droidfish/DroidFish/jni/stockfish/position.cpp

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/*
Stockfish, a UCI chess playing engine derived from Glaurung 2.1
Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
Copyright (C) 2008-2014 Marco Costalba, Joona Kiiski, Tord Romstad
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Stockfish is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
Stockfish is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#include <algorithm>
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#include <cassert>
#include <cstring>
#include <iomanip>
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#include <sstream>
#include "bitcount.h"
#include "movegen.h"
#include "notation.h"
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#include "position.h"
#include "psqtab.h"
#include "rkiss.h"
#include "thread.h"
#include "tt.h"
using std::string;
static const string PieceToChar(" PNBRQK pnbrqk");
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CACHE_LINE_ALIGNMENT
Value PieceValue[PHASE_NB][PIECE_NB] = {
{ VALUE_ZERO, PawnValueMg, KnightValueMg, BishopValueMg, RookValueMg, QueenValueMg },
{ VALUE_ZERO, PawnValueEg, KnightValueEg, BishopValueEg, RookValueEg, QueenValueEg } };
static Score psq[COLOR_NB][PIECE_TYPE_NB][SQUARE_NB];
namespace Zobrist {
Key psq[COLOR_NB][PIECE_TYPE_NB][SQUARE_NB];
Key enpassant[FILE_NB];
Key castling[CASTLING_RIGHT_NB];
Key side;
Key exclusion;
}
Key Position::exclusion_key() const { return st->key ^ Zobrist::exclusion;}
namespace {
// min_attacker() is a helper function used by see() to locate the least
// valuable attacker for the side to move, remove the attacker we just found
// from the bitboards and scan for new X-ray attacks behind it.
template<int Pt> FORCE_INLINE
PieceType min_attacker(const Bitboard* bb, const Square& to, const Bitboard& stmAttackers,
Bitboard& occupied, Bitboard& attackers) {
Bitboard b = stmAttackers & bb[Pt];
if (!b)
return min_attacker<Pt+1>(bb, to, stmAttackers, occupied, attackers);
occupied ^= b & ~(b - 1);
if (Pt == PAWN || Pt == BISHOP || Pt == QUEEN)
attackers |= attacks_bb<BISHOP>(to, occupied) & (bb[BISHOP] | bb[QUEEN]);
if (Pt == ROOK || Pt == QUEEN)
attackers |= attacks_bb<ROOK>(to, occupied) & (bb[ROOK] | bb[QUEEN]);
attackers &= occupied; // After X-ray that may add already processed pieces
return (PieceType)Pt;
}
template<> FORCE_INLINE
PieceType min_attacker<KING>(const Bitboard*, const Square&, const Bitboard&, Bitboard&, Bitboard&) {
return KING; // No need to update bitboards: it is the last cycle
}
} // namespace
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/// CheckInfo c'tor
CheckInfo::CheckInfo(const Position& pos) {
Color them = ~pos.side_to_move();
ksq = pos.king_square(them);
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pinned = pos.pinned_pieces(pos.side_to_move());
dcCandidates = pos.discovered_check_candidates();
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checkSq[PAWN] = pos.attacks_from<PAWN>(ksq, them);
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checkSq[KNIGHT] = pos.attacks_from<KNIGHT>(ksq);
checkSq[BISHOP] = pos.attacks_from<BISHOP>(ksq);
checkSq[ROOK] = pos.attacks_from<ROOK>(ksq);
checkSq[QUEEN] = checkSq[BISHOP] | checkSq[ROOK];
checkSq[KING] = 0;
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}
/// Position::init() initializes at startup the various arrays used to compute
/// hash keys and the piece square tables. The latter is a two-step operation:
/// Firstly, the white halves of the tables are copied from PSQT[] tables.
/// Secondly, the black halves of the tables are initialized by flipping and
/// changing the sign of the white scores.
void Position::init() {
RKISS rk;
for (Color c = WHITE; c <= BLACK; ++c)
for (PieceType pt = PAWN; pt <= KING; ++pt)
for (Square s = SQ_A1; s <= SQ_H8; ++s)
Zobrist::psq[c][pt][s] = rk.rand<Key>();
for (File f = FILE_A; f <= FILE_H; ++f)
Zobrist::enpassant[f] = rk.rand<Key>();
for (int cf = NO_CASTLING; cf <= ANY_CASTLING; ++cf)
{
Bitboard b = cf;
while (b)
{
Key k = Zobrist::castling[1ULL << pop_lsb(&b)];
Zobrist::castling[cf] ^= k ? k : rk.rand<Key>();
}
}
Zobrist::side = rk.rand<Key>();
Zobrist::exclusion = rk.rand<Key>();
for (PieceType pt = PAWN; pt <= KING; ++pt)
{
PieceValue[MG][make_piece(BLACK, pt)] = PieceValue[MG][pt];
PieceValue[EG][make_piece(BLACK, pt)] = PieceValue[EG][pt];
Score v = make_score(PieceValue[MG][pt], PieceValue[EG][pt]);
for (Square s = SQ_A1; s <= SQ_H8; ++s)
{
psq[WHITE][pt][ s] = (v + PSQT[pt][s]);
psq[BLACK][pt][~s] = -(v + PSQT[pt][s]);
}
}
}
/// Position::operator=() creates a copy of 'pos'. We want the new born Position
/// object to not depend on any external data so we detach state pointer from
/// the source one.
