X-Git-Url: https://git.sesse.net/?p=stockfish;a=blobdiff_plain;f=src%2Fmaterial.cpp;h=845519bc41648cedd2a7933564d4307b5ceafffa;hp=44700f815d8017a9f2539c3d64f4731b3028d3f6;hb=03f524c591c90120302e127cd0c1adba4c498806;hpb=31d4f0b73430677e79873beef16830dc07857ddd

diff --git a/src/material.cpp b/src/material.cpp
index 44700f81..845519bc 100644
--- a/src/material.cpp
+++ b/src/material.cpp
@@ -1,7 +1,7 @@
 /*
   Stockfish, a UCI chess playing engine derived from Glaurung 2.1
   Copyright (C) 2004-2008 Tord Romstad (Glaurung author)
-  Copyright (C) 2008 Marco Costalba
+  Copyright (C) 2008-2009 Marco Costalba
 
   Stockfish is free software: you can redistribute it and/or modify
   it under the terms of the GNU General Public License as published by
@@ -23,11 +23,12 @@
 ////
 
 #include <cassert>
-#include <cstring>
+#include <sstream>
 #include <map>
 
 #include "material.h"
 
+using std::string;
 
 ////
 //// Local definitions
@@ -35,8 +36,9 @@
 
 namespace {
 
-  const Value BishopPairMidgameBonus = Value(100);
-  const Value BishopPairEndgameBonus = Value(100);
+  // Values modified by Joona Kiiski
+  const Value BishopPairMidgameBonus = Value(109);
+  const Value BishopPairEndgameBonus = Value(97);
 
   Key KNNKMaterialKey, KKNNMaterialKey;
 
@@ -54,20 +56,21 @@ class EndgameFunctions {
 
 public:
   EndgameFunctions();
-  EndgameEvaluationFunction* getEEF(Key key) const;
-  ScalingFunction* getESF(Key key, Color* c) const;
+  EndgameEvaluationFunctionBase* getEEF(Key key) const;
+  EndgameScalingFunctionBase* getESF(Key key, Color* c) const;
 
 private:
-  void add(Key k, EndgameEvaluationFunction* f);
-  void add(Key k, Color c, ScalingFunction* f);
+  void add(const string& keyCode, EndgameEvaluationFunctionBase* f);
+  void add(const string& keyCode, Color c, EndgameScalingFunctionBase* f);
+  Key buildKey(const string& keyCode);
 
   struct ScalingInfo
   {
       Color col;
-      ScalingFunction* fun;
+      EndgameScalingFunctionBase* fun;
   };
 
-  std::map<Key, EndgameEvaluationFunction*> EEFmap;
+  std::map<Key, EndgameEvaluationFunctionBase*> EEFmap;
   std::map<Key, ScalingInfo> ESFmap;
 };
 
@@ -88,9 +91,8 @@ MaterialInfoTable::MaterialInfoTable(unsigned int numOfEntries) {
   {
       std::cerr << "Failed to allocate " << (numOfEntries * sizeof(MaterialInfo))
                 << " bytes for material hash table." << std::endl;
-      exit(EXIT_FAILURE);
+      Application::exit_with_failure();
   }
-  clear();
 }
 
 
@@ -98,17 +100,8 @@ MaterialInfoTable::MaterialInfoTable(unsigned int numOfEntries) {
 
 MaterialInfoTable::~MaterialInfoTable() {
 
-  delete [] entries;
   delete funcs;
-}
-
-
-/// MaterialInfoTable::clear() clears a material hash table by setting
-/// all entries to 0.
-
-void MaterialInfoTable::clear() {
-
-  memset(entries, 0, size * sizeof(MaterialInfo));
+  delete [] entries;
 }
 
 
@@ -143,20 +136,21 @@ MaterialInfo* MaterialInfoTable::get_material_info(const Position& pos) {
   }
 
   // Let's look if we have a specialized evaluation function for this
-  // particular material configuration.
+  // particular material configuration. First we look for a fixed
+  // configuration one, then a generic one if previous search failed.
   if ((mi->evaluationFunction = funcs->getEEF(key)) != NULL)
       return mi;
 
