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https://github.com/sockspls/badfish
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759b3c79cf
To more clearly distinguish them from "const" local variables, this patch defines compile-time local constants as constexpr. This is consistent with the definition of PvNode as constexpr in search() and qsearch(). It also makes the code more robust, since the compiler will now check that those constants are indeed compile-time constants. We can go even one step further and define all the evaluation and search compile-time constants as constexpr. In generate_castling() I replaced "K" with "step", since K was incorrectly capitalised (in the Chess960 case). In timeman.cpp I had to make the non-local constants MaxRatio and StealRatio constepxr, since otherwise gcc would complain when calculating TMaxRatio and TStealRatio. (Strangely, I did not have to make Is64Bit constexpr even though it is used in ucioption.cpp in the calculation of constexpr MaxHashMB.) I have renamed PieceCount to pieceCount in material.h, since the values of the array are not compile-time constants. Some compile-time constants in tbprobe.cpp were overlooked. Sides and MaxFile are not compile-time constants, so were renamed to sides and maxFile. Non-functional change.
228 lines
8.4 KiB
C++
228 lines
8.4 KiB
C++
/*
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Stockfish, a UCI chess playing engine derived from Glaurung 2.1
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Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
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Copyright (C) 2008-2015 Marco Costalba, Joona Kiiski, Tord Romstad
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Copyright (C) 2015-2018 Marco Costalba, Joona Kiiski, Gary Linscott, Tord Romstad
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Stockfish is free software: you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation, either version 3 of the License, or
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(at your option) any later version.
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Stockfish is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program. If not, see <http://www.gnu.org/licenses/>.
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*/
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#include <algorithm> // For std::min
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#include <cassert>
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#include <cstring> // For std::memset
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#include "material.h"
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#include "thread.h"
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using namespace std;
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namespace {
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// Polynomial material imbalance parameters
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constexpr int QuadraticOurs[][PIECE_TYPE_NB] = {
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// OUR PIECES
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// pair pawn knight bishop rook queen
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{1667 }, // Bishop pair
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{ 40, 0 }, // Pawn
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{ 32, 255, -3 }, // Knight OUR PIECES
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{ 0, 104, 4, 0 }, // Bishop
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{ -26, -2, 47, 105, -149 }, // Rook
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{-189, 24, 117, 133, -134, -10 } // Queen
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};
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constexpr int QuadraticTheirs[][PIECE_TYPE_NB] = {
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// THEIR PIECES
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// pair pawn knight bishop rook queen
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{ 0 }, // Bishop pair
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{ 36, 0 }, // Pawn
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{ 9, 63, 0 }, // Knight OUR PIECES
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{ 59, 65, 42, 0 }, // Bishop
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{ 46, 39, 24, -24, 0 }, // Rook
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{ 97, 100, -42, 137, 268, 0 } // Queen
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};
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// Endgame evaluation and scaling functions are accessed directly and not through
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// the function maps because they correspond to more than one material hash key.
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Endgame<KXK> EvaluateKXK[] = { Endgame<KXK>(WHITE), Endgame<KXK>(BLACK) };
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Endgame<KBPsK> ScaleKBPsK[] = { Endgame<KBPsK>(WHITE), Endgame<KBPsK>(BLACK) };
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Endgame<KQKRPs> ScaleKQKRPs[] = { Endgame<KQKRPs>(WHITE), Endgame<KQKRPs>(BLACK) };
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Endgame<KPsK> ScaleKPsK[] = { Endgame<KPsK>(WHITE), Endgame<KPsK>(BLACK) };
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Endgame<KPKP> ScaleKPKP[] = { Endgame<KPKP>(WHITE), Endgame<KPKP>(BLACK) };
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// Helper used to detect a given material distribution
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bool is_KXK(const Position& pos, Color us) {
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return !more_than_one(pos.pieces(~us))
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&& pos.non_pawn_material(us) >= RookValueMg;
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}
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bool is_KBPsK(const Position& pos, Color us) {
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return pos.non_pawn_material(us) == BishopValueMg
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&& pos.count<BISHOP>(us) == 1
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&& pos.count<PAWN >(us) >= 1;
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}
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bool is_KQKRPs(const Position& pos, Color us) {
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return !pos.count<PAWN>(us)
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&& pos.non_pawn_material(us) == QueenValueMg
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&& pos.count<QUEEN>(us) == 1
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&& pos.count<ROOK>(~us) == 1
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&& pos.count<PAWN>(~us) >= 1;
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}
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/// imbalance() calculates the imbalance by comparing the piece count of each
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/// piece type for both colors.
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template<Color Us>
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int imbalance(const int pieceCount[][PIECE_TYPE_NB]) {
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constexpr Color Them = (Us == WHITE ? BLACK : WHITE);
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int bonus = 0;
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// Second-degree polynomial material imbalance, by Tord Romstad
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for (int pt1 = NO_PIECE_TYPE; pt1 <= QUEEN; ++pt1)
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{
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if (!pieceCount[Us][pt1])
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continue;
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int v = 0;
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for (int pt2 = NO_PIECE_TYPE; pt2 <= pt1; ++pt2)
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v += QuadraticOurs[pt1][pt2] * pieceCount[Us][pt2]
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+ QuadraticTheirs[pt1][pt2] * pieceCount[Them][pt2];
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bonus += pieceCount[Us][pt1] * v;
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}
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return bonus;
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}
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} // namespace
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namespace Material {
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/// Material::probe() looks up the current position's material configuration in
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/// the material hash table. It returns a pointer to the Entry if the position
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/// is found. Otherwise a new Entry is computed and stored there, so we don't
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/// have to recompute all when the same material configuration occurs again.