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Position& Position::operator=(const Position& pos) {
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std::memcpy(this, &pos, sizeof(Position));
startState = *st;
st = &startState;
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nodes = 0;
assert(pos_is_ok());
return *this;
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}
/// Position::clear() erases the position object to a pristine state, with an
/// empty board, white to move, and no castling rights.
void Position::clear() {
std::memset(this, 0, sizeof(Position));
startState.epSquare = SQ_NONE;
st = &startState;
for (int i = 0; i < PIECE_TYPE_NB; ++i)
for (int j = 0; j < 16; ++j)
pieceList[WHITE][i][j] = pieceList[BLACK][i][j] = SQ_NONE;
}
/// Position::set() initializes the position object with the given FEN string.
/// This function is not very robust - make sure that input FENs are correct,
/// this is assumed to be the responsibility of the GUI.
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void Position::set(const string& fenStr, bool isChess960, Thread* th) {
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/*
A FEN string defines a particular position using only the ASCII character set.
A FEN string contains six fields separated by a space. The fields are:
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1) Piece placement (from white's perspective). Each rank is described, starting
with rank 8 and ending with rank 1. Within each rank, the contents of each
square are described from file A through file H. Following the Standard
Algebraic Notation (SAN), each piece is identified by a single letter taken
from the standard English names. White pieces are designated using upper-case
letters ("PNBRQK") whilst Black uses lowercase ("pnbrqk"). Blank squares are
noted using digits 1 through 8 (the number of blank squares), and "/"
separates ranks.
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2) Active color. "w" means white moves next, "b" means black.
3) Castling availability. If neither side can castle, this is "-". Otherwise,
this has one or more letters: "K" (White can castle kingside), "Q" (White
can castle queenside), "k" (Black can castle kingside), and/or "q" (Black
can castle queenside).
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4) En passant target square (in algebraic notation). If there's no en passant
target square, this is "-". If a pawn has just made a 2-square move, this
is the position "behind" the pawn. This is recorded regardless of whether
there is a pawn in position to make an en passant capture.
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5) Halfmove clock. This is the number of halfmoves since the last pawn advance
or capture. This is used to determine if a draw can be claimed under the
fifty-move rule.
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6) Fullmove number. The number of the full move. It starts at 1, and is
incremented after Black's move.
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*/
char col, row, token;
size_t idx;
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Square sq = SQ_A8;
std::istringstream ss(fenStr);
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clear();
ss >> std::noskipws;
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// 1. Piece placement
while ((ss >> token) && !isspace(token))
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{
if (isdigit(token))
sq += Square(token - '0'); // Advance the given number of files
else if (token == '/')
sq -= Square(16);
else if ((idx = PieceToChar.find(token)) != string::npos)
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{
put_piece(sq, color_of(Piece(idx)), type_of(Piece(idx)));
++sq;
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}
}
// 2. Active color
ss >> token;
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sideToMove = (token == 'w' ? WHITE : BLACK);
ss >> token;
// 3. Castling availability. Compatible with 3 standards: Normal FEN standard,
// Shredder-FEN that uses the letters of the columns on which the rooks began
// the game instead of KQkq and also X-FEN standard that, in case of Chess960,
// if an inner rook is associated with the castling right, the castling tag is
// replaced by the file letter of the involved rook, as for the Shredder-FEN.
while ((ss >> token) && !isspace(token))
{
Square rsq;
Color c = islower(token) ? BLACK : WHITE;
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token = char(toupper(token));
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if (token == 'K')
for (rsq = relative_square(c, SQ_H1); type_of(piece_on(rsq)) != ROOK; --rsq) {}
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else if (token == 'Q')
for (rsq = relative_square(c, SQ_A1); type_of(piece_on(rsq)) != ROOK; ++rsq) {}
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else if (token >= 'A' && token <= 'H')
rsq = make_square(File(token - 'A'), relative_rank(c, RANK_1));
else
continue;
set_castling_right(c, rsq);
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}
// 4. En passant square. Ignore if no pawn capture is possible
if ( ((ss >> col) && (col >= 'a' && col <= 'h'))
&& ((ss >> row) && (row == '3' || row == '6')))
{
st->epSquare = make_square(File(col - 'a'), Rank(row - '1'));
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if (!(attackers_to(st->epSquare) & pieces(sideToMove, PAWN)))
st->epSquare = SQ_NONE;
}
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// 5-6. Halfmove clock and fullmove number
ss >> std::skipws >> st->rule50 >> gamePly;
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// Convert from fullmove starting from 1 to ply starting from 0,
// handle also common incorrect FEN with fullmove = 0.
gamePly = std::max(2 * (gamePly - 1), 0) + (sideToMove == BLACK);
chess960 = isChess960;
thisThread = th;
set_state(st);
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assert(pos_is_ok());
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}
/// Position::set_castling_right() is a helper function used to set castling
/// rights given the corresponding color and the rook starting square.
