Stockfish 1.9

Signature is: stockfish bench 128 1 12 default depth Node counts: 10914593 Signed-off-by: Marco Costalba <mcostalba@gmail.com>
Less aggressive move count based futility pruning
2025-12-16 23:26:23 +08:00 · 2010-10-02 09:55:10 +01:00 · 2010-09-26 10:27:15 +01:00 · 2010-09-25 11:24:20 +01:00 · 2010-09-25 11:12:55 +01:00 · 2010-09-24 12:56:45 +01:00
54 changed files with 3827 additions and 4591 deletions
--- a/Readme.txt
+++ b/Readme.txt
@@ -3,7 +3,7 @@
 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, Jos<EFBFBD>, Arena, Sigma Chess, Shredder,
+(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.
@@ -83,8 +83,3 @@ 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.
 6. Feedback
 -----------
 The author's e-mail address is mcostalba@gmail.com
--- a/polyglot.ini
+++ b/polyglot.ini
@@ -7,7 +7,7 @@ EngineCommand = ./stockfish
 Book = false
 BookFile = book.bin
-Log = true
+Log = false
 LogFile = stockfish.log
 Resign = true
@@ -19,28 +19,18 @@ 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
 Pawn Structure (Middle Game) = 100
 Pawn Structure (Endgame) = 100
 Passed Pawns (Middle Game) = 100
 Passed Pawns (Endgame) = 100
 Space = 100
 Aggressiveness = 100
 Cowardice = 100
 King Safety Curve = Quadratic
 Quadratic = Linear
 King Safety Coefficient = 40
 King Safety X Intercept = 0
 King Safety Max Slope = 30
 King Safety Max Value = 500
 Queen Contact Check Bonus = 3
 Queen Check Bonus = 2
 Rook Check Bonus = 1
 Bishop Check Bonus = 1
 Knight Check Bonus = 1
 Discovered Check Bonus = 3
 Mate Threat Bonus = 3
 Check Extension (PV nodes) = 2
 Check Extension (non-PV nodes) = 1
 Single Reply Extension (PV nodes) = 2
@@ -53,11 +43,6 @@ Passed Pawn Extension (PV nodes) = 1
 Passed Pawn Extension (non-PV nodes) = 0
 Pawn Endgame Extension (PV nodes) = 2
 Pawn Endgame Extension (non-PV nodes) = 2
 Full Depth Moves (PV nodes) = 14
 Full Depth Moves (non-PV nodes) = 3
 Threat Depth = 5
 Futility Pruning (Main Search) = true
 Futility Pruning (Quiescence Search) = true
 Randomness = 0
 Minimum Split Depth = 4
 Maximum Number of Threads per Split Point = 5
--- a/src/Makefile
+++ b/src/Makefile
@@ -1,7 +1,7 @@
 # Stockfish, a UCI chess playing engine derived from Glaurung 2.1
-# Copyright (C) 2004-2007 Tord Romstad
+# Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-# Copyright (C) 2008 Marco Costalba
+# Copyright (C) 2008-2010 Marco Costalba, Joona Kiiski, Tord Romstad
-
+#
 # This file is part of Stockfish.
 #
 # Stockfish is free software: you can redistribute it and/or modify
@@ -18,318 +18,490 @@
 # along with this program.  If not, see <http://www.gnu.org/licenses/>.
-### Executable name. Do not change
+### ==========================================================================
 ### Section 1. General Configuration
 ### ==========================================================================
 ### Executable name
 EXE = stockfish
 ### Installation dir definitions
 PREFIX = /usr/local
 BINDIR = $(PREFIX)/bin
-
+### Built-in benchmark for pgo-builds
 ### ==========================================================================
 ### Compiler speed switches for both GCC and ICC. These settings are generally
 ### fast on a broad range of systems, but may be changed experimentally
 ### ==========================================================================
 GCCFLAGS = -O3 -msse
 ICCFLAGS = -fast -msse
 ICCFLAGS-OSX = -fast -mdynamic-no-pic
 ### ==========================================================================
 ### Enable/disable debugging, disabled by default
 ### ==========================================================================
 GCCFLAGS += -DNDEBUG
 ICCFLAGS += -DNDEBUG
 ICCFLAGS-OSX += -DNDEBUG
 ### ==========================================================================
 ### Remove below comments to compile for a big-endian machine
 ### ==========================================================================
 #GCCFLAGS += -DBIGENDIAN
 #ICCFLAGS += -DBIGENDIAN
 #ICCFLAGS-OSX += -DBIGENDIAN
 ### ==========================================================================
 ### Run built-in benchmark for pgo-builds with:  32MB hash  1 thread  10 depth
 ### These settings are generally fast, but may be changed experimentally
 ### ==========================================================================
 PGOBENCH = ./$(EXE) bench 32 1 10 default depth
-
+### Object files
 ### General compiler settings. Do not change
 GCCFLAGS += -g -Wall -fno-exceptions -fno-rtti
 ICCFLAGS += -g -Wall -fno-exceptions -fno-rtti -wd383,869,981,10187,10188,11505,11503
 ICCFLAGS-OSX += -g -Wall -fno-exceptions -fno-rtti -wd383,869,981,10187,10188,11505,11503
 ### General linker settings. Do not change
 LDFLAGS  = -lpthread
 ### Object files. Do not change
 OBJS = application.o bitboard.o pawns.o material.o endgame.o evaluate.o main.o \
 	misc.o move.o movegen.o history.o movepick.o search.o piece.o \
-	position.o direction.o tt.o value.o uci.o ucioption.o \
+	position.o direction.o tt.o uci.o ucioption.o \
-	mersenne.o book.o bitbase.o san.o benchmark.o
+	mersenne.o book.o bitbase.o san.o benchmark.o timeman.o
-### General rules. Do not change
+### ==========================================================================
 ### Section 2. High-level Configuration
 ### ==========================================================================
 #
 # flag                --- Comp switch --- Description
 # ----------------------------------------------------------------------------
 #
 # debug = no/yes      --- -DNDEBUG    --- Enable/Disable debug mode
 # optimize = yes/no   --- (-O3/-fast etc.) --- Enable/Disable optimizations
 # arch = (name)       --- (-arch)     --- Target architecture
 # os = (name)         ---             --- Target operating system
 # bits = 64/32        --- -DIS_64BIT  --- 64-/32-bit operating system
 # bigendian = no/yes  --- -DBIGENDIAN --- big/little-endian byte order
 # prefetch = no/yes   --- -DUSE_PREFETCH  --- Use prefetch x86 asm-instruction
 # bsfq = no/yes       --- -DUSE_BSFQ  --- Use bsfq x86_64 asm-instruction
 #                                     --- (Works only with GCC and ICC 64-bit)
 # popcnt = no/yes     --- -DUSE_POPCNT --- Use popcnt 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
 debug = no
 optimize = yes
 ### 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 ($(ARCH),osx-ppc-64)
 	arch = ppc64
 	os = osx
 	bits = 64
 	bigendian = yes
 	prefetch = no
 	bsfq = no
 	popcnt = no
 endif
 ifeq ($(ARCH),osx-ppc-32)
 	arch = ppc
 	os = osx
 	bits = 32
 	bigendian = yes
 	prefetch = no
 	bsfq = no
 	popcnt = no
 endif
 ifeq ($(ARCH),osx-x86-64)
 	arch = x86_64
 	os = osx
 	bits = 64
 	bigendian = no
 	prefetch = yes
 	bsfq = yes
 	popcnt = no
 endif
 ifeq ($(ARCH),osx-x86-32)
 	arch = i386
 	os = osx
 	bits = 32
 	bigendian = no
 	prefetch = yes
 	bsfq = no
 	popcnt = no
 endif
 ### ==========================================================================
 ### Section 3. Low-level configuration
 ### ==========================================================================
 ### 3.1 Selecting compiler (default = gcc)
 ifeq ($(COMP),)
 	COMP=gcc
 endif
 ifeq ($(COMP),gcc)
 	comp=gcc
 	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),icc)
 	comp=icc
 	CXX=icpc
 	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
 CXXFLAGS = -g -Wall -fno-exceptions -fno-rtti $(EXTRACXXFLAGS)
 ifeq ($(comp),icc)
 	CXXFLAGS += -wd383,869,981,10187,10188,11505,11503
 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
 endif
 ### 3.5 Optimization
 ifeq ($(optimize),yes)
 	ifeq ($(comp),gcc)
 		CXXFLAGS += -O3
 		ifeq ($(os),osx)
 			ifeq ($(arch),i386)
 				CXXFLAGS += -mdynamic-no-pic
 			endif
 			ifeq ($(arch),x86_64)
 				CXXFLAGS += -mdynamic-no-pic
 			endif
 		endif
 	endif
 	ifeq ($(comp),icc)
 		CXXFLAGS += -fast
 		ifeq ($(os),osx)
 			CXXFLAGS += -mdynamic-no-pic
 		endif
 	endif
 endif
 ### 3.6. Bits
 ifeq ($(bits),64)
 	CXXFLAGS += -DIS_64BIT
 endif
 ### 3.7 Endianess
 ifeq ($(bigendian),yes)
 	CXXFLAGS += -DBIGENDIAN
 endif
 ### 3.8 prefetch
 ifeq ($(prefetch),yes)
 	CXXFLAGS += -msse
 	DEPENDFLAGS += -msse
 else
 	CXXFLAGS += -DNO_PREFETCH
 endif
 ### 3.9 bsfq
 ifeq ($(bsfq),yes)
 	CXXFLAGS += -DUSE_BSFQ
 endif
 ### 3.10 popcnt
 ifeq ($(popcnt),yes)
 	CXXFLAGS += -DUSE_POPCNT
 endif
 ### ==========================================================================
 ### Section 4. Public targets
 ### ==========================================================================
 default:
-	$(MAKE) gcc
+	$(MAKE) ARCH=$(ARCH) COMP=$(COMP) build
 help:
 	@echo ""
-	@echo "Makefile options:"
+	@echo "To compile stockfish, type: "
 	@echo ""
-	@echo "make                >  Default: Compiler = g++"
+	@echo "make target ARCH=arch [COMP=comp]"
-	@echo "make gcc-popcnt     >  Compiler = g++ + popcnt-support"
+	@echo ""
-	@echo "make icc            >  Compiler = icpc"
+	@echo "Supported targets:"
-	@echo "make icc-profile    >  Compiler = icpc + automatic pgo-build"
+	@echo ""
-	@echo "make icc-profile-popcnt >  Compiler = icpc + automatic pgo-build + popcnt-support"
+	@echo "build                > Build unoptimized version"
-	@echo "make osx-ppc32      >  PPC-Mac OS X 32 bit. Compiler = g++"
+	@echo "profile-build        > Build PGO-optimized version"
-	@echo "make osx-ppc64      >  PPC-Mac OS X 64 bit. Compiler = g++"
+	@echo "popcnt-profile-build > Build PGO-optimized version with optional popcnt-support"
-	@echo "make osx-x86        >  x86-Mac OS X 32 bit. Compiler = g++"
+	@echo "strip                > Strip executable"
-	@echo "make osx-x86_64     >  x86-Mac OS X 64 bit. Compiler = g++"
+	@echo "install              > Install executable"
-	@echo "make osx-icc32      >  x86-Mac OS X 32 bit. Compiler = icpc"
+	@echo "clean                > Clean up"
-	@echo "make osx-icc64      >  x86-Mac OS X 64 bit. Compiler = icpc"
+	@echo "testrun              > Make sample run"
-	@echo "make osx-icc32-profile > OSX 32 bit. Compiler = icpc + automatic pgo-build"
+	@echo ""
-	@echo "make osx-icc64-profile > OSX 64 bit. Compiler = icpc + automatic pgo-build"
+	@echo "Supported archs:"
-	@echo "make hpux           >  HP-UX. Compiler = aCC"
+	@echo ""
-	@echo "make strip          >  Strip executable"
+	@echo "x86-64               > x86 64-bit"
-	@echo "make clean          >  Clean up"
+	@echo "x86-64-modern        > x86 64-bit with runtime support for popcnt-instruction"
 	@echo "x86-32               > x86 32-bit excluding very old hardware without SSE-support"
 	@echo "x86-32-old           > x86 32-bit including also very old hardware"
 	@echo "osx-ppc-64           > PPC-Mac OS X 64 bit"
 	@echo "osx-ppc-32           > PPC-Mac OS X 32 bit"
 	@echo "osx-x86-64           > x86-Mac OS X 64 bit"
 	@echo "osx-x86-32           > x86-Mac OS X 32 bit"
 	@echo "general-64           > unspecified 64-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 ""
 	@echo "gcc                  > Gnu compiler (default)"
 	@echo "icc                  > Intel compiler"
 	@echo ""
 	@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 profile-build ARCH=x86-32    (This is for 32-bit systems)"
 	@echo ""
-all: $(EXE) .depend
+build:
 	$(MAKE) ARCH=$(ARCH) COMP=$(COMP) config-sanity
 	$(MAKE) ARCH=$(ARCH) COMP=$(COMP) all
-test check: default
+profile-build:
-	@$(PGOBENCH)
+	$(MAKE) ARCH=$(ARCH) COMP=$(COMP) config-sanity
-
+	@echo ""
-clean:
+	@echo "Step 0/4. Preparing for profile build."
-	$(RM) *.o .depend *~ $(EXE) core bench.txt
+	$(MAKE) ARCH=$(ARCH) COMP=$(COMP) $(profile_prepare)
-
+	@echo ""
-
+	@echo "Step 1/4. Building executable for benchmark ..."
 ### Possible targets. You may add your own ones here
 gcc:
 	$(MAKE) \
 	CXX='g++' \
 	CXXFLAGS="$(GCCFLAGS)" \
 	all
 gcc-popcnt:
 	$(MAKE) \
 	CXX='g++' \
 	CXXFLAGS="$(GCCFLAGS) -DUSE_POPCNT" \
 	all
 icc:
 	$(MAKE) \
 	CXX='icpc' \
 	CXXFLAGS="$(ICCFLAGS)" \
 	all
 icc-profile-make:
 	$(MAKE) \
 	CXX='icpc' \
 	CXXFLAGS="$(ICCFLAGS)" \
 	CXXFLAGS+='-prof-gen=srcpos -prof_dir ./profdir' \
 	all
 icc-profile-use:
 	$(MAKE) \
 	CXX='icpc' \
 	CXXFLAGS="$(ICCFLAGS)" \
 	CXXFLAGS+='-prof_use -prof_dir ./profdir' \
 	all
 icc-profile:
 	@rm -rf profdir
 	@mkdir profdir
 	@touch *.cpp *.h
-	$(MAKE) icc-profile-make
+	$(MAKE) ARCH=$(ARCH) COMP=$(COMP) $(profile_make)
 	@echo ""
-	@echo "Running benchmark for pgo-build ..."
+	@echo "Step 2/4. Running benchmark for pgo-build ..."
 	@$(PGOBENCH) > /dev/null
 	@echo "Benchmark finished. Build final executable now ..."
 	@echo ""
-	@touch *.cpp *.h
+	@echo "Step 3/4. Building final executable ..."
-	$(MAKE) icc-profile-use
+	@touch *.cpp
-	@rm -rf profdir bench.txt
+	$(MAKE) ARCH=$(ARCH) COMP=$(COMP) $(profile_use)
 icc-profile-make-with-popcnt:
 	$(MAKE) \
 	CXX='icpc' \
 	CXXFLAGS="$(ICCFLAGS) -DUSE_POPCNT" \
 	CXXFLAGS+='-prof-gen=srcpos -prof_dir ./profdir' \
 	all
 icc-profile-use-with-popcnt:
 	$(MAKE) \
 	CXX='icpc' \
 	CXXFLAGS="$(ICCFLAGS) -DUSE_POPCNT" \
 	CXXFLAGS+='-prof_use -prof_dir ./profdir' \
 	all
 icc-profile-popcnt:
 	@rm -rf profdir
 	@mkdir profdir
 	@touch *.cpp *.h
 	$(MAKE) icc-profile-make
 	@echo ""
-	@echo "Running benchmark for pgo-build (popcnt disabled)..."
+	@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
 	@touch *.cpp *.h
 	$(MAKE) icc-profile-make-with-popcnt
 	@echo ""
-	@echo "Running benchmark for pgo-build (popcnt enabled)..."
+	@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 "Benchmarks finished. Build final executable now ..."
 	@echo ""
 	@echo "Step 5/6. Building final executable ..."
 	@touch *.cpp *.h
-	$(MAKE) icc-profile-use-with-popcnt
+	$(MAKE) ARCH=$(ARCH) COMP=$(COMP) $(profile_use)
 	@rm -rf profdir bench.txt
 osx-ppc32:
 	$(MAKE) \
 	CXX='g++' \
 	CXXFLAGS="$(GCCFLAGS)" \
 	CXXFLAGS+='-arch ppc' \
 	CXXFLAGS+='-DBIGENDIAN' \
 	LDFLAGS+='-arch ppc' \
 	all
 osx-ppc64:
 	$(MAKE) \
 	CXX='g++' \
 	CXXFLAGS="$(GCCFLAGS)" \
 	CXXFLAGS+='-arch ppc64' \
 	CXXFLAGS+='-DBIGENDIAN' \
 	LDFLAGS+='-arch ppc64' \
 	all
 osx-x86:
 	$(MAKE) \
 	CXX='g++' \
 	CXXFLAGS="$(GCCFLAGS)" \
 	CXXFLAGS+='-arch i386 -mdynamic-no-pic' \
 	LDFLAGS+='-arch i386 -mdynamic-no-pic' \
 	all
 osx-x86_64:
 	$(MAKE) \
 	CXX='g++' \
 	CXXFLAGS="$(GCCFLAGS)" \
 	CXXFLAGS+='-arch x86_64 -mdynamic-no-pic' \
 	LDFLAGS+='-arch x86_64 -mdynamic-no-pic' \
 	all
 osx-icc32:
 	$(MAKE) \
 	CXX='icpc' \
 	CXXFLAGS="$(ICCFLAGS-OSX)" \
 	CXXFLAGS+='-arch i386' \
 	LDFLAGS+='-arch i386' \
 	all
 osx-icc64:
 	$(MAKE) \
 	CXX='icpc' \
 	CXXFLAGS="$(ICCFLAGS-OSX)" \
 	CXXFLAGS+='-arch x86_64' \
 	LDFLAGS+='-arch x86_64' \
 	all
 osx-icc32-profile-make:
 	$(MAKE) \
 	CXX='icpc' \
 	CXXFLAGS="$(ICCFLAGS-OSX)" \
 	CXXFLAGS+='-arch i386' \
 	CXXFLAGS+='-prof_gen -prof_dir ./profdir' \
 	LDFLAGS+='-arch i386' \
 	all
 osx-icc32-profile-use:
 	$(MAKE) \
 	CXX='icpc' \
 	CXXFLAGS="$(ICCFLAGS-OSX)" \
 	CXXFLAGS+='-arch i386' \
 	CXXFLAGS+='-prof_use -prof_dir ./profdir' \
 	LDFLAGS+='-arch i386' \
 	all
 osx-icc32-profile:
 	@rm -rf profdir
 	@mkdir profdir
 	@touch *.cpp *.h
 	$(MAKE) osx-icc32-profile-make
 	@echo ""
-	@echo "Running benchmark for pgo-build ..."
+	@echo "Step 6/6. Deleting profile data ..."
-	@$(PGOBENCH) > /dev/null
+	$(MAKE) ARCH=$(ARCH) COMP=$(COMP) $(profile_clean)
 	@echo "Benchmark finished. Build final executable now ..."
 	@echo ""
 	@touch *.cpp *.h
 	$(MAKE) osx-icc32-profile-use
 	@rm -rf profdir bench.txt
 osx-icc64-profile-make:
 	$(MAKE) \
 	CXX='icpc' \
 	CXXFLAGS="$(ICCFLAGS-OSX)" \
 	CXXFLAGS+='-arch x86_64' \
 	CXXFLAGS+='-prof_gen -prof_dir ./profdir' \
 	LDFLAGS+='-arch x86_64' \
 	all
 osx-icc64-profile-use:
 	$(MAKE) \
 	CXX='icpc' \
 	CXXFLAGS="$(ICCFLAGS-OSX)" \
 	CXXFLAGS+='-arch x86_64' \
 	CXXFLAGS+='-prof_use -prof_dir ./profdir' \
 	LDFLAGS+='-arch x86_64' \
 	all
 osx-icc64-profile:
 	@rm -rf profdir
 	@mkdir profdir
 	@touch *.cpp *.h
 	$(MAKE) osx-icc64-profile-make
 	@echo ""
 	@echo "Running benchmark for pgo-build ..."
 	@$(PGOBENCH) > /dev/null
 	@echo "Benchmark finished. Build final executable now ..."
 	@echo ""
 	@touch *.cpp *.h
 	$(MAKE) osx-icc64-profile-use
 	@rm -rf profdir bench.txt
 hpux:
 	$(MAKE) \
 	CXX='/opt/aCC/bin/aCC -AA +hpxstd98 -DBIGENDIAN -mt +O3 -DNDEBUG' \
 	CXXFLAGS="" \
 	LDFLAGS="" \
 	all
 strip:
 	strip $(EXE)
-
+install:
 ### Compilation. Do not change
 $(EXE): $(OBJS)
 	$(CXX) $(LDFLAGS) -o $@ $(OBJS)
 ### Installation
 install: default
 	-mkdir -p -m 755 $(BINDIR)
 	-cp $(EXE) $(BINDIR)
 	-strip $(BINDIR)/$(EXE)
-### Dependencies. Do not change
+clean:
 	$(RM) $(EXE) *.o .depend *~ core bench.txt *.gcda
 testrun:
 	@$(PGOBENCH)
 ### ==========================================================================
 ### Section 5. Private targets
 ### ==========================================================================
 all: $(EXE) .depend
 config-sanity:
 	@echo ""
 	@echo "Config:"
 	@echo "debug: '$(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 ""
 	@echo "Flags:"
 	@echo "CXX: $(CXX)"
 	@echo "CXXFLAGS: $(CXXFLAGS)"
 	@echo "LDFLAGS: $(LDFLAGS)"
 	@echo ""
 	@echo "Testing config sanity. If this fails, try 'make help' ..."
 	@echo ""
 	@test "$(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 "$(os)" = "any" || test "$(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"
 $(EXE): $(OBJS)
 	$(CXX) -o $@ $(OBJS) $(LDFLAGS)
 gcc-profile-prepare:
 	$(MAKE) ARCH=$(ARCH) COMP=$(COMP) gcc-profile-clean
 gcc-profile-make:
 	$(MAKE) ARCH=$(ARCH) COMP=$(COMP) \
 	EXTRACXXFLAGS='-fprofile-generate' \
 	EXTRALDFLAGS='-lgcov' \
 	all
 gcc-profile-use:
 	$(MAKE) ARCH=$(ARCH) COMP=$(COMP) \
 	EXTRACXXFLAGS='-fprofile-use' \
 	all
 gcc-profile-clean:
 	@rm -rf *.gcda *.gcno bench.txt
 icc-profile-prepare:
 	$(MAKE) ARCH=$(ARCH) COMP=$(COMP) icc-profile-clean
 	@mkdir profdir
 icc-profile-make:
 	$(MAKE) ARCH=$(ARCH) COMP=$(COMP) \
 	EXTRACXXFLAGS='-prof-gen=srcpos -prof_dir ./profdir' \
 	all
 icc-profile-use:
 	$(MAKE) ARCH=$(ARCH) COMP=$(COMP) \
 	EXTRACXXFLAGS='-prof_use -prof_dir ./profdir' \
 	all
 icc-profile-clean:
 	@rm -rf profdir bench.txt
 .depend:
-	-@$(CXX) -msse -MM $(OBJS:.o=.cpp) > $@ 2> /dev/null
+	-@$(CXX) $(DEPENDFLAGS) -MM $(OBJS:.o=.cpp) > $@ 2> /dev/null
 -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
--- a/src/application.cpp
+++ b/src/application.cpp
@@ -57,12 +57,6 @@ Application::Application() {
        genrand_int32();
 }
 Application::~Application() {
  exit_threads();
  quit_eval();
 }
 void Application::initialize() {
  // A static Application object is allocated
@@ -70,7 +64,15 @@ void Application::initialize() {
  static Application singleton;
 }
 void Application::free_resources() {
  // Warning, following functions reference global objects that
  // must be still alive when free_resources() is called.
  exit_threads();
  quit_eval();
 }
 void Application::exit_with_failure() {
-  exit(EXIT_FAILURE); // d'tor will be called automatically
+  exit(EXIT_FAILURE);
 }
--- a/src/application.h
+++ b/src/application.h
@@ -29,10 +29,10 @@ class Application {
  Application();
  Application(const Application&);
 ~Application();
 public:
  static void initialize();
  static void free_resources();
  static void exit_with_failure();
 };
--- a/src/benchmark.cpp
+++ b/src/benchmark.cpp
@@ -38,8 +38,8 @@ using namespace std;
 const string BenchmarkPositions[] = {
  "rnbqkbnr/pppppppp/8/8/8/8/PPPPPPPP/RNBQKBNR w KQkq - 0 1",
-  "r4rk1/1b2qppp/p1n1p3/1p6/1b1PN3/3BRN2/PP3PPP/R2Q2K1 b - - 7 16",
+  "r3k2r/p1ppqpb1/bn2pnp1/3PN3/1p2P3/2N2Q1p/PPPBBPPP/R3K2R w KQkq -",
-  "4r1k1/ppq3pp/3b4/2pP4/2Q1p3/4B1P1/PP5P/R5K1 b - - 0 20",
+  "8/2p5/3p4/KP5r/1R3p1k/8/4P1P1/8 w - -",
  "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",
@@ -51,7 +51,7 @@ const string BenchmarkPositions[] = {
  "r1bq1r1k/b1p1npp1/p2p3p/1p6/3PP3/1B2NN2/PP3PPP/R2Q1RK1 w - - 1 16",
  "3r1rk1/p5pp/bpp1pp2/8/q1PP1P2/b3P3/P2NQRPP/1R2B1K1 b - - 6 22",
  "r1q2rk1/2p1bppp/2Pp4/p6b/Q1PNp3/4B3/PP1R1PPP/2K4R w - - 2 18",
-  "4k2r/1pb2ppp/1p2p3/1R1p4/3P4/2r1PN2/P4PPP/1R4K1 b  - 3 22",
+  "4k2r/1pb2ppp/1p2p3/1R1p4/3P4/2r1PN2/P4PPP/1R4K1 b - - 3 22",
  "3q2k1/pb3p1p/4pbp1/2r5/PpN2N2/1P2P2P/5PP1/Q2R2K1 b - - 4 26"
 };
@@ -151,13 +151,18 @@ void benchmark(const string& commandLine) {
  {
      Move moves[1] = {MOVE_NONE};
      int dummy[2] = {0, 0};
-      Position pos(*it);
+      Position pos(*it, 0);
      cerr << "\nBench position: " << cnt << '/' << positions.size() << endl << endl;
      if (limitType == "perft")
-          totalNodes += perft(pos, maxDepth * OnePly);
+      {
-      else if (!think(pos, false, false, 0, dummy, dummy, 0, maxDepth, maxNodes, secsPerPos, moves))
+          int64_t perftCnt = perft(pos, maxDepth * ONE_PLY);
-          break;
+          cerr << "\nPerft " << maxDepth << " result (nodes searched): " << perftCnt << endl << endl;
-      totalNodes += nodes_searched();
+          totalNodes += perftCnt;
      } else {
          if (!think(pos, false, false, dummy, dummy, 0, maxDepth, maxNodes, secsPerPos, moves))
              break;
          totalNodes += nodes_searched();
      }
  }
  cnt = get_system_time() - startTime;
--- a/src/bitbase.cpp
+++ b/src/bitbase.cpp
@@ -26,7 +26,6 @@
 #include "bitbase.h"
 #include "bitboard.h"
 #include "move.h"
 #include "square.h"
@@ -46,30 +45,22 @@ namespace {
  struct KPKPosition {
    void from_index(int index);
    int to_index() const;
    bool is_legal() const;
    bool is_immediate_draw() const;
    bool is_immediate_win() const;
-    Bitboard wk_attacks() const;
+    Bitboard wk_attacks()   const { return StepAttackBB[WK][whiteKingSquare]; }
-    Bitboard bk_attacks() const;
+    Bitboard bk_attacks()   const { return StepAttackBB[BK][blackKingSquare]; }
-    Bitboard pawn_attacks() const;
+    Bitboard pawn_attacks() const { return StepAttackBB[WP][pawnSquare]; }
    Square whiteKingSquare, blackKingSquare, pawnSquare;
    Color sideToMove;
  };
  const int IndexMax = 2 * 24 * 64 * 64;
-  Result *Bitbase;
+  Result classify_wtm(const KPKPosition& pos, const Result bb[]);
-  const int IndexMax = 2*24*64*64;
+  Result classify_btm(const KPKPosition& pos, const Result bb[]);
  int UnknownCount = 0;
  void initialize();
  bool next_iteration();
  Result classify_wtm(const KPKPosition &p);
  Result classify_btm(const KPKPosition &p);
  int compute_index(Square wksq, Square bksq, Square psq, Color stm);
  int compress_result(Result r);
 }
@@ -78,273 +69,252 @@ namespace {
 ////
 void generate_kpk_bitbase(uint8_t bitbase[]) {
  // Allocate array and initialize:
  Bitbase = new Result[IndexMax];
  initialize();
-  // Iterate until all positions are classified:
+  bool repeat;
  while(next_iteration());
  // Compress bitbase into the supplied parameter:
  int i, j, b;
-  for(i = 0; i < 24576; i++) {
+  KPKPosition pos;
-    for(b = 0, j = 0; j < 8; b |= (compress_result(Bitbase[8*i+j]) << j), j++);
+  Result bb[IndexMax];
-    assert(b == int(uint8_t(b)));
+
-    bitbase[i] = (uint8_t)b;
+  // Initialize table
  for (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;
  }
-  // Release allocated memory:
+  // Iterate until all positions are classified (30 cycles needed)
-  delete [] Bitbase;
+  do {
      repeat = false;
      for (i = 0; i < IndexMax; i++)
          if (bb[i] == RESULT_UNKNOWN)
          {
              pos.from_index(i);
              bb[i] = (pos.sideToMove == WHITE) ? classify_wtm(pos, bb)
                                                : classify_btm(pos, bb);
              if (bb[i] != RESULT_UNKNOWN)
                  repeat = true;
          }
  } while (repeat);
  // Compress result and map into supplied bitbase parameter
  for (i = 0; i < 24576; i++)
  {
      b = 0;
      for (j = 0; j < 8; j++)
          if (bb[8*i+j] == RESULT_WIN || bb[8*i+j] == RESULT_LOSS)
              b |= (1 << j);
      bitbase[i] = (uint8_t)b;
  }
 }
 namespace {
  int compute_index(Square wksq, Square bksq, Square psq, Color stm) {
      int p = int(square_file(psq)) + (int(square_rank(psq)) - 1) * 4;
      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;
+
    int s = (index / 8192) % 24;
    sideToMove = Color(index % 2);
    blackKingSquare = Square((index / 2) % 64);
    whiteKingSquare = Square((index / 128) % 64);
    s = (index / 8192) % 24;
    pawnSquare = make_square(File(s % 4), Rank(s / 4 + 1));
  }
  int KPKPosition::to_index() const {
    return compute_index(whiteKingSquare, blackKingSquare, pawnSquare,
                         sideToMove);
  }
  bool KPKPosition::is_legal() const {
-    if(whiteKingSquare == pawnSquare || whiteKingSquare == blackKingSquare ||
+
-       pawnSquare == blackKingSquare)
+    if (   whiteKingSquare == pawnSquare
-      return false;
+        || whiteKingSquare == blackKingSquare
-    if(sideToMove == WHITE) {
+        || pawnSquare == blackKingSquare)
      if(bit_is_set(this->wk_attacks(), blackKingSquare))
        return false;
      if(bit_is_set(this->pawn_attacks(), blackKingSquare))
        return false;
    if (sideToMove == WHITE)
    {
        if (   bit_is_set(wk_attacks(), blackKingSquare)
            || bit_is_set(pawn_attacks(), blackKingSquare))
            return false;
    }
-    else {
+    else if (bit_is_set(bk_attacks(), whiteKingSquare))
      if(bit_is_set(this->bk_attacks(), whiteKingSquare))
        return false;
-    }
+
    return true;
  }
  bool KPKPosition::is_immediate_draw() const {
    if(sideToMove == BLACK) {
      Bitboard wka = this->wk_attacks();
      Bitboard bka = this->bk_attacks();
-      // Case 1: Stalemate
+    if (sideToMove == BLACK)
-      if((bka & ~(wka | this->pawn_attacks())) == EmptyBoardBB)
+    {
-        return true;
+        Bitboard wka = wk_attacks();
        Bitboard bka = bk_attacks();
-      // Case 2: King can capture pawn
+        // Case 1: Stalemate
-      if(bit_is_set(bka, pawnSquare) && !bit_is_set(wka, pawnSquare))
+        if ((bka & ~(wka | pawn_attacks())) == EmptyBoardBB)
-        return true;
+            return true;
        // Case 2: King can capture pawn
        if (bit_is_set(bka, pawnSquare) && !bit_is_set(wka, pawnSquare))
            return true;
    }
-    else {
+    else
-      // Case 1: Stalemate
+    {
-      if(whiteKingSquare == SQ_A8 && pawnSquare == SQ_A7 &&
+        // Case 1: Stalemate
-         (blackKingSquare == SQ_C7 || blackKingSquare == SQ_C8))
+        if (   whiteKingSquare == SQ_A8
-        return true;
+            && pawnSquare == SQ_A7
            && (blackKingSquare == SQ_C7 || blackKingSquare == SQ_C8))
            return true;
    }
    return false;
  }
  bool KPKPosition::is_immediate_win() const {
-    // The position is an immediate win if it is white to move and the white
+
-    // pawn can be promoted without getting captured:
+    // The position is an immediate win if it is white to move and the
-    return
+    // white pawn can be promoted without getting captured.
