ -1,7 +1,7 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
@@ -17,470 +17,305 @@
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
-#include <iostream>
+#include <algorithm>
 #include <cstring>   // For std::memset
 #include "bitboard.h"
 #include "bitcount.h"
 #include "misc.h"
-#if defined(IS_64BIT)
+int SquareDistance[SQUARE_NB][SQUARE_NB];
-const uint64_t BMult[64] = {
+Bitboard  RookMasks  [SQUARE_NB];
-  0x0440049104032280ULL, 0x1021023C82008040ULL, 0x0404040082000048ULL,
+Bitboard  RookMagics [SQUARE_NB];
-  0x48C4440084048090ULL, 0x2801104026490000ULL, 0x4100880442040800ULL,
+Bitboard* RookAttacks[SQUARE_NB];
-  0x0181011002E06040ULL, 0x9101004104200E00ULL, 0x1240848848310401ULL,
+unsigned  RookShifts [SQUARE_NB];
  0x2000142828050024ULL, 0x00001004024D5000ULL, 0x0102044400800200ULL,
  0x8108108820112000ULL, 0xA880818210C00046ULL, 0x4008008801082000ULL,
  0x0060882404049400ULL, 0x0104402004240810ULL, 0x000A002084250200ULL,
  0x00100B0880801100ULL, 0x0004080201220101ULL, 0x0044008080A00000ULL,
  0x0000202200842000ULL, 0x5006004882D00808ULL, 0x0000200045080802ULL,
  0x0086100020200601ULL, 0xA802080A20112C02ULL, 0x0080411218080900ULL,
  0x000200A0880080A0ULL, 0x9A01010000104000ULL, 0x0028008003100080ULL,
  0x0211021004480417ULL, 0x0401004188220806ULL, 0x00825051400C2006ULL,
  0x00140C0210943000ULL, 0x0000242800300080ULL, 0x00C2208120080200ULL,
  0x2430008200002200ULL, 0x1010100112008040ULL, 0x8141050100020842ULL,
  0x0000822081014405ULL, 0x800C049E40400804ULL, 0x4A0404028A000820ULL,
  0x0022060201041200ULL, 0x0360904200840801ULL, 0x0881A08208800400ULL,
  0x0060202C00400420ULL, 0x1204440086061400ULL, 0x0008184042804040ULL,
  0x0064040315300400ULL, 0x0C01008801090A00ULL, 0x0808010401140C00ULL,
  0x04004830C2020040ULL, 0x0080005002020054ULL, 0x40000C14481A0490ULL,
  0x0010500101042048ULL, 0x1010100200424000ULL, 0x0000640901901040ULL,
  0x00000A0201014840ULL, 0x00840082AA011002ULL, 0x010010840084240AULL,
  0x0420400810420608ULL, 0x8D40230408102100ULL, 0x4A00200612222409ULL,
  0x0A08520292120600ULL
 };
-const uint64_t RMult[64] = {
+Bitboard  BishopMasks  [SQUARE_NB];
-  0x0A8002C000108020ULL, 0x4440200140003000ULL, 0x8080200010011880ULL,
+Bitboard  BishopMagics [SQUARE_NB];
-  0x0380180080141000ULL, 0x1A00060008211044ULL, 0x410001000A0C0008ULL,
+Bitboard* BishopAttacks[SQUARE_NB];
-  0x9500060004008100ULL, 0x0100024284A20700ULL, 0x0000802140008000ULL,
+unsigned  BishopShifts [SQUARE_NB];
  0x0080C01002A00840ULL, 0x0402004282011020ULL, 0x9862000820420050ULL,
  0x0001001448011100ULL, 0x6432800200800400ULL, 0x040100010002000CULL,
  0x0002800D0010C080ULL, 0x90C0008000803042ULL, 0x4010004000200041ULL,
  0x0003010010200040ULL, 0x0A40828028001000ULL, 0x0123010008000430ULL,
  0x0024008004020080ULL, 0x0060040001104802ULL, 0x00582200028400D1ULL,
  0x4000802080044000ULL, 0x0408208200420308ULL, 0x0610038080102000ULL,
  0x3601000900100020ULL, 0x0000080080040180ULL, 0x00C2020080040080ULL,
  0x0080084400100102ULL, 0x4022408200014401ULL, 0x0040052040800082ULL,
  0x0B08200280804000ULL, 0x008A80A008801000ULL, 0x4000480080801000ULL,
  0x0911808800801401ULL, 0x822A003002001894ULL, 0x401068091400108AULL,
  0x000004A10A00004CULL, 0x2000800640008024ULL, 0x1486408102020020ULL,
  0x000100A000D50041ULL, 0x00810050020B0020ULL, 0x0204000800808004ULL,
  0x00020048100A000CULL, 0x0112000831020004ULL, 0x0009000040810002ULL,
  0x0440490200208200ULL, 0x8910401000200040ULL, 0x6404200050008480ULL,
  0x4B824A2010010100ULL, 0x04080801810C0080ULL, 0x00000400802A0080ULL,
  0x8224080110026400ULL, 0x40002C4104088200ULL, 0x01002100104A0282ULL,
  0x1208400811048021ULL, 0x3201014A40D02001ULL, 0x0005100019200501ULL,
  0x0101000208001005ULL, 0x0002008450080702ULL, 0x001002080301D00CULL,
  0x410201CE5C030092ULL
 };
 const int BShift[64] = {
  58, 59, 59, 59, 59, 59, 59, 58, 59, 59, 59, 59, 59, 59, 59, 59,
  59, 59, 57, 57, 57, 57, 59, 59, 59, 59, 57, 55, 55, 57, 59, 59,
  59, 59, 57, 55, 55, 57, 59, 59, 59, 59, 57, 57, 57, 57, 59, 59,
  59, 59, 59, 59, 59, 59, 59, 59, 58, 59, 59, 59, 59, 59, 59, 58
 };
 const int RShift[64] = {
  52, 53, 53, 53, 53, 53, 53, 52, 53, 54, 54, 54, 54, 54, 54, 53,
  53, 54, 54, 54, 54, 54, 54, 53, 53, 54, 54, 54, 54, 54, 54, 53,
  53, 54, 54, 54, 54, 54, 54, 53, 53, 54, 54, 54, 54, 54, 54, 53,
  53, 54, 54, 54, 54, 54, 54, 53, 52, 53, 53, 53, 53, 53, 53, 52
 };
 #else // if !defined(IS_64BIT)
 const uint64_t BMult[64] = {
  0x54142844C6A22981ULL, 0x710358A6EA25C19EULL, 0x704F746D63A4A8DCULL,
  0xBFED1A0B80F838C5ULL, 0x90561D5631E62110ULL, 0x2804260376E60944ULL,
  0x84A656409AA76871ULL, 0xF0267F64C28B6197ULL, 0x70764EBB762F0585ULL,
  0x92AA09E0CFE161DEULL, 0x41EE1F6BB266F60EULL, 0xDDCBF04F6039C444ULL,
  0x5A3FAB7BAC0D988AULL, 0xD3727877FA4EAA03ULL, 0xD988402D868DDAAEULL,
  0x812B291AFA075C7CULL, 0x94FAF987B685A932ULL, 0x3ED867D8470D08DBULL,
  0x92517660B8901DE8ULL, 0x2D97E43E058814B4ULL, 0x880A10C220B25582ULL,
  0xC7C6520D1F1A0477ULL, 0xDBFC7FBCD7656AA6ULL, 0x78B1B9BFB1A2B84FULL,
  0x2F20037F112A0BC1ULL, 0x657171EA2269A916ULL, 0xC08302B07142210EULL,
  0x0880A4403064080BULL, 0x3602420842208C00ULL, 0x852800DC7E0B6602ULL,
  0x595A3FBBAA0F03B2ULL, 0x9F01411558159D5EULL, 0x2B4A4A5F88B394F2ULL,
  0x4AFCBFFC292DD03AULL, 0x4A4094A3B3F10522ULL, 0xB06F00B491F30048ULL,
  0xD5B3820280D77004ULL, 0x8B2E01E7C8E57A75ULL, 0x2D342794E886C2E6ULL,
  0xC302C410CDE21461ULL, 0x111F426F1379C274ULL, 0xE0569220ABB31588ULL,
  0x5026D3064D453324ULL, 0xE2076040C343CD8AULL, 0x93EFD1E1738021EEULL,
  0xB680804BED143132ULL, 0x44E361B21986944CULL, 0x44C60170EF5C598CULL,
  0xF4DA475C195C9C94ULL, 0xA3AFBB5F72060B1DULL, 0xBC75F410E41C4FFCULL,
  0xB51C099390520922ULL, 0x902C011F8F8EC368ULL, 0x950B56B3D6F5490AULL,
  0x3909E0635BF202D0ULL, 0x5744F90206EC10CCULL, 0xDC59FD76317ABBC1ULL,
  0x881C7C67FCBFC4F6ULL, 0x47CA41E7E440D423ULL, 0xEB0C88112048D004ULL,
  0x51C60E04359AEF1AULL, 0x1AA1FE0E957A5554ULL, 0xDD9448DB4F5E3104ULL,
  0xDC01F6DCA4BEBBDCULL,
 };
 const uint64_t RMult[64] = {
  0xD7445CDEC88002C0ULL, 0xD0A505C1F2001722ULL, 0xE065D1C896002182ULL,
  0x9A8C41E75A000892ULL, 0x8900B10C89002AA8ULL, 0x9B28D1C1D60005A2ULL,
  0x015D6C88DE002D9AULL, 0xB1DBFC802E8016A9ULL, 0x149A1042D9D60029ULL,
  0xB9C08050599E002FULL, 0x132208C3AF300403ULL, 0xC1000CE2E9C50070ULL,
  0x9D9AA13C99020012ULL, 0xB6B078DAF71E0046ULL, 0x9D880182FB6E002EULL,
  0x52889F467E850037ULL, 0xDA6DC008D19A8480ULL, 0x468286034F902420ULL,
  0x7140AC09DC54C020ULL, 0xD76FFFFA39548808ULL, 0xEA901C4141500808ULL,
  0xC91004093F953A02ULL, 0x02882AFA8F6BB402ULL, 0xAEBE335692442C01ULL,
  0x0E904A22079FB91EULL, 0x13A514851055F606ULL, 0x76C782018C8FE632ULL,
  0x1DC012A9D116DA06ULL, 0x3C9E0037264FFFA6ULL, 0x2036002853C6E4A2ULL,
  0xE3FE08500AFB47D4ULL, 0xF38AF25C86B025C2ULL, 0xC0800E2182CF9A40ULL,
  0x72002480D1F60673ULL, 0x2500200BAE6E9B53ULL, 0xC60018C1EEFCA252ULL,
  0x0600590473E3608AULL, 0x46002C4AB3FE51B2ULL, 0xA200011486BCC8D2ULL,
  0xB680078095784C63ULL, 0x2742002639BF11AEULL, 0xC7D60021A5BDB142ULL,
  0xC8C04016BB83D820ULL, 0xBD520028123B4842ULL, 0x9D1600344AC2A832ULL,
  0x6A808005631C8A05ULL, 0x604600A148D5389AULL, 0xE2E40103D40DEA65ULL,
  0x945B5A0087C62A81ULL, 0x012DC200CD82D28EULL, 0x2431C600B5F9EF76ULL,
  0xFB142A006A9B314AULL, 0x06870E00A1C97D62ULL, 0x2A9DB2004A2689A2ULL,
  0xD3594600CAF5D1A2ULL, 0xEE0E4900439344A7ULL, 0x89C4D266CA25007AULL,
  0x3E0013A2743F97E3ULL, 0x0180E31A0431378AULL, 0x3A9E465A4D42A512ULL,
  0x98D0A11A0C0D9CC2ULL, 0x8E711C1ABA19B01EULL, 0x8DCDC836DD201142ULL,
  0x5AC08A4735370479ULL,
 };
 const int BShift[64] = {
  26, 27, 27, 27, 27, 27, 27, 26, 27, 27, 27, 27, 27, 27, 27, 27,
  27, 27, 25, 25, 25, 25, 27, 27, 27, 27, 25, 23, 23, 25, 27, 27,
  27, 27, 25, 23, 23, 25, 27, 27, 27, 27, 25, 25, 25, 25, 27, 27,
  27, 27, 27, 27, 27, 27, 27, 27, 26, 27, 27, 27, 27, 27, 27, 26
 };
 const int RShift[64] = {
  20, 21, 21, 21, 21, 21, 21, 20, 21, 22, 22, 22, 22, 22, 22, 21,
  21, 22, 22, 22, 22, 22, 22, 21, 21, 22, 22, 22, 22, 22, 22, 21,
  21, 22, 22, 22, 22, 22, 22, 21, 21, 22, 22, 22, 22, 22, 22, 21,
  21, 22, 22, 22, 22, 22, 22, 21, 20, 21, 21, 21, 21, 21, 21, 20
 };
 #endif // defined(IS_64BIT)
 // Global bitboards definitions with static storage duration are
 // automatically set to zero before enter main().
 Bitboard RMask[64];
 int RAttackIndex[64];
 Bitboard RAttacks[0x19000];
 Bitboard BMask[64];
 int BAttackIndex[64];
 Bitboard BAttacks[0x1480];
 Bitboard SetMaskBB[65];
 Bitboard ClearMaskBB[65];
 Bitboard SquaresByColorBB[2];
 Bitboard FileBB[8];
 Bitboard RankBB[8];
 Bitboard NeighboringFilesBB[8];
 Bitboard ThisAndNeighboringFilesBB[8];
 Bitboard InFrontBB[2][8];
 Bitboard StepAttacksBB[16][64];
 Bitboard BetweenBB[64][64];
 Bitboard SquaresInFrontMask[2][64];
 Bitboard PassedPawnMask[2][64];
 Bitboard AttackSpanMask[2][64];
 Bitboard BishopPseudoAttacks[64];
 Bitboard RookPseudoAttacks[64];
 Bitboard QueenPseudoAttacks[64];
 uint8_t BitCount8Bit[256];
 Bitboard SquareBB[SQUARE_NB];
 Bitboard FileBB[FILE_NB];
 Bitboard RankBB[RANK_NB];
 Bitboard AdjacentFilesBB[FILE_NB];
 Bitboard InFrontBB[COLOR_NB][RANK_NB];
 Bitboard StepAttacksBB[PIECE_NB][SQUARE_NB];
 Bitboard BetweenBB[SQUARE_NB][SQUARE_NB];
 Bitboard LineBB[SQUARE_NB][SQUARE_NB];
 Bitboard DistanceRingBB[SQUARE_NB][8];
 Bitboard ForwardBB[COLOR_NB][SQUARE_NB];
 Bitboard PassedPawnMask[COLOR_NB][SQUARE_NB];
 Bitboard PawnAttackSpan[COLOR_NB][SQUARE_NB];
 Bitboard PseudoAttacks[PIECE_TYPE_NB][SQUARE_NB];
 namespace {
-  void init_masks();
+  // De Bruijn sequences. See chessprogramming.wikispaces.com/BitScan
-  void init_step_attacks();
+  const uint64_t DeBruijn64 = 0x3F79D71B4CB0A89ULL;
-  void init_pseudo_attacks();
+  const uint32_t DeBruijn32 = 0x783A9B23;
-  void init_between_bitboards();
+
-  Bitboard index_to_bitboard(int index, Bitboard mask);
+  int MS1BTable[256];           // To implement software msb()
-  Bitboard sliding_attacks(int sq, Bitboard occupied, int deltas[][2],
+  Square BSFTable[SQUARE_NB];   // To implement software bitscan
-                           int fmin, int fmax, int rmin, int rmax);
+  Bitboard RookTable[0x19000];  // To store rook attacks
-  void init_sliding_attacks(Bitboard attacks[], int attackIndex[], Bitboard mask[],
+  Bitboard BishopTable[0x1480]; // To store bishop attacks
-                            const int shift[], const Bitboard mult[], int deltas[][2]);
+
  typedef unsigned (Fn)(Square, Bitboard);
  void init_magics(Bitboard table[], Bitboard* attacks[], Bitboard magics[],
                   Bitboard masks[], unsigned shifts[], Square deltas[], Fn index);
  // bsf_index() returns the index into BSFTable[] to look up the bitscan. Uses
  // Matt Taylor's folding for 32 bit case, extended to 64 bit by Kim Walisch.
  FORCE_INLINE unsigned bsf_index(Bitboard b) {
    b ^= b - 1;
    return Is64Bit ? (b * DeBruijn64) >> 58
                   : ((unsigned(b) ^ unsigned(b >> 32)) * DeBruijn32) >> 26;
  }
 }
 #ifndef USE_BSFQ
-/// print_bitboard() prints a bitboard in an easily readable format to the
+/// Software fall-back of lsb() and msb() for CPU lacking hardware support
 /// standard output. This is sometimes useful for debugging.
-void print_bitboard(Bitboard b) {
+Square lsb(Bitboard b) {
  return BSFTable[bsf_index(b)];
 }
-  for (Rank r = RANK_8; r >= RANK_1; r--)
+Square msb(Bitboard b) {
  unsigned b32;
  int result = 0;
  if (b > 0xFFFFFFFF)
  {
-      std::cout << "+---+---+---+---+---+---+---+---+" << '\n';
+      b >>= 32;
-      for (File f = FILE_A; f <= FILE_H; f++)
+      result = 32;
          std::cout << "| " << (bit_is_set(b, make_square(f, r)) ? 'X' : ' ') << ' ';
      std::cout << "|\n";
  }
-  std::cout << "+---+---+---+---+---+---+---+---+" << std::endl;
+
  b32 = unsigned(b);
  if (b32 > 0xFFFF)
  {
      b32 >>= 16;
      result += 16;
  }
  if (b32 > 0xFF)
  {
      b32 >>= 8;
      result += 8;
  }
  return Square(result + MS1BTable[b32]);
 }
 #endif // ifndef USE_BSFQ
 /// Bitboards::pretty() returns an ASCII representation of a bitboard suitable
 /// to be printed to standard output. Useful for debugging.
 const std::string Bitboards::pretty(Bitboard b) {
  std::string s = "+---+---+---+---+---+---+---+---+\n";
  for (Rank r = RANK_8; r >= RANK_1; --r)
  {
      for (File f = FILE_A; f <= FILE_H; ++f)
          s.append(b & make_square(f, r) ? "| X " : "|   ");
      s.append("|\n+---+---+---+---+---+---+---+---+\n");
  }
  return s;
 }
-/// first_1() finds the least significant nonzero bit in a nonzero bitboard.
+/// Bitboards::init() initializes various bitboard tables. It is called at
-/// pop_1st_bit() finds and clears the least significant nonzero bit in a
+/// startup and relies on global objects to be already zero-initialized.
 /// nonzero bitboard.
-#if defined(IS_64BIT) && !defined(USE_BSFQ)
+void Bitboards::init() {
-static CACHE_LINE_ALIGNMENT
+  for (Square s = SQ_A1; s <= SQ_H8; ++s)
-const int BitTable[64] = {
+  {
-   0,  1,  2,  7,  3, 13,  8, 19,  4, 25, 14, 28,  9, 34, 20, 40,  5, 17, 26,
+      SquareBB[s] = 1ULL << s;
-  38, 15, 46, 29, 48, 10, 31, 35, 54, 21, 50, 41, 57, 63,  6, 12, 18, 24, 27,
+      BSFTable[bsf_index(SquareBB[s])] = s;
-  33, 39, 16, 37, 45, 47, 30, 53, 49, 56, 62, 11, 23, 32, 36, 44, 52, 55, 61,
+  }
  22, 43, 51, 60, 42, 59, 58
 };
-Square first_1(Bitboard b) {
+  for (Bitboard b = 1; b < 256; ++b)
-  return Square(BitTable[((b & -b) * 0x218a392cd3d5dbfULL) >> 58]);
+      MS1BTable[b] = more_than_one(b) ? MS1BTable[b - 1] : lsb(b);
  for (File f = FILE_A; f <= FILE_H; ++f)
      FileBB[f] = f > FILE_A ? FileBB[f - 1] << 1 : FileABB;
  for (Rank r = RANK_1; r <= RANK_8; ++r)
      RankBB[r] = r > RANK_1 ? RankBB[r - 1] << 8 : Rank1BB;
  for (File f = FILE_A; f <= FILE_H; ++f)
      AdjacentFilesBB[f] = (f > FILE_A ? FileBB[f - 1] : 0) | (f < FILE_H ? FileBB[f + 1] : 0);
  for (Rank r = RANK_1; r < RANK_8; ++r)
      InFrontBB[WHITE][r] = ~(InFrontBB[BLACK][r + 1] = InFrontBB[BLACK][r] | RankBB[r]);
  for (Color c = WHITE; c <= BLACK; ++c)
      for (Square s = SQ_A1; s <= SQ_H8; ++s)
      {
          ForwardBB[c][s]      = InFrontBB[c][rank_of(s)] & FileBB[file_of(s)];
          PawnAttackSpan[c][s] = InFrontBB[c][rank_of(s)] & AdjacentFilesBB[file_of(s)];
          PassedPawnMask[c][s] = ForwardBB[c][s] | PawnAttackSpan[c][s];
      }
  for (Square s1 = SQ_A1; s1 <= SQ_H8; ++s1)
      for (Square s2 = SQ_A1; s2 <= SQ_H8; ++s2)
          if (s1 != s2)
          {
              SquareDistance[s1][s2] = std::max(distance<File>(s1, s2), distance<Rank>(s1, s2));
              DistanceRingBB[s1][SquareDistance[s1][s2] - 1] |= s2;
          }
  int steps[][9] = { {}, { 7, 9 }, { 17, 15, 10, 6, -6, -10, -15, -17 },
                     {}, {}, {}, { 9, 7, -7, -9, 8, 1, -1, -8 } };
  for (Color c = WHITE; c <= BLACK; ++c)
      for (PieceType pt = PAWN; pt <= KING; ++pt)
          for (Square s = SQ_A1; s <= SQ_H8; ++s)
              for (int i = 0; steps[pt][i]; ++i)
              {
                  Square to = s + Square(c == WHITE ? steps[pt][i] : -steps[pt][i]);
                  if (is_ok(to) && distance(s, to) < 3)
                      StepAttacksBB[make_piece(c, pt)][s] |= to;
              }
  Square RookDeltas[] = { DELTA_N,  DELTA_E,  DELTA_S,  DELTA_W  };
  Square BishopDeltas[] = { DELTA_NE, DELTA_SE, DELTA_SW, DELTA_NW };
  init_magics(RookTable, RookAttacks, RookMagics, RookMasks, RookShifts, RookDeltas, magic_index<ROOK>);
  init_magics(BishopTable, BishopAttacks, BishopMagics, BishopMasks, BishopShifts, BishopDeltas, magic_index<BISHOP>);
  for (Square s1 = SQ_A1; s1 <= SQ_H8; ++s1)
  {
      PseudoAttacks[QUEEN][s1]  = PseudoAttacks[BISHOP][s1] = attacks_bb<BISHOP>(s1, 0);
      PseudoAttacks[QUEEN][s1] |= PseudoAttacks[  ROOK][s1] = attacks_bb<  ROOK>(s1, 0);
      for (Square s2 = SQ_A1; s2 <= SQ_H8; ++s2)
      {
          Piece pc = (PseudoAttacks[BISHOP][s1] & s2) ? W_BISHOP :
                     (PseudoAttacks[ROOK][s1]   & s2) ? W_ROOK   : NO_PIECE;
          if (pc == NO_PIECE)
              continue;
          LineBB[s1][s2] = (attacks_bb(pc, s1, 0) & attacks_bb(pc, s2, 0)) | s1 | s2;
          BetweenBB[s1][s2] = attacks_bb(pc, s1, SquareBB[s2]) & attacks_bb(pc, s2, SquareBB[s1]);
      }
  }
 }
 Square pop_1st_bit(Bitboard* b) {
  Bitboard bb = *b;
  *b &= (*b - 1);
  return Square(BitTable[((bb & -bb) * 0x218a392cd3d5dbfULL) >> 58]);
 }
 #elif !defined(USE_BSFQ)
 static CACHE_LINE_ALIGNMENT
 const int BitTable[64] = {
  63, 30,  3, 32, 25, 41, 22, 33, 15, 50, 42, 13, 11, 53, 19, 34, 61, 29,  2,
  51, 21, 43, 45, 10, 18, 47,  1, 54,  9, 57,  0, 35, 62, 31, 40,  4, 49,  5,
  52, 26, 60,  6, 23, 44, 46, 27, 56, 16,  7, 39, 48, 24, 59, 14, 12, 55, 38,
  28, 58, 20, 37, 17, 36, 8
 };
 Square first_1(Bitboard b) {
  b ^= (b - 1);
  uint32_t fold = int(b) ^ int(b >> 32);
  return Square(BitTable[(fold * 0x783a9b23) >> 26]);
 }
 // Use type-punning
 union b_union {
    Bitboard b;
    struct {
 #if defined (BIGENDIAN)
        uint32_t h;
        uint32_t l;
 #else
        uint32_t l;
        uint32_t h;
 #endif
    } dw;
 };
 Square pop_1st_bit(Bitboard* bb) {
   b_union u;
   Square ret;
   u.b = *bb;
   if (u.dw.l)
   {
       ret = Square(BitTable[((u.dw.l ^ (u.dw.l - 1)) * 0x783a9b23) >> 26]);
       u.dw.l &= (u.dw.l - 1);
       *bb = u.b;
       return ret;
   }
   ret = Square(BitTable[((~(u.dw.h ^ (u.dw.h - 1))) * 0x783a9b23) >> 26]);
   u.dw.h &= (u.dw.h - 1);
   *bb = u.b;
   return ret;
 }
 #endif // !defined(USE_BSFQ)
 /// init_bitboards() initializes various bitboard arrays. It is called during
 /// program initialization.
 void init_bitboards() {
  int rookDeltas[4][2] = {{0,1},{0,-1},{1,0},{-1,0}};
  int bishopDeltas[4][2] = {{1,1},{-1,1},{1,-1},{-1,-1}};
  init_masks();
  init_step_attacks();
  init_sliding_attacks(RAttacks, RAttackIndex, RMask, RShift, RMult, rookDeltas);
  init_sliding_attacks(BAttacks, BAttackIndex, BMask, BShift, BMult, bishopDeltas);
  init_pseudo_attacks();
  init_between_bitboards();
 }
 namespace {
-  // All functions below are used to precompute various bitboards during
+  Bitboard sliding_attack(Square deltas[], Square sq, Bitboard occupied) {
  // program initialization.  Some of the functions may be difficult to
  // understand, but they all seem to work correctly, and it should never
  // be necessary to touch any of them.
-  void init_masks() {
+    Bitboard attack = 0;
-    SquaresByColorBB[DARK]  =  0xAA55AA55AA55AA55ULL;
+    for (int i = 0; i < 4; ++i)
-    SquaresByColorBB[LIGHT] = ~SquaresByColorBB[DARK];
+        for (Square s = sq + deltas[i];
-
+             is_ok(s) && distance(s, s - deltas[i]) == 1;
-    FileBB[FILE_A] = FileABB;
+             s += deltas[i])
    RankBB[RANK_1] = Rank1BB;
    for (int f = FILE_B; f <= FILE_H; f++)
    {
        FileBB[f] = FileBB[f - 1] << 1;
        RankBB[f] = RankBB[f - 1] << 8;
    }
    for (int f = FILE_A; f <= FILE_H; f++)
    {
        NeighboringFilesBB[f] = (f > FILE_A ? FileBB[f - 1] : 0) | (f < FILE_H ? FileBB[f + 1] : 0);
        ThisAndNeighboringFilesBB[f] = FileBB[f] | NeighboringFilesBB[f];
    }
    for (int rw = RANK_7, rb = RANK_2; rw >= RANK_1; rw--, rb++)
    {
        InFrontBB[WHITE][rw] = InFrontBB[WHITE][rw + 1] | RankBB[rw + 1];
        InFrontBB[BLACK][rb] = InFrontBB[BLACK][rb - 1] | RankBB[rb - 1];
    }
    SetMaskBB[SQ_NONE] = EmptyBoardBB;
    ClearMaskBB[SQ_NONE] = ~SetMaskBB[SQ_NONE];
    for (Square s = SQ_A1; s <= SQ_H8; s++)
    {
        SetMaskBB[s] = (1ULL << s);
        ClearMaskBB[s] = ~SetMaskBB[s];
    }
    for (Color c = WHITE; c <= BLACK; c++)
        for (Square s = SQ_A1; s <= SQ_H8; s++)
        {
-            SquaresInFrontMask[c][s] = in_front_bb(c, s) & file_bb(s);
+            attack |= s;
            PassedPawnMask[c][s] = in_front_bb(c, s) & this_and_neighboring_files_bb(s);
            AttackSpanMask[c][s] = in_front_bb(c, s) & neighboring_files_bb(s);
        }
-    for (Bitboard b = 0; b < 256; b++)
+            if (occupied & s)
        BitCount8Bit[b] = (uint8_t)count_1s<CNT32>(b);
  }
  void init_step_attacks() {
    const int step[][9] =  {
      {0},
      {7,9,0}, {17,15,10,6,-6,-10,-15,-17,0}, {0}, {0}, {0},
      {9,7,-7,-9,8,1,-1,-8,0}, {0}, {0},
      {-7,-9,0}, {17,15,10,6,-6,-10,-15,-17,0}, {0}, {0}, {0},
      {9,7,-7,-9,8,1,-1,-8,0}
    };
    for (Square s = SQ_A1; s <= SQ_H8; s++)
        for (Piece pc = WP; pc <= BK; pc++)
            for (int k = 0; step[pc][k] != 0; k++)
            {
                Square to = s + Square(step[pc][k]);
                if (square_is_ok(to) && square_distance(s, to) < 3)
                    set_bit(&StepAttacksBB[pc][s], to);
           }
  }
  Bitboard sliding_attacks(int sq, Bitboard occupied, int deltas[][2],
                           int fmin, int fmax, int rmin, int rmax) {
    int dx, dy, f, r;
    int rk = sq / 8;
    int fl = sq % 8;
    Bitboard attacks = EmptyBoardBB;
    for (int i = 0; i < 4; i++)
    {
        dx = deltas[i][0];
        dy = deltas[i][1];
        f = fl + dx;
        r = rk + dy;
        while (   (dx == 0 || (f >= fmin && f <= fmax))
               && (dy == 0 || (r >= rmin && r <= rmax)))
        {
            attacks |= (1ULL << (f + r * 8));
            if (occupied & (1ULL << (f + r * 8)))
                break;
            f += dx;
            r += dy;
        }
-    }
+
-    return attacks;
+    return attack;
  }
  Bitboard index_to_bitboard(int index, Bitboard mask) {
-    Bitboard result = EmptyBoardBB;
+  // init_magics() computes all rook and bishop attacks at startup. Magic
-    int sq, cnt = 0;
+  // bitboards are used to look up attacks of sliding pieces. As a reference see
  // chessprogramming.wikispaces.com/Magic+Bitboards. In particular, here we
  // use the so called "fancy" approach.
-    while (mask)
+  void init_magics(Bitboard table[], Bitboard* attacks[], Bitboard magics[],
                   Bitboard masks[], unsigned shifts[], Square deltas[], Fn index) {
    int seeds[][RANK_NB] = { { 8977, 44560, 54343, 38998,  5731, 95205, 104912, 17020 },
                             {  728, 10316, 55013, 32803, 12281, 15100,  16645,   255 } };
    Bitboard occupancy[4096], reference[4096], edges, b;
    int i, size;
    // attacks[s] is a pointer to the beginning of the attacks table for square 's'
    attacks[SQ_A1] = table;
    for (Square s = SQ_A1; s <= SQ_H8; ++s)
    {
-        sq = pop_1st_bit(&mask);
+        // Board edges are not considered in the relevant occupancies
        edges = ((Rank1BB | Rank8BB) & ~rank_bb(s)) | ((FileABB | FileHBB) & ~file_bb(s));
-        if (index & (1 << cnt++))
+        // Given a square 's', the mask is the bitboard of sliding attacks from
-            result |= (1ULL << sq);
+        // 's' computed on an empty board. The index must be big enough to contain
-    }
+        // all the attacks for each possible subset of the mask and so is 2 power
-    return result;
+        // the number of 1s of the mask. Hence we deduce the size of the shift to
-  }
+        // apply to the 64 or 32 bits word to get the index.
        masks[s]  = sliding_attack(deltas, s, 0) & ~edges;
        shifts[s] = (Is64Bit ? 64 : 32) - popcount<Max15>(masks[s]);
-  void init_sliding_attacks(Bitboard attacks[], int attackIndex[], Bitboard mask[],
+        // Use Carry-Rippler trick to enumerate all subsets of masks[s] and
-                            const int shift[], const Bitboard mult[], int deltas[][2]) {
+        // store the corresponding sliding attack bitboard in reference[].
-    Bitboard b, v;
+        b = size = 0;
-    int i, j, index;
+        do {
            occupancy[size] = b;
            reference[size] = sliding_attack(deltas, s, b);
-    for (i = index = 0; i < 64; i++)
+            if (HasPext)
-    {
+                attacks[s][pext(b, masks[s])] = reference[size];
        attackIndex[i] = index;
        mask[i] = sliding_attacks(i, 0, deltas, 1, 6, 1, 6);
        j = 1 << ((CpuIs64Bit ? 64 : 32) - shift[i]);
-        for (int k = 0; k < j; k++)
+            size++;
-        {
+            b = (b - masks[s]) & masks[s];
-            b = index_to_bitboard(k, mask[i]);
+        } while (b);
            v = CpuIs64Bit ? b * mult[i] : unsigned(b * mult[i] ^ (b >> 32) * (mult[i] >> 32));
            attacks[index + (v >> shift[i])] = sliding_attacks(i, b, deltas, 0, 7, 0, 7);
        }
        index += j;
    }
  }
-  void init_pseudo_attacks() {
+        // Set the offset for the table of the next square. We have individual
        // table sizes for each square with "Fancy Magic Bitboards".
        if (s < SQ_H8)
            attacks[s + 1] = attacks[s] + size;
-    for (Square s = SQ_A1; s <= SQ_H8; s++)
+        if (HasPext)
-    {
+            continue;
        BishopPseudoAttacks[s] = bishop_attacks_bb(s, EmptyBoardBB);
        RookPseudoAttacks[s]   = rook_attacks_bb(s, EmptyBoardBB);
        QueenPseudoAttacks[s]  = queen_attacks_bb(s, EmptyBoardBB);
    }
  }
-  void init_between_bitboards() {
+        PRNG rng(seeds[Is64Bit][rank_of(s)]);
-    Square s1, s2, s3, d;
+        // Find a magic for square 's' picking up an (almost) random number
-    int f, r;
+        // until we find the one that passes the verification test.
        do {
            do
                magics[s] = rng.sparse_rand<Bitboard>();
            while (popcount<Max15>((magics[s] * masks[s]) >> 56) < 6);
-    for (s1 = SQ_A1; s1 <= SQ_H8; s1++)
+            std::memset(attacks[s], 0, size * sizeof(Bitboard));
-        for (s2 = SQ_A1; s2 <= SQ_H8; s2++)
+
-            if (bit_is_set(QueenPseudoAttacks[s1], s2))
+            // A good magic must map every possible occupancy to an index that
            // looks up the correct sliding attack in the attacks[s] database.
            // Note that we build up the database for square 's' as a side
            // effect of verifying the magic.
            for (i = 0; i < size; ++i)
            {
-                f = file_distance(s1, s2);
+                Bitboard& attack = attacks[s][index(s, occupancy[i])];
                r = rank_distance(s1, s2);
-                d = (s2 - s1) / Max(f, r);
+                if (attack && attack != reference[i])
                    break;
-                for (s3 = s1 + d; s3 != s2; s3 += d)
+                assert(reference[i]);
-                    set_bit(&(BetweenBB[s1][s2]), s3);
+
                attack = reference[i];
            }
        } while (i < size);
    }
  }
 }
@@ -1,7 +1,7 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
@@ -18,12 +18,28 @@
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
-#if !defined(BITBOARD_H_INCLUDED)
+#ifndef BITBOARD_H_INCLUDED
 #define BITBOARD_H_INCLUDED
 #include <string>
 #include "types.h"
-const Bitboard EmptyBoardBB = 0;
+namespace Bitbases {
 void init();
 bool probe(Square wksq, Square wpsq, Square bksq, Color us);
 }
 namespace Bitboards {
 void init();
 const std::string pretty(Bitboard b);
 }
 const Bitboard DarkSquares = 0xAA55AA55AA55AA55ULL;
 const Bitboard FileABB = 0x0101010101010101ULL;
 const Bitboard FileBBB = FileABB << 1;
@@ -43,79 +59,70 @@ const Bitboard Rank6BB = Rank1BB << (8 * 5);
 const Bitboard Rank7BB = Rank1BB << (8 * 6);
 const Bitboard Rank8BB = Rank1BB << (8 * 7);
-extern Bitboard SquaresByColorBB[2];
+extern int SquareDistance[SQUARE_NB][SQUARE_NB];
 extern Bitboard FileBB[8];
 extern Bitboard NeighboringFilesBB[8];
 extern Bitboard ThisAndNeighboringFilesBB[8];
 extern Bitboard RankBB[8];
 extern Bitboard InFrontBB[2][8];
-extern Bitboard SetMaskBB[65];
+extern Bitboard  RookMasks  [SQUARE_NB];
-extern Bitboard ClearMaskBB[65];
+extern Bitboard  RookMagics [SQUARE_NB];
 extern Bitboard* RookAttacks[SQUARE_NB];
 extern unsigned  RookShifts [SQUARE_NB];
-extern Bitboard StepAttacksBB[16][64];
+extern Bitboard  BishopMasks  [SQUARE_NB];
-extern Bitboard BetweenBB[64][64];
+extern Bitboard  BishopMagics [SQUARE_NB];
 extern Bitboard* BishopAttacks[SQUARE_NB];
 extern unsigned  BishopShifts [SQUARE_NB];
-extern Bitboard SquaresInFrontMask[2][64];
+extern Bitboard SquareBB[SQUARE_NB];
-extern Bitboard PassedPawnMask[2][64];
+extern Bitboard FileBB[FILE_NB];
-extern Bitboard AttackSpanMask[2][64];
+extern Bitboard RankBB[RANK_NB];
-
+extern Bitboard AdjacentFilesBB[FILE_NB];
-extern const uint64_t RMult[64];
+extern Bitboard InFrontBB[COLOR_NB][RANK_NB];
-extern const int RShift[64];
+extern Bitboard StepAttacksBB[PIECE_NB][SQUARE_NB];
-extern Bitboard RMask[64];
+extern Bitboard BetweenBB[SQUARE_NB][SQUARE_NB];
-extern int RAttackIndex[64];
+extern Bitboard LineBB[SQUARE_NB][SQUARE_NB];
-extern Bitboard RAttacks[0x19000];
+extern Bitboard DistanceRingBB[SQUARE_NB][8];
-
+extern Bitboard ForwardBB[COLOR_NB][SQUARE_NB];
-extern const uint64_t BMult[64];
+extern Bitboard PassedPawnMask[COLOR_NB][SQUARE_NB];
-extern const int BShift[64];
+extern Bitboard PawnAttackSpan[COLOR_NB][SQUARE_NB];
-extern Bitboard BMask[64];
+extern Bitboard PseudoAttacks[PIECE_TYPE_NB][SQUARE_NB];
 extern int BAttackIndex[64];
 extern Bitboard BAttacks[0x1480];
 extern Bitboard BishopPseudoAttacks[64];
 extern Bitboard RookPseudoAttacks[64];
 extern Bitboard QueenPseudoAttacks[64];
 extern uint8_t BitCount8Bit[256];
-/// Functions for testing whether a given bit is set in a bitboard, and for
+/// Overloads of bitwise operators between a Bitboard and a Square for testing
-/// setting and clearing bits.
+/// whether a given bit is set in a bitboard, and for setting and clearing bits.
-inline Bitboard bit_is_set(Bitboard b, Square s) {
+inline Bitboard operator&(Bitboard b, Square s) {
-  return b & SetMaskBB[s];
+  return b & SquareBB[s];
 }
-inline void set_bit(Bitboard *b, Square s) {
+inline Bitboard operator|(Bitboard b, Square s) {
-  *b |= SetMaskBB[s];
+  return b | SquareBB[s];
 }
-inline void clear_bit(Bitboard *b, Square s) {
+inline Bitboard operator^(Bitboard b, Square s) {
-  *b &= ClearMaskBB[s];
+  return b ^ SquareBB[s];
 }
 inline Bitboard& operator|=(Bitboard& b, Square s) {
  return b |= SquareBB[s];
 }
 inline Bitboard& operator^=(Bitboard& b, Square s) {
  return b ^= SquareBB[s];
 }
 inline bool more_than_one(Bitboard b) {
  return b & (b - 1);
 }
-/// Functions used to update a bitboard after a move. This is faster
+/// rank_bb() and file_bb() return a bitboard representing all the squares on
-/// then calling a sequence of clear_bit() + set_bit()
+/// the given file or rank.
 inline Bitboard make_move_bb(Square from, Square to) {
  return SetMaskBB[from] | SetMaskBB[to];
 }
 inline void do_move_bb(Bitboard *b, Bitboard move_bb) {
  *b ^= move_bb;
 }
 /// rank_bb() and file_bb() take a file or a square as input and return
 /// a bitboard representing all squares on the given file or rank.
 inline Bitboard rank_bb(Rank r) {
  return RankBB[r];
 }
 inline Bitboard rank_bb(Square s) {
-  return RankBB[square_rank(s)];
+  return RankBB[rank_of(s)];
 }
 inline Bitboard file_bb(File f) {
@@ -123,173 +130,211 @@ inline Bitboard file_bb(File f) {
 }
 inline Bitboard file_bb(Square s) {
-  return FileBB[square_file(s)];
+  return FileBB[file_of(s)];
 }
-/// neighboring_files_bb takes a file or a square as input and returns a
+/// shift_bb() moves a bitboard one step along direction Delta. Mainly for pawns
 /// bitboard representing all squares on the neighboring files.
-inline Bitboard neighboring_files_bb(File f) {
+template<Square Delta>
-  return NeighboringFilesBB[f];
+inline Bitboard shift_bb(Bitboard b) {
-}
+  return  Delta == DELTA_N  ?  b             << 8 : Delta == DELTA_S  ?  b             >> 8
-
+        : Delta == DELTA_NE ? (b & ~FileHBB) << 9 : Delta == DELTA_SE ? (b & ~FileHBB) >> 7
-inline Bitboard neighboring_files_bb(Square s) {
+        : Delta == DELTA_NW ? (b & ~FileABB) << 7 : Delta == DELTA_SW ? (b & ~FileABB) >> 9
-  return NeighboringFilesBB[square_file(s)];
+        : 0;
 }
-/// this_and_neighboring_files_bb takes a file or a square as input and returns
+/// adjacent_files_bb() returns a bitboard representing all the squares on the
-/// a bitboard representing all squares on the given and neighboring files.
+/// adjacent files of the given one.
-inline Bitboard this_and_neighboring_files_bb(File f) {
+inline Bitboard adjacent_files_bb(File f) {
-  return ThisAndNeighboringFilesBB[f];
+  return AdjacentFilesBB[f];
 }
 inline Bitboard this_and_neighboring_files_bb(Square s) {
  return ThisAndNeighboringFilesBB[square_file(s)];
 }
-/// in_front_bb() takes a color and a rank or square as input, and returns a
+/// between_bb() returns a bitboard representing all the squares between the two
-/// bitboard representing all the squares on all ranks in front of the rank
+/// given ones. For instance, between_bb(SQ_C4, SQ_F7) returns a bitboard with
-/// (or square), from the given color's point of view.  For instance,
+/// the bits for square d5 and e6 set. If s1 and s2 are not on the same rank, file
-/// in_front_bb(WHITE, RANK_5) will give all squares on ranks 6, 7 and 8, while
+/// or diagonal, 0 is returned.
-/// in_front_bb(BLACK, SQ_D3) will give all squares on ranks 1 and 2.
+
 inline Bitboard between_bb(Square s1, Square s2) {
  return BetweenBB[s1][s2];
 }
 /// in_front_bb() returns a bitboard representing all the squares on all the ranks
 /// in front of the given one, from the point of view of the given color. For
 /// instance, in_front_bb(BLACK, RANK_3) will return the squares on ranks 1 and 2.
 inline Bitboard in_front_bb(Color c, Rank r) {
  return InFrontBB[c][r];
 }
-inline Bitboard in_front_bb(Color c, Square s) {
+
-  return InFrontBB[c][square_rank(s)];
+/// forward_bb() returns a bitboard representing all the squares along the line
 /// in front of the given one, from the point of view of the given color:
 ///        ForwardBB[c][s] = in_front_bb(c, s) & file_bb(s)
 inline Bitboard forward_bb(Color c, Square s) {
  return ForwardBB[c][s];
 }
-/// Functions for computing sliding attack bitboards. rook_attacks_bb(),
+/// pawn_attack_span() returns a bitboard representing all the squares that can be
-/// bishop_attacks_bb() and queen_attacks_bb() all take a square and a
+/// attacked by a pawn of the given color when it moves along its file, starting
-/// bitboard of occupied squares as input, and return a bitboard representing
+/// from the given square:
-/// all squares attacked by a rook, bishop or queen on the given square.
+///       PawnAttackSpan[c][s] = in_front_bb(c, s) & adjacent_files_bb(s);
-#if defined(IS_64BIT)
+inline Bitboard pawn_attack_span(Color c, Square s) {
-
+  return PawnAttackSpan[c][s];
 inline Bitboard rook_attacks_bb(Square s, Bitboard blockers) {
  Bitboard b = blockers & RMask[s];
  return RAttacks[RAttackIndex[s] + ((b * RMult[s]) >> RShift[s])];
 }
 inline Bitboard bishop_attacks_bb(Square s, Bitboard blockers) {
  Bitboard b = blockers & BMask[s];
  return BAttacks[BAttackIndex[s] + ((b * BMult[s]) >> BShift[s])];
 }
 #else // if !defined(IS_64BIT)
 inline Bitboard rook_attacks_bb(Square s, Bitboard blockers) {
  Bitboard b = blockers & RMask[s];
  return RAttacks[RAttackIndex[s] +
        (unsigned(int(b) * int(RMult[s]) ^ int(b >> 32) * int(RMult[s] >> 32)) >> RShift[s])];
 }
 inline Bitboard bishop_attacks_bb(Square s, Bitboard blockers) {
  Bitboard b = blockers & BMask[s];
  return BAttacks[BAttackIndex[s] +
        (unsigned(int(b) * int(BMult[s]) ^ int(b >> 32) * int(BMult[s] >> 32)) >> BShift[s])];
 }
 #endif
 inline Bitboard queen_attacks_bb(Square s, Bitboard blockers) {
  return rook_attacks_bb(s, blockers) | bishop_attacks_bb(s, blockers);
 }
-/// squares_between returns a bitboard representing all squares between
+/// passed_pawn_mask() returns a bitboard mask which can be used to test if a
-/// two squares.  For instance, squares_between(SQ_C4, SQ_F7) returns a
+/// pawn of the given color and on the given square is a passed pawn:
-/// bitboard with the bits for square d5 and e6 set.  If s1 and s2 are not
+///       PassedPawnMask[c][s] = pawn_attack_span(c, s) | forward_bb(c, s)
 /// on the same line, file or diagonal, EmptyBoardBB is returned.
 inline Bitboard squares_between(Square s1, Square s2) {
  return BetweenBB[s1][s2];
 }
 /// squares_in_front_of takes a color and a square as input, and returns a
 /// bitboard representing all squares along the line in front of the square,
 /// from the point of view of the given color. Definition of the table is:
 /// SquaresInFrontOf[c][s] = in_front_bb(c, s) & file_bb(s)
 inline Bitboard squares_in_front_of(Color c, Square s) {
  return SquaresInFrontMask[c][s];
 }
 /// passed_pawn_mask takes a color and a square as input, and returns a
 /// bitboard mask which can be used to test if a pawn of the given color on
 /// the given square is a passed pawn. Definition of the table is:
 /// PassedPawnMask[c][s] = in_front_bb(c, s) & this_and_neighboring_files_bb(s)
 inline Bitboard passed_pawn_mask(Color c, Square s) {
  return PassedPawnMask[c][s];
 }
-/// attack_span_mask takes a color and a square as input, and returns a bitboard
+/// squares_of_color() returns a bitboard representing all the squares of the
-/// representing all squares that can be attacked by a pawn of the given color
+/// same color of the given one.
 /// when it moves along its file starting from the given square. Definition is:
 /// AttackSpanMask[c][s] = in_front_bb(c, s) & neighboring_files_bb(s);
-inline Bitboard attack_span_mask(Color c, Square s) {
+inline Bitboard squares_of_color(Square s) {
-  return AttackSpanMask[c][s];
+  return DarkSquares & s ? DarkSquares : ~DarkSquares;
 }
-/// squares_aligned returns true if the squares s1, s2 and s3 are aligned
+/// aligned() returns true if the squares s1, s2 and s3 are aligned either on a
-/// either on a straight or on a diagonal line.
+/// straight or on a diagonal line.
-inline bool squares_aligned(Square s1, Square s2, Square s3) {
+inline bool aligned(Square s1, Square s2, Square s3) {
-  return  (BetweenBB[s1][s2] | BetweenBB[s1][s3] | BetweenBB[s2][s3])
+  return LineBB[s1][s2] & s3;
        & ((1ULL << s1) | (1ULL << s2) | (1ULL << s3));
 }
-/// first_1() finds the least significant nonzero bit in a nonzero bitboard.
+/// distance() functions return the distance between x and y, defined as the
-/// pop_1st_bit() finds and clears the least significant nonzero bit in a
+/// number of steps for a king in x to reach y. Works with squares, ranks, files.
 /// nonzero bitboard.
-#if defined(USE_BSFQ)
+template<typename T> inline int distance(T x, T y) { return x < y ? y - x : x - y; }
 template<> inline int distance<Square>(Square x, Square y) { return SquareDistance[x][y]; }
-#if defined(_MSC_VER) && !defined(__INTEL_COMPILER)
+template<typename T1, typename T2> inline int distance(T2 x, T2 y);
 template<> inline int distance<File>(Square x, Square y) { return distance(file_of(x), file_of(y)); }
 template<> inline int distance<Rank>(Square x, Square y) { return distance(rank_of(x), rank_of(y)); }
-FORCE_INLINE Square first_1(Bitboard b) {
+
-   unsigned long index;
+/// attacks_bb() returns a bitboard representing all the squares attacked by a
-   _BitScanForward64(&index, b);
+/// piece of type Pt (bishop or rook) placed on 's'. The helper magic_index()
-   return (Square) index;
+/// looks up the index using the 'magic bitboards' approach.
 template<PieceType Pt>
 FORCE_INLINE unsigned magic_index(Square s, Bitboard occupied) {
  Bitboard* const Masks  = Pt == ROOK ? RookMasks  : BishopMasks;
  Bitboard* const Magics = Pt == ROOK ? RookMagics : BishopMagics;
  unsigned* const Shifts = Pt == ROOK ? RookShifts : BishopShifts;
  if (HasPext)
      return unsigned(pext(occupied, Masks[s]));
  if (Is64Bit)
      return unsigned(((occupied & Masks[s]) * Magics[s]) >> Shifts[s]);
  unsigned lo = unsigned(occupied) & unsigned(Masks[s]);
  unsigned hi = unsigned(occupied >> 32) & unsigned(Masks[s] >> 32);
  return (lo * unsigned(Magics[s]) ^ hi * unsigned(Magics[s] >> 32)) >> Shifts[s];
 }
 #else
-FORCE_INLINE Square first_1(Bitboard b) { // Assembly code by Heinz van Saanen
+template<PieceType Pt>
-  Bitboard dummy;
+inline Bitboard attacks_bb(Square s, Bitboard occupied) {
-  __asm__("bsfq %1, %0": "=r"(dummy): "rm"(b) );
+  return (Pt == ROOK ? RookAttacks : BishopAttacks)[s][magic_index<Pt>(s, occupied)];
  return (Square) dummy;
 }
 inline Bitboard attacks_bb(Piece pc, Square s, Bitboard occupied) {
  switch (type_of(pc))
  {
  case BISHOP: return attacks_bb<BISHOP>(s, occupied);
  case ROOK  : return attacks_bb<ROOK>(s, occupied);
  case QUEEN : return attacks_bb<BISHOP>(s, occupied) | attacks_bb<ROOK>(s, occupied);
  default    : return StepAttacksBB[pc][s];
  }
 }
 /// lsb() and msb() return the least/most significant bit in a non-zero bitboard
 #ifdef USE_BSFQ
 #  if defined(_MSC_VER) && !defined(__INTEL_COMPILER)
 FORCE_INLINE Square lsb(Bitboard b) {
  unsigned long idx;
  _BitScanForward64(&idx, b);
  return (Square) idx;
 }
 FORCE_INLINE Square msb(Bitboard b) {
  unsigned long idx;
  _BitScanReverse64(&idx, b);
  return (Square) idx;
 }
 #  elif defined(__arm__)
 FORCE_INLINE int lsb32(uint32_t v) {
  __asm__("rbit %0, %1" : "=r"(v) : "r"(v));
  return __builtin_clz(v);
 }
 FORCE_INLINE Square msb(Bitboard b) {
  return (Square) (63 - __builtin_clzll(b));
 }
 FORCE_INLINE Square lsb(Bitboard b) {
  return (Square) (uint32_t(b) ? lsb32(uint32_t(b)) : 32 + lsb32(uint32_t(b >> 32)));
 }
 #  else // Assumed gcc or compatible compiler
 FORCE_INLINE Square lsb(Bitboard b) { // Assembly code by Heinz van Saanen
  Bitboard idx;
  __asm__("bsfq %1, %0": "=r"(idx): "rm"(b) );
  return (Square) idx;
 }
 FORCE_INLINE Square msb(Bitboard b) {
  Bitboard idx;
  __asm__("bsrq %1, %0": "=r"(idx): "rm"(b) );
  return (Square) idx;
 }
 #  endif
 #else // ifdef(USE_BSFQ)
 Square lsb(Bitboard b);
 Square msb(Bitboard b);
 #endif
-FORCE_INLINE Square pop_1st_bit(Bitboard* b) {
+
-  const Square s = first_1(*b);
+/// pop_lsb() finds and clears the least significant bit in a non-zero bitboard
-  *b &= ~(1ULL<<s);
+
 FORCE_INLINE Square pop_lsb(Bitboard* b) {
  const Square s = lsb(*b);
  *b &= *b - 1;
  return s;
 }
 #else // if !defined(USE_BSFQ)
-extern Square first_1(Bitboard b);
+/// frontmost_sq() and backmost_sq() return the square corresponding to the
-extern Square pop_1st_bit(Bitboard* b);
+/// most/least advanced bit relative to the given color.