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void Position::set_castling_right(Color c, Square rfrom) {
Square kfrom = king_square(c);
CastlingSide cs = kfrom < rfrom ? KING_SIDE : QUEEN_SIDE;
CastlingRight cr = (c | cs);
st->castlingRights |= cr;
castlingRightsMask[kfrom] |= cr;
castlingRightsMask[rfrom] |= cr;
castlingRookSquare[cr] = rfrom;
Square kto = relative_square(c, cs == KING_SIDE ? SQ_G1 : SQ_C1);
Square rto = relative_square(c, cs == KING_SIDE ? SQ_F1 : SQ_D1);
for (Square s = std::min(rfrom, rto); s <= std::max(rfrom, rto); ++s)
if (s != kfrom && s != rfrom)
castlingPath[cr] |= s;
for (Square s = std::min(kfrom, kto); s <= std::max(kfrom, kto); ++s)
if (s != kfrom && s != rfrom)
castlingPath[cr] |= s;
}
/// Position::set_state() computes the hash keys of the position, and other
/// data that once computed is updated incrementally as moves are made.
/// The function is only used when a new position is set up, and to verify
/// the correctness of the StateInfo data when running in debug mode.
void Position::set_state(StateInfo* si) const {
si->key = si->pawnKey = si->materialKey = 0;
si->npMaterial[WHITE] = si->npMaterial[BLACK] = VALUE_ZERO;
si->psq = SCORE_ZERO;
si->checkersBB = attackers_to(king_square(sideToMove)) & pieces(~sideToMove);
for (Bitboard b = pieces(); b; )
{
Square s = pop_lsb(&b);
Piece pc = piece_on(s);
si->key ^= Zobrist::psq[color_of(pc)][type_of(pc)][s];
si->psq += psq[color_of(pc)][type_of(pc)][s];
}
if (ep_square() != SQ_NONE)
si->key ^= Zobrist::enpassant[file_of(ep_square())];
if (sideToMove == BLACK)
si->key ^= Zobrist::side;
si->key ^= Zobrist::castling[st->castlingRights];
for (Bitboard b = pieces(PAWN); b; )
{
Square s = pop_lsb(&b);
si->pawnKey ^= Zobrist::psq[color_of(piece_on(s))][PAWN][s];
}
for (Color c = WHITE; c <= BLACK; ++c)
for (PieceType pt = PAWN; pt <= KING; ++pt)
for (int cnt = 0; cnt < pieceCount[c][pt]; ++cnt)
si->materialKey ^= Zobrist::psq[c][pt][cnt];
for (Color c = WHITE; c <= BLACK; ++c)
for (PieceType pt = KNIGHT; pt <= QUEEN; ++pt)
si->npMaterial[c] += pieceCount[c][pt] * PieceValue[MG][pt];
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}
/// Position::fen() returns a FEN representation of the position. In case of
/// Chess960 the Shredder-FEN notation is used. This is mainly a debugging function.
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const string Position::fen() const {
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int emptyCnt;
std::ostringstream ss;
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for (Rank r = RANK_8; r >= RANK_1; --r)
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{
for (File f = FILE_A; f <= FILE_H; ++f)
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{
for (emptyCnt = 0; f <= FILE_H && empty(make_square(f, r)); ++f)
++emptyCnt;
if (emptyCnt)
ss << emptyCnt;
if (f <= FILE_H)
ss << PieceToChar[piece_on(make_square(f, r))];
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}
if (r > RANK_1)
ss << '/';
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}
ss << (sideToMove == WHITE ? " w " : " b ");
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if (can_castle(WHITE_OO))
ss << (chess960 ? to_char(file_of(castling_rook_square(WHITE | KING_SIDE)), false) : 'K');
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if (can_castle(WHITE_OOO))
ss << (chess960 ? to_char(file_of(castling_rook_square(WHITE | QUEEN_SIDE)), false) : 'Q');
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if (can_castle(BLACK_OO))
ss << (chess960 ? to_char(file_of(castling_rook_square(BLACK | KING_SIDE)), true) : 'k');
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if (can_castle(BLACK_OOO))
ss << (chess960 ? to_char(file_of(castling_rook_square(BLACK | QUEEN_SIDE)), true) : 'q');
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if (!can_castle(WHITE) && !can_castle(BLACK))
ss << '-';
ss << (ep_square() == SQ_NONE ? " - " : " " + to_string(ep_square()) + " ")
<< st->rule50 << " " << 1 + (gamePly - (sideToMove == BLACK)) / 2;
return ss.str();
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}
/// Position::pretty() returns an ASCII representation of the position to be
/// printed to the standard output together with the move's san notation.