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Entry* probe(const Position& pos) {
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Key key = pos.material_key();
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Entry* e = pos.this_thread()->materialTable[key];
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if (e->key == key)
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return e;
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std::memset(e, 0, sizeof(Entry));
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e->key = key;
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e->factor[WHITE] = e->factor[BLACK] = (uint8_t)SCALE_FACTOR_NORMAL;
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Value npm_w = pos.non_pawn_material(WHITE);
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Value npm_b = pos.non_pawn_material(BLACK);
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Value npm = std::max(EndgameLimit, std::min(npm_w + npm_b, MidgameLimit));
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// Map total non-pawn material into [PHASE_ENDGAME, PHASE_MIDGAME]
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e->gamePhase = Phase(((npm - EndgameLimit) * PHASE_MIDGAME) / (MidgameLimit - EndgameLimit));
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// Let's look if we have a specialized evaluation function for this particular
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// material configuration. Firstly we look for a fixed configuration one, then
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// for a generic one if the previous search failed.
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if ((e->evaluationFunction = pos.this_thread()->endgames.probe<Value>(key)) != nullptr)
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return e;
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for (Color c = WHITE; c <= BLACK; ++c)
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if (is_KXK(pos, c))
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{
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e->evaluationFunction = &EvaluateKXK[c];
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return e;
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}
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// OK, we didn't find any special evaluation function for the current material
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// configuration. Is there a suitable specialized scaling function?
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EndgameBase<ScaleFactor>* sf;
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if ((sf = pos.this_thread()->endgames.probe<ScaleFactor>(key)) != nullptr)
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{
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e->scalingFunction[sf->strongSide] = sf; // Only strong color assigned
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return e;
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}
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// We didn't find any specialized scaling function, so fall back on generic
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// ones that refer to more than one material distribution. Note that in this
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// case we don't return after setting the function.
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for (Color c = WHITE; c <= BLACK; ++c)
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{
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if (is_KBPsK(pos, c))
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e->scalingFunction[c] = &ScaleKBPsK[c];
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else if (is_KQKRPs(pos, c))
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e->scalingFunction[c] = &ScaleKQKRPs[c];
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}
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if (npm_w + npm_b == VALUE_ZERO && pos.pieces(PAWN)) // Only pawns on the board
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{
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if (!pos.count<PAWN>(BLACK))
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{
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assert(pos.count<PAWN>(WHITE) >= 2);
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e->scalingFunction[WHITE] = &ScaleKPsK[WHITE];
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}
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else if (!pos.count<PAWN>(WHITE))
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{
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assert(pos.count<PAWN>(BLACK) >= 2);
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e->scalingFunction[BLACK] = &ScaleKPsK[BLACK];
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}
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else if (pos.count<PAWN>(WHITE) == 1 && pos.count<PAWN>(BLACK) == 1)
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{
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// This is a special case because we set scaling functions
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// for both colors instead of only one.
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e->scalingFunction[WHITE] = &ScaleKPKP[WHITE];
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e->scalingFunction[BLACK] = &ScaleKPKP[BLACK];
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}
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}
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// Zero or just one pawn makes it difficult to win, even with a small material
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// advantage. This catches some trivial draws like KK, KBK and KNK and gives a
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// drawish scale factor for cases such as KRKBP and KmmKm (except for KBBKN).
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if (!pos.count<PAWN>(WHITE) && npm_w - npm_b <= BishopValueMg)
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e->factor[WHITE] = uint8_t(npm_w < RookValueMg ? SCALE_FACTOR_DRAW :
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npm_b <= BishopValueMg ? 4 : 14);
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if (!pos.count<PAWN>(BLACK) && npm_b - npm_w <= BishopValueMg)
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e->factor[BLACK] = uint8_t(npm_b < RookValueMg ? SCALE_FACTOR_DRAW :
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npm_w <= BishopValueMg ? 4 : 14);
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if (pos.count<PAWN>(WHITE) == 1 && npm_w - npm_b <= BishopValueMg)
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e->factor[WHITE] = (uint8_t) SCALE_FACTOR_ONEPAWN;
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if (pos.count<PAWN>(BLACK) == 1 && npm_b - npm_w <= BishopValueMg)
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e->factor[BLACK] = (uint8_t) SCALE_FACTOR_ONEPAWN;
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// Evaluate the material imbalance. We use PIECE_TYPE_NONE as a place holder
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// for the bishop pair "extended piece", which allows us to be more flexible
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// in defining bishop pair bonuses.
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const int pieceCount[COLOR_NB][PIECE_TYPE_NB] = {
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{ pos.count<BISHOP>(WHITE) > 1, pos.count<PAWN>(WHITE), pos.count<KNIGHT>(WHITE),
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pos.count<BISHOP>(WHITE) , pos.count<ROOK>(WHITE), pos.count<QUEEN >(WHITE) },
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{ pos.count<BISHOP>(BLACK) > 1, pos.count<PAWN>(BLACK), pos.count<KNIGHT>(BLACK),
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pos.count<BISHOP>(BLACK) , pos.count<ROOK>(BLACK), pos.count<QUEEN >(BLACK) } };
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e->value = int16_t((imbalance<WHITE>(pieceCount) - imbalance<BLACK>(pieceCount)) / 16);
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return e;
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}
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} // namespace Material
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