X-Git-Url: https://git.sesse.net/?p=stockfish;a=blobdiff_plain;f=src%2Fbitboard.h;h=b29f3e24fa1d5d29e230cde88c0105b0d8e6365f;hp=0f55810cece9864471329997ae359d56877cc8d6;hb=0e89d6e7546d26a19a108d047b489d9ba6f7970c;hpb=6f15e7fab277c2595633ad08fdc25bdd7e0ab166 diff --git a/src/bitboard.h b/src/bitboard.h index 0f55810c..b29f3e24 100644 --- a/src/bitboard.h +++ b/src/bitboard.h @@ -1,8 +1,6 @@ /* Stockfish, a UCI chess playing engine derived from Glaurung 2.1 - Copyright (C) 2004-2008 Tord Romstad (Glaurung author) - Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad - Copyright (C) 2015-2020 Marco Costalba, Joona Kiiski, Gary Linscott, Tord Romstad + Copyright (C) 2004-2021 The Stockfish developers (see AUTHORS file) Stockfish is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by @@ -25,19 +23,21 @@ #include "types.h" +namespace Stockfish { + namespace Bitbases { void init(); bool probe(Square wksq, Square wpsq, Square bksq, Color us); -} +} // namespace Stockfish::Bitbases namespace Bitboards { void init(); -const std::string pretty(Bitboard b); +std::string pretty(Bitboard b); -} +} // namespace Stockfish::Bitboards constexpr Bitboard AllSquares = ~Bitboard(0); constexpr Bitboard DarkSquares = 0xAA55AA55AA55AA55ULL; @@ -75,6 +75,7 @@ extern uint8_t PopCnt16[1 << 16]; extern uint8_t SquareDistance[SQUARE_NB][SQUARE_NB]; extern Bitboard SquareBB[SQUARE_NB]; +extern Bitboard BetweenBB[SQUARE_NB][SQUARE_NB]; extern Bitboard LineBB[SQUARE_NB][SQUARE_NB]; extern Bitboard PseudoAttacks[PIECE_TYPE_NB][SQUARE_NB]; extern Bitboard PawnAttacks[COLOR_NB][SQUARE_NB]; @@ -110,6 +111,7 @@ inline Bitboard square_bb(Square s) { return SquareBB[s]; } + /// Overloads of bitwise operators between a Bitboard and a Square for testing /// whether a given bit is set in a bitboard, and for setting and clearing bits. @@ -123,12 +125,13 @@ inline Bitboard operator&(Square s, Bitboard b) { return b & s; } inline Bitboard operator|(Square s, Bitboard b) { return b | s; } inline Bitboard operator^(Square s, Bitboard b) { return b ^ s; } -inline Bitboard operator|(Square s, Square s2) { return square_bb(s) | s2; } +inline Bitboard operator|(Square s1, Square s2) { return square_bb(s1) | s2; } constexpr bool more_than_one(Bitboard b) { return b & (b - 1); } + constexpr bool opposite_colors(Square s1, Square s2) { return (s1 + rank_of(s1) + s2 + rank_of(s2)) & 1; } @@ -137,19 +140,19 @@ constexpr bool opposite_colors(Square s1, Square s2) { /// rank_bb() and file_bb() return a bitboard representing all the squares on /// the given file or rank. -inline Bitboard rank_bb(Rank r) { +constexpr Bitboard rank_bb(Rank r) { return Rank1BB << (8 * r); } -inline Bitboard rank_bb(Square s) { +constexpr Bitboard rank_bb(Square s) { return rank_bb(rank_of(s)); } -inline Bitboard file_bb(File f) { +constexpr Bitboard file_bb(File f) { return FileABB << f; } -inline Bitboard file_bb(Square s) { +constexpr Bitboard file_bb(Square s) { return file_bb(file_of(s)); } @@ -194,39 +197,47 @@ constexpr Bitboard pawn_double_attacks_bb(Bitboard b) { /// adjacent_files_bb() returns a bitboard representing all the squares on the -/// adjacent files of the given one. +/// adjacent files of a given square. -inline Bitboard adjacent_files_bb(Square s) { +constexpr Bitboard adjacent_files_bb(Square s) { return shift(file_bb(s)) | shift(file_bb(s)); } -/// line_bb(Square, Square) returns a Bitboard representing an entire line -/// (from board edge to board edge) that intersects the given squares. -/// If the given squares are not on a same file/rank/diagonal, return 0. -/// Ex. line_bb(SQ_C4, SQ_F7) returns a bitboard with the A2-G8 diagonal. + +/// line_bb() returns a bitboard representing an entire line (from board edge +/// to board edge) that intersects the two given squares. If the given squares +/// are not on a same file/rank/diagonal, the function returns 0. For instance, +/// line_bb(SQ_C4, SQ_F7) will return a bitboard with the A2-G8 diagonal. inline Bitboard line_bb(Square s1, Square s2) { assert(is_ok(s1) && is_ok(s2)); + return LineBB[s1][s2]; } -/// between_bb() returns a Bitboard representing squares that are linearly -/// between the given squares (excluding the given squares). -/// If the given squares are not on a same file/rank/diagonal, return 0. -/// Ex. between_bb(SQ_C4, SQ_F7) returns a bitboard with squares D5 and