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const string Position::pretty(Move m) const {
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std::ostringstream ss;
if (m)
ss << "\nMove: " << (sideToMove == BLACK ? ".." : "")
<< move_to_san(*const_cast<Position*>(this), m);
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ss << "\n +---+---+---+---+---+---+---+---+\n";
for (Rank r = RANK_8; r >= RANK_1; --r)
{
for (File f = FILE_A; f <= FILE_H; ++f)
ss << " | " << PieceToChar[piece_on(make_square(f, r))];
ss << " |\n +---+---+---+---+---+---+---+---+\n";
}
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ss << "\nFen: " << fen() << "\nKey: " << std::hex << std::uppercase
<< std::setfill('0') << std::setw(16) << st->key << "\nCheckers: ";
for (Bitboard b = checkers(); b; )
ss << to_string(pop_lsb(&b)) << " ";
ss << "\nLegal moves: ";
for (MoveList<LEGAL> it(*this); *it; ++it)
ss << move_to_san(*const_cast<Position*>(this), *it) << " ";
return ss.str();
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}
/// Position::check_blockers() returns a bitboard of all the pieces with color
/// 'c' that are blocking check on the king with color 'kingColor'. A piece
/// blocks a check if removing that piece from the board would result in a
/// position where the king is in check. A check blocking piece can be either a
/// pinned or a discovered check piece, according if its color 'c' is the same
/// or the opposite of 'kingColor'.
Bitboard Position::check_blockers(Color c, Color kingColor) const {
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Bitboard b, pinners, result = 0;
Square ksq = king_square(kingColor);
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// Pinners are sliders that give check when a pinned piece is removed
pinners = ( (pieces( ROOK, QUEEN) & PseudoAttacks[ROOK ][ksq])
| (pieces(BISHOP, QUEEN) & PseudoAttacks[BISHOP][ksq])) & pieces(~kingColor);
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while (pinners)
{
b = between_bb(ksq, pop_lsb(&pinners)) & pieces();
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if (!more_than_one(b))
result |= b & pieces(c);
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}
return result;
}
/// Position::attackers_to() computes a bitboard of all pieces which attack a
/// given square. Slider attacks use the occ bitboard to indicate occupancy.
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Bitboard Position::attackers_to(Square s, Bitboard occ) const {
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return (attacks_from<PAWN>(s, BLACK) & pieces(WHITE, PAWN))
| (attacks_from<PAWN>(s, WHITE) & pieces(BLACK, PAWN))
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| (attacks_from<KNIGHT>(s) & pieces(KNIGHT))
| (attacks_bb<ROOK>(s, occ) & pieces(ROOK, QUEEN))
| (attacks_bb<BISHOP>(s, occ) & pieces(BISHOP, QUEEN))
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| (attacks_from<KING>(s) & pieces(KING));
}
/// Position::legal() tests whether a pseudo-legal move is legal
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bool Position::legal(Move m, Bitboard pinned) const {
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assert(is_ok(m));
assert(pinned == pinned_pieces(sideToMove));
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Color us = sideToMove;
Square from = from_sq(m);
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assert(color_of(moved_piece(m)) == us);
assert(piece_on(king_square(us)) == make_piece(us, KING));
// En passant captures are a tricky special case. Because they are rather
// uncommon, we do it simply by testing whether the king is attacked after
// the move is made.
if (type_of(m) == ENPASSANT)
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{
Square ksq = king_square(us);
Square to = to_sq(m);
Square capsq = to - pawn_push(us);
Bitboard occ = (pieces() ^ from ^ capsq) | to;
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assert(to == ep_square());
assert(moved_piece(m) == make_piece(us, PAWN));
assert(piece_on(capsq) == make_piece(~us, PAWN));
assert(piece_on(to) == NO_PIECE);
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return !(attacks_bb< ROOK>(ksq, occ) & pieces(~us, QUEEN, ROOK))
&& !(attacks_bb<BISHOP>(ksq, occ) & pieces(~us, QUEEN, BISHOP));
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}
// If the moving piece is a king, check whether the destination
// square is attacked by the opponent. Castling moves are checked
// for legality during move generation.
if (type_of(piece_on(from)) == KING)
return type_of(m) == CASTLING || !(attackers_to(to_sq(m)) & pieces(~us));
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// A non-king move is legal if and only if it is not pinned or it
// is moving along the ray towards or away from the king.
return !pinned
|| !(pinned & from)
|| aligned(from, to_sq(m), king_square(us));
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}
/// Position::pseudo_legal() takes a random move and tests whether the move is
/// pseudo legal. It is used to validate moves from TT that can be corrupted
/// due to SMP concurrent access or hash position key aliasing.
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bool Position::pseudo_legal(const Move m) const {
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Color us = sideToMove;
Square from = from_sq(m);
Square to = to_sq(m);
Piece pc = moved_piece(m);
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// Use a slower but simpler function for uncommon cases
if (type_of(m) != NORMAL)
return MoveList<LEGAL>(*this).contains(m);
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// Is not a promotion, so promotion piece must be empty
if (promotion_type(m) - 2 != NO_PIECE_TYPE)
return false;
// If the 'from' square is not occupied by a piece belonging to the side to
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// move, the move is obviously not legal.
if (pc == NO_PIECE || color_of(pc) != us)
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return false;
// The destination square cannot be occupied by a friendly piece
if (pieces(us) & to)
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return false;
// Handle the special case of a pawn move
if (type_of(pc) == PAWN)
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{
// We have already handled promotion moves, so destination
// cannot be on the 8th/1st rank.
if (rank_of(to) == relative_rank(us, RANK_8))
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return false;
if ( !(attacks_from<PAWN>(from, us) & pieces(~us) & to) // Not a capture
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&& !((from + pawn_push(us) == to) && empty(to)) // Not a single push
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&& !( (from + 2 * pawn_push(us) == to) // Not a double push
&& (rank_of(from) == relative_rank(us, RANK_2))
&& empty(to)
&& empty(to - pawn_push(us))))
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return false;
}
else if (!(attacks_from(pc, from) & to))
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return false;
// Evasions generator already takes care to avoid some kind of illegal moves
// and legal() relies on this. We therefore have to take care that the same
// kind of moves are filtered out here.