-#endif
+inline Square frontmost_sq(Color c, Bitboard b) { return c == WHITE ? msb(b) : lsb(b); }
 inline Square  backmost_sq(Color c, Bitboard b) { return c == WHITE ? lsb(b) : msb(b); }
-
+#endif // #ifndef BITBOARD_H_INCLUDED
 extern void print_bitboard(Bitboard b);
 extern void init_bitboards();
 #endif // !defined(BITBOARD_H_INCLUDED)
@@ -1,7 +1,7 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
@@ -18,81 +18,88 @@
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
-#if !defined(BITCOUNT_H_INCLUDED)
+#ifndef BITCOUNT_H_INCLUDED
 #define BITCOUNT_H_INCLUDED
 #include <cassert>
 #include "types.h"
 enum BitCountType {
-    CNT64,
+  CNT_64,
-    CNT64_MAX15,
+  CNT_64_MAX15,
-    CNT32,
+  CNT_32,
-    CNT32_MAX15,
+  CNT_32_MAX15,
-    CNT_POPCNT
+  CNT_HW_POPCNT
 };
-/// count_1s() counts the number of nonzero bits in a bitboard.
+/// Determine at compile time the best popcount<> specialization according to
-/// We have different optimized versions according if platform
+/// whether the platform is 32 or 64 bit, the maximum number of non-zero
-/// is 32 or 64 bits, and to the maximum number of nonzero bits.
+/// bits to count and if the hardware popcnt instruction is available.
-/// We also support hardware popcnt instruction. See Readme.txt
+const BitCountType Full  = HasPopCnt ? CNT_HW_POPCNT : Is64Bit ? CNT_64       : CNT_32;
-/// on how to pgo compile with popcnt support.
+const BitCountType Max15 = HasPopCnt ? CNT_HW_POPCNT : Is64Bit ? CNT_64_MAX15 : CNT_32_MAX15;
-template<BitCountType> inline int count_1s(Bitboard);
+
 /// popcount() counts the number of non-zero bits in a bitboard
 template<BitCountType> inline int popcount(Bitboard);
 template<>
-inline int count_1s<CNT64>(Bitboard b) {
+inline int popcount<CNT_64>(Bitboard b) {
-  b -= ((b>>1) & 0x5555555555555555ULL);
+  b -=  (b >> 1) & 0x5555555555555555ULL;
-  b = ((b>>2) & 0x3333333333333333ULL) + (b & 0x3333333333333333ULL);
+  b  = ((b >> 2) & 0x3333333333333333ULL) + (b & 0x3333333333333333ULL);
-  b = ((b>>4) + b) & 0x0F0F0F0F0F0F0F0FULL;
+  b  = ((b >> 4) + b) & 0x0F0F0F0F0F0F0F0FULL;
-  b *= 0x0101010101010101ULL;
+  return (b * 0x0101010101010101ULL) >> 56;
  return int(b >> 56);
 }
 template<>
-inline int count_1s<CNT64_MAX15>(Bitboard b) {
+inline int popcount<CNT_64_MAX15>(Bitboard b) {
-  b -= (b>>1) & 0x5555555555555555ULL;
+  b -=  (b >> 1) & 0x5555555555555555ULL;
-  b = ((b>>2) & 0x3333333333333333ULL) + (b & 0x3333333333333333ULL);
+  b  = ((b >> 2) & 0x3333333333333333ULL) + (b & 0x3333333333333333ULL);
-  b *= 0x1111111111111111ULL;
+  return (b * 0x1111111111111111ULL) >> 60;
  return int(b >> 60);
 }
 template<>
-inline int count_1s<CNT32>(Bitboard b) {
+inline int popcount<CNT_32>(Bitboard b) {
  unsigned w = unsigned(b >> 32), v = unsigned(b);
-  v -= (v >> 1) & 0x55555555; // 0-2 in 2 bits
+  v -=  (v >> 1) & 0x55555555; // 0-2 in 2 bits
-  w -= (w >> 1) & 0x55555555;
+  w -=  (w >> 1) & 0x55555555;
-  v = ((v >> 2) & 0x33333333) + (v & 0x33333333); // 0-4 in 4 bits
+  v  = ((v >> 2) & 0x33333333) + (v & 0x33333333); // 0-4 in 4 bits
-  w = ((w >> 2) & 0x33333333) + (w & 0x33333333);
+  w  = ((w >> 2) & 0x33333333) + (w & 0x33333333);
-  v = ((v >> 4) + v) & 0x0F0F0F0F; // 0-8 in 8 bits
+  v  = ((v >> 4) + v + (w >> 4) + w) & 0x0F0F0F0F;
-  v += (((w >> 4) + w) & 0x0F0F0F0F);  // 0-16 in 8 bits
+  return (v * 0x01010101) >> 24;
  v *= 0x01010101; // mul is fast on amd procs
  return int(v >> 24);
 }
 template<>
-inline int count_1s<CNT32_MAX15>(Bitboard b) {
+inline int popcount<CNT_32_MAX15>(Bitboard b) {
  unsigned w = unsigned(b >> 32), v = unsigned(b);
-  v -= (v >> 1) & 0x55555555; // 0-2 in 2 bits
+  v -=  (v >> 1) & 0x55555555; // 0-2 in 2 bits
-  w -= (w >> 1) & 0x55555555;
+  w -=  (w >> 1) & 0x55555555;
-  v = ((v >> 2) & 0x33333333) + (v & 0x33333333); // 0-4 in 4 bits
+  v  = ((v >> 2) & 0x33333333) + (v & 0x33333333); // 0-4 in 4 bits
-  w = ((w >> 2) & 0x33333333) + (w & 0x33333333);
+  w  = ((w >> 2) & 0x33333333) + (w & 0x33333333);
-  v += w; // 0-8 in 4 bits
+  return ((v + w) * 0x11111111) >> 28;
  v *= 0x11111111;
  return int(v >> 28);
 }
 template<>
-inline int count_1s<CNT_POPCNT>(Bitboard b) {
+inline int popcount<CNT_HW_POPCNT>(Bitboard b) {
-#if !defined(USE_POPCNT)
+
-  return int(b != 0); // Avoid 'b not used' warning
+#ifndef USE_POPCNT
  assert(false);
  return b != 0; // Avoid 'b not used' warning
 #elif defined(_MSC_VER) && defined(__INTEL_COMPILER)
  return _mm_popcnt_u64(b);
 #elif defined(_MSC_VER)
  return (int)__popcnt64(b);
-#elif defined(__GNUC__)
+
-  unsigned long ret;
+#else // Assumed gcc or compatible compiler
-  __asm__("popcnt %1, %0" : "=r" (ret) : "r" (b));
+
-  return ret;
+  return __builtin_popcountll(b);
 #endif
 }
-#endif // !defined(BITCOUNT_H_INCLUDED)
+#endif // #ifndef BITCOUNT_H_INCLUDED
@@ -1,540 +0,0 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
  the Free Software Foundation, either version 3 of the License, or
  (at your option) any later version.
  Stockfish is distributed in the hope that it will be useful,
  but WITHOUT ANY WARRANTY; without even the implied warranty of
  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  GNU General Public License for more details.
  You should have received a copy of the GNU General Public License
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
 /*
  The code in this file is based on the opening book code in PolyGlot
  by Fabien Letouzey. PolyGlot is available under the GNU General
  Public License, and can be downloaded from http://wbec-ridderkerk.nl
 */
 #include <cassert>
 #include <iostream>
 #include "book.h"
 #include "movegen.h"
 using namespace std;
 namespace {
  // Random numbers from PolyGlot, used to compute book hash keys
  const uint64_t Random64[781] = {
    0x9D39247E33776D41ULL, 0x2AF7398005AAA5C7ULL, 0x44DB015024623547ULL,
    0x9C15F73E62A76AE2ULL, 0x75834465489C0C89ULL, 0x3290AC3A203001BFULL,
    0x0FBBAD1F61042279ULL, 0xE83A908FF2FB60CAULL, 0x0D7E765D58755C10ULL,
    0x1A083822CEAFE02DULL, 0x9605D5F0E25EC3B0ULL, 0xD021FF5CD13A2ED5ULL,
    0x40BDF15D4A672E32ULL, 0x011355146FD56395ULL, 0x5DB4832046F3D9E5ULL,
    0x239F8B2D7FF719CCULL, 0x05D1A1AE85B49AA1ULL, 0x679F848F6E8FC971ULL,
    0x7449BBFF801FED0BULL, 0x7D11CDB1C3B7ADF0ULL, 0x82C7709E781EB7CCULL,
    0xF3218F1C9510786CULL, 0x331478F3AF51BBE6ULL, 0x4BB38DE5E7219443ULL,
    0xAA649C6EBCFD50FCULL, 0x8DBD98A352AFD40BULL, 0x87D2074B81D79217ULL,
    0x19F3C751D3E92AE1ULL, 0xB4AB30F062B19ABFULL, 0x7B0500AC42047AC4ULL,
    0xC9452CA81A09D85DULL, 0x24AA6C514DA27500ULL, 0x4C9F34427501B447ULL,
    0x14A68FD73C910841ULL, 0xA71B9B83461CBD93ULL, 0x03488B95B0F1850FULL,
    0x637B2B34FF93C040ULL, 0x09D1BC9A3DD90A94ULL, 0x3575668334A1DD3BULL,
    0x735E2B97A4C45A23ULL, 0x18727070F1BD400BULL, 0x1FCBACD259BF02E7ULL,
    0xD310A7C2CE9B6555ULL, 0xBF983FE0FE5D8244ULL, 0x9F74D14F7454A824ULL,
    0x51EBDC4AB9BA3035ULL, 0x5C82C505DB9AB0FAULL, 0xFCF7FE8A3430B241ULL,
    0x3253A729B9BA3DDEULL, 0x8C74C368081B3075ULL, 0xB9BC6C87167C33E7ULL,
    0x7EF48F2B83024E20ULL, 0x11D505D4C351BD7FULL, 0x6568FCA92C76A243ULL,
    0x4DE0B0F40F32A7B8ULL, 0x96D693460CC37E5DULL, 0x42E240CB63689F2FULL,
    0x6D2BDCDAE2919661ULL, 0x42880B0236E4D951ULL, 0x5F0F4A5898171BB6ULL,
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    0x50065E535A213CF6ULL, 0x9C1169FA2777B874ULL, 0x78EDEFD694AF1EEDULL,
    0x6DC93D9526A50E68ULL, 0xEE97F453F06791EDULL, 0x32AB0EDB696703D3ULL,
    0x3A6853C7E70757A7ULL, 0x31865CED6120F37DULL, 0x67FEF95D92607890ULL,
    0x1F2B1D1F15F6DC9CULL, 0xB69E38A8965C6B65ULL, 0xAA9119FF184CCCF4ULL,
    0xF43C732873F24C13ULL, 0xFB4A3D794A9A80D2ULL, 0x3550C2321FD6109CULL,
    0x371F77E76BB8417EULL, 0x6BFA9AAE5EC05779ULL, 0xCD04F3FF001A4778ULL,
    0xE3273522064480CAULL, 0x9F91508BFFCFC14AULL, 0x049A7F41061A9E60ULL,
    0xFCB6BE43A9F2FE9BULL, 0x08DE8A1C7797DA9BULL, 0x8F9887E6078735A1ULL,
    0xB5B4071DBFC73A66ULL, 0x230E343DFBA08D33ULL, 0x43ED7F5A0FAE657DULL,
    0x3A88A0FBBCB05C63ULL, 0x21874B8B4D2DBC4FULL, 0x1BDEA12E35F6A8C9ULL,
    0x53C065C6C8E63528ULL, 0xE34A1D250E7A8D6BULL, 0xD6B04D3B7651DD7EULL,
    0x5E90277E7CB39E2DULL, 0x2C046F22062DC67DULL, 0xB10BB459132D0A26ULL,
    0x3FA9DDFB67E2F199ULL, 0x0E09B88E1914F7AFULL, 0x10E8B35AF3EEAB37ULL,
    0x9EEDECA8E272B933ULL, 0xD4C718BC4AE8AE5FULL, 0x81536D601170FC20ULL,
    0x91B534F885818A06ULL, 0xEC8177F83F900978ULL, 0x190E714FADA5156EULL,
    0xB592BF39B0364963ULL, 0x89C350C893AE7DC1ULL, 0xAC042E70F8B383F2ULL,
    0xB49B52E587A1EE60ULL, 0xFB152FE3FF26DA89ULL, 0x3E666E6F69AE2C15ULL,
    0x3B544EBE544C19F9ULL, 0xE805A1E290CF2456ULL, 0x24B33C9D7ED25117ULL,
    0xE74733427B72F0C1ULL, 0x0A804D18B7097475ULL, 0x57E3306D881EDB4FULL,
    0x4AE7D6A36EB5DBCBULL, 0x2D8D5432157064C8ULL, 0xD1E649DE1E7F268BULL,
    0x8A328A1CEDFE552CULL, 0x07A3AEC79624C7DAULL, 0x84547DDC3E203C94ULL,
    0x990A98FD5071D263ULL, 0x1A4FF12616EEFC89ULL, 0xF6F7FD1431714200ULL,
    0x30C05B1BA332F41CULL, 0x8D2636B81555A786ULL, 0x46C9FEB55D120902ULL,
    0xCCEC0A73B49C9921ULL, 0x4E9D2827355FC492ULL, 0x19EBB029435DCB0FULL,
    0x4659D2B743848A2CULL, 0x963EF2C96B33BE31ULL, 0x74F85198B05A2E7DULL,
    0x5A0F544DD2B1FB18ULL, 0x03727073C2E134B1ULL, 0xC7F6AA2DE59AEA61ULL,
    0x352787BAA0D7C22FULL, 0x9853EAB63B5E0B35ULL, 0xABBDCDD7ED5C0860ULL,
    0xCF05DAF5AC8D77B0ULL, 0x49CAD48CEBF4A71EULL, 0x7A4C10EC2158C4A6ULL,
    0xD9E92AA246BF719EULL, 0x13AE978D09FE5557ULL, 0x730499AF921549FFULL,
    0x4E4B705B92903BA4ULL, 0xFF577222C14F0A3AULL, 0x55B6344CF97AAFAEULL,
    0xB862225B055B6960ULL, 0xCAC09AFBDDD2CDB4ULL, 0xDAF8E9829FE96B5FULL,
    0xB5FDFC5D3132C498ULL, 0x310CB380DB6F7503ULL, 0xE87FBB46217A360EULL,
    0x2102AE466EBB1148ULL, 0xF8549E1A3AA5E00DULL, 0x07A69AFDCC42261AULL,
    0xC4C118BFE78FEAAEULL, 0xF9F4892ED96BD438ULL, 0x1AF3DBE25D8F45DAULL,
    0xF5B4B0B0D2DEEEB4ULL, 0x962ACEEFA82E1C84ULL, 0x046E3ECAAF453CE9ULL,
    0xF05D129681949A4CULL, 0x964781CE734B3C84ULL, 0x9C2ED44081CE5FBDULL,
    0x522E23F3925E319EULL, 0x177E00F9FC32F791ULL, 0x2BC60A63A6F3B3F2ULL,
    0x222BBFAE61725606ULL, 0x486289DDCC3D6780ULL, 0x7DC7785B8EFDFC80ULL,
    0x8AF38731C02BA980ULL, 0x1FAB64EA29A2DDF7ULL, 0xE4D9429322CD065AULL,
    0x9DA058C67844F20CULL, 0x24C0E332B70019B0ULL, 0x233003B5A6CFE6ADULL,
    0xD586BD01C5C217F6ULL, 0x5E5637885F29BC2BULL, 0x7EBA726D8C94094BULL,
    0x0A56A5F0BFE39272ULL, 0xD79476A84EE20D06ULL, 0x9E4C1269BAA4BF37ULL,
    0x17EFEE45B0DEE640ULL, 0x1D95B0A5FCF90BC6ULL, 0x93CBE0B699C2585DULL,
    0x65FA4F227A2B6D79ULL, 0xD5F9E858292504D5ULL, 0xC2B5A03F71471A6FULL,
    0x59300222B4561E00ULL, 0xCE2F8642CA0712DCULL, 0x7CA9723FBB2E8988ULL,
    0x2785338347F2BA08ULL, 0xC61BB3A141E50E8CULL, 0x150F361DAB9DEC26ULL,
    0x9F6A419D382595F4ULL, 0x64A53DC924FE7AC9ULL, 0x142DE49FFF7A7C3DULL,
    0x0C335248857FA9E7ULL, 0x0A9C32D5EAE45305ULL, 0xE6C42178C4BBB92EULL,
    0x71F1CE2490D20B07ULL, 0xF1BCC3D275AFE51AULL, 0xE728E8C83C334074ULL,
    0x96FBF83A12884624ULL, 0x81A1549FD6573DA5ULL, 0x5FA7867CAF35E149ULL,
    0x56986E2EF3ED091BULL, 0x917F1DD5F8886C61ULL, 0xD20D8C88C8FFE65FULL,
    0x31D71DCE64B2C310ULL, 0xF165B587DF898190ULL, 0xA57E6339DD2CF3A0ULL,
    0x1EF6E6DBB1961EC9ULL, 0x70CC73D90BC26E24ULL, 0xE21A6B35DF0C3AD7ULL,
    0x003A93D8B2806962ULL, 0x1C99DED33CB890A1ULL, 0xCF3145DE0ADD4289ULL,
    0xD0E4427A5514FB72ULL, 0x77C621CC9FB3A483ULL, 0x67A34DAC4356550BULL,
    0xF8D626AAAF278509ULL
  };
  // Indices to the Random64[] array
  const int PieceIdx     = 0;
  const int CastleIdx    = 768;
  const int EnPassantIdx = 772;
  const int TurnIdx      = 780;
  // book_key() builds up a PolyGlot hash key out of a position
  uint64_t book_key(const Position& pos) {
    // Piece offset is calculated as (64 * PolyPieceType + square), where
    // PolyPieceType is: BP = 0, WP = 1, BN = 2, WN = 3 .... BK = 10, WK = 11
    static const int PieceToPoly[] = { 0, 1, 3, 5, 7, 9, 11, 0, 0, 0, 2, 4, 6, 8, 10 };
    uint64_t result = 0;
    Bitboard b = pos.occupied_squares();
    while (b)
    {
        Square s = pop_1st_bit(&b);
        int p = PieceToPoly[int(pos.piece_on(s))];
        result ^= Random64[PieceIdx + 64 * p + int(s)];
    }
    if (pos.can_castle_kingside(WHITE))
        result ^= Random64[CastleIdx + 0];
    if (pos.can_castle_queenside(WHITE))
        result ^= Random64[CastleIdx + 1];
    if (pos.can_castle_kingside(BLACK))
        result ^= Random64[CastleIdx + 2];
    if (pos.can_castle_queenside(BLACK))
        result ^= Random64[CastleIdx + 3];
    if (pos.ep_square() != SQ_NONE)
        result ^= Random64[EnPassantIdx + square_file(pos.ep_square())];
    if (pos.side_to_move() == WHITE)
        result ^= Random64[TurnIdx];
    return result;
  }
 }
 /// Book c'tor. Make random number generation less deterministic, for book moves
 Book::Book() {
  for (int i = abs(get_system_time() % 10000); i > 0; i--)
      RKiss.rand<unsigned>();
 }
 /// Book destructor. Be sure file is closed before we leave.
 Book::~Book() {
  close();
 }
 /// Book::close() closes the file only if it is open, otherwise
 /// we can end up in a little mess due to how std::ifstream works.
 void Book::close() {
  if (bookFile.is_open())
      bookFile.close();
  bookName = "";
 }
 /// Book::open() opens a book file with a given file name
 void Book::open(const string& fileName) {
  // Close old file before opening the new
  close();
  bookFile.open(fileName.c_str(), ifstream::in | ifstream::binary);
  // Silently return when asked to open a non-exsistent file
  if (!bookFile.is_open())
      return;
  // Get the book size in number of entries
  bookFile.seekg(0, ios::end);
  bookSize = long(bookFile.tellg()) / sizeof(BookEntry);
  if (!bookFile.good())
  {
      cerr << "Failed to open book file " << fileName << endl;
      exit(EXIT_FAILURE);
  }
  // Set only if successful
  bookName = fileName;
 }
 /// Book::get_move() gets a book move for a given position. Returns
 /// MOVE_NONE if no book move is found. If findBestMove is true then
 /// return always the highest rated book move.
 Move Book::get_move(const Position& pos, bool findBestMove) {
  if (!bookFile.is_open() || bookSize == 0)
      return MOVE_NONE;
  BookEntry entry;
  int bookMove = MOVE_NONE;
  unsigned score, scoresSum = 0, bestScore = 0;
  uint64_t key = book_key(pos);
  // Choose a book move among the possible moves for the given position
  for (int idx = find_entry(key); idx < bookSize; idx++)
  {
      entry = read_entry(idx);
      if (entry.key != key)
          break;
      score = entry.count;
      if (!findBestMove)
      {
          // Choose book move according to its score. If a move has a very
          // high score it has more probability to be choosen then a one with
          // lower score. Note that first entry is always chosen.
          scoresSum += score;
          if (RKiss.rand<unsigned>() % scoresSum < score)
              bookMove = entry.move;
      }
      else if (score > bestScore)
      {
          bestScore = score;
          bookMove = entry.move;
      }
  }
  // A PolyGlot book move is encoded as follows:
  //
  // bit  0- 5: destination square (from 0 to 63)
  // bit  6-11: origin square (from 0 to 63)
  // bit 12-13-14: promotion piece (from KNIGHT == 1 to QUEEN == 4)
  //
  // Castling moves follow "king captures rook" representation. So in case
  // book move is a promotion we have to convert to our representation, in
  // all other cases we can directly compare with a Move after having
  // masked out special Move's flags that are not supported by PolyGlot.
  int p = (bookMove >> 12) & 7;
  if (p)
      bookMove = int(make_promotion_move(move_from(Move(bookMove)),
                 move_to(Move(bookMove)), PieceType(p + 1)));
  // Verify the book move (if any) is legal
  MoveStack mlist[MAX_MOVES];
  MoveStack* last = generate<MV_LEGAL>(pos, mlist);
  for (MoveStack* cur = mlist; cur != last; cur++)
      if ((int(cur->move) & ~(3 << 14)) == bookMove) // Mask out special flags
          return cur->move;
  return MOVE_NONE;
 }
 /// Book::find_entry() takes a book key as input, and does a binary search
 /// through the book file for the given key. The index to the first book
 /// entry with the same key as the input is returned. When the key is not
 /// found in the book file, bookSize is returned.
 int Book::find_entry(uint64_t key) {
  int left, right, mid;
  // Binary search (finds the leftmost entry)
  left = 0;
  right = bookSize - 1;
  assert(left <= right);
  while (left < right)
  {
      mid = (left + right) / 2;
      assert(mid >= left && mid < right);
      if (key <= read_entry(mid).key)
          right = mid;
      else
          left = mid + 1;
  }
  assert(left == right);
  return read_entry(left).key == key ? left : bookSize;
 }
 /// Book::get_number() reads sizeof(T) chars from the file's binary byte
 /// stream and converts them in a number of type T.
 template<typename T>
 void Book::get_number(T& n) {
  n = 0;
  for (size_t i = 0; i < sizeof(T); i++)
      n = (n << 8) + (T)bookFile.get();
 }
 /// Book::read_entry() takes an integer index, and returns the BookEntry
 /// at the given index in the book file.
 BookEntry Book::read_entry(int idx) {
  assert(idx >= 0 && idx < bookSize);
  assert(bookFile.is_open());
  BookEntry e;
  bookFile.seekg(idx * sizeof(BookEntry), ios_base::beg);
  get_number(e.key);
  get_number(e.move);
  get_number(e.count);
  get_number(e.learn);
  if (!bookFile.good())
  {
      cerr << "Failed to read book entry at index " << idx << endl;
      exit(EXIT_FAILURE);
  }
  return e;
 }
@@ -1,62 +0,0 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
  the Free Software Foundation, either version 3 of the License, or
  (at your option) any later version.
  Stockfish is distributed in the hope that it will be useful,
  but WITHOUT ANY WARRANTY; without even the implied warranty of
  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  GNU General Public License for more details.
  You should have received a copy of the GNU General Public License
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
 #if !defined(BOOK_H_INCLUDED)
 #define BOOK_H_INCLUDED
 #include <fstream>
 #include <string>
 #include "move.h"
 #include "position.h"
 #include "rkiss.h"
 // A Polyglot book is a series of "entries" of 16 bytes. All integers are
 // stored highest byte first (regardless of size). The entries are ordered
 // according to key. Lowest key first.
 struct BookEntry {
  uint64_t key;
  uint16_t move;
  uint16_t count;
  uint32_t learn;
 };
 class Book {
 public:
  Book();
  ~Book();
  void open(const std::string& fileName);
  void close();
  Move get_move(const Position& pos, bool findBestMove);
  const std::string name() const { return bookName; }
 private:
  template<typename T> void get_number(T& n);
  BookEntry read_entry(int idx);
  int find_entry(uint64_t key);
  std::ifstream bookFile;
  std::string bookName;
  int bookSize;
  RKISS RKiss;
 };
 #endif // !defined(BOOK_H_INCLUDED)
@@ -1,7 +1,7 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
@@ -17,11 +17,11 @@
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
-#if !defined(ENDGAME_H_INCLUDED)
+#ifndef ENDGAME_H_INCLUDED
 #define ENDGAME_H_INCLUDED
 #include <string>
 #include <map>
 #include <string>
 #include "position.h"
 #include "types.h"
@@ -33,80 +33,90 @@ enum EndgameType {
  // Evaluation functions
  KNNK,  // KNN vs K
  KXK,   // Generic "mate lone king" eval
  KBNK,  // KBN vs K
  KPK,   // KP vs K
  KRKP,  // KR vs KP
  KRKB,  // KR vs KB
  KRKN,  // KR vs KN
  KQKP,  // KQ vs KP
  KQKR,  // KQ vs KR
  KBBKN, // KBB vs KN
  KNNK,  // KNN vs K
  KmmKm, // K and two minors vs K and one or two minors
  // Scaling functions
  SCALING_FUNCTIONS,
-  KBPsK,   // KB+pawns vs K
+  KBPsK,   // KB and pawns vs K
-  KQKRPs,  // KQ vs KR+pawns
+  KQKRPs,  // KQ vs KR and pawns
  KRPKR,   // KRP vs KR
  KRPKB,   // KRP vs KB
  KRPPKRP, // KRPP vs KRP
-  KPsK,    // King and pawns vs king
+  KPsK,    // K and pawns vs K
  KBPKB,   // KBP vs KB
  KBPPKB,  // KBPP vs KB
  KBPKN,   // KBP vs KN
  KNPK,    // KNP vs K
  KNPKB,   // KNP vs KB
  KPKP     // KP vs KP
 };
 /// Endgame functions can be of two types depending on whether they return a
 /// Value or a ScaleFactor. Type eg_fun<int>::type returns either ScaleFactor
 /// or Value depending on whether the template parameter is 0 or 1.
 template<int> struct eg_fun { typedef Value type; };
 template<> struct eg_fun<1> { typedef ScaleFactor type; };
 /// Base and derived templates for endgame evaluation and scaling functions
 template<typename T>
 struct EndgameBase {
  typedef EndgameBase<T> Base;
  virtual ~EndgameBase() {}
-  virtual Color color() const = 0;
+  virtual Color strong_side() const = 0;
-  virtual T apply(const Position&) const = 0;
+  virtual T operator()(const Position&) const = 0;
 };
-template<typename T, EndgameType>
+template<EndgameType E, typename T = typename eg_fun<(E > SCALING_FUNCTIONS)>::type>
 struct Endgame : public EndgameBase<T> {
-  explicit Endgame(Color c) : strongerSide(c), weakerSide(opposite_color(c)) {}
+  explicit Endgame(Color c) : strongSide(c), weakSide(~c) {}
-  Color color() const { return strongerSide; }
+  Color strong_side() const { return strongSide; }
-  T apply(const Position&) const;
+  T operator()(const Position&) const;
 private:
-  Color strongerSide, weakerSide;
+  Color strongSide, weakSide;
 };
-/// Endgames class stores in two std::map the pointers to endgame evaluation
+/// The Endgames class stores the pointers to endgame evaluation and scaling
-/// and scaling base objects. Then we use polymorphism to invoke the actual
+/// base objects in two std::map. We use polymorphism to invoke the actual
-/// endgame function calling its apply() method that is virtual.
+/// endgame function by calling its virtual operator().
 class Endgames {
-  typedef std::map<Key, EndgameBase<Value>* > EFMap;
+  typedef std::map<Key, EndgameBase<eg_fun<0>::type>*> M1;
-  typedef std::map<Key, EndgameBase<ScaleFactor>* > SFMap;
+  typedef std::map<Key, EndgameBase<eg_fun<1>::type>*> M2;
  M1 m1;
  M2 m2;
  M1& map(M1::mapped_type) { return m1; }
  M2& map(M2::mapped_type) { return m2; }
  template<EndgameType E> void add(const std::string& code);
 public:
  Endgames();
-  ~Endgames();
+ ~Endgames();
  template<class T> T* get(Key key) const;
-private:
+  template<typename T> T probe(Key key, T& eg) {
-  template<class T> void add(const std::string& keyCode);
+    return eg = map(eg).count(key) ? map(eg)[key] : NULL;
-
+  }
  // Here we store two maps, for evaluate and scaling functions...
  std::pair<EFMap, SFMap> maps;
  // ...and here is the accessing template function
  template<typename T> const std::map<Key, T*>& get() const;
 };
-#endif // !defined(ENDGAME_H_INCLUDED)
+#endif // #ifndef ENDGAME_H_INCLUDED
@@ -1,7 +1,7 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
@@ -17,15 +17,23 @@
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
-#if !defined(EVALUATE_H_INCLUDED)
+#ifndef EVALUATE_H_INCLUDED
 #define EVALUATE_H_INCLUDED
 #include <string>
 #include "types.h"
 class Position;
-extern Value evaluate(const Position& pos, Value& margin);
+namespace Eval {
 extern std::string trace_evaluate(const Position& pos);
 extern void read_evaluation_uci_options(Color sideToMove);
-#endif // !defined(EVALUATE_H_INCLUDED)
+const Value Tempo = Value(17); // Must be visible to search
 void init();
 Value evaluate(const Position& pos);
 std::string trace(const Position& pos);
 }
 #endif // #ifndef EVALUATE_H_INCLUDED
@@ -1,70 +0,0 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
  the Free Software Foundation, either version 3 of the License, or
  (at your option) any later version.
  Stockfish is distributed in the hope that it will be useful,
  but WITHOUT ANY WARRANTY; without even the implied warranty of
  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  GNU General Public License for more details.
  You should have received a copy of the GNU General Public License
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
 #if !defined(HISTORY_H_INCLUDED)
 #define HISTORY_H_INCLUDED
 #include <cstring>
 #include "types.h"
 /// The History class stores statistics about how often different moves
 /// have been successful or unsuccessful during the current search. These
 /// statistics are used for reduction and move ordering decisions. History
 /// entries are stored according only to moving piece and destination square,
 /// in particular two moves with different origin but same destination and
 /// same piece will be considered identical.
 class History {
 public:
  void clear();
  Value value(Piece p, Square to) const;
  void update(Piece p, Square to, Value bonus);
  Value gain(Piece p, Square to) const;
  void update_gain(Piece p, Square to, Value g);
  static const Value MaxValue = Value(2000);
 private:
  Value history[16][64];  // [piece][to_square]
  Value maxGains[16][64]; // [piece][to_square]
 };
 inline void History::clear() {
  memset(history,  0, 16 * 64 * sizeof(Value));
  memset(maxGains, 0, 16 * 64 * sizeof(Value));
 }
 inline Value History::value(Piece p, Square to) const {
  return history[p][to];
 }
 inline void History::update(Piece p, Square to, Value bonus) {
  if (abs(history[p][to] + bonus) < MaxValue) history[p][to] += bonus;
 }
 inline Value History::gain(Piece p, Square to) const {
  return maxGains[p][to];
 }
 inline void History::update_gain(Piece p, Square to, Value g) {
  maxGains[p][to] = Max(g, maxGains[p][to] - 1);
 }
 #endif // !defined(HISTORY_H_INCLUDED)
@@ -1,79 +0,0 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
  the Free Software Foundation, either version 3 of the License, or
  (at your option) any later version.
  Stockfish is distributed in the hope that it will be useful,
  but WITHOUT ANY WARRANTY; without even the implied warranty of
  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  GNU General Public License for more details.
  You should have received a copy of the GNU General Public License
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
 #if !defined(LOCK_H_INCLUDED)
 #define LOCK_H_INCLUDED
 #if !defined(_MSC_VER)
 #  include <pthread.h>
 typedef pthread_mutex_t Lock;
 typedef pthread_cond_t WaitCondition;
 #  define lock_init(x) pthread_mutex_init(x, NULL)
 #  define lock_grab(x) pthread_mutex_lock(x)
 #  define lock_release(x) pthread_mutex_unlock(x)
 #  define lock_destroy(x) pthread_mutex_destroy(x)
 #  define cond_destroy(x) pthread_cond_destroy(x)
 #  define cond_init(x) pthread_cond_init(x, NULL)
 #  define cond_signal(x) pthread_cond_signal(x)
 #  define cond_wait(x,y) pthread_cond_wait(x,y)
 #else
 #define WIN32_LEAN_AND_MEAN
 #include <windows.h>
 #undef WIN32_LEAN_AND_MEAN
 // Default fast and race free locks and condition variables
 #if !defined(OLD_LOCKS)
 typedef SRWLOCK Lock;
 typedef CONDITION_VARIABLE WaitCondition;
 #  define lock_init(x) InitializeSRWLock(x)
 #  define lock_grab(x) AcquireSRWLockExclusive(x)
 #  define lock_release(x) ReleaseSRWLockExclusive(x)
 #  define lock_destroy(x) (x)
 #  define cond_destroy(x) (x)
 #  define cond_init(x) InitializeConditionVariable(x)
 #  define cond_signal(x) WakeConditionVariable(x)
 #  define cond_wait(x,y) SleepConditionVariableSRW(x, y, INFINITE,0)
 // Fallback solution to build for Windows XP and older versions, note that
 // cond_wait() is racy between lock_release() and WaitForSingleObject().
 #else
 typedef CRITICAL_SECTION Lock;
 typedef HANDLE WaitCondition;
 #  define lock_init(x) InitializeCriticalSection(x)
 #  define lock_grab(x) EnterCriticalSection(x)
 #  define lock_release(x) LeaveCriticalSection(x)
 #  define lock_destroy(x) DeleteCriticalSection(x)
 #  define cond_init(x) { *x = CreateEvent(0, FALSE, FALSE, 0); }
 #  define cond_destroy(x) CloseHandle(*x)
 #  define cond_signal(x) SetEvent(*x)
 #  define cond_wait(x,y) { lock_release(y); WaitForSingleObject(*x, INFINITE); lock_grab(y); }
 #endif
 #endif
 #endif // !defined(LOCK_H_INCLUDED)
@@ -1,7 +1,7 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
@@ -17,71 +17,33 @@
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
 // To profile with callgrind uncomment following line
 //#define USE_CALLGRIND
 #include <cstdio>
 #include <iostream>
 #include <string>
 #include "bitboard.h"
 #include "evaluate.h"
 #include "position.h"
 #include "thread.h"
 #include "search.h"
-#include "ucioption.h"
+#include "thread.h"
-
+#include "tt.h"
-#ifdef USE_CALLGRIND
+#include "uci.h"
-#include <valgrind/callgrind.h>
+#include "syzygy/tbprobe.h"
 #endif
 using namespace std;
 extern bool execute_uci_command(const string& cmd);
 extern void benchmark(int argc, char* argv[]);
 extern void init_kpk_bitbase();
 int main(int argc, char* argv[]) {
-  // Disable IO buffering for C and C++ standard libraries
+  std::cout << engine_info() << std::endl;
  setvbuf(stdin, NULL, _IONBF, 0);
  setvbuf(stdout, NULL, _IONBF, 0);
  cout.rdbuf()->pubsetbuf(NULL, 0);
  cin.rdbuf()->pubsetbuf(NULL, 0);
-  // Startup initializations
+  UCI::init(Options);
-  init_bitboards();
+  Bitboards::init();
-  Position::init_zobrist();
+  Position::init();
-  Position::init_piece_square_tables();
+  Bitbases::init();
-  init_kpk_bitbase();
+  Search::init();
-  init_search();
+  Eval::init();
  Pawns::init();
  Threads.init();
  Tablebases::init(Options["SyzygyPath"]);
  TT.resize(Options["Hash"]);
-#ifdef USE_CALLGRIND
+  UCI::loop(argc, argv);
  CALLGRIND_START_INSTRUMENTATION;
 #endif
  if (argc < 2)
  {
      // Print copyright notice
      cout << engine_name() << " by " << engine_authors() << endl;
      if (CpuHasPOPCNT)
          cout << "Good! CPU has hardware POPCNT." << endl;
      // Wait for a command from the user, and passes this command to
      // execute_uci_command() and also intercepts EOF from stdin to
      // ensure that we exit gracefully if the GUI dies unexpectedly.
      string cmd;
      while (getline(cin, cmd) && execute_uci_command(cmd)) {}
  }
  else if (string(argv[1]) == "bench" && argc < 8)
      benchmark(argc, argv);
  else
      cout << "Usage: stockfish bench [hash size = 128] [threads = 1] "
           << "[limit = 12] [fen positions file = default] "
           << "[limited by depth, time, nodes or perft = depth]" << endl;
  Threads.exit();
  return 0;
 }
@@ -1,7 +1,7 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
@@ -17,269 +17,222 @@
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
 #include <algorithm> // For std::min
 #include <cassert>
-#include <cstring>
+#include <cstring>   // For std::memset
 #include "material.h"
 #include "thread.h"
 using namespace std;
 namespace {
-  // Values modified by Joona Kiiski
+  // Polynomial material imbalance parameters
  const Value MidgameLimit = Value(15581);
  const Value EndgameLimit = Value(3998);
-  // Scale factors used when one side has no more pawns
+  //                      pair  pawn knight bishop rook queen
-  const int NoPawnsSF[4] = { 6, 12, 32 };
+  const int Linear[6] = { 1852, -162, -1122, -183,  249, -154 };
-  // Polynomial material balance parameters
+  const int QuadraticOurs[][PIECE_TYPE_NB] = {
-  const Value RedundantQueenPenalty = Value(320);
+    //            OUR PIECES
-  const Value RedundantRookPenalty  = Value(554);
+    // pair pawn knight bishop rook queen
    {   0                               }, // Bishop pair
    {  39,    2                         }, // Pawn
    {  35,  271,  -4                    }, // Knight      OUR PIECES
    {   0,  105,   4,    0              }, // Bishop
    { -27,   -2,  46,   100,  -141      }, // Rook
    {-177,   25, 129,   142,  -137,   0 }  // Queen
  };
-  const int LinearCoefficients[6] = { 1617, -162, -1172, -190, 105, 26 };
+  const int QuadraticTheirs[][PIECE_TYPE_NB] = {
    //           THEIR PIECES
    // pair pawn knight bishop rook queen
    {   0                               }, // Bishop pair
    {  37,    0                         }, // Pawn
    {  10,   62,   0                    }, // Knight      OUR PIECES
    {  57,   64,  39,     0             }, // Bishop
    {  50,   40,  23,   -22,    0       }, // Rook
    {  98,  105, -39,   141,  274,    0 }  // Queen
  };
-  const int QuadraticCoefficientsSameColor[][8] = {
+  // Endgame evaluation and scaling functions are accessed directly and not through
-  { 7, 7, 7, 7, 7, 7 }, { 39, 2, 7, 7, 7, 7 }, { 35, 271, -4, 7, 7, 7 },
+  // the function maps because they correspond to more than one material hash key.
-  { 7, 25, 4, 7, 7, 7 }, { -27, -2, 46, 100, 56, 7 }, { 58, 29, 83, 148, -3, -25 } };
+  Endgame<KXK>    EvaluateKXK[] = { Endgame<KXK>(WHITE),    Endgame<KXK>(BLACK) };
-  const int QuadraticCoefficientsOppositeColor[][8] = {
+  Endgame<KBPsK>  ScaleKBPsK[]  = { Endgame<KBPsK>(WHITE),  Endgame<KBPsK>(BLACK) };
-  { 41, 41, 41, 41, 41, 41 }, { 37, 41, 41, 41, 41, 41 }, { 10, 62, 41, 41, 41, 41 },
+  Endgame<KQKRPs> ScaleKQKRPs[] = { Endgame<KQKRPs>(WHITE), Endgame<KQKRPs>(BLACK) };
-  { 57, 64, 39, 41, 41, 41 }, { 50, 40, 23, -22, 41, 41 }, { 106, 101, 3, 151, 171, 41 } };
+  Endgame<KPsK>   ScaleKPsK[]   = { Endgame<KPsK>(WHITE),   Endgame<KPsK>(BLACK) };
-
+  Endgame<KPKP>   ScaleKPKP[]   = { Endgame<KPKP>(WHITE),   Endgame<KPKP>(BLACK) };
  // Endgame evaluation and scaling functions accessed direcly and not through
  // the function maps because correspond to more then one material hash key.
  Endgame<Value, KmmKm> EvaluateKmmKm[] = { Endgame<Value, KmmKm>(WHITE), Endgame<Value, KmmKm>(BLACK) };
  Endgame<Value, KXK>   EvaluateKXK[]   = { Endgame<Value, KXK>(WHITE),   Endgame<Value, KXK>(BLACK) };
  Endgame<ScaleFactor, KBPsK>  ScaleKBPsK[]  = { Endgame<ScaleFactor, KBPsK>(WHITE),  Endgame<ScaleFactor, KBPsK>(BLACK) };
  Endgame<ScaleFactor, KQKRPs> ScaleKQKRPs[] = { Endgame<ScaleFactor, KQKRPs>(WHITE), Endgame<ScaleFactor, KQKRPs>(BLACK) };
  Endgame<ScaleFactor, KPsK>   ScaleKPsK[]   = { Endgame<ScaleFactor, KPsK>(WHITE),   Endgame<ScaleFactor, KPsK>(BLACK) };
  Endgame<ScaleFactor, KPKP>   ScaleKPKP[]   = { Endgame<ScaleFactor, KPKP>(WHITE),   Endgame<ScaleFactor, KPKP>(BLACK) };
  // Helper templates used to detect a given material distribution
  template<Color Us> bool is_KXK(const Position& pos) {
    const Color Them = (Us == WHITE ? BLACK : WHITE);
-    return   pos.non_pawn_material(Them) == VALUE_ZERO
+    return  !more_than_one(pos.pieces(Them))
-          && pos.piece_count(Them, PAWN) == 0
+          && pos.non_pawn_material(Us) >= RookValueMg;
          && pos.non_pawn_material(Us)   >= RookValueMidgame;
  }
  template<Color Us> bool is_KBPsKs(const Position& pos) {
-    return   pos.non_pawn_material(Us)   == BishopValueMidgame
+    return   pos.non_pawn_material(Us) == BishopValueMg
-          && pos.piece_count(Us, BISHOP) == 1
+          && pos.count<BISHOP>(Us) == 1
-          && pos.piece_count(Us, PAWN)   >= 1;
+          && pos.count<PAWN  >(Us) >= 1;
  }
  template<Color Us> bool is_KQKRPs(const Position& pos) {
    const Color Them = (Us == WHITE ? BLACK : WHITE);
-    return   pos.piece_count(Us, PAWN)    == 0
+    return  !pos.count<PAWN>(Us)
-          && pos.non_pawn_material(Us)    == QueenValueMidgame
+          && pos.non_pawn_material(Us) == QueenValueMg
-          && pos.piece_count(Us, QUEEN)   == 1
+          && pos.count<QUEEN>(Us)  == 1
-          && pos.piece_count(Them, ROOK)  == 1
+          && pos.count<ROOK>(Them) == 1
-          && pos.piece_count(Them, PAWN)  >= 1;
+          && pos.count<PAWN>(Them) >= 1;
  }
  /// imbalance() calculates the imbalance by comparing the piece count of each
  /// piece type for both colors.
  template<Color Us>
  int imbalance(const int pieceCount[][PIECE_TYPE_NB]) {
    const Color Them = (Us == WHITE ? BLACK : WHITE);
    int bonus = 0;
    // Second-degree polynomial material imbalance by Tord Romstad
    for (int pt1 = NO_PIECE_TYPE; pt1 <= QUEEN; ++pt1)
    {
        if (!pieceCount[Us][pt1])
            continue;
        int v = Linear[pt1];
        for (int pt2 = NO_PIECE_TYPE; pt2 <= pt1; ++pt2)
            v +=  QuadraticOurs[pt1][pt2] * pieceCount[Us][pt2]
                + QuadraticTheirs[pt1][pt2] * pieceCount[Them][pt2];
        bonus += pieceCount[Us][pt1] * v;
    }
    return bonus;
  }
 } // namespace
 namespace Material {
-/// MaterialInfoTable c'tor and d'tor allocate and free the space for Endgames
+/// Material::probe() looks up the current position's material configuration in
 /// the material hash table. It returns a pointer to the Entry if the position
 /// is found. Otherwise a new Entry is computed and stored there, so we don't
 /// have to recompute all when the same material configuration occurs again.
-void MaterialInfoTable::init() { Base::init(); if (!funcs) funcs = new Endgames(); }
+Entry* probe(const Position& pos) {
 MaterialInfoTable::~MaterialInfoTable() { delete funcs; }
  Key key = pos.material_key();
  Entry* e = pos.this_thread()->materialTable[key];
-/// MaterialInfoTable::get_material_info() takes a position object as input,
+  if (e->key == key)
-/// computes or looks up a MaterialInfo object, and returns a pointer to it.
+      return e;
 /// If the material configuration is not already present in the table, it
 /// is stored there, so we don't have to recompute everything when the
 /// same material configuration occurs again.
-MaterialInfo* MaterialInfoTable::get_material_info(const Position& pos) const {
+  std::memset(e, 0, sizeof(Entry));
  e->key = key;
  e->factor[WHITE] = e->factor[BLACK] = (uint8_t)SCALE_FACTOR_NORMAL;
  e->gamePhase = pos.game_phase();
-  Key key = pos.get_material_key();
+  // Let's look if we have a specialized evaluation function for this particular
-  MaterialInfo* mi = probe(key);
+  // material configuration. Firstly we look for a fixed configuration one, then
-
+  // for a generic one if the previous search failed.
-  // If mi->key matches the position's material hash key, it means that we
+  if (pos.this_thread()->endgames.probe(key, e->evaluationFunction))
-  // have analysed this material configuration before, and we can simply
+      return e;
  // return the information we found the last time instead of recomputing it.
  if (mi->key == key)
      return mi;
  // Initialize MaterialInfo entry
  memset(mi, 0, sizeof(MaterialInfo));
  mi->key = key;
  mi->factor[WHITE] = mi->factor[BLACK] = (uint8_t)SCALE_FACTOR_NORMAL;
  // Store game phase
  mi->gamePhase = MaterialInfoTable::game_phase(pos);
  // Let's look if we have a specialized evaluation function for this
  // particular material configuration. First we look for a fixed
  // configuration one, then a generic one if previous search failed.
  if ((mi->evaluationFunction = funcs->get<EndgameBase<Value> >(key)) != NULL)
      return mi;
  if (is_KXK<WHITE>(pos))
  {
-      mi->evaluationFunction = &EvaluateKXK[WHITE];
+      e->evaluationFunction = &EvaluateKXK[WHITE];
-      return mi;
+      return e;
  }
  if (is_KXK<BLACK>(pos))
  {
-      mi->evaluationFunction = &EvaluateKXK[BLACK];
+      e->evaluationFunction = &EvaluateKXK[BLACK];
-      return mi;
+      return e;
  }
-  if (!pos.pieces(PAWN) && !pos.pieces(ROOK) && !pos.pieces(QUEEN))
+  // OK, we didn't find any special evaluation function for the current material
-  {
+  // configuration. Is there a suitable specialized scaling function?
      // Minor piece endgame with at least one minor piece per side and
      // no pawns. Note that the case KmmK is already handled by KXK.
      assert((pos.pieces(KNIGHT, WHITE) | pos.pieces(BISHOP, WHITE)));
      assert((pos.pieces(KNIGHT, BLACK) | pos.pieces(BISHOP, BLACK)));
      if (   pos.piece_count(WHITE, BISHOP) + pos.piece_count(WHITE, KNIGHT) <= 2
          && pos.piece_count(BLACK, BISHOP) + pos.piece_count(BLACK, KNIGHT) <= 2)
      {
          mi->evaluationFunction = &EvaluateKmmKm[WHITE];
          return mi;
      }
  }
  // OK, we didn't find any special evaluation function for the current
  // material configuration. Is there a suitable scaling function?
  //
  // We face problems when there are several conflicting applicable
  // scaling functions and we need to decide which one to use.
  EndgameBase<ScaleFactor>* sf;
-  if ((sf = funcs->get<EndgameBase<ScaleFactor> >(key)) != NULL)
+  if (pos.this_thread()->endgames.probe(key, sf))
  {
-      mi->scalingFunction[sf->color()] = sf;
+      e->scalingFunction[sf->strong_side()] = sf; // Only strong color assigned
-      return mi;
+      return e;
  }
-  // Generic scaling functions that refer to more then one material
+  // We didn't find any specialized scaling function, so fall back on generic
-  // distribution. Should be probed after the specialized ones.
+  // ones that refer to more than one material distribution. Note that in this
-  // Note that these ones don't return after setting the function.
+  // case we don't return after setting the function.
  if (is_KBPsKs<WHITE>(pos))
-      mi->scalingFunction[WHITE] = &ScaleKBPsK[WHITE];
+      e->scalingFunction[WHITE] = &ScaleKBPsK[WHITE];
  if (is_KBPsKs<BLACK>(pos))
-      mi->scalingFunction[BLACK] = &ScaleKBPsK[BLACK];
+      e->scalingFunction[BLACK] = &ScaleKBPsK[BLACK];
  if (is_KQKRPs<WHITE>(pos))
-      mi->scalingFunction[WHITE] = &ScaleKQKRPs[WHITE];
+      e->scalingFunction[WHITE] = &ScaleKQKRPs[WHITE];
  else if (is_KQKRPs<BLACK>(pos))
-      mi->scalingFunction[BLACK] = &ScaleKQKRPs[BLACK];
+      e->scalingFunction[BLACK] = &ScaleKQKRPs[BLACK];
  Value npm_w = pos.non_pawn_material(WHITE);
  Value npm_b = pos.non_pawn_material(BLACK);
-  if (npm_w + npm_b == VALUE_ZERO)
+  if (npm_w + npm_b == VALUE_ZERO && pos.pieces(PAWN)) // Only pawns on the board
  {
-      if (pos.piece_count(BLACK, PAWN) == 0)
+      if (!pos.count<PAWN>(BLACK))
      {
-          assert(pos.piece_count(WHITE, PAWN) >= 2);
+          assert(pos.count<PAWN>(WHITE) >= 2);
-          mi->scalingFunction[WHITE] = &ScaleKPsK[WHITE];
+
          e->scalingFunction[WHITE] = &ScaleKPsK[WHITE];
      }
-      else if (pos.piece_count(WHITE, PAWN) == 0)
+      else if (!pos.count<PAWN>(WHITE))
      {
-          assert(pos.piece_count(BLACK, PAWN) >= 2);
+          assert(pos.count<PAWN>(BLACK) >= 2);
-          mi->scalingFunction[BLACK] = &ScaleKPsK[BLACK];
+
          e->scalingFunction[BLACK] = &ScaleKPsK[BLACK];
      }
-      else if (pos.piece_count(WHITE, PAWN) == 1 && pos.piece_count(BLACK, PAWN) == 1)
+      else if (pos.count<PAWN>(WHITE) == 1 && pos.count<PAWN>(BLACK) == 1)
      {
          // This is a special case because we set scaling functions
          // for both colors instead of only one.
-          mi->scalingFunction[WHITE] = &ScaleKPKP[WHITE];
+          e->scalingFunction[WHITE] = &ScaleKPKP[WHITE];
-          mi->scalingFunction[BLACK] = &ScaleKPKP[BLACK];
+          e->scalingFunction[BLACK] = &ScaleKPKP[BLACK];
      }
  }
-  // No pawns makes it difficult to win, even with a material advantage
+  // Zero or just one pawn makes it difficult to win, even with a small material
-  if (pos.piece_count(WHITE, PAWN) == 0 && npm_w - npm_b <= BishopValueMidgame)
+  // advantage. This catches some trivial draws like KK, KBK and KNK and gives a
-  {
+  // drawish scale factor for cases such as KRKBP and KmmKm (except for KBBKN).