-      sideToMove == WHITE &&
+    return   sideToMove == WHITE
-      square_rank(pawnSquare) == RANK_7 &&
+          && square_rank(pawnSquare) == RANK_7
-      (square_distance(blackKingSquare, pawnSquare+DELTA_N) > 1 ||
+          && (   square_distance(blackKingSquare, pawnSquare + DELTA_N) > 1
-       bit_is_set(this->wk_attacks(), pawnSquare+DELTA_N));
+              || bit_is_set(wk_attacks(), pawnSquare + DELTA_N));
  }
-
+  Result classify_wtm(const KPKPosition& pos, const Result bb[]) {
  Bitboard KPKPosition::wk_attacks() const {
    return StepAttackBB[WK][whiteKingSquare];
  }
  Bitboard KPKPosition::bk_attacks() const {
    return StepAttackBB[BK][blackKingSquare];
  }
  Bitboard KPKPosition::pawn_attacks() const {
    return StepAttackBB[WP][pawnSquare];
  }
  void initialize() {
    KPKPosition p;
    for(int i = 0; i < IndexMax; i++) {
      p.from_index(i);
      if(!p.is_legal())
        Bitbase[i] = RESULT_INVALID;
      else if(p.is_immediate_draw())
        Bitbase[i] = RESULT_DRAW;
      else if(p.is_immediate_win())
        Bitbase[i] = RESULT_WIN;
      else {
        Bitbase[i] = RESULT_UNKNOWN;
        UnknownCount++;
      }
    }
  }
  bool next_iteration() {
    KPKPosition p;
    int previousUnknownCount = UnknownCount;
    for(int i = 0; i < IndexMax; i++)
      if(Bitbase[i] == RESULT_UNKNOWN) {
        p.from_index(i);
        Bitbase[i] = (p.sideToMove == WHITE)? classify_wtm(p) : classify_btm(p);
        if(Bitbase[i] == RESULT_WIN || Bitbase[i] == RESULT_LOSS ||
           Bitbase[i] == RESULT_DRAW)
          UnknownCount--;
      }
    return UnknownCount != previousUnknownCount;
  }
  Result classify_wtm(const KPKPosition &p) {
    // 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
+    // of the current position is RESULT_WIN. If all moves lead to positions
-    // classified as RESULT_DRAW, the current position is classified as
+    // classified as RESULT_DRAW, the current position is classified RESULT_DRAW
-    // RESULT_DRAW.  Otherwise, the current position is classified as
+    // otherwise the current position is classified as RESULT_UNKNOWN.
    // RESULT_UNKNOWN.
    bool unknownFound = false;
    Bitboard b;
    Square s;
    int idx;
    // King moves
-    b = p.wk_attacks();
+    b = pos.wk_attacks();
-    while(b) {
+    while (b)
-      s = pop_1st_bit(&b);
+    {
-      switch(Bitbase[compute_index(s, p.blackKingSquare, p.pawnSquare,
+        s = pop_1st_bit(&b);
-                                   BLACK)]) {
+        idx = compute_index(s, pos.blackKingSquare, pos.pawnSquare, BLACK);
      case RESULT_LOSS:
        return RESULT_WIN;
-      case RESULT_UNKNOWN:
+        switch (bb[idx]) {
        unknownFound = true;
        break;
-      case RESULT_DRAW: case RESULT_INVALID:
+        case RESULT_LOSS:
-        break;
+            return RESULT_WIN;
-      default:
+        case RESULT_UNKNOWN:
-        assert(false);
+            unknownFound = true;
-      }
+
        case RESULT_DRAW:
        case RESULT_INVALID:
             break;
         default:
             assert(false);
        }
    }
    // Pawn moves
-    if(square_rank(p.pawnSquare) < RANK_7) {
+    if (square_rank(pos.pawnSquare) < RANK_7)
-      s = p.pawnSquare + DELTA_N;
+    {
-      switch(Bitbase[compute_index(p.whiteKingSquare, p.blackKingSquare, s,
+        s = pos.pawnSquare + DELTA_N;
-                                   BLACK)]) {
+        idx = compute_index(pos.whiteKingSquare, pos.blackKingSquare, s, BLACK);
      case RESULT_LOSS:
        return RESULT_WIN;
-      case RESULT_UNKNOWN:
+        switch (bb[idx]) {
        unknownFound = true;
        break;
      case RESULT_DRAW: case RESULT_INVALID:
        break;
      default:
        assert(false);
      }
      if(square_rank(s) == RANK_3 &&
         s != p.whiteKingSquare && s != p.blackKingSquare) {
        s += DELTA_N;
        switch(Bitbase[compute_index(p.whiteKingSquare, p.blackKingSquare, s,
                                     BLACK)]) {
        case RESULT_LOSS:
-          return RESULT_WIN;
+            return RESULT_WIN;
        case RESULT_UNKNOWN:
-          unknownFound = true;
+            unknownFound = true;
          break;
-        case RESULT_DRAW: case RESULT_INVALID:
+        case RESULT_DRAW:
-          break;
+        case RESULT_INVALID:
            break;
        default:
-          assert(false);
+            assert(false);
        }
      }
    }
-    return unknownFound? RESULT_UNKNOWN : RESULT_DRAW;
+        // Double pawn push
        if (   square_rank(s) == RANK_3
            && s != pos.whiteKingSquare
            && s != pos.blackKingSquare)
        {
            s += DELTA_N;
            idx = compute_index(pos.whiteKingSquare, pos.blackKingSquare, s, BLACK);
            switch (bb[idx]) {
            case RESULT_LOSS:
                return RESULT_WIN;
            case RESULT_UNKNOWN:
                unknownFound = true;
            case RESULT_DRAW:
            case RESULT_INVALID:
                break;
            default:
                assert(false);
            }
        }
    }
    return unknownFound ? RESULT_UNKNOWN : RESULT_DRAW;
  }
-  Result classify_btm(const KPKPosition &p) {
+  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
+    // 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_LOSS. Otherwise, the current position is classified as
    // RESULT_UNKNOWN.
    bool unknownFound = false;
    Bitboard b;
    Square s;
    int idx;
    // King moves
-    b = p.bk_attacks();
+    b = pos.bk_attacks();
-    while(b) {
+    while (b)
-      s = pop_1st_bit(&b);
+    {
-      switch(Bitbase[compute_index(p.whiteKingSquare, s, p.pawnSquare,
+        s = pop_1st_bit(&b);
-                                   WHITE)]) {
+        idx = compute_index(pos.whiteKingSquare, s, pos.pawnSquare, WHITE);
      case RESULT_DRAW:
        return RESULT_DRAW;
-      case RESULT_UNKNOWN:
+        switch (bb[idx]) {
        unknownFound = true;
        break;
-      case RESULT_WIN: case RESULT_INVALID:
+        case RESULT_DRAW:
-        break;
+            return RESULT_DRAW;
-      default:
+        case RESULT_UNKNOWN:
-        assert(false);
+            unknownFound = true;
-      }
+
        case RESULT_WIN:
        case RESULT_INVALID:
            break;
        default:
            assert(false);
        }
    }
-
+    return unknownFound ? RESULT_UNKNOWN : RESULT_LOSS;
    return unknownFound? RESULT_UNKNOWN : RESULT_LOSS;
  }
  int compute_index(Square wksq, Square bksq, Square psq, Color stm) {
    int p = int(square_file(psq)) + (int(square_rank(psq)) - 1) * 4;
    int result = int(stm) + 2*int(bksq) + 128*int(wksq) + 8192*p;
    assert(result >= 0 && result < IndexMax);
    return result;
  }
  int compress_result(Result r) {
    return (r == RESULT_WIN || r == RESULT_LOSS)? 1 : 0;
  }
 }
--- a/src/bitboard.cpp
+++ b/src/bitboard.cpp
@@ -163,7 +163,10 @@ const int RShift[64] = {
 #endif // defined(IS_64BIT)
-const Bitboard SquaresByColorBB[2] = { BlackSquaresBB, WhiteSquaresBB };
+const Bitboard LightSquaresBB = 0x55AA55AA55AA55AAULL;
 const Bitboard DarkSquaresBB  = 0xAA55AA55AA55AA55ULL;
 const Bitboard SquaresByColorBB[2] = { DarkSquaresBB, LightSquaresBB };
 const Bitboard FileBB[8] = {
  FileABB, FileBBB, FileCBB, FileDBB, FileEBB, FileFBB, FileGBB, FileHBB
@@ -226,8 +229,9 @@ Bitboard StepAttackBB[16][64];
 Bitboard RayBB[64][8];
 Bitboard BetweenBB[64][64];
 Bitboard SquaresInFrontMask[2][64];
 Bitboard PassedPawnMask[2][64];
-Bitboard OutpostMask[2][64];
+Bitboard AttackSpanMask[2][64];
 Bitboard BishopPseudoAttacks[64];
 Bitboard RookPseudoAttacks[64];
@@ -246,14 +250,12 @@ namespace {
  void init_ray_bitboards();
  void init_attacks();
  void init_between_bitboards();
  void init_pseudo_attacks();
  Bitboard index_to_bitboard(int index, Bitboard mask);
  Bitboard sliding_attacks(int sq, Bitboard block, int dirs, int deltas[][2],
                           int fmin, int fmax, int rmin, int rmax);
-  Bitboard index_to_bitboard(int index, Bitboard mask);
+  void init_sliding_attacks(Bitboard attacks[], int attackIndex[], Bitboard mask[],
-  void init_sliding_attacks(Bitboard attacks[],
+                            const int shift[], const Bitboard mult[], int deltas[][2]);
                            int attackIndex[], Bitboard mask[],
                            const int shift[2], const Bitboard mult[],
                            int deltas[][2]);
  void init_pseudo_attacks();
 }
@@ -265,11 +267,14 @@ namespace {
 /// standard output.  This is sometimes useful for debugging.
 void print_bitboard(Bitboard b) {
-  for(Rank r = RANK_8; r >= RANK_1; r--) {
+
-    std::cout << "+---+---+---+---+---+---+---+---+" << std::endl;
+  for (Rank r = RANK_8; r >= RANK_1; r--)
-    for(File f = FILE_A; f <= FILE_H; f++)
+  {
-      std::cout << "| " << (bit_is_set(b, make_square(f, r))? 'X' : ' ') << ' ';
+      std::cout << "+---+---+---+---+---+---+---+---+" << std::endl;
-    std::cout << "|" << std::endl;
+      for (File f = FILE_A; f <= FILE_H; f++)
          std::cout << "| " << (bit_is_set(b, make_square(f, r))? 'X' : ' ') << ' ';
      std::cout << "|" << std::endl;
  }
  std::cout << "+---+---+---+---+---+---+---+---+" << std::endl;
 }
@@ -279,8 +284,10 @@ void print_bitboard(Bitboard b) {
 /// 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_ray_bitboards();
  init_attacks();
@@ -326,6 +333,7 @@ const int BitTable[64] = {
 };
 Square first_1(Bitboard b) {
  b ^= (b - 1);
  uint32_t fold = int(b) ^ int(b >> 32);
  return Square(BitTable[(fold * 0x783a9b23) >> 26]);
@@ -368,39 +376,6 @@ Square pop_1st_bit(Bitboard* bb) {
 #endif
 // Optimized bitScanReverse32() implementation by Pascal Georges. Note
 // that first bit is 1, this allow to differentiate between 0 and 1.
 static CACHE_LINE_ALIGNMENT
 const char MsbTable[256] = {
  0, 1, 2, 2, 3, 3, 3, 3, 4, 4, 4, 4, 4, 4, 4, 4, 5, 5, 5, 5, 5, 5, 5, 5,
  5, 5, 5, 5, 5, 5, 5, 5, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6,
  6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 6, 7, 7, 7, 7, 7, 7, 7, 7,
  7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7,
  7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7, 7,
  7, 7, 7, 7, 7, 7, 7, 7, 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, 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, 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, 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, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8, 8
 };
 int bitScanReverse32(uint32_t b)
 {
   int result = 0;
   if (b > 0xFFFF)
   {
      b >>= 16;
      result += 16;
   }
   if (b > 0xFF)
   {
      b >>= 8;
      result += 8;
   }
   return result + MsbTable[b];
 }
 namespace {
@@ -410,39 +385,46 @@ namespace {
  // be necessary to touch any of them.
  void init_masks() {
    SetMaskBB[SQ_NONE] = 0ULL;
    ClearMaskBB[SQ_NONE] = ~SetMaskBB[SQ_NONE];
-    for(Square s = SQ_A1; s <= SQ_H8; s++) {
+
-      SetMaskBB[s] = (1ULL << s);
+    for (Square s = SQ_A1; s <= SQ_H8; s++)
-      ClearMaskBB[s] = ~SetMaskBB[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++) {
+    for (Color c = WHITE; c <= BLACK; c++)
-        PassedPawnMask[c][s] =
+        for (Square s = SQ_A1; s <= SQ_H8; s++)
-          in_front_bb(c, s) & this_and_neighboring_files_bb(s);
+        {
-        OutpostMask[c][s] = in_front_bb(c, s) & neighboring_files_bb(s);
+            SquaresInFrontMask[c][s] = in_front_bb(c, s) & file_bb(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 = 0ULL; b < 256ULL; b++)
        BitCount8Bit[b] = (uint8_t)count_1s(b);
  }
  int remove_bit_8(int i) { return ((i & ~15) >> 1) | (i & 7); }
  void init_ray_bitboards() {
    int d[8] = {1, -1, 16, -16, 17, -17, 15, -15};
-    for(int i = 0; i < 128; i = (i + 9) & ~8) {
+
-      for(int j = 0; j < 8; j++) {
+    for (int i = 0; i < 128; i = (i + 9) & ~8)
-        RayBB[(i&7)|((i>>4)<<3)][j] = EmptyBoardBB;
+        for (int j = 0; j < 8; j++)
-        for(int k = i + d[j]; (k & 0x88) == 0; k += d[j])
+        {
-          set_bit(&(RayBB[(i&7)|((i>>4)<<3)][j]), Square((k&7)|((k>>4)<<3)));
+            RayBB[remove_bit_8(i)][j] = EmptyBoardBB;
-      }
+            for (int k = i + d[j]; (k & 0x88) == 0; k += d[j])
-    }
+                set_bit(&(RayBB[remove_bit_8(i)][j]), Square(remove_bit_8(k)));
        }
  }
  void init_attacks() {
-    int i, j, k, l;
+
-    int step[16][8] =  {
+    const int step[16][8] =  {
      {0},
      {7,9,0}, {17,15,10,6,-6,-10,-15,-17}, {9,7,-7,-9,0}, {8,1,-1,-8,0},
      {9,7,-7,-9,8,1,-1,-8}, {9,7,-7,-9,8,1,-1,-8}, {0}, {0},
@@ -450,105 +432,115 @@ namespace {
      {9,7,-7,-9,8,1,-1,-8}, {9,7,-7,-9,8,1,-1,-8}
    };
-    for(i = 0; i < 64; i++) {
+    for (int i = 0; i < 64; i++)
-      for(j = 0; j <= int(BK); j++) {
+        for (int j = 0; j <= int(BK); j++)
-        StepAttackBB[j][i] = EmptyBoardBB;
+        {
-        for(k = 0; k < 8 && step[j][k] != 0; k++) {
+            StepAttackBB[j][i] = EmptyBoardBB;
-          l = i + step[j][k];
+            for (int k = 0; k < 8 && step[j][k] != 0; k++)
-          if(l >= 0 && l < 64 && abs((i&7) - (l&7)) < 3)
+            {
-            StepAttackBB[j][i] |= (1ULL << l);
+                int l = i + step[j][k];
                if (l >= 0 && l < 64 && abs((i & 7) - (l & 7)) < 3)
                    StepAttackBB[j][i] |= (1ULL << l);
           }
        }
      }
    }
  }
  Bitboard sliding_attacks(int sq, Bitboard block, int dirs, int deltas[][2],
                           int fmin=0, int fmax=7, int rmin=0, int rmax=7) {
    Bitboard result = 0ULL;
-    int rk = sq / 8, fl = sq % 8, r, f, i;
+    int rk = sq / 8;
-    for(i = 0; i < dirs; i++) {
+    int fl = sq % 8;
-      int dx = deltas[i][0], dy = deltas[i][1];
+
-      for(f = fl+dx, r = rk+dy;
+    for (int i = 0; i < dirs; i++)
-          (dx==0 || (f>=fmin && f<=fmax)) && (dy==0 || (r>=rmin && r<=rmax));
+    {
-          f += dx, r += dy) {
+        int dx = deltas[i][0];
-        result |= (1ULL << (f + r*8));
+        int dy = deltas[i][1];
-        if(block & (1ULL << (f + r*8))) break;
+        int f = fl + dx;
-      }
+        int r = rk + dy;
        while (   (dx == 0 || (f >= fmin && f <= fmax))
               && (dy == 0 || (r >= rmin && r <= rmax)))
        {
            result |= (1ULL << (f + r*8));
            if (block & (1ULL << (f + r*8)))
                break;
            f += dx;
            r += dy;
        }
    }
    return result;
  }
  void init_between_bitboards() {
-    SquareDelta step[8] = {
+
-      DELTA_E, DELTA_W, DELTA_N, DELTA_S, DELTA_NE, DELTA_SW, DELTA_NW, DELTA_SE
+    const SquareDelta step[8] = { DELTA_E, DELTA_W, DELTA_N, DELTA_S,
-    };
+                                  DELTA_NE, DELTA_SW, DELTA_NW, DELTA_SE };
-    SignedDirection d;
+
-    for(Square s1 = SQ_A1; s1 <= SQ_H8; s1++)
+    for (Square s1 = SQ_A1; s1 <= SQ_H8; s1++)
-      for(Square s2 = SQ_A1; s2 <= SQ_H8; s2++) {
+        for (Square s2 = SQ_A1; s2 <= SQ_H8; s2++)
-        BetweenBB[s1][s2] = EmptyBoardBB;
+        {
-        d = signed_direction_between_squares(s1, s2);
+            BetweenBB[s1][s2] = EmptyBoardBB;
-        if(d != SIGNED_DIR_NONE)
+            SignedDirection d = signed_direction_between_squares(s1, s2);
-          for(Square s3 = s1 + step[d]; s3 != s2; s3 += step[d])
+
-            set_bit(&(BetweenBB[s1][s2]), s3);
+            if (d != SIGNED_DIR_NONE)
            {
                for (Square s3 = s1 + step[d]; s3 != s2; s3 += step[d])
                    set_bit(&(BetweenBB[s1][s2]), s3);
            }
      }
  }
  Bitboard index_to_bitboard(int index, Bitboard mask) {
-    int i, j, bits = count_1s(mask);
+
    Bitboard result = 0ULL;
-    for(i = 0; i < bits; i++) {
+    int bits = count_1s(mask);
-      j = pop_1st_bit(&mask);
+
-      if(index & (1 << i)) result |= (1ULL << j);
+    for (int i = 0; i < bits; i++)
    {
        int j = pop_1st_bit(&mask);
        if (index & (1 << i))
            result |= (1ULL << j);
    }
    return result;
  }
  void init_sliding_attacks(Bitboard attacks[], int attackIndex[], Bitboard mask[],
                            const int shift[], const Bitboard mult[], int deltas[][2]) {
-  void init_sliding_attacks(Bitboard attacks[],
+    for (int i = 0, index = 0; i < 64; i++)
-                            int attackIndex[], Bitboard mask[],
+    {
-                            const int shift[2], const Bitboard mult[],
+        attackIndex[i] = index;
-                            int deltas[][2]) {
+        mask[i] = sliding_attacks(i, 0ULL, 4, deltas, 1, 6, 1, 6);
    int i, j, k, index = 0;
    Bitboard b;
    for(i = 0; i < 64; i++) {
      attackIndex[i] = index;
      mask[i] = sliding_attacks(i, 0ULL, 4, deltas, 1, 6, 1, 6);
 #if defined(IS_64BIT)
-      j = (1 << (64 - shift[i]));
+        int j = (1 << (64 - shift[i]));
 #else
-      j = (1 << (32 - shift[i]));
+        int j = (1 << (32 - shift[i]));
 #endif
-      for(k = 0; k < j; k++) {
+        for (int k = 0; k < j; k++)
-
+        {
 #if defined(IS_64BIT)
-        b = index_to_bitboard(k, mask[i]);
+            Bitboard b = index_to_bitboard(k, mask[i]);
-        attacks[index + ((b * mult[i]) >> shift[i])] =
+            attacks[index + ((b * mult[i]) >> shift[i])] = sliding_attacks(i, b, 4, deltas);
          sliding_attacks(i, b, 4, deltas);
 #else
-        b = index_to_bitboard(k, mask[i]);
+            Bitboard b = index_to_bitboard(k, mask[i]);
-        attacks[index +
+            unsigned v = int(b) * int(mult[i]) ^ int(b >> 32) * int(mult[i] >> 32);
-                 (unsigned(int(b) * int(mult[i]) ^
+            attacks[index + (v >> shift[i])] = sliding_attacks(i, b, 4, deltas);
                           int(b >> 32) * int(mult[i] >> 32))
                  >> shift[i])] =
          sliding_attacks(i, b, 4, deltas);
 #endif
-      }
+        }
-      index += j;
+        index += j;
    }
  }
  void init_pseudo_attacks() {
-    Square s;
+
-    for(s = SQ_A1; s <= SQ_H8; s++) {
+    for (Square s = SQ_A1; s <= SQ_H8; s++)
-      BishopPseudoAttacks[s] = bishop_attacks_bb(s, EmptyBoardBB);
+    {
-      RookPseudoAttacks[s] = rook_attacks_bb(s, EmptyBoardBB);
+        BishopPseudoAttacks[s] = bishop_attacks_bb(s, EmptyBoardBB);
-      QueenPseudoAttacks[s] = queen_attacks_bb(s, EmptyBoardBB);
+        RookPseudoAttacks[s]   = rook_attacks_bb(s, EmptyBoardBB);
        QueenPseudoAttacks[s]  = queen_attacks_bb(s, EmptyBoardBB);
    }
  }
--- a/src/bitboard.h
+++ b/src/bitboard.h
@@ -36,28 +36,25 @@
 //// Constants and variables
 ////
-const Bitboard EmptyBoardBB = 0ULL;
+const Bitboard EmptyBoardBB = 0;
 const Bitboard WhiteSquaresBB = 0x55AA55AA55AA55AAULL;
 const Bitboard BlackSquaresBB = 0xAA55AA55AA55AA55ULL;
 const Bitboard FileABB = 0x0101010101010101ULL;
-const Bitboard FileBBB = 0x0202020202020202ULL;
+const Bitboard FileBBB = FileABB << 1;
-const Bitboard FileCBB = 0x0404040404040404ULL;
+const Bitboard FileCBB = FileABB << 2;
-const Bitboard FileDBB = 0x0808080808080808ULL;
+const Bitboard FileDBB = FileABB << 3;
-const Bitboard FileEBB = 0x1010101010101010ULL;
+const Bitboard FileEBB = FileABB << 4;
-const Bitboard FileFBB = 0x2020202020202020ULL;
+const Bitboard FileFBB = FileABB << 5;
-const Bitboard FileGBB = 0x4040404040404040ULL;
+const Bitboard FileGBB = FileABB << 6;
-const Bitboard FileHBB = 0x8080808080808080ULL;
+const Bitboard FileHBB = FileABB << 7;
-const Bitboard Rank1BB = 0xFFULL;
+const Bitboard Rank1BB = 0xFF;
-const Bitboard Rank2BB = 0xFF00ULL;
+const Bitboard Rank2BB = Rank1BB << (8 * 1);
-const Bitboard Rank3BB = 0xFF0000ULL;
+const Bitboard Rank3BB = Rank1BB << (8 * 2);
-const Bitboard Rank4BB = 0xFF000000ULL;
+const Bitboard Rank4BB = Rank1BB << (8 * 3);
-const Bitboard Rank5BB = 0xFF00000000ULL;
+const Bitboard Rank5BB = Rank1BB << (8 * 4);
-const Bitboard Rank6BB = 0xFF0000000000ULL;
+const Bitboard Rank6BB = Rank1BB << (8 * 5);
-const Bitboard Rank7BB = 0xFF000000000000ULL;
+const Bitboard Rank7BB = Rank1BB << (8 * 6);
-const Bitboard Rank8BB = 0xFF00000000000000ULL;
+const Bitboard Rank8BB = Rank1BB << (8 * 7);
 extern const Bitboard SquaresByColorBB[2];
 extern const Bitboard FileBB[8];
@@ -74,8 +71,9 @@ extern Bitboard StepAttackBB[16][64];
 extern Bitboard RayBB[64][8];
 extern Bitboard BetweenBB[64][64];
 extern Bitboard SquaresInFrontMask[2][64];
 extern Bitboard PassedPawnMask[2][64];
-extern Bitboard OutpostMask[2][64];
+extern Bitboard AttackSpanMask[2][64];
 extern const uint64_t RMult[64];
 extern const int RShift[64];
@@ -127,9 +125,8 @@ inline void do_move_bb(Bitboard *b, Bitboard move_bb) {
  *b ^= move_bb;
 }
-/// rank_bb() and file_bb() gives a bitboard containing all squares on a given
+/// rank_bb() and file_bb() take a file or a square as input, and return
-/// file or rank.  It is also possible to pass a square as input to these
+/// a bitboard representing all squares on the given file or rank.
 /// functions.
 inline Bitboard rank_bb(Rank r) {
  return RankBB[r];
@@ -156,7 +153,7 @@ inline Bitboard neighboring_files_bb(File f) {
 }
 inline Bitboard neighboring_files_bb(Square s) {
-  return neighboring_files_bb(square_file(s));
+  return NeighboringFilesBB[square_file(s)];
 }
@@ -169,7 +166,7 @@ inline Bitboard this_and_neighboring_files_bb(File f) {
 }
 inline Bitboard this_and_neighboring_files_bb(Square s) {
-  return this_and_neighboring_files_bb(square_file(s));
+  return ThisAndNeighboringFilesBB[square_file(s)];
 }
@@ -195,7 +192,7 @@ inline Bitboard in_front_bb(Color c, Rank r) {
 }
 inline Bitboard in_front_bb(Color c, Square s) {
-  return in_front_bb(c, square_rank(s));
+  return InFrontBB[c][square_rank(s)];
 }
@@ -208,7 +205,7 @@ inline Bitboard behind_bb(Color c, Rank r) {
 }
 inline Bitboard behind_bb(Color c, Square s) {
-  return in_front_bb(opposite_color(c), square_rank(s));
+  return InFrontBB[opposite_color(c)][square_rank(s)];
 }
@@ -274,12 +271,11 @@ inline Bitboard squares_between(Square s1, Square 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.  For instance,
+/// from the point of view of the given color. Definition of the table is:
-/// squares_in_front_of(BLACK, SQ_E4) returns a bitboard with the squares
+/// SquaresInFrontOf[c][s] = in_front_bb(c, s) & file_bb(s)
 /// e3, e2 and e1 set.
 inline Bitboard squares_in_front_of(Color c, Square s) {
-  return in_front_bb(c, s) & file_bb(s);
+  return SquaresInFrontMask[c][s];
 }
@@ -287,33 +283,27 @@ inline Bitboard squares_in_front_of(Color c, Square s) {
 /// behind the square instead of in front of the square.
 inline Bitboard squares_behind(Color c, Square s) {
-  return in_front_bb(opposite_color(c), s) & file_bb(s);
+  return SquaresInFrontMask[opposite_color(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.