if (checkers())
{
if (type_of(pc) != KING)
{
// Double check? In this case a king move is required
if (more_than_one(checkers()))
return false;
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// Our move must be a blocking evasion or a capture of the checking piece
if (!((between_bb(lsb(checkers()), king_square(us)) | checkers()) & to))
return false;
}
// In case of king moves under check we have to remove king so as to catch
// invalid moves like b1a1 when opposite queen is on c1.
else if (attackers_to(to, pieces() ^ from) & pieces(~us))
return false;
}
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return true;
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}
/// Position::gives_check() tests whether a pseudo-legal move gives a check
bool Position::gives_check(Move m, const CheckInfo& ci) const {
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assert(is_ok(m));
assert(ci.dcCandidates == discovered_check_candidates());
assert(color_of(moved_piece(m)) == sideToMove);
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Square from = from_sq(m);
Square to = to_sq(m);
PieceType pt = type_of(piece_on(from));
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// Is there a direct check?
if (ci.checkSq[pt] & to)
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return true;
// Is there a discovered check?
if ( unlikely(ci.dcCandidates)
&& (ci.dcCandidates & from)
&& !aligned(from, to, ci.ksq))
return true;
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switch (type_of(m))
{
case NORMAL:
return false;
case PROMOTION:
return attacks_bb(Piece(promotion_type(m)), to, pieces() ^ from) & ci.ksq;
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// En passant capture with check? We have already handled the case
// of direct checks and ordinary discovered check, so the only case we
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// need to handle is the unusual case of a discovered check through
// the captured pawn.
case ENPASSANT:
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{
Square capsq = make_square(file_of(to), rank_of(from));
Bitboard b = (pieces() ^ from ^ capsq) | to;
return (attacks_bb< ROOK>(ci.ksq, b) & pieces(sideToMove, QUEEN, ROOK))
| (attacks_bb<BISHOP>(ci.ksq, b) & pieces(sideToMove, QUEEN, BISHOP));
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}
case CASTLING:
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{
Square kfrom = from;
Square rfrom = to; // Castling is encoded as 'King captures the rook'
Square kto = relative_square(sideToMove, rfrom > kfrom ? SQ_G1 : SQ_C1);
Square rto = relative_square(sideToMove, rfrom > kfrom ? SQ_F1 : SQ_D1);
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return (PseudoAttacks[ROOK][rto] & ci.ksq)
&& (attacks_bb<ROOK>(rto, (pieces() ^ kfrom ^ rfrom) | rto | kto) & ci.ksq);
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}
default:
assert(false);
return false;
}
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}
/// Position::do_move() makes a move, and saves all information necessary
/// to a StateInfo object. The move is assumed to be legal. Pseudo-legal
/// moves should be filtered out before this function is called.
void Position::do_move(Move m, StateInfo& newSt) {
CheckInfo ci(*this);
do_move(m, newSt, ci, gives_check(m, ci));
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}
void Position::do_move(Move m, StateInfo& newSt, const CheckInfo& ci, bool moveIsCheck) {
assert(is_ok(m));
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assert(&newSt != st);
++nodes;
Key k = st->key;
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// Copy some fields of the old state to our new StateInfo object except the
// ones which are going to be recalculated from scratch anyway and then switch
// our state pointer to point to the new (ready to be updated) state.
std::memcpy(&newSt, st, StateCopySize64 * sizeof(uint64_t));
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newSt.previous = st;
st = &newSt;
// Update side to move
k ^= Zobrist::side;
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// Increment ply counters. In particular, rule50 will be reset to zero later on
// in case of a capture or a pawn move.
++gamePly;
++st->rule50;
++st->pliesFromNull;
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Color us = sideToMove;
Color them = ~us;
Square from = from_sq(m);
Square to = to_sq(m);
Piece pc = piece_on(from);
PieceType pt = type_of(pc);
PieceType captured = type_of(m) == ENPASSANT ? PAWN : type_of(piece_on(to));
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assert(color_of(pc) == us);
assert(piece_on(to) == NO_PIECE || color_of(piece_on(to)) == them || type_of(m) == CASTLING);
assert(captured != KING);
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if (type_of(m) == CASTLING)
{
assert(pc == make_piece(us, KING));
Square rfrom, rto;
do_castling<true>(from, to, rfrom, rto);
captured = NO_PIECE_TYPE;
st->psq += psq[us][ROOK][rto] - psq[us][ROOK][rfrom];
k ^= Zobrist::psq[us][ROOK][rfrom] ^ Zobrist::psq[us][ROOK][rto];
}
if (captured)
{
Square capsq = to;
// If the captured piece is a pawn, update pawn hash key, otherwise
// update non-pawn material.