-      mi->factor[WHITE] = uint8_t
+  if (!pos.count<PAWN>(WHITE) && npm_w - npm_b <= BishopValueMg)
-      (npm_w == npm_b || npm_w < RookValueMidgame ? 0 : NoPawnsSF[Min(pos.piece_count(WHITE, BISHOP), 2)]);
+      e->factor[WHITE] = uint8_t(npm_w <  RookValueMg   ? SCALE_FACTOR_DRAW :
-  }
+                                 npm_b <= BishopValueMg ? 4 : 12);
-  if (pos.piece_count(BLACK, PAWN) == 0 && npm_b - npm_w <= BishopValueMidgame)
+  if (!pos.count<PAWN>(BLACK) && npm_b - npm_w <= BishopValueMg)
-  {
+      e->factor[BLACK] = uint8_t(npm_b <  RookValueMg   ? SCALE_FACTOR_DRAW :
-      mi->factor[BLACK] = uint8_t
+                                 npm_w <= BishopValueMg ? 4 : 12);
      (npm_w == npm_b || npm_b < RookValueMidgame ? 0 : NoPawnsSF[Min(pos.piece_count(BLACK, BISHOP), 2)]);
  }
-  // Compute the space weight
+  if (pos.count<PAWN>(WHITE) == 1 && npm_w - npm_b <= BishopValueMg)
-  if (npm_w + npm_b >= 2 * QueenValueMidgame + 4 * RookValueMidgame + 2 * KnightValueMidgame)
+      e->factor[WHITE] = (uint8_t) SCALE_FACTOR_ONEPAWN;
  {
      int minorPieceCount =  pos.piece_count(WHITE, KNIGHT) + pos.piece_count(WHITE, BISHOP)
                           + pos.piece_count(BLACK, KNIGHT) + pos.piece_count(BLACK, BISHOP);
-      mi->spaceWeight = minorPieceCount * minorPieceCount;
+  if (pos.count<PAWN>(BLACK) == 1 && npm_b - npm_w <= BishopValueMg)
-  }
+      e->factor[BLACK] = (uint8_t) SCALE_FACTOR_ONEPAWN;
  // Evaluate the material imbalance. We use PIECE_TYPE_NONE as a place holder
-  // for the bishop pair "extended piece", this allow us to be more flexible
+  // for the bishop pair "extended piece", which allows us to be more flexible
  // in defining bishop pair bonuses.
-  const int pieceCount[2][8] = {
+  const int PieceCount[COLOR_NB][PIECE_TYPE_NB] = {
-  { pos.piece_count(WHITE, BISHOP) > 1, pos.piece_count(WHITE, PAWN), pos.piece_count(WHITE, KNIGHT),
+  { pos.count<BISHOP>(WHITE) > 1, pos.count<PAWN>(WHITE), pos.count<KNIGHT>(WHITE),
-    pos.piece_count(WHITE, BISHOP)    , pos.piece_count(WHITE, ROOK), pos.piece_count(WHITE, QUEEN) },
+    pos.count<BISHOP>(WHITE)    , pos.count<ROOK>(WHITE), pos.count<QUEEN >(WHITE) },
-  { pos.piece_count(BLACK, BISHOP) > 1, pos.piece_count(BLACK, PAWN), pos.piece_count(BLACK, KNIGHT),
+  { pos.count<BISHOP>(BLACK) > 1, pos.count<PAWN>(BLACK), pos.count<KNIGHT>(BLACK),
-    pos.piece_count(BLACK, BISHOP)    , pos.piece_count(BLACK, ROOK), pos.piece_count(BLACK, QUEEN) } };
+    pos.count<BISHOP>(BLACK)    , pos.count<ROOK>(BLACK), pos.count<QUEEN >(BLACK) } };
-  mi->value = int16_t((imbalance<WHITE>(pieceCount) - imbalance<BLACK>(pieceCount)) / 16);
+  e->value = int16_t((imbalance<WHITE>(PieceCount) - imbalance<BLACK>(PieceCount)) / 16);
-  return mi;
+  return e;
 }
-
+} // namespace Material
 /// MaterialInfoTable::imbalance() calculates imbalance comparing piece count of each
 /// piece type for both colors.
 template<Color Us>
 int MaterialInfoTable::imbalance(const int pieceCount[][8]) {
  const Color Them = (Us == WHITE ? BLACK : WHITE);
  int pt1, pt2, pc, v;
  int value = 0;
  // Redundancy of major pieces, formula based on Kaufman's paper
  // "The Evaluation of Material Imbalances in Chess"
  if (pieceCount[Us][ROOK] > 0)
      value -=  RedundantRookPenalty * (pieceCount[Us][ROOK] - 1)
              + RedundantQueenPenalty * pieceCount[Us][QUEEN];
  // Second-degree polynomial material imbalance by Tord Romstad
  for (pt1 = PIECE_TYPE_NONE; pt1 <= QUEEN; pt1++)
  {
      pc = pieceCount[Us][pt1];
      if (!pc)
          continue;
      v = LinearCoefficients[pt1];
      for (pt2 = PIECE_TYPE_NONE; pt2 <= pt1; pt2++)
          v +=  QuadraticCoefficientsSameColor[pt1][pt2] * pieceCount[Us][pt2]
              + QuadraticCoefficientsOppositeColor[pt1][pt2] * pieceCount[Them][pt2];
      value += pc * v;
  }
  return value;
 }
 /// MaterialInfoTable::game_phase() calculates the phase given the current
 /// position. Because the phase is strictly a function of the material, it
 /// is stored in MaterialInfo.
 Phase MaterialInfoTable::game_phase(const Position& pos) {
  Value npm = pos.non_pawn_material(WHITE) + pos.non_pawn_material(BLACK);
  return  npm >= MidgameLimit ? PHASE_MIDGAME
        : npm <= EndgameLimit ? PHASE_ENDGAME
        : Phase(((npm - EndgameLimit) * 128) / (MidgameLimit - EndgameLimit));
 }
@@ -1,7 +1,7 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
@@ -17,101 +17,56 @@
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
-#if !defined(MATERIAL_H_INCLUDED)
+#ifndef MATERIAL_H_INCLUDED
 #define MATERIAL_H_INCLUDED
 #include "endgame.h"
 #include "misc.h"
 #include "position.h"
 #include "tt.h"
 #include "types.h"
-const int MaterialTableSize = 8192;
+namespace Material {
-/// MaterialInfo is a class which contains various information about a
+/// Material::Entry contains various information about a material configuration.
-/// material configuration. It contains a material balance evaluation,
+/// It contains a material imbalance evaluation, a function pointer to a special
-/// a function pointer to a special endgame evaluation function (which in
+/// endgame evaluation function (which in most cases is NULL, meaning that the
-/// most cases is NULL, meaning that the standard evaluation function will
+/// standard evaluation function will be used), and scale factors.
 /// be used), and "scale factors" for black and white.
 ///
-/// The scale factors are used to scale the evaluation score up or down.
+/// The scale factors are used to scale the evaluation score up or down. For
-/// For instance, in KRB vs KR endgames, the score is scaled down by a factor
+/// instance, in KRB vs KR endgames, the score is scaled down by a factor of 4,
-/// of 4, which will result in scores of absolute value less than one pawn.
+/// which will result in scores of absolute value less than one pawn.
-class MaterialInfo {
+struct Entry {
-  friend class MaterialInfoTable;
+  Score imbalance() const { return make_score(value, value); }
  Phase game_phase() const { return gamePhase; }
  bool specialized_eval_exists() const { return evaluationFunction != NULL; }
  Value evaluate(const Position& pos) const { return (*evaluationFunction)(pos); }
-public:
+  // scale_factor takes a position and a color as input and returns a scale factor
-  Score material_value() const;
+  // for the given color. We have to provide the position in addition to the color
-  ScaleFactor scale_factor(const Position& pos, Color c) const;
+  // because the scale factor may also be a function which should be applied to
-  int space_weight() const;
+  // the position. For instance, in KBP vs K endgames, the scaling function looks
-  Phase game_phase() const;
+  // for rook pawns and wrong-colored bishops.
-  bool specialized_eval_exists() const;
+  ScaleFactor scale_factor(const Position& pos, Color c) const {
-  Value evaluate(const Position& pos) const;
+    return   !scalingFunction[c]
          || (*scalingFunction[c])(pos) == SCALE_FACTOR_NONE ? ScaleFactor(factor[c])
                                                             : (*scalingFunction[c])(pos);
  }
 private:
  Key key;
  int16_t value;
-  uint8_t factor[2];
+  uint8_t factor[COLOR_NB];
  EndgameBase<Value>* evaluationFunction;
-  EndgameBase<ScaleFactor>* scalingFunction[2];
+  EndgameBase<ScaleFactor>* scalingFunction[COLOR_NB]; // Could be one for each
-  int spaceWeight;
+                                                       // side (e.g. KPKP, KBPsKs)
  Phase gamePhase;
 };
 typedef HashTable<Entry, 8192> Table;
-/// The MaterialInfoTable class represents a pawn hash table. The most important
+Entry* probe(const Position& pos);
 /// method is get_material_info, which returns a pointer to a MaterialInfo object.
-class MaterialInfoTable : public SimpleHash<MaterialInfo, MaterialTableSize> {
+} // namespace Material
 public:
  ~MaterialInfoTable();
  void init();
  MaterialInfo* get_material_info(const Position& pos) const;
  static Phase game_phase(const Position& pos);
-private:
+#endif // #ifndef MATERIAL_H_INCLUDED
  template<Color Us>
  static int imbalance(const int pieceCount[][8]);
  Endgames* funcs;
 };
 /// MaterialInfo::scale_factor takes a position and a color as input, and
 /// returns a scale factor for the given color. We have to provide the
 /// position in addition to the color, because the scale factor need not
 /// to be a constant: It can also be a function which should be applied to
 /// the position. For instance, in KBP vs K endgames, a scaling function
 /// which checks for draws with rook pawns and wrong-colored bishops.
 inline ScaleFactor MaterialInfo::scale_factor(const Position& pos, Color c) const {
  if (!scalingFunction[c])
      return ScaleFactor(factor[c]);
  ScaleFactor sf = scalingFunction[c]->apply(pos);
  return sf == SCALE_FACTOR_NONE ? ScaleFactor(factor[c]) : sf;
 }
 inline Value MaterialInfo::evaluate(const Position& pos) const {
  return evaluationFunction->apply(pos);
 }
 inline Score MaterialInfo::material_value() const {
  return make_score(value, value);
 }
 inline int MaterialInfo::space_weight() const {
  return spaceWeight;
 }
 inline Phase MaterialInfo::game_phase() const {
  return gamePhase;
 }
 inline bool MaterialInfo::specialized_eval_exists() const {
  return evaluationFunction != NULL;
 }
 #endif // !defined(MATERIAL_H_INCLUDED)
@@ -1,7 +1,7 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
@@ -17,239 +17,174 @@
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
-#if !defined(_MSC_VER)
+#include <fstream>
 #  include <sys/time.h>
 #  include <sys/types.h>
 #  include <unistd.h>
 #  if defined(__hpux)
 #     include <sys/pstat.h>
 #  endif
 #else
 #define _CRT_SECURE_NO_DEPRECATE
 #include <windows.h>
 #include <sys/timeb.h>
 #endif
 #if !defined(NO_PREFETCH)
 #  include <xmmintrin.h>
 #endif
 #include <cassert>
 #include <cstdio>
 #include <iomanip>
 #include <iostream>
 #include <sstream>
 #include "bitcount.h"
 #include "misc.h"
 #include "thread.h"
 using namespace std;
-/// Version number. If EngineVersion is left empty, then AppTag plus
+namespace {
 /// current date (in the format YYMMDD) is used as a version number.
-static const string AppName = "Stockfish";
+/// Version number. If Version is left empty, then compile date in the format
-static const string EngineVersion = "2.1.1";
+/// DD-MM-YY and show in engine_info.
-static const string AppTag  = "";
+const string Version = "6";
 /// Debug counters
 int64_t hits[2], means[2];
-/// engine_name() returns the full name of the current Stockfish version.
+/// Our fancy logging facility. The trick here is to replace cin.rdbuf() and
-/// This will be either "Stockfish YYMMDD" (where YYMMDD is the date when
+/// cout.rdbuf() with two Tie objects that tie cin and cout to a file stream. We
-/// the program was compiled) or "Stockfish <version number>", depending
+/// can toggle the logging of std::cout and std:cin at runtime whilst preserving
-/// on whether the constant EngineVersion is empty.
+/// usual i/o functionality, all without changing a single line of code!
 /// Idea from http://groups.google.com/group/comp.lang.c++/msg/1d941c0f26ea0d81
-const string engine_name() {
+struct Tie: public streambuf { // MSVC requires splitted streambuf for cin and cout
  Tie(streambuf* b, ofstream* f) : buf(b), file(f) {}
  int sync() { return file->rdbuf()->pubsync(), buf->pubsync(); }
  int overflow(int c) { return log(buf->sputc((char)c), "<< "); }
  int underflow() { return buf->sgetc(); }
  int uflow() { return log(buf->sbumpc(), ">> "); }
  streambuf* buf;
  ofstream* file;
  int log(int c, const char* prefix) {
    static int last = '\n';
    if (last == '\n')
        file->rdbuf()->sputn(prefix, 3);
    return last = file->rdbuf()->sputc((char)c);
  }
 };
 class Logger {
  Logger() : in(cin.rdbuf(), &file), out(cout.rdbuf(), &file) {}
 ~Logger() { start(false); }
  ofstream file;
  Tie in, out;
 public:
  static void start(bool b) {
    static Logger l;
    if (b && !l.file.is_open())
    {
        l.file.open("io_log.txt", ifstream::out | ifstream::app);
        cin.rdbuf(&l.in);
        cout.rdbuf(&l.out);
    }
    else if (!b && l.file.is_open())
    {
        cout.rdbuf(l.out.buf);
        cin.rdbuf(l.in.buf);
        l.file.close();
    }
  }
 };
 } // namespace
 /// engine_info() returns the full name of the current Stockfish version. This
 /// will be either "Stockfish <Tag> DD-MM-YY" (where DD-MM-YY is the date when
 /// the program was compiled) or "Stockfish <Version>", depending on whether
 /// Version is empty.
 const string engine_info(bool to_uci) {
  const string months("Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec");
  const string cpu64(CpuIs64Bit ? " 64bit" : "");
  if (!EngineVersion.empty())
      return AppName + " " + EngineVersion + cpu64;
  stringstream s, date(__DATE__); // From compiler, format is "Sep 21 2008"
  string month, day, year;
  stringstream ss, date(__DATE__); // From compiler, format is "Sep 21 2008"
-  date >> month >> day >> year;
+  ss << "Stockfish " << Version << setfill('0');
-  s << setfill('0') << AppName + " " + AppTag + " "
+  if (Version.empty())
    << year.substr(2, 2) << setw(2)
    << (1 + months.find(month) / 4) << setw(2)
    << day << cpu64;
  return s.str();
 }
 /// Our brave developers! Required by UCI
 const string engine_authors() {
  return "Tord Romstad, Marco Costalba and Joona Kiiski";
 }
 /// Debug stuff. Helper functions used mainly for debugging purposes
 static uint64_t dbg_hit_cnt0;
 static uint64_t dbg_hit_cnt1;
 static uint64_t dbg_mean_cnt0;
 static uint64_t dbg_mean_cnt1;
 void dbg_print_hit_rate() {
  if (dbg_hit_cnt0)
      cout << "Total " << dbg_hit_cnt0 << " Hit " << dbg_hit_cnt1
           << " hit rate (%) " << 100 * dbg_hit_cnt1 / dbg_hit_cnt0 << endl;
 }
 void dbg_print_mean() {
  if (dbg_mean_cnt0)
      cout << "Total " << dbg_mean_cnt0 << " Mean "
           << (float)dbg_mean_cnt1 / dbg_mean_cnt0 << endl;
 }
 void dbg_mean_of(int v) {
  dbg_mean_cnt0++;
  dbg_mean_cnt1 += v;
 }
 void dbg_hit_on(bool b) {
  dbg_hit_cnt0++;
  if (b)
      dbg_hit_cnt1++;
 }
 void dbg_hit_on_c(bool c, bool b) { if (c) dbg_hit_on(b); }
 void dbg_before() { dbg_hit_on(false); }
 void dbg_after()  { dbg_hit_on(true); dbg_hit_cnt0--; }
 /// get_system_time() returns the current system time, measured in milliseconds
 int get_system_time() {
 #if defined(_MSC_VER)
  struct _timeb t;
  _ftime(&t);
  return int(t.time * 1000 + t.millitm);
 #else
  struct timeval t;
  gettimeofday(&t, NULL);
  return t.tv_sec * 1000 + t.tv_usec / 1000;
 #endif
 }
 /// cpu_count() tries to detect the number of CPU cores
 int cpu_count() {
 #if defined(_MSC_VER)
  SYSTEM_INFO s;
  GetSystemInfo(&s);
  return Min(s.dwNumberOfProcessors, MAX_THREADS);
 #else
 #  if defined(_SC_NPROCESSORS_ONLN)
  return Min(sysconf(_SC_NPROCESSORS_ONLN), MAX_THREADS);
 #  elif defined(__hpux)
  struct pst_dynamic psd;
  if (pstat_getdynamic(&psd, sizeof(psd), (size_t)1, 0) == -1)
      return 1;
  return Min(psd.psd_proc_cnt, MAX_THREADS);
 #  else
  return 1;
 #  endif
 #endif
 }
 /// Check for console input. Original code from Beowulf, Olithink and Greko
 #ifndef _WIN32
 int input_available() {
  fd_set readfds;
  struct timeval  timeout;
  FD_ZERO(&readfds);
  FD_SET(fileno(stdin), &readfds);
  timeout.tv_sec = 0; // Set to timeout immediately
  timeout.tv_usec = 0;
  select(16, &readfds, 0, 0, &timeout);
  return (FD_ISSET(fileno(stdin), &readfds));
 }
 #else
 int input_available() {
  static HANDLE inh = NULL;
  static bool usePipe = false;
  INPUT_RECORD rec[256];
  DWORD nchars, recCnt;
  if (!inh)
  {
-      inh = GetStdHandle(STD_INPUT_HANDLE);
+      date >> month >> day >> year;
-      if (GetConsoleMode(inh, &nchars))
+      ss << setw(2) << day << setw(2) << (1 + months.find(month) / 4) << year.substr(2);
      {
          SetConsoleMode(inh, nchars & ~(ENABLE_MOUSE_INPUT | ENABLE_WINDOW_INPUT));
          FlushConsoleInputBuffer(inh);
      } else
          usePipe = true;
  }
-  // When using Standard C input functions, also check if there
+  ss << (Is64Bit ? " 64" : "")
-  // is anything in the buffer. After a call to such functions,
+     << (HasPext ? " BMI2" : (HasPopCnt ? " POPCNT" : ""))
-  // the input waiting in the pipe will be copied to the buffer,
+     << (to_uci  ? "\nid author ": " by ")
-  // and the call to PeekNamedPipe can indicate no input available.
+     << "Tord Romstad, Marco Costalba and Joona Kiiski";
  // Setting stdin to unbuffered was not enough. [from Greko]
  if (stdin->_cnt > 0)
      return 1;
-  // When running under a GUI the input commands are sent to us
+  return ss.str();
  // directly over the internal pipe. If PeekNamedPipe() returns 0
  // then something went wrong. Probably the parent program exited.
  // Returning 1 will make the next call to the input function
  // return EOF, where this should be catched then.
  if (usePipe)
      return PeekNamedPipe(inh, NULL, 0, NULL, &nchars, NULL) ? nchars : 1;
  // Count the number of unread input records, including keyboard,
  // mouse, and window-resizing input records.
  GetNumberOfConsoleInputEvents(inh, &nchars);
  // Read data from console without removing it from the buffer
  if (nchars <= 0 || !PeekConsoleInput(inh, rec, Min(nchars, 256), &recCnt))
      return 0;
  // Search for at least one keyboard event
  for (DWORD i = 0; i < recCnt; i++)
      if (rec[i].EventType == KEY_EVENT)
          return 1;
  return 0;
 }
 /// Debug functions used mainly to collect run-time statistics
 void dbg_hit_on(bool b) { ++hits[0]; if (b) ++hits[1]; }
 void dbg_hit_on_c(bool c, bool b) { if (c) dbg_hit_on(b); }
 void dbg_mean_of(int v) { ++means[0]; means[1] += v; }
 void dbg_print() {
  if (hits[0])
      cerr << "Total " << hits[0] << " Hits " << hits[1]
           << " hit rate (%) " << 100 * hits[1] / hits[0] << endl;
  if (means[0])
      cerr << "Total " << means[0] << " Mean "
           << (double)means[1] / means[0] << endl;
 }
 /// Used to serialize access to std::cout to avoid multiple threads writing at
 /// the same time.
 std::ostream& operator<<(std::ostream& os, SyncCout sc) {
  static Mutex m;
  if (sc == IO_LOCK)
      m.lock();
  if (sc == IO_UNLOCK)
      m.unlock();
  return os;
 }
 /// Trampoline helper to avoid moving Logger to misc.h
 void start_logger(bool b) { Logger::start(b); }
 /// timed_wait() waits for msec milliseconds. It is mainly a helper to wrap
 /// the conversion from milliseconds to struct timespec, as used by pthreads.
 void timed_wait(WaitCondition& sleepCond, Lock& sleepLock, int msec) {
 #ifdef _WIN32
  int tm = msec;
 #else
  timespec ts, *tm = &ts;
  uint64_t ms = Time::now() + msec;
  ts.tv_sec = ms / 1000;
  ts.tv_nsec = (ms % 1000) * 1000000LL;
 #endif
  cond_timedwait(sleepCond, sleepLock, tm);
 }
-/// prefetch() preloads the given address in L1/L2 cache. This is a non
+
-/// blocking function and do not stalls the CPU waiting for data to be
+/// prefetch() preloads the given address in L1/L2 cache. This is a non-blocking
-/// loaded from memory, that can be quite slow.
+/// function that doesn't stall the CPU waiting for data to be loaded from memory,
-#if defined(NO_PREFETCH)
+/// which can be quite slow.
 #ifdef NO_PREFETCH
 void prefetch(char*) {}
@@ -257,14 +192,17 @@ void prefetch(char*) {}
 void prefetch(char* addr) {
-#if defined(__INTEL_COMPILER) || defined(__ICL)
+#  if defined(__INTEL_COMPILER)
-   // This hack prevents prefetches to be optimized away by
+   // This hack prevents prefetches from being optimized away by
-   // Intel compiler. Both MSVC and gcc seems not affected.
+   // Intel compiler. Both MSVC and gcc seem not be affected by this.
   __asm__ ("");
-#endif
+#  endif
-  _mm_prefetch(addr, _MM_HINT_T2);
+#  if defined(__INTEL_COMPILER) || defined(_MSC_VER)
-  _mm_prefetch(addr+64, _MM_HINT_T2); // 64 bytes ahead
+  _mm_prefetch(addr, _MM_HINT_T0);
 #  else
  __builtin_prefetch(addr);
 #  endif
 }
 #endif
@@ -1,7 +1,7 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
@@ -17,25 +17,84 @@
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
-#if !defined(MISC_H_INCLUDED)
+#ifndef MISC_H_INCLUDED
 #define MISC_H_INCLUDED
 #include <cassert>
 #include <ostream>
 #include <string>
 #include <vector>
 #include "types.h"
-extern const std::string engine_name();
+const std::string engine_info(bool to_uci = false);
-extern const std::string engine_authors();
+void timed_wait(WaitCondition&, Lock&, int);
-extern int get_system_time();
+void prefetch(char* addr);
-extern int cpu_count();
+void start_logger(bool b);
 extern int input_available();
 extern void prefetch(char* addr);
-extern void dbg_hit_on(bool b);
+void dbg_hit_on(bool b);
-extern void dbg_hit_on_c(bool c, bool b);
+void dbg_hit_on_c(bool c, bool b);
-extern void dbg_before();
+void dbg_mean_of(int v);
-extern void dbg_after();
+void dbg_print();
 extern void dbg_mean_of(int v);
 extern void dbg_print_hit_rate();
 extern void dbg_print_mean();
-#endif // !defined(MISC_H_INCLUDED)
+
 namespace Time {
  typedef int64_t point;
  inline point now() { return system_time_to_msec(); }
 }
 template<class Entry, int Size>
 struct HashTable {
  HashTable() : table(Size, Entry()) {}
  Entry* operator[](Key key) { return &table[(uint32_t)key & (Size - 1)]; }
 private:
  std::vector<Entry> table;
 };
 enum SyncCout { IO_LOCK, IO_UNLOCK };
 std::ostream& operator<<(std::ostream&, SyncCout);
 #define sync_cout std::cout << IO_LOCK
 #define sync_endl std::endl << IO_UNLOCK
 /// xorshift64star Pseudo-Random Number Generator
 /// This class is based on original code written and dedicated
 /// to the public domain by Sebastiano Vigna (2014).
 /// It has the following characteristics:
 ///
 ///  -  Outputs 64-bit numbers
 ///  -  Passes Dieharder and SmallCrush test batteries
 ///  -  Does not require warm-up, no zeroland to escape
 ///  -  Internal state is a single 64-bit integer
 ///  -  Period is 2^64 - 1
 ///  -  Speed: 1.60 ns/call (Core i7 @3.40GHz)
 ///
 /// For further analysis see
 ///   <http://vigna.di.unimi.it/ftp/papers/xorshift.pdf>
 class PRNG {
  uint64_t s;
  uint64_t rand64() {
    s ^= s >> 12, s ^= s << 25, s ^= s >> 27;
    return s * 2685821657736338717LL;
  }
 public:
  PRNG(uint64_t seed) : s(seed) { assert(seed); }
  template<typename T> T rand() { return T(rand64()); }
  /// Special generator used to fast init magic numbers.
  /// Output values only have 1/8th of their bits set on average.
  template<typename T> T sparse_rand()
  { return T(rand64() & rand64() & rand64()); }
 };
 #endif // #ifndef MISC_H_INCLUDED
@@ -1,258 +0,0 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
  the Free Software Foundation, either version 3 of the License, or
  (at your option) any later version.
  Stockfish is distributed in the hope that it will be useful,
  but WITHOUT ANY WARRANTY; without even the implied warranty of
  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  GNU General Public License for more details.
  You should have received a copy of the GNU General Public License
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
 #include <cassert>
 #include <cstring>
 #include <iomanip>
 #include <string>
 #include <sstream>
 #include "move.h"
 #include "movegen.h"
 #include "search.h"
 using std::string;
 namespace {
  const string time_string(int milliseconds);
  const string score_string(Value v);
 }
 /// move_to_uci() converts a move to a string in coordinate notation
 /// (g1f3, a7a8q, etc.). The only special case is castling moves, where we
 /// print in the e1g1 notation in normal chess mode, and in e1h1 notation in
 /// Chess960 mode.
 const string move_to_uci(Move m, bool chess960) {
  Square from = move_from(m);
  Square to = move_to(m);
  string promotion;
  if (m == MOVE_NONE)
      return "(none)";
  if (m == MOVE_NULL)
      return "0000";
  if (move_is_short_castle(m) && !chess960)
      return from == SQ_E1 ? "e1g1" : "e8g8";
  if (move_is_long_castle(m) && !chess960)
      return from == SQ_E1 ? "e1c1" : "e8c8";
  if (move_is_promotion(m))
      promotion = char(tolower(piece_type_to_char(move_promotion_piece(m))));
  return square_to_string(from) + square_to_string(to) + promotion;
 }
 /// move_from_uci() takes a position and a string representing a move in
 /// simple coordinate notation and returns an equivalent Move if any.
 /// Moves are guaranteed to be legal.
 Move move_from_uci(const Position& pos, const string& str) {
  MoveStack mlist[MAX_MOVES];
  MoveStack* last = generate<MV_LEGAL>(pos, mlist);
  for (MoveStack* cur = mlist; cur != last; cur++)
      if (str == move_to_uci(cur->move, pos.is_chess960()))
          return cur->move;
  return MOVE_NONE;
 }
 /// move_to_san() takes a position and a move as input, where it is assumed
 /// that the move is a legal move from the position. The return value is
 /// a string containing the move in short algebraic notation.
 const string move_to_san(Position& pos, Move m) {
  assert(pos.is_ok());
  assert(move_is_ok(m));
  MoveStack mlist[MAX_MOVES];
  Square from = move_from(m);
  Square to = move_to(m);
  PieceType pt = pos.type_of_piece_on(from);
  string san;
  if (m == MOVE_NONE)
      return "(none)";
  if (m == MOVE_NULL)
      return "(null)";
  if (move_is_long_castle(m))
      san = "O-O-O";
  else if (move_is_short_castle(m))
      san = "O-O";
  else
  {
      if (pt != PAWN)
      {
          san = piece_type_to_char(pt);
          // Collect all legal moves of piece type 'pt' with destination 'to'
          MoveStack* last = generate<MV_LEGAL>(pos, mlist);
          int f = 0, r = 0;
          for (MoveStack* cur = mlist; cur != last; cur++)
              if (   move_to(cur->move) == to
                  && pos.type_of_piece_on(move_from(cur->move)) == pt)
              {
                  if (square_file(move_from(cur->move)) == square_file(from))
                      f++;
                  if (square_rank(move_from(cur->move)) == square_rank(from))
                      r++;
              }
          assert(f > 0 && r > 0);
          // Disambiguation if we have more then one piece with destination 'to'
          if (f == 1 && r > 1)
              san += file_to_char(square_file(from));
          else if (f > 1 && r == 1)
              san += rank_to_char(square_rank(from));
          else if (f > 1 && r > 1)
              san += square_to_string(from);
      }
      if (pos.move_is_capture(m))
      {
          if (pt == PAWN)
              san += file_to_char(square_file(from));
          san += 'x';
      }
      san += square_to_string(to);
      if (move_is_promotion(m))
      {
          san += '=';
          san += piece_type_to_char(move_promotion_piece(m));
      }
  }
  // The move gives check? We don't use pos.move_gives_check() here
  // because we need to test for a mate after the move is done.
  StateInfo st;
  pos.do_move(m, st);
  if (pos.in_check())
      san += pos.is_mate() ? "#" : "+";
  pos.undo_move(m);
  return san;
 }
 /// pretty_pv() creates a human-readable string from a position and a PV.
 /// It is used to write search information to the log file (which is created
 /// when the UCI parameter "Use Search Log" is "true").
 const string pretty_pv(Position& pos, int depth, Value score, int time, Move pv[]) {
  const int64_t K = 1000;
  const int64_t M = 1000000;
  const int startColumn = 28;
  const size_t maxLength = 80 - startColumn;
  const string lf = string("\n") + string(startColumn, ' ');
  StateInfo state[PLY_MAX_PLUS_2], *st = state;
  Move* m = pv;
  string san;
  std::stringstream s;
  size_t length = 0;
  // First print depth, score, time and searched nodes...
  s << std::setw(2) << depth
    << std::setw(8) << score_string(score)
    << std::setw(8) << time_string(time);
  if (pos.nodes_searched() < M)
      s << std::setw(8) << pos.nodes_searched() / 1 << "  ";
  else if (pos.nodes_searched() < K * M)
      s << std::setw(7) << pos.nodes_searched() / K << "K  ";
  else
      s << std::setw(7) << pos.nodes_searched() / M << "M  ";
  // ...then print the full PV line in short algebraic notation
  while (*m != MOVE_NONE)
  {
      san = move_to_san(pos, *m);
      length += san.length() + 1;
      if (length > maxLength)
      {
          length = san.length() + 1;
          s << lf;
      }
      s << san << ' ';
      pos.do_move(*m++, *st++);
  }
  // Restore original position before to leave
  while (m != pv) pos.undo_move(*--m);
  return s.str();
 }
 namespace {
  const string time_string(int millisecs) {
    const int MSecMinute = 1000 * 60;
    const int MSecHour   = 1000 * 60 * 60;
    int hours = millisecs / MSecHour;
    int minutes =  (millisecs % MSecHour) / MSecMinute;
    int seconds = ((millisecs % MSecHour) % MSecMinute) / 1000;
    std::stringstream s;
    if (hours)
        s << hours << ':';
    s << std::setfill('0') << std::setw(2) << minutes << ':' << std::setw(2) << seconds;
    return s.str();
  }
  const string score_string(Value v) {
    std::stringstream s;
    if (v >= VALUE_MATE - 200)
        s << "#" << (VALUE_MATE - v + 1) / 2;
    else if (v <= -VALUE_MATE + 200)
        s << "-#" << (VALUE_MATE + v) / 2;
    else
        s << std::setprecision(2) << std::fixed << std::showpos << float(v) / PawnValueMidgame;
    return s.str();
  }
 }
@@ -1,195 +0,0 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
  the Free Software Foundation, either version 3 of the License, or
  (at your option) any later version.
  Stockfish is distributed in the hope that it will be useful,
  but WITHOUT ANY WARRANTY; without even the implied warranty of
  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  GNU General Public License for more details.
  You should have received a copy of the GNU General Public License
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
 #if !defined(MOVE_H_INCLUDED)
 #define MOVE_H_INCLUDED
 #include <string>
 #include "misc.h"
 #include "types.h"
 // Maximum number of allowed moves per position
 const int MAX_MOVES = 256;
 /// A move needs 16 bits to be stored
 ///
 /// bit  0- 5: destination square (from 0 to 63)
 /// bit  6-11: origin square (from 0 to 63)
 /// bit 12-13: promotion piece type - 2 (from KNIGHT-2 to QUEEN-2)
 /// bit 14-15: special move flag: promotion (1), en passant (2), castle (3)
 ///
 /// Special cases are MOVE_NONE and MOVE_NULL. We can sneak these in
 /// because in any normal move destination square is always different
 /// from origin square while MOVE_NONE and MOVE_NULL have the same
 /// origin and destination square, 0 and 1 respectively.
 enum Move {
  MOVE_NONE = 0,
  MOVE_NULL = 65
 };
 struct MoveStack {
  Move move;
  int score;
 };
 inline bool operator<(const MoveStack& f, const MoveStack& s) { return f.score < s.score; }
 // An helper insertion sort implementation, works with pointers and iterators
 template<typename T, typename K>
 inline void insertion_sort(K firstMove, K lastMove)
 {
    T value;
    K cur, p, d;
    if (firstMove != lastMove)
        for (cur = firstMove + 1; cur != lastMove; cur++)
        {
            p = d = cur;
            value = *p--;
            if (*p < value)
            {
                do *d = *p;
                while (--d != firstMove && *--p < value);
                *d = value;
            }
        }
 }
 // Our dedicated sort in range [firstMove, lastMove), first splits
 // positive scores from ramining then order seaprately the two sets.
 template<typename T>
 inline void sort_moves(T* firstMove, T* lastMove, T** lastPositive)
 {
    T tmp;
    T *p, *d;
    d = lastMove;
    p = firstMove - 1;
    d->score = -1; // right guard
    // Split positives vs non-positives
    do {
        while ((++p)->score > 0) {}
        if (p != d)
        {
            while (--d != p && d->score <= 0) {}
            tmp = *p;
            *p = *d;
            *d = tmp;
        }
    } while (p != d);
    // Sort just positive scored moves, remaining only when we get there
    insertion_sort<T, T*>(firstMove, p);
    *lastPositive = p;
 }
 // Picks up the best move in range [curMove, lastMove), one per cycle.
 // It is faster then sorting all the moves in advance when moves are few,
 // as normally are the possible captures. Note that is not a stable alghoritm.
 template<typename T>
 inline T pick_best(T* curMove, T* lastMove)
 {
    T bestMove, tmp;
    bestMove = *curMove;
    while (++curMove != lastMove)
    {
        if (bestMove < *curMove)
        {
            tmp = *curMove;
            *curMove = bestMove;
            bestMove = tmp;
        }
    }
    return bestMove;
 }
 inline Square move_from(Move m) {
  return Square((int(m) >> 6) & 0x3F);
 }
 inline Square move_to(Move m) {
  return Square(m & 0x3F);
 }
 inline bool move_is_special(Move m) {
  return m & (3 << 14);
 }
 inline bool move_is_promotion(Move m) {
  return (m & (3 << 14)) == (1 << 14);
 }
 inline int move_is_ep(Move m) {
  return (m & (3 << 14)) == (2 << 14);
 }
 inline int move_is_castle(Move m) {
  return (m & (3 << 14)) == (3 << 14);
 }
 inline bool move_is_short_castle(Move m) {
  return move_is_castle(m) && (move_to(m) > move_from(m));
 }
 inline bool move_is_long_castle(Move m) {
  return move_is_castle(m) && (move_to(m) < move_from(m));
 }
 inline PieceType move_promotion_piece(Move m) {
  return move_is_promotion(m) ? PieceType(((int(m) >> 12) & 3) + 2) : PIECE_TYPE_NONE;
 }
 inline Move make_move(Square from, Square to) {
  return Move(int(to) | (int(from) << 6));
 }
 inline Move make_promotion_move(Square from, Square to, PieceType promotion) {
  return Move(int(to) | (int(from) << 6) | ((int(promotion) - 2) << 12) | (1 << 14));
 }
 inline Move make_ep_move(Square from, Square to) {
  return Move(int(to) | (int(from) << 6) | (2 << 14));
 }
 inline Move make_castle_move(Square from, Square to) {
  return Move(int(to) | (int(from) << 6) | (3 << 14));
 }
 inline bool move_is_ok(Move m) {
  return move_from(m) != move_to(m); // Catches also MOVE_NONE
 }
 class Position;
 extern const std::string move_to_uci(Move m, bool chess960);
 extern Move move_from_uci(const Position& pos, const std::string& str);
 extern const std::string move_to_san(Position& pos, Move m);
 extern const std::string pretty_pv(Position& pos, int depth, Value score, int time, Move pv[]);
 #endif // !defined(MOVE_H_INCLUDED)
@@ -1,7 +1,7 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
@@ -19,524 +19,400 @@
 #include <cassert>
 #include "bitcount.h"
 #include "movegen.h"
-
+#include "position.h"
 // Simple macro to wrap a very common while loop, no facny, no flexibility,
 // hardcoded list name 'mlist' and from square 'from'.
 #define SERIALIZE_MOVES(b) while (b) (*mlist++).move = make_move(from, pop_1st_bit(&b))
 // Version used for pawns, where the 'from' square is given as a delta from the 'to' square
 #define SERIALIZE_MOVES_D(b, d) while (b) { to = pop_1st_bit(&b); (*mlist++).move = make_move(to + (d), to); }
 namespace {
-  enum CastlingSide {
+  template<CastlingRight Cr, bool Checks, bool Chess960>
-    KING_SIDE,
+  ExtMove* generate_castling(const Position& pos, ExtMove* moveList, Color us, const CheckInfo* ci) {
    QUEEN_SIDE
  };
-  template<CastlingSide>
+    static const bool KingSide = (Cr == WHITE_OO || Cr == BLACK_OO);
  MoveStack* generate_castle_moves(const Position&, MoveStack*, Color us);
-  template<Color, MoveType>
+    if (pos.castling_impeded(Cr) || !pos.can_castle(Cr))
-  MoveStack* generate_pawn_moves(const Position&, MoveStack*, Bitboard, Square);
+        return moveList;
-  template<PieceType Pt>
+    // After castling, the rook and king final positions are the same in Chess960
-  inline MoveStack* generate_discovered_checks(const Position& pos, MoveStack* mlist, Square from) {
+    // as they would be in standard chess.
    Square kfrom = pos.king_square(us);
    Square rfrom = pos.castling_rook_square(Cr);
    Square kto = relative_square(us, KingSide ? SQ_G1 : SQ_C1);
    Bitboard enemies = pos.pieces(~us);
-    assert(Pt != QUEEN);
+    assert(!pos.checkers());
-    Bitboard b = pos.attacks_from<Pt>(from) & pos.empty_squares();
+    const Square K = Chess960 ? kto > kfrom ? DELTA_W : DELTA_E
-    if (Pt == KING)
+                              : KingSide    ? DELTA_W : DELTA_E;
    for (Square s = kto; s != kfrom; s += K)
        if (pos.attackers_to(s) & enemies)
            return moveList;
    // Because we generate only legal castling moves we need to verify that
    // when moving the castling rook we do not discover some hidden checker.
    // For instance an enemy queen in SQ_A1 when castling rook is in SQ_B1.
    if (Chess960 && (attacks_bb<ROOK>(kto, pos.pieces() ^ rfrom) & pos.pieces(~us, ROOK, QUEEN)))
        return moveList;
    Move m = make<CASTLING>(kfrom, rfrom);
    if (Checks && !pos.gives_check(m, *ci))
        return moveList;
    (moveList++)->move = m;
    return moveList;
  }
  template<GenType Type, Square Delta>
  inline ExtMove* make_promotions(ExtMove* moveList, Square to, const CheckInfo* ci) {
    if (Type == CAPTURES || Type == EVASIONS || Type == NON_EVASIONS)
        (moveList++)->move = make<PROMOTION>(to - Delta, to, QUEEN);
    if (Type == QUIETS || Type == EVASIONS || Type == NON_EVASIONS)
    {
-        Square ksq = pos.king_square(opposite_color(pos.side_to_move()));
+        (moveList++)->move = make<PROMOTION>(to - Delta, to, ROOK);
-        b &= ~QueenPseudoAttacks[ksq];
+        (moveList++)->move = make<PROMOTION>(to - Delta, to, BISHOP);
        (moveList++)->move = make<PROMOTION>(to - Delta, to, KNIGHT);
    }
-    SERIALIZE_MOVES(b);
+
-    return mlist;
+    // Knight promotion is the only promotion that can give a direct check
    // that's not already included in the queen promotion.
    if (Type == QUIET_CHECKS && (StepAttacksBB[W_KNIGHT][to] & ci->ksq))
        (moveList++)->move = make<PROMOTION>(to - Delta, to, KNIGHT);
    else
        (void)ci; // Silence a warning under MSVC
    return moveList;
  }
  template<PieceType Pt>
  inline MoveStack* generate_direct_checks(const Position& pos, MoveStack* mlist, Color us,
                                           Bitboard dc, Square ksq) {
    assert(Pt != KING);
-    Bitboard checkSqs, b;
+  template<Color Us, GenType Type>
-    Square from;
+  ExtMove* generate_pawn_moves(const Position& pos, ExtMove* moveList,
-    const Square* ptr = pos.piece_list_begin(us, Pt);
+                               Bitboard target, const CheckInfo* ci) {
-    if ((from = *ptr++) == SQ_NONE)
+    // Compute our parametrized parameters at compile time, named according to
-        return mlist;
+    // the point of view of white side.
    const Color    Them     = (Us == WHITE ? BLACK    : WHITE);
    const Bitboard TRank8BB = (Us == WHITE ? Rank8BB  : Rank1BB);
    const Bitboard TRank7BB = (Us == WHITE ? Rank7BB  : Rank2BB);
    const Bitboard TRank3BB = (Us == WHITE ? Rank3BB  : Rank6BB);
    const Square   Up       = (Us == WHITE ? DELTA_N  : DELTA_S);
    const Square   Right    = (Us == WHITE ? DELTA_NE : DELTA_SW);
    const Square   Left     = (Us == WHITE ? DELTA_NW : DELTA_SE);
-    checkSqs = pos.attacks_from<Pt>(ksq) & pos.empty_squares();
+    Bitboard emptySquares;
-    do
+    Bitboard pawnsOn7    = pos.pieces(Us, PAWN) &  TRank7BB;
    Bitboard pawnsNotOn7 = pos.pieces(Us, PAWN) & ~TRank7BB;
    Bitboard enemies = (Type == EVASIONS ? pos.pieces(Them) & target:
                        Type == CAPTURES ? target : pos.pieces(Them));
    // Single and double pawn pushes, no promotions
    if (Type != CAPTURES)
    {
-        if (   (Pt == QUEEN  && !(QueenPseudoAttacks[from]  & checkSqs))
+        emptySquares = (Type == QUIETS || Type == QUIET_CHECKS ? target : ~pos.pieces());
            || (Pt == ROOK   && !(RookPseudoAttacks[from]   & checkSqs))
            || (Pt == BISHOP && !(BishopPseudoAttacks[from] & checkSqs)))
            continue;
-        if (dc && bit_is_set(dc, from))
+        Bitboard b1 = shift_bb<Up>(pawnsNotOn7)   & emptySquares;
-            continue;
+        Bitboard b2 = shift_bb<Up>(b1 & TRank3BB) & emptySquares;
-        b = pos.attacks_from<Pt>(from) & checkSqs;
+        if (Type == EVASIONS) // Consider only blocking squares
        SERIALIZE_MOVES(b);
    } while ((from = *ptr++) != SQ_NONE);
    return mlist;
  }
  template<>
  FORCE_INLINE MoveStack* generate_direct_checks<PAWN>(const Position& p, MoveStack* m, Color us, Bitboard dc, Square ksq) {
    return (us == WHITE ? generate_pawn_moves<WHITE, MV_CHECK>(p, m, dc, ksq)
                        : generate_pawn_moves<BLACK, MV_CHECK>(p, m, dc, ksq));
  }
  template<PieceType Pt, MoveType Type>
  FORCE_INLINE MoveStack* generate_piece_moves(const Position& p, MoveStack* m, Color us, Bitboard t) {
    assert(Pt == PAWN);
    assert(Type == MV_CAPTURE || Type == MV_NON_CAPTURE || Type == MV_EVASION);
    return (us == WHITE ? generate_pawn_moves<WHITE, Type>(p, m, t, SQ_NONE)
                        : generate_pawn_moves<BLACK, Type>(p, m, t, SQ_NONE));
  }
  template<PieceType Pt>
  FORCE_INLINE MoveStack* generate_piece_moves(const Position& pos, MoveStack* mlist, Color us, Bitboard target) {
    Bitboard b;
    Square from;
    const Square* ptr = pos.piece_list_begin(us, Pt);
    if (*ptr != SQ_NONE)
    {
        do {
            from = *ptr;
            b = pos.attacks_from<Pt>(from) & target;
            SERIALIZE_MOVES(b);
        } while (*++ptr != SQ_NONE);
    }
    return mlist;
  }
  template<>
  FORCE_INLINE MoveStack* generate_piece_moves<KING>(const Position& pos, MoveStack* mlist, Color us, Bitboard target) {
    Bitboard b;
    Square from = pos.king_square(us);
    b = pos.attacks_from<KING>(from) & target;
    SERIALIZE_MOVES(b);
    return mlist;
  }
 }
 /// generate<MV_CAPTURE> generates all pseudo-legal captures and queen
 /// promotions. Returns a pointer to the end of the move list.
 ///
 /// generate<MV_NON_CAPTURE> generates all pseudo-legal non-captures and
 /// underpromotions. Returns a pointer to the end of the move list.
 ///
 /// generate<MV_NON_EVASION> generates all pseudo-legal captures and
 /// non-captures. Returns a pointer to the end of the move list.
 template<MoveType Type>
 MoveStack* generate(const Position& pos, MoveStack* mlist) {
  assert(pos.is_ok());
  assert(!pos.in_check());
  Color us = pos.side_to_move();
  Bitboard target;
  if (Type == MV_CAPTURE || Type == MV_NON_EVASION)
      target = pos.pieces_of_color(opposite_color(us));
  else if (Type == MV_NON_CAPTURE)
      target = pos.empty_squares();
  else
      assert(false);
  if (Type == MV_NON_EVASION)
  {
      mlist = generate_piece_moves<PAWN, MV_CAPTURE>(pos, mlist, us, target);
      mlist = generate_piece_moves<PAWN, MV_NON_CAPTURE>(pos, mlist, us, pos.empty_squares());
      target |= pos.empty_squares();
  }
  else
      mlist = generate_piece_moves<PAWN, Type>(pos, mlist, us, target);
  mlist = generate_piece_moves<KNIGHT>(pos, mlist, us, target);
  mlist = generate_piece_moves<BISHOP>(pos, mlist, us, target);
  mlist = generate_piece_moves<ROOK>(pos, mlist, us, target);
  mlist = generate_piece_moves<QUEEN>(pos, mlist, us, target);
  mlist = generate_piece_moves<KING>(pos, mlist, us, target);
  if (Type != MV_CAPTURE)
  {
      if (pos.can_castle_kingside(us))
          mlist = generate_castle_moves<KING_SIDE>(pos, mlist, us);
      if (pos.can_castle_queenside(us))
          mlist = generate_castle_moves<QUEEN_SIDE>(pos, mlist, us);
  }
  return mlist;
 }
 // Explicit template instantiations
 template MoveStack* generate<MV_CAPTURE>(const Position& pos, MoveStack* mlist);
 template MoveStack* generate<MV_NON_CAPTURE>(const Position& pos, MoveStack* mlist);
 template MoveStack* generate<MV_NON_EVASION>(const Position& pos, MoveStack* mlist);
 /// generate_non_capture_checks() generates all pseudo-legal non-captures and knight
 /// underpromotions that give check. Returns a pointer to the end of the move list.
 template<>
 MoveStack* generate<MV_NON_CAPTURE_CHECK>(const Position& pos, MoveStack* mlist) {
  assert(pos.is_ok());
  assert(!pos.in_check());
  Bitboard b, dc;
  Square from;
  Color us = pos.side_to_move();
  Square ksq = pos.king_square(opposite_color(us));
  assert(pos.piece_on(ksq) == make_piece(opposite_color(us), KING));
  // Discovered non-capture checks
  b = dc = pos.discovered_check_candidates(us);
  while (b)
  {
     from = pop_1st_bit(&b);
     switch (pos.type_of_piece_on(from))
     {
      case PAWN:   /* Will be generated togheter with pawns direct checks */     break;
      case KNIGHT: mlist = generate_discovered_checks<KNIGHT>(pos, mlist, from); break;
      case BISHOP: mlist = generate_discovered_checks<BISHOP>(pos, mlist, from); break;
      case ROOK:   mlist = generate_discovered_checks<ROOK>(pos, mlist, from);   break;
      case KING:   mlist = generate_discovered_checks<KING>(pos, mlist, from);   break;
      default: assert(false); break;
     }
  }
  // Direct non-capture checks
  mlist = generate_direct_checks<PAWN>(pos, mlist, us, dc, ksq);
  mlist = generate_direct_checks<KNIGHT>(pos, mlist, us, dc, ksq);
  mlist = generate_direct_checks<BISHOP>(pos, mlist, us, dc, ksq);
  mlist = generate_direct_checks<ROOK>(pos, mlist, us, dc, ksq);
  return  generate_direct_checks<QUEEN>(pos, mlist, us, dc, ksq);
 }
 /// generate_evasions() generates all pseudo-legal check evasions when
 /// the side to move is in check. Returns a pointer to the end of the move list.
 template<>
 MoveStack* generate<MV_EVASION>(const Position& pos, MoveStack* mlist) {
  assert(pos.is_ok());
  assert(pos.in_check());
  Bitboard b, target;
  Square from, checksq;
  int checkersCnt = 0;
  Color us = pos.side_to_move();
  Square ksq = pos.king_square(us);
  Bitboard checkers = pos.checkers();
  Bitboard sliderAttacks = EmptyBoardBB;
  assert(pos.piece_on(ksq) == make_piece(us, KING));
  assert(checkers);
  // Find squares attacked by slider checkers, we will remove
  // them from the king evasions set so to early skip known
  // illegal moves and avoid an useless legality check later.
  b = checkers;
  do
  {
      checkersCnt++;
      checksq = pop_1st_bit(&b);
      assert(pos.color_of_piece_on(checksq) == opposite_color(us));
      switch (pos.type_of_piece_on(checksq))
      {
      case BISHOP: sliderAttacks |= BishopPseudoAttacks[checksq]; break;
      case ROOK:   sliderAttacks |= RookPseudoAttacks[checksq];   break;
      case QUEEN:
          // In case of a queen remove also squares attacked in the other direction to
          // avoid possible illegal moves when queen and king are on adjacent squares.
          if (RookPseudoAttacks[checksq] & (1ULL << ksq))
              sliderAttacks |= RookPseudoAttacks[checksq] | pos.attacks_from<BISHOP>(checksq);
          else
              sliderAttacks |= BishopPseudoAttacks[checksq] | pos.attacks_from<ROOK>(checksq);
      default:
          break;
      }
  } while (b);
  // Generate evasions for king, capture and non capture moves
  b = pos.attacks_from<KING>(ksq) & ~pos.pieces_of_color(us) & ~sliderAttacks;
  from = ksq;
  SERIALIZE_MOVES(b);
  // Generate evasions for other pieces only if not double check
  if (checkersCnt > 1)
      return mlist;
  // Find squares where a blocking evasion or a capture of the
  // checker piece is possible.
  target = squares_between(checksq, ksq) | checkers;
  mlist = generate_piece_moves<PAWN, MV_EVASION>(pos, mlist, us, target);
  mlist = generate_piece_moves<KNIGHT>(pos, mlist, us, target);
  mlist = generate_piece_moves<BISHOP>(pos, mlist, us, target);
  mlist = generate_piece_moves<ROOK>(pos, mlist, us, target);
  return  generate_piece_moves<QUEEN>(pos, mlist, us, target);
 }
 /// generate<MV_LEGAL / MV_PSEUDO_LEGAL> computes a complete list of legal
 /// or pseudo-legal moves in the current position.
 template<>
 MoveStack* generate<MV_PSEUDO_LEGAL>(const Position& pos, MoveStack* mlist) {
  assert(pos.is_ok());
  return pos.in_check() ? generate<MV_EVASION>(pos, mlist)
                        : generate<MV_NON_EVASION>(pos, mlist);
 }
 template<>
 MoveStack* generate<MV_LEGAL>(const Position& pos, MoveStack* mlist) {
  assert(pos.is_ok());
  MoveStack *last, *cur = mlist;
  Bitboard pinned = pos.pinned_pieces(pos.side_to_move());
  last = generate<MV_PSEUDO_LEGAL>(pos, mlist);
  // Remove illegal moves from the list
  while (cur != last)
      if (!pos.pl_move_is_legal(cur->move, pinned))
          cur->move = (--last)->move;
      else
          cur++;
  return last;
 }
 namespace {
  template<Square Delta>
  inline Bitboard move_pawns(Bitboard p) {
    return Delta == DELTA_N  ? p << 8 : Delta == DELTA_S  ? p >> 8 :
           Delta == DELTA_NE ? p << 9 : Delta == DELTA_SE ? p >> 7 :
           Delta == DELTA_NW ? p << 7 : Delta == DELTA_SW ? p >> 9 : p;
  }
  template<MoveType Type, Square Delta>
  inline MoveStack* generate_pawn_captures(MoveStack* mlist, Bitboard pawns, Bitboard target) {
    const Bitboard TFileABB = (Delta == DELTA_NE || Delta == DELTA_SE ? FileABB : FileHBB);
    Bitboard b;
    Square to;
    // Captures in the a1-h8 (a8-h1 for black) diagonal or in the h1-a8 (h8-a1 for black)
    b = move_pawns<Delta>(pawns) & target & ~TFileABB;
    SERIALIZE_MOVES_D(b, -Delta);
    return mlist;
  }
  template<Color Us, MoveType Type, Square Delta>
  inline MoveStack* generate_promotions(const Position& pos, MoveStack* mlist, Bitboard pawnsOn7, Bitboard target) {
    const Bitboard TFileABB = (Delta == DELTA_NE || Delta == DELTA_SE ? FileABB : FileHBB);
    Bitboard b;
    Square to;
    // Promotions and under-promotions, both captures and non-captures
    b = move_pawns<Delta>(pawnsOn7) & target;
    if (Delta != DELTA_N && Delta != DELTA_S)
        b &= ~TFileABB;
    while (b)
    {
        to = pop_1st_bit(&b);
        if (Type == MV_CAPTURE || Type == MV_EVASION)
            (*mlist++).move = make_promotion_move(to - Delta, to, QUEEN);
        if (Type == MV_NON_CAPTURE || Type == MV_EVASION)
        {
-            (*mlist++).move = make_promotion_move(to - Delta, to, ROOK);
+            b1 &= target;
-            (*mlist++).move = make_promotion_move(to - Delta, to, BISHOP);
+            b2 &= target;
            (*mlist++).move = make_promotion_move(to - Delta, to, KNIGHT);
        }
-        // This is the only possible under promotion that can give a check
+        if (Type == QUIET_CHECKS)
        // not already included in the queen-promotion.
        if (   Type == MV_CHECK
            && bit_is_set(pos.attacks_from<KNIGHT>(to), pos.king_square(opposite_color(Us))))
            (*mlist++).move = make_promotion_move(to - Delta, to, KNIGHT);
        else (void)pos; // Silence a warning under MSVC
    }
    return mlist;
  }
  template<Color Us, MoveType Type>
  MoveStack* generate_pawn_moves(const Position& pos, MoveStack* mlist, Bitboard target, Square ksq) {
    // Calculate our parametrized parameters at compile time, named
    // according to the point of view of white side.
    const Color    Them      = (Us == WHITE ? BLACK    : WHITE);
    const Bitboard TRank7BB  = (Us == WHITE ? Rank7BB  : Rank2BB);
    const Bitboard TRank3BB  = (Us == WHITE ? Rank3BB  : Rank6BB);
    const Square   TDELTA_N  = (Us == WHITE ? DELTA_N  : DELTA_S);
    const Square   TDELTA_NE = (Us == WHITE ? DELTA_NE : DELTA_SE);
    const Square   TDELTA_NW = (Us == WHITE ? DELTA_NW : DELTA_SW);
    Square to;
    Bitboard b1, b2, dc1, dc2, pawnPushes, emptySquares;
    Bitboard pawns = pos.pieces(PAWN, Us);
    Bitboard pawnsOn7 = pawns & TRank7BB;
    Bitboard enemyPieces = (Type == MV_CAPTURE ? target : pos.pieces_of_color(Them));
    // Pre-calculate pawn pushes before changing emptySquares definition
    if (Type != MV_CAPTURE)
    {
        emptySquares = (Type == MV_NON_CAPTURE ? target : pos.empty_squares());
        pawnPushes = move_pawns<TDELTA_N>(pawns & ~TRank7BB) & emptySquares;
    }
    if (Type == MV_EVASION)
    {
        emptySquares &= target; // Only blocking squares
        enemyPieces  &= target; // Capture only the checker piece
    }
    // Promotions and underpromotions
    if (pawnsOn7)
    {
        if (Type == MV_CAPTURE)
            emptySquares = pos.empty_squares();
        pawns &= ~TRank7BB;
        mlist = generate_promotions<Us, Type, TDELTA_NE>(pos, mlist, pawnsOn7, enemyPieces);
        mlist = generate_promotions<Us, Type, TDELTA_NW>(pos, mlist, pawnsOn7, enemyPieces);
        mlist = generate_promotions<Us, Type, TDELTA_N >(pos, mlist, pawnsOn7, emptySquares);
    }
    // Standard captures
    if (Type == MV_CAPTURE || Type == MV_EVASION)
    {
        mlist = generate_pawn_captures<Type, TDELTA_NE>(mlist, pawns, enemyPieces);
        mlist = generate_pawn_captures<Type, TDELTA_NW>(mlist, pawns, enemyPieces);
    }
    // Single and double pawn pushes
    if (Type != MV_CAPTURE)
    {
        b1 = pawnPushes & emptySquares;
        b2 = move_pawns<TDELTA_N>(pawnPushes & TRank3BB) & emptySquares;
        if (Type == MV_CHECK)
        {
-            // Consider only pawn moves which give direct checks
+            b1 &= pos.attacks_from<PAWN>(ci->ksq, Them);
-            b1 &= pos.attacks_from<PAWN>(ksq, Them);
+            b2 &= pos.attacks_from<PAWN>(ci->ksq, Them);
            b2 &= pos.attacks_from<PAWN>(ksq, Them);
-            // Add pawn moves which gives discovered check. This is possible only
+            // Add pawn pushes which give discovered check. This is possible only
            // if the pawn is not on the same file as the enemy king, because we
-            // don't generate captures.