+/// 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];
 }
-/// outpost_mask takes a color and a square as input, and returns a bitboard
+/// attack_span_mask takes a color and a square as input, and returns a bitboard
-/// mask which can be used to test whether a piece on the square can possibly
+/// representing all squares that can be attacked by a pawn of the given color
-/// be driven away by an enemy pawn.
+/// 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 outpost_mask(Color c, Square s) {
+inline Bitboard attack_span_mask(Color c, Square s) {
-  return OutpostMask[c][s];
+  return AttackSpanMask[c][s];
 }
 /// isolated_pawn_mask takes a square as input, and returns a bitboard mask
 /// which can be used to test whether a pawn on the given square is isolated.
 inline Bitboard isolated_pawn_mask(Square s) {
  return neighboring_files_bb(s);
 }
@@ -349,7 +339,6 @@ extern Square pop_1st_bit(Bitboard* b);
 extern void print_bitboard(Bitboard b);
 extern void init_bitboards();
 extern int bitScanReverse32(uint32_t b);
 #endif // !defined(BITBOARD_H_INCLUDED)
--- a/src/book.cpp
+++ b/src/book.cpp
@@ -366,7 +366,7 @@ void Book::open(const string& fName) {
  // Get the book size in number of entries
  seekg(0, ios::end);
-  bookSize = tellg() / EntrySize;
+  bookSize = long(tellg()) / EntrySize;
  seekg(0, ios::beg);
  if (!good())
@@ -399,14 +399,15 @@ const string Book::file_name() { // Not const to compile on HP-UX 11.X
 /// Book::get_move() gets a book move for a given position. Returns
 /// MOVE_NONE if no book move is found.
-Move Book::get_move(const Position& pos) {
+Move Book::get_move(const Position& pos, bool findBestMove) {
  if (!is_open() || bookSize == 0)
      return MOVE_NONE;
  int bookMove = 0, scoresSum = 0;
  uint64_t key = book_key(pos);
  BookEntry entry;
  int bookMove = MOVE_NONE;
  int 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_key(key); idx < bookSize; idx++)
@@ -419,6 +420,17 @@ Move Book::get_move(const Position& pos) {
      assert(score > 0);
      // If findBestMove is true choose highest rated book move
      if (findBestMove)
      {
          if (score > bestScore)
          {
              bestScore = score;
              bookMove = entry.move;
          }
          continue;
      }
      // 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.
--- a/src/book.h
+++ b/src/book.h
@@ -61,7 +61,7 @@ public:
  void open(const std::string& fName);
  void close();
  const std::string file_name();
-  Move get_move(const Position& pos);
+  Move get_move(const Position& pos, bool findBestMove);
 private:
  Book& operator>>(uint64_t& n) { n = read_integer(8); return *this; }
--- a/src/color.h
+++ b/src/color.h
@@ -21,6 +21,7 @@
 #if !defined(COLOR_H_INCLUDED)
 #define COLOR_H_INCLUDED
 #include "types.h"
 ////
 //// Types
@@ -32,13 +33,18 @@ enum Color {
  COLOR_NONE
 };
 enum SquareColor {
  DARK,
  LIGHT
 };
 ENABLE_OPERATORS_ON(Color);
 ////
 //// Inline functions
 ////
 inline void operator++ (Color &c, int) { c = Color(int(c) + 1); }
 inline Color opposite_color(Color c) {
  return Color(int(c) ^ 1);
 }
--- a/src/depth.h
+++ b/src/depth.h
@@ -21,40 +21,20 @@
 #if !defined(DEPTH_H_INCLUDED)
 #define DEPTH_H_INCLUDED
 #include "types.h"
 ////
 //// Types
 ////
 enum Depth {
  ONE_PLY = 2,
  DEPTH_ZERO = 0,
-  DEPTH_MAX = 200  // 100 * OnePly;
+  DEPTH_NONE = -127 * ONE_PLY
 };
-
+ENABLE_OPERATORS_ON(Depth);
 ////
 //// Constants
 ////
 const Depth OnePly = Depth(2);
 ////
 //// Inline functions
 ////
 inline Depth operator+ (Depth d, int i) { return Depth(int(d) + i); }
 inline Depth operator+ (Depth d1, Depth d2) { return Depth(int(d1) + int(d2)); }
 inline void operator+= (Depth &d, int i) { d = Depth(int(d) + i); }
 inline void operator+= (Depth &d1, Depth d2) { d1 += int(d2); }
 inline Depth operator- (Depth d, int i) { return Depth(int(d) - i); }
 inline Depth operator- (Depth d1, Depth d2) { return Depth(int(d1) - int(d2)); }
 inline void operator-= (Depth &d, int i) { d = Depth(int(d) - i); }
 inline void operator-= (Depth &d1, Depth d2) { d1 -= int(d2); }
 inline Depth operator* (Depth d, int i) { return Depth(int(d) * i); }
 inline Depth operator* (int i, Depth d) { return Depth(int(d) * i); }
 inline void operator*= (Depth &d, int i) { d = Depth(int(d) * i); }
 inline Depth operator/ (Depth d, int i) { return Depth(int(d) / i); }
 inline void operator/= (Depth &d, int i) { d = Depth(int(d) / i); }
 #endif // !defined(DEPTH_H_INCLUDED)
--- a/src/direction.h
+++ b/src/direction.h
@@ -45,6 +45,8 @@ enum SignedDirection {
  SIGNED_DIR_NONE = 8
 };
 ENABLE_OPERATORS_ON(SignedDirection);
 ////
 //// Variables
@@ -58,14 +60,6 @@ extern uint8_t SignedDirectionTable[64][64];
 //// Inline functions
 ////
 inline void operator++ (Direction& d, int) {
  d = Direction(int(d) + 1);
 }
 inline void operator++ (SignedDirection& d, int) {
  d = SignedDirection(int(d) + 1);
 }
 inline Direction direction_between_squares(Square s1, Square s2) {
  return Direction(DirectionTable[s1][s2]);
 }
--- a/src/endgame.cpp
+++ b/src/endgame.cpp
@@ -65,13 +65,13 @@ namespace {
  // the two kings in basic endgames.
  const int DistanceBonus[8] = { 0, 0, 100, 80, 60, 40, 20, 10 };
  // Bitbase for KP vs K
  uint8_t KPKBitbase[24576];
  // Penalty for big distance between king and knight for the defending king
  // and knight in KR vs KN endgames.
  const int KRKNKingKnightDistancePenalty[8] = { 0, 0, 4, 10, 20, 32, 48, 70 };
  // Bitbase for KP vs K
  uint8_t KPKBitbase[24576];
  // Various inline functions for accessing the above arrays
  inline Value mate_table(Square s) {
    return Value(MateTable[s]);
@@ -99,15 +99,24 @@ namespace {
 //// Functions
 ////
 /// init_bitbases() is called during program initialization, and simply loads
 /// bitbases from disk into memory.  At the moment, there is only the bitbase
 /// for KP vs K, but we may decide to add other bitbases later.
 void init_bitbases() {
  generate_kpk_bitbase(KPKBitbase);
 }
 /// Mate with KX vs K. This function is used to evaluate positions with
 /// King and plenty of material vs a lone king. It simply gives the
 /// attacking side a bonus for driving the defending king towards the edge
 /// of the board, and for keeping the distance between the two kings small.
 template<>
-Value EvaluationFunction<KXK>::apply(const Position& pos) {
+Value EvaluationFunction<KXK>::apply(const Position& pos) const {
-  assert(pos.non_pawn_material(weakerSide) == Value(0));
+  assert(pos.non_pawn_material(weakerSide) == VALUE_ZERO);
-  assert(pos.piece_count(weakerSide, PAWN) == Value(0));
+  assert(pos.piece_count(weakerSide, PAWN) == VALUE_ZERO);
  Square winnerKSq = pos.king_square(strongerSide);
  Square loserKSq = pos.king_square(weakerSide);
@@ -117,23 +126,23 @@ Value EvaluationFunction<KXK>::apply(const Position& pos) {
                 + mate_table(loserKSq)
                 + distance_bonus(square_distance(winnerKSq, loserKSq));
-  if (   pos.piece_count(strongerSide, QUEEN) > 0
+  if (   pos.piece_count(strongerSide, QUEEN)
-      || pos.piece_count(strongerSide, ROOK) > 0
+      || pos.piece_count(strongerSide, ROOK)
      || pos.piece_count(strongerSide, BISHOP) > 1)
      // TODO: check for two equal-colored bishops!
      result += VALUE_KNOWN_WIN;
-  return (strongerSide == pos.side_to_move() ? result : -result);
+  return strongerSide == pos.side_to_move() ? result : -result;
 }
 /// Mate with KBN vs K. This is similar to KX vs K, but we have to drive the
 /// defending king towards a corner square of the right color.
 template<>
-Value EvaluationFunction<KBNK>::apply(const Position& pos) {
+Value EvaluationFunction<KBNK>::apply(const Position& pos) const {
-  assert(pos.non_pawn_material(weakerSide) == Value(0));
+  assert(pos.non_pawn_material(weakerSide) == VALUE_ZERO);
-  assert(pos.piece_count(weakerSide, PAWN) == Value(0));
+  assert(pos.piece_count(weakerSide, PAWN) == VALUE_ZERO);
  assert(pos.non_pawn_material(strongerSide) == KnightValueMidgame + BishopValueMidgame);
  assert(pos.piece_count(strongerSide, BISHOP) == 1);
  assert(pos.piece_count(strongerSide, KNIGHT) == 1);
@@ -143,7 +152,10 @@ Value EvaluationFunction<KBNK>::apply(const Position& pos) {
  Square loserKSq = pos.king_square(weakerSide);
  Square bishopSquare = pos.piece_list(strongerSide, BISHOP, 0);
-  if (square_color(bishopSquare) == BLACK)
+  // kbnk_mate_table() tries to drive toward corners A1 or H8,
  // if we have a bishop that cannot reach the above squares we
  // mirror the kings so to drive enemy toward corners A8 or H1.
  if (!same_color_squares(bishopSquare, SQ_A1))
  {
      winnerKSq = flop_square(winnerKSq);
      loserKSq = flop_square(loserKSq);
@@ -153,16 +165,16 @@ Value EvaluationFunction<KBNK>::apply(const Position& pos) {
                + distance_bonus(square_distance(winnerKSq, loserKSq))
                + kbnk_mate_table(loserKSq);
-  return (strongerSide == pos.side_to_move() ? result : -result);
+  return strongerSide == pos.side_to_move() ? result : -result;
 }
 /// KP vs K. This endgame is evaluated with the help of a bitbase.
 template<>
-Value EvaluationFunction<KPK>::apply(const Position& pos) {
+Value EvaluationFunction<KPK>::apply(const Position& pos) const {
-  assert(pos.non_pawn_material(strongerSide) == Value(0));
+  assert(pos.non_pawn_material(strongerSide) == VALUE_ZERO);
-  assert(pos.non_pawn_material(weakerSide) == Value(0));
+  assert(pos.non_pawn_material(weakerSide) == VALUE_ZERO);
  assert(pos.piece_count(strongerSide, PAWN) == 1);
  assert(pos.piece_count(weakerSide, PAWN) == 0);
@@ -186,9 +198,9 @@ Value EvaluationFunction<KPK>::apply(const Position& pos) {
  if (square_file(wpsq) >= FILE_E)
  {
-    wksq = flop_square(wksq);
+      wksq = flop_square(wksq);
-    bksq = flop_square(bksq);
+      bksq = flop_square(bksq);
-    wpsq = flop_square(wpsq);
+      wpsq = flop_square(wpsq);
  }
  if (!probe_kpk(wksq, wpsq, bksq, stm))
@@ -198,7 +210,7 @@ Value EvaluationFunction<KPK>::apply(const Position& pos) {
                + PawnValueEndgame
                + Value(square_rank(wpsq));
-  return (strongerSide == pos.side_to_move() ? result : -result);
+  return strongerSide == pos.side_to_move() ? result : -result;
 }
@@ -207,7 +219,7 @@ Value EvaluationFunction<KPK>::apply(const Position& pos) {
 /// far advanced with support of the king, while the attacking king is far
 /// away.
 template<>
-Value EvaluationFunction<KRKP>::apply(const Position& pos) {
+Value EvaluationFunction<KRKP>::apply(const Position& pos) const {
  assert(pos.non_pawn_material(strongerSide) == RookValueMidgame);
  assert(pos.piece_count(strongerSide, PAWN) == 0);
@@ -239,7 +251,7 @@ Value EvaluationFunction<KRKP>::apply(const Position& pos) {
  // If the weaker side's king is too far from the pawn and the rook,
  // it's a win
-  else if (   square_distance(bksq, bpsq) - (tempo^1) >= 3
+  else if (   square_distance(bksq, bpsq) - (tempo ^ 1) >= 3
           && square_distance(bksq, wrsq) >= 3)
      result = RookValueEndgame - Value(square_distance(wksq, bpsq));
@@ -257,14 +269,14 @@ Value EvaluationFunction<KRKP>::apply(const Position& pos) {
              + Value(square_distance(bksq, bpsq + DELTA_S) * 8)
              + Value(square_distance(bpsq, queeningSq) * 8);
-  return (strongerSide == pos.side_to_move() ? result : -result);
+  return strongerSide == pos.side_to_move() ? result : -result;
 }
 /// KR vs KB. This is very simple, and always returns drawish scores.  The
 /// score is slightly bigger when the defending king is close to the edge.
 template<>
-Value EvaluationFunction<KRKB>::apply(const Position& pos) {
+Value EvaluationFunction<KRKB>::apply(const Position& pos) const {
  assert(pos.non_pawn_material(strongerSide) == RookValueMidgame);
  assert(pos.piece_count(strongerSide, PAWN) == 0);
@@ -273,14 +285,14 @@ Value EvaluationFunction<KRKB>::apply(const Position& pos) {
  assert(pos.piece_count(weakerSide, BISHOP) == 1);
  Value result = mate_table(pos.king_square(weakerSide));
-  return (pos.side_to_move() == strongerSide ? result : -result);
+  return strongerSide == pos.side_to_move() ? result : -result;
 }
 /// KR vs KN.  The attacking side has slightly better winning chances than
 /// in KR vs KB, particularly if the king and the knight are far apart.
 template<>
-Value EvaluationFunction<KRKN>::apply(const Position& pos) {
+Value EvaluationFunction<KRKN>::apply(const Position& pos) const {
  assert(pos.non_pawn_material(strongerSide) == RookValueMidgame);
  assert(pos.piece_count(strongerSide, PAWN) == 0);
@@ -291,10 +303,12 @@ Value EvaluationFunction<KRKN>::apply(const Position& pos) {
  Square defendingKSq = pos.king_square(weakerSide);
  Square nSq = pos.piece_list(weakerSide, KNIGHT, 0);
-  Value result = Value(10) + mate_table(defendingKSq) +
+  int d = square_distance(defendingKSq, nSq);
-    krkn_king_knight_distance_penalty(square_distance(defendingKSq, nSq));
+  Value result =   Value(10)
                 + mate_table(defendingKSq)
                 + krkn_king_knight_distance_penalty(d);
-  return (strongerSide == pos.side_to_move())? result : -result;
+  return strongerSide == pos.side_to_move() ? result : -result;
 }
@@ -304,7 +318,7 @@ Value EvaluationFunction<KRKN>::apply(const Position& pos) {
 /// for the defending side in the search, this is usually sufficient to be
 /// able to win KQ vs KR.
 template<>
-Value EvaluationFunction<KQKR>::apply(const Position& pos) {
+Value EvaluationFunction<KQKR>::apply(const Position& pos) const {
  assert(pos.non_pawn_material(strongerSide) == QueenValueMidgame);
  assert(pos.piece_count(strongerSide, PAWN) == 0);
@@ -319,11 +333,11 @@ Value EvaluationFunction<KQKR>::apply(const Position& pos) {
                + mate_table(loserKSq)
                + distance_bonus(square_distance(winnerKSq, loserKSq));
-  return (strongerSide == pos.side_to_move())? result : -result;
+  return strongerSide == pos.side_to_move() ? result : -result;
 }
 template<>
-Value EvaluationFunction<KBBKN>::apply(const Position& pos) {
+Value EvaluationFunction<KBBKN>::apply(const Position& pos) const {
  assert(pos.piece_count(strongerSide, BISHOP) == 2);
  assert(pos.non_pawn_material(strongerSide) == 2*BishopValueMidgame);
@@ -345,29 +359,29 @@ Value EvaluationFunction<KBBKN>::apply(const Position& pos) {
  // Bonus for restricting the knight's mobility
  result += Value((8 - count_1s_max_15(pos.attacks_from<KNIGHT>(nsq))) * 8);
-  return (strongerSide == pos.side_to_move() ? result : -result);
+  return strongerSide == pos.side_to_move() ? result : -result;
 }
 /// K and two minors vs K and one or two minors or K and two knights against
 /// king alone are always draw.
 template<>
-Value EvaluationFunction<KmmKm>::apply(const Position&) {
+Value EvaluationFunction<KmmKm>::apply(const Position&) const {
-  return Value(0);
+  return VALUE_ZERO;
 }
 template<>
-Value EvaluationFunction<KNNK>::apply(const Position&) {
+Value EvaluationFunction<KNNK>::apply(const Position&) const {
-  return Value(0);
+  return VALUE_ZERO;
 }
 /// KBPKScalingFunction scales endgames where the stronger side has king,
 /// bishop and one or more pawns. It checks for draws with rook pawns and a
-/// bishop of the wrong color. If such a draw is detected, ScaleFactor(0) is
+/// bishop of the wrong color. If such a draw is detected, SCALE_FACTOR_ZERO is
 /// returned. If not, the return value is SCALE_FACTOR_NONE, i.e. no scaling
 /// will be used.
 template<>
-ScaleFactor ScalingFunction<KBPsK>::apply(const Position& pos) {
+ScaleFactor ScalingFunction<KBPsK>::apply(const Position& pos) const {
  assert(pos.non_pawn_material(strongerSide) == BishopValueMidgame);
  assert(pos.piece_count(strongerSide, BISHOP) == 1);
@@ -387,7 +401,7 @@ ScaleFactor ScalingFunction<KBPsK>::apply(const Position& pos) {
      Square queeningSq = relative_square(strongerSide, make_square(pawnFile, RANK_8));
      Square kingSq = pos.king_square(weakerSide);
-      if (   square_color(queeningSq) != square_color(bishopSq)
+      if (  !same_color_squares(queeningSq, bishopSq)
          && file_distance(square_file(kingSq), pawnFile) <= 1)
      {
          // The bishop has the wrong color, and the defending king is on the
@@ -401,15 +415,15 @@ ScaleFactor ScalingFunction<KBPsK>::apply(const Position& pos) {
          }
          else
          {
-              for(rank = RANK_2; (rank_bb(rank) & pawns) == EmptyBoardBB; rank++) {}
+              for (rank = RANK_2; (rank_bb(rank) & pawns) == EmptyBoardBB; rank++) {}
-              rank = Rank(rank^7);  // HACK to get the relative rank
+              rank = Rank(rank ^ 7);  // HACK to get the relative rank
              assert(rank >= RANK_2 && rank <= RANK_7);
          }
          // If the defending king has distance 1 to the promotion square or
          // is placed somewhere in front of the pawn, it's a draw.
          if (   square_distance(kingSq, queeningSq) <= 1
              || relative_rank(strongerSide, kingSq) >= rank)
-              return ScaleFactor(0);
+              return SCALE_FACTOR_ZERO;
      }
  }
  return SCALE_FACTOR_NONE;
@@ -421,7 +435,7 @@ ScaleFactor ScalingFunction<KBPsK>::apply(const Position& pos) {
 /// It tests for fortress draws with a rook on the third rank defended by
 /// a pawn.
 template<>
-ScaleFactor ScalingFunction<KQKRPs>::apply(const Position& pos) {
+ScaleFactor ScalingFunction<KQKRPs>::apply(const Position& pos) const {
  assert(pos.non_pawn_material(strongerSide) == QueenValueMidgame);
  assert(pos.piece_count(strongerSide, QUEEN) == 1);
@@ -438,7 +452,7 @@ ScaleFactor ScalingFunction<KQKRPs>::apply(const Position& pos) {
  {
      Square rsq = pos.piece_list(weakerSide, ROOK, 0);
      if (pos.attacks_from<PAWN>(rsq, strongerSide) & pos.pieces(PAWN, weakerSide))
-          return ScaleFactor(0);
+          return SCALE_FACTOR_ZERO;
  }
  return SCALE_FACTOR_NONE;
 }
@@ -452,7 +466,7 @@ ScaleFactor ScalingFunction<KQKRPs>::apply(const Position& pos) {
 /// It would also be nice to rewrite the actual code for this function,
 /// which is mostly copied from Glaurung 1.x, and not very pretty.
 template<>
-ScaleFactor ScalingFunction<KRPKR>::apply(const Position &pos) {
+ScaleFactor ScalingFunction<KRPKR>::apply(const Position& pos) const {
  assert(pos.non_pawn_material(strongerSide) == RookValueMidgame);
  assert(pos.piece_count(strongerSide, PAWN) == 1);
@@ -495,7 +509,7 @@ ScaleFactor ScalingFunction<KRPKR>::apply(const Position &pos) {
      && square_distance(bksq, queeningSq) <= 1
      && wksq <= SQ_H5
      && (square_rank(brsq) == RANK_6 || (r <= RANK_3 && square_rank(wrsq) != RANK_6)))
-      return ScaleFactor(0);
+      return SCALE_FACTOR_ZERO;
  // The defending side saves a draw by checking from behind in case the pawn
  // has advanced to the 6th rank with the king behind.
@@ -503,13 +517,13 @@ ScaleFactor ScalingFunction<KRPKR>::apply(const Position &pos) {
      && square_distance(bksq, queeningSq) <= 1
      && square_rank(wksq) + tempo <= RANK_6
      && (square_rank(brsq) == RANK_1 || (!tempo && abs(square_file(brsq) - f) >= 3)))
-      return ScaleFactor(0);
+      return SCALE_FACTOR_ZERO;
  if (   r >= RANK_6
      && bksq == queeningSq
      && square_rank(brsq) == RANK_1
      && (!tempo || square_distance(wksq, wpsq) >= 2))
-      return ScaleFactor(0);
+      return SCALE_FACTOR_ZERO;
  // White pawn on a7 and rook on a8 is a draw if black's king is on g7 or h7
  // and the black rook is behind the pawn.
@@ -518,7 +532,7 @@ ScaleFactor ScalingFunction<KRPKR>::apply(const Position &pos) {
      && (bksq == SQ_H7 || bksq == SQ_G7)
      && square_file(brsq) == FILE_A
      && (square_rank(brsq) <= RANK_3 || square_file(wksq) >= FILE_D || square_rank(wksq) <= RANK_5))
-      return ScaleFactor(0);
+      return SCALE_FACTOR_ZERO;
  // If the defending king blocks the pawn and the attacking king is too far
  // away, it's a draw.
@@ -526,7 +540,7 @@ ScaleFactor ScalingFunction<KRPKR>::apply(const Position &pos) {
      && bksq == wpsq + DELTA_N
      && square_distance(wksq, wpsq) - tempo >= 2
      && square_distance(wksq, brsq) - tempo >= 2)
-      return ScaleFactor(0);
+      return SCALE_FACTOR_ZERO;
  // Pawn on the 7th rank supported by the rook from behind usually wins if the
  // attacking king is closer to the queening square than the defending king,
@@ -549,8 +563,8 @@ ScaleFactor ScalingFunction<KRPKR>::apply(const Position &pos) {
          || (    square_distance(wksq, queeningSq) < square_distance(bksq, wrsq) + tempo
              && (square_distance(wksq, wpsq + DELTA_N) < square_distance(bksq, wrsq) + tempo))))
      return ScaleFactor(  SCALE_FACTOR_MAX
-                         - (8 * square_distance(wpsq, queeningSq)
+                         - 8 * square_distance(wpsq, queeningSq)
-                         + 2 * square_distance(wksq, queeningSq)));
+                         - 2 * square_distance(wksq, queeningSq));
  // If the pawn is not far advanced, and the defending king is somewhere in
  // the pawn's path, it's probably a draw.
@@ -570,7 +584,7 @@ ScaleFactor ScalingFunction<KRPKR>::apply(const Position &pos) {
 /// single pattern: If the stronger side has no pawns and the defending king
 /// is actively placed, the position is drawish.
 template<>
-ScaleFactor ScalingFunction<KRPPKRP>::apply(const Position &pos) {
+ScaleFactor ScalingFunction<KRPPKRP>::apply(const Position& pos) const {
  assert(pos.non_pawn_material(strongerSide) == RookValueMidgame);
  assert(pos.piece_count(strongerSide, PAWN) == 2);
@@ -609,43 +623,35 @@ ScaleFactor ScalingFunction<KRPPKRP>::apply(const Position &pos) {
 /// against king. There is just a single rule here: If all pawns are on
 /// the same rook file and are blocked by the defending king, it's a draw.
 template<>
-ScaleFactor ScalingFunction<KPsK>::apply(const Position &pos) {
+ScaleFactor ScalingFunction<KPsK>::apply(const Position& pos) const {
-  assert(pos.non_pawn_material(strongerSide) == Value(0));
+  assert(pos.non_pawn_material(strongerSide) == VALUE_ZERO);
  assert(pos.piece_count(strongerSide, PAWN) >= 2);
-  assert(pos.non_pawn_material(weakerSide) == Value(0));
+  assert(pos.non_pawn_material(weakerSide) == VALUE_ZERO);
  assert(pos.piece_count(weakerSide, PAWN) == 0);
  Square ksq = pos.king_square(weakerSide);
  Bitboard pawns = pos.pieces(PAWN, strongerSide);
  // Are all pawns on the 'a' file?
  if ((pawns & ~FileABB) == EmptyBoardBB)
  {
      // Does the defending king block the pawns?
-      Square ksq = pos.king_square(weakerSide);
+      if (   square_distance(ksq, relative_square(strongerSide, SQ_A8)) <= 1
-      if (square_distance(ksq, relative_square(strongerSide, SQ_A8)) <= 1)
+          || (   square_file(ksq) == FILE_A
-          return ScaleFactor(0);
+              && (in_front_bb(strongerSide, ksq) & pawns) == EmptyBoardBB))
-      else if(   square_file(ksq) == FILE_A
+          return SCALE_FACTOR_ZERO;
              && (in_front_bb(strongerSide, ksq) & pawns) == EmptyBoardBB)
          return ScaleFactor(0);
      else
          return SCALE_FACTOR_NONE;
  }
  // Are all pawns on the 'h' file?
  else if ((pawns & ~FileHBB) == EmptyBoardBB)
  {
    // Does the defending king block the pawns?