if (captured == PAWN)
{
if (type_of(m) == ENPASSANT)
{
capsq += pawn_push(them);
assert(pt == PAWN);
assert(to == st->epSquare);
assert(relative_rank(us, to) == RANK_6);
assert(piece_on(to) == NO_PIECE);
assert(piece_on(capsq) == make_piece(them, PAWN));
board[capsq] = NO_PIECE;
}
st->pawnKey ^= Zobrist::psq[them][PAWN][capsq];
}
else
st->npMaterial[them] -= PieceValue[MG][captured];
// Update board and piece lists
remove_piece(capsq, them, captured);
// Update material hash key and prefetch access to materialTable
k ^= Zobrist::psq[them][captured][capsq];
st->materialKey ^= Zobrist::psq[them][captured][pieceCount[them][captured]];
prefetch((char*)thisThread->materialTable[st->materialKey]);
// Update incremental scores
st->psq -= psq[them][captured][capsq];
// Reset rule 50 counter
st->rule50 = 0;
}
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// Update hash key
k ^= Zobrist::psq[us][pt][from] ^ Zobrist::psq[us][pt][to];
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// Reset en passant square
if (st->epSquare != SQ_NONE)
{
k ^= Zobrist::enpassant[file_of(st->epSquare)];
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st->epSquare = SQ_NONE;
}
// Update castling rights if needed
if (st->castlingRights && (castlingRightsMask[from] | castlingRightsMask[to]))
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{
int cr = castlingRightsMask[from] | castlingRightsMask[to];
k ^= Zobrist::castling[st->castlingRights & cr];
st->castlingRights &= ~cr;
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}
// Prefetch TT access as soon as we know the new hash key
prefetch((char*)TT.first_entry(k));
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// Move the piece. The tricky Chess960 castling is handled earlier
if (type_of(m) != CASTLING)
move_piece(from, to, us, pt);
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// If the moving piece is a pawn do some special extra work
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if (pt == PAWN)
{
// Set en-passant square if the moved pawn can be captured
if ( (int(to) ^ int(from)) == 16
&& (attacks_from<PAWN>(from + pawn_push(us), us) & pieces(them, PAWN)))
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{
st->epSquare = Square((from + to) / 2);
k ^= Zobrist::enpassant[file_of(st->epSquare)];
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}
else if (type_of(m) == PROMOTION)
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{
PieceType promotion = promotion_type(m);
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assert(relative_rank(us, to) == RANK_8);
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assert(promotion >= KNIGHT && promotion <= QUEEN);
remove_piece(to, us, PAWN);
put_piece(to, us, promotion);
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// Update hash keys
k ^= Zobrist::psq[us][PAWN][to] ^ Zobrist::psq[us][promotion][to];
st->pawnKey ^= Zobrist::psq[us][PAWN][to];
st->materialKey ^= Zobrist::psq[us][promotion][pieceCount[us][promotion]-1]
^ Zobrist::psq[us][PAWN][pieceCount[us][PAWN]];
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// Update incremental score
st->psq += psq[us][promotion][to] - psq[us][PAWN][to];
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// Update material
st->npMaterial[us] += PieceValue[MG][promotion];
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}
// Update pawn hash key and prefetch access to pawnsTable
st->pawnKey ^= Zobrist::psq[us][PAWN][from] ^ Zobrist::psq[us][PAWN][to];
prefetch((char*)thisThread->pawnsTable[st->pawnKey]);
// Reset rule 50 draw counter
st->rule50 = 0;
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}
// Update incremental scores
st->psq += psq[us][pt][to] - psq[us][pt][from];
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// Set capture piece
st->capturedType = captured;
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// Update the key with the final value
st->key = k;
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// Update checkers bitboard: piece must be already moved due to attacks_from()
st->checkersBB = 0;
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if (moveIsCheck)
{
if (type_of(m) != NORMAL)
st->checkersBB = attackers_to(king_square(them)) & pieces(us);
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else
{
// Direct checks
if (ci.checkSq[pt] & to)
st->checkersBB |= to;
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// Discovered checks
if (unlikely(ci.dcCandidates) && (ci.dcCandidates & from))
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{
if (pt != ROOK)
st->checkersBB |= attacks_from<ROOK>(king_square(them)) & pieces(us, QUEEN, ROOK);
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if (pt != BISHOP)
st->checkersBB |= attacks_from<BISHOP>(king_square(them)) & pieces(us, QUEEN, BISHOP);
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}
}
}
sideToMove = ~sideToMove;
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assert(pos_is_ok());
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}
/// Position::undo_move() unmakes a move. When it returns, the position should
/// be restored to exactly the same state as before the move was made.