+            // don't generate captures. Note that a possible discovery check
-            if (pawns & target) // For CHECK type target is dc bitboard
+            // promotion has been already generated amongst the captures.
            if (pawnsNotOn7 & ci->dcCandidates)
            {
-                dc1 = move_pawns<TDELTA_N>(pawns & target & ~file_bb(ksq)) & emptySquares;
+                Bitboard dc1 = shift_bb<Up>(pawnsNotOn7 & ci->dcCandidates) & emptySquares & ~file_bb(ci->ksq);
-                dc2 = move_pawns<TDELTA_N>(dc1 & TRank3BB) & emptySquares;
+                Bitboard dc2 = shift_bb<Up>(dc1 & TRank3BB) & emptySquares;
                b1 |= dc1;
                b2 |= dc2;
            }
        }
        SERIALIZE_MOVES_D(b1, -TDELTA_N);
        SERIALIZE_MOVES_D(b2, -TDELTA_N -TDELTA_N);
    }
    // En passant captures
    if ((Type == MV_CAPTURE || Type == MV_EVASION) && pos.ep_square() != SQ_NONE)
    {
        assert(Us != WHITE || square_rank(pos.ep_square()) == RANK_6);
        assert(Us != BLACK || square_rank(pos.ep_square()) == RANK_3);
        // An en passant capture can be an evasion only if the checking piece
        // is the double pushed pawn and so is in the target. Otherwise this
        // is a discovery check and we are forced to do otherwise.
        if (Type == MV_EVASION && !bit_is_set(target, pos.ep_square() - TDELTA_N))
            return mlist;
        b1 = pawns & pos.attacks_from<PAWN>(pos.ep_square(), Them);
        assert(b1 != EmptyBoardBB);
        while (b1)
        {
-            to = pop_1st_bit(&b1);
+            Square to = pop_lsb(&b1);
-            (*mlist++).move = make_ep_move(to, pos.ep_square());
+            (moveList++)->move = make_move(to - Up, to);
        }
        while (b2)
        {
            Square to = pop_lsb(&b2);
            (moveList++)->move = make_move(to - Up - Up, to);
        }
    }
-    return mlist;
+
    // Promotions and underpromotions
    if (pawnsOn7 && (Type != EVASIONS || (target & TRank8BB)))
    {
        if (Type == CAPTURES)
            emptySquares = ~pos.pieces();
        if (Type == EVASIONS)
            emptySquares &= target;
        Bitboard b1 = shift_bb<Right>(pawnsOn7) & enemies;
        Bitboard b2 = shift_bb<Left >(pawnsOn7) & enemies;
        Bitboard b3 = shift_bb<Up   >(pawnsOn7) & emptySquares;
        while (b1)
            moveList = make_promotions<Type, Right>(moveList, pop_lsb(&b1), ci);
        while (b2)
            moveList = make_promotions<Type, Left >(moveList, pop_lsb(&b2), ci);
        while (b3)
            moveList = make_promotions<Type, Up   >(moveList, pop_lsb(&b3), ci);
    }
    // Standard and en-passant captures
    if (Type == CAPTURES || Type == EVASIONS || Type == NON_EVASIONS)
    {
        Bitboard b1 = shift_bb<Right>(pawnsNotOn7) & enemies;
        Bitboard b2 = shift_bb<Left >(pawnsNotOn7) & enemies;
        while (b1)
        {
            Square to = pop_lsb(&b1);
            (moveList++)->move = make_move(to - Right, to);
        }
        while (b2)
        {
            Square to = pop_lsb(&b2);
            (moveList++)->move = make_move(to - Left, to);
        }
        if (pos.ep_square() != SQ_NONE)
        {
            assert(rank_of(pos.ep_square()) == relative_rank(Us, RANK_6));
            // An en passant capture can be an evasion only if the checking piece
            // is the double pushed pawn and so is in the target. Otherwise this
            // is a discovery check and we are forced to do otherwise.
            if (Type == EVASIONS && !(target & (pos.ep_square() - Up)))
                return moveList;
            b1 = pawnsNotOn7 & pos.attacks_from<PAWN>(pos.ep_square(), Them);
            assert(b1);
            while (b1)
                (moveList++)->move = make<ENPASSANT>(pop_lsb(&b1), pos.ep_square());
        }
    }
    return moveList;
  }
  template<CastlingSide Side>
  MoveStack* generate_castle_moves(const Position& pos, MoveStack* mlist, Color us) {
-    Color them = opposite_color(us);
+  template<PieceType Pt, bool Checks> FORCE_INLINE
-    Square ksq = pos.king_square(us);
+  ExtMove* generate_moves(const Position& pos, ExtMove* moveList, Color us,
                          Bitboard target, const CheckInfo* ci) {
-    assert(pos.piece_on(ksq) == make_piece(us, KING));
+    assert(Pt != KING && Pt != PAWN);
-    Square rsq = (Side == KING_SIDE ? pos.initial_kr_square(us) : pos.initial_qr_square(us));
+    const Square* pl = pos.list<Pt>(us);
    Square s1 = relative_square(us, Side == KING_SIDE ? SQ_G1 : SQ_C1);
    Square s2 = relative_square(us, Side == KING_SIDE ? SQ_F1 : SQ_D1);
    Square s;
    bool illegal = false;
-    assert(pos.piece_on(rsq) == make_piece(us, ROOK));
+    for (Square from = *pl; from != SQ_NONE; from = *++pl)
    {
        if (Checks)
        {
            if (    (Pt == BISHOP || Pt == ROOK || Pt == QUEEN)
                && !(PseudoAttacks[Pt][from] & target & ci->checkSq[Pt]))
                continue;
-    // It is a bit complicated to correctly handle Chess960
+            if (ci->dcCandidates && (ci->dcCandidates & from))
-    for (s = Min(ksq, s1); s <= Max(ksq, s1); s++)
+                continue;
-        if (  (s != ksq && s != rsq && pos.square_is_occupied(s))
+        }
            ||(pos.attackers_to(s) & pos.pieces_of_color(them)))
            illegal = true;
-    for (s = Min(rsq, s2); s <= Max(rsq, s2); s++)
+        Bitboard b = pos.attacks_from<Pt>(from) & target;
        if (s != ksq && s != rsq && pos.square_is_occupied(s))
            illegal = true;
-    if (   Side == QUEEN_SIDE
+        if (Checks)
-        && square_file(rsq) == FILE_B
+            b &= ci->checkSq[Pt];
        && (   pos.piece_on(relative_square(us, SQ_A1)) == make_piece(them, ROOK)
            || pos.piece_on(relative_square(us, SQ_A1)) == make_piece(them, QUEEN)))
        illegal = true;
-    if (!illegal)
+        while (b)
-        (*mlist++).move = make_castle_move(ksq, rsq);
+            (moveList++)->move = make_move(from, pop_lsb(&b));
    }
-    return mlist;
+    return moveList;
  }
  template<Color Us, GenType Type> FORCE_INLINE
  ExtMove* generate_all(const Position& pos, ExtMove* moveList, Bitboard target,
                        const CheckInfo* ci = NULL) {
    const bool Checks = Type == QUIET_CHECKS;
    moveList = generate_pawn_moves<Us, Type>(pos, moveList, target, ci);
    moveList = generate_moves<KNIGHT, Checks>(pos, moveList, Us, target, ci);
    moveList = generate_moves<BISHOP, Checks>(pos, moveList, Us, target, ci);
    moveList = generate_moves<  ROOK, Checks>(pos, moveList, Us, target, ci);
    moveList = generate_moves< QUEEN, Checks>(pos, moveList, Us, target, ci);
    if (Type != QUIET_CHECKS && Type != EVASIONS)
    {
        Square ksq = pos.king_square(Us);
        Bitboard b = pos.attacks_from<KING>(ksq) & target;
        while (b)
            (moveList++)->move = make_move(ksq, pop_lsb(&b));
    }
    if (Type != CAPTURES && Type != EVASIONS && pos.can_castle(Us))
    {
        if (pos.is_chess960())
        {
            moveList = generate_castling<MakeCastling<Us,  KING_SIDE>::right, Checks, true>(pos, moveList, Us, ci);
            moveList = generate_castling<MakeCastling<Us, QUEEN_SIDE>::right, Checks, true>(pos, moveList, Us, ci);
        }
        else
        {
            moveList = generate_castling<MakeCastling<Us,  KING_SIDE>::right, Checks, false>(pos, moveList, Us, ci);
            moveList = generate_castling<MakeCastling<Us, QUEEN_SIDE>::right, Checks, false>(pos, moveList, Us, ci);
        }
    }
    return moveList;
  }
 } // namespace
 /// generate<CAPTURES> generates all pseudo-legal captures and queen
 /// promotions. Returns a pointer to the end of the move list.
 ///
 /// generate<QUIETS> generates all pseudo-legal non-captures and
 /// underpromotions. Returns a pointer to the end of the move list.
 ///
 /// generate<NON_EVASIONS> generates all pseudo-legal captures and
 /// non-captures. Returns a pointer to the end of the move list.
 template<GenType Type>
 ExtMove* generate(const Position& pos, ExtMove* moveList) {
  assert(Type == CAPTURES || Type == QUIETS || Type == NON_EVASIONS);
  assert(!pos.checkers());
  Color us = pos.side_to_move();
  Bitboard target =  Type == CAPTURES     ?  pos.pieces(~us)
                   : Type == QUIETS       ? ~pos.pieces()
                   : Type == NON_EVASIONS ? ~pos.pieces(us) : 0;
  return us == WHITE ? generate_all<WHITE, Type>(pos, moveList, target)
                     : generate_all<BLACK, Type>(pos, moveList, target);
 }
 // Explicit template instantiations
 template ExtMove* generate<CAPTURES>(const Position&, ExtMove*);
 template ExtMove* generate<QUIETS>(const Position&, ExtMove*);
 template ExtMove* generate<NON_EVASIONS>(const Position&, ExtMove*);
 /// generate<QUIET_CHECKS> generates all pseudo-legal non-captures and knight
 /// underpromotions that give check. Returns a pointer to the end of the move list.
 template<>
 ExtMove* generate<QUIET_CHECKS>(const Position& pos, ExtMove* moveList) {
  assert(!pos.checkers());
  Color us = pos.side_to_move();
  CheckInfo ci(pos);
  Bitboard dc = ci.dcCandidates;
  while (dc)
  {
     Square from = pop_lsb(&dc);
     PieceType pt = type_of(pos.piece_on(from));
     if (pt == PAWN)
         continue; // Will be generated together with direct checks
     Bitboard b = pos.attacks_from(Piece(pt), from) & ~pos.pieces();
     if (pt == KING)
         b &= ~PseudoAttacks[QUEEN][ci.ksq];
     while (b)
         (moveList++)->move = make_move(from, pop_lsb(&b));
  }
  return us == WHITE ? generate_all<WHITE, QUIET_CHECKS>(pos, moveList, ~pos.pieces(), &ci)
                     : generate_all<BLACK, QUIET_CHECKS>(pos, moveList, ~pos.pieces(), &ci);
 }
 /// generate<EVASIONS> generates all pseudo-legal check evasions when the side
 /// to move is in check. Returns a pointer to the end of the move list.
 template<>
 ExtMove* generate<EVASIONS>(const Position& pos, ExtMove* moveList) {
  assert(pos.checkers());
  Color us = pos.side_to_move();
  Square ksq = pos.king_square(us);
  Bitboard sliderAttacks = 0;
  Bitboard sliders = pos.checkers() & ~pos.pieces(KNIGHT, PAWN);
  // Find all the squares attacked by slider checkers. We will remove them from
  // the king evasions in order to skip known illegal moves, which avoids any
  // useless legality checks later on.
  while (sliders)
  {
      Square checksq = pop_lsb(&sliders);
      sliderAttacks |= LineBB[checksq][ksq] ^ checksq;
  }
  // Generate evasions for king, capture and non capture moves
  Bitboard b = pos.attacks_from<KING>(ksq) & ~pos.pieces(us) & ~sliderAttacks;
  while (b)
      (moveList++)->move = make_move(ksq, pop_lsb(&b));
  if (more_than_one(pos.checkers()))
      return moveList; // Double check, only a king move can save the day
  // Generate blocking evasions or captures of the checking piece
  Square checksq = lsb(pos.checkers());
  Bitboard target = between_bb(checksq, ksq) | checksq;
  return us == WHITE ? generate_all<WHITE, EVASIONS>(pos, moveList, target)
                     : generate_all<BLACK, EVASIONS>(pos, moveList, target);
 }
 /// generate<LEGAL> generates all the legal moves in the given position
 template<>
 ExtMove* generate<LEGAL>(const Position& pos, ExtMove* moveList) {
  Bitboard pinned = pos.pinned_pieces(pos.side_to_move());
  Square ksq = pos.king_square(pos.side_to_move());
  ExtMove* cur = moveList;
  moveList = pos.checkers() ? generate<EVASIONS    >(pos, moveList)
                            : generate<NON_EVASIONS>(pos, moveList);
  while (cur != moveList)
      if (   (pinned || from_sq(cur->move) == ksq || type_of(cur->move) == ENPASSANT)
          && !pos.legal(cur->move, pinned))
          cur->move = (--moveList)->move;
      else
          ++cur;
  return moveList;
 }
@@ -1,7 +1,7 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
@@ -17,24 +17,51 @@
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
-#if !defined(MOVEGEN_H_INCLUDED)
+#ifndef MOVEGEN_H_INCLUDED
 #define MOVEGEN_H_INCLUDED
-#include "move.h"
+#include "types.h"
 #include "position.h"
-enum MoveType {
+class Position;
-  MV_CAPTURE,
+
-  MV_NON_CAPTURE,
+enum GenType {
-  MV_CHECK,
+  CAPTURES,
-  MV_NON_CAPTURE_CHECK,
+  QUIETS,
-  MV_EVASION,
+  QUIET_CHECKS,
-  MV_NON_EVASION,
+  EVASIONS,
-  MV_LEGAL,
+  NON_EVASIONS,
-  MV_PSEUDO_LEGAL
+  LEGAL
 };
-template<MoveType>
+struct ExtMove {
-MoveStack* generate(const Position& pos, MoveStack* mlist);
+  Move move;
  Value value;
 };
-#endif // !defined(MOVEGEN_H_INCLUDED)
+inline bool operator<(const ExtMove& f, const ExtMove& s) {
  return f.value < s.value;
 }
 template<GenType>
 ExtMove* generate(const Position& pos, ExtMove* moveList);
 /// The MoveList struct is a simple wrapper around generate(). It sometimes comes
 /// in handy to use this class instead of the low level generate() function.
 template<GenType T>
 struct MoveList {
  explicit MoveList(const Position& pos) : cur(moveList), last(generate<T>(pos, moveList)) { last->move = MOVE_NONE; }
  void operator++() { ++cur; }
  Move operator*() const { return cur->move; }
  size_t size() const { return last - moveList; }
  bool contains(Move m) const {
    for (const ExtMove* it(moveList); it != last; ++it) if (it->move == m) return true;
    return false;
  }
 private:
  ExtMove moveList[MAX_MOVES];
  ExtMove *cur, *last;
 };
 #endif // #ifndef MOVEGEN_H_INCLUDED
@@ -1,7 +1,7 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
@@ -20,174 +20,125 @@
 #include <cassert>
 #include "movegen.h"
 #include "movepick.h"
-#include "search.h"
+#include "thread.h"
 #include "types.h"
 namespace {
-  enum MovegenPhase {
+  enum Stages {
-    PH_TT_MOVES,      // Transposition table move and mate killer
+    MAIN_SEARCH, CAPTURES_S1, KILLERS_S1, QUIETS_1_S1, QUIETS_2_S1, BAD_CAPTURES_S1,
-    PH_GOOD_CAPTURES, // Queen promotions and captures with SEE values >= 0
+    EVASION,     EVASIONS_S2,
-    PH_KILLERS,       // Killer moves from the current ply
+    QSEARCH_0,   CAPTURES_S3, QUIET_CHECKS_S3,
-    PH_NONCAPTURES,   // Non-captures and underpromotions
+    QSEARCH_1,   CAPTURES_S4,
-    PH_BAD_CAPTURES,  // Queen promotions and captures with SEE values < 0
+    PROBCUT,     CAPTURES_S5,
-    PH_EVASIONS,      // Check evasions
+    RECAPTURE,   CAPTURES_S6,
-    PH_QCAPTURES,     // Captures in quiescence search
+    STOP
    PH_QCHECKS,       // Non-capture checks in quiescence search
    PH_STOP
  };
-  CACHE_LINE_ALIGNMENT
+  // Our insertion sort, which is guaranteed (and also needed) to be stable
-  const uint8_t MainSearchTable[] = { PH_TT_MOVES, PH_GOOD_CAPTURES, PH_KILLERS, PH_NONCAPTURES, PH_BAD_CAPTURES, PH_STOP };
+  void insertion_sort(ExtMove* begin, ExtMove* end)
-  const uint8_t EvasionTable[] = { PH_TT_MOVES, PH_EVASIONS, PH_STOP };
+  {
-  const uint8_t QsearchWithChecksTable[] = { PH_TT_MOVES, PH_QCAPTURES, PH_QCHECKS, PH_STOP };
+    ExtMove tmp, *p, *q;
-  const uint8_t QsearchWithoutChecksTable[] = { PH_TT_MOVES, PH_QCAPTURES, PH_STOP };
+
-}
+    for (p = begin + 1; p < end; ++p)
    {
        tmp = *p;
        for (q = p; q != begin && *(q-1) < tmp; --q)
            *q = *(q-1);
        *q = tmp;
    }
  }
  // Unary predicate used by std::partition to split positive values from remaining
  // ones so as to sort the two sets separately, with the second sort delayed.
  inline bool has_positive_value(const ExtMove& move) { return move.value > VALUE_ZERO; }
  // Picks the best move in the range (begin, end) and moves it to the front.
  // It's faster than sorting all the moves in advance when there are few
  // moves e.g. possible captures.
  inline ExtMove* pick_best(ExtMove* begin, ExtMove* end)
  {
      std::swap(*begin, *std::max_element(begin, end));
      return begin;
  }
 } // namespace
-/// Constructor for the MovePicker class. Apart from the position for which
+/// Constructors of the MovePicker class. As arguments we pass information
-/// it is asked to pick legal moves, MovePicker also wants some information
+/// to help it to return the (presumably) good moves first, to decide which
 /// to help it to return the presumably good moves first, to decide which
 /// moves to return (in the quiescence search, for instance, we only want to
-/// search captures, promotions and some checks) and about how important good
+/// search captures, promotions and some checks) and how important good move
-/// move ordering is at the current node.
+/// ordering is at the current node.
-MovePicker::MovePicker(const Position& p, Move ttm, Depth d, const History& h,
+MovePicker::MovePicker(const Position& p, Move ttm, Depth d, const HistoryStats& h,
-                       SearchStack* ss, Value beta) : pos(p), H(h) {
+                       Move* cm, Move* fm, Search::Stack* s) : pos(p), history(h), depth(d) {
  int searchTT = ttm;
  ttMoves[0].move = ttm;
  badCaptureThreshold = 0;
  badCaptures = moves + MAX_MOVES;
  assert(d > DEPTH_ZERO);
-  pinned = p.pinned_pieces(pos.side_to_move());
+  cur = end = moves;
  endBadCaptures = moves + MAX_MOVES - 1;
  countermoves = cm;
  followupmoves = fm;
  ss = s;
  if (pos.checkers())
      stage = EVASION;
  if (p.in_check())
  {
      ttMoves[1].move = killers[0].move = killers[1].move = MOVE_NONE;
      phasePtr = EvasionTable;
  }
  else
-  {
+      stage = MAIN_SEARCH;
      ttMoves[1].move = (ss->mateKiller == ttm) ? MOVE_NONE : ss->mateKiller;
      searchTT |= ttMoves[1].move;
      killers[0].move = ss->killers[0];
      killers[1].move = ss->killers[1];
-      // Consider sligtly negative captures as good if at low
+  ttMove = (ttm && pos.pseudo_legal(ttm) ? ttm : MOVE_NONE);
-      // depth and far from beta.
+  end += (ttMove != MOVE_NONE);
      if (ss && ss->eval < beta - PawnValueMidgame && d < 3 * ONE_PLY)
          badCaptureThreshold = -PawnValueMidgame;
      phasePtr = MainSearchTable;
  }
  phasePtr += int(!searchTT) - 1;
  go_next_phase();
 }
-MovePicker::MovePicker(const Position& p, Move ttm, Depth d, const History& h)
+MovePicker::MovePicker(const Position& p, Move ttm, Depth d, const HistoryStats& h,
-                      : pos(p), H(h) {
+                       Square s) : pos(p), history(h), cur(moves), end(moves) {
  int searchTT = ttm;
  ttMoves[0].move = ttm;
  ttMoves[1].move = MOVE_NONE;
  assert(d <= DEPTH_ZERO);
-  pinned = p.pinned_pieces(pos.side_to_move());
+  if (pos.checkers())
      stage = EVASION;
  else if (d > DEPTH_QS_NO_CHECKS)
      stage = QSEARCH_0;
  else if (d > DEPTH_QS_RECAPTURES)
      stage = QSEARCH_1;
  if (p.in_check())
      phasePtr = EvasionTable;
  else if (d >= DEPTH_QS_CHECKS)
      phasePtr = QsearchWithChecksTable;
  else
  {
-      phasePtr = QsearchWithoutChecksTable;
+      stage = RECAPTURE;
-
+      recaptureSquare = s;
-      // Skip TT move if is not a capture or a promotion, this avoids
+      ttm = MOVE_NONE;
      // qsearch tree explosion due to a possible perpetual check or
      // similar rare cases when TT table is full.
      if (ttm != MOVE_NONE && !pos.move_is_capture_or_promotion(ttm))
          searchTT = ttMoves[0].move = MOVE_NONE;
  }
-  phasePtr += int(!searchTT) - 1;
+  ttMove = (ttm && pos.pseudo_legal(ttm) ? ttm : MOVE_NONE);
-  go_next_phase();
+  end += (ttMove != MOVE_NONE);
 }
 MovePicker::MovePicker(const Position& p, Move ttm, const HistoryStats& h, PieceType pt)
                       : pos(p), history(h), cur(moves), end(moves) {
  assert(!pos.checkers());
  stage = PROBCUT;
  // In ProbCut we generate only captures that are better than the parent's
  // captured piece.
  captureThreshold = PieceValue[MG][pt];
  ttMove = (ttm && pos.pseudo_legal(ttm) ? ttm : MOVE_NONE);
  if (ttMove && (!pos.capture(ttMove) || pos.see(ttMove) <= captureThreshold))
      ttMove = MOVE_NONE;
  end += (ttMove != MOVE_NONE);
 }
-/// MovePicker::go_next_phase() generates, scores and sorts the next bunch
+/// score() assign a numerical value to each move in a move list. The moves with
-/// of moves when there are no more moves to try for the current phase.
+/// highest values will be picked first.
-
+template<>
-void MovePicker::go_next_phase() {
+void MovePicker::score<CAPTURES>() {
  curMove = moves;
  phase = *(++phasePtr);
  switch (phase) {
  case PH_TT_MOVES:
      curMove = ttMoves;
      lastMove = curMove + 2;
      return;
  case PH_GOOD_CAPTURES:
      lastMove = generate<MV_CAPTURE>(pos, moves);
      score_captures();
      return;
  case PH_KILLERS:
      curMove = killers;
      lastMove = curMove + 2;
      return;
  case PH_NONCAPTURES:
      lastMove = generate<MV_NON_CAPTURE>(pos, moves);
      score_noncaptures();
      sort_moves(moves, lastMove, &lastGoodNonCapture);
      return;
  case PH_BAD_CAPTURES:
      // Bad captures SEE value is already calculated so just pick
      // them in order to get SEE move ordering.
      curMove = badCaptures;
      lastMove = moves + MAX_MOVES;
      return;
  case PH_EVASIONS:
      assert(pos.in_check());
      lastMove = generate<MV_EVASION>(pos, moves);
      score_evasions();
      return;
  case PH_QCAPTURES:
      lastMove = generate<MV_CAPTURE>(pos, moves);
      score_captures();
      return;
  case PH_QCHECKS:
      lastMove = generate<MV_NON_CAPTURE_CHECK>(pos, moves);
      return;
  case PH_STOP:
      lastMove = curMove + 1; // Avoid another go_next_phase() call
      return;
  default:
      assert(false);
      return;
  }
 }
 /// MovePicker::score_captures(), MovePicker::score_noncaptures() and
 /// MovePicker::score_evasions() assign a numerical move ordering score
 /// to each move in a move list.  The moves with highest scores will be
 /// picked first by get_next_move().
 void MovePicker::score_captures() {
  // Winning and equal captures in the main search are ordered by MVV/LVA.
  // Suprisingly, this appears to perform slightly better than SEE based
  // move ordering. The reason is probably that in a position with a winning
@@ -197,154 +148,238 @@ void MovePicker::score_captures() {
  // where it is possible to recapture with the hanging piece). Exchanging
  // big pieces before capturing a hanging piece probably helps to reduce
  // the subtree size.
-  // In main search we want to push captures with negative SEE values to
+  // In main search we want to push captures with negative SEE values to the
-  // badCaptures[] array, but instead of doing it now we delay till when
+  // badCaptures[] array, but instead of doing it now we delay until the move
-  // the move has been picked up in pick_move_from_list(), this way we save
+  // has been picked up in pick_move_from_list(). This way we save some SEE
-  // some SEE calls in case we get a cutoff (idea from Pablo Vazquez).
+  // calls in case we get a cutoff.
  Move m;
-  // Use MVV/LVA ordering
+  for (ExtMove* it = moves; it != end; ++it)
  for (MoveStack* cur = moves; cur != lastMove; cur++)
  {
-      m = cur->move;
+      m = it->move;
-      if (move_is_promotion(m))
+      it->value =  PieceValue[MG][pos.piece_on(to_sq(m))]
-          cur->score = QueenValueMidgame;
+                 - Value(type_of(pos.moved_piece(m)));
      if (type_of(m) == ENPASSANT)
          it->value += PieceValue[MG][PAWN];
      else if (type_of(m) == PROMOTION)
          it->value += PieceValue[MG][promotion_type(m)] - PieceValue[MG][PAWN];
  }
 }
 template<>
 void MovePicker::score<QUIETS>() {
  Move m;
  for (ExtMove* it = moves; it != end; ++it)
  {
      m = it->move;
      it->value = history[pos.moved_piece(m)][to_sq(m)];
  }
 }
 template<>
 void MovePicker::score<EVASIONS>() {
  // Try good captures ordered by MVV/LVA, then non-captures if destination square
  // is not under attack, ordered by history value, then bad-captures and quiet
  // moves with a negative SEE. This last group is ordered by the SEE value.
  Move m;
  Value see;
  for (ExtMove* it = moves; it != end; ++it)
  {
      m = it->move;
      if ((see = pos.see_sign(m)) < VALUE_ZERO)
          it->value = see - HistoryStats::Max; // At the bottom
      else if (pos.capture(m))
          it->value =  PieceValue[MG][pos.piece_on(to_sq(m))]
                     - Value(type_of(pos.moved_piece(m))) + HistoryStats::Max;
      else
-          cur->score =  pos.midgame_value_of_piece_on(move_to(m))
+          it->value = history[pos.moved_piece(m)][to_sq(m)];
                      - pos.type_of_piece_on(move_from(m));
  }
 }
 void MovePicker::score_noncaptures() {
-  Move m;
+/// generate_next_stage() generates, scores and sorts the next bunch of moves,
-  Square from;
+/// when there are no more moves to try for the current stage.
-  for (MoveStack* cur = moves; cur != lastMove; cur++)
+void MovePicker::generate_next_stage() {
  {
      m = cur->move;
      from = move_from(m);
      cur->score = H.value(pos.piece_on(from), move_to(m));
  }
 }
-void MovePicker::score_evasions() {
+  cur = moves;
  // Try good captures ordered by MVV/LVA, then non-captures if
  // destination square is not under attack, ordered by history
  // value, and at the end bad-captures and non-captures with a
  // negative SEE. This last group is ordered by the SEE score.
  Move m;
  int seeScore;
-  // Skip if we don't have at least two moves to order
+  switch (++stage) {
-  if (lastMove < moves + 2)
+
  case CAPTURES_S1: case CAPTURES_S3: case CAPTURES_S4: case CAPTURES_S5: case CAPTURES_S6:
      end = generate<CAPTURES>(pos, moves);
      score<CAPTURES>();
      return;
-  for (MoveStack* cur = moves; cur != lastMove; cur++)
+  case KILLERS_S1:
-  {
+      cur = killers;
-      m = cur->move;
+      end = cur + 2;
-      if ((seeScore = pos.see_sign(m)) < 0)
+
-          cur->score = seeScore - History::MaxValue; // Be sure we are at the bottom
+      killers[0].move = ss->killers[0];
-      else if (pos.move_is_capture(m))
+      killers[1].move = ss->killers[1];
-          cur->score =  pos.midgame_value_of_piece_on(move_to(m))
+      killers[2].move = killers[3].move = MOVE_NONE;
-                      - pos.type_of_piece_on(move_from(m)) + History::MaxValue;
+      killers[4].move = killers[5].move = MOVE_NONE;
-      else
+
-          cur->score = H.value(pos.piece_on(move_from(m)), move_to(m));
+      // Please note that following code is racy and could yield to rare (less
      // than 1 out of a million) duplicated entries in SMP case. This is harmless.
      // Be sure countermoves are different from killers
      for (int i = 0; i < 2; ++i)
          if (   countermoves[i] != (cur+0)->move
              && countermoves[i] != (cur+1)->move)
              (end++)->move = countermoves[i];
      // Be sure followupmoves are different from killers and countermoves
      for (int i = 0; i < 2; ++i)
          if (   followupmoves[i] != (cur+0)->move
              && followupmoves[i] != (cur+1)->move
              && followupmoves[i] != (cur+2)->move
              && followupmoves[i] != (cur+3)->move)
              (end++)->move = followupmoves[i];
      return;
  case QUIETS_1_S1:
      endQuiets = end = generate<QUIETS>(pos, moves);
      score<QUIETS>();
      end = std::partition(cur, end, has_positive_value);
      insertion_sort(cur, end);
      return;
  case QUIETS_2_S1:
      cur = end;
      end = endQuiets;
      if (depth >= 3 * ONE_PLY)
          insertion_sort(cur, end);
      return;
  case BAD_CAPTURES_S1:
      // Just pick them in reverse order to get MVV/LVA ordering
      cur = moves + MAX_MOVES - 1;
      end = endBadCaptures;
      return;
  case EVASIONS_S2:
      end = generate<EVASIONS>(pos, moves);
      if (end > moves + 1)
          score<EVASIONS>();
      return;
  case QUIET_CHECKS_S3:
      end = generate<QUIET_CHECKS>(pos, moves);
      return;
  case EVASION: case QSEARCH_0: case QSEARCH_1: case PROBCUT: case RECAPTURE:
      stage = STOP;
      /* Fall through */
  case STOP:
      end = cur + 1; // Avoid another next_phase() call
      return;
  default:
      assert(false);
  }
 }
 /// MovePicker::get_next_move() is the most important method of the MovePicker
 /// class. It returns a new legal move every time it is called, until there
 /// are no more moves left. It picks the move with the biggest score from a list
 /// of generated moves taking care not to return the tt move if has already been
 /// searched previously. Note that this function is not thread safe so should be
 /// lock protected by caller when accessed through a shared MovePicker object.
-Move MovePicker::get_next_move() {
+/// next_move() is the most important method of the MovePicker class. It returns
 /// a new pseudo legal move every time it is called, until there are no more moves
 /// left. It picks the move with the biggest value from a list of generated moves
 /// taking care not to return the ttMove if it has already been searched.
 template<>
 Move MovePicker::next_move<false>() {
  Move move;
  while (true)
  {
-      while (curMove == lastMove)
+      while (cur == end)
-          go_next_phase();
+          generate_next_stage();
-      switch (phase) {
+      switch (stage) {
-      case PH_TT_MOVES:
+      case MAIN_SEARCH: case EVASION: case QSEARCH_0: case QSEARCH_1: case PROBCUT:
-          move = (curMove++)->move;
+          ++cur;
-          if (   move != MOVE_NONE
+          return ttMove;
              && pos.move_is_legal(move, pinned))
              return move;
          break;
-      case PH_GOOD_CAPTURES:
+      case CAPTURES_S1:
-          move = pick_best(curMove++, lastMove).move;
+          move = pick_best(cur++, end)->move;
-          if (   move != ttMoves[0].move
+          if (move != ttMove)
              && move != ttMoves[1].move
              && pos.pl_move_is_legal(move, pinned))
          {
-              // Check for a non negative SEE now
+              if (pos.see_sign(move) >= VALUE_ZERO)
              int seeValue = pos.see_sign(move);
              if (seeValue >= badCaptureThreshold)
                  return move;
-              // Losing capture, move it to the tail of the array, note
+              // Losing capture, move it to the tail of the array
-              // that move has now been already checked for legality.
+              (endBadCaptures--)->move = move;
              (--badCaptures)->move = move;
              badCaptures->score = seeValue;
          }
          break;
-      case PH_KILLERS:
+      case KILLERS_S1:
-          move = (curMove++)->move;
+          move = (cur++)->move;
-          if (   move != MOVE_NONE
+          if (    move != MOVE_NONE
-              && pos.move_is_legal(move, pinned)
+              &&  move != ttMove
-              && move != ttMoves[0].move
+              &&  pos.pseudo_legal(move)
-              && move != ttMoves[1].move
+              && !pos.capture(move))
              && !pos.move_is_capture(move))
              return move;
          break;
-      case PH_NONCAPTURES:
+      case QUIETS_1_S1: case QUIETS_2_S1:
-          // Sort negative scored moves only when we get there
+          move = (cur++)->move;
-          if (curMove == lastGoodNonCapture)
+          if (   move != ttMove
              insertion_sort<MoveStack>(lastGoodNonCapture, lastMove);
          move = (curMove++)->move;
          if (   move != ttMoves[0].move
              && move != ttMoves[1].move
              && move != killers[0].move
              && move != killers[1].move
-              && pos.pl_move_is_legal(move, pinned))
+              && move != killers[2].move
              && move != killers[3].move
              && move != killers[4].move
              && move != killers[5].move)
              return move;
          break;
-      case PH_BAD_CAPTURES:
+      case BAD_CAPTURES_S1:
-          move = pick_best(curMove++, lastMove).move;
+          return (cur--)->move;
          return move;
-      case PH_EVASIONS:
+      case EVASIONS_S2: case CAPTURES_S3: case CAPTURES_S4:
-      case PH_QCAPTURES:
+          move = pick_best(cur++, end)->move;
-          move = pick_best(curMove++, lastMove).move;
+          if (move != ttMove)
          if (   move != ttMoves[0].move
              && pos.pl_move_is_legal(move, pinned))
              return move;
          break;
-      case PH_QCHECKS:
+      case CAPTURES_S5:
-          move = (curMove++)->move;
+           move = pick_best(cur++, end)->move;
-          if (   move != ttMoves[0].move
+           if (move != ttMove && pos.see(move) > captureThreshold)
-              && pos.pl_move_is_legal(move, pinned))
+               return move;
           break;
      case CAPTURES_S6:
          move = pick_best(cur++, end)->move;
          if (to_sq(move) == recaptureSquare)
              return move;
          break;
-      case PH_STOP:
+      case QUIET_CHECKS_S3:
          move = (cur++)->move;
          if (move != ttMove)
              return move;
          break;
      case STOP:
          return MOVE_NONE;
      default:
          assert(false);
          break;
      }
  }
 }
 /// Version of next_move() to use at split point nodes where the move is grabbed
 /// from the split point's shared MovePicker object. This function is not thread
 /// safe so must be lock protected by the caller.
 template<>
 Move MovePicker::next_move<true>() { return ss->splitPoint->movePicker->next_move<false>(); }
@@ -1,7 +1,7 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
@@ -17,47 +17,96 @@
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
-#if !defined MOVEPICK_H_INCLUDED
+#ifndef MOVEPICK_H_INCLUDED
 #define MOVEPICK_H_INCLUDED
-#include "history.h"
+#include <algorithm> // For std::max
-#include "move.h"
+#include <cstring>   // For std::memset
 #include "movegen.h"
 #include "position.h"
 #include "search.h"
 #include "types.h"
 struct SearchStack;
-/// MovePicker is a class which is used to pick one legal move at a time from
+/// The Stats struct stores moves statistics. According to the template parameter
-/// the current position. It is initialized with a Position object and a few
+/// the class can store History, Gains and Countermoves. History records how often
-/// moves we have reason to believe are good. The most important method is
+/// different moves have been successful or unsuccessful during the current search
-/// MovePicker::get_next_move(), which returns a new legal move each time it
+/// and is used for reduction and move ordering decisions. Gains records the move's
-/// is called, until there are no legal moves left, when MOVE_NONE is returned.
+/// best evaluation gain from one ply to the next and is used for pruning decisions.
-/// In order to improve the efficiency of the alpha beta algorithm, MovePicker
+/// Countermoves store the move that refute a previous one. Entries are stored
-/// attempts to return the moves which are most likely to get a cut-off first.
+/// using only the moving piece and destination square, hence two moves with
 /// different origin but same destination and piece will be considered identical.
 template<bool Gain, typename T>
 struct Stats {
  static const Value Max = Value(250);
  const T* operator[](Piece pc) const { return table[pc]; }
  void clear() { std::memset(table, 0, sizeof(table)); }
  void update(Piece pc, Square to, Move m) {
    if (m == table[pc][to].first)
        return;
    table[pc][to].second = table[pc][to].first;
    table[pc][to].first = m;
  }
  void update(Piece pc, Square to, Value v) {
    if (Gain)
        table[pc][to] = std::max(v, table[pc][to] - 1);
    else if (abs(table[pc][to] + v) < Max)
        table[pc][to] +=  v;
  }
 private:
  T table[PIECE_NB][SQUARE_NB];
 };
 typedef Stats< true, Value> GainsStats;
 typedef Stats<false, Value> HistoryStats;
 typedef Stats<false, std::pair<Move, Move> > MovesStats;
 /// MovePicker class is used to pick one pseudo legal move at a time from the
 /// current position. The most important method is next_move(), which returns a
 /// new pseudo legal move each time it is called, until there are no moves left,
 /// when MOVE_NONE is returned. In order to improve the efficiency of the alpha
 /// beta algorithm, MovePicker attempts to return the moves which are most likely
 /// to get a cut-off first.
 class MovePicker {
  MovePicker& operator=(const MovePicker&); // Silence a warning under MSVC
 public:
-  MovePicker(const Position&, Move, Depth, const History&, SearchStack*, Value);
+  MovePicker(const Position&, Move, Depth, const HistoryStats&, Square);
-  MovePicker(const Position&, Move, Depth, const History&);
+  MovePicker(const Position&, Move, const HistoryStats&, PieceType);
-  Move get_next_move();
+  MovePicker(const Position&, Move, Depth, const HistoryStats&, Move*, Move*, Search::Stack*);
  template<bool SpNode> Move next_move();
 private:
-  void score_captures();
+  template<GenType> void score();
-  void score_noncaptures();
+  void generate_next_stage();
  void score_evasions();
  void go_next_phase();
  const Position& pos;
-  const History& H;
+  const HistoryStats& history;
-  Bitboard pinned;
+  Search::Stack* ss;
-  MoveStack ttMoves[2], killers[2];
+  Move* countermoves;
-  int badCaptureThreshold, phase;
+  Move* followupmoves;
-  const uint8_t* phasePtr;
+  Depth depth;
-  MoveStack *curMove, *lastMove, *lastGoodNonCapture, *badCaptures;
+  Move ttMove;
-  MoveStack moves[MAX_MOVES];
+  ExtMove killers[6];
  Square recaptureSquare;
  Value captureThreshold;
  int stage;
  ExtMove *cur, *end, *endQuiets, *endBadCaptures;
  ExtMove moves[MAX_MOVES];
 };
-#endif // !defined(MOVEPICK_H_INCLUDED)
+#endif // #ifndef MOVEPICK_H_INCLUDED
@@ -1,7 +1,7 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
@@ -17,227 +17,296 @@
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
 #include <algorithm>
 #include <cassert>
 #include "bitboard.h"
 #include "bitcount.h"
 #include "pawns.h"
 #include "position.h"
 #include "thread.h"
 namespace {
  #define V Value
  #define S(mg, eg) make_score(mg, eg)
-  // Doubled pawn penalty by opposed flag and file
+  // Doubled pawn penalty by file
-  const Score DoubledPawnPenalty[2][8] = {
+  const Score Doubled[FILE_NB] = {
-  { S(13, 43), S(20, 48), S(23, 48), S(23, 48),
+    S(13, 43), S(20, 48), S(23, 48), S(23, 48),
-    S(23, 48), S(23, 48), S(20, 48), S(13, 43) },
+    S(23, 48), S(23, 48), S(20, 48), S(13, 43) };
  { S(13, 43), S(20, 48), S(23, 48), S(23, 48),
    S(23, 48), S(23, 48), S(20, 48), S(13, 43) }};
  // Isolated pawn penalty by opposed flag and file
-  const Score IsolatedPawnPenalty[2][8] = {
+  const Score Isolated[2][FILE_NB] = {
  { S(37, 45), S(54, 52), S(60, 52), S(60, 52),
    S(60, 52), S(60, 52), S(54, 52), S(37, 45) },
  { S(25, 30), S(36, 35), S(40, 35), S(40, 35),
-    S(40, 35), S(40, 35), S(36, 35), S(25, 30) }};
+    S(40, 35), S(40, 35), S(36, 35), S(25, 30) } };
  // Backward pawn penalty by opposed flag and file
-  const Score BackwardPawnPenalty[2][8] = {
+  const Score Backward[2][FILE_NB] = {
  { S(30, 42), S(43, 46), S(49, 46), S(49, 46),
    S(49, 46), S(49, 46), S(43, 46), S(30, 42) },
  { S(20, 28), S(29, 31), S(33, 31), S(33, 31),
-    S(33, 31), S(33, 31), S(29, 31), S(20, 28) }};
+    S(33, 31), S(33, 31), S(29, 31), S(20, 28) } };
-  // Pawn chain membership bonus by file
+  // Connected pawn bonus by opposed, phalanx flags and rank
-  const Score ChainBonus[8] = {
+  Score Connected[2][2][RANK_NB];
    S(11,-1), S(13,-1), S(13,-1), S(14,-1),
    S(14,-1), S(13,-1), S(13,-1), S(11,-1)
  };
-  // Candidate passed pawn bonus by rank
+  // Levers bonus by rank
-  const Score CandidateBonus[8] = {
+  const Score Lever[RANK_NB] = {
-    S( 0, 0), S( 6, 13), S(6,13), S(14,29),
+    S( 0, 0), S( 0, 0), S(0, 0), S(0, 0),
-    S(34,68), S(83,166), S(0, 0), S( 0, 0)
+    S(20,20), S(40,40), S(0, 0), S(0, 0) };
  };
-  const Score PawnStructureWeight = S(233, 201);
+  // Unsupported pawn penalty
  const Score UnsupportedPawnPenalty = S(20, 10);
  // Weakness of our pawn shelter in front of the king by [distance from edge][rank]
  const Value ShelterWeakness[][RANK_NB] = {
  { V(100), V(13), V(24), V(64), V(89), V( 93), V(104) },
  { V(110), V( 1), V(29), V(75), V(96), V(102), V(107) },
  { V(102), V( 0), V(39), V(74), V(88), V(101), V( 98) },
  { V( 88), V( 4), V(33), V(67), V(92), V( 94), V(107) } };
  // Danger of enemy pawns moving toward our king by [type][distance from edge][rank]
  const Value StormDanger[][4][RANK_NB] = {
  { { V( 0),  V(  63), V( 128), V(43), V(27) },
    { V( 0),  V(  62), V( 131), V(44), V(26) },
    { V( 0),  V(  59), V( 121), V(50), V(28) },
    { V( 0),  V(  62), V( 127), V(54), V(28) } },
  { { V(24),  V(  40), V(  93), V(42), V(22) },
    { V(24),  V(  28), V( 101), V(38), V(20) },
    { V(24),  V(  32), V(  95), V(36), V(23) },
    { V(27),  V(  24), V(  99), V(36), V(24) } },
  { { V( 0),  V(   0), V(  81), V(16), V( 6) },
    { V( 0),  V(   0), V( 165), V(29), V( 9) },
    { V( 0),  V(   0), V( 163), V(23), V(12) },
    { V( 0),  V(   0), V( 161), V(28), V(13) } },
  { { V( 0),  V(-296), V(-299), V(55), V(25) },
    { V( 0),  V(  67), V( 131), V(46), V(21) },
    { V( 0),  V(  65), V( 135), V(50), V(31) },
    { V( 0),  V(  62), V( 128), V(51), V(24) } } };
  // Max bonus for king safety. Corresponds to start position with all the pawns
  // in front of the king and no enemy pawn on the horizon.
  const Value MaxSafetyBonus = V(257);
  #undef S
  #undef V
-  inline Score apply_weight(Score v, Score w) {
+  template<Color Us>
-    return make_score((int(mg_value(v)) * mg_value(w)) / 0x100,
+  Score evaluate(const Position& pos, Pawns::Entry* e) {
-                      (int(eg_value(v)) * eg_value(w)) / 0x100);
+
    const Color  Them  = (Us == WHITE ? BLACK    : WHITE);
    const Square Up    = (Us == WHITE ? DELTA_N  : DELTA_S);
    const Square Right = (Us == WHITE ? DELTA_NE : DELTA_SW);
    const Square Left  = (Us == WHITE ? DELTA_NW : DELTA_SE);
    Bitboard b, p, doubled, connected;
    Square s;
    bool passed, isolated, opposed, phalanx, backward, unsupported, lever;
    Score score = SCORE_ZERO;
    const Square* pl = pos.list<PAWN>(Us);
    const Bitboard* pawnAttacksBB = StepAttacksBB[make_piece(Us, PAWN)];
    Bitboard ourPawns   = pos.pieces(Us  , PAWN);
    Bitboard theirPawns = pos.pieces(Them, PAWN);
    e->passedPawns[Us] = 0;
    e->kingSquares[Us] = SQ_NONE;
    e->semiopenFiles[Us] = 0xFF;
    e->pawnAttacks[Us] = shift_bb<Right>(ourPawns) | shift_bb<Left>(ourPawns);
    e->pawnsOnSquares[Us][BLACK] = popcount<Max15>(ourPawns & DarkSquares);
    e->pawnsOnSquares[Us][WHITE] = pos.count<PAWN>(Us) - e->pawnsOnSquares[Us][BLACK];
    // Loop through all pawns of the current color and score each pawn
    while ((s = *pl++) != SQ_NONE)
    {
        assert(pos.piece_on(s) == make_piece(Us, PAWN));
        File f = file_of(s);
        // This file cannot be semi-open
        e->semiopenFiles[Us] &= ~(1 << f);
        // Previous rank
        p = rank_bb(s - pawn_push(Us));
        // Flag the pawn as passed, isolated, doubled,
        // unsupported or connected (but not the backward one).
        connected   =   ourPawns   & adjacent_files_bb(f) & (rank_bb(s) | p);
        phalanx     =   connected  & rank_bb(s);
        unsupported = !(ourPawns   & adjacent_files_bb(f) & p);
        isolated    = !(ourPawns   & adjacent_files_bb(f));
        doubled     =   ourPawns   & forward_bb(Us, s);
        opposed     =   theirPawns & forward_bb(Us, s);
        passed      = !(theirPawns & passed_pawn_mask(Us, s));
        lever       =   theirPawns & pawnAttacksBB[s];
        // Test for backward pawn.
        // If the pawn is passed, isolated, or connected it cannot be
        // backward. If there are friendly pawns behind on adjacent files
        // or if it can capture an enemy pawn it cannot be backward either.
        if (   (passed | isolated | connected)
            || (ourPawns & pawn_attack_span(Them, s))
            || (pos.attacks_from<PAWN>(s, Us) & theirPawns))
            backward = false;
        else
        {
            // We now know that there are no friendly pawns beside or behind this
            // pawn on adjacent files. We now check whether the pawn is
            // backward by looking in the forward direction on the adjacent
            // files, and picking the closest pawn there.
            b = pawn_attack_span(Us, s) & (ourPawns | theirPawns);
            b = pawn_attack_span(Us, s) & rank_bb(backmost_sq(Us, b));
            // If we have an enemy pawn in the same or next rank, the pawn is
            // backward because it cannot advance without being captured.
            backward = (b | shift_bb<Up>(b)) & theirPawns;
        }
        assert(opposed | passed | (pawn_attack_span(Us, s) & theirPawns));
        // Passed pawns will be properly scored in evaluation because we need
        // full attack info to evaluate passed pawns. Only the frontmost passed
        // pawn on each file is considered a true passed pawn.
        if (passed && !doubled)
            e->passedPawns[Us] |= s;
        // Score this pawn
        if (isolated)
            score -= Isolated[opposed][f];
        if (unsupported && !isolated)
            score -= UnsupportedPawnPenalty;
        if (doubled)
            score -= Doubled[f] / distance<Rank>(s, frontmost_sq(Us, doubled));
        if (backward)
            score -= Backward[opposed][f];
        if (connected)
            score += Connected[opposed][phalanx][relative_rank(Us, s)];
        if (lever)
            score += Lever[relative_rank(Us, s)];
    }
    b = e->semiopenFiles[Us] ^ 0xFF;
    e->pawnSpan[Us] = b ? int(msb(b) - lsb(b)) : 0;
    return score;
  }
 } // namespace
 namespace Pawns {
 /// Pawns::init() initializes some tables needed by evaluation. Instead of using
 /// hard-coded tables, when makes sense, we prefer to calculate them with a formula
 /// to reduce independent parameters and to allow easier tuning and better insight.
 void init()
 {
  static const int Seed[RANK_NB] = { 0, 6, 15, 10, 57, 75, 135, 258 };
  for (int opposed = 0; opposed <= 1; ++opposed)
      for (int phalanx = 0; phalanx <= 1; ++phalanx)
          for (Rank r = RANK_2; r < RANK_8; ++r)
          {
              int bonus = Seed[r] + (phalanx ? (Seed[r + 1] - Seed[r]) / 2 : 0);
              Connected[opposed][phalanx][r] = make_score(bonus / 2, bonus >> opposed);
          }
 }
-/// PawnInfoTable::get_pawn_info() takes a position object as input, computes
+/// Pawns::probe() looks up the current position's pawns configuration in
-/// a PawnInfo object, and returns a pointer to it. The result is also stored
+/// the pawns hash table. It returns a pointer to the Entry if the position
-/// in an hash table, so we don't have to recompute everything when the same
+/// is found. Otherwise a new Entry is computed and stored there, so we don't
-/// pawn structure occurs again.