-    Square ksq = pos.king_square(weakerSide);
+    if (   square_distance(ksq, relative_square(strongerSide, SQ_H8)) <= 1
-    if (square_distance(ksq, relative_square(strongerSide, SQ_H8)) <= 1)
+        || (   square_file(ksq) == FILE_H
-        return ScaleFactor(0);
+            && (in_front_bb(strongerSide, ksq) & pawns) == EmptyBoardBB))
-    else if (   square_file(ksq) == FILE_H
+        return SCALE_FACTOR_ZERO;
             && (in_front_bb(strongerSide, ksq) & pawns) == EmptyBoardBB)
        return ScaleFactor(0);
    else
        return SCALE_FACTOR_NONE;
  }
-  else
+  return SCALE_FACTOR_NONE;
      return SCALE_FACTOR_NONE;
 }
@@ -655,7 +661,7 @@ ScaleFactor ScalingFunction<KPsK>::apply(const Position &pos) {
 /// it's a draw. If the two bishops have opposite color, it's almost always
 /// a draw.
 template<>
-ScaleFactor ScalingFunction<KBPKB>::apply(const Position &pos) {
+ScaleFactor ScalingFunction<KBPKB>::apply(const Position& pos) const {
  assert(pos.non_pawn_material(strongerSide) == BishopValueMidgame);
  assert(pos.piece_count(strongerSide, BISHOP) == 1);
@@ -672,12 +678,12 @@ ScaleFactor ScalingFunction<KBPKB>::apply(const Position &pos) {
  // Case 1: Defending king blocks the pawn, and cannot be driven away
  if (   square_file(weakerKingSq) == square_file(pawnSq)
      && relative_rank(strongerSide, pawnSq) < relative_rank(strongerSide, weakerKingSq)
-      && (   square_color(weakerKingSq) != square_color(strongerBishopSq)
+      && (  !same_color_squares(weakerKingSq, strongerBishopSq)
          || relative_rank(strongerSide, weakerKingSq) <= RANK_6))
-      return ScaleFactor(0);
+      return SCALE_FACTOR_ZERO;
  // Case 2: Opposite colored bishops
-  if (square_color(strongerBishopSq) != square_color(weakerBishopSq))
+  if (!same_color_squares(strongerBishopSq, weakerBishopSq))
  {
      // We assume that the position is drawn in the following three situations:
      //
@@ -690,15 +696,16 @@ ScaleFactor ScalingFunction<KBPKB>::apply(const Position &pos) {
      // reasonably well.
      if (relative_rank(strongerSide, pawnSq) <= RANK_5)
-          return ScaleFactor(0);
+          return SCALE_FACTOR_ZERO;
      else
      {
          Bitboard ray = ray_bb(pawnSq, (strongerSide == WHITE)? SIGNED_DIR_N : SIGNED_DIR_S);
          if (ray & pos.pieces(KING, weakerSide))
-              return ScaleFactor(0);
+              return SCALE_FACTOR_ZERO;
-          if(  (pos.attacks_from<BISHOP>(weakerBishopSq) & ray)
+
-             && square_distance(weakerBishopSq, pawnSq) >= 3)
+          if (  (pos.attacks_from<BISHOP>(weakerBishopSq) & ray)
-              return ScaleFactor(0);
+              && square_distance(weakerBishopSq, pawnSq) >= 3)
              return SCALE_FACTOR_ZERO;
      }
  }
  return SCALE_FACTOR_NONE;
@@ -708,7 +715,7 @@ ScaleFactor ScalingFunction<KBPKB>::apply(const Position &pos) {
 /// KBPPKBScalingFunction scales KBPP vs KB endgames. It detects a few basic
 /// draws with opposite-colored bishops.
 template<>
-ScaleFactor ScalingFunction<KBPPKB>::apply(const Position& pos) {
+ScaleFactor ScalingFunction<KBPPKB>::apply(const Position& pos) const {
  assert(pos.non_pawn_material(strongerSide) == BishopValueMidgame);
  assert(pos.piece_count(strongerSide, BISHOP) == 1);
@@ -720,7 +727,7 @@ ScaleFactor ScalingFunction<KBPPKB>::apply(const Position& pos) {
  Square wbsq = pos.piece_list(strongerSide, BISHOP, 0);
  Square bbsq = pos.piece_list(weakerSide, BISHOP, 0);
-  if (square_color(wbsq) == square_color(bbsq))
+  if (same_color_squares(wbsq, bbsq))
      // Not opposite-colored bishops, no scaling
      return SCALE_FACTOR_NONE;
@@ -749,8 +756,8 @@ ScaleFactor ScalingFunction<KBPPKB>::apply(const Position& pos) {
    // some square in the frontmost pawn's path.
    if (   square_file(ksq) == square_file(blockSq1)
        && relative_rank(strongerSide, ksq) >= relative_rank(strongerSide, blockSq1)
-        && square_color(ksq) != square_color(wbsq))
+        && !same_color_squares(ksq, wbsq))
-        return ScaleFactor(0);
+        return SCALE_FACTOR_ZERO;
    else
        return SCALE_FACTOR_NONE;
@@ -759,16 +766,17 @@ ScaleFactor ScalingFunction<KBPPKB>::apply(const Position& pos) {
    // in front of the frontmost pawn's path, and the square diagonally behind
    // this square on the file of the other pawn.
    if (   ksq == blockSq1
-        && square_color(ksq) != square_color(wbsq)
+        && !same_color_squares(ksq, wbsq)
        && (   bbsq == blockSq2
            || (pos.attacks_from<BISHOP>(blockSq2) & pos.pieces(BISHOP, weakerSide))
            || rank_distance(r1, r2) >= 2))
-        return ScaleFactor(0);
+        return SCALE_FACTOR_ZERO;
    else if (   ksq == blockSq2
-             && square_color(ksq) != square_color(wbsq)
+             && !same_color_squares(ksq, wbsq)
             && (   bbsq == blockSq1
                 || (pos.attacks_from<BISHOP>(blockSq1) & pos.pieces(BISHOP, weakerSide))))
-        return ScaleFactor(0);
+        return SCALE_FACTOR_ZERO;
    else
        return SCALE_FACTOR_NONE;
@@ -784,7 +792,7 @@ ScaleFactor ScalingFunction<KBPPKB>::apply(const Position& pos) {
 /// square of the king is not of the same color as the stronger side's bishop,
 /// it's a draw.
 template<>
-ScaleFactor ScalingFunction<KBPKN>::apply(const Position &pos) {
+ScaleFactor ScalingFunction<KBPKN>::apply(const Position& pos) const {
  assert(pos.non_pawn_material(strongerSide) == BishopValueMidgame);
  assert(pos.piece_count(strongerSide, BISHOP) == 1);
@@ -799,9 +807,9 @@ ScaleFactor ScalingFunction<KBPKN>::apply(const Position &pos) {
  if (   square_file(weakerKingSq) == square_file(pawnSq)
      && relative_rank(strongerSide, pawnSq) < relative_rank(strongerSide, weakerKingSq)
-      && (   square_color(weakerKingSq) != square_color(strongerBishopSq)
+      && (  !same_color_squares(weakerKingSq, strongerBishopSq)
          || relative_rank(strongerSide, weakerKingSq) <= RANK_6))
-      return ScaleFactor(0);
+      return SCALE_FACTOR_ZERO;
  return SCALE_FACTOR_NONE;
 }
@@ -811,12 +819,12 @@ ScaleFactor ScalingFunction<KBPKN>::apply(const Position &pos) {
 /// If the pawn is a rook pawn on the 7th rank and the defending king prevents
 /// the pawn from advancing, the position is drawn.
 template<>
-ScaleFactor ScalingFunction<KNPK>::apply(const Position &pos) {
+ScaleFactor ScalingFunction<KNPK>::apply(const Position& pos) const {
  assert(pos.non_pawn_material(strongerSide) == KnightValueMidgame);
  assert(pos.piece_count(strongerSide, KNIGHT) == 1);
  assert(pos.piece_count(strongerSide, PAWN) == 1);
-  assert(pos.non_pawn_material(weakerSide) == Value(0));
+  assert(pos.non_pawn_material(weakerSide) == VALUE_ZERO);
  assert(pos.piece_count(weakerSide, PAWN) == 0);
  Square pawnSq = pos.piece_list(strongerSide, PAWN, 0);
@@ -824,11 +832,11 @@ ScaleFactor ScalingFunction<KNPK>::apply(const Position &pos) {
  if (   pawnSq == relative_square(strongerSide, SQ_A7)
      && square_distance(weakerKingSq, relative_square(strongerSide, SQ_A8)) <= 1)
-      return ScaleFactor(0);
+      return SCALE_FACTOR_ZERO;
  if (   pawnSq == relative_square(strongerSide, SQ_H7)
      && square_distance(weakerKingSq, relative_square(strongerSide, SQ_H8)) <= 1)
-      return ScaleFactor(0);
+      return SCALE_FACTOR_ZERO;
  return SCALE_FACTOR_NONE;
 }
@@ -841,10 +849,10 @@ ScaleFactor ScalingFunction<KNPK>::apply(const Position &pos) {
 /// advanced and not on a rook file; in this case it is often possible to win
 /// (e.g. 8/4k3/3p4/3P4/6K1/8/8/8 w - - 0 1).
 template<>
-ScaleFactor ScalingFunction<KPKP>::apply(const Position &pos) {
+ScaleFactor ScalingFunction<KPKP>::apply(const Position& pos) const {
-  assert(pos.non_pawn_material(strongerSide) == Value(0));
+  assert(pos.non_pawn_material(strongerSide) == VALUE_ZERO);
-  assert(pos.non_pawn_material(weakerSide) == Value(0));
+  assert(pos.non_pawn_material(weakerSide) == VALUE_ZERO);
  assert(pos.piece_count(WHITE, PAWN) == 1);
  assert(pos.piece_count(BLACK, PAWN) == 1);
@@ -881,32 +889,21 @@ ScaleFactor ScalingFunction<KPKP>::apply(const Position &pos) {
  // Probe the KPK bitbase with the weakest side's pawn removed. If it's a
  // draw, it's probably at least a draw even with the pawn.
-  if (probe_kpk(wksq, wpsq, bksq, stm))
+  return probe_kpk(wksq, wpsq, bksq, stm) ? SCALE_FACTOR_NONE : SCALE_FACTOR_ZERO;
      return SCALE_FACTOR_NONE;
  else
      return ScaleFactor(0);
 }
 /// init_bitbases() is called during program initialization, and simply loads
 /// bitbases from disk into memory.  At the moment, there is only the bitbase
 /// for KP vs K, but we may decide to add other bitbases later.
 void init_bitbases() {
  generate_kpk_bitbase(KPKBitbase);
 }
 namespace {
-  // Probe the KP vs K bitbase:
+  // Probe the KP vs K bitbase
  int probe_kpk(Square wksq, Square wpsq, Square bksq, Color stm) {
-    int wp = int(square_file(wpsq)) + (int(square_rank(wpsq)) - 1) * 4;
+    int wp = square_file(wpsq) + 4 * (square_rank(wpsq) - 1);
-    int index = int(stm) + 2*int(bksq) + 128*int(wksq) + 8192*wp;
+    int index = int(stm) + 2 * bksq + 128 * wksq + 8192 * wp;
-    assert(index >= 0 && index < 24576*8);
+    assert(index >= 0 && index < 24576 * 8);
-    return KPKBitbase[index/8] & (1 << (index&7));
+
    return KPKBitbase[index / 8] & (1 << (index & 7));
  }
 }
--- a/src/endgame.h
+++ b/src/endgame.h
@@ -26,7 +26,6 @@
 ////
 #include "position.h"
 #include "scale.h"
 #include "value.h"
@@ -68,7 +67,7 @@ class EndgameFunctionBase {
 public:
  EndgameFunctionBase(Color c) : strongerSide(c), weakerSide(opposite_color(c)) {}
  virtual ~EndgameFunctionBase() {}
-  virtual T apply(const Position&) = 0;
+  virtual T apply(const Position&) const = 0;
  Color color() const { return strongerSide; }
 protected:
@@ -85,14 +84,14 @@ template<EndgameType>
 struct EvaluationFunction : public EndgameEvaluationFunctionBase {
  typedef EndgameEvaluationFunctionBase Base;
  explicit EvaluationFunction(Color c): EndgameEvaluationFunctionBase(c) {}
-  Value apply(const Position&);
+  Value apply(const Position&) const;
 };
 template<EndgameType>
 struct ScalingFunction : public EndgameScalingFunctionBase {
  typedef EndgameScalingFunctionBase Base;
  explicit ScalingFunction(Color c) : EndgameScalingFunctionBase(c) {}
-  ScaleFactor apply(const Position&);
+  ScaleFactor apply(const Position&) const;
 };
--- a/src/evaluate.cpp
+++ b/src/evaluate.cpp
--- a/src/evaluate.h
+++ b/src/evaluate.h
@@ -21,94 +21,14 @@
 #if !defined(EVALUATE_H_INCLUDED)
 #define EVALUATE_H_INCLUDED
-////
+#include "color.h"
-//// Includes
+#include "value.h"
 ////
 #include <iostream>
 #include "material.h"
 #include "pawns.h"
 ////
 //// Types
 ////
 /// The EvalInfo struct contains various information computed and collected
 /// by the evaluation function. An EvalInfo object is passed as one of the
 /// arguments to the evaluation function, and the search can make use of its
 /// contents to make intelligent search decisions.
 ///
 /// At the moment, this is not utilized very much: The only part of the
 /// EvalInfo object which is used by the search is futilityMargin.
 class Position;
-struct EvalInfo {
+extern Value evaluate(const Position& pos, Value& margin);
  EvalInfo() { futilityMargin[0] = futilityMargin[1] = Value(0); }
  // Middle game and endgame evaluations
  Score value;
  // Pointers to material and pawn hash table entries
  MaterialInfo* mi;
  PawnInfo* pi;
  // attackedBy[color][piece type] is a bitboard representing all squares
  // attacked by a given color and piece type, attackedBy[color][0] contains
  // all squares attacked by the given color.
  Bitboard attackedBy[2][8];
  Bitboard attacked_by(Color c) const { return attackedBy[c][0]; }
  Bitboard attacked_by(Color c, PieceType pt) const { return attackedBy[c][pt]; }
  // kingZone[color] is the zone around the enemy king which is considered
  // by the king safety evaluation. This consists of the squares directly
  // adjacent to the king, and the three (or two, for a king on an edge file)
  // squares two ranks in front of the king. For instance, if black's king
  // is on g8, kingZone[WHITE] is a bitboard containing the squares f8, h8,
  // f7, g7, h7, f6, g6 and h6.
  Bitboard kingZone[2];
  // kingAttackersCount[color] is the number of pieces of the given color
  // which attack a square in the kingZone of the enemy king.
  int kingAttackersCount[2];
  // kingAttackersWeight[color] is the sum of the "weight" of the pieces of the
  // given color which attack a square in the kingZone of the enemy king. The
  // weights of the individual piece types are given by the variables
  // QueenAttackWeight, RookAttackWeight, BishopAttackWeight and
  // KnightAttackWeight in evaluate.cpp
  int kingAttackersWeight[2];
  // kingAdjacentZoneAttacksCount[color] is the number of attacks to squares
  // directly adjacent to the king of the given color. Pieces which attack
  // more than one square are counted multiple times. For instance, if black's
  // king is on g8 and there's a white knight on g5, this knight adds
  // 2 to kingAdjacentZoneAttacksCount[BLACK].
  int kingAdjacentZoneAttacksCount[2];
  // mateThreat[color] is a move for the given side which gives a direct mate.
  Move mateThreat[2];
  // Middle game and endgame mobility scores.
  Score mobility;
  // Extra futility margin. This is added to the standard futility margin
  // in the quiescence search. One for each color.
  Value futilityMargin[2];
 };
 ////
 //// Prototypes
 ////
 extern Value evaluate(const Position& pos, EvalInfo& ei, int threadID);
 extern void init_eval(int threads);
 extern void quit_eval();
 extern void read_weights(Color sideToMove);
 #endif // !defined(EVALUATE_H_INCLUDED)
--- a/src/history.cpp
+++ b/src/history.cpp
@@ -41,8 +41,8 @@ History::History() { clear(); }
 /// History::clear() clears the history tables
 void History::clear() {
-  memset(history, 0, 2 * 8 * 64 * sizeof(int));
+  memset(history, 0, 16 * 64 * sizeof(int));
-  memset(maxStaticValueDelta, 0, 2 * 8 * 64 * sizeof(int));
+  memset(maxStaticValueDelta, 0, 16 * 64 * sizeof(int));
 }
@@ -85,31 +85,14 @@ void History::failure(Piece p, Square to, Depth d) {
 }
 /// History::move_ordering_score() returns an integer value used to order the
 /// non-capturing moves in the MovePicker class.
 int History::move_ordering_score(Piece p, Square to) const {
  assert(piece_is_ok(p));
  assert(square_is_ok(to));
  return history[p][to];
 }
 /// History::set_gain() and History::gain() store and retrieve the
 /// gain of a move given the delta of the static position evaluations
 /// before and after the move.
-void History::set_gain(Piece p, Square to, Value delta)
+void History::set_gain(Piece p, Square to, Value delta) {
-{
+
  if (delta >= maxStaticValueDelta[p][to])
      maxStaticValueDelta[p][to] = delta;
  else
      maxStaticValueDelta[p][to]--;
 }
 Value History::gain(Piece p, Square to) const
 {
  return Value(maxStaticValueDelta[p][to]);
 }
--- a/src/history.h
+++ b/src/history.h
@@ -49,7 +49,7 @@ public:
  void clear();
  void success(Piece p, Square to, Depth d);
  void failure(Piece p, Square to, Depth d);
-  int move_ordering_score(Piece p, Square to) const;
+  int value(Piece p, Square to) const;
  void set_gain(Piece p, Square to, Value delta);
  Value gain(Piece p, Square to) const;
@@ -71,7 +71,19 @@ private:
 /// recently have a bigger importance for move ordering than the moves which
 /// have been searched a long time ago.
-const int HistoryMax = 50000 * OnePly;
+const int HistoryMax = 50000 * ONE_PLY;
 ////
 //// Inline functions
 ////
 inline int History::value(Piece p, Square to) const {
  return history[p][to];
 }
 inline Value History::gain(Piece p, Square to) const {
  return Value(maxStaticValueDelta[p][to]);
 }
 #endif // !defined(HISTORY_H_INCLUDED)
--- a/src/lock.h
+++ b/src/lock.h
@@ -22,63 +22,13 @@
 #define LOCK_H_INCLUDED
-// x86 assembly language locks or OS spin locks may perform faster than
+#if !defined(_MSC_VER)
 // mutex locks on some platforms. On my machine, mutexes seem to be the
 // best.
 //#define ASM_LOCK
 //#define OS_SPIN_LOCK
 #if defined(ASM_LOCK)
 typedef volatile int Lock;
 static inline void LockX86(Lock *lock) {
  int dummy;
  asm __volatile__("1:          movl    $1, %0" "\n\t"
      "            xchgl   (%1), %0" "\n\t" "            testl   %0, %0" "\n\t"
      "            jz      3f" "\n\t" "2:          pause" "\n\t"
      "            movl    (%1), %0" "\n\t" "            testl   %0, %0" "\n\t"
      "            jnz     2b" "\n\t" "            jmp     1b" "\n\t" "3:"
      "\n\t":"=&q"(dummy)
      :"q"(lock)
      :"cc");
 }
 static inline void UnlockX86(Lock *lock) {
  int dummy;
  asm __volatile__("movl    $0, (%1)":"=&q"(dummy)
      :"q"(lock));
 }
 #  define lock_init(x, y) (*(x) = 0)
 #  define lock_grab(x) LockX86(x)
 #  define lock_release(x) UnlockX86(x)
 #  define lock_destroy(x)
 #elif defined(OS_SPIN_LOCK)
 #  include <libkern/OSAtomic.h>
 typedef OSSpinLock Lock;
 #  define lock_init(x, y) (*(x) = 0)
 #  define lock_grab(x) OSSpinLockLock(x)
 #  define lock_release(x) OSSpinLockUnlock(x)
 #  define lock_destroy(x)
 #elif !defined(_MSC_VER)
 #  include <pthread.h>
 typedef pthread_mutex_t Lock;
-#  define lock_init(x, y) pthread_mutex_init(x, y)
+#  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)
@@ -91,7 +41,7 @@ typedef pthread_mutex_t Lock;
 #undef WIN32_LEAN_AND_MEAN
 typedef CRITICAL_SECTION Lock;
-#  define lock_init(x, y) InitializeCriticalSection(x)
+#  define lock_init(x) InitializeCriticalSection(x)
 #  define lock_grab(x) EnterCriticalSection(x)
 #  define lock_release(x) LeaveCriticalSection(x)
 #  define lock_destroy(x) DeleteCriticalSection(x)
--- a/src/main.cpp
+++ b/src/main.cpp
@@ -57,8 +57,19 @@ int main(int argc, char *argv[]) {
  CALLGRIND_START_INSTRUMENTATION;
 #endif
-  // Process command line arguments if any
+  if (argc <= 1)
-  if (argc > 1)
+  {
      // Print copyright notice
      cout << engine_name()
           << " by Tord Romstad, Marco Costalba, Joona Kiiski" << endl;
      if (CpuHasPOPCNT)
          cout << "Good! CPU has hardware POPCNT." << endl;
      // Enter UCI mode
      uci_main_loop();
  }
  else // Process command line arguments
  {
      if (string(argv[1]) != "bench" || argc < 4 || argc > 8)
          cout << "Usage: stockfish bench <hash size> <threads> "
@@ -68,22 +79,13 @@ int main(int argc, char *argv[]) {
      else
      {
          string time = argc > 4 ? argv[4] : "60";
-          string fen = argc > 5 ? argv[5] : "default";
+          string fen  = argc > 5 ? argv[5] : "default";
-          string lim = argc > 6 ? argv[6] : "time";
+          string lim  = argc > 6 ? argv[6] : "time";
-          string tim = argc > 7 ? argv[7] : "";
+          string tim  = argc > 7 ? argv[7] : "";
          benchmark(string(argv[2]) + " " + string(argv[3]) + " " + time + " " + fen + " " + lim + " " + tim);
      }
      return 0;
  }
-  // Print copyright notice
+  Application::free_resources();
  cout << engine_name()
       << ". By Tord Romstad, Marco Costalba, Joona Kiiski." << endl;
  if (CpuHasPOPCNT)
      cout << "Good! CPU has hardware POPCNT. We will use it." << endl;
  // Enter UCI mode
  uci_main_loop();
  return 0;
 }
--- a/src/material.cpp
+++ b/src/material.cpp
@@ -23,6 +23,7 @@
 ////
 #include <cassert>
 #include <cstring>
 #include <sstream>
 #include <map>
@@ -55,17 +56,42 @@ namespace {
  { 41, 41, 41, 41, 41, 41 }, { 37, 41, 41, 41, 41, 41 }, { 10, 62, 41, 41, 41, 41 },
  { 57, 64, 39, 41, 41, 41 }, { 50, 40, 23, -22, 41, 41 }, { 106, 101, 3, 151, 171, 41 } };
  // Named endgame evaluation and scaling functions, these
  // are accessed direcly and not through the function maps.
  EvaluationFunction<KmmKm> EvaluateKmmKm(WHITE);
  EvaluationFunction<KXK>   EvaluateKXK(WHITE), EvaluateKKX(BLACK);
  ScalingFunction<KBPsK>    ScaleKBPsK(WHITE),  ScaleKKBPs(BLACK);
  ScalingFunction<KQKRPs>   ScaleKQKRPs(WHITE), ScaleKRPsKQ(BLACK);
  ScalingFunction<KPsK>     ScaleKPsK(WHITE),   ScaleKKPs(BLACK);
  ScalingFunction<KPKP>     ScaleKPKPw(WHITE),  ScaleKPKPb(BLACK);
  typedef EndgameEvaluationFunctionBase EF;
  typedef EndgameScalingFunctionBase SF;
  typedef map<Key, EF*> EFMap;
  typedef map<Key, SF*> SFMap;
  // Endgame evaluation and scaling functions accessed direcly and not through
  // the function maps because correspond to more then one material hash key.
  EvaluationFunction<KmmKm> EvaluateKmmKm[] = { EvaluationFunction<KmmKm>(WHITE), EvaluationFunction<KmmKm>(BLACK) };
  EvaluationFunction<KXK>   EvaluateKXK[]   = { EvaluationFunction<KXK>(WHITE),   EvaluationFunction<KXK>(BLACK) };
  ScalingFunction<KBPsK>    ScaleKBPsK[]    = { ScalingFunction<KBPsK>(WHITE),    ScalingFunction<KBPsK>(BLACK) };
  ScalingFunction<KQKRPs>   ScaleKQKRPs[]   = { ScalingFunction<KQKRPs>(WHITE),   ScalingFunction<KQKRPs>(BLACK) };
  ScalingFunction<KPsK>     ScaleKPsK[]     = { ScalingFunction<KPsK>(WHITE),     ScalingFunction<KPsK>(BLACK) };
  ScalingFunction<KPKP>     ScaleKPKP[]     = { ScalingFunction<KPKP>(WHITE),     ScalingFunction<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
          && pos.piece_count(Them, PAWN) == 0
          && pos.non_pawn_material(Us)   >= RookValueMidgame;
  }
  template<Color Us> bool is_KBPsK(const Position& pos) {
    return   pos.non_pawn_material(Us)   == BishopValueMidgame
          && pos.piece_count(Us, BISHOP) == 1
          && pos.piece_count(Us, PAWN)   >= 1;
  }
  template<Color Us> bool is_KQKRPs(const Position& pos) {
    const Color Them = (Us == WHITE ? BLACK : WHITE);
    return   pos.piece_count(Us, PAWN)    == 0
          && pos.non_pawn_material(Us)    == QueenValueMidgame
          && pos.piece_count(Us, QUEEN)   == 1
          && pos.piece_count(Them, ROOK)  == 1
          && pos.piece_count(Them, PAWN)  >= 1;
  }
 }
@@ -90,21 +116,17 @@ private:
  static Key buildKey(const string& keyCode);
  static const string swapColors(const string& keyCode);
-  // Here we store two maps, for evaluate and scaling functions
+  // Here we store two maps, for evaluate and scaling functions...
-  pair<map<Key, EF*>, map<Key, SF*> > maps;
+  pair<EFMap, SFMap> maps;
-  // Maps accessing functions returning const and non-const references
+  // ...and here is the accessing template function
-  template<typename T> const map<Key, T*>& get() const { return maps.first; }
+  template<typename T> const map<Key, T*>& get() const;
  template<typename T> map<Key, T*>& get() { return maps.first; }
 };
 // Explicit specializations of a member function shall be declared in
 // the namespace of which the class template is a member.
-template<> const map<Key, SF*>&
+template<> const EFMap& EndgameFunctions::get<EF>() const { return maps.first; }
-EndgameFunctions::get<SF>() const { return maps.second; }
+template<> const SFMap& EndgameFunctions::get<SF>() const { return maps.second; }
 template<> map<Key, SF*>&
 EndgameFunctions::get<SF>() { return maps.second; }
 ////
@@ -113,15 +135,14 @@ EndgameFunctions::get<SF>() { return maps.second; }
 /// MaterialInfoTable c'tor and d'tor, called once by each thread
-MaterialInfoTable::MaterialInfoTable(unsigned int numOfEntries) {
+MaterialInfoTable::MaterialInfoTable() {
-  size = numOfEntries;
+  entries = new MaterialInfo[MaterialTableSize];
  entries = new MaterialInfo[size];
  funcs = new EndgameFunctions();
  if (!entries || !funcs)
  {
-      cerr << "Failed to allocate " << numOfEntries * sizeof(MaterialInfo)
+      cerr << "Failed to allocate " << MaterialTableSize * sizeof(MaterialInfo)
           << " bytes for material hash table." << endl;
      Application::exit_with_failure();
  }
@@ -144,7 +165,8 @@ Phase MaterialInfoTable::game_phase(const Position& pos) {
  if (npm >= MidgameLimit)
      return PHASE_MIDGAME;
-  else if (npm <= EndgameLimit)
+
  if (npm <= EndgameLimit)
      return PHASE_ENDGAME;
  return Phase(((npm - EndgameLimit) * 128) / (MidgameLimit - EndgameLimit));
@@ -159,7 +181,7 @@ Phase MaterialInfoTable::game_phase(const Position& pos) {
 MaterialInfo* MaterialInfoTable::get_material_info(const Position& pos) {
  Key key = pos.get_material_key();
-  int index = key & (size - 1);
+  unsigned index = unsigned(key & (MaterialTableSize - 1));
  MaterialInfo* mi = entries + index;
  // If mi->key matches the position's material hash key, it means that we
@@ -169,7 +191,8 @@ MaterialInfo* MaterialInfoTable::get_material_info(const Position& pos) {
      return mi;
  // Clear the MaterialInfo object, and set its key
-  mi->clear();
+  memset(mi, 0, sizeof(MaterialInfo));
  mi->factor[WHITE] = mi->factor[BLACK] = uint8_t(SCALE_FACTOR_NORMAL);
  mi->key = key;
  // Store game phase
@@ -181,23 +204,15 @@ MaterialInfo* MaterialInfoTable::get_material_info(const Position& pos) {
  if ((mi->evaluationFunction = funcs->get<EF>(key)) != NULL)
      return mi;
-  else if (   pos.non_pawn_material(BLACK) == Value(0)
+  if (is_KXK<WHITE>(pos) || is_KXK<BLACK>(pos))
           && pos.piece_count(BLACK, PAWN) == 0
           && pos.non_pawn_material(WHITE) >= RookValueMidgame)
  {
-      mi->evaluationFunction = &EvaluateKXK;
+      mi->evaluationFunction = is_KXK<WHITE>(pos) ? &EvaluateKXK[WHITE] : &EvaluateKXK[BLACK];
      return mi;
  }
-  else if (   pos.non_pawn_material(WHITE) == Value(0)
+
-           && pos.piece_count(WHITE, PAWN) == 0
+  if (   pos.pieces(PAWN)  == EmptyBoardBB
-           && pos.non_pawn_material(BLACK) >= RookValueMidgame)
+      && pos.pieces(ROOK)  == EmptyBoardBB
-  {
+      && pos.pieces(QUEEN) == EmptyBoardBB)
      mi->evaluationFunction = &EvaluateKKX;
      return mi;
  }
  else if (   pos.pieces(PAWN) == EmptyBoardBB
           && pos.pieces(ROOK) == EmptyBoardBB
           && pos.pieces(QUEEN) == EmptyBoardBB)
  {
      // Minor piece endgame with at least one minor piece per side and
      // no pawns. Note that the case KmmK is already handled by KXK.
@@ -207,7 +222,7 @@ MaterialInfo* MaterialInfoTable::get_material_info(const Position& pos) {
      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;
+          mi->evaluationFunction = &EvaluateKmmKm[WHITE];
          return mi;
      }
  }
@@ -215,10 +230,8 @@ MaterialInfo* MaterialInfoTable::get_material_info(const Position& pos) {
  // OK, we didn't find any special evaluation function for the current
  // material configuration. Is there a suitable scaling function?
  //
-  // The code below is rather messy, and it could easily get worse later,
+  // We face problems when there are several conflicting applicable
-  // if we decide to add more special cases. We face problems when there
+  // scaling functions and we need to decide which one to use.
  // are several conflicting applicable scaling functions and we need to
  // decide which one to use.
  SF* sf;
  if ((sf = funcs->get<SF>(key)) != NULL)
@@ -230,48 +243,36 @@ MaterialInfo* MaterialInfoTable::get_material_info(const Position& pos) {
  // Generic scaling functions that refer to more then one material
  // distribution. Should be probed after the specialized ones.
  // Note that these ones don't return after setting the function.
-  if (   pos.non_pawn_material(WHITE) == BishopValueMidgame
+  if (is_KBPsK<WHITE>(pos))
-      && pos.piece_count(WHITE, BISHOP) == 1
+      mi->scalingFunction[WHITE] = &ScaleKBPsK[WHITE];
      && pos.piece_count(WHITE, PAWN) >= 1)
      mi->scalingFunction[WHITE] = &ScaleKBPsK;
-  if (   pos.non_pawn_material(BLACK) == BishopValueMidgame
+  if (is_KBPsK<BLACK>(pos))
-      && pos.piece_count(BLACK, BISHOP) == 1
+      mi->scalingFunction[BLACK] = &ScaleKBPsK[BLACK];
      && pos.piece_count(BLACK, PAWN) >= 1)
      mi->scalingFunction[BLACK] = &ScaleKKBPs;
-  if (   pos.piece_count(WHITE, PAWN) == 0
+  if (is_KQKRPs<WHITE>(pos))
-      && pos.non_pawn_material(WHITE) == QueenValueMidgame
+      mi->scalingFunction[WHITE] = &ScaleKQKRPs[WHITE];
      && pos.piece_count(WHITE, QUEEN) == 1
      && pos.piece_count(BLACK, ROOK) == 1
      && pos.piece_count(BLACK, PAWN) >= 1)
      mi->scalingFunction[WHITE] = &ScaleKQKRPs;
-  else if (   pos.piece_count(BLACK, PAWN) == 0
+  else if (is_KQKRPs<BLACK>(pos))
-           && pos.non_pawn_material(BLACK) == QueenValueMidgame
+      mi->scalingFunction[BLACK] = &ScaleKQKRPs[BLACK];
           && pos.piece_count(BLACK, QUEEN) == 1
           && pos.piece_count(WHITE, ROOK) == 1
           && pos.piece_count(WHITE, PAWN) >= 1)
      mi->scalingFunction[BLACK] = &ScaleKRPsKQ;
-  if (pos.non_pawn_material(WHITE) + pos.non_pawn_material(BLACK) == Value(0))
+  if (pos.non_pawn_material(WHITE) + pos.non_pawn_material(BLACK) == VALUE_ZERO)
  {
      if (pos.piece_count(BLACK, PAWN) == 0)
      {
          assert(pos.piece_count(WHITE, PAWN) >= 2);
-          mi->scalingFunction[WHITE] = &ScaleKPsK;
+          mi->scalingFunction[WHITE] = &ScaleKPsK[WHITE];
      }
      else if (pos.piece_count(WHITE, PAWN) == 0)
      {
          assert(pos.piece_count(BLACK, PAWN) >= 2);
-          mi->scalingFunction[BLACK] = &ScaleKKPs;
+          mi->scalingFunction[BLACK] = &ScaleKPsK[BLACK];
      }
      else if (pos.piece_count(WHITE, PAWN) == 1 && pos.piece_count(BLACK, PAWN) == 1)
      {
          // This is a special case because we set scaling functions
          // for both colors instead of only one.