void Position::undo_move(Move m) {
assert(is_ok(m));
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sideToMove = ~sideToMove;
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Color us = sideToMove;
Square from = from_sq(m);
Square to = to_sq(m);
PieceType pt = type_of(piece_on(to));
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assert(empty(from) || type_of(m) == CASTLING);
assert(st->capturedType != KING);
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if (type_of(m) == PROMOTION)
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{
assert(pt == promotion_type(m));
assert(relative_rank(us, to) == RANK_8);
assert(promotion_type(m) >= KNIGHT && promotion_type(m) <= QUEEN);
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remove_piece(to, us, promotion_type(m));
put_piece(to, us, PAWN);
pt = PAWN;
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}
if (type_of(m) == CASTLING)
{
Square rfrom, rto;
do_castling<false>(from, to, rfrom, rto);
}
else
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{
move_piece(to, from, us, pt); // Put the piece back at the source square
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if (st->capturedType)
{
Square capsq = to;
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if (type_of(m) == ENPASSANT)
{
capsq -= pawn_push(us);
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assert(pt == PAWN);
assert(to == st->previous->epSquare);
assert(relative_rank(us, to) == RANK_6);
assert(piece_on(capsq) == NO_PIECE);
}
put_piece(capsq, ~us, st->capturedType); // Restore the captured piece
}
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}
// Finally point our state pointer back to the previous state
st = st->previous;
--gamePly;
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assert(pos_is_ok());
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}
/// Position::do_castling() is a helper used to do/undo a castling move. This
/// is a bit tricky, especially in Chess960.
template<bool Do>
void Position::do_castling(Square from, Square& to, Square& rfrom, Square& rto) {
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bool kingSide = to > from;
rfrom = to; // Castling is encoded as "king captures friendly rook"
rto = relative_square(sideToMove, kingSide ? SQ_F1 : SQ_D1);
to = relative_square(sideToMove, kingSide ? SQ_G1 : SQ_C1);
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// Remove both pieces first since squares could overlap in Chess960
remove_piece(Do ? from : to, sideToMove, KING);
remove_piece(Do ? rfrom : rto, sideToMove, ROOK);
board[Do ? from : to] = board[Do ? rfrom : rto] = NO_PIECE; // Since remove_piece doesn't do it for us
put_piece(Do ? to : from, sideToMove, KING);
put_piece(Do ? rto : rfrom, sideToMove, ROOK);
}
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/// Position::do(undo)_null_move() is used to do(undo) a "null move": It flips
/// the side to move without executing any move on the board.
void Position::do_null_move(StateInfo& newSt) {
assert(!checkers());
std::memcpy(&newSt, st, sizeof(StateInfo)); // Fully copy here
newSt.previous = st;
st = &newSt;
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if (st->epSquare != SQ_NONE)
{
st->key ^= Zobrist::enpassant[file_of(st->epSquare)];
st->epSquare = SQ_NONE;
}
st->key ^= Zobrist::side;
prefetch((char*)TT.first_entry(st->key));
++st->rule50;
st->pliesFromNull = 0;
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sideToMove = ~sideToMove;
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assert(pos_is_ok());
}
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void Position::undo_null_move() {
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assert(!checkers());
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st = st->previous;
sideToMove = ~sideToMove;
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}
/// Position::see() is a static exchange evaluator: It tries to estimate the
/// material gain or loss resulting from a move.
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Value Position::see_sign(Move m) const {
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assert(is_ok(m));
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// Early return if SEE cannot be negative because captured piece value
// is not less then capturing one. Note that king moves always return
// here because king midgame value is set to 0.
if (PieceValue[MG][moved_piece(m)] <= PieceValue[MG][piece_on(to_sq(m))])
return VALUE_KNOWN_WIN;
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return see(m);
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}
Value Position::see(Move m) const {
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Square from, to;
Bitboard occupied, attackers, stmAttackers;
Value swapList[32];
int slIndex = 1;
PieceType captured;
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Color stm;
assert(is_ok(m));
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from = from_sq(m);
to = to_sq(m);
swapList[0] = PieceValue[MG][piece_on(to)];
stm = color_of(piece_on(from));
occupied = pieces() ^ from;
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// Castling moves are implemented as king capturing the rook so cannot be
// handled correctly. Simply return 0 that is always the correct value
// unless in the rare case the rook ends up under attack.
if (type_of(m) == CASTLING)
return VALUE_ZERO;
if (type_of(m) == ENPASSANT)
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{
occupied ^= to - pawn_push(stm); // Remove the captured pawn
swapList[0] = PieceValue[MG][PAWN];
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}
// Find all attackers to the destination square, with the moving piece
// removed, but possibly an X-ray attacker added behind it.
attackers = attackers_to(to, occupied) & occupied;
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// If the opponent has no attackers we are finished
stm = ~stm;
stmAttackers = attackers & pieces(stm);
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if (!stmAttackers)
return swapList[0];
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// The destination square is defended, which makes things rather more
// difficult to compute. We proceed by building up a "swap list" containing
// the material gain or loss at each stop in a sequence of captures to the
// destination square, where the sides alternately capture, and always
// capture with the least valuable piece. After each capture, we look for
// new X-ray attacks from behind the capturing piece.
captured = type_of(piece_on(from));
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do {
assert(slIndex < 32);
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// Add the new entry to the swap list
swapList[slIndex] = -swapList[slIndex - 1] + PieceValue[MG][captured];
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// Locate and remove the next least valuable attacker
captured = min_attacker<PAWN>(byTypeBB, to, stmAttackers, occupied, attackers);
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// Stop before processing a king capture
if (captured == KING)
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{
if (stmAttackers == attackers)
++slIndex;
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break;
}
stm = ~stm;
stmAttackers = attackers & pieces(stm);
++slIndex;
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} while (stmAttackers);
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// Having built the swap list, we negamax through it to find the best
// achievable score from the point of view of the side to move.
while (--slIndex)
swapList[slIndex - 1] = std::min(-swapList[slIndex], swapList[slIndex - 1]);
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return swapList[0];
}
/// Position::is_draw() tests whether the position is drawn by material, 50 moves
/// rule or repetition. It does not detect stalemates.