+/// have to recompute all when the same pawns configuration occurs again.
-PawnInfo* PawnInfoTable::get_pawn_info(const Position& pos) const {
+Entry* probe(const Position& pos) {
-  assert(pos.is_ok());
+  Key key = pos.pawn_key();
  Entry* e = pos.this_thread()->pawnsTable[key];
-  Key key = pos.get_pawn_key();
+  if (e->key == key)
-  PawnInfo* pi = probe(key);
+      return e;
-  // If pi->key matches the position's pawn hash key, it means that we
+  e->key = key;
-  // have analysed this pawn structure before, and we can simply return
+  e->score = evaluate<WHITE>(pos, e) - evaluate<BLACK>(pos, e);
-  // the information we found the last time instead of recomputing it.
+  return e;
  if (pi->key == key)
      return pi;
  // Initialize PawnInfo entry
  pi->key = key;
  pi->passedPawns[WHITE] = pi->passedPawns[BLACK] = 0;
  pi->kingSquares[WHITE] = pi->kingSquares[BLACK] = SQ_NONE;
  pi->halfOpenFiles[WHITE] = pi->halfOpenFiles[BLACK] = 0xFF;
  // Calculate pawn attacks
  Bitboard wPawns = pos.pieces(PAWN, WHITE);
  Bitboard bPawns = pos.pieces(PAWN, BLACK);
  pi->pawnAttacks[WHITE] = ((wPawns << 9) & ~FileABB) | ((wPawns << 7) & ~FileHBB);
  pi->pawnAttacks[BLACK] = ((bPawns >> 7) & ~FileABB) | ((bPawns >> 9) & ~FileHBB);
  // Evaluate pawns for both colors and weight the result
  pi->value =  evaluate_pawns<WHITE>(pos, wPawns, bPawns, pi)
             - evaluate_pawns<BLACK>(pos, bPawns, wPawns, pi);
  pi->value = apply_weight(pi->value, PawnStructureWeight);
  return pi;
 }
-/// PawnInfoTable::evaluate_pawns() evaluates each pawn of the given color
+/// Entry::shelter_storm() calculates shelter and storm penalties for the file
 /// the king is on, as well as the two adjacent files.
 template<Color Us>
-Score PawnInfoTable::evaluate_pawns(const Position& pos, Bitboard ourPawns,
+Value Entry::shelter_storm(const Position& pos, Square ksq) {
                                    Bitboard theirPawns, PawnInfo* pi) {
  const BitCountType Max15 = CpuIs64Bit ? CNT64_MAX15 : CNT32_MAX15;
  const Color Them = (Us == WHITE ? BLACK : WHITE);
-  Bitboard b;
+  enum { NoFriendlyPawn, Unblocked, BlockedByPawn, BlockedByKing };
  Square s;
  File f;
  Rank r;
  bool passed, isolated, doubled, opposed, chain, backward, candidate;
  Score value = SCORE_ZERO;
  const Square* ptr = pos.piece_list_begin(Us, PAWN);
-  // Loop through all pawns of the current color and score each pawn
+  Bitboard b = pos.pieces(PAWN) & (in_front_bb(Us, rank_of(ksq)) | rank_bb(ksq));
-  while ((s = *ptr++) != SQ_NONE)
+  Bitboard ourPawns = b & pos.pieces(Us);
  Bitboard theirPawns = b & pos.pieces(Them);
  Value safety = MaxSafetyBonus;
  File center = std::max(FILE_B, std::min(FILE_G, file_of(ksq)));
  for (File f = center - File(1); f <= center + File(1); ++f)
  {
-      assert(pos.piece_on(s) == make_piece(Us, PAWN));
+      b = ourPawns & file_bb(f);
      Rank rkUs = b ? relative_rank(Us, backmost_sq(Us, b)) : RANK_1;
-      f = square_file(s);
+      b  = theirPawns & file_bb(f);
-      r = square_rank(s);
+      Rank rkThem = b ? relative_rank(Us, frontmost_sq(Them, b)) : RANK_1;
-      // This file cannot be half open
+      safety -=  ShelterWeakness[std::min(f, FILE_H - f)][rkUs]
-      pi->halfOpenFiles[Us] &= ~(1 << f);
+               + StormDanger
-
+                 [f == file_of(ksq) && rkThem == relative_rank(Us, ksq) + 1 ? BlockedByKing  :
-      // Our rank plus previous one. Used for chain detection
+                  rkUs   == RANK_1                                          ? NoFriendlyPawn :
-      b = rank_bb(r) | rank_bb(Us == WHITE ? r - Rank(1) : r + Rank(1));
+                  rkThem == rkUs + 1                                        ? BlockedByPawn  : Unblocked]
-
+                 [std::min(f, FILE_H - f)][rkThem];
      // Flag the pawn as passed, isolated, doubled or member of a pawn
      // chain (but not the backward one).
      passed   = !(theirPawns & passed_pawn_mask(Us, s));
      doubled  =   ourPawns   & squares_in_front_of(Us, s);
      opposed  =   theirPawns & squares_in_front_of(Us, s);
      isolated = !(ourPawns   & neighboring_files_bb(f));
      chain    =   ourPawns   & neighboring_files_bb(f) & b;
      // Test for backward pawn
      backward = false;
      // If the pawn is passed, isolated, or member of a pawn chain it cannot
      // be backward. If there are friendly pawns behind on neighboring files
      // or if can capture an enemy pawn it cannot be backward either.
      if (   !(passed | isolated | chain)
          && !(ourPawns & attack_span_mask(Them, s))
          && !(pos.attacks_from<PAWN>(s, Us) & theirPawns))
      {
          // We now know that there are no friendly pawns beside or behind this
          // pawn on neighboring files. We now check whether the pawn is
          // backward by looking in the forward direction on the neighboring
          // files, and seeing whether we meet a friendly or an enemy pawn first.
          b = pos.attacks_from<PAWN>(s, Us);
          // Note that we are sure to find something because pawn is not passed
          // nor isolated, so loop is potentially infinite, but it isn't.
          while (!(b & (ourPawns | theirPawns)))
              Us == WHITE ? b <<= 8 : b >>= 8;
          // The friendly pawn needs to be at least two ranks closer than the
          // enemy pawn in order to help the potentially backward pawn advance.
          backward = (b | (Us == WHITE ? b << 8 : b >> 8)) & theirPawns;
      }
      assert(opposed | passed | (attack_span_mask(Us, s) & theirPawns));
      // A not passed pawn is a candidate to become passed if it is free to
      // advance and if the number of friendly pawns beside or behind this
      // pawn on neighboring files is higher or equal than the number of
      // enemy pawns in the forward direction on the neighboring files.
      candidate =   !(opposed | passed | backward | isolated)
                 && (b = attack_span_mask(Them, s + pawn_push(Us)) & ourPawns) != EmptyBoardBB
                 &&  count_1s<Max15>(b) >= count_1s<Max15>(attack_span_mask(Us, s) & theirPawns);
      // Passed pawns will be properly scored in evaluation because we need
      // full attack info to evaluate passed pawns. Only the frontmost passed
      // pawn on each file is considered a true passed pawn.
      if (passed && !doubled)
          set_bit(&(pi->passedPawns[Us]), s);
      // Score this pawn
      if (isolated)
          value -= IsolatedPawnPenalty[opposed][f];
      if (doubled)
          value -= DoubledPawnPenalty[opposed][f];
      if (backward)
          value -= BackwardPawnPenalty[opposed][f];
      if (chain)
          value += ChainBonus[f];
      if (candidate)
          value += CandidateBonus[relative_rank(Us, s)];
  }
-  return value;
+
  return safety;
 }
-/// PawnInfo::updateShelter() calculates and caches king shelter. It is called
+/// Entry::do_king_safety() calculates a bonus for king safety. It is called only
-/// only when king square changes, about 20% of total king_shelter() calls.
+/// when king square changes, which is about 20% of total king_safety() calls.
 template<Color Us>
-Score PawnInfo::updateShelter(const Position& pos, Square ksq) {
+Score Entry::do_king_safety(const Position& pos, Square ksq) {
  const int Shift = (Us == WHITE ? 8 : -8);
  Bitboard pawns;
  int r, shelter = 0;
  if (relative_rank(Us, ksq) <= RANK_4)
  {
      pawns = pos.pieces(PAWN, Us) & this_and_neighboring_files_bb(ksq);
      r = ksq & (7 << 3);
      for (int i = 0; i < 3; i++)
      {
          r += Shift;
          shelter += BitCount8Bit[(pawns >> r) & 0xFF] * (64 >> i);
      }
  }
  kingSquares[Us] = ksq;
-  kingShelters[Us] = make_score(shelter, 0);
+  castlingRights[Us] = pos.can_castle(Us);
-  return kingShelters[Us];
+  minKingPawnDistance[Us] = 0;
  Bitboard pawns = pos.pieces(Us, PAWN);
  if (pawns)
      while (!(DistanceRingBB[ksq][minKingPawnDistance[Us]++] & pawns)) {}
  if (relative_rank(Us, ksq) > RANK_4)
      return make_score(0, -16 * minKingPawnDistance[Us]);
  Value bonus = shelter_storm<Us>(pos, ksq);
  // If we can castle use the bonus after the castling if it is bigger
  if (pos.can_castle(MakeCastling<Us, KING_SIDE>::right))
      bonus = std::max(bonus, shelter_storm<Us>(pos, relative_square(Us, SQ_G1)));
  if (pos.can_castle(MakeCastling<Us, QUEEN_SIDE>::right))
      bonus = std::max(bonus, shelter_storm<Us>(pos, relative_square(Us, SQ_C1)));
  return make_score(bonus, -16 * minKingPawnDistance[Us]);
 }
 // Explicit template instantiation
-template Score PawnInfo::updateShelter<WHITE>(const Position& pos, Square ksq);
+template Score Entry::do_king_safety<WHITE>(const Position& pos, Square ksq);
-template Score PawnInfo::updateShelter<BLACK>(const Position& pos, Square ksq);
+template Score Entry::do_king_safety<BLACK>(const Position& pos, Square ksq);
 } // namespace Pawns
@@ -1,7 +1,7 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
@@ -17,91 +17,68 @@
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
-#if !defined(PAWNS_H_INCLUDED)
+#ifndef PAWNS_H_INCLUDED
 #define PAWNS_H_INCLUDED
 #include "misc.h"
 #include "position.h"
 #include "tt.h"
 #include "types.h"
-const int PawnTableSize = 16384;
+namespace Pawns {
-/// PawnInfo is a class which contains various information about a pawn
+/// Pawns::Entry contains various information about a pawn structure. A lookup
-/// structure. Currently, it only includes a middle game and an end game
+/// to the pawn hash table (performed by calling the probe function) returns a
-/// pawn structure evaluation, and a bitboard of passed pawns. We may want
+/// pointer to an Entry object.
 /// to add further information in the future. A lookup to the pawn hash table
 /// (performed by calling the get_pawn_info method in a PawnInfoTable object)
 /// returns a pointer to a PawnInfo object.
-class PawnInfo {
+struct Entry {
-  friend class PawnInfoTable;
+  Score pawns_score() const { return score; }
  Bitboard pawn_attacks(Color c) const { return pawnAttacks[c]; }
  Bitboard passed_pawns(Color c) const { return passedPawns[c]; }
  int pawn_span(Color c) const { return pawnSpan[c]; }
-public:
+  int semiopen_file(Color c, File f) const {
-  Score pawns_value() const;
+    return semiopenFiles[c] & (1 << f);
-  Bitboard pawn_attacks(Color c) const;
+  }
-  Bitboard passed_pawns(Color c) const;
+
-  int file_is_half_open(Color c, File f) const;
+  int semiopen_side(Color c, File f, bool leftSide) const {
-  int has_open_file_to_left(Color c, File f) const;
+    return semiopenFiles[c] & (leftSide ? (1 << f) - 1 : ~((1 << (f + 1)) - 1));
-  int has_open_file_to_right(Color c, File f) const;
+  }
  int pawns_on_same_color_squares(Color c, Square s) const {
    return pawnsOnSquares[c][!!(DarkSquares & s)];
  }
  template<Color Us>
-  Score king_shelter(const Position& pos, Square ksq);
+  Score king_safety(const Position& pos, Square ksq)  {
    return  kingSquares[Us] == ksq && castlingRights[Us] == pos.can_castle(Us)
          ? kingSafety[Us] : (kingSafety[Us] = do_king_safety<Us>(pos, ksq));
  }
 private:
  template<Color Us>
-  Score updateShelter(const Position& pos, Square ksq);
+  Score do_king_safety(const Position& pos, Square ksq);
  template<Color Us>
  Value shelter_storm(const Position& pos, Square ksq);
  Key key;
-  Bitboard passedPawns[2];
+  Score score;
-  Bitboard pawnAttacks[2];
+  Bitboard passedPawns[COLOR_NB];
-  Square kingSquares[2];
+  Bitboard pawnAttacks[COLOR_NB];
-  Score value;
+  Square kingSquares[COLOR_NB];
-  int halfOpenFiles[2];
+  Score kingSafety[COLOR_NB];
-  Score kingShelters[2];
+  int minKingPawnDistance[COLOR_NB];
  int castlingRights[COLOR_NB];
  int semiopenFiles[COLOR_NB];
  int pawnSpan[COLOR_NB];
  int pawnsOnSquares[COLOR_NB][COLOR_NB]; // [color][light/dark squares]
 };
 typedef HashTable<Entry, 16384> Table;
-/// The PawnInfoTable class represents a pawn hash table. The most important
+void init();
-/// method is get_pawn_info, which returns a pointer to a PawnInfo object.
+Entry* probe(const Position& pos);
-class PawnInfoTable : public SimpleHash<PawnInfo, PawnTableSize> {
+} // namespace Pawns
 public:
  PawnInfo* get_pawn_info(const Position& pos) const;
-private:
+#endif // #ifndef PAWNS_H_INCLUDED
  template<Color Us>
  static Score evaluate_pawns(const Position& pos, Bitboard ourPawns, Bitboard theirPawns, PawnInfo* pi);
 };
 inline Score PawnInfo::pawns_value() const {
  return value;
 }
 inline Bitboard PawnInfo::pawn_attacks(Color c) const {
  return pawnAttacks[c];
 }
 inline Bitboard PawnInfo::passed_pawns(Color c) const {
  return passedPawns[c];
 }
 inline int PawnInfo::file_is_half_open(Color c, File f) const {
  return halfOpenFiles[c] & (1 << int(f));
 }
 inline int PawnInfo::has_open_file_to_left(Color c, File f) const {
  return halfOpenFiles[c] & ((1 << int(f)) - 1);
 }
 inline int PawnInfo::has_open_file_to_right(Color c, File f) const {
  return halfOpenFiles[c] & ~((1 << int(f+1)) - 1);
 }
 template<Color Us>
 inline Score PawnInfo::king_shelter(const Position& pos, Square ksq) {
  return kingSquares[Us] == ksq ? kingShelters[Us] : updateShelter<Us>(pos, ksq);
 }
 #endif // !defined(PAWNS_H_INCLUDED)
@@ -0,0 +1,116 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
  the Free Software Foundation, either version 3 of the License, or
  (at your option) any later version.
  Stockfish is distributed in the hope that it will be useful,
  but WITHOUT ANY WARRANTY; without even the implied warranty of
  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  GNU General Public License for more details.
  You should have received a copy of the GNU General Public License
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
 #ifndef PLATFORM_H_INCLUDED
 #define PLATFORM_H_INCLUDED
 #ifdef _MSC_VER
 // Disable some silly and noisy warnings from MSVC compiler
 #pragma warning(disable: 4127) // Conditional expression is constant
 #pragma warning(disable: 4146) // Unary minus operator applied to unsigned type
 #pragma warning(disable: 4800) // Forcing value to bool 'true' or 'false'
 #pragma warning(disable: 4996) // Function _ftime() may be unsafe
 // MSVC does not support <inttypes.h>
 typedef   signed __int8    int8_t;
 typedef unsigned __int8   uint8_t;
 typedef   signed __int16  int16_t;
 typedef unsigned __int16 uint16_t;
 typedef   signed __int32  int32_t;
 typedef unsigned __int32 uint32_t;
 typedef   signed __int64  int64_t;
 typedef unsigned __int64 uint64_t;
 #else
 #  include <inttypes.h>
 #endif
 #ifndef _WIN32 // Linux - Unix
 #  include <sys/time.h>
 inline int64_t system_time_to_msec() {
  timeval t;
  gettimeofday(&t, NULL);
  return t.tv_sec * 1000LL + t.tv_usec / 1000;
 }
 #  include <pthread.h>
 typedef pthread_mutex_t Lock;
 typedef pthread_cond_t WaitCondition;
 typedef pthread_t NativeHandle;
 typedef void*(*pt_start_fn)(void*);
 #  define lock_init(x) pthread_mutex_init(&(x), NULL)
 #  define lock_grab(x) pthread_mutex_lock(&(x))
 #  define lock_release(x) pthread_mutex_unlock(&(x))
 #  define lock_destroy(x) pthread_mutex_destroy(&(x))
 #  define cond_destroy(x) pthread_cond_destroy(&(x))
 #  define cond_init(x) pthread_cond_init(&(x), NULL)
 #  define cond_signal(x) pthread_cond_signal(&(x))
 #  define cond_wait(x,y) pthread_cond_wait(&(x),&(y))
 #  define cond_timedwait(x,y,z) pthread_cond_timedwait(&(x),&(y),z)
 #  define thread_create(x,f,t) pthread_create(&(x),NULL,(pt_start_fn)f,t)
 #  define thread_join(x) pthread_join(x, NULL)
 #else // Windows and MinGW
 #  include <sys/timeb.h>
 inline int64_t system_time_to_msec() {
  _timeb t;
  _ftime(&t);
  return t.time * 1000LL + t.millitm;
 }
 #ifndef NOMINMAX
 #  define NOMINMAX // disable macros min() and max()
 #endif
 #define WIN32_LEAN_AND_MEAN
 #include <windows.h>
 #undef WIN32_LEAN_AND_MEAN
 #undef NOMINMAX
 // We use critical sections on Windows to support Windows XP and older versions.
 // Unfortunately, cond_wait() is racy between lock_release() and WaitForSingleObject()
 // but apart from this they have the same speed performance of SRW locks.
 typedef CRITICAL_SECTION Lock;
 typedef HANDLE WaitCondition;
 typedef HANDLE NativeHandle;
 // On Windows 95 and 98 parameter lpThreadId may not be null
 inline DWORD* dwWin9xKludge() { static DWORD dw; return &dw; }
 #  define lock_init(x) InitializeCriticalSection(&(x))
 #  define lock_grab(x) EnterCriticalSection(&(x))
 #  define lock_release(x) LeaveCriticalSection(&(x))
 #  define lock_destroy(x) DeleteCriticalSection(&(x))
 #  define cond_init(x) { x = CreateEvent(0, FALSE, FALSE, 0); }
 #  define cond_destroy(x) CloseHandle(x)
 #  define cond_signal(x) SetEvent(x)
 #  define cond_wait(x,y) { lock_release(y); WaitForSingleObject(x, INFINITE); lock_grab(y); }
 #  define cond_timedwait(x,y,z) { lock_release(y); WaitForSingleObject(x,z); lock_grab(y); }
 #  define thread_create(x,f,t) (x = CreateThread(NULL,0,(LPTHREAD_START_ROUTINE)f,t,0,dwWin9xKludge()))
 #  define thread_join(x) { WaitForSingleObject(x, INFINITE); CloseHandle(x); }
 #endif
 #endif // #ifndef PLATFORM_H_INCLUDED
@@ -1,7 +1,7 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
@@ -17,193 +17,133 @@
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
-#if !defined(POSITION_H_INCLUDED)
+#ifndef POSITION_H_INCLUDED
 #define POSITION_H_INCLUDED
 #include <cassert>
 #include <cstddef>  // For offsetof()
 #include <string>
 #include "bitboard.h"
 #include "move.h"
 #include "types.h"
 /// Maximum number of plies per game (220 should be enough, because the
 /// maximum search depth is 100, and during position setup we reset the
 /// move counter for every non-reversible move).
 const int MaxGameLength = 220;
 class Position;
 struct Thread;
-/// struct checkInfo is initialized at c'tor time and keeps
+/// CheckInfo struct is initialized at c'tor time and keeps info used to detect
-/// info used to detect if a move gives check.
+/// if a move gives check.
 struct CheckInfo {
-    explicit CheckInfo(const Position&);
+  explicit CheckInfo(const Position&);
-    Bitboard dcCandidates;
+  Bitboard dcCandidates;
-    Bitboard checkSq[8];
+  Bitboard pinned;
-    Square ksq;
+  Bitboard checkSq[PIECE_TYPE_NB];
-};
+  Square   ksq;
 /// Castle rights, encoded as bit fields
 enum CastleRights {
  CASTLES_NONE = 0,
  WHITE_OO     = 1,
  BLACK_OO     = 2,
  WHITE_OOO    = 4,
  BLACK_OOO    = 8,
  ALL_CASTLES  = 15
 };
 /// Game phase
 enum Phase {
  PHASE_ENDGAME = 0,
  PHASE_MIDGAME = 128
 };
-/// The StateInfo struct stores information we need to restore a Position
+/// StateInfo struct stores information needed to restore a Position object to
-/// object to its previous state when we retract a move. Whenever a move
+/// its previous state when we retract a move. Whenever a move is made on the
-/// is made on the board (by calling Position::do_move), an StateInfo object
+/// board (by calling Position::do_move), a StateInfo object must be passed.
 /// must be passed as a parameter.
 struct StateInfo {
  Key pawnKey, materialKey;
  int castleRights, rule50, gamePly, pliesFromNull;
  Square epSquare;
  Score value;
  Value npMaterial[2];
-  PieceType capturedType;
+  // Copied when making a move
-  Key key;
+  Key    pawnKey;
-  Bitboard checkersBB;
+  Key    materialKey;
  Value  nonPawnMaterial[COLOR_NB];
  int    castlingRights;
  int    rule50;
  int    pliesFromNull;
  Score  psq;
  Square epSquare;
  // Not copied when making a move
  Key        key;
  Bitboard   checkersBB;
  PieceType  capturedType;
  StateInfo* previous;
 };
-/// The position data structure. A position consists of the following data:
+/// When making a move the current StateInfo up to 'key' excluded is copied to
-///
+/// the new one. Here we calculate the quad words (64 bit) needed to be copied.
-///    * For each piece type, a bitboard representing the squares occupied
+const size_t StateCopySize64 = offsetof(StateInfo, key) / sizeof(uint64_t) + 1;
-///      by pieces of that type.
+
-///    * For each color, a bitboard representing the squares occupied by
+
-///      pieces of that color.
+/// Position class stores information regarding the board representation as
-///    * A bitboard of all occupied squares.
+/// pieces, side to move, hash keys, castling info, etc. Important methods are
-///    * A bitboard of all checking pieces.
+/// do_move() and undo_move(), used by the search to update node info when
-///    * A 64-entry array of pieces, indexed by the squares of the board.
+/// traversing the search tree.
 ///    * The current side to move.
 ///    * Information about the castling rights for both sides.
 ///    * The initial files of the kings and both pairs of rooks. This is
 ///      used to implement the Chess960 castling rules.
 ///    * The en passant square (which is SQ_NONE if no en passant capture is
 ///      possible).
 ///    * The squares of the kings for both sides.
 ///    * Hash keys for the position itself, the current pawn structure, and
 ///      the current material situation.
 ///    * Hash keys for all previous positions in the game for detecting
 ///      repetition draws.
 ///    * A counter for detecting 50 move rule draws.
 class Position {
-  Position(); // No default or copy c'tor allowed
+  friend std::ostream& operator<<(std::ostream&, const Position&);
-  Position(const Position& pos);
+
  Position(const Position&); // Disable the default copy constructor
 public:
-  enum GamePhase {
+  static void init();
      MidGame,
      EndGame
  };
-  // Constructors
+  Position() {} // To define the global object RootPos
-  Position(const Position& pos, int threadID);
+  Position(const Position& pos, Thread* th) { *this = pos; thisThread = th; }
-  Position(const std::string& fen, bool isChess960, int threadID);
+  Position(const std::string& f, bool c960, Thread* th) { set(f, c960, th); }
  Position& operator=(const Position&); // To assign RootPos from UCI
-  // Text input/output
+  // FEN string input/output
-  void from_fen(const std::string& fen, bool isChess960);
+  void set(const std::string& fenStr, bool isChess960, Thread* th);
-  const std::string to_fen() const;
+  const std::string fen() const;
  void print(Move m = MOVE_NONE) const;
-  // Copying
+  // Position representation
-  void flip();
+  Bitboard pieces() const;
  // The piece on a given square
  Piece piece_on(Square s) const;
  PieceType type_of_piece_on(Square s) const;
  Color color_of_piece_on(Square s) const;
  bool square_is_empty(Square s) const;
  bool square_is_occupied(Square s) const;
  Value midgame_value_of_piece_on(Square s) const;
  Value endgame_value_of_piece_on(Square s) const;
  // Side to move
  Color side_to_move() const;
  // Bitboard representation of the position
  Bitboard empty_squares() const;
  Bitboard occupied_squares() const;
  Bitboard pieces_of_color(Color c) const;
  Bitboard pieces(PieceType pt) const;
  Bitboard pieces(PieceType pt, Color c) const;
  Bitboard pieces(PieceType pt1, PieceType pt2) const;
-  Bitboard pieces(PieceType pt1, PieceType pt2, Color c) const;
+  Bitboard pieces(Color c) const;
-
+  Bitboard pieces(Color c, PieceType pt) const;
-  // Number of pieces of each color and type
+  Bitboard pieces(Color c, PieceType pt1, PieceType pt2) const;
-  int piece_count(Color c, PieceType pt) const;
+  Piece piece_on(Square s) const;
  // The en passant square
  Square ep_square() const;
  // Current king position for each color
  Square king_square(Color c) const;
  Square ep_square() const;
  bool empty(Square s) const;
  template<PieceType Pt> int count(Color c) const;
  template<PieceType Pt> const Square* list(Color c) const;
-  // Castling rights
+  // Castling
-  bool can_castle_kingside(Color c) const;
+  int can_castle(Color c) const;
-  bool can_castle_queenside(Color c) const;
+  int can_castle(CastlingRight cr) const;
-  bool can_castle(Color c) const;
+  bool castling_impeded(CastlingRight cr) const;
-  Square initial_kr_square(Color c) const;
+  Square castling_rook_square(CastlingRight cr) const;
  Square initial_qr_square(Color c) const;
-  // Bitboards for pinned pieces and discovered check candidates
+  // Checking
-  Bitboard discovered_check_candidates(Color c) const;
+  Bitboard checkers() const;
  Bitboard discovered_check_candidates() const;
  Bitboard pinned_pieces(Color c) const;
-  // Checking pieces and under check information
+  // Attacks to/from a given square
  Bitboard checkers() const;
  bool in_check() const;
  // Piece lists
  Square piece_list(Color c, PieceType pt, int index) const;
  const Square* piece_list_begin(Color c, PieceType pt) const;
  // Information about attacks to or from a given square
  Bitboard attackers_to(Square s) const;
-  Bitboard attacks_from(Piece p, Square s) const;
+  Bitboard attackers_to(Square s, Bitboard occupied) const;
-  static Bitboard attacks_from(Piece p, Square s, Bitboard occ);
+  Bitboard attacks_from(Piece pc, Square s) const;
  template<PieceType> Bitboard attacks_from(Square s) const;
  template<PieceType> Bitboard attacks_from(Square s, Color c) const;
  // Properties of moves
-  bool pl_move_is_legal(Move m, Bitboard pinned) const;
+  bool legal(Move m, Bitboard pinned) const;
-  bool pl_move_is_evasion(Move m, Bitboard pinned) const;
+  bool pseudo_legal(const Move m) const;
-  bool move_is_legal(const Move m) const;
+  bool capture(Move m) const;
-  bool move_is_legal(const Move m, Bitboard pinned) const;
+  bool capture_or_promotion(Move m) const;
-  bool move_gives_check(Move m) const;
+  bool gives_check(Move m, const CheckInfo& ci) const;
-  bool move_gives_check(Move m, const CheckInfo& ci) const;
+  bool advanced_pawn_push(Move m) const;
-  bool move_is_capture(Move m) const;
+  Piece moved_piece(Move m) const;
  bool move_is_capture_or_promotion(Move m) const;
  bool move_is_passed_pawn_push(Move m) const;
  bool move_attacks_square(Move m, Square s) const;
  // Piece captured with previous moves
  PieceType captured_piece_type() const;
-  // Information about pawns
+  // Piece specific
-  bool pawn_is_passed(Color c, Square s) const;
+  bool pawn_passed(Color c, Square s) const;
-
+  bool pawn_on_7th(Color c) const;
-  // Weak squares
+  bool opposite_bishops() const;
  bool square_is_weak(Square s, Color c) const;
  // Doing and undoing moves
  void do_setup_move(Move m);
  void do_move(Move m, StateInfo& st);
  void do_move(Move m, StateInfo& st, const CheckInfo& ci, bool moveIsCheck);
  void undo_move(Move m);
@@ -211,218 +151,143 @@ public:
  void undo_null_move();
  // Static exchange evaluation
-  int see(Square from, Square to) const;
+  Value see(Move m) const;
-  int see(Move m) const;
+  Value see_sign(Move m) const;
  int see_sign(Move m) const;
  // Accessing hash keys
-  Key get_key() const;
+  Key key() const;
-  Key get_exclusion_key() const;
+  Key key_after(Move m) const;
-  Key get_pawn_key() const;
+  Key exclusion_key() const;
-  Key get_material_key() const;
+  Key material_key() const;
-
+  Key pawn_key() const;
  // Incremental evaluation
  Score value() const;
  Value non_pawn_material(Color c) const;
  static Score pst_delta(Piece piece, Square from, Square to);
  // Game termination checks
  bool is_mate() const;
  bool is_draw() const;
  // Number of plies from starting position
  int startpos_ply_counter() const;
  // Other properties of the position
-  bool opposite_colored_bishops() const;
+  Color side_to_move() const;
-  bool has_pawn_on_7th(Color c) const;
+  Phase game_phase() const;
  int game_ply() const;
  bool is_chess960() const;
-
+  Thread* this_thread() const;
-  // Current thread ID searching on the position
+  uint64_t nodes_searched() const;
-  int thread() const;
+  void set_nodes_searched(uint64_t n);
-
+  bool is_draw() const;
-  int64_t nodes_searched() const;
+  int rule50_count() const;
-  void set_nodes_searched(int64_t n);
+  Score psq_score() const;
  Value non_pawn_material(Color c) const;
  // Position consistency check, for debugging
-  bool is_ok(int* failedStep = NULL) const;
+  bool pos_is_ok(int* step = NULL) const;
-
+  void flip();
  // Static member functions
  static void init_zobrist();
  static void init_piece_square_tables();
 private:
-
+  // Initialization helpers (used while setting up a position)
  // Initialization helper functions (used while setting up a position)
  void clear();
-  void detach();
+  void set_castling_right(Color c, Square rfrom);
-  void put_piece(Piece p, Square s);
+  void set_state(StateInfo* si) const;
  void do_allow_oo(Color c);
  void do_allow_ooo(Color c);
  bool set_castling_rights(char token);
-  // Helper functions for doing and undoing moves
+  // Other helpers
-  void do_capture_move(Key& key, PieceType capture, Color them, Square to, bool ep);
+  Bitboard check_blockers(Color c, Color kingColor) const;
-  void do_castle_move(Move m);
+  void put_piece(Square s, Color c, PieceType pt);
-  void undo_castle_move(Move m);
+  void remove_piece(Square s, Color c, PieceType pt);
-  void find_checkers();
+  void move_piece(Square from, Square to, Color c, PieceType pt);
  template<bool Do>
  void do_castling(Square from, Square& to, Square& rfrom, Square& rto);
-  template<bool FindPinned>
+  // Data members
-  Bitboard hidden_checkers(Color c) const;
+  Piece board[SQUARE_NB];
-
+  Bitboard byTypeBB[PIECE_TYPE_NB];
-  // Computing hash keys from scratch (for initialization and debugging)
+  Bitboard byColorBB[COLOR_NB];
-  Key compute_key() const;
+  int pieceCount[COLOR_NB][PIECE_TYPE_NB];
-  Key compute_pawn_key() const;
+  Square pieceList[COLOR_NB][PIECE_TYPE_NB][16];
-  Key compute_material_key() const;
+  int index[SQUARE_NB];
-
+  int castlingRightsMask[SQUARE_NB];
-  // Computing incremental evaluation scores and material counts
+  Square castlingRookSquare[CASTLING_RIGHT_NB];
-  static Score pst(Color c, PieceType pt, Square s);
+  Bitboard castlingPath[CASTLING_RIGHT_NB];
  Score compute_value() const;
  Value compute_non_pawn_material(Color c) const;
  // Board
  Piece board[64];
  // Bitboards
  Bitboard byTypeBB[8], byColorBB[2];
  // Piece counts
  int pieceCount[2][8]; // [color][pieceType]
  // Piece lists
  Square pieceList[2][8][16]; // [color][pieceType][index]
  int index[64]; // [square]
  // Other info
  Color sideToMove;
  Key history[MaxGameLength];
  int castleRightsMask[64];
  StateInfo startState;
-  File initialKFile, initialKRFile, initialQRFile;
+  uint64_t nodes;
-  bool chess960;
+  int gamePly;
-  int startPosPlyCounter;
+  Color sideToMove;
-  int threadID;
+  Thread* thisThread;
  int64_t nodes;
  StateInfo* st;
-
+  bool chess960;
  // Static variables
  static Key zobrist[2][8][64];
  static Key zobEp[64];
  static Key zobCastle[16];
  static Key zobSideToMove;
  static Score PieceSquareTable[16][64];
  static Key zobExclusion;
  static const Value seeValues[8];
  static const Value PieceValueMidgame[17];
  static const Value PieceValueEndgame[17];
 };
-inline int64_t Position::nodes_searched() const {
+inline Color Position::side_to_move() const {
-  return nodes;
+  return sideToMove;
 }
-inline void Position::set_nodes_searched(int64_t n) {
+inline bool Position::empty(Square s) const {
-  nodes = n;
+  return board[s] == NO_PIECE;
 }
 inline Piece Position::piece_on(Square s) const {
  return board[s];
 }
-inline Color Position::color_of_piece_on(Square s) const {
+inline Piece Position::moved_piece(Move m) const {
-  return color_of_piece(piece_on(s));
+  return board[from_sq(m)];
 }
-inline PieceType Position::type_of_piece_on(Square s) const {
+inline Bitboard Position::pieces() const {
-  return type_of_piece(piece_on(s));
+  return byTypeBB[ALL_PIECES];
 }
 inline bool Position::square_is_empty(Square s) const {
  return piece_on(s) == PIECE_NONE;
 }
 inline bool Position::square_is_occupied(Square s) const {
  return !square_is_empty(s);
 }
 inline Value Position::midgame_value_of_piece_on(Square s) const {
  return PieceValueMidgame[piece_on(s)];
 }
 inline Value Position::endgame_value_of_piece_on(Square s) const {
  return PieceValueEndgame[piece_on(s)];
 }
 inline Color Position::side_to_move() const {
  return sideToMove;
 }
 inline Bitboard Position::occupied_squares() const {
  return byTypeBB[0];
 }
 inline Bitboard Position::empty_squares() const {
  return ~occupied_squares();
 }
 inline Bitboard Position::pieces_of_color(Color c) const {
  return byColorBB[c];
 }
 inline Bitboard Position::pieces(PieceType pt) const {
  return byTypeBB[pt];
 }
 inline Bitboard Position::pieces(PieceType pt, Color c) const {
  return byTypeBB[pt] & byColorBB[c];
 }
 inline Bitboard Position::pieces(PieceType pt1, PieceType pt2) const {
  return byTypeBB[pt1] | byTypeBB[pt2];
 }
-inline Bitboard Position::pieces(PieceType pt1, PieceType pt2, Color c) const {
+inline Bitboard Position::pieces(Color c) const {
-  return (byTypeBB[pt1] | byTypeBB[pt2]) & byColorBB[c];
+  return byColorBB[c];
 }
-inline int Position::piece_count(Color c, PieceType pt) const {
+inline Bitboard Position::pieces(Color c, PieceType pt) const {
-  return pieceCount[c][pt];
+  return byColorBB[c] & byTypeBB[pt];
 }
-inline Square Position::piece_list(Color c, PieceType pt, int idx) const {
+inline Bitboard Position::pieces(Color c, PieceType pt1, PieceType pt2) const {
-  return pieceList[c][pt][idx];
+  return byColorBB[c] & (byTypeBB[pt1] | byTypeBB[pt2]);
 }
-inline const Square* Position::piece_list_begin(Color c, PieceType pt) const {
+template<PieceType Pt> inline int Position::count(Color c) const {
-  return pieceList[c][pt];
+  return pieceCount[c][Pt];
 }
-inline Square Position::ep_square() const {
+template<PieceType Pt> inline const Square* Position::list(Color c) const {
-  return st->epSquare;
+  return pieceList[c][Pt];
 }
 inline Square Position::king_square(Color c) const {
  return pieceList[c][KING][0];
 }
-inline bool Position::can_castle_kingside(Color side) const {
+inline Square Position::ep_square() const {
-  return st->castleRights & (1+int(side));
+  return st->epSquare;
 }
-inline bool Position::can_castle_queenside(Color side) const {
+inline int Position::can_castle(CastlingRight cr) const {
-  return st->castleRights & (4+4*int(side));
+  return st->castlingRights & cr;
 }
-inline bool Position::can_castle(Color side) const {
+inline int Position::can_castle(Color c) const {
-  return can_castle_kingside(side) || can_castle_queenside(side);
+  return st->castlingRights & ((WHITE_OO | WHITE_OOO) << (2 * c));
 }
-inline Square Position::initial_kr_square(Color c) const {
+inline bool Position::castling_impeded(CastlingRight cr) const {
-  return relative_square(c, make_square(initialKRFile, RANK_1));
+  return byTypeBB[ALL_PIECES] & castlingPath[cr];
 }
-inline Square Position::initial_qr_square(Color c) const {
+inline Square Position::castling_rook_square(CastlingRight cr) const {
-  return relative_square(c, make_square(initialQRFile, RANK_1));
+  return castlingRookSquare[cr];
 }
 template<PieceType Pt>
 inline Bitboard Position::attacks_from(Square s) const {
  return  Pt == BISHOP || Pt == ROOK ? attacks_bb<Pt>(s, byTypeBB[ALL_PIECES])
        : Pt == QUEEN  ? attacks_from<ROOK>(s) | attacks_from<BISHOP>(s)
        : StepAttacksBB[Pt][s];
 }
 template<>
@@ -430,125 +295,146 @@ inline Bitboard Position::attacks_from<PAWN>(Square s, Color c) const {
  return StepAttacksBB[make_piece(c, PAWN)][s];
 }
-template<PieceType Piece> // Knight and King and white pawns
+inline Bitboard Position::attacks_from(Piece pc, Square s) const {
-inline Bitboard Position::attacks_from(Square s) const {
+  return attacks_bb(pc, s, byTypeBB[ALL_PIECES]);
  return StepAttacksBB[Piece][s];
 }
-template<>
+inline Bitboard Position::attackers_to(Square s) const {
-inline Bitboard Position::attacks_from<BISHOP>(Square s) const {
+  return attackers_to(s, byTypeBB[ALL_PIECES]);
  return bishop_attacks_bb(s, occupied_squares());
 }
 template<>
 inline Bitboard Position::attacks_from<ROOK>(Square s) const {
  return rook_attacks_bb(s, occupied_squares());
 }
 template<>
 inline Bitboard Position::attacks_from<QUEEN>(Square s) const {
  return attacks_from<ROOK>(s) | attacks_from<BISHOP>(s);
 }
 inline Bitboard Position::checkers() const {
  return st->checkersBB;
 }
-inline bool Position::in_check() const {
+inline Bitboard Position::discovered_check_candidates() const {
-  return st->checkersBB != EmptyBoardBB;
+  return check_blockers(sideToMove, ~sideToMove);
 }
-inline bool Position::pawn_is_passed(Color c, Square s) const {
+inline Bitboard Position::pinned_pieces(Color c) const {
-  return !(pieces(PAWN, opposite_color(c)) & passed_pawn_mask(c, s));
+  return check_blockers(c, c);
 }
-inline bool Position::square_is_weak(Square s, Color c) const {
+inline bool Position::pawn_passed(Color c, Square s) const {
-  return !(pieces(PAWN, opposite_color(c)) & attack_span_mask(c, s));
+  return !(pieces(~c, PAWN) & passed_pawn_mask(c, s));
 }
-inline Key Position::get_key() const {
+inline bool Position::advanced_pawn_push(Move m) const {
  return   type_of(moved_piece(m)) == PAWN
        && relative_rank(sideToMove, from_sq(m)) > RANK_4;
 }
 inline Key Position::key() const {
  return st->key;
 }
-inline Key Position::get_exclusion_key() const {
+inline Key Position::pawn_key() const {
  return st->key ^ zobExclusion;
 }
 inline Key Position::get_pawn_key() const {
  return st->pawnKey;
 }
-inline Key Position::get_material_key() const {
+inline Key Position::material_key() const {
  return st->materialKey;
 }
-inline Score Position::pst(Color c, PieceType pt, Square s) {
+inline Score Position::psq_score() const {
-  return PieceSquareTable[make_piece(c, pt)][s];
+  return st->psq;
 }
 inline Score Position::pst_delta(Piece piece, Square from, Square to) {
  return PieceSquareTable[piece][to] - PieceSquareTable[piece][from];
 }
 inline Score Position::value() const {
  return st->value;
 }
 inline Value Position::non_pawn_material(Color c) const {
-  return st->npMaterial[c];
+  return st->nonPawnMaterial[c];
 }
-inline bool Position::move_is_passed_pawn_push(Move m) const {
+inline int Position::game_ply() const {
-
+  return gamePly;
  Color c = side_to_move();
  return   piece_on(move_from(m)) == make_piece(c, PAWN)
        && pawn_is_passed(c, move_to(m));
 }
-inline int Position::startpos_ply_counter() const {
+inline int Position::rule50_count() const {
-  return startPosPlyCounter;
+  return st->rule50;
 }
-inline bool Position::opposite_colored_bishops() const {
+inline uint64_t Position::nodes_searched() const {
-
+  return nodes;
  return   piece_count(WHITE, BISHOP) == 1 && piece_count(BLACK, BISHOP) == 1
        && opposite_color_squares(piece_list(WHITE, BISHOP, 0), piece_list(BLACK, BISHOP, 0));
 }
-inline bool Position::has_pawn_on_7th(Color c) const {
+inline void Position::set_nodes_searched(uint64_t n) {
-  return pieces(PAWN, c) & rank_bb(relative_rank(c, RANK_7));
+  nodes = n;
 }
 inline bool Position::opposite_bishops() const {
  return   pieceCount[WHITE][BISHOP] == 1
        && pieceCount[BLACK][BISHOP] == 1
        && opposite_colors(pieceList[WHITE][BISHOP][0], pieceList[BLACK][BISHOP][0]);
 }
 inline bool Position::pawn_on_7th(Color c) const {
  return pieces(c, PAWN) & rank_bb(relative_rank(c, RANK_7));
 }
 inline bool Position::is_chess960() const {
  return chess960;
 }
-inline bool Position::move_is_capture(Move m) const {
+inline bool Position::capture_or_promotion(Move m) const {
-  // Move must not be MOVE_NONE !
+  assert(is_ok(m));
-  return (m & (3 << 15)) ? !move_is_castle(m) : !square_is_empty(move_to(m));
+  return type_of(m) != NORMAL ? type_of(m) != CASTLING : !empty(to_sq(m));
 }
-inline bool Position::move_is_capture_or_promotion(Move m) const {
+inline bool Position::capture(Move m) const {
-  // Move must not be MOVE_NONE !
+  // Castling is encoded as "king captures the rook"
-  return (m & (0x1F << 12)) ? !move_is_castle(m) : !square_is_empty(move_to(m));
+  assert(is_ok(m));
  return (!empty(to_sq(m)) && type_of(m) != CASTLING) || type_of(m) == ENPASSANT;
 }
 inline PieceType Position::captured_piece_type() const {
  return st->capturedType;
 }
-inline int Position::thread() const {
+inline Thread* Position::this_thread() const {
-  return threadID;
+  return thisThread;
 }
-inline void Position::do_allow_oo(Color c) {
+inline void Position::put_piece(Square s, Color c, PieceType pt) {
-  st->castleRights |= (1 + int(c));
+
  board[s] = make_piece(c, pt);
  byTypeBB[ALL_PIECES] |= s;
  byTypeBB[pt] |= s;
  byColorBB[c] |= s;
  index[s] = pieceCount[c][pt]++;
  pieceList[c][pt][index[s]] = s;
  pieceCount[c][ALL_PIECES]++;
 }
-inline void Position::do_allow_ooo(Color c) {
+inline void Position::move_piece(Square from, Square to, Color c, PieceType pt) {
-  st->castleRights |= (4 + 4*int(c));
+
  // index[from] is not updated and becomes stale. This works as long as index[]
  // is accessed just by known occupied squares.