   else if (   pos.non_pawn_material(BLACK) == Value(0)
            && pos.piece_count(BLACK, PAWN) == 0
-           && pos.non_pawn_material(WHITE) >= RookValueEndgame)
+           && pos.non_pawn_material(WHITE) >= RookValueMidgame)
   {
       mi->evaluationFunction = &EvaluateKXK;
       return mi;
   }
   else if (   pos.non_pawn_material(WHITE) == Value(0)
            && pos.piece_count(WHITE, PAWN) == 0
-           && pos.non_pawn_material(BLACK) >= RookValueEndgame)
+           && pos.non_pawn_material(BLACK) >= RookValueMidgame)
   {
       mi->evaluationFunction = &EvaluateKKX;
       return mi;
@@ -186,7 +180,7 @@ MaterialInfo* MaterialInfoTable::get_material_info(const Position& pos) {
   // are several conflicting applicable scaling functions and we need to
   // decide which one to use.
   Color c;
-  ScalingFunction* sf;
+  EndgameScalingFunctionBase* sf;
 
   if ((sf = funcs->getESF(key, &c)) != NULL)
   {
@@ -309,69 +303,85 @@ MaterialInfo* MaterialInfoTable::get_material_info(const Position& pos) {
 
 
 /// EndgameFunctions member definitions. This class is used to store the maps
-/// of end game and scaling functions that MaterialInfoTable will query for 
+/// of end game and scaling functions that MaterialInfoTable will query for
 /// each key. The maps are constant and are populated only at construction,
 /// but are per-thread instead of globals to avoid expensive locks.
 
 EndgameFunctions::EndgameFunctions() {
 
-  typedef Key ZM[2][8][16];
-  const ZM& z = Position::zobMaterial;
-
-  static const Color W = WHITE;
-  static const Color B = BLACK;
-
-  KNNKMaterialKey = z[W][KNIGHT][1] ^ z[W][KNIGHT][2];
-  KKNNMaterialKey = z[B][KNIGHT][1] ^ z[B][KNIGHT][2];
-
-  add(z[W][PAWN][1], &EvaluateKPK);
-  add(z[B][PAWN][1], &EvaluateKKP);
-
-  add(z[W][BISHOP][1] ^ z[W][KNIGHT][1], &EvaluateKBNK);
-  add(z[B][BISHOP][1] ^ z[B][KNIGHT][1], &EvaluateKKBN);
-  add(z[W][ROOK][1]   ^ z[B][PAWN][1],   &EvaluateKRKP);
-  add(z[W][PAWN][1]   ^ z[B][ROOK][1],   &EvaluateKPKR);
-  add(z[W][ROOK][1]   ^ z[B][BISHOP][1], &EvaluateKRKB);
-  add(z[W][BISHOP][1] ^ z[B][ROOK][1],   &EvaluateKBKR);
-  add(z[W][ROOK][1]   ^ z[B][KNIGHT][1], &EvaluateKRKN);
-  add(z[W][KNIGHT][1] ^ z[B][ROOK][1],   &EvaluateKNKR);
-  add(z[W][QUEEN][1]  ^ z[B][ROOK][1],   &EvaluateKQKR);
-  add(z[W][ROOK][1]   ^ z[B][QUEEN][1],  &EvaluateKRKQ);
-  add(z[W][BISHOP][2] ^ z[B][KNIGHT][1], &EvaluateKBBKN);
-  add(z[W][KNIGHT][1] ^ z[B][BISHOP][2], &EvaluateKNKBB);
-
-  add(z[W][KNIGHT][1] ^ z[W][PAWN][1], W, &ScaleKNPK);
-  add(z[B][KNIGHT][1] ^ z[B][PAWN][1], B, &ScaleKKNP);
-
-  add(z[W][ROOK][1]   ^ z[W][PAWN][1]   ^ z[B][ROOK][1]  , W, &ScaleKRPKR);
-  add(z[W][ROOK][1]   ^ z[B][ROOK][1]   ^ z[B][PAWN][1]  , B, &ScaleKRKRP);
-  add(z[W][BISHOP][1] ^ z[W][PAWN][1]   ^ z[B][BISHOP][1], W, &ScaleKBPKB);
-  add(z[W][BISHOP][1] ^ z[B][BISHOP][1] ^ z[B][PAWN][1]  , B, &ScaleKBKBP);
-  add(z[W][BISHOP][1] ^ z[W][PAWN][1]   ^ z[B][KNIGHT][1], W, &ScaleKBPKN);
-  add(z[W][KNIGHT][1] ^ z[B][BISHOP][1] ^ z[B][PAWN][1]  , B, &ScaleKNKBP);
-
-  add(z[W][ROOK][1] ^ z[W][PAWN][1] ^ z[W][PAWN][2] ^ z[B][ROOK][1] ^ z[B][PAWN][1], W, &ScaleKRPPKRP);
-  add(z[W][ROOK][1] ^ z[W][PAWN][1] ^ z[B][ROOK][1] ^ z[B][PAWN][1] ^ z[B][PAWN][2], B, &ScaleKRPKRPP);
+  KNNKMaterialKey = buildKey("KNNK");
+  KKNNMaterialKey = buildKey("KKNN");
+
+  add("KPK",   &EvaluateKPK);
+  add("KKP",   &EvaluateKKP);
+  add("KBNK",  &EvaluateKBNK);
+  add("KKBN",  &EvaluateKKBN);
+  add("KRKP",  &EvaluateKRKP);
+  add("KPKR",  &EvaluateKPKR);
+  add("KRKB",  &EvaluateKRKB);
+  add("KBKR",  &EvaluateKBKR);
+  add("KRKN",  &EvaluateKRKN);
+  add("KNKR",  &EvaluateKNKR);
+  add("KQKR",  &EvaluateKQKR);
+  add("KRKQ",  &EvaluateKRKQ);
+  add("KBBKN", &EvaluateKBBKN);
+  add("KNKBB", &EvaluateKNKBB);
+
+  add("KNPK",    WHITE, &ScaleKNPK);
+  add("KKNP",    BLACK, &ScaleKKNP);
+  add("KRPKR",   WHITE, &ScaleKRPKR);
+  add("KRKRP",   BLACK, &ScaleKRKRP);
+  add("KBPKB",   WHITE, &ScaleKBPKB);
+  add("KBKBP",   BLACK, &ScaleKBKBP);
+  add("KBPPKB",  WHITE, &ScaleKBPPKB);
+  add("KBKBPP",  BLACK, &ScaleKBKBPP);
+  add("KBPKN",   WHITE, &ScaleKBPKN);
+  add("KNKBP",   BLACK, &ScaleKNKBP);
+  add("KRPPKRP", WHITE, &ScaleKRPPKRP);
+  add("KRPKRPP", BLACK, &ScaleKRPKRPP);
+  add("KRPPKRP", WHITE, &ScaleKRPPKRP);
+  add("KRPKRPP", BLACK, &ScaleKRPKRPP);
+}
+
+Key EndgameFunctions::buildKey(const string& keyCode) {
+
+    assert(keyCode.length() > 0 && keyCode[0] == 'K');
+    assert(keyCode.length() < 8);
+
+    std::stringstream s;
+    bool upcase = false;
+
+    // Build up a fen substring with the given pieces, note
+    // that the fen string could be of an illegal position.
+    for (size_t i = 0; i < keyCode.length(); i++)
+    {
+        if (keyCode[i] == 'K')
+            upcase = !upcase;
+
+        s << char(upcase? toupper(keyCode[i]) : tolower(keyCode[i]));
+    }
+    s << 8 - keyCode.length() << "/8/8/8/8/8/8/8 w -";
+    return Position(s.str()).get_material_key();
 }
 