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bool Position::is_draw() const {
if ( !pieces(PAWN)
&& (non_pawn_material(WHITE) + non_pawn_material(BLACK) <= BishopValueMg))
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return true;
if (st->rule50 > 99 && (!checkers() || MoveList<LEGAL>(*this).size()))
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return true;
StateInfo* stp = st;
for (int i = 2, e = std::min(st->rule50, st->pliesFromNull); i <= e; i += 2)
{
stp = stp->previous->previous;
if (stp->key == st->key)
return true; // Draw at first repetition
}
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return false;
}
/// Position::flip() flips position with the white and black sides reversed. This
/// is only useful for debugging e.g. for finding evaluation symmetry bugs.
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static char toggle_case(char c) {
return char(islower(c) ? toupper(c) : tolower(c));
}
void Position::flip() {
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string f, token;
std::stringstream ss(fen());
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for (Rank r = RANK_8; r >= RANK_1; --r) // Piece placement
{
std::getline(ss, token, r > RANK_1 ? '/' : ' ');
f.insert(0, token + (f.empty() ? " " : "/"));
}
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ss >> token; // Active color
f += (token == "w" ? "B " : "W "); // Will be lowercased later
ss >> token; // Castling availability
f += token + " ";
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std::transform(f.begin(), f.end(), f.begin(), toggle_case);
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ss >> token; // En passant square
f += (token == "-" ? token : token.replace(1, 1, token[1] == '3' ? "6" : "3"));
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std::getline(ss, token); // Half and full moves
f += token;
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set(f, is_chess960(), this_thread());
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assert(pos_is_ok());
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}
/// Position::pos_is_ok() performs some consistency checks for the position object.
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/// This is meant to be helpful when debugging.
bool Position::pos_is_ok(int* step) const {
// Which parts of the position should be verified?
const bool all = false;
const bool testBitboards = all || false;
const bool testState = all || false;
const bool testKingCount = all || false;
const bool testKingCapture = all || false;
const bool testPieceCounts = all || false;
const bool testPieceList = all || false;
const bool testCastlingSquares = all || false;
if (step)
*step = 1;
if ( (sideToMove != WHITE && sideToMove != BLACK)
|| piece_on(king_square(WHITE)) != W_KING
|| piece_on(king_square(BLACK)) != B_KING
|| ( ep_square() != SQ_NONE
&& relative_rank(sideToMove, ep_square()) != RANK_6))
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return false;
if (step && ++*step, testBitboards)
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{
// The intersection of the white and black pieces must be empty
if (pieces(WHITE) & pieces(BLACK))
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return false;
// The union of the white and black pieces must be equal to all
// occupied squares
if ((pieces(WHITE) | pieces(BLACK)) != pieces())
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return false;
// Separate piece type bitboards must have empty intersections
for (PieceType p1 = PAWN; p1 <= KING; ++p1)
for (PieceType p2 = PAWN; p2 <= KING; ++p2)
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if (p1 != p2 && (pieces(p1) & pieces(p2)))
return false;
}
if (step && ++*step, testState)
{
StateInfo si;
set_state(&si);
if ( st->key != si.key
|| st->pawnKey != si.pawnKey
|| st->materialKey != si.materialKey
|| st->npMaterial[WHITE] != si.npMaterial[WHITE]
|| st->npMaterial[BLACK] != si.npMaterial[BLACK]
|| st->psq != si.psq
|| st->checkersBB != si.checkersBB)
return false;
}
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if (step && ++*step, testKingCount)
if ( std::count(board, board + SQUARE_NB, W_KING) != 1
|| std::count(board, board + SQUARE_NB, B_KING) != 1)
return false;
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if (step && ++*step, testKingCapture)
if (attackers_to(king_square(~sideToMove)) & pieces(sideToMove))
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return false;
if (step && ++*step, testPieceCounts)
for (Color c = WHITE; c <= BLACK; ++c)
for (PieceType pt = PAWN; pt <= KING; ++pt)
if (pieceCount[c][pt] != popcount<Full>(pieces(c, pt)))
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return false;
if (step && ++*step, testPieceList)
for (Color c = WHITE; c <= BLACK; ++c)
for (PieceType pt = PAWN; pt <= KING; ++pt)
for (int i = 0; i < pieceCount[c][pt]; ++i)
if ( board[pieceList[c][pt][i]] != make_piece(c, pt)
|| index[pieceList[c][pt][i]] != i)
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return false;
if (step && ++*step, testCastlingSquares)
for (Color c = WHITE; c <= BLACK; ++c)
for (CastlingSide s = KING_SIDE; s <= QUEEN_SIDE; s = CastlingSide(s + 1))
{
if (!can_castle(c | s))
continue;
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if ( (castlingRightsMask[king_square(c)] & (c | s)) != (c | s)
|| piece_on(castlingRookSquare[c | s]) != make_piece(c, ROOK)
|| castlingRightsMask[castlingRookSquare[c | s]] != (c | s))
return false;
}
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return true;
}