  Bitboard from_to_bb = SquareBB[from] ^ SquareBB[to];
  byTypeBB[ALL_PIECES] ^= from_to_bb;
  byTypeBB[pt] ^= from_to_bb;
  byColorBB[c] ^= from_to_bb;
  board[from] = NO_PIECE;
  board[to] = make_piece(c, pt);
  index[to] = index[from];
  pieceList[c][pt][index[to]] = to;
 }
-#endif // !defined(POSITION_H_INCLUDED)
+inline void Position::remove_piece(Square s, Color c, PieceType pt) {
  // WARNING: This is not a reversible operation. If we remove a piece in
  // do_move() and then replace it in undo_move() we will put it at the end of
  // the list and not in its original place, it means index[] and pieceList[]
  // are not guaranteed to be invariant to a do_move() + undo_move() sequence.
  byTypeBB[ALL_PIECES] ^= s;
  byTypeBB[pt] ^= s;
  byColorBB[c] ^= s;
  /* board[s] = NO_PIECE;  Not needed, overwritten by the capturing one */
  Square lastSquare = pieceList[c][pt][--pieceCount[c][pt]];
  index[lastSquare] = index[s];
  pieceList[c][pt][index[lastSquare]] = lastSquare;
  pieceList[c][pt][pieceCount[c][pt]] = SQ_NONE;
  pieceCount[c][ALL_PIECES]--;
 }
 #endif // #ifndef POSITION_H_INCLUDED
@@ -1,7 +1,7 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
@@ -17,169 +17,82 @@
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
-#if !defined(PSQTAB_H_INCLUDED)
+#ifndef PSQTAB_H_INCLUDED
 #define PSQTAB_H_INCLUDED
 #include "types.h"
-namespace {
+#define S(mg, eg) make_score(mg, eg)
 ////
 //// Constants modified by Joona Kiiski
 ////
-const Value MP = PawnValueMidgame;
+/// PSQT[PieceType][Square] contains Piece-Square scores. For each piece type on
-const Value MK = KnightValueMidgame;
+/// a given square a (middlegame, endgame) score pair is assigned. PSQT is defined
-const Value MB = BishopValueMidgame;
+/// for the white side and the tables are symmetric for the black side.
 const Value MR = RookValueMidgame;
 const Value MQ = QueenValueMidgame;
-const Value EP = PawnValueEndgame;
+static const Score PSQT[][SQUARE_NB] = {
 const Value EK = KnightValueEndgame;
 const Value EB = BishopValueEndgame;
 const Value ER = RookValueEndgame;
 const Value EQ = QueenValueEndgame;
 const int MgPST[][64] = {
  { },
-  {// Pawn
+  { // Pawn
-   // A      B      C     D      E      F      G     H
+   S(  0, 0), S( 0, 0), S( 0, 0), S( 0, 0), S(0,  0), S( 0, 0), S( 0, 0), S(  0, 0),
-        0,    0,     0,     0,     0,     0,    0,     0,
+   S(-20, 0), S( 0, 0), S( 0, 0), S( 0, 0), S(0,  0), S( 0, 0), S( 0, 0), S(-20, 0),
-    MP-28, MP-6, MP+ 4, MP+14, MP+14, MP+ 4, MP-6, MP-28,
+   S(-20, 0), S( 0, 0), S(10, 0), S(20, 0), S(20, 0), S(10, 0), S( 0, 0), S(-20, 0),
-    MP-28, MP-6, MP+ 9, MP+36, MP+36, MP+ 9, MP-6, MP-28,
+   S(-20, 0), S( 0, 0), S(20, 0), S(40, 0), S(40, 0), S(20, 0), S( 0, 0), S(-20, 0),
-    MP-28, MP-6, MP+17, MP+58, MP+58, MP+17, MP-6, MP-28,
+   S(-20, 0), S( 0, 0), S(10, 0), S(20, 0), S(20, 0), S(10, 0), S( 0, 0), S(-20, 0),
-    MP-28, MP-6, MP+17, MP+36, MP+36, MP+17, MP-6, MP-28,
+   S(-20, 0), S( 0, 0), S( 0, 0), S( 0, 0), S(0,  0), S( 0, 0), S( 0, 0), S(-20, 0),
-    MP-28, MP-6, MP+ 9, MP+14, MP+14, MP+ 9, MP-6, MP-28,
+   S(-20, 0), S( 0, 0), S( 0, 0), S( 0, 0), S(0,  0), S( 0, 0), S( 0, 0), S(-20, 0),
-    MP-28, MP-6, MP+ 4, MP+14, MP+14, MP+ 4, MP-6, MP-28,
+   S(  0, 0), S( 0, 0), S( 0, 0), S( 0, 0), S(0,  0), S( 0, 0), S( 0, 0), S(  0, 0)
        0,    0,     0,     0,     0,     0,    0,     0
  },
-  {// Knight
+  { // Knight
-   //  A      B       C      D      E      F      G       H
+   S(-144,-98), S(-109,-83), S(-85,-51), S(-73,-16), S(-73,-16), S(-85,-51), S(-109,-83), S(-144,-98),
-    MK-135, MK-107, MK-80, MK-67, MK-67, MK-80, MK-107, MK-135,
+   S( -88,-68), S( -43,-53), S(-19,-21), S( -7, 14), S( -7, 14), S(-19,-21), S( -43,-53), S( -88,-68),
-    MK- 93, MK- 67, MK-39, MK-25, MK-25, MK-39, MK- 67, MK- 93,
+   S( -69,-53), S( -24,-38), S(  0, -6), S( 12, 29), S( 12, 29), S(  0, -6), S( -24,-38), S( -69,-53),
-    MK- 53, MK- 25, MK+ 1, MK+13, MK+13, MK+ 1, MK- 25, MK- 53,
+   S( -28,-42), S(  17,-27), S( 41,  5), S( 53, 40), S( 53, 40), S( 41,  5), S(  17,-27), S( -28,-42),
-    MK- 25, MK+  1, MK+27, MK+41, MK+41, MK+27, MK+  1, MK- 25,
+   S( -30,-42), S(  15,-27), S( 39,  5), S( 51, 40), S( 51, 40), S( 39,  5), S(  15,-27), S( -30,-42),
-    MK- 11, MK+ 13, MK+41, MK+55, MK+55, MK+41, MK+ 13, MK- 11,
+   S( -10,-53), S(  35,-38), S( 59, -6), S( 71, 29), S( 71, 29), S( 59, -6), S(  35,-38), S( -10,-53),
-    MK- 11, MK+ 13, MK+41, MK+55, MK+55, MK+41, MK+ 13, MK- 11,
+   S( -64,-68), S( -19,-53), S(  5,-21), S( 17, 14), S( 17, 14), S(  5,-21), S( -19,-53), S( -64,-68),
-    MK- 53, MK- 25, MK+ 1, MK+13, MK+13, MK+ 1, MK- 25, MK- 53,
+   S(-200,-98), S( -65,-83), S(-41,-51), S(-29,-16), S(-29,-16), S(-41,-51), S( -65,-83), S(-200,-98)
    MK-193, MK- 67, MK-39, MK-25, MK-25, MK-39, MK- 67, MK-193
  },
-  {// Bishop
+  { // Bishop
-   // A      B      C      D      E      F      G      H
+   S(-54,-65), S(-27,-42), S(-34,-44), S(-43,-26), S(-43,-26), S(-34,-44), S(-27,-42), S(-54,-65),
-    MB-40, MB-40, MB-35, MB-30, MB-30, MB-35, MB-40, MB-40,
+   S(-29,-43), S(  8,-20), S(  1,-22), S( -8, -4), S( -8, -4), S(  1,-22), S(  8,-20), S(-29,-43),
-    MB-17, MB+ 0, MB- 4, MB+ 0, MB+ 0, MB- 4, MB+ 0, MB-17,
+   S(-20,-33), S( 17,-10), S( 10,-12), S(  1,  6), S(  1,  6), S( 10,-12), S( 17,-10), S(-20,-33),
-    MB-13, MB- 4, MB+ 8, MB+ 4, MB+ 4, MB+ 8, MB- 4, MB-13,
+   S(-19,-35), S( 18,-12), S( 11,-14), S(  2,  4), S(  2,  4), S( 11,-14), S( 18,-12), S(-19,-35),
-    MB- 8, MB+ 0, MB+ 4, MB+17, MB+17, MB+ 4, MB+ 0, MB- 8,
+   S(-22,-35), S( 15,-12), S(  8,-14), S( -1,  4), S( -1,  4), S(  8,-14), S( 15,-12), S(-22,-35),
-    MB- 8, MB+ 0, MB+ 4, MB+17, MB+17, MB+ 4, MB+ 0, MB- 8,
+   S(-28,-33), S(  9,-10), S(  2,-12), S( -7,  6), S( -7,  6), S(  2,-12), S(  9,-10), S(-28,-33),
-    MB-13, MB- 4, MB+ 8, MB+ 4, MB+ 4, MB+ 8, MB- 4, MB-13,
+   S(-32,-43), S(  5,-20), S( -2,-22), S(-11, -4), S(-11, -4), S( -2,-22), S(  5,-20), S(-32,-43),
-    MB-17, MB+ 0, MB- 4, MB+ 0, MB+ 0, MB- 4, MB+ 0, MB-17,
+   S(-49,-65), S(-22,-42), S(-29,-44), S(-38,-26), S(-38,-26), S(-29,-44), S(-22,-42), S(-49,-65)
    MB-17, MB-17, MB-13, MB- 8, MB- 8, MB-13, MB-17, MB-17
  },
-  {// Rook
+  { // Rook
-   // A      B     C     D     E     F     G     H
+   S(-22, 3), S(-17, 3), S(-12, 3), S(-8, 3), S(-8, 3), S(-12, 3), S(-17, 3), S(-22, 3),
-    MR-12, MR-7, MR-2, MR+2, MR+2, MR-2, MR-7, MR-12,
+   S(-22, 3), S( -7, 3), S( -2, 3), S( 2, 3), S( 2, 3), S( -2, 3), S( -7, 3), S(-22, 3),
-    MR-12, MR-7, MR-2, MR+2, MR+2, MR-2, MR-7, MR-12,
+   S(-22, 3), S( -7, 3), S( -2, 3), S( 2, 3), S( 2, 3), S( -2, 3), S( -7, 3), S(-22, 3),
-    MR-12, MR-7, MR-2, MR+2, MR+2, MR-2, MR-7, MR-12,
+   S(-22, 3), S( -7, 3), S( -2, 3), S( 2, 3), S( 2, 3), S( -2, 3), S( -7, 3), S(-22, 3),
-    MR-12, MR-7, MR-2, MR+2, MR+2, MR-2, MR-7, MR-12,
+   S(-22, 3), S( -7, 3), S( -2, 3), S( 2, 3), S( 2, 3), S( -2, 3), S( -7, 3), S(-22, 3),
-    MR-12, MR-7, MR-2, MR+2, MR+2, MR-2, MR-7, MR-12,
+   S(-22, 3), S( -7, 3), S( -2, 3), S( 2, 3), S( 2, 3), S( -2, 3), S( -7, 3), S(-22, 3),
-    MR-12, MR-7, MR-2, MR+2, MR+2, MR-2, MR-7, MR-12,
+   S(-11, 3), S(  4, 3), S(  9, 3), S(13, 3), S(13, 3), S(  9, 3), S(  4, 3), S(-11, 3),
-    MR-12, MR-7, MR-2, MR+2, MR+2, MR-2, MR-7, MR-12,
+   S(-22, 3), S(-17, 3), S(-12, 3), S(-8, 3), S(-8, 3), S(-12, 3), S(-17, 3), S(-22, 3)
    MR-12, MR-7, MR-2, MR+2, MR+2, MR-2, MR-7, MR-12
  },
-  {// Queen
+  { // Queen
-   // A     B     C     D     E     F     G     H
+   S(-2,-80), S(-2,-54), S(-2,-42), S(-2,-30), S(-2,-30), S(-2,-42), S(-2,-54), S(-2,-80),
-    MQ+8, MQ+8, MQ+8, MQ+8, MQ+8, MQ+8, MQ+8, MQ+8,
+   S(-2,-54), S( 8,-30), S( 8,-18), S( 8, -6), S( 8, -6), S( 8,-18), S( 8,-30), S(-2,-54),
-    MQ+8, MQ+8, MQ+8, MQ+8, MQ+8, MQ+8, MQ+8, MQ+8,
+   S(-2,-42), S( 8,-18), S( 8, -6), S( 8,  6), S( 8,  6), S( 8, -6), S( 8,-18), S(-2,-42),
-    MQ+8, MQ+8, MQ+8, MQ+8, MQ+8, MQ+8, MQ+8, MQ+8,
+   S(-2,-30), S( 8, -6), S( 8,  6), S( 8, 18), S( 8, 18), S( 8,  6), S( 8, -6), S(-2,-30),
-    MQ+8, MQ+8, MQ+8, MQ+8, MQ+8, MQ+8, MQ+8, MQ+8,
+   S(-2,-30), S( 8, -6), S( 8,  6), S( 8, 18), S( 8, 18), S( 8,  6), S( 8, -6), S(-2,-30),
-    MQ+8, MQ+8, MQ+8, MQ+8, MQ+8, MQ+8, MQ+8, MQ+8,
+   S(-2,-42), S( 8,-18), S( 8, -6), S( 8,  6), S( 8,  6), S( 8, -6), S( 8,-18), S(-2,-42),
-    MQ+8, MQ+8, MQ+8, MQ+8, MQ+8, MQ+8, MQ+8, MQ+8,
+   S(-2,-54), S( 8,-30), S( 8,-18), S( 8, -6), S( 8, -6), S( 8,-18), S( 8,-30), S(-2,-54),
-    MQ+8, MQ+8, MQ+8, MQ+8, MQ+8, MQ+8, MQ+8, MQ+8,
+   S(-2,-80), S(-2,-54), S(-2,-42), S(-2,-30), S(-2,-30), S(-2,-42), S(-2,-54), S(-2,-80)
    MQ+8, MQ+8, MQ+8, MQ+8, MQ+8, MQ+8, MQ+8, MQ+8
  },
-  {// King
+  { // King
-   //A    B    C    D    E    F    G    H
+   S(298, 27), S(332, 81), S(273,108), S(225,116), S(225,116), S(273,108), S(332, 81), S(298, 27),
-    287, 311, 262, 214, 214, 262, 311, 287,
+   S(287, 74), S(321,128), S(262,155), S(214,163), S(214,163), S(262,155), S(321,128), S(287, 74),
-    262, 287, 238, 190, 190, 238, 287, 262,
+   S(224,111), S(258,165), S(199,192), S(151,200), S(151,200), S(199,192), S(258,165), S(224,111),
-    214, 238, 190, 142, 142, 190, 238, 214,
+   S(196,135), S(230,189), S(171,216), S(123,224), S(123,224), S(171,216), S(230,189), S(196,135),
-    190, 214, 167, 119, 119, 167, 214, 190,
+   S(173,135), S(207,189), S(148,216), S(100,224), S(100,224), S(148,216), S(207,189), S(173,135),
-    167, 190, 142,  94,  94, 142, 190, 167,
+   S(146,111), S(180,165), S(121,192), S( 73,200), S( 73,200), S(121,192), S(180,165), S(146,111),
-    142, 167, 119,  69,  69, 119, 167, 142,
+   S(119, 74), S(153,128), S( 94,155), S( 46,163), S( 46,163), S( 94,155), S(153,128), S(119, 74),
-    119, 142,  94,  46,  46,  94, 142, 119,
+   S( 98, 27), S(132, 81), S( 73,108), S( 25,116), S( 25,116), S( 73,108), S(132, 81), S( 98, 27)
     94, 119,  69,  21,  21,  69, 119,  94
  }
 };
-const int EgPST[][64] = {
+#undef S
  { },
  {// Pawn
   // A     B     C     D     E     F     G     H
       0,    0,    0,    0,    0,    0,    0,    0,
    EP-8, EP-8, EP-8, EP-8, EP-8, EP-8, EP-8, EP-8,
    EP-8, EP-8, EP-8, EP-8, EP-8, EP-8, EP-8, EP-8,
    EP-8, EP-8, EP-8, EP-8, EP-8, EP-8, EP-8, EP-8,
    EP-8, EP-8, EP-8, EP-8, EP-8, EP-8, EP-8, EP-8,
    EP-8, EP-8, EP-8, EP-8, EP-8, EP-8, EP-8, EP-8,
    EP-8, EP-8, EP-8, EP-8, EP-8, EP-8, EP-8, EP-8,
       0,    0,    0,    0,    0,    0,    0,    0
  },
  {// Knight
   // A       B      C      D      E      F      G      H
    EK-104, EK-79, EK-55, EK-42, EK-42, EK-55, EK-79, EK-104,
    EK- 79, EK-55, EK-30, EK-17, EK-17, EK-30, EK-55, EK- 79,
    EK- 55, EK-30, EK- 6, EK+ 5, EK+ 5, EK- 6, EK-30, EK- 55,
    EK- 42, EK-17, EK+ 5, EK+18, EK+18, EK+ 5, EK-17, EK- 42,
    EK- 42, EK-17, EK+ 5, EK+18, EK+18, EK+ 5, EK-17, EK- 42,
    EK- 55, EK-30, EK- 6, EK+ 5, EK+ 5, EK- 6, EK-30, EK- 55,
    EK- 79, EK-55, EK-30, EK-17, EK-17, EK-30, EK-55, EK- 79,
    EK-104, EK-79, EK-55, EK-42, EK-42, EK-55, EK-79, EK-104
  },
  {// Bishop
   // A      B      C      D      E      F      G      H
    EB-59, EB-42, EB-35, EB-26, EB-26, EB-35, EB-42, EB-59,
    EB-42, EB-26, EB-18, EB-11, EB-11, EB-18, EB-26, EB-42,
    EB-35, EB-18, EB-11, EB- 4, EB- 4, EB-11, EB-18, EB-35,
    EB-26, EB-11, EB- 4, EB+ 4, EB+ 4, EB- 4, EB-11, EB-26,
    EB-26, EB-11, EB- 4, EB+ 4, EB+ 4, EB- 4, EB-11, EB-26,
    EB-35, EB-18, EB-11, EB- 4, EB- 4, EB-11, EB-18, EB-35,
    EB-42, EB-26, EB-18, EB-11, EB-11, EB-18, EB-26, EB-42,
    EB-59, EB-42, EB-35, EB-26, EB-26, EB-35, EB-42, EB-59
  },
  {// Rook
   // A     B     C     D     E     F     G     H
    ER+3, ER+3, ER+3, ER+3, ER+3, ER+3, ER+3, ER+3,
    ER+3, ER+3, ER+3, ER+3, ER+3, ER+3, ER+3, ER+3,
    ER+3, ER+3, ER+3, ER+3, ER+3, ER+3, ER+3, ER+3,
    ER+3, ER+3, ER+3, ER+3, ER+3, ER+3, ER+3, ER+3,
    ER+3, ER+3, ER+3, ER+3, ER+3, ER+3, ER+3, ER+3,
    ER+3, ER+3, ER+3, ER+3, ER+3, ER+3, ER+3, ER+3,
    ER+3, ER+3, ER+3, ER+3, ER+3, ER+3, ER+3, ER+3,
    ER+3, ER+3, ER+3, ER+3, ER+3, ER+3, ER+3, ER+3
  },
  {// Queen
   // A      B      C      D      E      F      G      H
    EQ-80, EQ-54, EQ-42, EQ-30, EQ-30, EQ-42, EQ-54, EQ-80,
    EQ-54, EQ-30, EQ-18, EQ- 6, EQ- 6, EQ-18, EQ-30, EQ-54,
    EQ-42, EQ-18, EQ- 6, EQ+ 6, EQ+ 6, EQ- 6, EQ-18, EQ-42,
    EQ-30, EQ- 6, EQ+ 6, EQ+18, EQ+18, EQ+ 6, EQ- 6, EQ-30,
    EQ-30, EQ- 6, EQ+ 6, EQ+18, EQ+18, EQ+ 6, EQ- 6, EQ-30,
    EQ-42, EQ-18, EQ- 6, EQ+ 6, EQ+ 6, EQ- 6, EQ-18, EQ-42,
    EQ-54, EQ-30, EQ-18, EQ- 6, EQ- 6, EQ-18, EQ-30, EQ-54,
    EQ-80, EQ-54, EQ-42, EQ-30, EQ-30, EQ-42, EQ-54, EQ-80
  },
  {// King
   //A    B    C    D    E    F    G    H
     18,  77, 105, 135, 135, 105,  77,  18,
     77, 135, 165, 193, 193, 165, 135,  77,
    105, 165, 193, 222, 222, 193, 165, 105,
    135, 193, 222, 251, 251, 222, 193, 135,
    135, 193, 222, 251, 251, 222, 193, 135,
    105, 165, 193, 222, 222, 193, 165, 105,
     77, 135, 165, 193, 193, 165, 135,  77,
     18,  77, 105, 135, 135, 105,  77,  18
  }
 };
-} // namespace
+#endif // #ifndef PSQTAB_H_INCLUDED
 #endif // !defined(PSQTAB_H_INCLUDED)
@@ -1,77 +0,0 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
  the Free Software Foundation, either version 3 of the License, or
  (at your option) any later version.
  Stockfish is distributed in the hope that it will be useful,
  but WITHOUT ANY WARRANTY; without even the implied warranty of
  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  GNU General Public License for more details.
  You should have received a copy of the GNU General Public License
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
  This file is based on original code by Heinz van Saanen and is
  available under the GNU General Public License as published by
  the Free Software Foundation, either version 3 of the License, or
  (at your option) any later version.
 ** George Marsaglia invented the RNG-Kiss-family in the early 90's.
 ** This is a specific version that Heinz van Saanen derived and
 ** tested from some public domain code by Bob Jenkins:
 **
 ** Quite platform independent
 ** Passes ALL dieharder tests! Here *nix sys-rand() e.g. fails miserably:-)
 ** ~12 times faster than my *nix sys-rand()
 ** ~4 times faster than SSE2-version of Mersenne twister
 ** Average cycle length: ~2^126
 ** 64 bit seed
 ** Return doubles with a full 53 bit mantissa
 ** Thread safe
 */
 #if !defined(RKISS_H_INCLUDED)
 #define RKISS_H_INCLUDED
 #include "types.h"
 class RKISS {
  // Keep variables always together
  struct S { uint64_t a, b, c, d; } s;
  uint64_t rotate(uint64_t x, uint64_t k) const {
    return (x << k) | (x >> (64 - k));
  }
  // Return 64 bit unsigned integer in between [0, 2^64 - 1]
  uint64_t rand64() {
    const uint64_t
      e = s.a - rotate(s.b,  7);
    s.a = s.b ^ rotate(s.c, 13);
    s.b = s.c + rotate(s.d, 37);
    s.c = s.d + e;
    return s.d = e + s.a;
  }
  // Init seed and scramble a few rounds
  void raninit() {
    s.a = 0xf1ea5eed;
    s.b = s.c = s.d = 0xd4e12c77;
    for (int i = 0; i < 73; i++)
        rand64();
  }
 public:
  RKISS() { raninit(); }
  template<typename T> T rand() { return T(rand64()); }
 };
 #endif // !defined(RKISS_H_INCLUDED)
@@ -1,7 +1,7 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
@@ -17,57 +17,98 @@
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
-#if !defined(SEARCH_H_INCLUDED)
+#ifndef SEARCH_H_INCLUDED
 #define SEARCH_H_INCLUDED
-#include <cstring>
+#include <memory>  // For std::auto_ptr
 #include <stack>
 #include <vector>
-#include "move.h"
+#include "misc.h"
 #include "position.h"
 #include "types.h"
 class Position;
 struct SplitPoint;
-/// The SearchStack struct keeps track of the information we need to remember
+namespace Search {
 /// from nodes shallower and deeper in the tree during the search.  Each
 /// search thread has its own array of SearchStack objects, indexed by the
 /// current ply.
-struct SearchStack {
+/// Stack struct keeps track of the information we need to remember from nodes
 /// shallower and deeper in the tree during the search. Each search thread has
 /// its own array of Stack objects, indexed by the current ply.
 struct Stack {
  SplitPoint* splitPoint;
  Move* pv;
  int ply;
  Move currentMove;
-  Move mateKiller;
+  Move ttMove;
  Move excludedMove;
  Move bestMove;
  Move killers[2];
  Depth reduction;
-  Value eval;
+  Value staticEval;
-  Value evalMargin;
+  bool skipEarlyPruning;
  bool skipNullMove;
  SplitPoint* sp;
 };
 /// RootMove struct is used for moves at the root of the tree. For each root move
 /// we store a score and a PV (really a refutation in the case of moves which
 /// fail low). Score is normally set at -VALUE_INFINITE for all non-pv moves.
-/// The SearchLimits struct stores information sent by GUI about available time
+struct RootMove {
 /// to search the current move, maximum depth/time, if we are in analysis mode
 /// or if we have to ponder while is our opponent's side to move.
-struct SearchLimits {
+  RootMove(Move m) : score(-VALUE_INFINITE), previousScore(-VALUE_INFINITE), pv(1, m) {}
-  SearchLimits() { memset(this, 0, sizeof(SearchLimits)); }
+  bool operator<(const RootMove& m) const { return score > m.score; } // Ascending sort
  bool operator==(const Move& m) const { return pv[0] == m; }
  void insert_pv_in_tt(Position& pos);
  Move extract_ponder_from_tt(Position& pos);
-  SearchLimits(int t, int i, int mtg, int mt, int md, int mn, bool inf, bool pon)
+  Value score;
-              : time(t), increment(i), movesToGo(mtg), maxTime(mt), maxDepth(md),
+  Value previousScore;
-                maxNodes(mn), infinite(inf), ponder(pon) {}
+  std::vector<Move> pv;
  bool useTimeManagement() const { return !(maxTime | maxDepth | maxNodes | int(infinite)); }
  int time, increment, movesToGo, maxTime, maxDepth, maxNodes;
  bool infinite, ponder;
 };
-extern void init_search();
+typedef std::vector<RootMove> RootMoveVector;
 extern int64_t perft(Position& pos, Depth depth);
 extern bool think(Position& pos, const SearchLimits& limits, Move searchMoves[]);
-#endif // !defined(SEARCH_H_INCLUDED)
+/// LimitsType struct stores information sent by GUI about available time to
 /// search the current move, maximum depth/time, if we are in analysis mode or
 /// if we have to ponder while it's our opponent's turn to move.
 struct LimitsType {
  LimitsType() { // Init explicitly due to broken value-initialization of non POD in MSVC
    nodes = time[WHITE] = time[BLACK] = inc[WHITE] = inc[BLACK] = movestogo =
    depth = movetime = mate = infinite = ponder = 0;
  }
  bool use_time_management() const {
    return !(mate | movetime | depth | nodes | infinite);
  }
  std::vector<Move> searchmoves;
  int time[COLOR_NB], inc[COLOR_NB], movestogo, depth, movetime, mate, infinite, ponder;
  int64_t nodes;
 };
 /// The SignalsType struct stores volatile flags updated during the search
 /// typically in an async fashion e.g. to stop the search by the GUI.
 struct SignalsType {
  bool stop, stopOnPonderhit, firstRootMove, failedLowAtRoot;
 };
 typedef std::auto_ptr<std::stack<StateInfo> > StateStackPtr;
 extern volatile SignalsType Signals;
 extern LimitsType Limits;
 extern RootMoveVector RootMoves;
 extern Position RootPos;
 extern Time::point SearchTime;
 extern StateStackPtr SetupStates;
 void init();
 void think();
 template<bool Root> uint64_t perft(Position& pos, Depth depth);
 } // namespace Search
 #endif // #ifndef SEARCH_H_INCLUDED
@@ -0,0 +1,169 @@
 /*
  Copyright (c) 2011-2013 Ronald de Man
 */
 #ifndef TBCORE_H
 #define TBCORE_H
 #ifndef _WIN32
 #include <pthread.h>
 #define SEP_CHAR ':'
 #define FD int
 #define FD_ERR -1
 #else
 #include <windows.h>
 #define SEP_CHAR ';'
 #define FD HANDLE
 #define FD_ERR INVALID_HANDLE_VALUE
 #endif
 #ifndef _WIN32
 #define LOCK_T pthread_mutex_t
 #define LOCK_INIT(x) pthread_mutex_init(&(x), NULL)
 #define LOCK(x) pthread_mutex_lock(&(x))
 #define UNLOCK(x) pthread_mutex_unlock(&(x))
 #else
 #define LOCK_T HANDLE
 #define LOCK_INIT(x) do { x = CreateMutex(NULL, FALSE, NULL); } while (0)
 #define LOCK(x) WaitForSingleObject(x, INFINITE)
 #define UNLOCK(x) ReleaseMutex(x)
 #endif
 #ifndef _MSC_VER
 #define BSWAP32(v) __builtin_bswap32(v)
 #define BSWAP64(v) __builtin_bswap64(v)
 #else
 #define BSWAP32(v) _byteswap_ulong(v)
 #define BSWAP64(v) _byteswap_uint64(v)
 #endif
 #define WDLSUFFIX ".rtbw"
 #define DTZSUFFIX ".rtbz"
 #define WDLDIR "RTBWDIR"
 #define DTZDIR "RTBZDIR"
 #define TBPIECES 6
 typedef unsigned long long uint64;
 typedef unsigned int uint32;
 typedef unsigned char ubyte;
 typedef unsigned short ushort;
 const ubyte WDL_MAGIC[4] = { 0x71, 0xe8, 0x23, 0x5d };
 const ubyte DTZ_MAGIC[4] = { 0xd7, 0x66, 0x0c, 0xa5 };
 #define TBHASHBITS 10
 struct TBHashEntry;
 typedef uint64 base_t;
 struct PairsData {
  char *indextable;
  ushort *sizetable;
  ubyte *data;
  ushort *offset;
  ubyte *symlen;
  ubyte *sympat;
  int blocksize;
  int idxbits;
  int min_len;
  base_t base[1]; // C++ complains about base[]...
 };
 struct TBEntry {
  char *data;
  uint64 key;
  uint64 mapping;
  ubyte ready;
  ubyte num;
  ubyte symmetric;
  ubyte has_pawns;
 }
 #ifndef _WIN32
 __attribute__((__may_alias__))
 #endif
 ;
 struct TBEntry_piece {
  char *data;
  uint64 key;
  uint64 mapping;
  ubyte ready;
  ubyte num;
  ubyte symmetric;
  ubyte has_pawns;
  ubyte enc_type;
  struct PairsData *precomp[2];
  int factor[2][TBPIECES];
  ubyte pieces[2][TBPIECES];
  ubyte norm[2][TBPIECES];
 };
 struct TBEntry_pawn {
  char *data;
  uint64 key;
  uint64 mapping;
  ubyte ready;
  ubyte num;
  ubyte symmetric;
  ubyte has_pawns;
  ubyte pawns[2];
  struct {
    struct PairsData *precomp[2];
    int factor[2][TBPIECES];
    ubyte pieces[2][TBPIECES];
    ubyte norm[2][TBPIECES];
  } file[4];
 };
 struct DTZEntry_piece {
  char *data;
  uint64 key;
  uint64 mapping;
  ubyte ready;
  ubyte num;
  ubyte symmetric;
  ubyte has_pawns;
  ubyte enc_type;
  struct PairsData *precomp;
  int factor[TBPIECES];
  ubyte pieces[TBPIECES];
  ubyte norm[TBPIECES];
  ubyte flags; // accurate, mapped, side
  ushort map_idx[4];
  ubyte *map;
 };
 struct DTZEntry_pawn {
  char *data;
  uint64 key;
  uint64 mapping;
  ubyte ready;
  ubyte num;
  ubyte symmetric;
  ubyte has_pawns;
  ubyte pawns[2];
  struct {
    struct PairsData *precomp;
    int factor[TBPIECES];
    ubyte pieces[TBPIECES];
    ubyte norm[TBPIECES];
  } file[4];
  ubyte flags[4];
  ushort map_idx[4][4];
  ubyte *map;
 };
 struct TBHashEntry {
  uint64 key;
  struct TBEntry *ptr;
 };
 struct DTZTableEntry {
  uint64 key1;
  uint64 key2;
  struct TBEntry *entry;
 };
 #endif
@@ -0,0 +1,831 @@
 /*
  Copyright (c) 2013 Ronald de Man
  This file may be redistributed and/or modified without restrictions.
  tbprobe.cpp contains the Stockfish-specific routines of the
  tablebase probing code. It should be relatively easy to adapt
  this code to other chess engines.
 */
 #include <algorithm>
 #include "../position.h"
 #include "../movegen.h"
 #include "../bitboard.h"
 #include "../search.h"
 #include "../bitcount.h"
 #include "tbprobe.h"
 #include "tbcore.h"
 #include "tbcore.cpp"
 namespace Zobrist {
  extern Key psq[COLOR_NB][PIECE_TYPE_NB][SQUARE_NB];
 }
 int Tablebases::MaxCardinality = 0;
 // Given a position with 6 or fewer pieces, produce a text string
 // of the form KQPvKRP, where "KQP" represents the white pieces if
 // mirror == 0 and the black pieces if mirror == 1.
 static void prt_str(Position& pos, char *str, int mirror)
 {
  Color color;
  PieceType pt;
  int i;
  color = !mirror ? WHITE : BLACK;
  for (pt = KING; pt >= PAWN; --pt)
    for (i = popcount<Max15>(pos.pieces(color, pt)); i > 0; i--)
      *str++ = pchr[6 - pt];
  *str++ = 'v';
  color = ~color;
  for (pt = KING; pt >= PAWN; --pt)
    for (i = popcount<Max15>(pos.pieces(color, pt)); i > 0; i--)
      *str++ = pchr[6 - pt];
  *str++ = 0;
 }
 // Given a position, produce a 64-bit material signature key.
 // If the engine supports such a key, it should equal the engine's key.
 static uint64 calc_key(Position& pos, int mirror)
 {
  Color color;
  PieceType pt;
  int i;
  uint64 key = 0;
  color = !mirror ? WHITE : BLACK;
  for (pt = PAWN; pt <= KING; ++pt)
    for (i = popcount<Max15>(pos.pieces(color, pt)); i > 0; i--)
      key ^= Zobrist::psq[WHITE][pt][i - 1];
  color = ~color;
  for (pt = PAWN; pt <= KING; ++pt)
    for (i = popcount<Max15>(pos.pieces(color, pt)); i > 0; i--)
      key ^= Zobrist::psq[BLACK][pt][i - 1];
  return key;
 }
 // Produce a 64-bit material key corresponding to the material combination
 // defined by pcs[16], where pcs[1], ..., pcs[6] is the number of white
 // pawns, ..., kings and pcs[9], ..., pcs[14] is the number of black
 // pawns, ..., kings.
 static uint64 calc_key_from_pcs(int *pcs, int mirror)
 {
  int color;
  PieceType pt;
  int i;
  uint64 key = 0;
  color = !mirror ? 0 : 8;
  for (pt = PAWN; pt <= KING; ++pt)
    for (i = 0; i < pcs[color + pt]; i++)
      key ^= Zobrist::psq[WHITE][pt][i];
  color ^= 8;
  for (pt = PAWN; pt <= KING; ++pt)
    for (i = 0; i < pcs[color + pt]; i++)
      key ^= Zobrist::psq[BLACK][pt][i];
  return key;
 }
 bool is_little_endian() {
  union {
    int i;
    char c[sizeof(int)];
  } x;
  x.i = 1;
  return x.c[0] == 1;
 }
 static ubyte decompress_pairs(struct PairsData *d, uint64 idx)
 {
  static const bool isLittleEndian = is_little_endian();
  return isLittleEndian ? decompress_pairs<true >(d, idx)
                        : decompress_pairs<false>(d, idx);
 }
 // probe_wdl_table and probe_dtz_table require similar adaptations.
 static int probe_wdl_table(Position& pos, int *success)
 {
  struct TBEntry *ptr;
  struct TBHashEntry *ptr2;
  uint64 idx;
  uint64 key;
  int i;
  ubyte res;
  int p[TBPIECES];
  // Obtain the position's material signature key.
  key = pos.material_key();
  // Test for KvK.
  if (key == (Zobrist::psq[WHITE][KING][0] ^ Zobrist::psq[BLACK][KING][0]))
    return 0;
  ptr2 = TB_hash[key >> (64 - TBHASHBITS)];
  for (i = 0; i < HSHMAX; i++)
    if (ptr2[i].key == key) break;
  if (i == HSHMAX) {
    *success = 0;
    return 0;
  }
  ptr = ptr2[i].ptr;
  if (!ptr->ready) {
    LOCK(TB_mutex);
    if (!ptr->ready) {
      char str[16];
      prt_str(pos, str, ptr->key != key);
      if (!init_table_wdl(ptr, str)) {
        ptr2[i].key = 0ULL;
        *success = 0;
        UNLOCK(TB_mutex);
        return 0;
      }
      // Memory barrier to ensure ptr->ready = 1 is not reordered.
 #ifdef _MSC_VER
      _ReadWriteBarrier();
 #else
      __asm__ __volatile__ ("" ::: "memory");
 #endif
      ptr->ready = 1;
    }
    UNLOCK(TB_mutex);
  }
  int bside, mirror, cmirror;
  if (!ptr->symmetric) {
    if (key != ptr->key) {
      cmirror = 8;
      mirror = 0x38;
      bside = (pos.side_to_move() == WHITE);
    } else {
      cmirror = mirror = 0;
      bside = !(pos.side_to_move() == WHITE);
    }
  } else {
    cmirror = pos.side_to_move() == WHITE ? 0 : 8;
    mirror = pos.side_to_move() == WHITE ? 0 : 0x38;
    bside = 0;
  }
  // p[i] is to contain the square 0-63 (A1-H8) for a piece of type
  // pc[i] ^ cmirror, where 1 = white pawn, ..., 14 = black king.
  // Pieces of the same type are guaranteed to be consecutive.
  if (!ptr->has_pawns) {
    struct TBEntry_piece *entry = (struct TBEntry_piece *)ptr;
    ubyte *pc = entry->pieces[bside];
    for (i = 0; i < entry->num;) {
      Bitboard bb = pos.pieces((Color)((pc[i] ^ cmirror) >> 3),
                                      (PieceType)(pc[i] & 0x07));
      do {
        p[i++] = pop_lsb(&bb);
      } while (bb);
    }
    idx = encode_piece(entry, entry->norm[bside], p, entry->factor[bside]);
    res = decompress_pairs(entry->precomp[bside], idx);
  } else {
    struct TBEntry_pawn *entry = (struct TBEntry_pawn *)ptr;
    int k = entry->file[0].pieces[0][0] ^ cmirror;
    Bitboard bb = pos.pieces((Color)(k >> 3), (PieceType)(k & 0x07));
    i = 0;
    do {
      p[i++] = pop_lsb(&bb) ^ mirror;
    } while (bb);
    int f = pawn_file(entry, p);
    ubyte *pc = entry->file[f].pieces[bside];
    for (; i < entry->num;) {
      bb = pos.pieces((Color)((pc[i] ^ cmirror) >> 3),
                                    (PieceType)(pc[i] & 0x07));
      do {
        p[i++] = pop_lsb(&bb) ^ mirror;
      } while (bb);
    }
    idx = encode_pawn(entry, entry->file[f].norm[bside], p, entry->file[f].factor[bside]);
    res = decompress_pairs(entry->file[f].precomp[bside], idx);
  }
  return ((int)res) - 2;
 }
 static int probe_dtz_table(Position& pos, int wdl, int *success)
 {
  struct TBEntry *ptr;
  uint64 idx;
  int i, res;
  int p[TBPIECES];
  // Obtain the position's material signature key.
  uint64 key = pos.material_key();
  if (DTZ_table[0].key1 != key && DTZ_table[0].key2 != key) {
    for (i = 1; i < DTZ_ENTRIES; i++)
      if (DTZ_table[i].key1 == key) break;
    if (i < DTZ_ENTRIES) {
      struct DTZTableEntry table_entry = DTZ_table[i];
      for (; i > 0; i--)
        DTZ_table[i] = DTZ_table[i - 1];
      DTZ_table[0] = table_entry;
    } else {
      struct TBHashEntry *ptr2 = TB_hash[key >> (64 - TBHASHBITS)];
      for (i = 0; i < HSHMAX; i++)
        if (ptr2[i].key == key) break;
      if (i == HSHMAX) {
        *success = 0;
        return 0;
      }
      ptr = ptr2[i].ptr;
      char str[16];
      int mirror = (ptr->key != key);
      prt_str(pos, str, mirror);
      if (DTZ_table[DTZ_ENTRIES - 1].entry)
        free_dtz_entry(DTZ_table[DTZ_ENTRIES-1].entry);
      for (i = DTZ_ENTRIES - 1; i > 0; i--)
        DTZ_table[i] = DTZ_table[i - 1];
      load_dtz_table(str, calc_key(pos, mirror), calc_key(pos, !mirror));
    }
  }
  ptr = DTZ_table[0].entry;
  if (!ptr) {
    *success = 0;
    return 0;
  }
  int bside, mirror, cmirror;
  if (!ptr->symmetric) {
    if (key != ptr->key) {
      cmirror = 8;
      mirror = 0x38;
      bside = (pos.side_to_move() == WHITE);
    } else {
      cmirror = mirror = 0;
      bside = !(pos.side_to_move() == WHITE);
    }
  } else {
    cmirror = pos.side_to_move() == WHITE ? 0 : 8;
    mirror = pos.side_to_move() == WHITE ? 0 : 0x38;
    bside = 0;
  }
  if (!ptr->has_pawns) {
    struct DTZEntry_piece *entry = (struct DTZEntry_piece *)ptr;
    if ((entry->flags & 1) != bside && !entry->symmetric) {
      *success = -1;
      return 0;
    }
    ubyte *pc = entry->pieces;
    for (i = 0; i < entry->num;) {
      Bitboard bb = pos.pieces((Color)((pc[i] ^ cmirror) >> 3),
                                    (PieceType)(pc[i] & 0x07));
      do {
        p[i++] = pop_lsb(&bb);
      } while (bb);
    }
    idx = encode_piece((struct TBEntry_piece *)entry, entry->norm, p, entry->factor);
    res = decompress_pairs(entry->precomp, idx);
    if (entry->flags & 2)
      res = entry->map[entry->map_idx[wdl_to_map[wdl + 2]] + res];
    if (!(entry->flags & pa_flags[wdl + 2]) || (wdl & 1))
      res *= 2;
  } else {
    struct DTZEntry_pawn *entry = (struct DTZEntry_pawn *)ptr;
    int k = entry->file[0].pieces[0] ^ cmirror;
    Bitboard bb = pos.pieces((Color)(k >> 3), (PieceType)(k & 0x07));
    i = 0;
    do {
      p[i++] = pop_lsb(&bb) ^ mirror;
    } while (bb);
    int f = pawn_file((struct TBEntry_pawn *)entry, p);
    if ((entry->flags[f] & 1) != bside) {
      *success = -1;
      return 0;
    }
    ubyte *pc = entry->file[f].pieces;
    for (; i < entry->num;) {
      bb = pos.pieces((Color)((pc[i] ^ cmirror) >> 3),
                            (PieceType)(pc[i] & 0x07));
      do {
        p[i++] = pop_lsb(&bb) ^ mirror;
      } while (bb);
    }
    idx = encode_pawn((struct TBEntry_pawn *)entry, entry->file[f].norm, p, entry->file[f].factor);
    res = decompress_pairs(entry->file[f].precomp, idx);
    if (entry->flags[f] & 2)
      res = entry->map[entry->map_idx[f][wdl_to_map[wdl + 2]] + res];
    if (!(entry->flags[f] & pa_flags[wdl + 2]) || (wdl & 1))
      res *= 2;
  }
  return res;
 }
 // Add underpromotion captures to list of captures.
 static ExtMove *add_underprom_caps(Position& pos, ExtMove *stack, ExtMove *end)
 {
  ExtMove *moves, *extra = end;
  for (moves = stack; moves < end; moves++) {
    Move move = moves->move;
    if (type_of(move) == PROMOTION && !pos.empty(to_sq(move))) {
      (*extra++).move = (Move)(move - (1 << 12));
      (*extra++).move = (Move)(move - (2 << 12));
      (*extra++).move = (Move)(move - (3 << 12));
    }
  }
  return extra;
 }
 static int probe_ab(Position& pos, int alpha, int beta, int *success)
 {
  int v;
  ExtMove stack[64];
  ExtMove *moves, *end;
  StateInfo st;
  // Generate (at least) all legal non-ep captures including (under)promotions.
  // It is OK to generate more, as long as they are filtered out below.
  if (!pos.checkers()) {
    end = generate<CAPTURES>(pos, stack);
    // Since underpromotion captures are not included, we need to add them.
    end = add_underprom_caps(pos, stack, end);
  } else
    end = generate<EVASIONS>(pos, stack);
  CheckInfo ci(pos);
  for (moves = stack; moves < end; moves++) {
    Move capture = moves->move;
    if (!pos.capture(capture) || type_of(capture) == ENPASSANT
                        || !pos.legal(capture, ci.pinned))
      continue;
    pos.do_move(capture, st, ci, pos.gives_check(capture, ci));
    v = -probe_ab(pos, -beta, -alpha, success);
    pos.undo_move(capture);
    if (*success == 0) return 0;
    if (v > alpha) {
      if (v >= beta) {
        *success = 2;
        return v;
      }
      alpha = v;
    }
  }
  v = probe_wdl_table(pos, success);
  if (*success == 0) return 0;
  if (alpha >= v) {
    *success = 1 + (alpha > 0);
    return alpha;
  } else {
    *success = 1;
    return v;
  }
 }
 // Probe the WDL table for a particular position.
 // If *success != 0, the probe was successful.
 // The return value is from the point of view of the side to move:
 // -2 : loss
 // -1 : loss, but draw under 50-move rule
 //  0 : draw
 //  1 : win, but draw under 50-move rule
 //  2 : win
 int Tablebases::probe_wdl(Position& pos, int *success)
 {
  int v;
  *success = 1;
  v = probe_ab(pos, -2, 2, success);
  // If en passant is not possible, we are done.
  if (pos.ep_square() == SQ_NONE)
    return v;
  if (!(*success)) return 0;
  // Now handle en passant.
  int v1 = -3;
  // Generate (at least) all legal en passant captures.
  ExtMove stack[192];
  ExtMove *moves, *end;
  StateInfo st;
  if (!pos.checkers())
    end = generate<CAPTURES>(pos, stack);
  else
    end = generate<EVASIONS>(pos, stack);
  CheckInfo ci(pos);
  for (moves = stack; moves < end; moves++) {
    Move capture = moves->move;
    if (type_of(capture) != ENPASSANT
          || !pos.legal(capture, ci.pinned))
      continue;
    pos.do_move(capture, st, ci, pos.gives_check(capture, ci));
    int v0 = -probe_ab(pos, -2, 2, success);
    pos.undo_move(capture);
    if (*success == 0) return 0;
    if (v0 > v1) v1 = v0;
  }
  if (v1 > -3) {
    if (v1 >= v) v = v1;
    else if (v == 0) {
      // Check whether there is at least one legal non-ep move.
      for (moves = stack; moves < end; moves++) {
        Move capture = moves->move;
        if (type_of(capture) == ENPASSANT) continue;
        if (pos.legal(capture, ci.pinned)) break;
      }
      if (moves == end && !pos.checkers()) {
        end = generate<QUIETS>(pos, end);
        for (; moves < end; moves++) {
          Move move = moves->move;
          if (pos.legal(move, ci.pinned))
            break;
        }
      }
      // If not, then we are forced to play the losing ep capture.
      if (moves == end)
        v = v1;
    }
  }
  return v;
 }
 // This routine treats a position with en passant captures as one without.
 static int probe_dtz_no_ep(Position& pos, int *success)
 {
  int wdl, dtz;
  wdl = probe_ab(pos, -2, 2, success);
  if (*success == 0) return 0;
  if (wdl == 0) return 0;
  if (*success == 2)
    return wdl == 2 ? 1 : 101;
  ExtMove stack[192];
  ExtMove *moves, *end = NULL;
  StateInfo st;
  CheckInfo ci(pos);
  if (wdl > 0) {
    // Generate at least all legal non-capturing pawn moves
    // including non-capturing promotions.
    if (!pos.checkers())
      end = generate<NON_EVASIONS>(pos, stack);
    else
      end = generate<EVASIONS>(pos, stack);
    for (moves = stack; moves < end; moves++) {
      Move move = moves->move;
      if (type_of(pos.moved_piece(move)) != PAWN || pos.capture(move)
                || !pos.legal(move, ci.pinned))
        continue;
      pos.do_move(move, st, ci, pos.gives_check(move, ci));
      int v = -probe_ab(pos, -2, -wdl + 1, success);
      pos.undo_move(move);
      if (*success == 0) return 0;
      if (v == wdl)
        return v == 2 ? 1 : 101;
    }
  }
  dtz = 1 + probe_dtz_table(pos, wdl, success);
  if (*success >= 0) {
    if (wdl & 1) dtz += 100;
    return wdl >= 0 ? dtz : -dtz;
  }
  if (wdl > 0) {
    int best = 0xffff;
    for (moves = stack; moves < end; moves++) {
      Move move = moves->move;
      if (pos.capture(move) || type_of(pos.moved_piece(move)) == PAWN
                || !pos.legal(move, ci.pinned))
        continue;
      pos.do_move(move, st, ci, pos.gives_check(move, ci));
      int v = -Tablebases::probe_dtz(pos, success);
      pos.undo_move(move);
      if (*success == 0) return 0;
      if (v > 0 && v + 1 < best)
        best = v + 1;
    }
    return best;
  } else {
    int best = -1;
    if (!pos.checkers())
      end = generate<NON_EVASIONS>(pos, stack);
    else
      end = generate<EVASIONS>(pos, stack);
    for (moves = stack; moves < end; moves++) {
      int v;
      Move move = moves->move;
      if (!pos.legal(move, ci.pinned))
        continue;
      pos.do_move(move, st, ci, pos.gives_check(move, ci));
      if (st.rule50 == 0) {
        if (wdl == -2) v = -1;
        else {
          v = probe_ab(pos, 1, 2, success);
          v = (v == 2) ? 0 : -101;
        }
      } else {
        v = -Tablebases::probe_dtz(pos, success) - 1;
      }
      pos.undo_move(move);
      if (*success == 0) return 0;
      if (v < best)
        best = v;
    }
    return best;
  }
 }
 static int wdl_to_dtz[] = {
  -1, -101, 0, 101, 1
 };
 // Probe the DTZ table for a particular position.
 // If *success != 0, the probe was successful.
 // The return value is from the point of view of the side to move:
 //         n < -100 : loss, but draw under 50-move rule
 // -100 <= n < -1   : loss in n ply (assuming 50-move counter == 0)
 //         0        : draw
 //     1 < n <= 100 : win in n ply (assuming 50-move counter == 0)
 //   100 < n        : win, but draw under 50-move rule
 //
 // The return value n can be off by 1: a return value -n can mean a loss
 // in n+1 ply and a return value +n can mean a win in n+1 ply. This
 // cannot happen for tables with positions exactly on the "edge" of
 // the 50-move rule.
 //
 // This implies that if dtz > 0 is returned, the position is certainly
 // a win if dtz + 50-move-counter <= 99. Care must be taken that the engine
 // picks moves that preserve dtz + 50-move-counter <= 99.
 //
 // If n = 100 immediately after a capture or pawn move, then the position
 // is also certainly a win, and during the whole phase until the next
 // capture or pawn move, the inequality to be preserved is
 // dtz + 50-movecounter <= 100.
 //
 // In short, if a move is available resulting in dtz + 50-move-counter <= 99,
 // then do not accept moves leading to dtz + 50-move-counter == 100.
 //
 int Tablebases::probe_dtz(Position& pos, int *success)
 {
  *success = 1;
  int v = probe_dtz_no_ep(pos, success);
  if (pos.ep_square() == SQ_NONE)
    return v;
  if (*success == 0) return 0;
  // Now handle en passant.
  int v1 = -3;
  ExtMove stack[192];
  ExtMove *moves, *end;
  StateInfo st;
  if (!pos.checkers())
    end = generate<CAPTURES>(pos, stack);
  else
    end = generate<EVASIONS>(pos, stack);
  CheckInfo ci(pos);
  for (moves = stack; moves < end; moves++) {
    Move capture = moves->move;
    if (type_of(capture) != ENPASSANT
                || !pos.legal(capture, ci.pinned))
      continue;
    pos.do_move(capture, st, ci, pos.gives_check(capture, ci));
    int v0 = -probe_ab(pos, -2, 2, success);
    pos.undo_move(capture);
    if (*success == 0) return 0;
    if (v0 > v1) v1 = v0;
  }
  if (v1 > -3) {
    v1 = wdl_to_dtz[v1 + 2];
    if (v < -100) {
      if (v1 >= 0)
        v = v1;
    } else if (v < 0) {
      if (v1 >= 0 || v1 < 100)
        v = v1;
    } else if (v > 100) {
      if (v1 > 0)
        v = v1;
    } else if (v > 0) {
      if (v1 == 1)
        v = v1;
    } else if (v1 >= 0) {
      v = v1;
    } else {
      for (moves = stack; moves < end; moves++) {
        Move move = moves->move;
        if (type_of(move) == ENPASSANT) continue;
        if (pos.legal(move, ci.pinned)) break;
      }
      if (moves == end && !pos.checkers()) {
        end = generate<QUIETS>(pos, end);
        for (; moves < end; moves++) {
          Move move = moves->move;
          if (pos.legal(move, ci.pinned))
            break;
        }
      }
      if (moves == end)
        v = v1;
    }
  }
  return v;
 }
 // Check whether there has been at least one repetition of positions
 // since the last capture or pawn move.
 static int has_repeated(StateInfo *st)
 {
  while (1) {
    int i = 4, e = std::min(st->rule50, st->pliesFromNull);
    if (e < i)
      return 0;
    StateInfo *stp = st->previous->previous;
    do {
      stp = stp->previous->previous;
      if (stp->key == st->key)
        return 1;
      i += 2;
    } while (i <= e);
    st = st->previous;
  }
 }
 static Value wdl_to_Value[5] = {
  -VALUE_MATE + MAX_PLY + 1,
  VALUE_DRAW - 2,
  VALUE_DRAW,
  VALUE_DRAW + 2,
  VALUE_MATE - MAX_PLY - 1
 };
 // Use the DTZ tables to filter out moves that don't preserve the win or draw.
 // If the position is lost, but DTZ is fairly high, only keep moves that
 // maximise DTZ.
 //
 // A return value false indicates that not all probes were successful and that
 // no moves were filtered out.
 bool Tablebases::root_probe(Position& pos, Search::RootMoveVector& rootMoves, Value& score)
 {
  int success;
  int dtz = probe_dtz(pos, &success);
  if (!success) return false;
  StateInfo st;
  CheckInfo ci(pos);
  // Probe each move.
  for (size_t i = 0; i < rootMoves.size(); i++) {
    Move move = rootMoves[i].pv[0];
    pos.do_move(move, st, ci, pos.gives_check(move, ci));
    int v = 0;
    if (pos.checkers() && dtz > 0) {
      ExtMove s[192];
      if (generate<LEGAL>(pos, s) == s)
        v = 1;
    }
    if (!v) {
      if (st.rule50 != 0) {
        v = -Tablebases::probe_dtz(pos, &success);
        if (v > 0) v++;
        else if (v < 0) v--;
      } else {
        v = -Tablebases::probe_wdl(pos, &success);
        v = wdl_to_dtz[v + 2];
      }
    }
    pos.undo_move(move);
    if (!success) return false;
    rootMoves[i].score = (Value)v;
  }
  // Obtain 50-move counter for the root position.
  // In Stockfish there seems to be no clean way, so we do it like this:
  int cnt50 = st.previous->rule50;
  // Use 50-move counter to determine whether the root position is
  // won, lost or drawn.
  int wdl = 0;
  if (dtz > 0)
    wdl = (dtz + cnt50 <= 100) ? 2 : 1;
  else if (dtz < 0)
    wdl = (-dtz + cnt50 <= 100) ? -2 : -1;
  // Determine the score to report to the user.
  score = wdl_to_Value[wdl + 2];
  // If the position is winning or losing, but too few moves left, adjust the
  // score to show how close it is to winning or losing.
  // NOTE: int(PawnValueEg) is used as scaling factor in score_to_uci().
  if (wdl == 1 && dtz <= 100)
    score = (Value)(((200 - dtz - cnt50) * int(PawnValueEg)) / 200);
  else if (wdl == -1 && dtz >= -100)
    score = -(Value)(((200 + dtz - cnt50) * int(PawnValueEg)) / 200);
  // Now be a bit smart about filtering out moves.
  size_t j = 0;
  if (dtz > 0) { // winning (or 50-move rule draw)
    int best = 0xffff;
    for (size_t i = 0; i < rootMoves.size(); i++) {
      int v = rootMoves[i].score;
      if (v > 0 && v < best)
        best = v;
    }
    int max = best;
    // If the current phase has not seen repetitions, then try all moves
    // that stay safely within the 50-move budget, if there are any.
    if (!has_repeated(st.previous) && best + cnt50 <= 99)
      max = 99 - cnt50;
    for (size_t i = 0; i < rootMoves.size(); i++) {
      int v = rootMoves[i].score;
      if (v > 0 && v <= max)
        rootMoves[j++] = rootMoves[i];
    }
  } else if (dtz < 0) { // losing (or 50-move rule draw)
    int best = 0;
    for (size_t i = 0; i < rootMoves.size(); i++) {
      int v = rootMoves[i].score;
      if (v < best)
        best = v;
    }
    // Try all moves, unless we approach or have a 50-move rule draw.
    if (-best * 2 + cnt50 < 100)
      return true;
    for (size_t i = 0; i < rootMoves.size(); i++) {
      if (rootMoves[i].score == best)
        rootMoves[j++] = rootMoves[i];
    }
  } else { // drawing
    // Try all moves that preserve the draw.
    for (size_t i = 0; i < rootMoves.size(); i++) {
      if (rootMoves[i].score == 0)
        rootMoves[j++] = rootMoves[i];
    }
  }
  rootMoves.resize(j, Search::RootMove(MOVE_NONE));
  return true;
 }
 // Use the WDL tables to filter out moves that don't preserve the win or draw.
 // This is a fallback for the case that some or all DTZ tables are missing.
 //
 // A return value false indicates that not all probes were successful and that
 // no moves were filtered out.
 bool Tablebases::root_probe_wdl(Position& pos, Search::RootMoveVector& rootMoves, Value& score)
 {
  int success;
  int wdl = Tablebases::probe_wdl(pos, &success);
  if (!success) return false;
  score = wdl_to_Value[wdl + 2];
  StateInfo st;
  CheckInfo ci(pos);
  int best = -2;
  // Probe each move.
  for (size_t i = 0; i < rootMoves.size(); i++) {
    Move move = rootMoves[i].pv[0];
    pos.do_move(move, st, ci, pos.gives_check(move, ci));
    int v = -Tablebases::probe_wdl(pos, &success);
    pos.undo_move(move);
    if (!success) return false;
    rootMoves[i].score = (Value)v;
    if (v > best)
      best = v;
  }
  size_t j = 0;
  for (size_t i = 0; i < rootMoves.size(); i++) {
    if (rootMoves[i].score == best)
      rootMoves[j++] = rootMoves[i];
  }
  rootMoves.resize(j, Search::RootMove(MOVE_NONE));
  return true;
 }
@@ -0,0 +1,18 @@
 #ifndef TBPROBE_H
 #define TBPROBE_H
 #include "../search.h"
 namespace Tablebases {
 extern int MaxCardinality;
 void init(const std::string& path);
 int probe_wdl(Position& pos, int *success);
 int probe_dtz(Position& pos, int *success);
 bool root_probe(Position& pos, Search::RootMoveVector& rootMoves, Value& score);
 bool root_probe_wdl(Position& pos, Search::RootMoveVector& rootMoves, Value& score);
 }
 #endif
@@ -1,7 +1,7 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
@@ -17,329 +17,369 @@
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
-#include <iostream>
+#include <algorithm> // For std::count
 #include <cassert>
 #include "movegen.h"
 #include "search.h"
 #include "thread.h"
-#include "ucioption.h"
+#include "uci.h"
-ThreadsManager Threads; // Global object definition
+using namespace Search;
-namespace { extern "C" {
+ThreadPool Threads; // Global object
 extern void check_time();
 namespace {
 // start_routine() is the C function which is called when a new thread
- // is launched. It simply calls idle_loop() with the supplied threadID.
+ // is launched. It is a wrapper to the virtual function idle_loop().
 // There are two versions of this function; one for POSIX threads and
 // one for Windows threads.
-#if defined(_MSC_VER)
+ extern "C" { long start_routine(ThreadBase* th) { th->idle_loop(); return 0; } }
  DWORD WINAPI start_routine(LPVOID threadID) {
    Threads.idle_loop(*(int*)threadID, NULL);
    return 0;
  }
 #else
  void* start_routine(void* threadID) {
    Threads.idle_loop(*(int*)threadID, NULL);
    return NULL;
  }
 #endif
 } }
-// wake_up() wakes up the thread, normally at the beginning of the search or,
+ // Helpers to launch a thread after creation and joining before delete. Must be
-// if "sleeping threads" is used, when there is some work to do.
+ // outside Thread c'tor and d'tor because the object must be fully initialized
 // when start_routine (and hence virtual idle_loop) is called and when joining.