-          mi->scalingFunction[WHITE] = &ScaleKPKPw;
+          mi->scalingFunction[WHITE] = &ScaleKPKP[WHITE];
-          mi->scalingFunction[BLACK] = &ScaleKPKPb;
+          mi->scalingFunction[BLACK] = &ScaleKPKP[BLACK];
      }
  }
@@ -334,7 +335,7 @@ MaterialInfo* MaterialInfoTable::get_material_info(const Position& pos) {
    //
    // We use NO_PIECE_TYPE as a place holder for the bishop pair "extended piece",
    // this allow us to be more flexible in defining bishop pair bonuses.
-    for (pt1 = NO_PIECE_TYPE; pt1 <= QUEEN; pt1++)
+    for (pt1 = PIECE_TYPE_NONE; pt1 <= QUEEN; pt1++)
    {
        pc = pieceCount[c][pt1];
        if (!pc)
@@ -342,7 +343,7 @@ MaterialInfo* MaterialInfoTable::get_material_info(const Position& pos) {
        vv = LinearCoefficients[pt1];
-        for (pt2 = NO_PIECE_TYPE; pt2 <= pt1; pt2++)
+        for (pt2 = PIECE_TYPE_NONE; pt2 <= pt1; pt2++)
            vv +=  pieceCount[c][pt2] * QuadraticCoefficientsSameColor[pt1][pt2]
                 + pieceCount[them][pt2] * QuadraticCoefficientsOppositeColor[pt1][pt2];
@@ -378,11 +379,11 @@ EndgameFunctions::EndgameFunctions() {
 EndgameFunctions::~EndgameFunctions() {
-    for (map<Key, EF*>::iterator it = maps.first.begin(); it != maps.first.end(); ++it)
+    for (EFMap::const_iterator it = maps.first.begin(); it != maps.first.end(); ++it)
-        delete (*it).second;
+        delete it->second;
-    for (map<Key, SF*>::iterator it = maps.second.begin(); it != maps.second.end(); ++it)
+    for (SFMap::const_iterator it = maps.second.begin(); it != maps.second.end(); ++it)
-        delete (*it).second;
+        delete it->second;
 }
 Key EndgameFunctions::buildKey(const string& keyCode) {
@@ -400,10 +401,10 @@ Key EndgameFunctions::buildKey(const string& keyCode) {
        if (keyCode[i] == 'K')
            upcase = !upcase;
-        s << char(upcase? toupper(keyCode[i]) : tolower(keyCode[i]));
+        s << char(upcase ? toupper(keyCode[i]) : tolower(keyCode[i]));
    }
-    s << 8 - keyCode.length() << "/8/8/8/8/8/8/8 w -";
+    s << 8 - keyCode.length() << "/8/8/8/8/8/8/8 w - -";
-    return Position(s.str()).get_material_key();
+    return Position(s.str(), 0).get_material_key();
 }
 const string EndgameFunctions::swapColors(const string& keyCode) {
@@ -417,14 +418,15 @@ template<class T>
 void EndgameFunctions::add(const string& keyCode) {
  typedef typename T::Base F;
  typedef map<Key, F*> M;
-  get<F>().insert(pair<Key, F*>(buildKey(keyCode), new T(WHITE)));
+  const_cast<M&>(get<F>()).insert(pair<Key, F*>(buildKey(keyCode), new T(WHITE)));
-  get<F>().insert(pair<Key, F*>(buildKey(swapColors(keyCode)), new T(BLACK)));
+  const_cast<M&>(get<F>()).insert(pair<Key, F*>(buildKey(swapColors(keyCode)), new T(BLACK)));
 }
 template<class T>
 T* EndgameFunctions::get(Key key) const {
-  typename map<Key, T*>::const_iterator it(get<T>().find(key));
+  typename map<Key, T*>::const_iterator it = get<T>().find(key);
-  return (it != get<T>().end() ? it->second : NULL);
+  return it != get<T>().end() ? it->second : NULL;
 }
--- a/src/material.h
+++ b/src/material.h
@@ -27,13 +27,14 @@
 #include "endgame.h"
 #include "position.h"
 #include "scale.h"
 ////
 //// Types
 ////
 const int MaterialTableSize = 1024;
 /// MaterialInfo is a class which contains various information about a
 /// material configuration. It contains a material balance evaluation,
 /// a function pointer to a special endgame evaluation function (which in
@@ -49,8 +50,6 @@ class MaterialInfo {
  friend class MaterialInfoTable;
 public:
  MaterialInfo() : key(0) { clear(); }
  Score material_value() const;
  ScaleFactor scale_factor(const Position& pos, Color c) const;
  int space_weight() const;
@@ -59,8 +58,6 @@ public:
  Value evaluate(const Position& pos) const;
 private:
  inline void clear();
  Key key;
  int16_t value;
  uint8_t factor[2];
@@ -79,14 +76,13 @@ class EndgameFunctions;
 class MaterialInfoTable {
 public:
-  MaterialInfoTable(unsigned numOfEntries);
+  MaterialInfoTable();
  ~MaterialInfoTable();
  MaterialInfo* get_material_info(const Position& pos);
  static Phase game_phase(const Position& pos);
 private:
  unsigned size;
  MaterialInfo* entries;
  EndgameFunctions* funcs;
 };
@@ -105,20 +101,6 @@ inline Score MaterialInfo::material_value() const {
  return make_score(value, value);
 }
 /// MaterialInfo::clear() resets a MaterialInfo object to an empty state,
 /// with all slots at their default values but the key.
 inline void MaterialInfo::clear() {
  value = 0;
  factor[WHITE] = factor[BLACK] = uint8_t(SCALE_FACTOR_NORMAL);
  evaluationFunction = NULL;
  scalingFunction[WHITE] = scalingFunction[BLACK] = NULL;
  spaceWeight = 0;
 }
 /// 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
--- a/src/mersenne.cpp
+++ b/src/mersenne.cpp
@@ -41,109 +41,131 @@
   email: m-mat @ math.sci.hiroshima-u.ac.jp (remove space)
 */
 #include "types.h"
 #include "mersenne.h"
-/* Period parameters */
+namespace {
 #define N 624
 #define M 397
 #define MATRIX_A 0x9908b0dfUL   /* constant vector a */
 #define UPPER_MASK 0x80000000UL /* most significant w-r bits */
 #define LOWER_MASK 0x7fffffffUL /* least significant r bits */
-static unsigned long mt[N]; /* the array for the state vector  */
+  // Period parameters
-static int mti=N+1; /* mti==N+1 means mt[N] is not initialized */
+  const int N = 624;
  const int M = 397;
  const unsigned long MATRIX_A   = 0x9908b0dfUL; // Constant vector a
  const unsigned long UPPER_MASK = 0x80000000UL; // Most significant w-r bits
  const unsigned long LOWER_MASK = 0x7fffffffUL; // Least significant r bits
-/* initializes mt[N] with a seed */
+  unsigned long mt[N]; // The array for the state vector
-static void init_genrand(unsigned long s)
+  int mti = N + 1;     // mti == N+1 means mt[N] is not initialized
 {
    mt[0]= s & 0xffffffffUL;
    for (mti=1; mti<N; mti++) {
        mt[mti] =
            (1812433253UL * (mt[mti-1] ^ (mt[mti-1] >> 30)) + mti);
        /* See Knuth TAOCP Vol2. 3rd Ed. P.106 for multiplier. */
        /* In the previous versions, MSBs of the seed affect   */
        /* only MSBs of the array mt[].                        */
        /* 2002/01/09 modified by Makoto Matsumoto             */
        mt[mti] &= 0xffffffffUL;
        /* for >32 bit machines */
    }
 }
-/* initialize by an array with array-length */
+  // Initializes mt[N] with a seed
-/* init_key is the array for initializing keys */
+  void init_genrand(unsigned long s) {
 /* key_length is its length */
 /* slight change for C++, 2004/2/26 */
 static void init_by_array(unsigned long init_key[], int key_length)
 {
    int i, j, k;
    init_genrand(19650218UL);
    i=1; j=0;
    k = (N>key_length ? N : key_length);
    for (; k; k--) {
        mt[i] = (mt[i] ^ ((mt[i-1] ^ (mt[i-1] >> 30)) * 1664525UL))
          + init_key[j] + j; /* non linear */
        mt[i] &= 0xffffffffUL; /* for WORDSIZE > 32 machines */
        i++; j++;
        if (i>=N) { mt[0] = mt[N-1]; i=1; }
        if (j>=key_length) j=0;
    }
    for (k=N-1; k; k--) {
        mt[i] = (mt[i] ^ ((mt[i-1] ^ (mt[i-1] >> 30)) * 1566083941UL))
          - i; /* non linear */
        mt[i] &= 0xffffffffUL; /* for WORDSIZE > 32 machines */
        i++;
        if (i>=N) { mt[0] = mt[N-1]; i=1; }
    }
-    mt[0] = 0x80000000UL; /* MSB is 1; assuring non-zero initial array */
+      mt[0]= s & 0xffffffffUL;
-}
+      for (mti = 1; mti < N; mti++)
      {
          // See Knuth TAOCP Vol2. 3rd Ed. P.106 for multiplier.
          // In the previous versions, MSBs of the seed affect
          // only MSBs of the array mt[].
          // 2002/01/09 modified by Makoto Matsumoto
          mt[mti] = 1812433253UL * (mt[mti-1] ^ (mt[mti-1] >> 30)) + mti;
          mt[mti] &= 0xffffffffUL; // For > 32 bit machines
      }
  }
  // Initialize by an array with array-length
  // init_key is the array for initializing keys
  // key_length is its length
  // slight change for C++, 2004/2/26
  void init_by_array(unsigned long init_key[], int key_length) {
      int i = 1;
      int j = 0;
      int k = (N > key_length ? N : key_length);
      init_genrand(19650218UL);
      for ( ; k; k--)
      {
          mt[i] = (mt[i] ^ ((mt[i-1] ^ (mt[i-1] >> 30)) * 1664525UL)) + init_key[j] + j; // Non linear
          mt[i] &= 0xffffffffUL; // For WORDSIZE > 32 machines
          i++; j++;
          if (i >= N)
          {
              mt[0] = mt[N-1];
              i = 1;
          }
          if (j >= key_length)
              j = 0;
      }
      for (k = N-1; k; k--)
      {
          mt[i] = (mt[i] ^ ((mt[i-1] ^ (mt[i-1] >> 30)) * 1566083941UL)) - i; // Non linear
          mt[i] &= 0xffffffffUL; // For WORDSIZE > 32 machines
          i++;
          if (i >= N)
          {
              mt[0] = mt[N-1];
              i = 1;
          }
      }
      mt[0] = 0x80000000UL; // MSB is 1; assuring non-zero initial array
  }
 } // namespace
 // Generates a random number on [0,0xffffffff]-interval
 uint32_t genrand_int32() {
 /* generates a random number on [0,0xffffffff]-interval */
 uint32_t genrand_int32(void) {
  unsigned long y;
-  static unsigned long mag01[2]={0x0UL, MATRIX_A};
+  static unsigned long mag01[2] = {0x0UL, MATRIX_A};
  /* mag01[x] = x * MATRIX_A  for x=0,1 */
-  if (mti >= N) { /* generate N words at one time */
+  // Generate N words at one time
-    int kk;
+  if (mti >= N)
  {
      int kk;
-    if (mti == N+1)   /* if init_genrand() has not been called, */
+      if (mti == N+1)           // If init_genrand() has not been called,
-      init_genrand(5489UL); /* a default initial seed is used */
+          init_genrand(5489UL); // a default initial seed is used.
-    for (kk=0;kk<N-M;kk++) {
+      for (kk = 0; kk < N-M; kk++)
-      y = (mt[kk]&UPPER_MASK)|(mt[kk+1]&LOWER_MASK);
+      {
-      mt[kk] = mt[kk+M] ^ (y >> 1) ^ mag01[y & 0x1UL];
+          y = (mt[kk] & UPPER_MASK) | (mt[kk+1] & LOWER_MASK);
-    }
+          mt[kk] = mt[kk+M] ^ (y >> 1) ^ mag01[y & 0x1UL];
-    for (;kk<N-1;kk++) {
+      }
-      y = (mt[kk]&UPPER_MASK)|(mt[kk+1]&LOWER_MASK);
+      for ( ; kk < N-1; kk++)
-      mt[kk] = mt[kk+(M-N)] ^ (y >> 1) ^ mag01[y & 0x1UL];
+      {
-    }
+          y = (mt[kk] & UPPER_MASK) | (mt[kk+1] & LOWER_MASK);
-    y = (mt[N-1]&UPPER_MASK)|(mt[0]&LOWER_MASK);
+          mt[kk] = mt[kk+(M-N)] ^ (y >> 1) ^ mag01[y & 0x1UL];
-    mt[N-1] = mt[M-1] ^ (y >> 1) ^ mag01[y & 0x1UL];
+      }
-
+      y = (mt[N-1] & UPPER_MASK) | (mt[0] & LOWER_MASK);
-    mti = 0;
+      mt[N-1] = mt[M-1] ^ (y >> 1) ^ mag01[y & 0x1UL];
      mti = 0;
  }
  y = mt[mti++];
-  /* Tempering */
+  // Tempering
  y ^= (y >> 11);
-  y ^= (y << 7) & 0x9d2c5680UL;
+  y ^= (y <<  7) & 0x9d2c5680UL;
  y ^= (y << 15) & 0xefc60000UL;
  y ^= (y >> 18);
  return y;
 }
-uint64_t genrand_int64(void) {
+uint64_t genrand_int64() {
  uint64_t x, y;
-  x = genrand_int32(); y = genrand_int32();
+  x = genrand_int32();
-  return (x<<32)|y;
+  y = genrand_int32();
  return (x << 32) | y;
 }
-void init_mersenne(void) {
+void init_mersenne() {
-  unsigned long init[4]={0x123, 0x234, 0x345, 0x456}, length=4;
+
  unsigned long init[4] = {0x123, 0x234, 0x345, 0x456};
  unsigned long length = 4;
  init_by_array(init, length);
 }
--- a/src/mersenne.h
+++ b/src/mersenne.h
@@ -32,9 +32,9 @@
 //// Prototypes
 ////
-extern uint32_t genrand_int32(void);
+extern uint32_t genrand_int32();
-extern uint64_t genrand_int64(void);
+extern uint64_t genrand_int64();
-extern void init_mersenne(void);
+extern void init_mersenne();
 #endif // !defined(MERSENNE_H_INCLUDED)
--- a/src/misc.cpp
+++ b/src/misc.cpp
@@ -39,22 +39,26 @@
 #endif
 #if !defined(NO_PREFETCH)
 #  include <xmmintrin.h>
 #endif
 #include <cassert>
 #include <cstdio>
 #include <cstring>
 #include <iomanip>
 #include <iostream>
 #include <sstream>
 #include "bitcount.h"
 #include "misc.h"
 #include "thread.h"
 using namespace std;
 /// Version number. If this is left empty, the current date (in the format
 /// YYMMDD) is used as a version number.
-static const string EngineVersion = "1.7";
+static const string EngineVersion = "1.9";
 static const string AppName = "Stockfish";
 static const string AppTag  = "";
@@ -63,8 +67,6 @@ static const string AppTag  = "";
 //// Variables
 ////
 bool Chess960;
 uint64_t dbg_cnt0 = 0;
 uint64_t dbg_cnt1 = 0;
@@ -147,7 +149,7 @@ const string engine_name() {
  const string cpu64(CpuHas64BitPath ? " 64bit" : "");
  if (!EngineVersion.empty())
-      return AppName+ " " + EngineVersion + cpu64;
+      return AppName + " " + EngineVersion + cpu64;
  string date(__DATE__); // From compiler, format is "Sep 21 2008"
  string months("Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec");
@@ -183,85 +185,39 @@ int get_system_time() {
 }
-/// builtin_cpu_count() tries to detect the number of CPU cores, if
+/// cpu_count() tries to detect the number of CPU cores.
 /// hyper-threading is enabled this is the number of logical processors.
 #if !defined(_MSC_VER)
 #  if defined(_SC_NPROCESSORS_ONLN)
-static int builtin_cpu_count() {
+int cpu_count() {
-  return Min(sysconf(_SC_NPROCESSORS_ONLN), 8);
+  return Min(sysconf(_SC_NPROCESSORS_ONLN), MAX_THREADS);
 }
 #  elif defined(__hpux)
-static int builtin_cpu_count() {
+int cpu_count() {
  struct pst_dynamic psd;
  if (pstat_getdynamic(&psd, sizeof(psd), (size_t)1, 0) == -1)
      return 1;
-  return Min(psd.psd_proc_cnt, 8);
+  return Min(psd.psd_proc_cnt, MAX_THREADS);
 }
 #  else
-static int builtin_cpu_count() {
+int cpu_count() {
  return 1;
 }
 #  endif
 #else
-static int builtin_cpu_count() {
+int cpu_count() {
  SYSTEM_INFO s;
  GetSystemInfo(&s);
-  return Min(s.dwNumberOfProcessors, 8);
+  return Min(s.dwNumberOfProcessors, MAX_THREADS);
 }
 #endif
 /// HT_enabled() returns true if hyper-threading is enabled on current machine
 static bool HT_enabled() {
  char CPUString[0x20];
  int CPUInfo[4] = {-1};
  int nIds, nLogicalCPU, nCores;
  // Detect CPU producer
  __cpuid(CPUInfo, 0);
  nIds = CPUInfo[0];
  memset(CPUString, 0, sizeof(CPUString));
  memcpy(&CPUString[0], &CPUInfo[1], sizeof(int));
  memcpy(&CPUString[4], &CPUInfo[3], sizeof(int));
  memcpy(&CPUString[8], &CPUInfo[2], sizeof(int));
  // Not an Intel CPU or CPUID.4 not supported
  if (strcmp(CPUString, "GenuineIntel") || nIds < 4)
      return false;
  // Detect if HT Technology is supported
  __cpuid(CPUInfo, 1);
  if (!((CPUInfo[3] >> 28) & 1))
      return false;
  nLogicalCPU = (CPUInfo[1] >> 16) & 0xFF;
  // Detect number of cores
  __cpuid(CPUInfo, 4);
  nCores = 1 + ((CPUInfo[0] >> 26) & 0x3F);
  return nLogicalCPU > nCores;
 }
 /// cpu_count() tries to detect the number of physical CPU cores taking
 /// in account hyper-threading.
 int cpu_count() {
  return HT_enabled() ? builtin_cpu_count() / 2 : builtin_cpu_count();
 }
 /*
  From Beowulf, from Olithink
 */
@@ -333,4 +289,27 @@ int Bioskey()
        return 0;
    }
 }
 #endif
 /// 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
 /// loaded from RAM, that can be very slow.
 #if defined(NO_PREFETCH)
 void prefetch(char*) {}
 #else
 void prefetch(char* addr) {
 #if defined(__INTEL_COMPILER) || defined(__ICL)
   // This hack prevents prefetches to be optimized away by
   // Intel compiler. Both MSVC and gcc seems not affected.
   __asm__ ("");
 #endif
  _mm_prefetch(addr, _MM_HINT_T2);
  _mm_prefetch(addr+64, _MM_HINT_T2); // 64 bytes ahead
 }
 #endif
--- a/src/misc.h
+++ b/src/misc.h
@@ -40,13 +40,6 @@
 #define Max(x, y) (((x) < (y))? (y) : (x))
 ////
 //// Variables
 ////
 extern bool Chess960;
 ////
 //// Prototypes
 ////
@@ -55,6 +48,8 @@ extern const std::string engine_name();
 extern int get_system_time();
 extern int cpu_count();
 extern int Bioskey();
 extern void prefetch(char* addr);
 extern void prefetchPawn(Key, int);
 ////
--- a/src/move.cpp
+++ b/src/move.cpp
@@ -104,11 +104,11 @@ Move move_from_string(const Position& pos, const std::string& str) {
 /// move_to_string() converts a move to a string in coordinate notation
-/// (g1f3, a7a8q, etc.).  The only special case is castling moves, where we
+/// (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 std::string move_to_string(Move move) {
+const std::string move_to_string(Move move, bool chess960) {
  std::string str;
  Square from = move_from(move);
@@ -120,14 +120,12 @@ const std::string move_to_string(Move move) {
      str = "0000";
  else
  {
-      if (!Chess960)
+      if (move_is_short_castle(move) && !chess960)
-      {
+          return (from == SQ_E1 ? "e1g1" : "e8g8");
-          if (move_is_short_castle(move))
+
-              return (from == SQ_E1 ? "e1g1" : "e8g8");
+      if (move_is_long_castle(move) && !chess960)
          return (from == SQ_E1 ? "e1c1" : "e8c8");
          if (move_is_long_castle(move))
              return (from == SQ_E1 ? "e1c1" : "e8c8");
      }
      str = square_to_string(from) + square_to_string(to);
      if (move_is_promotion(move))
          str += piece_type_to_char(move_promotion_piece(move), false);
@@ -138,9 +136,10 @@ const std::string move_to_string(Move move) {
 /// Overload the << operator, to make it easier to print moves.
-std::ostream &operator << (std::ostream& os, Move m) {
+std::ostream& operator << (std::ostream& os, Move m) {
-  return os << move_to_string(m);
+  bool chess960 = (os.iword(0) != 0); // See set960()
  return os << move_to_string(m, chess960);
 }
--- a/src/move.h
+++ b/src/move.h
@@ -101,11 +101,11 @@ inline void sort_moves(T* firstMove, T* lastMove, T** lastPositive)
    // Split positives vs non-positives
    do {
-        while ((++p)->score > 0);
+        while ((++p)->score > 0) {}
        if (p != d)
        {
-            while (--d != p && d->score <= 0);
+            while (--d != p && d->score <= 0) {}
            tmp = *p;
            *p = *d;
@@ -201,9 +201,9 @@ inline Move make_ep_move(Square from, Square to) {
 //// Prototypes
 ////
-extern std::ostream& operator<<(std::ostream &os, Move m);
+extern std::ostream& operator<<(std::ostream& os, Move m);
-extern Move move_from_string(const Position &pos, const std::string &str);
+extern Move move_from_string(const Position& pos, const std::string &str);
-extern const std::string move_to_string(Move m);
+extern const std::string move_to_string(Move m, bool chess960);
 extern bool move_is_ok(Move m);
--- a/src/movegen.cpp
+++ b/src/movegen.cpp
@@ -140,6 +140,32 @@ MoveStack* generate_noncaptures(const Position& pos, MoveStack* mlist) {
 }
 /// generate_non_evasions() generates all pseudo-legal captures and
 /// non-captures. Returns a pointer to the end of the move list.
 MoveStack* generate_non_evasions(const Position& pos, MoveStack* mlist) {
  assert(pos.is_ok());
  assert(!pos.is_check());
  Color us = pos.side_to_move();
  Bitboard target = pos.pieces_of_color(opposite_color(us));
  mlist = generate_piece_moves<PAWN, CAPTURE>(pos, mlist, us, target);
  mlist = generate_piece_moves<PAWN, NON_CAPTURE>(pos, mlist, us, pos.empty_squares());
  target |= pos.empty_squares();
  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);
  mlist = generate_castle_moves<KING_SIDE>(pos, mlist);
  return  generate_castle_moves<QUEEN_SIDE>(pos, 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.
@@ -260,11 +286,8 @@ MoveStack* generate_moves(const Position& pos, MoveStack* mlist, bool pseudoLega
  Bitboard pinned = pos.pinned_pieces(pos.side_to_move());
  // Generate pseudo-legal moves
-  if (pos.is_check())
+  last = pos.is_check() ? generate_evasions(pos, mlist)
-      last = generate_evasions(pos, mlist);
+                        : generate_non_evasions(pos, mlist);
  else
      last = generate_noncaptures(pos, generate_captures(pos, mlist));
  if (pseudoLegal)
      return last;
@@ -338,6 +361,10 @@ bool move_is_legal(const Position& pos, const Move m, Bitboard pinned) {
           ||(square_rank(to) == RANK_1 && us != WHITE)) != bool(move_is_promotion(m)))
          return false;
      // The promotion piece, if any, must be valid
      if (move_promotion_piece(m) > QUEEN || move_promotion_piece(m) == PAWN)
          return false;
      // Proceed according to the square delta between the origin and
      // destination squares.
      switch (direction)
@@ -402,10 +429,13 @@ namespace {
    Square from;
    const Square* ptr = pos.piece_list_begin(us, Piece);
-    while ((from = *ptr++) != SQ_NONE)
+    if (*ptr != SQ_NONE)
    {
-        b = pos.attacks_from<Piece>(from) & target;
+        do {
-        SERIALIZE_MOVES(b);
+            from = *ptr;
            b = pos.attacks_from<Piece>(from) & target;
            SERIALIZE_MOVES(b);
        } while (*++ptr != SQ_NONE);
    }
    return mlist;
  }
--- a/src/movegen.h
+++ b/src/movegen.h
@@ -36,6 +36,7 @@ extern MoveStack* generate_captures(const Position& pos, MoveStack* mlist);
 extern MoveStack* generate_noncaptures(const Position& pos, MoveStack* mlist);
 extern MoveStack* generate_non_capture_checks(const Position& pos, MoveStack* mlist);
 extern MoveStack* generate_evasions(const Position& pos, MoveStack* mlist);
 extern MoveStack* generate_non_evasions(const Position& pos, MoveStack* mlist);
 extern MoveStack* generate_moves(const Position& pos, MoveStack* mlist, bool pseudoLegal = false);
 extern bool move_is_legal(const Position& pos, const Move m, Bitboard pinned);
 extern bool move_is_legal(const Position& pos, const Move m);
--- a/src/movepick.cpp
+++ b/src/movepick.cpp
@@ -70,18 +70,18 @@ namespace {
 /// search captures, promotions and some checks) and about how important good
 /// move ordering is at the current node.
-MovePicker::MovePicker(const Position& p, Move ttm, Depth d,
+MovePicker::MovePicker(const Position& p, Move ttm, Depth d, const History& h,
-                       const History& h, SearchStack* ss, Value beta) : pos(p), H(h) {
+                       SearchStack* ss, Value beta) : pos(p), H(h) {
  int searchTT = ttm;
  ttMoves[0].move = ttm;
  lastBadCapture = badCaptures;
  badCaptureThreshold = 0;
  badCaptures = moves + 256;
  pinned = p.pinned_pieces(pos.side_to_move());
  if (ss && !p.is_check())
  {
-      ttMoves[1].move = (ss->mateKiller == ttm)? MOVE_NONE : ss->mateKiller;
+      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];
@@ -90,15 +90,16 @@ MovePicker::MovePicker(const Position& p, Move ttm, Depth d,
  if (p.is_check())
      phasePtr = EvasionsPhaseTable;
-  else if (d > Depth(0))
+  else if (d > DEPTH_ZERO)
  {
      // Consider sligtly negative captures as good if at low
      // depth and far from beta.
-      if (ss && ss->eval < beta - PawnValueMidgame && d < 3 * OnePly)
+      if (ss && ss->eval < beta - PawnValueMidgame && d < 3 * ONE_PLY)
          badCaptureThreshold = -PawnValueMidgame;
      phasePtr = MainSearchPhaseTable;
-  } else if (d == Depth(0))
+  }
  else if (d == DEPTH_ZERO)
      phasePtr = QsearchWithChecksPhaseTable;
  else
  {
@@ -111,7 +112,7 @@ MovePicker::MovePicker(const Position& p, Move ttm, Depth d,
          searchTT = ttMoves[0].move = MOVE_NONE;
  }
-  phasePtr += !searchTT - 1;
+  phasePtr += int(!searchTT) - 1;
  go_next_phase();
 }
@@ -147,16 +148,16 @@ void MovePicker::go_next_phase() {
      return;
  case PH_BAD_CAPTURES:
-      // Bad captures SEE value is already calculated so just sort them
+      // Bad captures SEE value is already calculated so just pick
-      // to get SEE move ordering.
+      // them in order to get SEE move ordering.
      curMove = badCaptures;
-      lastMove = lastBadCapture;
+      lastMove = moves + 256;
      return;
  case PH_EVASIONS:
      assert(pos.is_check());
      lastMove = generate_evasions(pos, moves);
-      score_evasions_or_checks();
+      score_evasions();
      return;
  case PH_QCAPTURES:
@@ -166,7 +167,6 @@ void MovePicker::go_next_phase() {
  case PH_QCHECKS:
      lastMove = generate_non_capture_checks(pos, moves);
      score_evasions_or_checks();
      return;
  case PH_STOP:
@@ -220,7 +220,6 @@ void MovePicker::score_noncaptures() {
  Move m;
  Piece piece;
  Square from, to;
  int hs;
  for (MoveStack* cur = moves; cur != lastMove; cur++)
  {
@@ -228,18 +227,11 @@ void MovePicker::score_noncaptures() {
      from = move_from(m);
      to = move_to(m);
      piece = pos.piece_on(from);
-      hs = H.move_ordering_score(piece, to);
+      cur->score = H.value(piece, to) + H.gain(piece, to);
      // Ensure history has always highest priority
      if (hs > 0)
          hs += 10000;
      // Gain table based scoring
      cur->score = hs + 16 * H.gain(piece, to);
  }
 }
-void MovePicker::score_evasions_or_checks() {
+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, and at the end bad-captures and non-captures with a
@@ -260,7 +252,7 @@ void MovePicker::score_evasions_or_checks() {
          cur->score =  pos.midgame_value_of_piece_on(move_to(m))
                      - pos.type_of_piece_on(move_from(m)) + HistoryMax;
      else
-          cur->score = H.move_ordering_score(pos.piece_on(move_from(m)), move_to(m));
+          cur->score = H.value(pos.piece_on(move_from(m)), move_to(m));
  }
 }
@@ -300,21 +292,19 @@ Move MovePicker::get_next_move() {
                  if (seeValue >= badCaptureThreshold)
                      return move;
-                  // Losing capture, move it to the badCaptures[] array, note
+                  // Losing capture, move it to the tail of the array, note
                  // that move has now been already checked for legality.