-void EndgameFunctions::add(Key k, EndgameEvaluationFunction* f) {
+void EndgameFunctions::add(const string& keyCode, EndgameEvaluationFunctionBase* f) {
 
-  EEFmap.insert(std::pair<Key, EndgameEvaluationFunction*>(k, f));
+  EEFmap.insert(std::pair<Key, EndgameEvaluationFunctionBase*>(buildKey(keyCode), f));
 }
 
-void EndgameFunctions::add(Key k, Color c, ScalingFunction* f) {
+void EndgameFunctions::add(const string& keyCode, Color c, EndgameScalingFunctionBase* f) {
 
   ScalingInfo s = {c, f};
-  ESFmap.insert(std::pair<Key, ScalingInfo>(k, s));
+  ESFmap.insert(std::pair<Key, ScalingInfo>(buildKey(keyCode), s));
 }
 
-EndgameEvaluationFunction* EndgameFunctions::getEEF(Key key) const {
+EndgameEvaluationFunctionBase* EndgameFunctions::getEEF(Key key) const {
 
-  std::map<Key, EndgameEvaluationFunction*>::const_iterator it(EEFmap.find(key));
+  std::map<Key, EndgameEvaluationFunctionBase*>::const_iterator it(EEFmap.find(key));
   return (it != EEFmap.end() ? it->second : NULL);
 }
 
-ScalingFunction* EndgameFunctions::getESF(Key key, Color* c) const {
+EndgameScalingFunctionBase* EndgameFunctions::getESF(Key key, Color* c) const {
 
   std::map<Key, ScalingInfo>::const_iterator it(ESFmap.find(key));
   if (it == ESFmap.end())