-void Thread::wake_up() {
+ template<typename T> T* new_thread() {
   T* th = new T();
   thread_create(th->handle, start_routine, th); // Will go to sleep
   return th;
 }
 void delete_thread(ThreadBase* th) {
   th->mutex.lock();
   th->exit = true; // Search must be already finished
   th->mutex.unlock();
   th->notify_one();
   thread_join(th->handle); // Wait for thread termination
   delete th;
 }
  lock_grab(&sleepLock);
  cond_signal(&sleepCond);
  lock_release(&sleepLock);
 }
-// cutoff_occurred() checks whether a beta cutoff has occurred in
+// ThreadBase::notify_one() wakes up the thread when there is some work to do
-// the thread's currently active split point, or in some ancestor of
+
-// the current split point.
+void ThreadBase::notify_one() {
  mutex.lock();
  sleepCondition.notify_one();
  mutex.unlock();
 }
 // ThreadBase::wait_for() set the thread to sleep until 'condition' turns true
 void ThreadBase::wait_for(volatile const bool& condition) {
  mutex.lock();
  while (!condition) sleepCondition.wait(mutex);
  mutex.unlock();
 }
 // Thread c'tor makes some init but does not launch any execution thread that
 // will be started only when c'tor returns.
 Thread::Thread() /* : splitPoints() */ { // Initialization of non POD broken in MSVC
  searching = false;
  maxPly = splitPointsSize = 0;
  activeSplitPoint = NULL;
  activePosition = NULL;
  idx = Threads.size(); // Starts from 0
 }
 // Thread::cutoff_occurred() checks whether a beta cutoff has occurred in the
 // current active split point, or in some ancestor of the split point.
 bool Thread::cutoff_occurred() const {
-  for (SplitPoint* sp = splitPoint; sp; sp = sp->parent)
+  for (SplitPoint* sp = activeSplitPoint; sp; sp = sp->parentSplitPoint)
-      if (sp->is_betaCutoff)
+      if (sp->cutoff)
          return true;
  return false;
 }
-// is_available_to() checks whether the thread is available to help the thread with
+// Thread::available_to() checks whether the thread is available to help the
-// threadID "master" at a split point. An obvious requirement is that thread must be
+// thread 'master' at a split point. An obvious requirement is that thread must
-// idle. With more than two threads, this is not by itself sufficient: If the thread
+// be idle. With more than two threads, this is not sufficient: If the thread is
-// is the master of some active split point, it is only available as a slave to the
+// the master of some split point, it is only available as a slave to the slaves
-// threads which are busy searching the split point at the top of "slave"'s split
+// which are busy searching the split point at the top of slave's split point
-// point stack (the "helpful master concept" in YBWC terminology).
+// stack (the "helpful master concept" in YBWC terminology).
-bool Thread::is_available_to(int master) const {
+bool Thread::available_to(const Thread* master) const {
-  if (state != AVAILABLE)
+  if (searching)
      return false;
-  // Make a local copy to be sure doesn't become zero under our feet while
+  // Make a local copy to be sure it doesn't become zero under our feet while
-  // testing next condition and so leading to an out of bound access.
+  // testing next condition and so leading to an out of bounds access.
-  int localActiveSplitPoints = activeSplitPoints;
+  const int size = splitPointsSize;
-  // No active split points means that the thread is available as a slave for any
+  // No split points means that the thread is available as a slave for any
  // other thread otherwise apply the "helpful master" concept if possible.
-  if (   !localActiveSplitPoints
+  return !size || splitPoints[size - 1].slavesMask.test(master->idx);
      || splitPoints[localActiveSplitPoints - 1].is_slave[master])
      return true;
  return false;
 }
-// read_uci_options() updates number of active threads and other internal
+// Thread::split() does the actual work of distributing the work at a node between
-// parameters according to the UCI options values. It is called before
+// several available threads. If it does not succeed in splitting the node
-// to start a new search.
+// (because no idle threads are available), the function immediately returns.
 // If splitting is possible, a SplitPoint object is initialized with all the
 // data that must be copied to the helper threads and then helper threads are
 // informed that they have been assigned work. This will cause them to instantly
 // leave their idle loops and call search(). When all threads have returned from
 // search() then split() returns.
-void ThreadsManager::read_uci_options() {
+void Thread::split(Position& pos, Stack* ss, Value alpha, Value beta, Value* bestValue,
                   Move* bestMove, Depth depth, int moveCount,
                   MovePicker* movePicker, int nodeType, bool cutNode) {
-  maxThreadsPerSplitPoint = Options["Maximum Number of Threads per Split Point"].value<int>();
+  assert(searching);
-  minimumSplitDepth       = Options["Minimum Split Depth"].value<int>() * ONE_PLY;
+  assert(-VALUE_INFINITE < *bestValue && *bestValue <= alpha && alpha < beta && beta <= VALUE_INFINITE);
-  useSleepingThreads      = Options["Use Sleeping Threads"].value<bool>();
+  assert(depth >= Threads.minimumSplitDepth);
-  activeThreads           = Options["Threads"].value<int>();
+  assert(splitPointsSize < MAX_SPLITPOINTS_PER_THREAD);
 }
  // Pick and init the next available split point
  SplitPoint& sp = splitPoints[splitPointsSize];
-// init() is called during startup. Initializes locks and condition variables
+  sp.masterThread = this;
-// and launches all threads sending them immediately to sleep.
+  sp.parentSplitPoint = activeSplitPoint;
  sp.slavesMask = 0, sp.slavesMask.set(idx);
  sp.depth = depth;
  sp.bestValue = *bestValue;
  sp.bestMove = *bestMove;
  sp.alpha = alpha;
  sp.beta = beta;
  sp.nodeType = nodeType;
  sp.cutNode = cutNode;
  sp.movePicker = movePicker;
  sp.moveCount = moveCount;
  sp.pos = &pos;
  sp.nodes = 0;
  sp.cutoff = false;
  sp.ss = ss;
-void ThreadsManager::init() {
+  // Try to allocate available threads and ask them to start searching setting
  // 'searching' flag. This must be done under lock protection to avoid concurrent
  // allocation of the same slave by another master.
  Threads.mutex.lock();
  sp.mutex.lock();
-  int threadID[MAX_THREADS];
+  sp.allSlavesSearching = true; // Must be set under lock protection
  ++splitPointsSize;
  activeSplitPoint = &sp;
  activePosition = NULL;
-  // This flag is needed to properly end the threads when program exits
+  Thread* slave;
  allThreadsShouldExit = false;
-  // Threads will sent to sleep as soon as created, only main thread is kept alive
+  while ((slave = Threads.available_slave(this)) != NULL)
  activeThreads = 1;
  threads[0].state = Thread::SEARCHING;
  // Allocate pawn and material hash tables for main thread
  init_hash_tables();
  lock_init(&mpLock);
  // Initialize thread and split point locks
  for (int i = 0; i < MAX_THREADS; i++)
  {
-      lock_init(&threads[i].sleepLock);
+      sp.slavesMask.set(slave->idx);
-      cond_init(&threads[i].sleepCond);
+      slave->activeSplitPoint = &sp;
-
+      slave->searching = true; // Slave leaves idle_loop()
-      for (int j = 0; j < MAX_ACTIVE_SPLIT_POINTS; j++)
+      slave->notify_one(); // Could be sleeping
          lock_init(&(threads[i].splitPoints[j].lock));
  }
-  // Create and startup all the threads but the main that is already running
+  // Everything is set up. The master thread enters the idle loop, from which
-  for (int i = 1; i < MAX_THREADS; i++)
+  // it will instantly launch a search, because its 'searching' flag is set.
-  {
+  // The thread will return from the idle loop when all slaves have finished
-      threads[i].state = Thread::INITIALIZING;
+  // their work at this split point.
-      threadID[i] = i;
+  sp.mutex.unlock();
  Threads.mutex.unlock();
-#if defined(_MSC_VER)
+  Thread::idle_loop(); // Force a call to base class idle_loop()
      bool ok = (CreateThread(NULL, 0, start_routine, (LPVOID)&threadID[i], 0, NULL) != NULL);
 #else
      pthread_t pthreadID;
      bool ok = (pthread_create(&pthreadID, NULL, start_routine, (void*)&threadID[i]) == 0);
      pthread_detach(pthreadID);
 #endif
      if (!ok)
      {
          std::cout << "Failed to create thread number " << i << std::endl;
          ::exit(EXIT_FAILURE);
      }
-      // Wait until the thread has finished launching and is gone to sleep
+  // In the helpful master concept, a master can help only a sub-tree of its
-      while (threads[i].state == Thread::INITIALIZING) {}
+  // split point and because everything is finished here, it's not possible
-  }
+  // for the master to be booked.
-}
+  assert(!searching);
-
+  assert(!activePosition);
 // exit() is called to cleanly exit the threads when the program finishes
 void ThreadsManager::exit() {
  // Force the woken up threads to exit idle_loop() and hence terminate
  allThreadsShouldExit = true;
  for (int i = 0; i < MAX_THREADS; i++)
  {
      // Wake up all the threads and waits for termination
      if (i != 0)
      {
          threads[i].wake_up();
          while (threads[i].state != Thread::TERMINATED) {}
      }
      // Now we can safely destroy the locks and wait conditions
      lock_destroy(&threads[i].sleepLock);
      cond_destroy(&threads[i].sleepCond);
      for (int j = 0; j < MAX_ACTIVE_SPLIT_POINTS; j++)
          lock_destroy(&(threads[i].splitPoints[j].lock));
  }
  lock_destroy(&mpLock);
 }
 // init_hash_tables() dynamically allocates pawn and material hash tables
 // according to the number of active threads. This avoids preallocating
 // memory for all possible threads if only few are used as, for instance,
 // on mobile devices where memory is scarce and allocating for MAX_THREADS
 // threads could even result in a crash.
 void ThreadsManager::init_hash_tables() {
  for (int i = 0; i < activeThreads; i++)
  {
      threads[i].pawnTable.init();
      threads[i].materialTable.init();
  }
 }
 // available_slave_exists() tries to find an idle thread which is available as
 // a slave for the thread with threadID "master".
 bool ThreadsManager::available_slave_exists(int master) const {
  assert(master >= 0 && master < activeThreads);
  for (int i = 0; i < activeThreads; i++)
      if (i != master && threads[i].is_available_to(master))
          return true;
  return false;
 }
 // split() does the actual work of distributing the work at a node between
 // several available threads. If it does not succeed in splitting the
 // node (because no idle threads are available, or because we have no unused
 // split point objects), the function immediately returns. If splitting is
 // possible, a SplitPoint object is initialized with all the data that must be
 // copied to the helper threads and we tell our helper threads that they have
 // been assigned work. This will cause them to instantly leave their idle loops and
 // call search().When all threads have returned from search() then split() returns.
 template <bool Fake>
 void ThreadsManager::split(Position& pos, SearchStack* ss, Value* alpha, const Value beta,
                           Value* bestValue, Depth depth, Move threatMove,
                           int moveCount, MovePicker* mp, bool pvNode) {
  assert(pos.is_ok());
  assert(*bestValue >= -VALUE_INFINITE);
  assert(*bestValue <= *alpha);
  assert(*alpha < beta);
  assert(beta <= VALUE_INFINITE);
  assert(depth > DEPTH_ZERO);
  assert(pos.thread() >= 0 && pos.thread() < activeThreads);
  assert(activeThreads > 1);
  int i, master = pos.thread();
  Thread& masterThread = threads[master];
  lock_grab(&mpLock);
  // If no other thread is available to help us, or if we have too many
  // active split points, don't split.
  if (   !available_slave_exists(master)
      || masterThread.activeSplitPoints >= MAX_ACTIVE_SPLIT_POINTS)
  {
      lock_release(&mpLock);
      return;
  }
  // Pick the next available split point object from the split point stack
  SplitPoint& splitPoint = masterThread.splitPoints[masterThread.activeSplitPoints++];
  // Initialize the split point object
  splitPoint.parent = masterThread.splitPoint;
  splitPoint.master = master;
  splitPoint.is_betaCutoff = false;
  splitPoint.depth = depth;
  splitPoint.threatMove = threatMove;
  splitPoint.alpha = *alpha;
  splitPoint.beta = beta;
  splitPoint.pvNode = pvNode;
  splitPoint.bestValue = *bestValue;
  splitPoint.mp = mp;
  splitPoint.moveCount = moveCount;
  splitPoint.pos = &pos;
  splitPoint.nodes = 0;
  splitPoint.ss = ss;
  for (i = 0; i < activeThreads; i++)
      splitPoint.is_slave[i] = false;
  masterThread.splitPoint = &splitPoint;
  // If we are here it means we are not available
  assert(masterThread.state != Thread::AVAILABLE);
  int workersCnt = 1; // At least the master is included
  // Allocate available threads setting state to THREAD_BOOKED
  for (i = 0; !Fake && i < activeThreads && workersCnt < maxThreadsPerSplitPoint; i++)
      if (i != master && threads[i].is_available_to(master))
      {
          threads[i].state = Thread::BOOKED;
          threads[i].splitPoint = &splitPoint;
          splitPoint.is_slave[i] = true;
          workersCnt++;
      }
  assert(Fake || workersCnt > 1);
  // We can release the lock because slave threads are already booked and master is not available
  lock_release(&mpLock);
  // Tell the threads that they have work to do. This will make them leave
  // their idle loop.
  for (i = 0; i < activeThreads; i++)
      if (i == master || splitPoint.is_slave[i])
      {
          assert(i == master || threads[i].state == Thread::BOOKED);
          threads[i].state = Thread::WORKISWAITING; // This makes the slave to exit from idle_loop()
          if (useSleepingThreads && i != master)
              threads[i].wake_up();
      }
  // Everything is set up. The master thread enters the idle loop, from
  // which it will instantly launch a search, because its state is
  // THREAD_WORKISWAITING.  We send the split point as a second parameter to the
  // idle loop, which means that the main thread will return from the idle
  // loop when all threads have finished their work at this split point.
  idle_loop(master, &splitPoint);
  // We have returned from the idle loop, which means that all threads are
-  // finished. Update alpha and bestValue, and return.
+  // finished. Note that setting 'searching' and decreasing splitPointsSize must
-  lock_grab(&mpLock);
+  // be done under lock protection to avoid a race with Thread::available_to().
  Threads.mutex.lock();
  sp.mutex.lock();
-  *alpha = splitPoint.alpha;
+  searching = true;
-  *bestValue = splitPoint.bestValue;
+  --splitPointsSize;
-  masterThread.activeSplitPoints--;
+  activeSplitPoint = sp.parentSplitPoint;
-  masterThread.splitPoint = splitPoint.parent;
+  activePosition = &pos;
-  pos.set_nodes_searched(pos.nodes_searched() + splitPoint.nodes);
+  pos.set_nodes_searched(pos.nodes_searched() + sp.nodes);
  *bestMove = sp.bestMove;
  *bestValue = sp.bestValue;
-  lock_release(&mpLock);
+  sp.mutex.unlock();
  Threads.mutex.unlock();
 }
-// Explicit template instantiations
+
-template void ThreadsManager::split<false>(Position&, SearchStack*, Value*, const Value, Value*, Depth, Move, int, MovePicker*, bool);
+// TimerThread::idle_loop() is where the timer thread waits Resolution milliseconds
-template void ThreadsManager::split<true>(Position&, SearchStack*, Value*, const Value, Value*, Depth, Move, int, MovePicker*, bool);
+// and then calls check_time(). When not searching, thread sleeps until it's woken up.
 void TimerThread::idle_loop() {
  while (!exit)
  {
      mutex.lock();
      if (!exit)
          sleepCondition.wait_for(mutex, run ? Resolution : INT_MAX);
      mutex.unlock();
      if (run)
          check_time();
  }
 }
 // MainThread::idle_loop() is where the main thread is parked waiting to be started
 // when there is a new search. The main thread will launch all the slave threads.
 void MainThread::idle_loop() {
  while (!exit)
  {
      mutex.lock();
      thinking = false;
      while (!thinking && !exit)
      {
          Threads.sleepCondition.notify_one(); // Wake up the UI thread if needed
          sleepCondition.wait(mutex);
      }
      mutex.unlock();
      if (!exit)
      {
          searching = true;
          Search::think();
          assert(searching);
          searching = false;
      }
  }
 }
 // ThreadPool::init() is called at startup to create and launch requested threads,
 // that will go immediately to sleep. We cannot use a c'tor because Threads is a
 // static object and we need a fully initialized engine at this point due to
 // allocation of Endgames in Thread c'tor.
 void ThreadPool::init() {
  timer = new_thread<TimerThread>();
  push_back(new_thread<MainThread>());
  read_uci_options();
 }
 // ThreadPool::exit() terminates the threads before the program exits. Cannot be
 // done in d'tor because threads must be terminated before freeing us.
 void ThreadPool::exit() {
  delete_thread(timer); // As first because check_time() accesses threads data
  for (iterator it = begin(); it != end(); ++it)
      delete_thread(*it);
 }
 // ThreadPool::read_uci_options() updates internal threads parameters from the
 // corresponding UCI options and creates/destroys threads to match the requested
 // number. Thread objects are dynamically allocated to avoid creating all possible
 // threads in advance (which include pawns and material tables), even if only a
 // few are to be used.
 void ThreadPool::read_uci_options() {
  minimumSplitDepth = Options["Min Split Depth"] * ONE_PLY;
  size_t requested  = Options["Threads"];
  assert(requested > 0);
  // If zero (default) then set best minimum split depth automatically
  if (!minimumSplitDepth)
      minimumSplitDepth = requested < 8 ? 4 * ONE_PLY : 7 * ONE_PLY;
  while (size() < requested)
      push_back(new_thread<Thread>());
  while (size() > requested)
  {
      delete_thread(back());
      pop_back();
  }
 }
 // ThreadPool::available_slave() tries to find an idle thread which is available
 // as a slave for the thread 'master'.
 Thread* ThreadPool::available_slave(const Thread* master) const {
  for (const_iterator it = begin(); it != end(); ++it)
      if ((*it)->available_to(master))
          return *it;
  return NULL;
 }
 // ThreadPool::wait_for_think_finished() waits for main thread to finish the search
 void ThreadPool::wait_for_think_finished() {
  MainThread* th = main();
  th->mutex.lock();
  while (th->thinking) sleepCondition.wait(th->mutex);
  th->mutex.unlock();
 }
 // ThreadPool::start_thinking() wakes up the main thread sleeping in
 // MainThread::idle_loop() and starts a new search, then returns immediately.
 void ThreadPool::start_thinking(const Position& pos, const LimitsType& limits,
                                StateStackPtr& states) {
  wait_for_think_finished();
  SearchTime = Time::now(); // As early as possible
  Signals.stopOnPonderhit = Signals.firstRootMove = false;
  Signals.stop = Signals.failedLowAtRoot = false;
  RootMoves.clear();
  RootPos = pos;
  Limits = limits;
  if (states.get()) // If we don't set a new position, preserve current state
  {
      SetupStates = states; // Ownership transfer here
      assert(!states.get());
  }
  for (MoveList<LEGAL> it(pos); *it; ++it)
      if (   limits.searchmoves.empty()
          || std::count(limits.searchmoves.begin(), limits.searchmoves.end(), *it))
          RootMoves.push_back(RootMove(*it));
  main()->thinking = true;
  main()->notify_one(); // Starts main thread
 }
@@ -1,7 +1,7 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
@@ -17,116 +17,170 @@
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
-#if !defined(THREAD_H_INCLUDED)
+#ifndef THREAD_H_INCLUDED
 #define THREAD_H_INCLUDED
-#include <cstring>
+#include <bitset>
 #include <vector>
 #include "lock.h"
 #include "material.h"
 #include "movepick.h"
 #include "pawns.h"
 #include "position.h"
 #include "search.h"
-const int MAX_THREADS = 32;
+struct Thread;
-const int MAX_ACTIVE_SPLIT_POINTS = 8;
+
 const int MAX_THREADS = 128;
 const int MAX_SPLITPOINTS_PER_THREAD = 8;
 /// Mutex and ConditionVariable struct are wrappers of the low level locking
 /// machinery and are modeled after the corresponding C++11 classes.
 struct Mutex {
  Mutex() { lock_init(l); }
 ~Mutex() { lock_destroy(l); }
  void lock() { lock_grab(l); }
  void unlock() { lock_release(l); }
 private:
  friend struct ConditionVariable;
  Lock l;
 };
 struct ConditionVariable {
  ConditionVariable() { cond_init(c); }
 ~ConditionVariable() { cond_destroy(c); }
  void wait(Mutex& m) { cond_wait(c, m.l); }
  void wait_for(Mutex& m, int ms) { timed_wait(c, m.l, ms); }
  void notify_one() { cond_signal(c); }
 private:
  WaitCondition c;
 };
 /// SplitPoint struct stores information shared by the threads searching in
 /// parallel below the same split point. It is populated at splitting time.
 struct SplitPoint {
-  // Const data after splitPoint has been setup
+  // Const data after split point has been setup
  SplitPoint* parent;
  const Position* pos;
  Search::Stack* ss;
  Thread* masterThread;
  Depth depth;
  bool pvNode;
  Value beta;
-  int ply;
+  int nodeType;
-  int master;
+  bool cutNode;
  Move threatMove;
  // Const pointers to shared data
-  MovePicker* mp;
+  MovePicker* movePicker;
-  SearchStack* ss;
+  SplitPoint* parentSplitPoint;
-  // Shared data
+  // Shared variable data
-  Lock lock;
+  Mutex mutex;
-  volatile int64_t nodes;
+  std::bitset<MAX_THREADS> slavesMask;
  volatile bool allSlavesSearching;
  volatile uint64_t nodes;
  volatile Value alpha;
  volatile Value bestValue;
  volatile Move bestMove;
  volatile int moveCount;
-  volatile bool is_betaCutoff;
+  volatile bool cutoff;
  volatile bool is_slave[MAX_THREADS];
 };
-/// Thread struct is used to keep together all the thread related stuff like locks,
+/// ThreadBase struct is the base of the hierarchy from where we derive all the
-/// state and especially split points. We also use per-thread pawn and material hash
+/// specialized thread classes.
 /// tables so that once we get a pointer to an entry its life time is unlimited and
 /// we don't have to care about someone changing the entry under our feet.
-struct Thread {
+struct ThreadBase {
-  enum ThreadState
+  ThreadBase() : handle(NativeHandle()), exit(false) {}
-  {
+  virtual ~ThreadBase() {}
-    INITIALIZING,  // Thread is initializing itself
+  virtual void idle_loop() = 0;
-    SEARCHING,     // Thread is performing work
+  void notify_one();
-    AVAILABLE,     // Thread is waiting for work
+  void wait_for(volatile const bool& b);
    BOOKED,        // Other thread (master) has booked us as a slave
    WORKISWAITING, // Master has ordered us to start
    TERMINATED     // We are quitting and thread is terminated
  };
-  void wake_up();
+  Mutex mutex;
  ConditionVariable sleepCondition;
  NativeHandle handle;
  volatile bool exit;
 };
 /// Thread struct keeps together all the thread related stuff like locks, state
 /// and especially split points. We also use per-thread pawn and material hash
 /// tables so that once we get a pointer to an entry its life time is unlimited
 /// and we don't have to care about someone changing the entry under our feet.
 struct Thread : public ThreadBase {
  Thread();
  virtual void idle_loop();
  bool cutoff_occurred() const;
-  bool is_available_to(int master) const;
+  bool available_to(const Thread* master) const;
-  MaterialInfoTable materialTable;
+  void split(Position& pos, Search::Stack* ss, Value alpha, Value beta, Value* bestValue, Move* bestMove,
-  PawnInfoTable pawnTable;
+             Depth depth, int moveCount, MovePicker* movePicker, int nodeType, bool cutNode);
  SplitPoint splitPoints[MAX_SPLITPOINTS_PER_THREAD];
  Pawns::Table pawnsTable;
  Material::Table materialTable;
  Endgames endgames;
  Position* activePosition;
  size_t idx;
  int maxPly;
-  Lock sleepLock;
+  SplitPoint* volatile activeSplitPoint;
-  WaitCondition sleepCond;
+  volatile int splitPointsSize;
-  volatile ThreadState state;
+  volatile bool searching;
  SplitPoint* volatile splitPoint;
  volatile int activeSplitPoints;
  SplitPoint splitPoints[MAX_ACTIVE_SPLIT_POINTS];
 };
-/// ThreadsManager class is used to handle all the threads related stuff like init,
+/// MainThread and TimerThread are derived classes used to characterize the two
-/// starting, parking and, the most important, launching a slave thread at a split
+/// special threads: the main one and the recurring timer.
 /// point. All the access to shared thread data is done through this class.
-class ThreadsManager {
+struct MainThread : public Thread {
-  /* As long as the single ThreadsManager object is defined as a global we don't
+  MainThread() : thinking(true) {} // Avoid a race with start_thinking()
-     need to explicitly initialize to zero its data members because variables with
+  virtual void idle_loop();
-     static storage duration are automatically set to zero before enter main()
+  volatile bool thinking;
-  */
+};
 public:
  Thread& operator[](int threadID) { return threads[threadID]; }
  void init();
  void exit();
  void init_hash_tables();
-  int min_split_depth() const { return minimumSplitDepth; }
+struct TimerThread : public ThreadBase {
  int size() const { return activeThreads; }
  void set_size(int cnt) { activeThreads = cnt; }
  static const int Resolution = 5; // Millisec between two check_time() calls
  TimerThread() : run(false) {}
  virtual void idle_loop();
  bool run;
 };
 /// ThreadPool struct handles all the threads related stuff like init, starting,
 /// parking and, most importantly, launching a slave thread at a split point.
 /// All the access to shared thread data is done through this class.
 struct ThreadPool : public std::vector<Thread*> {
  void init(); // No c'tor and d'tor, threads rely on globals that should be
  void exit(); // initialized and are valid during the whole thread lifetime.
  MainThread* main() { return static_cast<MainThread*>(at(0)); }
  void read_uci_options();
-  bool available_slave_exists(int master) const;
+  Thread* available_slave(const Thread* master) const;
-  void idle_loop(int threadID, SplitPoint* sp);
+  void wait_for_think_finished();
  void start_thinking(const Position&, const Search::LimitsType&, Search::StateStackPtr&);
  template <bool Fake>
  void split(Position& pos, SearchStack* ss, Value* alpha, const Value beta, Value* bestValue,
             Depth depth, Move threatMove, int moveCount, MovePicker* mp, bool pvNode);
 private:
  Lock mpLock;
  Depth minimumSplitDepth;
-  int maxThreadsPerSplitPoint;
+  Mutex mutex;
-  bool useSleepingThreads;
+  ConditionVariable sleepCondition;
-  int activeThreads;
+  TimerThread* timer;
  volatile bool allThreadsShouldExit;
  Thread threads[MAX_THREADS];
 };
-extern ThreadsManager Threads;
+extern ThreadPool Threads;
-#endif // !defined(THREAD_H_INCLUDED)
+#endif // #ifndef THREAD_H_INCLUDED
@@ -1,7 +1,7 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
@@ -17,145 +17,100 @@
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
 #include <algorithm>
 #include <cfloat>
 #include <cmath>
 #include "misc.h"
 #include "search.h"
 #include "timeman.h"
-#include "ucioption.h"
+#include "uci.h"
 namespace {
  /// Constants
  const int MoveHorizon  = 50;    // Plan time management at most this many moves ahead
  const float MaxRatio   = 3.0f;  // When in trouble, we can step over reserved time with this ratio
  const float StealRatio = 0.33f; // However we must not steal time from remaining moves over this ratio
  // MoveImportance[] is based on naive statistical analysis of "how many games are still undecided
  // after n half-moves". Game is considered "undecided" as long as neither side has >275cp advantage.
  // Data was extracted from CCRL game database with some simple filtering criteria.
  const int MoveImportance[512] = {
    7780, 7780, 7780, 7780, 7780, 7780, 7780, 7780, 7780, 7780, 7780, 7780, 7780, 7780, 7780, 7780,
    7780, 7780, 7780, 7780, 7778, 7778, 7776, 7776, 7776, 7773, 7770, 7768, 7766, 7763, 7757, 7751,
    7743, 7735, 7724, 7713, 7696, 7689, 7670, 7656, 7627, 7605, 7571, 7549, 7522, 7493, 7462, 7425,
    7385, 7350, 7308, 7272, 7230, 7180, 7139, 7094, 7055, 7010, 6959, 6902, 6841, 6778, 6705, 6651,
    6569, 6508, 6435, 6378, 6323, 6253, 6152, 6085, 5995, 5931, 5859, 5794, 5717, 5646, 5544, 5462,
    5364, 5282, 5172, 5078, 4988, 4901, 4831, 4764, 4688, 4609, 4536, 4443, 4365, 4293, 4225, 4155,
    4085, 4005, 3927, 3844, 3765, 3693, 3634, 3560, 3479, 3404, 3331, 3268, 3207, 3146, 3077, 3011,
    2947, 2894, 2828, 2776, 2727, 2676, 2626, 2589, 2538, 2490, 2442, 2394, 2345, 2302, 2243, 2192,
    2156, 2115, 2078, 2043, 2004, 1967, 1922, 1893, 1845, 1809, 1772, 1736, 1702, 1674, 1640, 1605,
    1566, 1536, 1509, 1479, 1452, 1423, 1388, 1362, 1332, 1304, 1289, 1266, 1250, 1228, 1206, 1180,
    1160, 1134, 1118, 1100, 1080, 1068, 1051, 1034, 1012, 1001, 980, 960, 945, 934, 916, 900, 888,
    878, 865, 852, 828, 807, 787, 770, 753, 744, 731, 722, 706, 700, 683, 676, 671, 664, 652, 641,
    634, 627, 613, 604, 591, 582, 568, 560, 552, 540, 534, 529, 519, 509, 495, 484, 474, 467, 460,
    450, 438, 427, 419, 410, 406, 399, 394, 387, 382, 377, 372, 366, 359, 353, 348, 343, 337, 333,
    328, 321, 315, 309, 303, 298, 293, 287, 284, 281, 277, 273, 265, 261, 255, 251, 247, 241, 240,
    235, 229, 218, 217, 213, 212, 208, 206, 197, 193, 191, 189, 185, 184, 180, 177, 172, 170, 170,
    170, 166, 163, 159, 158, 156, 155, 151, 146, 141, 138, 136, 132, 130, 128, 125, 123, 122, 118,
    118, 118, 117, 115, 114, 108, 107, 105, 105, 105, 102, 97, 97, 95, 94, 93, 91, 88, 86, 83, 80,
    80, 79, 79, 79, 78, 76, 75, 72, 72, 71, 70, 68, 65, 63, 61, 61, 59, 59, 59, 58, 56, 55, 54, 54,
    52, 49, 48, 48, 48, 48, 45, 45, 45, 44, 43, 41, 41, 41, 41, 40, 40, 38, 37, 36, 34, 34, 34, 33,
    31, 29, 29, 29, 28, 28, 28, 28, 28, 28, 28, 27, 27, 27, 27, 27, 24, 24, 23, 23, 22, 21, 20, 20,
    19, 19, 19, 19, 19, 18, 18, 18, 18, 17, 17, 17, 17, 17, 16, 16, 15, 15, 14, 14, 14, 12, 12, 11,
    9, 9, 9, 9, 9, 9, 9, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8,
    8, 8, 8, 8, 7, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 5, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4,
    4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 3, 3, 2, 2, 2, 2,
    2, 1, 1, 1, 1, 1, 1, 1 };
  int move_importance(int ply) { return MoveImportance[Min(ply, 511)]; }
  /// Function Prototypes
  enum TimeType { OptimumTime, MaxTime };
-  template<TimeType>
+  const int MoveHorizon   = 50;   // Plan time management at most this many moves ahead
-  int remaining(int myTime, int movesToGo, int currentPly);
+  const double MaxRatio   = 7.0;  // When in trouble, we can step over reserved time with this ratio
-}
+  const double StealRatio = 0.33; // However we must not steal time from remaining moves over this ratio
-void TimeManager::pv_instability(int curChanges, int prevChanges) {
+  // move_importance() is a skew-logistic function based on naive statistical
  // analysis of "how many games are still undecided after n half-moves". Game
  // is considered "undecided" as long as neither side has >275cp advantage.
  // Data was extracted from CCRL game database with some simple filtering criteria.
-    unstablePVExtraTime =  curChanges  * (optimumSearchTime / 2)
+  double move_importance(int ply) {
                         + prevChanges * (optimumSearchTime / 3);
 }
    const double XScale = 9.3;
    const double XShift = 59.8;
    const double Skew   = 0.172;
-void TimeManager::init(const SearchLimits& limits, int currentPly)
+    return pow((1 + exp((ply - XShift) / XScale)), -Skew) + DBL_MIN; // Ensure non-zero
 {
  /* We support four different kind of time controls:
      increment == 0 && movesToGo == 0 means: x basetime  [sudden death!]
      increment == 0 && movesToGo != 0 means: x moves in y minutes
      increment >  0 && movesToGo == 0 means: x basetime + z increment
      increment >  0 && movesToGo != 0 means: x moves in y minutes + z increment
    Time management is adjusted by following UCI parameters:
      emergencyMoveHorizon: Be prepared to always play at least this many moves
      emergencyBaseTime   : Always attempt to keep at least this much time (in ms) at clock
      emergencyMoveTime   : Plus attempt to keep at least this much time for each remaining emergency move
      minThinkingTime     : No matter what, use at least this much thinking before doing the move
  */
  int hypMTG, hypMyTime, t1, t2;
  // Read uci parameters
  int emergencyMoveHorizon = Options["Emergency Move Horizon"].value<int>();
  int emergencyBaseTime    = Options["Emergency Base Time"].value<int>();
  int emergencyMoveTime    = Options["Emergency Move Time"].value<int>();
  int minThinkingTime      = Options["Minimum Thinking Time"].value<int>();
  // Initialize to maximum values but unstablePVExtraTime that is reset
  unstablePVExtraTime = 0;
  optimumSearchTime = maximumSearchTime = limits.time;
  // We calculate optimum time usage for different hypothetic "moves to go"-values and choose the
  // minimum of calculated search time values. Usually the greatest hypMTG gives the minimum values.
  for (hypMTG = 1; hypMTG <= (limits.movesToGo ? Min(limits.movesToGo, MoveHorizon) : MoveHorizon); hypMTG++)
  {
      // Calculate thinking time for hypothetic "moves to go"-value
      hypMyTime =  limits.time
                 + limits.increment * (hypMTG - 1)
                 - emergencyBaseTime
                 - emergencyMoveTime * Min(hypMTG, emergencyMoveHorizon);
      hypMyTime = Max(hypMyTime, 0);
      t1 = minThinkingTime + remaining<OptimumTime>(hypMyTime, hypMTG, currentPly);
      t2 = minThinkingTime + remaining<MaxTime>(hypMyTime, hypMTG, currentPly);
      optimumSearchTime = Min(optimumSearchTime, t1);
      maximumSearchTime = Min(maximumSearchTime, t2);
  }
  if (Options["Ponder"].value<bool>())
      optimumSearchTime += optimumSearchTime / 4;
  // Make sure that maxSearchTime is not over absoluteMaxSearchTime
  optimumSearchTime = Min(optimumSearchTime, maximumSearchTime);
 }
 namespace {
  template<TimeType T>
-  int remaining(int myTime, int movesToGo, int currentPly)
+  int remaining(int myTime, int movesToGo, int ply, int slowMover)
  {
-    const float TMaxRatio   = (T == OptimumTime ? 1 : MaxRatio);
+    const double TMaxRatio   = (T == OptimumTime ? 1 : MaxRatio);
-    const float TStealRatio = (T == OptimumTime ? 0 : StealRatio);
+    const double TStealRatio = (T == OptimumTime ? 0 : StealRatio);
-    int thisMoveImportance = move_importance(currentPly);
+    double moveImportance = (move_importance(ply) * slowMover) / 100;
-    int otherMovesImportance = 0;
+    double otherMovesImportance = 0;
-    for (int i = 1; i < movesToGo; i++)
+    for (int i = 1; i < movesToGo; ++i)
-        otherMovesImportance += move_importance(currentPly + 2 * i);
+        otherMovesImportance += move_importance(ply + 2 * i);
-    float ratio1 = (TMaxRatio * thisMoveImportance) / float(TMaxRatio * thisMoveImportance + otherMovesImportance);
+    double ratio1 = (TMaxRatio * moveImportance) / (TMaxRatio * moveImportance + otherMovesImportance);
-    float ratio2 = (thisMoveImportance + TStealRatio * otherMovesImportance) / float(thisMoveImportance + otherMovesImportance);
+    double ratio2 = (moveImportance + TStealRatio * otherMovesImportance) / (moveImportance + otherMovesImportance);
-    return int(floor(myTime * Min(ratio1, ratio2)));
+    return int(myTime * std::min(ratio1, ratio2)); // Intel C++ asks an explicit cast
  }
 } // namespace
 /// init() is called at the beginning of the search and calculates the allowed
 /// thinking time out of the time control and current game ply. We support four
 /// different kinds of time controls, passed in 'limits':
 ///
 ///  inc == 0 && movestogo == 0 means: x basetime  [sudden death!]
 ///  inc == 0 && movestogo != 0 means: x moves in y minutes
 ///  inc >  0 && movestogo == 0 means: x basetime + z increment
 ///  inc >  0 && movestogo != 0 means: x moves in y minutes + z increment
 void TimeManager::init(const Search::LimitsType& limits, Color us, int ply)
 {
  int minThinkingTime = Options["Minimum Thinking Time"];
  int moveOverhead    = Options["Move Overhead"];
  int slowMover       = Options["Slow Mover"];
  // Initialize unstablePvFactor to 1 and search times to maximum values
  unstablePvFactor = 1;
  optimumSearchTime = maximumSearchTime = std::max(limits.time[us], minThinkingTime);
  const int MaxMTG = limits.movestogo ? std::min(limits.movestogo, MoveHorizon) : MoveHorizon;
  // We calculate optimum time usage for different hypothetical "moves to go"-values
  // and choose the minimum of calculated search time values. Usually the greatest
  // hypMTG gives the minimum values.
  for (int hypMTG = 1; hypMTG <= MaxMTG; ++hypMTG)
  {
      // Calculate thinking time for hypothetical "moves to go"-value
      int hypMyTime =  limits.time[us]
                     + limits.inc[us] * (hypMTG - 1)
                     - moveOverhead * (2 + std::min(hypMTG, 40));
      hypMyTime = std::max(hypMyTime, 0);
      int t1 = minThinkingTime + remaining<OptimumTime>(hypMyTime, hypMTG, ply, slowMover);
      int t2 = minThinkingTime + remaining<MaxTime    >(hypMyTime, hypMTG, ply, slowMover);
      optimumSearchTime = std::min(t1, optimumSearchTime);
      maximumSearchTime = std::min(t2, maximumSearchTime);
  }
  if (Options["Ponder"])
      optimumSearchTime += optimumSearchTime / 4;
  optimumSearchTime = std::min(optimumSearchTime, maximumSearchTime);
 }
@@ -1,7 +1,7 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
@@ -17,23 +17,23 @@
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
-#if !defined(TIMEMAN_H_INCLUDED)
+#ifndef TIMEMAN_H_INCLUDED
 #define TIMEMAN_H_INCLUDED
-struct SearchLimits;
+/// The TimeManager class computes the optimal time to think depending on the
 /// maximum available time, the game move number and other parameters.
 class TimeManager {
 public:
-
+  void init(const Search::LimitsType& limits, Color us, int ply);
-  void init(const SearchLimits& limits, int currentPly);
+  void pv_instability(double bestMoveChanges) { unstablePvFactor = 1 + bestMoveChanges; }
-  void pv_instability(int curChanges, int prevChanges);
+  int available_time() const { return int(optimumSearchTime * unstablePvFactor * 0.71); }
  int available_time() const { return optimumSearchTime + unstablePVExtraTime; }
  int maximum_time() const { return maximumSearchTime; }
 private:
  int optimumSearchTime;
  int maximumSearchTime;
-  int unstablePVExtraTime;
+  double unstablePvFactor;
 };
-#endif // !defined(TIMEMAN_H_INCLUDED)
+#endif // #ifndef TIMEMAN_H_INCLUDED
@@ -1,7 +1,7 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
@@ -17,128 +17,82 @@
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
-#include <cassert>
+#include <cstring>   // For std::memset
 #include <cstring>
 #include <iostream>
 #include "bitboard.h"
 #include "tt.h"
 TranspositionTable TT; // Our global transposition table
 TranspositionTable::TranspositionTable() {
-  size = generation = 0;
+/// TranspositionTable::resize() sets the size of the transposition table,
-  entries = NULL;
+/// measured in megabytes. Transposition table consists of a power of 2 number
-}
+/// of clusters and each cluster consists of ClusterSize number of TTEntry.
-TranspositionTable::~TranspositionTable() {
+void TranspositionTable::resize(size_t mbSize) {
-  delete [] entries;
+  assert(sizeof(Cluster) == CacheLineSize / 2);
 }
  size_t newClusterCount = size_t(1) << msb((mbSize * 1024 * 1024) / sizeof(Cluster));
-/// TranspositionTable::set_size() sets the size of the transposition table,
+  if (newClusterCount == clusterCount)
 /// measured in megabytes.
 void TranspositionTable::set_size(size_t mbSize) {
  size_t newSize = 1024;
  // Transposition table consists of clusters and each cluster consists
  // of ClusterSize number of TTEntries. Each non-empty entry contains
  // information of exactly one position and newSize is the number of
  // clusters we are going to allocate.
  while (2ULL * newSize * sizeof(TTCluster) <= (mbSize << 20))
      newSize *= 2;
  if (newSize == size)
      return;
-  size = newSize;
+  clusterCount = newClusterCount;
-  delete [] entries;
+
-  entries = new (std::nothrow) TTCluster[size];
+  free(mem);
-  if (!entries)
+  mem = calloc(clusterCount * sizeof(Cluster) + CacheLineSize - 1, 1);
  if (!mem)
  {
      std::cerr << "Failed to allocate " << mbSize
-                << " MB for transposition table." << std::endl;
+                << "MB for transposition table." << std::endl;
      exit(EXIT_FAILURE);
  }
-  clear();
+
  table = (Cluster*)((uintptr_t(mem) + CacheLineSize - 1) & ~(CacheLineSize - 1));
 }
 /// TranspositionTable::clear() overwrites the entire transposition table
-/// with zeroes. It is called whenever the table is resized, or when the
+/// with zeros. It is called whenever the table is resized, or when the
 /// user asks the program to clear the table (from the UCI interface).
 void TranspositionTable::clear() {
-  memset(entries, 0, size * sizeof(TTCluster));
+  std::memset(table, 0, clusterCount * sizeof(Cluster));
 }
-/// TranspositionTable::store() writes a new entry containing position key and
+/// TranspositionTable::probe() looks up the current position in the transposition
-/// valuable information of current position. The lowest order bits of position
+/// table. It returns true and a pointer to the TTEntry if the position is found.
-/// key are used to decide on which cluster the position will be placed.
+/// Otherwise, it returns false and a pointer to an empty or least valuable TTEntry
-/// When a new entry is written and there are no empty entries available in cluster,
+/// to be replaced later. A TTEntry t1 is considered to be more valuable than a
-/// it replaces the least valuable of entries. A TTEntry t1 is considered to be
+/// TTEntry t2 if t1 is from the current search and t2 is from a previous search,
-/// more valuable than a TTEntry t2 if t1 is from the current search and t2 is from
+/// or if the depth of t1 is bigger than the depth of t2.
 /// a previous search, or if the depth of t1 is bigger than the depth of t2.
-void TranspositionTable::store(const Key posKey, Value v, ValueType t, Depth d, Move m, Value statV, Value kingD) {
+TTEntry* TranspositionTable::probe(const Key key, bool& found) const {
-  int c1, c2, c3;
+  TTEntry* const tte = first_entry(key);
-  TTEntry *tte, *replace;
+  const uint16_t key16 = key >> 48;  // Use the high 16 bits as key inside the cluster
  uint32_t posKey32 = posKey >> 32; // Use the high 32 bits as key inside the cluster
-  tte = replace = first_entry(posKey);
+  for (int i = 0; i < ClusterSize; ++i)
-
+      if (!tte[i].key16 || tte[i].key16 == key16)
  for (int i = 0; i < ClusterSize; i++, tte++)
  {
      if (!tte->key() || tte->key() == posKey32) // Empty or overwrite old
      {
-          // Preserve any existing ttMove
+          if (tte[i].key16)
-          if (m == MOVE_NONE)
+              tte[i].genBound8 = uint8_t(generation8 | tte[i].bound()); // Refresh
              m = tte->move();
-          tte->save(posKey32, v, t, d, m, generation, statV, kingD);
+          return found = (bool)tte[i].key16, &tte[i];
          return;
      }
-      // Implement replace strategy
+  // Find an entry to be replaced according to the replacement strategy
-      c1 = (replace->generation() == generation ?  2 : 0);
+  TTEntry* replace = tte;
-      c2 = (tte->generation() == generation || tte->type() == VALUE_TYPE_EXACT ? -2 : 0);
+  for (int i = 1; i < ClusterSize; ++i)
-      c3 = (tte->depth() < replace->depth() ?  1 : 0);
+      if (  ((  tte[i].genBound8 & 0xFC) == generation8 || tte[i].bound() == BOUND_EXACT)
          - ((replace->genBound8 & 0xFC) == generation8)
          - (tte[i].depth8 < replace->depth8) < 0)
          replace = &tte[i];
-      if (c1 + c2 + c3 > 0)
+  return found = false, replace;
          replace = tte;
  }
  replace->save(posKey32, v, t, d, m, generation, statV, kingD);
 }
 /// TranspositionTable::probe() looks up the current position in the
 /// transposition table. Returns a pointer to the TTEntry or NULL if
 /// position is not found.
 TTEntry* TranspositionTable::probe(const Key posKey) const {
  uint32_t posKey32 = posKey >> 32;
  TTEntry* tte = first_entry(posKey);
  for (int i = 0; i < ClusterSize; i++, tte++)
      if (tte->key() == posKey32)
          return tte;
  return NULL;
 }
 /// TranspositionTable::new_search() is called at the beginning of every new
 /// search. It increments the "generation" variable, which is used to
 /// distinguish transposition table entries from previous searches from
 /// entries from the current search.
 void TranspositionTable::new_search() {
  generation++;
 }
@@ -1,7 +1,7 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
@@ -17,157 +17,90 @@
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
-#if !defined(TT_H_INCLUDED)
+#ifndef TT_H_INCLUDED
 #define TT_H_INCLUDED
-#include <iostream>
+#include "misc.h"
 #include "move.h"
 #include "types.h"
-
+/// TTEntry struct is the 10 bytes transposition table entry, defined as below:
 /// The TTEntry is the class of transposition table entries
 ///
-/// A TTEntry needs 128 bits to be stored
+/// key        16 bit
-///
+/// move       16 bit
-/// bit  0-31: key
+/// value      16 bit
-/// bit 32-63: data
+/// eval value 16 bit
-/// bit 64-79: value
+/// generation  6 bit
-/// bit 80-95: depth
+/// bound type  2 bit
-/// bit 96-111: static value
+/// depth       8 bit
 /// bit 112-127: margin of static value
 ///
 /// the 32 bits of the data field are so defined
 ///
 /// bit  0-15: move
 /// bit 16-20: not used
 /// bit 21-22: value type
 /// bit 23-31: generation
-class TTEntry {
+struct TTEntry {
-public:
+  Move  move()  const { return (Move )move16; }
-  void save(uint32_t k, Value v, ValueType t, Depth d, Move m, int g, Value statV, Value statM) {
+  Value value() const { return (Value)value16; }
  Value eval()  const { return (Value)eval16; }
  Depth depth() const { return (Depth)depth8; }
  Bound bound() const { return (Bound)(genBound8 & 0x3); }
-    key32        = (uint32_t)k;
+  void save(Key k, Value v, Bound b, Depth d, Move m, Value ev, uint8_t g) {
-    move16       = (uint16_t)m;
+
-    valueType    = (uint8_t)t;
+    if (m || (k >> 48) != key16) // Preserve any existing move for the same position
-    generation8  = (uint8_t)g;
+        move16 = (uint16_t)m;
-    value16      = (int16_t)v;
+
-    depth16      = (int16_t)d;
+    key16     = (uint16_t)(k >> 48);
-    staticValue  = (int16_t)statV;
+    value16   = (int16_t)v;
-    staticMargin = (int16_t)statM;
+    eval16    = (int16_t)ev;
    genBound8 = (uint8_t)(g | b);
    depth8    = (int8_t)d;
  }
  void set_generation(int g) { generation8 = (uint8_t)g; }
  uint32_t key() const              { return key32; }
  Depth depth() const               { return (Depth)depth16; }
  Move move() const                 { return (Move)move16; }
  Value value() const               { return (Value)value16; }
  ValueType type() const            { return (ValueType)valueType; }
  int generation() const            { return (int)generation8; }
  Value static_value() const        { return (Value)staticValue; }
  Value static_value_margin() const { return (Value)staticMargin; }
 private:
-  uint32_t key32;
+  friend class TranspositionTable;
  uint16_t key16;
  uint16_t move16;
-  uint8_t valueType, generation8;
+  int16_t  value16;
-  int16_t value16, depth16, staticValue, staticMargin;
+  int16_t  eval16;
  uint8_t  genBound8;
  int8_t   depth8;
 };
-/// This is the number of TTEntry slots for each cluster
+/// A TranspositionTable consists of a power of 2 number of clusters and each
-const int ClusterSize = 4;
+/// cluster consists of ClusterSize number of TTEntry. Each non-empty entry
-
+/// contains information of exactly one position. The size of a cluster should
-
+/// not be bigger than a cache line size. In case it is less, it should be padded
-/// TTCluster consists of ClusterSize number of TTEntries. Size of TTCluster
+/// to guarantee always aligned accesses.
 /// must not be bigger than a cache line size. In case it is less, it should
 /// be padded to guarantee always aligned accesses.
 struct TTCluster {
  TTEntry data[ClusterSize];
 };
 /// The transposition table class. This is basically just a huge array containing
 /// TTCluster objects, and a few methods for writing and reading entries.
 class TranspositionTable {
-  TranspositionTable(const TranspositionTable&);
+  static const int CacheLineSize = 64;
-  TranspositionTable& operator=(const TranspositionTable&);
+  static const int ClusterSize = 3;
  struct Cluster {
    TTEntry entry[ClusterSize];
    char padding[2]; // Align to the cache line size
  };
 public:
-  TranspositionTable();
+ ~TranspositionTable() { free(mem); }
-  ~TranspositionTable();
+  void new_search() { generation8 += 4; } // Lower 2 bits are used by Bound
-  void set_size(size_t mbSize);
+  uint8_t generation() const { return generation8; }
  TTEntry* probe(const Key key, bool& found) const;
  void resize(size_t mbSize);
  void clear();
-  void store(const Key posKey, Value v, ValueType type, Depth d, Move m, Value statV, Value kingD);
+
-  TTEntry* probe(const Key posKey) const;
+  // The lowest order bits of the key are used to get the index of the cluster
-  void new_search();
+  TTEntry* first_entry(const Key key) const {
-  TTEntry* first_entry(const Key posKey) const;
+    return &table[(size_t)key & (clusterCount - 1)].entry[0];
-  void refresh(const TTEntry* tte) const;
+  }
 private:
-  size_t size;
+  size_t clusterCount;
-  TTCluster* entries;
+  Cluster* table;
-  uint8_t generation; // Size must be not bigger then TTEntry::generation8
+  void* mem;
  uint8_t generation8; // Size must be not bigger than TTEntry::genBound8
 };
 extern TranspositionTable TT;
-
+#endif // #ifndef TT_H_INCLUDED
 /// TranspositionTable::first_entry() returns a pointer to the first entry of
 /// a cluster given a position. The lowest order bits of the key are used to
 /// get the index of the cluster.
 inline TTEntry* TranspositionTable::first_entry(const Key posKey) const {
  return entries[((uint32_t)posKey) & (size - 1)].data;
 }
 /// TranspositionTable::refresh() updates the 'generation' value of the TTEntry
 /// to avoid aging. Normally called after a TT hit.
 inline void TranspositionTable::refresh(const TTEntry* tte) const {
  const_cast<TTEntry*>(tte)->set_generation(generation);
 }
 /// A simple fixed size hash table used to store pawns and material
 /// configurations. It is basically just an array of Entry objects.
 /// Without cluster concept or overwrite policy.
 template<class Entry, int HashSize>
 struct SimpleHash {
  typedef SimpleHash<Entry, HashSize> Base;
  void init() {
    if (entries)
        return;
    entries = new (std::nothrow) Entry[HashSize];
    if (!entries)
    {
        std::cerr << "Failed to allocate " << HashSize * sizeof(Entry)
                  << " bytes for hash table." << std::endl;
        exit(EXIT_FAILURE);
    }
    memset(entries, 0, HashSize * sizeof(Entry));
  }
  virtual ~SimpleHash() { delete [] entries; }
  Entry* probe(Key key) const { return entries + ((uint32_t)key & (HashSize - 1)); }
  void prefetch(Key key) const { ::prefetch((char*)probe(key)); }
 protected:
  Entry* entries;
 };
 #endif // !defined(TT_H_INCLUDED)
@@ -1,7 +1,7 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
@@ -17,195 +17,207 @@
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
-#if !defined(TYPES_H_INCLUDED)
+#ifndef TYPES_H_INCLUDED
 #define TYPES_H_INCLUDED
 /// When compiling with provided Makefile (e.g. for Linux and OSX), configuration
 /// is done automatically. To get started type 'make help'.
 ///
 /// When Makefile is not used (e.g. with Microsoft Visual Studio) some switches
 /// need to be set manually:
 ///
 /// -DNDEBUG      | Disable debugging mode. Always use this for release.
 ///
 /// -DNO_PREFETCH | Disable use of prefetch asm-instruction. You may need this to
 ///               | run on some very old machines.
 ///
 /// -DUSE_POPCNT  | Add runtime support for use of popcnt asm-instruction. Works
 ///               | only in 64-bit mode and requires hardware with popcnt support.