-                  assert(int(lastBadCapture - badCaptures) < 63);
+                  (--badCaptures)->move = move;
-                  lastBadCapture->move = move;
+                  badCaptures->score = seeValue;
                  lastBadCapture->score = seeValue;
                  lastBadCapture++;
              }
              break;
          case PH_KILLERS:
              move = (curMove++)->move;
              if (   move != MOVE_NONE
                  && move_is_legal(pos, move, pinned)
                  && move != ttMoves[0].move
                  && move != ttMoves[1].move
                  && move_is_legal(pos, move, pinned)
                  && !pos.move_is_capture(move))
                  return move;
              break;
--- a/src/movepick.h
+++ b/src/movepick.h
@@ -56,17 +56,17 @@ public:
 private:
  void score_captures();
  void score_noncaptures();
-  void score_evasions_or_checks();
+  void score_evasions();
  void go_next_phase();
  const Position& pos;
  const History& H;
  Bitboard pinned;
  MoveStack ttMoves[2], killers[2];
  int badCaptureThreshold, phase;
  const uint8_t* phasePtr;
-  MoveStack *curMove, *lastMove, *lastGoodNonCapture, *lastBadCapture;
+  MoveStack *curMove, *lastMove, *lastGoodNonCapture, *badCaptures;
-  Bitboard pinned;
+  MoveStack moves[256];
  MoveStack moves[256], badCaptures[64];
 };
--- a/src/pawns.cpp
+++ b/src/pawns.cpp
@@ -70,36 +70,7 @@ namespace {
    S(34,68), S(83,166), S(0, 0), S( 0, 0)
  };
-  // Pawn storm tables for positions with opposite castling
+  #undef S
  const int QStormTable[64] = {
    0,  0,  0,  0, 0, 0, 0, 0,
  -22,-22,-22,-14,-6, 0, 0, 0,
   -6,-10,-10,-10,-6, 0, 0, 0,
    4, 12, 16, 12, 4, 0, 0, 0,
   16, 23, 23, 16, 0, 0, 0, 0,
   23, 31, 31, 23, 0, 0, 0, 0,
   23, 31, 31, 23, 0, 0, 0, 0,
    0,  0,  0,  0, 0, 0, 0, 0
  };
  const int KStormTable[64] = {
    0, 0, 0,  0,  0,  0,  0,  0,
    0, 0, 0,-10,-19,-28,-33,-33,
    0, 0, 0,-10,-15,-19,-24,-24,
    0, 0, 0,  0,  1,  1,  1,  1,
    0, 0, 0,  0,  1, 10, 19, 19,
    0, 0, 0,  0,  1, 19, 31, 27,
    0, 0, 0,  0,  0, 22, 31, 22,
    0, 0, 0,  0,  0,  0,  0,  0
  };
  // Pawn storm open file bonuses by file
  const int16_t KStormOpenFileBonus[8] = { 31, 31, 18, 0, 0, 0, 0, 0 };
  const int16_t QStormOpenFileBonus[8] = { 0, 0, 0, 0, 0, 26, 42, 26 };
  // Pawn storm lever bonuses by file
  const int StormLeverBonus[8] = { -8, -8, -13, 0, 0, -13, -8, -8 };
 }
@@ -107,49 +78,38 @@ namespace {
 //// Functions
 ////
-/// Constructor
+/// PawnInfoTable c'tor and d'tor instantiated one each thread
-PawnInfoTable::PawnInfoTable(unsigned numOfEntries) {
+PawnInfoTable::PawnInfoTable() {
  entries = new PawnInfo[PawnTableSize];
  size = numOfEntries;
  entries = new PawnInfo[size];
  if (!entries)
  {
-      std::cerr << "Failed to allocate " << (numOfEntries * sizeof(PawnInfo))
+      std::cerr << "Failed to allocate " << (PawnTableSize * sizeof(PawnInfo))
                << " bytes for pawn hash table." << std::endl;
      Application::exit_with_failure();
  }
 }
 /// Destructor
 PawnInfoTable::~PawnInfoTable() {
  delete [] entries;
 }
 /// PawnInfo::clear() resets to zero the PawnInfo entry. Note that
 /// kingSquares[] is initialized to SQ_NONE instead.
 void PawnInfo::clear() {
  memset(this, 0, sizeof(PawnInfo));
  kingSquares[WHITE] = kingSquares[BLACK] = SQ_NONE;
 }
 /// PawnInfoTable::get_pawn_info() takes a position object as input, computes
-/// a PawnInfo object, and returns a pointer to it.  The result is also
+/// a PawnInfo object, and returns a pointer to it. The result is also stored
-/// stored in a hash table, so we don't have to recompute everything when
+/// in a hash table, so we don't have to recompute everything when the same
-/// the same pawn structure occurs again.
+/// pawn structure occurs again.
-PawnInfo* PawnInfoTable::get_pawn_info(const Position& pos) {
+PawnInfo* PawnInfoTable::get_pawn_info(const Position& pos) const {
  assert(pos.is_ok());
  Key key = pos.get_pawn_key();
-  int index = int(key & (size - 1));
+  unsigned index = unsigned(key & (PawnTableSize - 1));
  PawnInfo* pi = entries + index;
  // If pi->key matches the position's pawn hash key, it means that we
@@ -159,7 +119,8 @@ PawnInfo* PawnInfoTable::get_pawn_info(const Position& pos) {
      return pi;
  // Clear the PawnInfo object, and set the key
-  pi->clear();
+  memset(pi, 0, sizeof(PawnInfo));
  pi->kingSquares[WHITE] = pi->kingSquares[BLACK] = SQ_NONE;
  pi->key = key;
  // Calculate pawn attacks
@@ -179,113 +140,56 @@ PawnInfo* PawnInfoTable::get_pawn_info(const Position& pos) {
 template<Color Us>
 Score PawnInfoTable::evaluate_pawns(const Position& pos, Bitboard ourPawns,
-                                    Bitboard theirPawns, PawnInfo* pi) {
+                                    Bitboard theirPawns, PawnInfo* pi) const {
  Bitboard b;
  Square s;
  File f;
  Rank r;
-  bool passed, isolated, doubled, chain, backward, candidate;
+  bool passed, isolated, doubled, opposed, chain, backward, candidate;
-  int bonus;
+  Score value = SCORE_ZERO;
  Score value = make_score(0, 0);
  const Square* ptr = pos.piece_list_begin(Us, PAWN);
-  // Initialize pawn storm scores by giving bonuses for open files
+  // Initialize halfOpenFiles[]
  for (f = FILE_A; f <= FILE_H; f++)
      if (!(ourPawns & file_bb(f)))
      {
          pi->ksStormValue[Us] += KStormOpenFileBonus[f];
          pi->qsStormValue[Us] += QStormOpenFileBonus[f];
          pi->halfOpenFiles[Us] |= (1 << f);
      }
  // Loop through all pawns of the current color and score each pawn
  while ((s = *ptr++) != SQ_NONE)
  {
      assert(pos.piece_on(s) == piece_of_color_and_type(Us, PAWN));
      f = square_file(s);
      r = square_rank(s);
-      assert(pos.piece_on(s) == piece_of_color_and_type(Us, PAWN));
+      // Our rank plus previous one. Used for chain detection.
      b = rank_bb(r) | rank_bb(Us == WHITE ? r - Rank(1) : r + Rank(1));
-      // Passed, isolated or doubled pawn?
+      // Passed, isolated, doubled or member of a pawn
-      passed   = Position::pawn_is_passed(theirPawns, Us, s);
+      // chain (but not the backward one) ?
-      isolated = Position::pawn_is_isolated(ourPawns, s);
+      passed   = !(theirPawns & passed_pawn_mask(Us, s));
-      doubled  = Position::pawn_is_doubled(ourPawns, Us, s);
+      doubled  =   ourPawns   & squares_behind(Us, s);
-
+      opposed  =   theirPawns & squares_in_front_of(Us, s);
-      // We calculate kingside and queenside pawn storm
+      isolated = !(ourPawns   & neighboring_files_bb(f));
-      // scores for both colors. These are used when evaluating
+      chain    =   ourPawns   & neighboring_files_bb(f) & b;
      // middle game positions with opposite side castling.
      //
      // Each pawn is given a base score given by a piece square table
      // (KStormTable[] or QStormTable[]). Pawns which seem to have good
      // chances of creating an open file by exchanging itself against an
      // enemy pawn on an adjacent file gets an additional bonus.
      // Kingside pawn storms
      bonus = KStormTable[relative_square(Us, s)];
      if (f >= FILE_F)
      {
          Bitboard b = outpost_mask(Us, s) & theirPawns & (FileFBB | FileGBB | FileHBB);
          while (b)
          {
              // Give a bonus according to the distance of the nearest enemy pawn
              Square s2 = pop_1st_bit(&b);
              int v = StormLeverBonus[f] - 2 * square_distance(s, s2);
              // If enemy pawn has no pawn beside itself is particularly vulnerable.
              // Big bonus, especially against a weakness on the rook file
              if (!(theirPawns & neighboring_files_bb(s2) & rank_bb(s2)))
                  v *= (square_file(s2) == FILE_H ? 4 : 2);
              bonus += v;
          }
      }
      pi->ksStormValue[Us] += bonus;
      // Queenside pawn storms
      bonus = QStormTable[relative_square(Us, s)];
      if (f <= FILE_C)
      {
          Bitboard b = outpost_mask(Us, s) & theirPawns & (FileABB | FileBBB | FileCBB);
          while (b)
          {
              // Give a bonus according to the distance of the nearest enemy pawn
              Square s2 = pop_1st_bit(&b);
              int v = StormLeverBonus[f] - 4 * square_distance(s, s2);
              // If enemy pawn has no pawn beside itself is particularly vulnerable.
              // Big bonus, especially against a weakness on the rook file
              if (!(theirPawns & neighboring_files_bb(s2) & rank_bb(s2)))
                  v *= (square_file(s2) == FILE_A ? 4 : 2);
              bonus += v;
          }
      }
      pi->qsStormValue[Us] += bonus;
      // Member of a pawn chain (but not the backward one)? We could speed up
      // the test a little by introducing an array of masks indexed by color
      // and square for doing the test, but because everything is hashed,
      // it probably won't make any noticable difference.
      chain =  ourPawns
             & neighboring_files_bb(f)
             & (rank_bb(r) | rank_bb(r - (Us == WHITE ? 1 : -1)));
      // Test for backward pawn
      //
      backward = false;
      // If the pawn is passed, isolated, or member of a pawn chain
      // it cannot be backward. If can capture an enemy pawn or if
      // there are friendly pawns behind on neighboring files it cannot
      // be backward either.
-      if (   (passed | isolated | chain)
+      if (   !(passed | isolated | chain)
-          || (ourPawns & behind_bb(Us, r) & neighboring_files_bb(f))
+          && !(ourPawns & attack_span_mask(opposite_color(Us), s))
-          || (pos.attacks_from<PAWN>(s, Us) & theirPawns))
+          && !(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 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.
-          Bitboard b = pos.attacks_from<PAWN>(s, Us);
+          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.
@@ -297,12 +201,12 @@ Score PawnInfoTable::evaluate_pawns(const Position& pos, Bitboard ourPawns,
          backward = (b | (Us == WHITE ? b << 8 : b >> 8)) & theirPawns;
      }
      assert(passed | opposed | (attack_span_mask(Us, s) & theirPawns));
      // Test for candidate passed pawn
-      candidate =   !passed
+      candidate =   !(opposed | passed)
-                 && !(theirPawns & file_bb(f))
+                 && (b = attack_span_mask(opposite_color(Us), s + pawn_push(Us)) & ourPawns) != EmptyBoardBB
-                 && (  count_1s_max_15(neighboring_files_bb(f) & (behind_bb(Us, r) | rank_bb(r)) & ourPawns)
+                 &&  count_1s_max_15(b) >= count_1s_max_15(attack_span_mask(Us, s) & theirPawns);
                     - count_1s_max_15(neighboring_files_bb(f) & in_front_bb(Us, r)              & theirPawns)
                     >= 0);
      // In order to prevent doubled passed pawns from receiving a too big
      // bonus, only the frontmost passed pawn on each file is considered as
@@ -310,14 +214,16 @@ Score PawnInfoTable::evaluate_pawns(const Position& pos, Bitboard ourPawns,
      if (passed && (ourPawns & squares_in_front_of(Us, s)))
          passed = false;
-      // Score this pawn
+      // Mark the pawn as passed. Pawn will be properly scored in evaluation
      // because we need full attack info to evaluate passed pawns.
      if (passed)
-          set_bit(&(pi->passedPawns), s);
+          set_bit(&(pi->passedPawns[Us]), s);
      // Score this pawn
      if (isolated)
      {
          value -= IsolatedPawnPenalty[f];
-          if (!(theirPawns & file_bb(f)))
+          if (!opposed)
              value -= IsolatedPawnPenalty[f] / 2;
      }
      if (doubled)
@@ -326,7 +232,7 @@ Score PawnInfoTable::evaluate_pawns(const Position& pos, Bitboard ourPawns,
      if (backward)
      {
          value -= BackwardPawnPenalty[f];
-          if (!(theirPawns & file_bb(f)))
+          if (!opposed)
              value -= BackwardPawnPenalty[f] / 2;
      }
      if (chain)
@@ -339,20 +245,3 @@ Score PawnInfoTable::evaluate_pawns(const Position& pos, Bitboard ourPawns,
  return value;
 }
 /// PawnInfo::updateShelter calculates and caches king shelter. It is called
 /// only when king square changes, about 20% of total get_king_shelter() calls.
 int PawnInfo::updateShelter(const Position& pos, Color c, Square ksq) {
  unsigned shelter = 0;
  Bitboard pawns = pos.pieces(PAWN, c) & this_and_neighboring_files_bb(ksq);
  unsigned r = ksq & (7 << 3);
  for (int i = 1, k = (c ? -8 : 8); i < 4; i++)
  {
      r += k;
      shelter += BitCount8Bit[(pawns >> r) & 0xFF] * (128 >> i);
  }
  kingSquares[c] = ksq;
  kingShelters[c] = shelter;
  return shelter;
 }
--- a/src/pawns.h
+++ b/src/pawns.h
@@ -26,49 +26,47 @@
 ////
 #include "bitboard.h"
 #include "position.h"
 #include "value.h"
 ////
 //// Types
 ////
 const int PawnTableSize = 16384;
 /// PawnInfo is a class which contains various information about a pawn
 /// structure. Currently, it only includes a middle game and an end game
 /// pawn structure evaluation, and a bitboard of passed pawns. We may want
 /// 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 Position;
 class PawnInfo {
  friend class PawnInfoTable;
 public:
  PawnInfo() { clear(); }
  Score pawns_value() const;
  Value kingside_storm_value(Color c) const;
  Value queenside_storm_value(Color c) const;
  Bitboard pawn_attacks(Color c) const;
-  Bitboard passed_pawns() const;
+  Bitboard passed_pawns(Color c) const;
  int file_is_half_open(Color c, File f) const;
  int has_open_file_to_left(Color c, File f) const;
  int has_open_file_to_right(Color c, File f) const;
-  int get_king_shelter(const Position& pos, Color c, Square ksq);
+
  template<Color Us>
  Score king_shelter(const Position& pos, Square ksq);
 private:
-  void clear();
+  template<Color Us>
-  int updateShelter(const Position& pos, Color c, Square ksq);
+  Score updateShelter(const Position& pos, Square ksq);
  Key key;
-  Bitboard passedPawns;
+  Bitboard passedPawns[2];
  Bitboard pawnAttacks[2];
  Score value;
  int16_t ksStormValue[2], qsStormValue[2];
  uint8_t halfOpenFiles[2];
  Square kingSquares[2];
-  uint8_t kingShelters[2];
+  Score value;
  int halfOpenFiles[2];
  Score kingShelters[2];
 };
 /// The PawnInfoTable class represents a pawn hash table.  It is basically
@@ -78,16 +76,18 @@ private:
 class PawnInfoTable {
  enum SideType { KingSide, QueenSide };
 public:
-  PawnInfoTable(unsigned numOfEntries);
+  PawnInfoTable();
  ~PawnInfoTable();
-  PawnInfo* get_pawn_info(const Position& pos);
+  PawnInfo* get_pawn_info(const Position& pos) const;
  void prefetch(Key key) const;
 private:
  template<Color Us>
-  Score evaluate_pawns(const Position& pos, Bitboard ourPawns, Bitboard theirPawns, PawnInfo* pi);
+  Score evaluate_pawns(const Position& pos, Bitboard ourPawns, Bitboard theirPawns, PawnInfo* pi) const;
  unsigned size;
  PawnInfo* entries;
 };
@@ -96,24 +96,23 @@ private:
 //// Inline functions
 ////
-inline Score PawnInfo::pawns_value() const {
+inline void PawnInfoTable::prefetch(Key key) const {
-  return value;
+
    unsigned index = unsigned(key & (PawnTableSize - 1));
    PawnInfo* pi = entries + index;
    ::prefetch((char*) pi);
 }
-inline Bitboard PawnInfo::passed_pawns() const {
+inline Score PawnInfo::pawns_value() const {
-  return passedPawns;
+  return value;
 }
 inline Bitboard PawnInfo::pawn_attacks(Color c) const {
  return pawnAttacks[c];
 }
-inline Value PawnInfo::kingside_storm_value(Color c) const {
+inline Bitboard PawnInfo::passed_pawns(Color c) const {
-  return Value(ksStormValue[c]);
+  return passedPawns[c];
 }
 inline Value PawnInfo::queenside_storm_value(Color c) const {
  return Value(qsStormValue[c]);
 }
 inline int PawnInfo::file_is_half_open(Color c, File f) const {
@@ -128,8 +127,34 @@ inline int PawnInfo::has_open_file_to_right(Color c, File f) const {
  return halfOpenFiles[c] & ~((1 << int(f+1)) - 1);
 }
-inline int PawnInfo::get_king_shelter(const Position& pos, Color c, Square ksq) {
+/// PawnInfo::updateShelter() calculates and caches king shelter. It is called
-  return (kingSquares[c] == ksq ? kingShelters[c] : updateShelter(pos, c, ksq));
+/// only when king square changes, about 20% of total king_shelter() calls.
 template<Color Us>
 Score PawnInfo::updateShelter(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 = square_rank(ksq) * 8;
      for (int i = 1; i < 4; i++)
      {
          r += Shift;
          shelter += BitCount8Bit[(pawns >> r) & 0xFF] * (128 >> i);
      }
  }
  kingSquares[Us] = ksq;
  kingShelters[Us] = make_score(shelter, 0);
  return kingShelters[Us];
 }
 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)
--- a/src/piece.cpp
+++ b/src/piece.cpp
@@ -28,6 +28,33 @@
 using namespace std;
 // Tables indexed by Piece
 const Value PieceValueMidgame[17] = {
  VALUE_ZERO,
  PawnValueMidgame, KnightValueMidgame, BishopValueMidgame,
  RookValueMidgame, QueenValueMidgame,
  VALUE_ZERO, VALUE_ZERO, VALUE_ZERO,
  PawnValueMidgame, KnightValueMidgame, BishopValueMidgame,
  RookValueMidgame, QueenValueMidgame,
  VALUE_ZERO, VALUE_ZERO, VALUE_ZERO
 };
 const Value PieceValueEndgame[17] = {
  VALUE_ZERO,
  PawnValueEndgame, KnightValueEndgame, BishopValueEndgame,
  RookValueEndgame, QueenValueEndgame,
  VALUE_ZERO, VALUE_ZERO, VALUE_ZERO,
  PawnValueEndgame, KnightValueEndgame, BishopValueEndgame,
  RookValueEndgame, QueenValueEndgame,
  VALUE_ZERO, VALUE_ZERO, VALUE_ZERO
 };
 const int SlidingArray[18] = {
  0, 0, 0, 1, 2, 3, 0, 0, 0, 0, 0, 1, 2, 3, 0, 0, 0, 0
 };
 ////
 //// Functions
 ////
@@ -38,12 +65,12 @@ static const string PieceChars(" pnbrqk PNBRQK");
 char piece_type_to_char(PieceType pt, bool upcase) {
-  return PieceChars[pt + upcase * 7];
+  return PieceChars[pt + int(upcase) * 7];
 }
 PieceType piece_type_from_char(char c) {
  size_t idx = PieceChars.find(c);
-  return idx != string::npos ? PieceType(idx % 7) : NO_PIECE_TYPE;
+  return idx != string::npos ? PieceType(idx % 7) : PIECE_TYPE_NONE;
 }
--- a/src/piece.h
+++ b/src/piece.h
@@ -27,6 +27,7 @@
 #include "color.h"
 #include "square.h"
 #include "value.h"
 ////
@@ -34,39 +35,49 @@
 ////
 enum PieceType {
-  NO_PIECE_TYPE = 0,
+  PIECE_TYPE_NONE = 0,
  PAWN = 1, KNIGHT = 2, BISHOP = 3, ROOK = 4, QUEEN = 5, KING = 6
 };
 enum Piece {
-  NO_PIECE = 0, WP = 1, WN = 2, WB = 3, WR = 4, WQ = 5, WK = 6,
+  PIECE_NONE_DARK_SQ = 0, WP = 1, WN = 2, WB = 3, WR = 4, WQ = 5, WK = 6,
-  BP = 9, BN = 10, BB = 11, BR = 12, BQ = 13, BK = 14,
+  BP = 9, BN = 10, BB = 11, BR = 12, BQ = 13, BK = 14, PIECE_NONE = 16
  EMPTY = 16, OUTSIDE = 17
 };
 ENABLE_OPERATORS_ON(PieceType);
 ENABLE_OPERATORS_ON(Piece);
 ////
 //// Constants
 ////
-const int SlidingArray[18] = {
+/// Important: If the material values are changed, one must also
-  0, 0, 0, 1, 2, 3, 0, 0, 0, 0, 0, 1, 2, 3, 0, 0, 0, 0
+/// adjust the piece square tables, and the method game_phase() in the
-};
+/// Position class!
 ///
 /// Values modified by Joona Kiiski
 const Value PawnValueMidgame   = Value(0x0C6);
 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);
 extern const Value PieceValueMidgame[17];
 extern const Value PieceValueEndgame[17];
 extern const int SlidingArray[18];
 ////
 //// Inline functions
 ////
 inline Piece operator+ (Piece p, int i) { return Piece(int(p) + i); }
 inline void operator++ (Piece &p, int) { p = Piece(int(p) + 1); }
 inline Piece operator- (Piece p, int i) { return Piece(int(p) - i); }
 inline void operator-- (Piece &p, int) { p = Piece(int(p) - 1); }
 inline PieceType operator+ (PieceType p, int i) {return PieceType(int(p) + i);}
 inline void operator++ (PieceType &p, int) { p = PieceType(int(p) + 1); }
 inline PieceType operator- (PieceType p, int i) {return PieceType(int(p) - i);}
 inline void operator-- (PieceType &p, int) { p = PieceType(int(p) - 1); }
 inline PieceType type_of_piece(Piece p)  {
  return PieceType(int(p) & 7);
 }
@@ -80,7 +91,7 @@ inline Piece piece_of_color_and_type(Color c, PieceType pt) {
 }
 inline int piece_is_slider(Piece p) {
-  return SlidingArray[int(p)];
+  return SlidingArray[p];
 }
 inline SquareDelta pawn_push(Color c) {
--- a/src/position.cpp
+++ b/src/position.cpp
--- a/src/position.h
+++ b/src/position.h
@@ -50,9 +50,6 @@
 //// Constants
 ////
 /// FEN string for the initial position
 const std::string StartPosition = "rnbqkbnr/pppppppp/8/8/8/8/PPPPPPPP/RNBQKBNR w KQkq - 0 1";
 /// 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).
@@ -68,22 +65,22 @@ const int MaxGameLength = 220;
 struct CheckInfo {
-    CheckInfo(const Position&);
+    explicit CheckInfo(const Position&);
    Square ksq;
    Bitboard dcCandidates;
    Bitboard checkSq[8];
    Square ksq;
 };
 /// Castle rights, encoded as bit fields
 enum CastleRights {
-  NO_CASTLES  = 0,
+  CASTLES_NONE = 0,
-  WHITE_OO    = 1,
+  WHITE_OO     = 1,
-  BLACK_OO    = 2,
+  BLACK_OO     = 2,
-  WHITE_OOO   = 4,
+  WHITE_OOO    = 4,
-  BLACK_OOO   = 8,
+  BLACK_OOO    = 8,
-  ALL_CASTLES = 15
+  ALL_CASTLES  = 15
 };
 /// Game phase
@@ -100,13 +97,13 @@ enum Phase {
 struct StateInfo {
  Key pawnKey, materialKey;
-  int castleRights, rule50, pliesFromNull;
+  int castleRights, rule50, gamePly, pliesFromNull;
  Square epSquare;
  Score value;
  Value npMaterial[2];
  PieceType capturedType;
  Key key;
  PieceType capture;
  Bitboard checkersBB;
  StateInfo* previous;
 };
@@ -139,6 +136,9 @@ class Position {
  friend class MaterialInfo;
  friend class EndgameFunctions;
  Position(); // No default or copy c'tor allowed
  Position(const Position& pos);
 public:
  enum GamePhase {
      MidGame,
@@ -146,9 +146,9 @@ public:
  };
  // Constructors
-  Position();
+  explicit Position(int threadID);
-  explicit Position(const Position& pos);
+  Position(const Position& pos, int threadID);
-  explicit Position(const std::string& fen);
+  Position(const std::string& fen, int threadID);
  // Text input/output
  void from_fen(const std::string& fen);
@@ -224,13 +224,10 @@ public:
  bool move_attacks_square(Move m, Square s) const;
  // Piece captured with previous moves
-  PieceType captured_piece() const;
+  PieceType captured_piece_type() const;
  // Information about pawns
  bool pawn_is_passed(Color c, Square s) const;
  static bool pawn_is_passed(Bitboard theirPawns, Color c, Square s);
  static bool pawn_is_isolated(Bitboard ourPawns, Square s);
  static bool pawn_is_doubled(Bitboard ourPawns, Color c, Square s);
  // Weak squares
  bool square_is_weak(Square s, Color c) const;
@@ -246,7 +243,6 @@ public:
  // Static exchange evaluation
  int see(Square from, Square to) const;
  int see(Move m) const;
  int see(Square to) const;
  int see_sign(Move m) const;
  // Accessing hash keys
@@ -258,25 +254,33 @@ public:
  // Incremental evaluation
  Score value() const;
  Value non_pawn_material(Color c) const;
-  Score pst_delta(Piece piece, Square from, Square to) const;
+  static Score pst_delta(Piece piece, Square from, Square to);
  // Game termination checks
  bool is_mate() const;
  bool is_draw() const;
-  // Check if one side threatens a mate in one
+  // Check if side to move could be mated in one
-  bool has_mate_threat(Color c);
+  bool has_mate_threat();
  // Number of plies since the last non-reversible move
  int rule_50_counter() const;
  int startpos_ply_counter() const;
  // Other properties of the position
  bool opposite_colored_bishops() const;
  bool has_pawn_on_7th(Color c) const;
  bool is_chess960() const;
  // Current thread ID searching on the position
  int thread() const;
  // Reset the gamePly variable to 0
  void reset_game_ply();
  void inc_startpos_ply_counter();
  // Position consistency check, for debugging
  bool is_ok(int* failedStep = NULL) const;
@@ -291,9 +295,10 @@ private:
  void put_piece(Piece p, Square s);
  void allow_oo(Color c);
  void allow_ooo(Color c);
  bool set_castling_rights(char token);
  // Helper functions for doing and undoing moves
-  void do_capture_move(Bitboard& key, PieceType capture, Color them, Square to, bool ep);
+  void do_capture_move(Key& key, PieceType capture, Color them, Square to, bool ep);
  void do_castle_move(Move m);
  void undo_castle_move(Move m);
  void find_checkers();
@@ -307,7 +312,7 @@ private:
  Key compute_material_key() const;
  // Computing incremental evaluation scores and material counts
-  Score pst(Color c, PieceType pt, Square s) const;
+  static Score pst(Color c, PieceType pt, Square s);
  Score compute_value() const;
  Value compute_non_pawn_material(Color c) const;
@@ -326,21 +331,23 @@ private:
  // Other info
  Color sideToMove;
  int gamePly;
  Key history[MaxGameLength];
  int castleRightsMask[64];
  File initialKFile, initialKRFile, initialQRFile;
  StateInfo startState;
  File initialKFile, initialKRFile, initialQRFile;
  bool isChess960;
  int startPosPlyCounter;
  int threadID;
  StateInfo* st;
  // Static variables
  static Key zobrist[2][8][64];
  static Key zobEp[64];
  static Key zobCastle[16];
  static Key zobMaterial[2][8][16];
  static Key zobSideToMove;
  static Score PieceSquareTable[16][64];
  static Key zobExclusion;
  static const Value seeValues[8];
 };
@@ -361,7 +368,7 @@ inline PieceType Position::type_of_piece_on(Square s) const {
 }
 inline bool Position::square_is_empty(Square s) const {
-  return piece_on(s) == EMPTY;
+  return piece_on(s) == PIECE_NONE;
 }
 inline bool Position::square_is_occupied(Square s) const {
@@ -369,11 +376,11 @@ inline bool Position::square_is_occupied(Square s) const {
 }
 inline Value Position::midgame_value_of_piece_on(Square s) const {
-  return piece_value_midgame(piece_on(s));
+  return PieceValueMidgame[piece_on(s)];
 }
 inline Value Position::endgame_value_of_piece_on(Square s) const {
-  return piece_value_endgame(piece_on(s));
+  return PieceValueEndgame[piece_on(s)];
 }
 inline Color Position::side_to_move() const {
@@ -412,8 +419,8 @@ inline int Position::piece_count(Color c, PieceType pt) const {
  return pieceCount[c][pt];
 }
-inline Square Position::piece_list(Color c, PieceType pt, int index) const {
+inline Square Position::piece_list(Color c, PieceType pt, int idx) const {
-  return pieceList[c][pt][index];
+  return pieceList[c][pt][idx];
 }
 inline const Square* Position::piece_list_begin(Color c, PieceType pt) const {
@@ -485,20 +492,8 @@ inline bool Position::pawn_is_passed(Color c, Square s) const {
  return !(pieces(PAWN, opposite_color(c)) & passed_pawn_mask(c, s));
 }
 inline bool Position::pawn_is_passed(Bitboard theirPawns, Color c, Square s) {
  return !(theirPawns & passed_pawn_mask(c, s));
 }
 inline bool Position::pawn_is_isolated(Bitboard ourPawns, Square s) {
  return !(ourPawns & neighboring_files_bb(s));
 }
 inline bool Position::pawn_is_doubled(Bitboard ourPawns, Color c, Square s) {
  return ourPawns & squares_behind(c, s);
 }
 inline bool Position::square_is_weak(Square s, Color c) const {
-  return !(pieces(PAWN, c) & outpost_mask(opposite_color(c), s));
+  return !(pieces(PAWN, opposite_color(c)) & attack_span_mask(c, s));
 }
 inline Key Position::get_key() const {
@@ -517,11 +512,11 @@ inline Key Position::get_material_key() const {
  return st->materialKey;
 }
-inline Score Position::pst(Color c, PieceType pt, Square s) const {
+inline Score Position::pst(Color c, PieceType pt, Square s) {
  return PieceSquareTable[piece_of_color_and_type(c, pt)][s];
 }
-inline Score Position::pst_delta(Piece piece, Square from, Square to) const {
+inline Score Position::pst_delta(Piece piece, Square from, Square to) {
  return PieceSquareTable[piece][to] - PieceSquareTable[piece][from];
 }
@@ -545,11 +540,16 @@ inline int Position::rule_50_counter() const {
  return st->rule50;
 }
 inline int Position::startpos_ply_counter() const {
  return startPosPlyCounter;
 }
 inline bool Position::opposite_colored_bishops() const {
  return   piece_count(WHITE, BISHOP) == 1
        && piece_count(BLACK, BISHOP) == 1
-        && square_color(piece_list(WHITE, BISHOP, 0)) != square_color(piece_list(BLACK, BISHOP, 0));
+        && !same_color_squares(piece_list(WHITE, BISHOP, 0), piece_list(BLACK, BISHOP, 0));
 }
 inline bool Position::has_pawn_on_7th(Color c) const {
@@ -557,6 +557,11 @@ inline bool Position::has_pawn_on_7th(Color c) const {
  return pieces(PAWN, c) & relative_rank_bb(c, RANK_7);
 }
 inline bool Position::is_chess960() const {
  return isChess960;
 }
 inline bool Position::move_is_capture(Move m) const {
  // Move must not be MOVE_NONE !