E6. + +/// between_bb(s1, s2) returns a bitboard representing the squares in the semi-open +/// segment between the squares s1 and s2 (excluding s1 but including s2). If the +/// given squares are not on a same file/rank/diagonal, it returns s2. For instance, +/// between_bb(SQ_C4, SQ_F7) will return a bitboard with squares D5, E6 and F7, but +/// between_bb(SQ_E6, SQ_F8) will return a bitboard with the square F8. This trick +/// allows to generate non-king evasion moves faster: the defending piece must either +/// interpose itself to cover the check or capture the checking piece. inline Bitboard between_bb(Square s1, Square s2) { - Bitboard b = line_bb(s1, s2) & ((AllSquares << s1) ^ (AllSquares << s2)); - return b & (b - 1); //exclude lsb + + assert(is_ok(s1) && is_ok(s2)); + + return BetweenBB[s1][s2]; } -/// forward_ranks_bb() returns a bitboard representing the squares on the ranks -/// in front of the given one, from the point of view of the given color. For instance, +/// forward_ranks_bb() returns a bitboard representing the squares on the ranks in +/// front of the given one, from the point of view of the given color. For instance, /// forward_ranks_bb(BLACK, SQ_D3) will return the 16 squares on ranks 1 and 2. -inline Bitboard forward_ranks_bb(Color c, Square s) { +constexpr Bitboard forward_ranks_bb(Color c, Square s) { return c == WHITE ? ~Rank1BB << 8 * relative_rank(WHITE, s) : ~Rank8BB >> 8 * relative_rank(BLACK, s); } @@ -235,16 +246,16 @@ inline Bitboard forward_ranks_bb(Color c, Square s) { /// forward_file_bb() returns a bitboard representing all the squares along the /// line in front of the given one, from the point of view of the given color. -inline Bitboard forward_file_bb(Color c, Square s) { +constexpr Bitboard forward_file_bb(Color c, Square s) { return forward_ranks_bb(c, s) & file_bb(s); } /// pawn_attack_span() returns a bitboard representing all the squares that can -/// be attacked by a pawn of the given color when it moves along its file, -/// starting from the given square. +/// be attacked by a pawn of the given color when it moves along its file, starting +/// from the given square. -inline Bitboard pawn_attack_span(Color c, Square s) { +constexpr Bitboard pawn_attack_span(Color c, Square s) { return forward_ranks_bb(c, s) & adjacent_files_bb(s); } @@ -252,7 +263,7 @@ inline Bitboard pawn_attack_span(Color c, Square s) { /// passed_pawn_span() returns a bitboard which can be used to test if a pawn of /// the given color and on the given square is a passed pawn. -inline Bitboard passed_pawn_span(Color c, Square s) { +constexpr Bitboard passed_pawn_span(Color c, Square s) { return pawn_attack_span(c, s) | forward_file_bb(c, s); } @@ -276,13 +287,6 @@ template<> inline int distance(Square x, Square y) { return SquareDistan inline int edge_distance(File f) { return std::min(f, File(FILE_H - f)); } inline int edge_distance(Rank r) { return std::min(r, Rank(RANK_8 - r)); } -/// Return the target square bitboard if we do not step off the board, empty otherwise - -inline Bitboard safe_destination(Square s, int step) -{ - Square to = Square(s + step); - return is_ok(to) && distance(s, to) <= 2 ? square_bb(to) : Bitboard(0); -} /// attacks_bb(Square) returns the pseudo attacks of the give piece type /// assuming an empty board. @@ -295,6 +299,7 @@ inline Bitboard attacks_bb(Square s) { return PseudoAttacks[Pt][s]; } + /// attacks_bb(Square, Bitboard) returns the attacks by the given piece /// assuming the board is occupied according to the passed Bitboard. /// Sliding piece attacks do not continue passed an occupied square. @@ -416,13 +421,20 @@ inline Square msb(Bitboard b) { #endif +/// least_significant_square_bb() returns the bitboard of the least significant +/// square of a non-zero bitboard. It is equivalent to square_bb(lsb(bb)). + +inline Bitboard least_significant_square_bb(Bitboard b) { + assert(b); + return b & -b; +} /// pop_lsb() finds and clears the least significant bit in a non-zero bitboard -inline Square pop_lsb(Bitboard* b) { - assert(*b); - const Square s = lsb(*b); - *b &= *b - 1; +inline Square pop_lsb(Bitboard& b) { + assert(b); + const Square s = lsb(b); + b &= b - 1; return s; } @@ -434,4 +446,6 @@ inline Square frontmost_sq(Color c, Bitboard b) { return c == WHITE ? msb(b) : lsb(b); } +} // namespace Stockfish + #endif // #ifndef BITBOARD_H_INCLUDED