 #include <cassert>
 #include <cctype>
 #include <climits>
 #include <cstdlib>
-#if defined(_MSC_VER)
+#include "platform.h"
-// Disable some silly and noisy warning from MSVC compiler
+/// Predefined macros hell:
-#pragma warning(disable: 4800) // Forcing value to bool 'true' or 'false'
+///
-#pragma warning(disable: 4127) // Conditional expression is constant
+/// __GNUC__           Compiler is gcc, Clang or Intel on Linux
-#pragma warning(disable: 4146) // Unary minus operator applied to unsigned type
+/// __INTEL_COMPILER   Compiler is Intel
 /// _MSC_VER           Compiler is MSVC or Intel on Windows
 /// _WIN32             Building on Windows (any)
 /// _WIN64             Building on Windows 64 bit
-// MSVC does not support <inttypes.h>
+#if defined(_WIN64) && !defined(IS_64BIT) // Last condition means Makefile is not used
-typedef   signed __int8    int8_t;
+#  include <intrin.h> // MSVC popcnt and bsfq instrinsics
-typedef unsigned __int8   uint8_t;
+#  define IS_64BIT
-typedef   signed __int16  int16_t;
+#  define USE_BSFQ
-typedef unsigned __int16 uint16_t;
+#endif
 typedef   signed __int32  int32_t;
 typedef unsigned __int32 uint32_t;
 typedef   signed __int64  int64_t;
 typedef unsigned __int64 uint64_t;
 #if defined(USE_POPCNT) && defined(__INTEL_COMPILER) && defined(_MSC_VER)
 #  include <nmmintrin.h> // Intel header for _mm_popcnt_u64() intrinsic
 #endif
 #if !defined(NO_PREFETCH) && (defined(__INTEL_COMPILER) || defined(_MSC_VER))
 #  include <xmmintrin.h> // Intel and Microsoft header for _mm_prefetch()
 #endif
 #if defined(USE_PEXT)
 #  include <immintrin.h> // Header for _pext_u64() intrinsic
 #  define pext(b, m) _pext_u64(b, m)
 #else
-
+#  define pext(b, m) (0)
 #include <inttypes.h>
 #endif
-#define Min(x, y) (((x) < (y)) ? (x) : (y))
+#ifdef _MSC_VER
-#define Max(x, y) (((x) < (y)) ? (y) : (x))
+#  define FORCE_INLINE  __forceinline
 ////
 //// Configuration
 ////
 //// For Linux and OSX configuration is done automatically using Makefile.
 //// To get started type "make help".
 ////
 //// For windows part of the configuration is detected automatically, but
 //// some switches need to be set manually:
 ////
 //// -DNDEBUG       | Disable debugging mode. Use always.
 ////
 //// -DNO_PREFETCH  | Disable use of prefetch asm-instruction. A must if you want the
 ////                | executable to run on some very old machines.
 ////
 //// -DUSE_POPCNT   | Add runtime support for use of popcnt asm-instruction.
 ////                | Works only in 64-bit mode. For compiling requires hardware
 ////                | with popcnt support. Around 4% speed-up.
 ////
 //// -DOLD_LOCKS    | By default under Windows are used the fast Slim Reader/Writer (SRW)
 ////                | Locks and Condition Variables: these are not supported by Windows XP
 ////                | and older, to compile for those platforms you should enable OLD_LOCKS.
 // Automatic detection for 64-bit under Windows
 #if defined(_WIN64)
 #define IS_64BIT
 #endif
 // Automatic detection for use of bsfq asm-instruction under Windows
 #if defined(_WIN64)
 #define USE_BSFQ
 #endif
 // Intel header for _mm_popcnt_u64() intrinsic
 #if defined(USE_POPCNT) && defined(_MSC_VER) && defined(__INTEL_COMPILER)
 #include <nmmintrin.h>
 #endif
 // Cache line alignment specification
 #if defined(_MSC_VER) || defined(__INTEL_COMPILER)
 #define CACHE_LINE_ALIGNMENT __declspec(align(64))
 #else
 #define CACHE_LINE_ALIGNMENT  __attribute__ ((aligned(64)))
 #endif
 // Define a __cpuid() function for gcc compilers, for Intel and MSVC
 // is already available as an intrinsic.
 #if defined(_MSC_VER)
 #include <intrin.h>
 #elif defined(__GNUC__) && (defined(__i386__) || defined(__x86_64__))
 inline void __cpuid(int CPUInfo[4], int InfoType)
 {
  int* eax = CPUInfo + 0;
  int* ebx = CPUInfo + 1;
  int* ecx = CPUInfo + 2;
  int* edx = CPUInfo + 3;
  *eax = InfoType;
  *ecx = 0;
  __asm__("cpuid" : "=a" (*eax), "=b" (*ebx), "=c" (*ecx), "=d" (*edx)
                  : "0" (*eax), "2" (*ecx));
 }
 #else
 inline void __cpuid(int CPUInfo[4], int)
 {
   CPUInfo[0] = CPUInfo[1] = CPUInfo[2] = CPUInfo[3] = 0;
 }
 #endif
 // Define FORCE_INLINE macro to force inlining overriding compiler choice
 #if defined(_MSC_VER)
 #define FORCE_INLINE  __forceinline
 #elif defined(__GNUC__)
-#define FORCE_INLINE  inline __attribute__((always_inline))
+#  define FORCE_INLINE  inline __attribute__((always_inline))
 #else
-#define FORCE_INLINE  inline
+#  define FORCE_INLINE  inline
 #endif
-/// cpu_has_popcnt() detects support for popcnt instruction at runtime
+#ifdef USE_POPCNT
-inline bool cpu_has_popcnt() {
+const bool HasPopCnt = true;
  int CPUInfo[4] = {-1};
  __cpuid(CPUInfo, 0x00000001);
  return (CPUInfo[2] >> 23) & 1;
 }
 /// CpuHasPOPCNT is a global constant initialized at startup that
 /// is set to true if CPU on which application runs supports popcnt
 /// hardware instruction. Unless USE_POPCNT is not defined.
 #if defined(USE_POPCNT)
 const bool CpuHasPOPCNT = cpu_has_popcnt();
 #else
-const bool CpuHasPOPCNT = false;
+const bool HasPopCnt = false;
 #endif
-
+#ifdef USE_PEXT
-/// CpuIs64Bit is a global constant initialized at compile time that
+const bool HasPext = true;
 /// is set to true if CPU on which application runs is a 64 bits.
 #if defined(IS_64BIT)
 const bool CpuIs64Bit = true;
 #else
-const bool CpuIs64Bit = false;
+const bool HasPext = false;
 #endif
-#include <string>
+#ifdef IS_64BIT
 const bool Is64Bit = true;
 #else
 const bool Is64Bit = false;
 #endif
 typedef uint64_t Key;
 typedef uint64_t Bitboard;
-const int PLY_MAX = 100;
+const int MAX_MOVES = 256;
-const int PLY_MAX_PLUS_2 = PLY_MAX + 2;
+const int MAX_PLY   = 128;
-enum ValueType {
+/// A move needs 16 bits to be stored
-  VALUE_TYPE_NONE  = 0,
+///
-  VALUE_TYPE_UPPER = 1,
+/// bit  0- 5: destination square (from 0 to 63)
-  VALUE_TYPE_LOWER = 2,
+/// bit  6-11: origin square (from 0 to 63)
-  VALUE_TYPE_EXACT = VALUE_TYPE_UPPER | VALUE_TYPE_LOWER
+/// bit 12-13: promotion piece type - 2 (from KNIGHT-2 to QUEEN-2)
 /// bit 14-15: special move flag: promotion (1), en passant (2), castling (3)
 /// NOTE: EN-PASSANT bit is set only when a pawn can be captured
 ///
 /// Special cases are MOVE_NONE and MOVE_NULL. We can sneak these in because in
 /// any normal move destination square is always different from origin square
 /// while MOVE_NONE and MOVE_NULL have the same origin and destination square.
 enum Move {
  MOVE_NONE,
  MOVE_NULL = 65
 };
 enum MoveType {
  NORMAL,
  PROMOTION = 1 << 14,
  ENPASSANT = 2 << 14,
  CASTLING  = 3 << 14
 };
 enum Color {
  WHITE, BLACK, NO_COLOR, COLOR_NB = 2
 };
 enum CastlingSide {
  KING_SIDE, QUEEN_SIDE, CASTLING_SIDE_NB = 2
 };
 enum CastlingRight {
  NO_CASTLING,
  WHITE_OO,
  WHITE_OOO = WHITE_OO << 1,
  BLACK_OO  = WHITE_OO << 2,
  BLACK_OOO = WHITE_OO << 3,
  ANY_CASTLING = WHITE_OO | WHITE_OOO | BLACK_OO | BLACK_OOO,
  CASTLING_RIGHT_NB = 16
 };
 template<Color C, CastlingSide S> struct MakeCastling {
  static const CastlingRight
  right = C == WHITE ? S == QUEEN_SIDE ? WHITE_OOO : WHITE_OO
                     : S == QUEEN_SIDE ? BLACK_OOO : BLACK_OO;
 };
 enum Phase {
  PHASE_ENDGAME,
  PHASE_MIDGAME = 128,
  MG = 0, EG = 1, PHASE_NB = 2
 };
 enum ScaleFactor {
  SCALE_FACTOR_DRAW    = 0,
  SCALE_FACTOR_ONEPAWN = 48,
  SCALE_FACTOR_NORMAL  = 64,
  SCALE_FACTOR_MAX     = 128,
  SCALE_FACTOR_NONE    = 255
 };
 enum Bound {
  BOUND_NONE,
  BOUND_UPPER,
  BOUND_LOWER,
  BOUND_EXACT = BOUND_UPPER | BOUND_LOWER
 };
 enum Value {
  VALUE_ZERO      = 0,
  VALUE_DRAW      = 0,
-  VALUE_KNOWN_WIN = 15000,
+  VALUE_KNOWN_WIN = 10000,
-  VALUE_MATE      = 30000,
+  VALUE_MATE      = 32000,
-  VALUE_INFINITE  = 30001,
+  VALUE_INFINITE  = 32001,
-  VALUE_NONE      = 30002,
+  VALUE_NONE      = 32002,
-  VALUE_MATE_IN_PLY_MAX  =  VALUE_MATE - PLY_MAX,
+  VALUE_MATE_IN_MAX_PLY  =  VALUE_MATE - 2 * MAX_PLY,
-  VALUE_MATED_IN_PLY_MAX = -VALUE_MATE + PLY_MAX,
+  VALUE_MATED_IN_MAX_PLY = -VALUE_MATE + 2 * MAX_PLY,
  VALUE_ENSURE_INTEGER_SIZE_P = INT_MAX,
-  VALUE_ENSURE_INTEGER_SIZE_N = INT_MIN
+  VALUE_ENSURE_INTEGER_SIZE_N = INT_MIN,
  PawnValueMg   = 198,   PawnValueEg   = 258,
  KnightValueMg = 817,   KnightValueEg = 846,
  BishopValueMg = 836,   BishopValueEg = 857,
  RookValueMg   = 1270,  RookValueEg   = 1278,
  QueenValueMg  = 2521,  QueenValueEg  = 2558,
  MidgameLimit  = 15581, EndgameLimit  = 3998
 };
 enum PieceType {
-  PIECE_TYPE_NONE = 0,
+  NO_PIECE_TYPE, PAWN, KNIGHT, BISHOP, ROOK, QUEEN, KING,
-  PAWN = 1, KNIGHT = 2, BISHOP = 3, ROOK = 4, QUEEN = 5, KING = 6
+  ALL_PIECES = 0,
  PIECE_TYPE_NB = 8
 };
 enum Piece {
-  PIECE_NONE_DARK_SQ = 0, WP = 1, WN = 2, WB = 3, WR = 4, WQ = 5, WK = 6,
+  NO_PIECE,
-  BP = 9, BN = 10, BB = 11, BR = 12, BQ = 13, BK = 14, PIECE_NONE = 16
+  W_PAWN = 1, W_KNIGHT, W_BISHOP, W_ROOK, W_QUEEN, W_KING,
-};
+  B_PAWN = 9, B_KNIGHT, B_BISHOP, B_ROOK, B_QUEEN, B_KING,
-
+  PIECE_NB = 16
 enum Color {
  WHITE, BLACK, COLOR_NONE
 };
 enum Depth {
-  ONE_PLY = 2,
+  ONE_PLY = 1,
-  DEPTH_ZERO         =  0 * ONE_PLY,
+  DEPTH_ZERO          =  0,
-  DEPTH_QS_CHECKS    = -1 * ONE_PLY,
+  DEPTH_QS_CHECKS     =  0,
-  DEPTH_QS_NO_CHECKS = -2 * ONE_PLY,
+  DEPTH_QS_NO_CHECKS  = -1,
  DEPTH_QS_RECAPTURES = -5,
-  DEPTH_NONE = -127 * ONE_PLY
+  DEPTH_NONE = -6,
  DEPTH_MAX  = MAX_PLY
 };
 enum Square {
@@ -219,6 +231,8 @@ enum Square {
  SQ_A8, SQ_B8, SQ_C8, SQ_D8, SQ_E8, SQ_F8, SQ_G8, SQ_H8,
  SQ_NONE,
  SQUARE_NB = 64,
  DELTA_N =  8,
  DELTA_E =  1,
  DELTA_S = -8,
@@ -233,238 +247,190 @@ enum Square {
 };
 enum File {
-  FILE_A, FILE_B, FILE_C, FILE_D, FILE_E, FILE_F, FILE_G, FILE_H
+  FILE_A, FILE_B, FILE_C, FILE_D, FILE_E, FILE_F, FILE_G, FILE_H, FILE_NB
 };
 enum Rank {
-  RANK_1, RANK_2, RANK_3, RANK_4, RANK_5, RANK_6, RANK_7, RANK_8
+  RANK_1, RANK_2, RANK_3, RANK_4, RANK_5, RANK_6, RANK_7, RANK_8, RANK_NB
 };
 enum SquareColor {
  DARK, LIGHT
 };
 enum ScaleFactor {
  SCALE_FACTOR_ZERO   = 0,
  SCALE_FACTOR_NORMAL = 64,
  SCALE_FACTOR_MAX    = 128,
  SCALE_FACTOR_NONE   = 255
 };
-/// Score enum keeps a midgame and an endgame value in a single
+/// Score enum stores a middlegame and an endgame value in a single integer.
-/// integer (enum), first LSB 16 bits are used to store endgame
+/// The least significant 16 bits are used to store the endgame value and
-/// value, while upper bits are used for midgame value. Compiler
+/// the upper 16 bits are used to store the middlegame value. The compiler
-/// is free to choose the enum type as long as can keep its data,
+/// is free to choose the enum type as long as it can store the data, so we
-/// so ensure Score to be an integer type.
+/// ensure that Score is an integer type by assigning some big int values.
 enum Score {
-    SCORE_ZERO = 0,
+  SCORE_ZERO,
-    SCORE_ENSURE_INTEGER_SIZE_P = INT_MAX,
+  SCORE_ENSURE_INTEGER_SIZE_P = INT_MAX,
-    SCORE_ENSURE_INTEGER_SIZE_N = INT_MIN
+  SCORE_ENSURE_INTEGER_SIZE_N = INT_MIN
 };
-#define ENABLE_OPERATORS_ON(T) \
+inline Score make_score(int mg, int eg) {
-inline T operator+ (const T d1, const T d2) { return T(int(d1) + int(d2)); } \
+  return Score((mg << 16) + eg);
-inline T operator- (const T d1, const T d2) { return T(int(d1) - int(d2)); } \
+}
 inline T operator* (int i, const T d) {  return T(i * int(d)); } \
 inline T operator* (const T d, int i) {  return T(int(d) * i); } \
 inline T operator/ (const T d, int i) { return T(int(d) / i); } \
 inline T operator- (const T d) { return T(-int(d)); } \
 inline T operator++ (T& d, int) {d = T(int(d) + 1); return d; } \
 inline T operator-- (T& d, int) { d = T(int(d) - 1); return d; } \
 inline void operator+= (T& d1, const T d2) { d1 = d1 + d2; } \
 inline void operator-= (T& d1, const T d2) { d1 = d1 - d2; } \
 inline void operator*= (T& d, int i) { d = T(int(d) * i); } \
 inline void operator/= (T& d, int i) { d = T(int(d) / i); }
-ENABLE_OPERATORS_ON(Value)
+/// Extracting the signed lower and upper 16 bits is not so trivial because
-ENABLE_OPERATORS_ON(PieceType)
+/// according to the standard a simple cast to short is implementation defined
-ENABLE_OPERATORS_ON(Piece)
+/// and so is a right shift of a signed integer.
-ENABLE_OPERATORS_ON(Color)
+inline Value mg_value(Score s) {
 ENABLE_OPERATORS_ON(Depth)
 ENABLE_OPERATORS_ON(Square)
 ENABLE_OPERATORS_ON(File)
 ENABLE_OPERATORS_ON(Rank)
-#undef ENABLE_OPERATORS_ON
+  union { uint16_t u; int16_t s; } mg = { uint16_t(unsigned(s + 0x8000) >> 16) };
  return Value(mg.s);
 }
-// Extra operators for adding integers to a Value
+inline Value eg_value(Score s) {
 inline Value operator+ (Value v, int i) { return Value(int(v) + i); }
 inline Value operator- (Value v, int i) { return Value(int(v) - i); }
-// Extracting the _signed_ lower and upper 16 bits it not so trivial
+  union { uint16_t u; int16_t s; } eg = { uint16_t(unsigned(s)) };
-// because according to the standard a simple cast to short is
+  return Value(eg.s);
-// implementation defined and so is a right shift of a signed integer.
+}
 inline Value mg_value(Score s) { return Value(((int(s) + 32768) & ~0xffff) / 0x10000); }
-// Unfortunatly on Intel 64 bit we have a small speed regression, so use a faster code in
+#define ENABLE_BASE_OPERATORS_ON(T)                             \
-// this case, although not 100% standard compliant it seems to work for Intel and MSVC.
+inline T operator+(T d1, T d2) { return T(int(d1) + int(d2)); } \
-#if defined(IS_64BIT) && (!defined(__GNUC__) || defined(__INTEL_COMPILER))
+inline T operator-(T d1, T d2) { return T(int(d1) - int(d2)); } \
-inline Value eg_value(Score s) { return Value(int16_t(s & 0xffff)); }
+inline T operator*(int i, T d) { return T(i * int(d)); }        \
-#else
+inline T operator*(T d, int i) { return T(int(d) * i); }        \
-inline Value eg_value(Score s) { return Value((int)(unsigned(s) & 0x7fffu) - (int)(unsigned(s) & 0x8000u)); }
+inline T operator-(T d) { return T(-int(d)); }                  \
-#endif
+inline T& operator+=(T& d1, T d2) { return d1 = d1 + d2; }      \
 inline T& operator-=(T& d1, T d2) { return d1 = d1 - d2; }      \
 inline T& operator*=(T& d, int i) { return d = T(int(d) * i); }
-inline Score make_score(int mg, int eg) { return Score((mg << 16) + eg); }
+#define ENABLE_FULL_OPERATORS_ON(T)                             \
 ENABLE_BASE_OPERATORS_ON(T)                                     \
 inline T& operator++(T& d) { return d = T(int(d) + 1); }        \
 inline T& operator--(T& d) { return d = T(int(d) - 1); }        \
 inline T operator/(T d, int i) { return T(int(d) / i); }        \
 inline int operator/(T d1, T d2) { return int(d1) / int(d2); }  \
 inline T& operator/=(T& d, int i) { return d = T(int(d) / i); }
-// Division must be handled separately for each term
+ENABLE_FULL_OPERATORS_ON(Value)
-inline Score operator/(Score s, int i) { return make_score(mg_value(s) / i, eg_value(s) / i); }
+ENABLE_FULL_OPERATORS_ON(PieceType)
 ENABLE_FULL_OPERATORS_ON(Piece)
 ENABLE_FULL_OPERATORS_ON(Color)
 ENABLE_FULL_OPERATORS_ON(Depth)
 ENABLE_FULL_OPERATORS_ON(Square)
 ENABLE_FULL_OPERATORS_ON(File)
 ENABLE_FULL_OPERATORS_ON(Rank)
-// Only declared but not defined. We don't want to multiply two scores due to
+ENABLE_BASE_OPERATORS_ON(Score)
-// a very high risk of overflow. So user should explicitly convert to integer.
+
 #undef ENABLE_FULL_OPERATORS_ON
 #undef ENABLE_BASE_OPERATORS_ON
 /// Additional operators to add integers to a Value
 inline Value operator+(Value v, int i) { return Value(int(v) + i); }
 inline Value operator-(Value v, int i) { return Value(int(v) - i); }
 inline Value& operator+=(Value& v, int i) { return v = v + i; }
 inline Value& operator-=(Value& v, int i) { return v = v - i; }
 /// Only declared but not defined. We don't want to multiply two scores due to
 /// a very high risk of overflow. So user should explicitly convert to integer.
 inline Score operator*(Score s1, Score s2);
-// Remaining Score operators are standard
+/// Division of a Score must be handled separately for each term
-inline Score operator+ (const Score d1, const Score d2) { return Score(int(d1) + int(d2)); }
+inline Score operator/(Score s, int i) {
-inline Score operator- (const Score d1, const Score d2) { return Score(int(d1) - int(d2)); }
+  return make_score(mg_value(s) / i, eg_value(s) / i);
-inline Score operator* (int i, const Score d) {  return Score(i * int(d)); }
+}
 inline Score operator* (const Score d, int i) {  return Score(int(d) * i); }
 inline Score operator- (const Score d) { return Score(-int(d)); }
 inline void operator+= (Score& d1, const Score d2) { d1 = d1 + d2; }
 inline void operator-= (Score& d1, const Score d2) { d1 = d1 - d2; }
 inline void operator*= (Score& d, int i) { d = Score(int(d) * i); }
 inline void operator/= (Score& d, int i) { d = Score(int(d) / i); }
-const Value PawnValueMidgame   = Value(0x0C6);
+extern Value PieceValue[PHASE_NB][PIECE_NB];
 const Value PawnValueEndgame   = Value(0x102);
 const Value KnightValueMidgame = Value(0x331);
 const Value KnightValueEndgame = Value(0x34E);
 const Value BishopValueMidgame = Value(0x344);
 const Value BishopValueEndgame = Value(0x359);
 const Value RookValueMidgame   = Value(0x4F6);
 const Value RookValueEndgame   = Value(0x4FE);
 const Value QueenValueMidgame  = Value(0x9D9);
 const Value QueenValueEndgame  = Value(0x9FE);
-inline Value value_mate_in(int ply) {
+inline Color operator~(Color c) {
  return Color(c ^ BLACK);
 }
 inline Square operator~(Square s) {
  return Square(s ^ SQ_A8); // Vertical flip SQ_A1 -> SQ_A8
 }
 inline CastlingRight operator|(Color c, CastlingSide s) {
  return CastlingRight(WHITE_OO << ((s == QUEEN_SIDE) + 2 * c));
 }
 inline Value mate_in(int ply) {
  return VALUE_MATE - ply;
 }
-inline Value value_mated_in(int ply) {
+inline Value mated_in(int ply) {
  return -VALUE_MATE + ply;
 }
 inline Piece make_piece(Color c, PieceType pt) {
  return Piece((int(c) << 3) | int(pt));
 }
 inline PieceType type_of_piece(Piece p)  {
  return PieceType(int(p) & 7);
 }
 inline Color color_of_piece(Piece p) {
  return Color(int(p) >> 3);
 }
 inline Color opposite_color(Color c) {
  return Color(int(c) ^ 1);
 }
 inline bool color_is_ok(Color c) {
  return c == WHITE || c == BLACK;
 }
 inline bool piece_type_is_ok(PieceType pt) {
  return pt >= PAWN && pt <= KING;
 }
 inline bool piece_is_ok(Piece p) {
  return piece_type_is_ok(type_of_piece(p)) && color_is_ok(color_of_piece(p));
 }
 inline char piece_type_to_char(PieceType pt) {
  static const char ch[] = " PNBRQK";
  return ch[pt];
 }
 inline Square make_square(File f, Rank r) {
-  return Square((int(r) << 3) | int(f));
+  return Square((r << 3) | f);
 }
-inline File square_file(Square s) {
+inline Piece make_piece(Color c, PieceType pt) {
-  return File(int(s) & 7);
+  return Piece((c << 3) | pt);
 }
-inline Rank square_rank(Square s) {
+inline PieceType type_of(Piece pc)  {
-  return Rank(int(s) >> 3);
+  return PieceType(pc & 7);
 }
-inline Square flip_square(Square s) {
+inline Color color_of(Piece pc) {
-  return Square(int(s) ^ 56);
+  assert(pc != NO_PIECE);
  return Color(pc >> 3);
 }
-inline Square flop_square(Square s) {
+inline bool is_ok(Square s) {
-  return Square(int(s) ^ 7);
+  return s >= SQ_A1 && s <= SQ_H8;
 }
 inline File file_of(Square s) {
  return File(s & 7);
 }
 inline Rank rank_of(Square s) {
  return Rank(s >> 3);
 }
 inline Square relative_square(Color c, Square s) {
-  return Square(int(s) ^ (int(c) * 56));
+  return Square(s ^ (c * 56));
 }
 inline Rank relative_rank(Color c, Rank r) {
-  return Rank(int(r) ^ (int(c) * 7));
+  return Rank(r ^ (c * 7));
 }
 inline Rank relative_rank(Color c, Square s) {
-  return relative_rank(c, square_rank(s));
+  return relative_rank(c, rank_of(s));
 }
-inline SquareColor square_color(Square s) {
+inline bool opposite_colors(Square s1, Square s2) {
  return SquareColor(int(square_rank(s) + s) & 1);
 }
 inline bool opposite_color_squares(Square s1, Square s2) {
  int s = int(s1) ^ int(s2);
  return ((s >> 3) ^ s) & 1;
 }
 inline int file_distance(Square s1, Square s2) {
  return abs(square_file(s1) - square_file(s2));
 }
 inline int rank_distance(Square s1, Square s2) {
  return abs(square_rank(s1) - square_rank(s2));
 }
 inline int square_distance(Square s1, Square s2) {
  return Max(file_distance(s1, s2), rank_distance(s1, s2));
 }
 inline File file_from_char(char c) {
  return File(c - 'a') + FILE_A;
 }
 inline char file_to_char(File f) {
  return char(f - FILE_A + int('a'));
 }
 inline Rank rank_from_char(char c) {
  return Rank(c - '1') + RANK_1;
 }
 inline char rank_to_char(Rank r) {
  return char(r - RANK_1 + int('1'));
 }
 inline const std::string square_to_string(Square s) {
  char ch[] = { file_to_char(square_file(s)), rank_to_char(square_rank(s)), 0 };
  return std::string(ch);
 }
 inline bool file_is_ok(File f) {
  return f >= FILE_A && f <= FILE_H;
 }
 inline bool rank_is_ok(Rank r) {
  return r >= RANK_1 && r <= RANK_8;
 }
 inline bool square_is_ok(Square s) {
  return s >= SQ_A1 && s <= SQ_H8;
 }
 inline Square pawn_push(Color c) {
  return c == WHITE ? DELTA_N : DELTA_S;
 }
-#endif // !defined(TYPES_H_INCLUDED)
+inline Square from_sq(Move m) {
  return Square((m >> 6) & 0x3F);
 }
 inline Square to_sq(Move m) {
  return Square(m & 0x3F);
 }
 inline MoveType type_of(Move m) {
  return MoveType(m & (3 << 14));
 }
 inline PieceType promotion_type(Move m) {
  return PieceType(((m >> 12) & 3) + 2);
 }
 inline Move make_move(Square from, Square to) {
  return Move(to | (from << 6));
 }
 template<MoveType T>
 inline Move make(Square from, Square to, PieceType pt = KNIGHT) {
  return Move(to | (from << 6) | T | ((pt - KNIGHT) << 12));
 }
 inline bool is_ok(Move m) {
  return from_sq(m) != to_sq(m); // Catch MOVE_NULL and MOVE_NONE
 }
 #endif // #ifndef TYPES_H_INCLUDED
@@ -1,7 +1,7 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
@@ -17,231 +17,266 @@
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
 #include <cassert>
 #include <iostream>
 #include <sstream>
 #include <string>
 #include "evaluate.h"
-#include "misc.h"
+#include "movegen.h"
 #include "move.h"
 #include "position.h"
 #include "search.h"
-#include "ucioption.h"
+#include "thread.h"
 #include "tt.h"
 #include "uci.h"
 using namespace std;
-namespace {
+extern void benchmark(const Position& pos, istream& is);
  // FEN string for the initial position
  const string StartPositionFEN = "rnbqkbnr/pppppppp/8/8/8/8/PPPPPPPP/RNBQKBNR w KQkq - 0 1";
  // UCIParser is a class for parsing UCI input. The class
  // is actually a string stream built on a given input string.
  typedef istringstream UCIParser;
  void set_option(UCIParser& up);
  void set_position(Position& pos, UCIParser& up);
  bool go(Position& pos, UCIParser& up);
  void perft(Position& pos, UCIParser& up);
 }
 /// execute_uci_command() takes a string as input, uses a UCIParser
 /// object to parse this text string as a UCI command, and calls
 /// the appropriate functions. In addition to the UCI commands,
 /// the function also supports a few debug commands.
 bool execute_uci_command(const string& cmd) {
  static Position pos(StartPositionFEN, false, 0); // The root position
  UCIParser up(cmd);
  string token;
  up >> token; // operator>>() skips any whitespace
  if (token == "quit")
      return false;
  if (token == "go")
      return go(pos, up);
  if (token == "ucinewgame")
      pos.from_fen(StartPositionFEN, false);
  else if (token == "isready")
      cout << "readyok" << endl;
  else if (token == "position")
      set_position(pos, up);
  else if (token == "setoption")
      set_option(up);
  else if (token == "perft")
      perft(pos, up);
  else if (token == "d")
      pos.print();
  else if (token == "flip")
      pos.flip();
  else if (token == "eval")
  {
      read_evaluation_uci_options(pos.side_to_move());
      cout << trace_evaluate(pos) << endl;
  }
  else if (token == "key")
      cout << "key: " << hex     << pos.get_key()
           << "\nmaterial key: " << pos.get_material_key()
           << "\npawn key: "     << pos.get_pawn_key() << endl;
  else if (token == "uci")
      cout << "id name "     << engine_name()
           << "\nid author " << engine_authors()
           << "\n"           << Options.print_all()
           << "\nuciok"      << endl;
  else
      cout << "Unknown command: " << cmd << endl;
  return true;
 }
 namespace {
-  // set_position() is called when engine receives the "position" UCI
+  // FEN string of the initial position, normal chess
-  // command. The function sets up the position described in the given
+  const char* StartFEN = "rnbqkbnr/pppppppp/8/8/8/8/PPPPPPPP/RNBQKBNR w KQkq - 0 1";
  // fen string ("fen") or the starting position ("startpos") and then
  // makes the moves given in the following move list ("moves").
-  void set_position(Position& pos, UCIParser& up) {
+  // Stack to keep track of the position states along the setup moves (from the
  // start position to the position just before the search starts). Needed by
  // 'draw by repetition' detection.
  Search::StateStackPtr SetupStates;
  // position() is called when engine receives the "position" UCI command.
  // The function sets up the position described in the given FEN string ("fen")
  // or the starting position ("startpos") and then makes the moves given in the
  // following move list ("moves").
  void position(Position& pos, istringstream& is) {
    Move m;
    string token, fen;
-    up >> token; // operator>>() skips any whitespace
+    is >> token;
    if (token == "startpos")
    {
-        pos.from_fen(StartPositionFEN, false);
+        fen = StartFEN;
-        up >> token; // Consume "moves" token if any
+        is >> token; // Consume "moves" token if any
    }
    else if (token == "fen")
-    {
+        while (is >> token && token != "moves")
        while (up >> token && token != "moves")
            fen += token + " ";
        pos.from_fen(fen, Options["UCI_Chess960"].value<bool>());
    }
    else return;
    // Parse move list (if any)
    while (up >> token)
        pos.do_setup_move(move_from_uci(pos, token));
  }
  // set_option() is called when engine receives the "setoption" UCI
  // command. The function updates the corresponding UCI option ("name")
  // to the given value ("value").
  void set_option(UCIParser& up) {
    string token, name;
    string value = "true"; // UCI buttons don't have a "value" field
    up >> token; // Consume "name" token
    up >> name;  // Read option name
    // Handle names with included spaces
    while (up >> token && token != "value")
        name += " " + token;
    up >> value; // Read option value
    // Handle values with included spaces
    while (up >> token)
        value += " " + token;
    if (Options.find(name) != Options.end())
        Options[name].set_value(value);
    else
        cout << "No such option: " << name << endl;
  }
  // go() is called when engine receives the "go" UCI command. The
  // function sets the thinking time and other parameters from the input
  // string, and then calls think(). Returns false if a quit command
  // is received while thinking, true otherwise.
  bool go(Position& pos, UCIParser& up) {
    string token;
    SearchLimits limits;
    Move searchMoves[MAX_MOVES], *cur = searchMoves;
    int time[] = { 0, 0 }, inc[] = { 0, 0 };
    while (up >> token)
    {
        if (token == "infinite")
            limits.infinite = true;
        else if (token == "ponder")
            limits.ponder = true;
        else if (token == "wtime")
            up >> time[WHITE];
        else if (token == "btime")
            up >> time[BLACK];
        else if (token == "winc")
            up >> inc[WHITE];
        else if (token == "binc")
            up >> inc[BLACK];
        else if (token == "movestogo")
            up >> limits.movesToGo;
        else if (token == "depth")
            up >> limits.maxDepth;
        else if (token == "nodes")
            up >> limits.maxNodes;
        else if (token == "movetime")
            up >> limits.maxTime;
        else if (token == "searchmoves")
            while (up >> token)
                *cur++ = move_from_uci(pos, token);
    }
    *cur = MOVE_NONE;
    limits.time = time[pos.side_to_move()];
    limits.increment = inc[pos.side_to_move()];
    assert(pos.is_ok());
    return think(pos, limits, searchMoves);
  }
  // perft() is called when engine receives the "perft" command.
  // The function calls perft() passing the required search depth
  // then prints counted leaf nodes and elapsed time.
  void perft(Position& pos, UCIParser& up) {
    int depth, time;
    int64_t n;
    if (!(up >> depth))
        return;
-    time = get_system_time();
+    pos.set(fen, Options["UCI_Chess960"], Threads.main());
    SetupStates = Search::StateStackPtr(new std::stack<StateInfo>());
-    n = perft(pos, depth * ONE_PLY);
+    // Parse move list (if any)
-
+    while (is >> token && (m = UCI::to_move(pos, token)) != MOVE_NONE)
-    time = get_system_time() - time;
+    {
-
+        SetupStates->push(StateInfo());
-    std::cout << "\nNodes " << n
+        pos.do_move(m, SetupStates->top());
-              << "\nTime (ms) " << time
+    }
              << "\nNodes/second " << int(n / (time / 1000.0)) << std::endl;
  }
  // setoption() is called when engine receives the "setoption" UCI command. The
  // function updates the UCI option ("name") to the given value ("value").
  void setoption(istringstream& is) {
    string token, name, value;
    is >> token; // Consume "name" token
    // Read option name (can contain spaces)
    while (is >> token && token != "value")
        name += string(" ", !name.empty()) + token;
    // Read option value (can contain spaces)
    while (is >> token)
        value += string(" ", !value.empty()) + token;
    if (Options.count(name))
        Options[name] = value;
    else
        sync_cout << "No such option: " << name << sync_endl;
  }
  // go() is called when engine receives the "go" UCI command. The function sets
  // the thinking time and other parameters from the input string, then starts
  // the search.
  void go(const Position& pos, istringstream& is) {
    Search::LimitsType limits;
    string token;
    while (is >> token)
        if (token == "searchmoves")
            while (is >> token)
                limits.searchmoves.push_back(UCI::to_move(pos, token));
        else if (token == "wtime")     is >> limits.time[WHITE];
        else if (token == "btime")     is >> limits.time[BLACK];
        else if (token == "winc")      is >> limits.inc[WHITE];
        else if (token == "binc")      is >> limits.inc[BLACK];
        else if (token == "movestogo") is >> limits.movestogo;
        else if (token == "depth")     is >> limits.depth;
        else if (token == "nodes")     is >> limits.nodes;
        else if (token == "movetime")  is >> limits.movetime;
        else if (token == "mate")      is >> limits.mate;
        else if (token == "infinite")  limits.infinite = true;
        else if (token == "ponder")    limits.ponder = true;
    Threads.start_thinking(pos, limits, SetupStates);
  }
 } // namespace
 /// UCI::loop() waits for a command from stdin, parses it and calls the appropriate
 /// function. Also intercepts EOF from stdin to ensure gracefully exiting if the
 /// GUI dies unexpectedly. When called with some command line arguments, e.g. to
 /// run 'bench', once the command is executed the function returns immediately.
 /// In addition to the UCI ones, also some additional debug commands are supported.
 void UCI::loop(int argc, char* argv[]) {
  Position pos(StartFEN, false, Threads.main()); // The root position
  string token, cmd;
  for (int i = 1; i < argc; ++i)
      cmd += std::string(argv[i]) + " ";
  do {
      if (argc == 1 && !getline(cin, cmd)) // Block here waiting for input or EOF
          cmd = "quit";
      istringstream is(cmd);
      token.clear(); // getline() could return empty or blank line
      is >> skipws >> token;
      // The GUI sends 'ponderhit' to tell us to ponder on the same move the
      // opponent has played. In case Signals.stopOnPonderhit is set we are
      // waiting for 'ponderhit' to stop the search (for instance because we
      // already ran out of time), otherwise we should continue searching but
      // switching from pondering to normal search.
      if (    token == "quit"
          ||  token == "stop"
          || (token == "ponderhit" && Search::Signals.stopOnPonderhit))
      {
          Search::Signals.stop = true;
          Threads.main()->notify_one(); // Could be sleeping
      }
      else if (token == "ponderhit")
          Search::Limits.ponder = false; // Switch to normal search
      else if (token == "uci")
          sync_cout << "id name " << engine_info(true)
                    << "\n"       << Options
                    << "\nuciok"  << sync_endl;
      else if (token == "isready")    sync_cout << "readyok" << sync_endl;
      else if (token == "ucinewgame") TT.clear();
      else if (token == "go")         go(pos, is);
      else if (token == "position")   position(pos, is);
      else if (token == "setoption")  setoption(is);
      // Additional custom non-UCI commands, useful for debugging
      else if (token == "flip")       pos.flip();
      else if (token == "bench")      benchmark(pos, is);
      else if (token == "d")          sync_cout << pos << sync_endl;
      else if (token == "eval")       sync_cout << Eval::trace(pos) << sync_endl;
      else if (token == "perft")
      {
          int depth;
          stringstream ss;
          is >> depth;
          ss << Options["Hash"]    << " "
             << Options["Threads"] << " " << depth << " current perft";
          benchmark(pos, ss);
      }
      else
          sync_cout << "Unknown command: " << cmd << sync_endl;
  } while (token != "quit" && argc == 1); // Passed args have one-shot behaviour
  Threads.wait_for_think_finished(); // Cannot quit whilst the search is running
 }
 /// UCI::value() converts a Value to a string suitable for use with the UCI
 /// protocol specification:
 ///
 /// cp <x>    The score from the engine's point of view in centipawns.
 /// mate <y>  Mate in y moves, not plies. If the engine is getting mated
 ///           use negative values for y.
 string UCI::value(Value v) {
  stringstream ss;
  if (abs(v) < VALUE_MATE - MAX_PLY)
      ss << "cp " << v * 100 / PawnValueEg;
  else
      ss << "mate " << (v > 0 ? VALUE_MATE - v + 1 : -VALUE_MATE - v) / 2;
  return ss.str();
 }
 /// UCI::square() converts a Square to a string in algebraic notation (g1, a7, etc.)
 std::string UCI::square(Square s) {
  char sq[] = { char('a' + file_of(s)), char('1' + rank_of(s)), 0 }; // NULL terminated
  return sq;
 }
 /// UCI::move() converts a Move to a string in coordinate notation (g1f3, a7a8q).
 /// The only special case is castling, where we print in the e1g1 notation in
 /// normal chess mode, and in e1h1 notation in chess960 mode. Internally all
 /// castling moves are always encoded as 'king captures rook'.
 string UCI::move(Move m, bool chess960) {
  Square from = from_sq(m);
  Square to = to_sq(m);
  if (m == MOVE_NONE)
      return "(none)";
  if (m == MOVE_NULL)
      return "0000";
  if (type_of(m) == CASTLING && !chess960)
      to = make_square(to > from ? FILE_G : FILE_C, rank_of(from));
  string move = UCI::square(from) + UCI::square(to);
  if (type_of(m) == PROMOTION)
      move += " pnbrqk"[promotion_type(m)];
  return move;
 }
 /// UCI::to_move() converts a string representing a move in coordinate notation
 /// (g1f3, a7a8q) to the corresponding legal Move, if any.
 Move UCI::to_move(const Position& pos, string& str) {
  if (str.length() == 5) // Junior could send promotion piece in uppercase
      str[4] = char(tolower(str[4]));
  for (MoveList<LEGAL> it(pos); *it; ++it)
      if (str == UCI::move(*it, pos.is_chess960()))
          return *it;
  return MOVE_NONE;
 }
@@ -0,0 +1,78 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
  the Free Software Foundation, either version 3 of the License, or
  (at your option) any later version.
  Stockfish is distributed in the hope that it will be useful,
  but WITHOUT ANY WARRANTY; without even the implied warranty of
  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  GNU General Public License for more details.
  You should have received a copy of the GNU General Public License
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
 #ifndef UCIOPTION_H_INCLUDED
 #define UCIOPTION_H_INCLUDED
 #include <map>
 #include <string>
 #include "types.h"
 class Position;
 namespace UCI {
 class Option;
 /// Custom comparator because UCI options should be case insensitive
 struct CaseInsensitiveLess {
  bool operator() (const std::string&, const std::string&) const;
 };
 /// Our options container is actually a std::map
 typedef std::map<std::string, Option, CaseInsensitiveLess> OptionsMap;
 /// Option class implements an option as defined by UCI protocol
 class Option {
  typedef void (*OnChange)(const Option&);
 public:
  Option(OnChange = NULL);
  Option(bool v, OnChange = NULL);
  Option(const char* v, OnChange = NULL);
  Option(int v, int min, int max, OnChange = NULL);
  Option& operator=(const std::string&);
  void operator<<(const Option&);
  operator int() const;
  operator std::string() const;
 private:
  friend std::ostream& operator<<(std::ostream&, const OptionsMap&);
  std::string defaultValue, currentValue, type;
  int min, max;
  size_t idx;
  OnChange on_change;
 };
 void init(OptionsMap&);
 void loop(int argc, char* argv[]);
 std::string value(Value v);
 std::string square(Square s);
 std::string move(Move m, bool chess960);
 Move to_move(const Position& pos, std::string& str);
 } // namespace UCI
 extern UCI::OptionsMap Options;
 #endif // #ifndef UCIOPTION_H_INCLUDED
@@ -1,7 +1,7 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
+  Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
@@ -17,154 +17,146 @@
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
-#include <cctype>
+#include <algorithm>
-#include <iostream>
+#include <cassert>
 #include <cstdlib>
 #include <sstream>
 #include "misc.h"
 #include "thread.h"
-#include "ucioption.h"
+#include "tt.h"
 #include "uci.h"
 #include "syzygy/tbprobe.h"
 using std::string;
 using std::cout;
 using std::endl;
-OptionsMap Options; // Global object
+UCI::OptionsMap Options; // Global object
 namespace UCI {
 /// 'On change' actions, triggered by an option's value change
 void on_clear_hash(const Option&) { TT.clear(); }
 void on_hash_size(const Option& o) { TT.resize(o); }
 void on_logger(const Option& o) { start_logger(o); }
 void on_threads(const Option&) { Threads.read_uci_options(); }
 void on_tb_path(const Option& o) { Tablebases::init(o); }
-// Our case insensitive less() function as required by UCI protocol
+/// Our case insensitive less() function as required by UCI protocol
 bool ci_less(char c1, char c2) { return tolower(c1) < tolower(c2); }
 bool CaseInsensitiveLess::operator() (const string& s1, const string& s2) const {
-
+  return std::lexicographical_compare(s1.begin(), s1.end(), s2.begin(), s2.end(), ci_less);
  int c1, c2;
  size_t i = 0;
  while (i < s1.size() && i < s2.size())
  {
      c1 = tolower(s1[i]);
      c2 = tolower(s2[i++]);
      if (c1 != c2)
          return c1 < c2;
  }
  return s1.size() < s2.size();
 }
-// stringify() converts a numeric value of type T to a std::string
+/// init() initializes the UCI options to their hard-coded default values
 template<typename T>
 static string stringify(const T& v) {
-  std::ostringstream ss;
+void init(OptionsMap& o) {
-  ss << v;
+
-  return ss.str();
+  const int MaxHashMB = Is64Bit ? 1024 * 1024 : 2048;
  o["Write Debug Log"]       << Option(false, on_logger);
  o["Contempt"]              << Option(0, -100, 100);
  o["Min Split Depth"]       << Option(0, 0, 12, on_threads);
  o["Threads"]               << Option(1, 1, MAX_THREADS, on_threads);
  o["Hash"]                  << Option(16, 1, MaxHashMB, on_hash_size);
  o["Clear Hash"]            << Option(on_clear_hash);
  o["Ponder"]                << Option(true);
  o["MultiPV"]               << Option(1, 1, 500);
  o["Skill Level"]           << Option(20, 0, 20);
  o["Move Overhead"]         << Option(30, 0, 5000);
  o["Minimum Thinking Time"] << Option(20, 0, 5000);
  o["Slow Mover"]            << Option(80, 10, 1000);
  o["UCI_Chess960"]          << Option(false);
  o["SyzygyPath"]            << Option("<empty>", on_tb_path);
  o["SyzygyProbeDepth"]      << Option(1, 1, 100);
  o["Syzygy50MoveRule"]      << Option(true);
  o["SyzygyProbeLimit"]      << Option(6, 0, 6);
 }
-/// OptionsMap c'tor initializes the UCI options to their hard coded default
+/// operator<<() is used to print all the options default values in chronological
 /// values and initializes the default value of "Threads" and "Minimum Split Depth"
 /// parameters according to the number of CPU cores.
 OptionsMap::OptionsMap() {
  OptionsMap& o = *this;
  o["Use Search Log"] = UCIOption(false);
  o["Search Log Filename"] = UCIOption("SearchLog.txt");
  o["Book File"] = UCIOption("book.bin");
  o["Best Book Move"] = UCIOption(false);
  o["Mobility (Middle Game)"] = UCIOption(100, 0, 200);
  o["Mobility (Endgame)"] = UCIOption(100, 0, 200);
  o["Passed Pawns (Middle Game)"] = UCIOption(100, 0, 200);
  o["Passed Pawns (Endgame)"] = UCIOption(100, 0, 200);
  o["Space"] = UCIOption(100, 0, 200);
  o["Aggressiveness"] = UCIOption(100, 0, 200);
  o["Cowardice"] = UCIOption(100, 0, 200);
  o["Minimum Split Depth"] = UCIOption(4, 4, 7);
  o["Maximum Number of Threads per Split Point"] = UCIOption(5, 4, 8);
  o["Threads"] = UCIOption(1, 1, MAX_THREADS);
  o["Use Sleeping Threads"] = UCIOption(false);
  o["Hash"] = UCIOption(32, 4, 8192);
  o["Clear Hash"] = UCIOption(false, "button");
  o["Ponder"] = UCIOption(true);
  o["OwnBook"] = UCIOption(true);
  o["MultiPV"] = UCIOption(1, 1, 500);
  o["Skill Level"] = UCIOption(20, 0, 20);
  o["Emergency Move Horizon"] = UCIOption(40, 0, 50);
  o["Emergency Base Time"] = UCIOption(200, 0, 30000);
  o["Emergency Move Time"] = UCIOption(70, 0, 5000);
  o["Minimum Thinking Time"] = UCIOption(20, 0, 5000);
  o["UCI_Chess960"] = UCIOption(false);
  o["UCI_AnalyseMode"] = UCIOption(false);
  // Set some SMP parameters accordingly to the detected CPU count
  UCIOption& thr = o["Threads"];
  UCIOption& msd = o["Minimum Split Depth"];
  thr.defaultValue = thr.currentValue = stringify(cpu_count());
  if (cpu_count() >= 8)
      msd.defaultValue = msd.currentValue = stringify(7);
 }
 /// OptionsMap::print_all() returns a string with all the UCI options in chronological
 /// insertion order (the idx field) and in the format defined by the UCI protocol.
-string OptionsMap::print_all() const {
+std::ostream& operator<<(std::ostream& os, const OptionsMap& om) {
-  std::stringstream s;
+  for (size_t idx = 0; idx < om.size(); ++idx)
-
+      for (OptionsMap::const_iterator it = om.begin(); it != om.end(); ++it)
-  for (size_t i = 0; i <= size(); i++)
+          if (it->second.idx == idx)
      for (OptionsMap::const_iterator it = begin(); it != end(); ++it)
          if (it->second.idx == i)
          {
-              const UCIOption& o = it->second;
+              const Option& o = it->second;
-              s << "\noption name " << it->first << " type " << o.type;
+              os << "\noption name " << it->first << " type " << o.type;
              if (o.type != "button")
-                  s << " default " << o.defaultValue;
+                  os << " default " << o.defaultValue;
              if (o.type == "spin")
-                  s << " min " << o.minValue << " max " << o.maxValue;
+                  os << " min " << o.min << " max " << o.max;
              break;
          }
-  return s.str();
+  return os;
 }
-/// Option class c'tors
+/// Option class constructors and conversion operators
-UCIOption::UCIOption(const char* def) : type("string"), minValue(0), maxValue(0), idx(Options.size())
+Option::Option(const char* v, OnChange f) : type("string"), min(0), max(0), on_change(f)
-{ defaultValue = currentValue = def; }
+{ defaultValue = currentValue = v; }
-UCIOption::UCIOption(bool def, string t) : type(t), minValue(0), maxValue(0), idx(Options.size())
+Option::Option(bool v, OnChange f) : type("check"), min(0), max(0), on_change(f)
-{ defaultValue = currentValue = (def ? "true" : "false"); }
+{ defaultValue = currentValue = (v ? "true" : "false"); }
-UCIOption::UCIOption(int def, int minv, int maxv) : type("spin"), minValue(minv), maxValue(maxv), idx(Options.size())
+Option::Option(OnChange f) : type("button"), min(0), max(0), on_change(f)
-{ defaultValue = currentValue = stringify(def); }
+{}
 Option::Option(int v, int minv, int maxv, OnChange f) : type("spin"), min(minv), max(maxv), on_change(f)
 { std::ostringstream ss; ss << v; defaultValue = currentValue = ss.str(); }
-/// set_value() updates currentValue of the Option object. Normally it's up to
+Option::operator int() const {
-/// the GUI to check for option's limits, but we could receive the new value
+  assert(type == "check" || type == "spin");
-/// directly from the user by teminal window. So let's check the bounds anyway.
+  return (type == "spin" ? atoi(currentValue.c_str()) : currentValue == "true");
 }
-void UCIOption::set_value(const string& v) {
+Option::operator std::string() const {
  assert(type == "string");
  return currentValue;
 }
 /// operator<<() inits options and assigns idx in the correct printing order
 void Option::operator<<(const Option& o) {
  static size_t insert_order = 0;
  *this = o;
  idx = insert_order++;
 }
 /// operator=() updates currentValue and triggers on_change() action. It's up to
 /// the GUI to check for option's limits, but we could receive the new value from
 /// the user by console window, so let's check the bounds anyway.
 Option& Option::operator=(const string& v) {
  assert(!type.empty());
-  if (v.empty())
+  if (   (type != "button" && v.empty())
-      return;
+      || (type == "check" && v != "true" && v != "false")
      || (type == "spin" && (atoi(v.c_str()) < min || atoi(v.c_str()) > max)))
      return *this;
-  if ((type == "check" || type == "button") != (v == "true" || v == "false"))
+  if (type != "button")
-      return;
+      currentValue = v;
-  if (type == "spin")
+  if (on_change)
-  {
+      on_change(*this);
      int val = atoi(v.c_str());
      if (val < minValue || val > maxValue)
          return;
  }
-  currentValue = v;
+  return *this;
 }
 } // namespace UCI
@@ -1,85 +0,0 @@
 /*
  Stockfish, a UCI chess playing engine derived from Glaurung 2.1
  Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
  Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
  Stockfish is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
  the Free Software Foundation, either version 3 of the License, or
  (at your option) any later version.
  Stockfish is distributed in the hope that it will be useful,
  but WITHOUT ANY WARRANTY; without even the implied warranty of
  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  GNU General Public License for more details.
  You should have received a copy of the GNU General Public License
  along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */
 #if !defined(UCIOPTION_H_INCLUDED)
 #define UCIOPTION_H_INCLUDED
 #include <cassert>
 #include <cstdlib>
 #include <map>
 #include <string>
 class UCIOption {
 public:
  UCIOption() {} // To be used in a std::map
  UCIOption(const char* defaultValue);
  UCIOption(bool defaultValue, std::string type = "check");
  UCIOption(int defaultValue, int minValue, int maxValue);
  void set_value(const std::string& v);
  template<typename T> T value() const;
 private:
  friend class OptionsMap;
  std::string defaultValue, currentValue, type;
  int minValue, maxValue;
  size_t idx;
 };
 /// Custom comparator because UCI options should not be case sensitive
 struct CaseInsensitiveLess {
  bool operator() (const std::string&, const std::string&) const;
 };
 /// Our options container is actually a map with a customized c'tor
 class OptionsMap : public std::map<std::string, UCIOption, CaseInsensitiveLess> {
 public:
  OptionsMap();
  std::string print_all() const;
 };
 extern OptionsMap Options;
 /// Option::value() definition and specializations
 template<typename T>
 T UCIOption::value() const {
  assert(type == "spin");
  return T(atoi(currentValue.c_str()));
 }
 template<>
 inline std::string UCIOption::value<std::string>() const {
  assert(type == "string");
  return currentValue;
 }
 template<>
 inline bool UCIOption::value<bool>() const {
  assert(type == "check" || type == "button");
  return currentValue == "true";
 }
 #endif // !defined(UCIOPTION_H_INCLUDED)