@@ -569,8 +574,12 @@ inline bool Position::move_is_capture_or_promotion(Move m) const {
  return (m & (0x1F << 12)) ? !move_is_castle(m) : !square_is_empty(move_to(m));
 }
-inline PieceType Position::captured_piece() const {
+inline PieceType Position::captured_piece_type() const {
-  return st->capture;
+  return st->capturedType;
 }
 inline int Position::thread() const {
  return threadID;
 }
 #endif // !defined(POSITION_H_INCLUDED)
--- a/src/san.cpp
+++ b/src/san.cpp
@@ -47,7 +47,7 @@ namespace {
    AMBIGUITY_BOTH
  };
-  const History H; // used as dummy argument for MovePicker c'tor
+  const History H; // Used as dummy argument for MovePicker c'tor
  Ambiguity move_ambiguity(const Position& pos, Move m);
  const string time_string(int milliseconds);
@@ -68,28 +68,25 @@ const string move_to_san(Position& pos, Move m) {
  assert(pos.is_ok());
  assert(move_is_ok(m));
-  Square from, to;
+  string san;
-  PieceType pt;
+  Square from = move_from(m);
-
+  Square to = move_to(m);
-  from = move_from(m);
+  PieceType pt = type_of_piece(pos.piece_on(move_from(m)));
  to = move_to(m);
  pt = type_of_piece(pos.piece_on(move_from(m)));
  string san = "";
  if (m == MOVE_NONE)
      return "(none)";
  else if (m == MOVE_NULL)
      return "(null)";
-  else if (move_is_long_castle(m) || (int(to - from) == -2 && pt == KING))
+  else if (move_is_long_castle(m)  || (int(to - from) == -2 && pt == KING))
      san = "O-O-O";
-  else if (move_is_short_castle(m) || (int(to - from) == 2 && pt == KING))
+  else if (move_is_short_castle(m) || (int(to - from) ==  2 && pt == KING))
      san = "O-O";
  else
  {
      if (pt != PAWN)
      {
          san += piece_type_to_char(pt, true);
          switch (move_ambiguity(pos, m)) {
          case AMBIGUITY_NONE:
            break;
@@ -115,13 +112,13 @@ const string move_to_san(Position& pos, Move m) {
      san += square_to_string(move_to(m));
      if (move_is_promotion(m))
      {
-          san += '=';
+          san += "=";
          san += piece_type_to_char(move_promotion_piece(m), true);
      }
  }
-  // Is the move check?  We don't use pos.move_is_check(m) here, because
+
-  // Position::move_is_check doesn't detect all checks (not castling moves,
+  // The move gives check ? We don't use pos.move_is_check() here
-  // promotions and en passant captures).
+  // because we need to test for mate after the move is done.
  StateInfo st;
  pos.do_move(m, st);
  if (pos.is_check())
@@ -141,7 +138,7 @@ Move move_from_san(const Position& pos, const string& movestr) {
  assert(pos.is_ok());
-  MovePicker mp = MovePicker(pos, MOVE_NONE, OnePly, H);
+  MovePicker mp = MovePicker(pos, MOVE_NONE, ONE_PLY, H);
  Bitboard pinned = pos.pinned_pieces(pos.side_to_move());
  // Castling moves
@@ -167,7 +164,7 @@ Move move_from_san(const Position& pos, const string& movestr) {
  // Normal moves. We use a simple FSM to parse the san string.
  enum { START, TO_FILE, TO_RANK, PROMOTION_OR_CHECK, PROMOTION, CHECK, END };
  static const string pieceLetters = "KQRBN";
-  PieceType pt = NO_PIECE_TYPE, promotion = NO_PIECE_TYPE;
+  PieceType pt = PIECE_TYPE_NONE, promotion = PIECE_TYPE_NONE;
  File fromFile = FILE_NONE, toFile = FILE_NONE;
  Rank fromRank = RANK_NONE, toRank = RANK_NONE;
  Square to;
@@ -299,23 +296,23 @@ const string line_to_san(const Position& pos, Move line[], int startColumn, bool
  string moveStr;
  size_t length = 0;
  size_t maxLength = 80 - startColumn;
-  Position p(pos);
+  Position p(pos, pos.thread());
-  for (int i = 0; line[i] != MOVE_NONE; i++)
+  for (Move* m = line; *m != MOVE_NONE; m++)
  {
-      moveStr = move_to_san(p, line[i]);
+      moveStr = move_to_san(p, *m);
      length += moveStr.length() + 1;
      if (breakLines && length > maxLength)
      {
-          s << '\n' << std::setw(startColumn) << ' ';
+          s << "\n" << std::setw(startColumn) << " ";
          length = moveStr.length() + 1;
      }
      s << moveStr << ' ';
-      if (line[i] == MOVE_NULL)
+      if (*m == MOVE_NULL)
          p.do_null_move(st);
      else
-          p.do_move(line[i], st);
+          p.do_move(*m, st);
  }
  return s.str();
 }
@@ -325,27 +322,31 @@ const string line_to_san(const Position& pos, Move line[], int startColumn, bool
 /// 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(const Position& pos, int time, int depth,
+const string pretty_pv(const Position& pos, int time, int depth, uint64_t nodes,
-                       uint64_t nodes, Value score, ValueType type, Move pv[]) {
+                       Value score, ValueType type, Move pv[]) {
  const uint64_t K = 1000;
  const uint64_t M = 1000000;
  std::stringstream s;
  // Depth
  s << std::setw(2) << depth << "  ";
  // Score
-  s << ((type == VALUE_TYPE_LOWER)? ">" : ((type == VALUE_TYPE_UPPER)? "<" : " "));
+  s << (type == VALUE_TYPE_LOWER ? ">" : type == VALUE_TYPE_UPPER ? "<" : " ")
-  s << std::setw(7) << score_string(score);
+    << std::setw(7) << score_string(score);
  // Time
  s << std::setw(8) << time_string(time) << " ";
  // Nodes
-  if (nodes < 1000000ULL)
+  if (nodes < M)
-    s << std::setw(8) << nodes << " ";
+      s << std::setw(8) << nodes / 1 << " ";
-  else if (nodes < 1000000000ULL)
+  else if (nodes < K * M)
-    s << std::setw(7) << nodes/1000ULL << 'k' << " ";
+      s << std::setw(7) << nodes / K << "K ";
  else
-    s << std::setw(7) << nodes/1000000ULL << 'M' << " ";
+      s << std::setw(7) << nodes / M << "M ";
  // PV
  s << line_to_san(pos, pv, 30, true);
@@ -367,7 +368,7 @@ namespace {
    if (type_of_piece(pc) == KING)
        return AMBIGUITY_NONE;
-    MovePicker mp = MovePicker(pos, MOVE_NONE, OnePly, H);
+    MovePicker mp = MovePicker(pos, MOVE_NONE, ONE_PLY, H);
    Bitboard pinned = pos.pinned_pieces(pos.side_to_move());
    Move mv, moveList[8];
@@ -398,14 +399,17 @@ namespace {
  }
-  const string time_string(int milliseconds) {
+  const string time_string(int millisecs) {
    const int MSecMinute = 1000 * 60;
    const int MSecHour   = 1000 * 60 * 60;
    std::stringstream s;
    s << std::setfill('0');
-    int hours = milliseconds / (1000*60*60);
+    int hours = millisecs / MSecHour;
-    int minutes = (milliseconds - hours*1000*60*60) / (1000*60);
+    int minutes = (millisecs - hours * MSecHour) / MSecMinute;
-    int seconds = (milliseconds - hours*1000*60*60 - minutes*1000*60) / 1000;
+    int seconds = (millisecs - hours * MSecHour - minutes * MSecMinute) / 1000;
    if (hours)
        s << hours << ':';
@@ -421,7 +425,7 @@ namespace {
    if (v >= VALUE_MATE - 200)
        s << "#" << (VALUE_MATE - v + 1) / 2;
-    else if(v <= -VALUE_MATE + 200)
+    else if (v <= -VALUE_MATE + 200)
        s << "-#" << (VALUE_MATE + v) / 2;
    else
    {
--- a/src/search.cpp
+++ b/src/search.cpp
--- a/src/search.h
+++ b/src/search.h
@@ -36,7 +36,6 @@
 const int PLY_MAX = 100;
 const int PLY_MAX_PLUS_2 = 102;
 const int KILLER_MAX = 2;
 ////
@@ -50,16 +49,14 @@ const int KILLER_MAX = 2;
 struct EvalInfo;
 struct SearchStack {
  Move pv[PLY_MAX_PLUS_2];
  Move currentMove;
  Move mateKiller;
-  Move threatMove;
+  Move excludedMove;
-  Move killers[KILLER_MAX];
+  Move bestMove;
  Move killers[2];
  Depth reduction;
  Value eval;
-
+  bool skipNullMove;
  void init(int ply);
  void initKillers();
 };
@@ -70,11 +67,9 @@ struct SearchStack {
 extern void init_search();
 extern void init_threads();
 extern void exit_threads();
-extern bool think(const Position &pos, bool infinite, bool ponder, int side_to_move,
+extern int perft(Position& pos, Depth depth);
                  int time[], int increment[], int movesToGo, int maxDepth,
                  int maxNodes, int maxTime, Move searchMoves[]);
 extern int perft(Position &pos, Depth depth);
 extern int64_t nodes_searched();
-
+extern bool think(const Position& pos, bool infinite, bool ponder, int time[], int increment[],
                  int movesToGo, int maxDepth, int maxNodes, int maxTime, Move searchMoves[]);
 #endif // !defined(SEARCH_H_INCLUDED)
--- a/src/square.h
+++ b/src/square.h
@@ -64,6 +64,11 @@ enum SquareDelta {
  DELTA_NN = 020, DELTA_NNE = 021
 };
 ENABLE_OPERATORS_ON(Square);
 ENABLE_OPERATORS_ON(File);
 ENABLE_OPERATORS_ON(Rank);
 ENABLE_OPERATORS_ON(SquareDelta);
 ////
 //// Constants
@@ -77,35 +82,10 @@ const int FlopMask = 07;
 //// Inline functions
 ////
-inline File operator+ (File x, int i) { return File(int(x) + i); }
+inline Square operator+ (Square x, SquareDelta i) { return x + Square(i); }
-inline File operator+ (File x, File y) { return x + int(y); }
+inline void operator+= (Square& x, SquareDelta i) { x = x + Square(i); }
-inline void operator++ (File &x, int) { x = File(int(x) + 1); }
+inline Square operator- (Square x, SquareDelta i) { return x - Square(i); }
-inline void operator+= (File &x, int i) { x = File(int(x) + i); }
+inline void operator-= (Square& x, SquareDelta i) { x = x - Square(i); }
 inline File operator- (File x, int i) { return File(int(x) - i); }
 inline void operator-- (File &x, int) { x = File(int(x) - 1); }
 inline void operator-= (File &x, int i) { x = File(int(x) - i); }
 inline Rank operator+ (Rank x, int i) { return Rank(int(x) + i); }
 inline Rank operator+ (Rank x, Rank y) { return x + int(y); }
 inline void operator++ (Rank &x, int) { x = Rank(int(x) + 1); }
 inline void operator+= (Rank &x, int i) { x = Rank(int(x) + i); }
 inline Rank operator- (Rank x, int i) { return Rank(int(x) - i); }
 inline void operator-- (Rank &x, int) { x = Rank(int(x) - 1); }
 inline void operator-= (Rank &x, int i) { x = Rank(int(x) - i); }
 inline Square operator+ (Square x, int i) { return Square(int(x) + i); }
 inline void operator++ (Square &x, int) { x = Square(int(x) + 1); }
 inline void operator+= (Square &x, int i) { x = Square(int(x) + i); }
 inline Square operator- (Square x, int i) { return Square(int(x) - i); }
 inline void operator-- (Square &x, int) { x = Square(int(x) - 1); }
 inline void operator-= (Square &x, int i) { x = Square(int(x) - i); }
 inline Square operator+ (Square x, SquareDelta i) { return Square(int(x) + i); }
 inline void operator+= (Square &x, SquareDelta i) { x = Square(int(x) + i); }
 inline Square operator- (Square x, SquareDelta i) { return Square(int(x) - i); }
 inline void operator-= (Square &x, SquareDelta i) { x = Square(int(x) - i); }
 inline SquareDelta operator- (Square x, Square y) {
  return SquareDelta(int(x) - int(y));
 }
 inline Square make_square(File f, Rank r) {
  return Square(int(f) | (int(r) << 3));
@@ -135,8 +115,13 @@ inline Rank relative_rank(Color c, Square s) {
  return square_rank(relative_square(c, s));
 }
-inline Color square_color(Square s) {
+inline SquareColor square_color(Square s) {
-  return Color((int(square_file(s)) + int(square_rank(s))) & 1);
+  return SquareColor((int(square_file(s)) + int(square_rank(s))) & 1);
 }
 inline bool same_color_squares(Square s1, Square s2) {
  int s = int(s1) ^ int(s2);
  return (((s >> 3) ^ s) & 1) == 0;
 }
 inline int file_distance(File f1, File f2) {
@@ -180,10 +165,8 @@ inline Square square_from_string(const std::string& str) {
 }
 inline const std::string square_to_string(Square s) {
-  std::string str;
+  return  std::string(1, file_to_char(square_file(s)))
-  str += file_to_char(square_file(s));
+        + std::string(1, rank_to_char(square_rank(s)));
  str += rank_to_char(square_rank(s));
  return str;
 }
 inline bool file_is_ok(File f) {
--- a/src/thread.h
+++ b/src/thread.h
@@ -39,7 +39,7 @@
 ////
 const int MAX_THREADS = 8;
-const int ACTIVE_SPLIT_POINTS_MAX = 8;
+const int MAX_ACTIVE_SPLIT_POINTS = 8;
 ////
@@ -51,11 +51,11 @@ struct SplitPoint {
  // Const data after splitPoint has been setup
  SplitPoint* parent;
  const Position* pos;
  bool pvNode;
  Depth depth;
-  bool mateThreat;
+  bool pvNode, mateThreat;
  Value beta;
-  int ply, master, slaves[MAX_THREADS];
+  int ply;
  Move threatMove;
  SearchStack sstack[MAX_THREADS][PLY_MAX_PLUS_2];
  // Const pointers to shared data
@@ -66,9 +66,9 @@ struct SplitPoint {
  Lock lock;
  volatile Value alpha;
  volatile Value bestValue;
-  volatile int moves;
+  volatile int moveCount;
  volatile int cpus;
  volatile bool stopRequest;
  volatile int slaves[MAX_THREADS];
 };
 // ThreadState type is used to represent thread's current state
@@ -84,12 +84,11 @@ enum ThreadState
 };
 struct Thread {
  SplitPoint* splitPoint;
  volatile int activeSplitPoints;
  uint64_t nodes;
  uint64_t betaCutOffs[2];
  volatile ThreadState state;
-  unsigned char pad[64]; // set some distance among local data for each thread
+  SplitPoint* volatile splitPoint;
  volatile int activeSplitPoints;
  SplitPoint splitPoints[MAX_ACTIVE_SPLIT_POINTS];
 };
--- a/src/timeman.cpp
+++ b/src/timeman.cpp
@@ -0,0 +1,170 @@
 /*
  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/>.
 */
 ////
 //// Includes
 ////
 #include <cmath>
 #include "misc.h"
 #include "timeman.h"
 #include "ucioption.h"
 ////
 //// Local definitions
 ////
 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>
  int remaining(int myTime, int movesToGo, int currentPly);
 }
 ////
 //// Functions
 ////
 void TimeManager::pv_unstability(int curChanges, int prevChanges) {
    unstablePVExtraTime =  curChanges  * (optimumSearchTime / 2)
                         + prevChanges * (optimumSearchTime / 3);
 }
 void TimeManager::init(int myTime, int myInc, int movesToGo, int currentPly)
 {
  /* We support four different kind of time controls:
      Inc == 0 && movesToGo == 0 means: x basetime  [sudden death!]
      Inc == 0 && movesToGo != 0 means: (x moves) / (y minutes)
      Inc > 0  && movesToGo == 0 means: x basetime + z inc.
      Inc > 0  && movesToGo != 0 means: (x moves) / (y minutes) + z inc
    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 = get_option_value_int("Emergency Move Horizon");
  int emergencyBaseTime    = get_option_value_int("Emergency Base Time");
  int emergencyMoveTime    = get_option_value_int("Emergency Move Time");
  int minThinkingTime      = get_option_value_int("Minimum Thinking Time");
  // Initialize to maximum values but unstablePVExtraTime that is reset
  unstablePVExtraTime = 0;
  optimumSearchTime = maximumSearchTime = myTime;
  // 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 <= (movesToGo ? Min(movesToGo, MoveHorizon) : MoveHorizon); hypMTG++)
  {
      // Calculate thinking time for hypothetic "moves to go"-value
      hypMyTime = Max(myTime + (hypMTG - 1) * myInc - emergencyBaseTime - Min(hypMTG, emergencyMoveHorizon) * emergencyMoveTime, 0);
      t1 = minThinkingTime + remaining<OptimumTime>(hypMyTime, hypMTG, currentPly);
      t2 = minThinkingTime + remaining<MaxTime>(hypMyTime, hypMTG, currentPly);
      optimumSearchTime = Min(optimumSearchTime, t1);
      maximumSearchTime = Min(maximumSearchTime, t2);
  }
  if (get_option_value_bool("Ponder"))
      optimumSearchTime += optimumSearchTime / 4;
  // Make sure that maxSearchTime is not over absoluteMaxSearchTime
  optimumSearchTime = Min(optimumSearchTime, maximumSearchTime);
 }
 ////
 //// Local functions
 ////
 namespace {
  template<TimeType T>
  int remaining(int myTime, int movesToGo, int currentPly)
  {
    const float TMaxRatio   = (T == OptimumTime ? 1 : MaxRatio);
    const float TStealRatio = (T == OptimumTime ? 0 : StealRatio);
    int thisMoveImportance = move_importance(currentPly);
    int otherMovesImportance = 0;
    for (int i = 1; i < movesToGo; i++)
        otherMovesImportance += move_importance(currentPly + 2 * i);
    float ratio1 = (TMaxRatio * thisMoveImportance) / float(TMaxRatio * thisMoveImportance + otherMovesImportance);
    float ratio2 = (thisMoveImportance + TStealRatio * otherMovesImportance) / float(thisMoveImportance + otherMovesImportance);
    return int(floor(myTime * Min(ratio1, ratio2)));
  }
 }
--- a/src/timeman.h
+++ b/src/timeman.h
@@ -18,35 +18,25 @@
 */
-#if !defined(SCALE_H_INCLUDED)
+#if !defined(TIMEMAN_H_INCLUDED)
-#define SCALE_H_INCLUDED
+#define TIMEMAN_H_INCLUDED
 ////
-//// Includes
+//// Prototypes
 ////
-#include "value.h"
+class TimeManager {
 public:
  void init(int myTime, int myInc, int movesToGo, int currentPly);
  void pv_unstability(int curChanges, int prevChanges);
  int available_time() const { return optimumSearchTime + unstablePVExtraTime; }
  int maximum_time() const { return maximumSearchTime; }
-////
+private:
-//// Types
+  int optimumSearchTime;
-////
+  int maximumSearchTime;
-
+  int unstablePVExtraTime;
 enum ScaleFactor {
  SCALE_FACTOR_ZERO = 0,
  SCALE_FACTOR_NORMAL = 64,
  SCALE_FACTOR_MAX = 128,
  SCALE_FACTOR_NONE = 255
 };
-
+#endif // !defined(TIMEMAN_H_INCLUDED)
 ////
 //// Inline functions
 ////
 inline Value apply_scale_factor(Value v, ScaleFactor f) {
  return Value((v * f) / int(SCALE_FACTOR_NORMAL));
 }
 #endif // !defined(SCALE_H_INCLUDED)
--- a/src/tt.cpp
+++ b/src/tt.cpp
@@ -23,13 +23,8 @@
 ////
 #include <cassert>
 #include <cmath>
 #include <cstring>
 #if !(defined(__hpux) || defined(__ppc__) || defined(__ppc64__) || defined(__arm__))
 #  include <xmmintrin.h>
 #endif
 #include "movegen.h"
 #include "tt.h"
 // The main transposition table
@@ -41,7 +36,7 @@ TranspositionTable TT;
 TranspositionTable::TranspositionTable() {
-  size = writes = 0;
+  size = 0;
  entries = 0;
  generation = 0;
 }
@@ -59,8 +54,10 @@ void TranspositionTable::set_size(size_t mbSize) {
  size_t newSize = 1024;
-  // We store a cluster of ClusterSize number of TTEntry for each position
+  // Transposition table consists of clusters and
-  // and newSize is the maximum number of storable positions.
+  // each cluster consists of ClusterSize number of TTEntries.
  // Each non-empty entry contains information of exactly one position.
  // newSize is the number of clusters we are going to allocate.
  while ((2 * newSize) * sizeof(TTCluster) <= (mbSize << 20))
      newSize *= 2;
@@ -75,7 +72,6 @@ void TranspositionTable::set_size(size_t mbSize) {
                    << " MB for transposition table." << std::endl;
          Application::exit_with_failure();
      }
      clear();
  }
 }
@@ -83,7 +79,7 @@ void TranspositionTable::set_size(size_t mbSize) {
 /// TranspositionTable::clear overwrites the entire transposition table
 /// with zeroes. It is called whenever the table is resized, or when the
 /// user asks the program to clear the table (from the UCI interface).
-/// Perhaps we should also clear it when the "ucinewgame" command is recieved?
+/// Perhaps we should also clear it when the "ucinewgame" command is received?
 void TranspositionTable::clear() {
@@ -91,28 +87,19 @@ void TranspositionTable::clear() {
 }
-/// TranspositionTable::first_entry returns a pointer to the first
+/// TranspositionTable::store writes a new entry containing position key and
-/// entry of a cluster given a position. The low 32 bits of the key
+/// valuable information of current position.
-/// are used to get the index in the table.
+/// The Lowest order bits of position key are used to decide on which cluster
-
+/// the position will be placed.
-inline TTEntry* TranspositionTable::first_entry(const Key posKey) const {
+/// When a new entry is written and there are no empty entries available in cluster,
-
+/// it replaces the least valuable of entries.
-  return entries[uint32_t(posKey) & (size - 1)].data;
+/// A TTEntry t1 is considered to be more valuable than a TTEntry t2 if t1 is from the
 }
 /// TranspositionTable::store writes a new entry containing a position,
 /// a value, a value type, a search depth, and a best move to the
 /// transposition table. Transposition table is organized in clusters of
 /// four TTEntry objects, and when a new entry is written, it replaces
 /// the least valuable of the four entries in a cluster. A TTEntry t1 is
 /// considered to be more valuable than a TTEntry t2 if t1 is from the
 /// current search and t2 is from a previous search, or if the depth of t1
-/// is bigger than the depth of t2. A TTEntry of type VALUE_TYPE_EVAL
+/// is bigger than the depth of t2.
 /// never replaces another entry for the same position.
-void TranspositionTable::store(const Key posKey, Value v, ValueType t, Depth d, Move m) {
+void TranspositionTable::store(const Key posKey, Value v, ValueType t, Depth d, Move m, Value statV, Value kingD) {
  int c1, c2, c3;
  TTEntry *tte, *replace;
  uint32_t posKey32 = posKey >> 32; // Use the high 32 bits as key
@@ -121,29 +108,25 @@ void TranspositionTable::store(const Key posKey, Value v, ValueType t, Depth d,
  {
      if (!tte->key() || tte->key() == posKey32) // empty or overwrite old
      {
-          // Do not overwrite when new type is VALUE_TYPE_EV_LO
+          // Preserve any existing ttMove
          if (tte->key() && t == VALUE_TYPE_EV_LO)
              return;
          // Preserve any exsisting ttMove
          if (m == MOVE_NONE)
              m = tte->move();
-          *tte = TTEntry(posKey32, v, t, d, m, generation);
+          tte->save(posKey32, v, t, d, m, generation, statV, kingD);
          return;
      }
-      else if (i == 0)  // replace would be a no-op in this common case
+
      if (i == 0)  // Replacing first entry is default and already set before entering for-loop
          continue;
-      int c1 = (replace->generation() == generation ?  2 : 0);
+      c1 = (replace->generation() == generation ?  2 : 0);
-      int c2 = (tte->generation() == generation ? -2 : 0);
+      c2 = (tte->generation() == generation ? -2 : 0);
-      int c3 = (tte->depth() < replace->depth() ?  1 : 0);
+      c3 = (tte->depth() < replace->depth() ?  1 : 0);
      if (c1 + c2 + c3 > 0)
          replace = tte;
  }
-  *replace = TTEntry(posKey32, v, t, d, m, generation);
+  replace->save(posKey32, v, t, d, m, generation, statV, kingD);
  writes++;
 }
@@ -164,100 +147,11 @@ TTEntry* TranspositionTable::retrieve(const Key posKey) const {
 }
 /// TranspositionTable::prefetch looks up the current position in the
 /// transposition table and load it in L1/L2 cache. This is a non
 /// blocking function and do not stalls the CPU waiting for data
 /// to be loaded from RAM, that can be very slow. When we will
 /// subsequently call retrieve() the TT data will be already
 /// quickly accessible in L1/L2 CPU cache.
 #if defined(__hpux) || defined(__ppc__) || defined(__ppc64__) || defined(__arm__)
 void TranspositionTable::prefetch(const Key) const {} // Not supported on HP UX
 #else
 void TranspositionTable::prefetch(const Key posKey) const {
 #if defined(__INTEL_COMPILER) || defined(__ICL)
   // This hack prevents prefetches to be optimized away by
   // Intel compiler. Both MSVC and gcc seems not affected.
   __asm__ ("");
 #endif
   char const* addr = (char*)first_entry(posKey);
  _mm_prefetch(addr, _MM_HINT_T2);
  _mm_prefetch(addr+64, _MM_HINT_T2); // 64 bytes ahead
 }
 #endif
 /// 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++;
  writes = 0;
 }
 /// TranspositionTable::insert_pv() is called at the end of a search
 /// iteration, and inserts the PV back into the PV. This makes sure
 /// the old PV moves are searched first, even if the old TT entries
 /// have been overwritten.
 void TranspositionTable::insert_pv(const Position& pos, Move pv[]) {
  StateInfo st;
  Position p(pos);
  for (int i = 0; pv[i] != MOVE_NONE; i++)
  {
      TTEntry *tte = retrieve(p.get_key());
      if (!tte || tte->move() != pv[i])
          store(p.get_key(), VALUE_NONE, VALUE_TYPE_NONE, Depth(-127*OnePly), pv[i]);
      p.do_move(pv[i], st);
  }
 }
 /// TranspositionTable::extract_pv() extends a PV by adding moves from the
 /// transposition table at the end. This should ensure that the PV is almost
 /// always at least two plies long, which is important, because otherwise we
 /// will often get single-move PVs when the search stops while failing high,
 /// and a single-move PV means that we don't have a ponder move.
 void TranspositionTable::extract_pv(const Position& pos, Move pv[], const int PLY_MAX) {
  const TTEntry* tte;
  StateInfo st;
  Position p(pos);
  int ply = 0;
  // Update position to the end of current PV
  while (pv[ply] != MOVE_NONE)
      p.do_move(pv[ply++], st);
  // Try to add moves from TT while possible
  while (   (tte = retrieve(p.get_key())) != NULL
         && tte->move() != MOVE_NONE
         && move_is_legal(p, tte->move())
         && (!p.is_draw() || ply < 2)
         && ply < PLY_MAX)
  {
      pv[ply] = tte->move();
      p.do_move(pv[ply++], st);
  }
  pv[ply] = MOVE_NONE;
 }
 /// TranspositionTable::full() returns the permill of all transposition table
 /// entries which have received at least one write during the current search.
 /// It is used to display the "info hashfull ..." information in UCI.
 int TranspositionTable::full() const {
  double N = double(size) * ClusterSize;
  return int(1000 * (1 - exp(writes * log(1.0 - 1.0/N))));
 }
--- a/src/tt.h
+++ b/src/tt.h
@@ -26,7 +26,7 @@
 ////
 #include "depth.h"
-#include "position.h"
+#include "move.h"
 #include "value.h"
@@ -36,58 +36,68 @@
 /// The TTEntry class is the class of transposition table entries
 ///
-/// A TTEntry needs 96 bits to be stored
+/// A TTEntry needs 128 bits to be stored
 ///
 /// bit  0-31: key
 /// bit 32-63: data
 /// bit 64-79: value
 /// bit 80-95: depth
 /// bit 96-111: static value
 /// bit 112-127: margin of static value
 ///
 /// the 32 bits of the data field are so defined
 ///
 /// bit  0-16: move
-/// bit 17-19: not used
+/// bit 17-20: not used
-/// bit 20-22: value type
+/// bit 21-22: value type
 /// bit 23-31: generation
 class TTEntry {
 public:
-  TTEntry() {}
+  void save(uint32_t k, Value v, ValueType t, Depth d, Move m, int g, Value statV, Value kd) {
  TTEntry(uint32_t k, Value v, ValueType t, Depth d, Move m, int generation)
        : key_ (k), data((m & 0x1FFFF) | (t << 20) | (generation << 23)),
          value_(int16_t(v)), depth_(int16_t(d)) {}
-  uint32_t key() const { return key_; }
+      key32 = k;
-  Depth depth() const { return Depth(depth_); }
+      data = (m & 0x1FFFF) | (t << 21) | (g << 23);
      value16     = int16_t(v);
      depth16     = int16_t(d);
      staticValue = int16_t(statV);
      staticValueMargin  = int16_t(kd);
  }
  uint32_t key() const { return key32; }
  Depth depth() const { return Depth(depth16); }
  Move move() const { return Move(data & 0x1FFFF); }
-  Value value() const { return Value(value_); }
+  Value value() const { return Value(value16); }
-  ValueType type() const { return ValueType((data >> 20) & 7); }
+  ValueType type() const { return ValueType((data >> 21) & 3); }
-  int generation() const { return (data >> 23); }
+  int generation() const { return data >> 23; }
  Value static_value() const { return Value(staticValue); }
  Value static_value_margin() const { return Value(staticValueMargin); }
 private:
-  uint32_t key_;
+  uint32_t key32;
  uint32_t data;
-  int16_t value_;
+  int16_t value16;
-  int16_t depth_;
+  int16_t depth16;
  int16_t staticValue;
  int16_t staticValueMargin;
 };
-/// This is the number of TTEntry slots for each position
+/// This is the number of TTEntry slots for each cluster
-const int ClusterSize = 5;
+const int ClusterSize = 4;
-/// Each group of ClusterSize number of TTEntry form a TTCluster
+/// TTCluster consists of ClusterSize number of TTEntries.
-/// that is indexed by a single position key. Cluster is padded
+/// Size of TTCluster must not be bigger than a cache line size.
-/// to a cache line size so to guarantee always aligned accesses.
+/// In case it is less, it should be padded to guarantee always aligned accesses.
 struct TTCluster {
  TTEntry data[ClusterSize];
  char cache_line_padding[64 - sizeof(TTEntry[ClusterSize])];
 };
 /// The transposition table class. This is basically just a huge array
-/// containing TTEntry objects, and a few methods for writing new entries
+/// containing TTCluster objects, and a few methods for writing new entries
 /// and reading new ones.
 class TranspositionTable {
@@ -97,23 +107,12 @@ public:
  ~TranspositionTable();
  void set_size(size_t mbSize);
  void clear();
-  void store(const Key posKey, Value v, ValueType type, Depth d, Move m);
+  void store(const Key posKey, Value v, ValueType type, Depth d, Move m, Value statV, Value kingD);
  TTEntry* retrieve(const Key posKey) const;
  void prefetch(const Key posKey) const;
  void new_search();
-  void insert_pv(const Position& pos, Move pv[]);
+  TTEntry* first_entry(const Key posKey) const;
  void extract_pv(const Position& pos, Move pv[], const int PLY_MAX);
  int full() const;
 private:
  inline TTEntry* first_entry(const Key posKey) const;
  // Be sure 'writes' is at least one cache line away
  // from read only variables.
  unsigned char pad_before[64 - sizeof(unsigned)];
  unsigned writes; // heavy SMP read/write access here
  unsigned char pad_after[64];
  size_t size;
  TTCluster* entries;
  uint8_t generation;
@@ -121,4 +120,14 @@ private:
 extern TranspositionTable TT;
 /// 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;
 }
 #endif // !defined(TT_H_INCLUDED)
--- a/src/types.h
+++ b/src/types.h
@@ -49,20 +49,32 @@ typedef uint64_t Bitboard;
 ////
-//// Compiler specific defines
+//// Configuration
 ////
-// Quiet a warning on Intel compiler
+//// For Linux and OSX configuration is done automatically using Makefile.
-#if !defined(__SIZEOF_INT__ )
+//// To get started type "make help".
-#define __SIZEOF_INT__ 0
+////
-#endif
+//// 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.
-// Check for 64 bits for different compilers: Intel, MSVC and gcc
+// Automatic detection for 64-bit under Windows
-#if defined(__x86_64) || defined(_M_X64) || defined(_WIN64) || (__SIZEOF_INT__ > 4)
+#if defined(_WIN64)
 #define IS_64BIT
 #endif
-#if defined(IS_64BIT) && (defined(__GNUC__) || defined(__INTEL_COMPILER))
+// Automatic detection for use of bsfq asm-instruction under Windows.
 // Works only in 64-bit mode. Does not work with MSVC.
 #if defined(_WIN64) && defined(__INTEL_COMPILER)
 #define USE_BSFQ
 #endif
@@ -97,4 +109,64 @@ inline void __cpuid(int CPUInfo[4], int)
 }
 #endif
 // Templetized operators used by enum types like Depth, Piece, Square and so on.
 // We don't want to write the same inline for each different enum. Note that we
 // pass by value to silence scaring warnings when using volatiles.
 // Because these templates override common operators and are included in all the
 // files, there is a possibility that the compiler silently performs some unwanted
 // overrides. To avoid possible very nasty bugs the templates are disabled by default
 // and must be enabled for each type on a case by case base. The enabling trick
 // uses template specialization, namely we just declare following struct.
 template<typename T> struct TempletizedOperator;
 // Then to enable the enum type we use following macro that defines a specialization
 // of TempletizedOperator for the given enum T. Here is defined typedef Not_Enabled.
 // Name of typedef is chosen to produce somewhat informative compile error messages.
 #define ENABLE_OPERATORS_ON(T)  \
        template<> struct TempletizedOperator<T> { typedef T Not_Enabled; }
 // Finally we use macro OK(T) to check if type T is enabled. The macro simply
 // tries to use Not_Enabled, if was not previously defined a compile error occurs.
 // The check is done fully at compile time and there is zero overhead at runtime.
 #define OK(T) typedef typename TempletizedOperator<T>::Not_Enabled Type
 template<typename T>
 inline T operator+ (const T d1, const T d2) { OK(T); return T(int(d1) + int(d2)); }
 template<typename T>
 inline T operator- (const T d1, const T d2) { OK(T); return T(int(d1) - int(d2)); }
 template<typename T>
 inline T operator* (int i, const T d) { OK(T); return T(i * int(d)); }
 template<typename T>
 inline T operator* (const T d, int i) { OK(T); return T(int(d) * i); }
 template<typename T>
 inline T operator/ (const T d, int i) { OK(T); return T(int(d) / i); }
 template<typename T>
 inline T operator- (const T d) { OK(T); return T(-int(d)); }
 template<typename T>
 inline void operator++ (T& d, int) { OK(T); d = T(int(d) + 1); }
 template<typename T>
 inline void operator-- (T& d, int) { OK(T); d = T(int(d) - 1); }
 template<typename T>
 inline void operator+= (T& d1, const T d2) { OK(T); d1 = d1 + d2; }
 template<typename T>
 inline void operator-= (T& d1, const T d2) { OK(T); d1 = d1 - d2; }
 template<typename T>
 inline void operator*= (T& d, int i) { OK(T); d = T(int(d) * i); }
 template<typename T>
 inline void operator/= (T& d, int i) { OK(T); d = T(int(d) / i); }
 #undef OK
 #endif // !defined(TYPES_H_INCLUDED)
--- a/src/uci.cpp
+++ b/src/uci.cpp
@@ -46,6 +46,9 @@ using namespace std;
 namespace {
  // FEN string for the initial position
  const string StartPositionFEN = "rnbqkbnr/pppppppp/8/8/8/8/PPPPPPPP/RNBQKBNR w KQkq - 0 1";
  // UCIInputParser is a class for parsing UCI input. The class
  // is actually a string stream built on a given input string.
@@ -54,7 +57,7 @@ namespace {
  // The root position. This is set up when the user (or in practice, the GUI)
  // sends the "position" UCI command. The root position is sent to the think()
  // function when the program receives the "go" command.
-  Position RootPosition;
+  Position RootPosition(0);
  // Local functions
  bool handle_command(const string& command);
@@ -79,7 +82,7 @@ namespace {
 void uci_main_loop() {
-  RootPosition.from_fen(StartPosition);
+  RootPosition.from_fen(StartPositionFEN);
  string command;
  do {
@@ -126,8 +129,7 @@ namespace {
    else if (token == "ucinewgame")
    {
        push_button("New Game");
-        Position::init_piece_square_tables();
+        RootPosition.from_fen(StartPositionFEN);
        RootPosition.from_fen(StartPosition);
    }
    else if (token == "isready")
        cout << "readyok" << endl;
@@ -143,15 +145,15 @@ namespace {
        RootPosition.print();
    else if (token == "flip")
    {
-        Position p(RootPosition);
+        Position p(RootPosition, RootPosition.thread());
        RootPosition.flipped_copy(p);
    }
    else if (token == "eval")
    {
-        EvalInfo ei;
+        Value evalMargin;
-        cout << "Incremental mg: " << mg_value(RootPosition.value())
+        cout << "Incremental mg: "   << mg_value(RootPosition.value())
             << "\nIncremental eg: " << eg_value(RootPosition.value())
-             << "\nFull eval: " << evaluate(RootPosition, ei, 0) << endl;
+             << "\nFull eval: "      << evaluate(RootPosition, evalMargin) << endl;
    }
    else if (token == "key")
        cout << "key: " << hex << RootPosition.get_key()
@@ -180,7 +182,7 @@ namespace {
        return;
    if (token == "startpos")
-        RootPosition.from_fen(StartPosition);
+        RootPosition.from_fen(StartPositionFEN);
    else if (token == "fen")
    {
        string fen;
@@ -207,9 +209,11 @@ namespace {
                RootPosition.do_move(move, st);
                if (RootPosition.rule_50_counter() == 0)
                    RootPosition.reset_game_ply();
                RootPosition.inc_startpos_ply_counter(); //FIXME: make from_fen to support this and rule50
            }
            // Our StateInfo st is about going out of scope so copy
-            // its content inside RootPosition before they disappear.
+            // its content inside RootPosition before it disappears.
            RootPosition.detach();
        }
    }
@@ -300,22 +304,22 @@ namespace {
    assert(RootPosition.is_ok());
-    return think(RootPosition, infinite, ponder, RootPosition.side_to_move(),
+    return think(RootPosition, infinite, ponder, time, inc, movesToGo,
-                 time, inc, movesToGo, depth, nodes, moveTime, searchMoves);
+                 depth, nodes, moveTime, searchMoves);
  }
  void perft(UCIInputParser& uip) {
    string token;
    int depth, tm, n;
-    Position pos(RootPosition);
+    Position pos(RootPosition, RootPosition.thread());
    if (!(uip >> depth))
        return;
    tm = get_system_time();
-    n = perft(pos, depth * OnePly);
+    n = perft(pos, depth * ONE_PLY);
    tm = get_system_time() - tm;
    std::cout << "\nNodes " << n
--- a/src/ucioption.cpp
+++ b/src/ucioption.cpp
@@ -34,6 +34,8 @@
 #include "ucioption.h"
 using std::string;
 using std::cout;
 using std::endl;
 ////
 //// Local definitions
@@ -41,13 +43,9 @@ using std::string;
 namespace {
  ///
  /// Types
  ///
  enum OptionType { SPIN, COMBO, CHECK, STRING, BUTTON };
-  typedef std::vector<string> ComboValues;
+  typedef std::vector<string> StrVector;
  struct Option {
@@ -55,23 +53,42 @@ namespace {
    OptionType type;
    size_t idx;
    int minValue, maxValue;
-    ComboValues comboValues;
+    StrVector comboValues;
    Option();
    Option(const char* defaultValue, OptionType = STRING);
    Option(bool defaultValue, OptionType = CHECK);
    Option(int defaultValue, int minValue, int maxValue);
-    bool operator<(const Option& o) const { return this->idx < o.idx; }
+    bool operator<(const Option& o) const { return idx < o.idx; }
  };
  typedef std::vector<Option> OptionsVector;
  typedef std::map<string, Option> Options;
-  ///
+  Options options;
  /// Constants
  ///
-  // load_defaults populates the options map with the hard
+  // stringify() converts a value of type T to a std::string
  template<typename T>
  string stringify(const T& v) {
     std::ostringstream ss;
     ss << v;
     return ss.str();
  }
  Option::Option() {} // To allow insertion in a std::map
  Option::Option(const char* def, OptionType t)
  : defaultValue(def), currentValue(def), type(t), idx(options.size()), minValue(0), maxValue(0) {}
  Option::Option(bool def, OptionType t)
  : defaultValue(stringify(def)), currentValue(stringify(def)), type(t), idx(options.size()), minValue(0), maxValue(0) {}
  Option::Option(int def, int minv, int maxv)
  : defaultValue(stringify(def)), currentValue(stringify(def)), type(SPIN), idx(options.size()), minValue(minv), maxValue(maxv) {}
  // load_defaults() populates the options map with the hard
  // coded names and default values.
  void load_defaults(Options& o) {
@@ -79,6 +96,7 @@ namespace {
    o["Use Search Log"] = Option(false);
    o["Search Log Filename"] = Option("SearchLog.txt");
    o["Book File"] = Option("book.bin");
    o["Best Book Move"] = Option(false);
    o["Mobility (Middle Game)"] = Option(100, 0, 200);
    o["Mobility (Endgame)"] = Option(100, 0, 200);
    o["Pawn Structure (Middle Game)"] = Option(100, 0, 200);
@@ -92,15 +110,14 @@ namespace {
    o["Check Extension (non-PV nodes)"] = Option(1, 0, 2);
    o["Single Evasion Extension (PV nodes)"] = Option(2, 0, 2);
    o["Single Evasion Extension (non-PV nodes)"] = Option(2, 0, 2);
-    o["Mate Threat Extension (PV nodes)"] = Option(0, 0, 2);
+    o["Mate Threat Extension (PV nodes)"] = Option(2, 0, 2);
-    o["Mate Threat Extension (non-PV nodes)"] = Option(0, 0, 2);
+    o["Mate Threat Extension (non-PV nodes)"] = Option(2, 0, 2);
    o["Pawn Push to 7th Extension (PV nodes)"] = Option(1, 0, 2);
    o["Pawn Push to 7th Extension (non-PV nodes)"] = Option(1, 0, 2);
    o["Passed Pawn Extension (PV nodes)"] = Option(1, 0, 2);
    o["Passed Pawn Extension (non-PV nodes)"] = Option(0, 0, 2);
    o["Pawn Endgame Extension (PV nodes)"] = Option(2, 0, 2);
    o["Pawn Endgame Extension (non-PV nodes)"] = Option(2, 0, 2);
    o["Randomness"] = Option(0, 0, 10);
    o["Minimum Split Depth"] = Option(4, 4, 7);
    o["Maximum Number of Threads per Split Point"] = Option(5, 4, 8);
    o["Threads"] = Option(1, 1, MAX_THREADS);
@@ -110,7 +127,10 @@ namespace {
    o["Ponder"] = Option(true);
    o["OwnBook"] = Option(true);
    o["MultiPV"] = Option(1, 1, 500);
-    o["UCI_Chess960"] = Option(false);
+    o["Emergency Move Horizon"] = Option(40, 0, 50);
    o["Emergency Base Time"] = Option(200, 0, 60000);
    o["Emergency Move Time"] = Option(70, 0, 5000);
    o["Minimum Thinking Time"] = Option(20, 0, 5000);
    o["UCI_AnalyseMode"] = Option(false);
    // Any option should know its name so to be easily printed
@@ -118,25 +138,8 @@ namespace {
        it->second.name = it->first;
  }
-  ///
+  // get_option_value() implements the various get_option_value_<type>
-  /// Variables
+  // functions defined later.
  ///
  Options options;
  // stringify converts a value of type T to a std::string
  template<typename T>
  string stringify(const T& v) {
     std::ostringstream ss;
     ss << v;
     return ss.str();
  }
  // get_option_value implements the various get_option_value_<type>
  // functions defined later, because only the option value
  // type changes a template seems a proper solution.
  template<typename T>
  T get_option_value(const string& optionName) {
@@ -150,9 +153,8 @@ namespace {
      return ret;
  }
-  // Specialization for std::string where instruction 'ss >> ret;'
+  // Specialization for std::string where instruction 'ss >> ret'
  // would erroneusly tokenize a string with spaces.
  template<>
  string get_option_value<string>(const string& optionName) {
@@ -164,20 +166,15 @@ namespace {
 }
 ////
 //// Functions
 ////
-/// init_uci_options() initializes the UCI options.  Currently, the only
+/// init_uci_options() initializes the UCI options. Currently, the only thing
-/// thing this function does is to initialize the default value of the
+/// this function does is to initialize the default value of "Threads" and
-/// "Threads" parameter to the number of available CPU cores.
+/// "Minimum Split Depth" parameters according to the number of CPU cores.
 void init_uci_options() {
  load_defaults(options);
  // Set optimal value for parameter "Minimum Split Depth"
  // according to number of available cores.
  assert(options.find("Threads") != options.end());
  assert(options.find("Minimum Split Depth") != options.end());
@@ -196,39 +193,40 @@ void init_uci_options() {
 void print_uci_options() {
-  static const char optionTypeName[][16] = {
+  const char OptTypeName[][16] = {
    "spin", "combo", "check", "string", "button"
  };
  // Build up a vector out of the options map and sort it according to idx
  // field, that is the chronological insertion order in options map.
-  std::vector<Option> vec;
+  OptionsVector vec;
  for (Options::const_iterator it = options.begin(); it != options.end(); ++it)
      vec.push_back(it->second);
  std::sort(vec.begin(), vec.end());
-  for (std::vector<Option>::const_iterator it = vec.begin(); it != vec.end(); ++it)
+  for (OptionsVector::const_iterator it = vec.begin(); it != vec.end(); ++it)
  {
-      std::cout << "\noption name " << it->name
+      cout << "\noption name " << it->name << " type " << OptTypeName[it->type];
                << " type "         << optionTypeName[it->type];
      if (it->type == BUTTON)
          continue;
      if (it->type == CHECK)
-          std::cout << " default " << (it->defaultValue == "1" ? "true" : "false");
+          cout << " default " << (it->defaultValue == "1" ? "true" : "false");
      else
-          std::cout << " default " << it->defaultValue;
+          cout << " default " << it->defaultValue;
      if (it->type == SPIN)
-          std::cout << " min " << it->minValue << " max " << it->maxValue;
+          cout << " min " << it->minValue << " max " << it->maxValue;
      else if (it->type == COMBO)
-          for (ComboValues::const_iterator itc = it->comboValues.begin();
+      {
-              itc != it->comboValues.end(); ++itc)
+          StrVector::const_iterator itc;
-              std::cout << " var " << *itc;
+          for (itc = it->comboValues.begin(); itc != it->comboValues.end(); ++itc)
              cout << " var " << *itc;
      }
  }
-  std::cout << std::endl;
+  cout << endl;
 }
@@ -261,12 +259,16 @@ string get_option_value_string(const string& optionName) {
 }
-/// set_option_value() inserts a new value for a UCI parameter. Note that
+/// set_option_value() inserts a new value for a UCI parameter
 /// the function does not check that the new value is legal for the given
 /// parameter: This is assumed to be the responsibility of the GUI.
 void set_option_value(const string& name, const string& value) {
  if (options.find(name) == options.end())
  {
      cout << "No such option: " << name << endl;
      return;
  }
  // UCI protocol uses "true" and "false" instead of "1" and "0", so convert
  // value according to standard C++ convention before to store it.
  string v(value);
@@ -275,12 +277,6 @@ void set_option_value(const string& name, const string& value) {
  else if (v == "false")
      v = "0";
  if (options.find(name) == options.end())
  {
      std::cout << "No such option: " << name << std::endl;
      return;
  }
  // Normally it's up to the GUI to check for option's limits,
  // but we could receive the new value directly from the user
  // by teminal window. So let's check the bounds anyway.
@@ -295,7 +291,6 @@ void set_option_value(const string& name, const string& value) {
      if (val < opt.minValue || val > opt.maxValue)
          return;
  }
  opt.currentValue = v;
 }
@@ -321,21 +316,3 @@ bool button_was_pressed(const string& buttonName) {
  set_option_value(buttonName, "false");
  return true;
 }
 namespace {
  // Define constructors of Option class.
  Option::Option() {} // To allow insertion in a std::map
  Option::Option(const char* def, OptionType t)
  : defaultValue(def), currentValue(def), type(t), idx(options.size()), minValue(0), maxValue(0) {}
  Option::Option(bool def, OptionType t)
  : defaultValue(stringify(def)), currentValue(stringify(def)), type(t), idx(options.size()), minValue(0), maxValue(0) {}
  Option::Option(int def, int minv, int maxv)
  : defaultValue(stringify(def)), currentValue(stringify(def)), type(SPIN), idx(options.size()), minValue(minv), maxValue(maxv) {}
 }
--- a/src/value.cpp
+++ b/src/value.cpp
@@ -1,96 +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/>.
 */
 ////
 //// Includes
 ////
 #include <sstream>
 #include <string>
 #include "value.h"
 ////
 //// Functions
 ////
 /// value_to_tt() adjusts a mate score from "plies to mate from the root" to
 /// "plies to mate from the current ply".  Non-mate scores are unchanged.
 /// The function is called before storing a value to the transposition table.
 Value value_to_tt(Value v, int ply) {
  if(v >= value_mate_in(100))
    return v + ply;
  else if(v <= value_mated_in(100))
    return v - ply;
  else
    return v;
 }
 /// value_from_tt() is the inverse of value_to_tt():  It adjusts a mate score
 /// from the transposition table to a mate score corrected for the current
 /// ply depth.
 Value value_from_tt(Value v, int ply) {
  if(v >= value_mate_in(100))
    return v - ply;
  else if(v <= value_mated_in(100))
    return v + ply;
  else
    return v;
 }
 /// value_to_centipawns() converts a value from Stockfish's somewhat unusual
 /// scale of pawn = 256 to the more conventional pawn = 100.
 int value_to_centipawns(Value v) {
  return (int(v) * 100) / int(PawnValueMidgame);
 }
 /// value_from_centipawns() converts a centipawn value to Stockfish's internal
 /// evaluation scale.  It's used when reading the values of UCI options
 /// containing material values (e.g. futility pruning margins).
 Value value_from_centipawns(int cp) {
  return Value((cp * 256) / 100);
 }
 /// value_to_string() converts a value to a string suitable for use with the
 /// UCI protocol.
 const std::string value_to_string(Value v) {
  std::stringstream s;
  if(abs(v) < VALUE_MATE - 200)
    s << "cp " << value_to_centipawns(v);
  else {
    s << "mate ";
    if(v > 0)
      s << (VALUE_MATE - v + 1) / 2;
    else
      s << -(VALUE_MATE + v) / 2;
  }
  return s.str();
 }
--- a/src/value.h
+++ b/src/value.h
@@ -21,37 +21,38 @@
 #if !defined(VALUE_H_INCLUDED)
 #define VALUE_H_INCLUDED
 ////
 //// Includes
 ////
 #include "piece.h"
 ////
 //// Types
 ////
 enum ValueType {
-  VALUE_TYPE_NONE = 0,
+  VALUE_TYPE_NONE  = 0,
  VALUE_TYPE_UPPER = 1,  // Upper bound
  VALUE_TYPE_LOWER = 2,  // Lower bound
-  VALUE_TYPE_EXACT = 3,  // Exact score
+  VALUE_TYPE_EXACT = VALUE_TYPE_UPPER | VALUE_TYPE_LOWER
  VALUE_TYPE_EVAL  = 4,  // Evaluation cache
  VALUE_TYPE_EV_UP = 5,  // Evaluation cache for upper bound
  VALUE_TYPE_EV_LO = 6   // Evaluation cache for lower bound
 };
 enum Value {
-  VALUE_DRAW = 0,
+  VALUE_ZERO      = 0,
  VALUE_DRAW      = 0,
  VALUE_KNOWN_WIN = 15000,
-  VALUE_MATE = 30000,
+  VALUE_MATE      = 30000,
-  VALUE_INFINITE = 30001,
+  VALUE_INFINITE  = 30001,
-  VALUE_NONE = 30002,
+  VALUE_NONE      = 30002,
  VALUE_ENSURE_SIGNED = -1
 };
 ENABLE_OPERATORS_ON(Value);
 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
 /// integer (enum), first LSB 16 bits are used to store endgame
@@ -59,7 +60,14 @@ enum Value {
 // Compiler is free to choose the enum type as long as can keep
 // its data, so ensure Score to be an integer type.
-enum Score { ENSURE_32_BITS_SIZE_P = (1 << 16), ENSURE_32_BITS_SIZE_N = -(1 << 16)};
+enum Score {
    SCORE_ZERO = 0,
    SCORE_ENSURE_32_BITS_SIZE_P =  (1 << 16),
    SCORE_ENSURE_32_BITS_SIZE_N = -(1 << 16)
 };
 ENABLE_OPERATORS_ON(Score);
 // Extracting the _signed_ lower and upper 16 bits it not so trivial
 // because according to the standard a simple cast to short is
@@ -76,13 +84,6 @@ inline Value eg_value(Score s) { return Value((int)(unsigned(s) & 0x7fffu) - (in
 inline Score make_score(int mg, int eg) { return Score((mg << 16) + eg); }
 inline Score operator-(Score s) { return Score(-int(s)); }
 inline Score operator+(Score s1, Score s2) { return Score(int(s1) + int(s2)); }
 inline Score operator-(Score s1, Score s2) { return Score(int(s1) - int(s2)); }
 inline void operator+=(Score& s1, Score s2) { s1 = Score(int(s1) + int(s2)); }
 inline void operator-=(Score& s1, Score s2) { s1 = Score(int(s1) - int(s2)); }
 inline Score operator*(int i, Score s) { return Score(i * int(s)); }
 // Division must be handled separately for each term
 inline Score operator/(Score s, int i) { return make_score(mg_value(s) / i, eg_value(s) / i); }
@@ -91,118 +92,20 @@ inline Score operator/(Score s, int i) { return make_score(mg_value(s) / i, eg_v
 inline Score operator*(Score s1, Score s2);
 ////
 //// Constants and variables
 ////
 /// Piece values, middle game and endgame
 /// Important: If the material values are changed, one must also
 /// adjust the piece square tables, and the method game_phase() in the
 /// Position class!
 ///
 /// Values modified by Joona Kiiski
 const Value PawnValueMidgame   = Value(0x0C6);
 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);
 const Value PieceValueMidgame[17] = {
  Value(0),
  PawnValueMidgame, KnightValueMidgame, BishopValueMidgame,
  RookValueMidgame, QueenValueMidgame,
  Value(0), Value(0), Value(0),
  PawnValueMidgame, KnightValueMidgame, BishopValueMidgame,
  RookValueMidgame, QueenValueMidgame,
  Value(0), Value(0), Value(0)
 };
 const Value PieceValueEndgame[17] = {
  Value(0),
  PawnValueEndgame, KnightValueEndgame, BishopValueEndgame,
  RookValueEndgame, QueenValueEndgame,
  Value(0), Value(0), Value(0),
  PawnValueEndgame, KnightValueEndgame, BishopValueEndgame,
  RookValueEndgame, QueenValueEndgame,
  Value(0), Value(0), Value(0)
 };
 /// Bonus for having the side to move (modified by Joona Kiiski)
 const Score TempoValue = make_score(48, 22);
 ////
 //// Inline functions
 ////
 inline Value operator+ (Value v, int i) { return Value(int(v) + i); }
 inline Value operator+ (Value v1, Value v2) { return Value(int(v1) + int(v2)); }
 inline void operator+= (Value &v1, Value v2) {
  v1 = Value(int(v1) + int(v2));
 }
 inline Value operator- (Value v, int i) { return Value(int(v) - i); }
 inline Value operator- (Value v) { return Value(-int(v)); }
 inline Value operator- (Value v1, Value v2) { return Value(int(v1) - int(v2)); }
 inline void operator-= (Value &v1, Value v2) {
  v1 = Value(int(v1) - int(v2));
 }
 inline Value operator* (Value v, int i) { return Value(int(v) * i); }
 inline void operator*= (Value &v, int i) { v = Value(int(v) * i); }
 inline Value operator* (int i, Value v) { return Value(int(v) * i); }
 inline Value operator/ (Value v, int i) { return Value(int(v) / i); }
 inline void operator/= (Value &v, int i) { v = Value(int(v) / i); }
 inline Value value_mate_in(int ply) {
-  return Value(VALUE_MATE - Value(ply));
+  return VALUE_MATE - ply;
 }
 inline Value value_mated_in(int ply) {
-  return Value(-VALUE_MATE + Value(ply));
+  return -VALUE_MATE + ply;
 }
 inline bool is_upper_bound(ValueType vt) {
  return (int(vt) & int(VALUE_TYPE_UPPER)) != 0;
 }
 inline bool is_lower_bound(ValueType vt) {
  return (int(vt) & int(VALUE_TYPE_LOWER)) != 0;
 }
 inline Value piece_value_midgame(PieceType pt) {
  return PieceValueMidgame[pt];
 }
 inline Value piece_value_endgame(PieceType pt) {
  return PieceValueEndgame[pt];
 }
 inline Value piece_value_midgame(Piece p) {
  return PieceValueMidgame[p];
 }
 inline Value piece_value_endgame(Piece p) {
  return PieceValueEndgame[p];
 }
 ////
 //// Prototypes
 ////
 extern Value value_to_tt(Value v, int ply);
 extern Value value_from_tt(Value v, int ply);
 extern int value_to_centipawns(Value v);
 extern Value value_from_centipawns(int cp);
 extern const std::string value_to_string(Value v);
 #endif // !defined(VALUE_H_INCLUDED)