#include "movegen.h"
#include "movepick.h"
+#include "thread.h"
namespace {
// Unary predicate used by std::partition to split positive scores from remaining
// ones so to sort separately the two sets, and with the second sort delayed.
- inline bool has_positive_score(const MoveStack& move) { return move.score > 0; }
+ inline bool has_positive_score(const MoveStack& ms) { return ms.score > 0; }
- // Picks and moves to the front the best move in the range [firstMove, lastMove),
+ // Picks and moves to the front the best move in the range [begin, end),
// it is faster than sorting all the moves in advance when moves are few, as
// normally are the possible captures.
- inline MoveStack* pick_best(MoveStack* firstMove, MoveStack* lastMove)
+ inline MoveStack* pick_best(MoveStack* begin, MoveStack* end)
{
- std::swap(*firstMove, *std::max_element(firstMove, lastMove));
- return firstMove;
+ std::swap(*begin, *std::max_element(begin, end));
+ return begin;
}
}
/// move ordering is at the current node.
MovePicker::MovePicker(const Position& p, Move ttm, Depth d, const History& h,
- Search::Stack* ss, Value beta) : pos(p), H(h), depth(d) {
+ Search::Stack* s, Value beta) : pos(p), H(h), depth(d) {
assert(d > DEPTH_ZERO);
captureThreshold = 0;
- curMove = lastMove = moves;
- lastBadCapture = moves + MAX_MOVES - 1;
+ cur = end = moves;
+ endBadCaptures = moves + MAX_MOVES - 1;
+ ss = s;
if (p.in_check())
phase = EVASION;
killers[1].move = ss->killers[1];
// Consider sligtly negative captures as good if at low depth and far from beta
- if (ss && ss->eval < beta - PawnValueMidgame && d < 3 * ONE_PLY)
- captureThreshold = -PawnValueMidgame;
+ if (ss && ss->eval < beta - PawnValueMg && d < 3 * ONE_PLY)
+ captureThreshold = -PawnValueMg;
// Consider negative captures as good if still enough to reach beta
else if (ss && ss->eval > beta)
}
ttMove = (ttm && pos.is_pseudo_legal(ttm) ? ttm : MOVE_NONE);
- lastMove += (ttMove != MOVE_NONE);
+ end += (ttMove != MOVE_NONE);
}
MovePicker::MovePicker(const Position& p, Move ttm, Depth d, const History& h,
- Square sq) : pos(p), H(h), curMove(moves), lastMove(moves) {
+ Square sq) : pos(p), H(h), cur(moves), end(moves) {
assert(d <= DEPTH_ZERO);
}
ttMove = (ttm && pos.is_pseudo_legal(ttm) ? ttm : MOVE_NONE);
- lastMove += (ttMove != MOVE_NONE);
+ end += (ttMove != MOVE_NONE);
}
MovePicker::MovePicker(const Position& p, Move ttm, const History& h, PieceType pt)
- : pos(p), H(h), curMove(moves), lastMove(moves) {
+ : pos(p), H(h), cur(moves), end(moves) {
assert(!pos.in_check());
phase = PROBCUT;
// In ProbCut we generate only captures better than parent's captured piece
- captureThreshold = PieceValueMidgame[pt];
+ captureThreshold = PieceValue[Mg][pt];
ttMove = (ttm && pos.is_pseudo_legal(ttm) ? ttm : MOVE_NONE);
if (ttMove && (!pos.is_capture(ttMove) || pos.see(ttMove) <= captureThreshold))
ttMove = MOVE_NONE;
- lastMove += (ttMove != MOVE_NONE);
+ end += (ttMove != MOVE_NONE);
}
// some SEE calls in case we get a cutoff (idea from Pablo Vazquez).
Move m;
- for (MoveStack* cur = moves; cur != lastMove; cur++)
+ for (MoveStack* it = moves; it != end; ++it)
{
- m = cur->move;
- cur->score = PieceValueMidgame[pos.piece_on(to_sq(m))]
- - type_of(pos.piece_moved(m));
+ m = it->move;
+ it->score = PieceValue[Mg][pos.piece_on(to_sq(m))]
+ - type_of(pos.piece_moved(m));
- if (is_promotion(m))
- cur->score += PieceValueMidgame[promotion_type(m)];
+ if (type_of(m) == PROMOTION)
+ it->score += PieceValue[Mg][promotion_type(m)];
}
}
Move m;
- for (MoveStack* cur = moves; cur != lastMove; cur++)
+ for (MoveStack* it = moves; it != end; ++it)
{
- m = cur->move;
- cur->score = H.value(pos.piece_moved(m), to_sq(m));
+ m = it->move;
+ it->score = H.value(pos.piece_moved(m), to_sq(m));
}
}
Move m;
int seeScore;
- if (lastMove < moves + 2)
+ if (end < moves + 2)
return;
- for (MoveStack* cur = moves; cur != lastMove; cur++)
+ for (MoveStack* it = moves; it != end; ++it)
{
- m = cur->move;
+ m = it->move;
if ((seeScore = pos.see_sign(m)) < 0)
- cur->score = seeScore - History::MaxValue; // Be sure we are at the bottom
+ it->score = seeScore - History::MaxValue; // Be sure we are at the bottom
else if (pos.is_capture(m))
- cur->score = PieceValueMidgame[pos.piece_on(to_sq(m))]
- - type_of(pos.piece_moved(m)) + History::MaxValue;
+ it->score = PieceValue[Mg][pos.piece_on(to_sq(m))]
+ - type_of(pos.piece_moved(m)) + History::MaxValue;
else
- cur->score = H.value(pos.piece_moved(m), to_sq(m));
+ it->score = H.value(pos.piece_moved(m), to_sq(m));
}
}
void MovePicker::generate_next() {
- curMove = moves;
+ cur = moves;
switch (++phase) {
case CAPTURES_S1: case CAPTURES_S3: case CAPTURES_S4: case CAPTURES_S5: case CAPTURES_S6:
- lastMove = generate<MV_CAPTURE>(pos, moves);
+ end = generate<CAPTURES>(pos, moves);
score_captures();
return;
case KILLERS_S1:
- curMove = killers;
- lastMove = curMove + 2;
+ cur = killers;
+ end = cur + 2;
return;
case QUIETS_1_S1:
- lastQuiet = lastMove = generate<MV_QUIET>(pos, moves);
+ endQuiets = end = generate<QUIETS>(pos, moves);
score_noncaptures();
- lastMove = std::partition(curMove, lastMove, has_positive_score);
- sort<MoveStack>(curMove, lastMove);
+ end = std::partition(cur, end, has_positive_score);
+ sort<MoveStack>(cur, end);
return;
case QUIETS_2_S1:
- curMove = lastMove;
- lastMove = lastQuiet;
+ cur = end;
+ end = endQuiets;
if (depth >= 3 * ONE_PLY)
- sort<MoveStack>(curMove, lastMove);
+ sort<MoveStack>(cur, end);
return;
case BAD_CAPTURES_S1:
// Just pick them in reverse order to get MVV/LVA ordering
- curMove = moves + MAX_MOVES - 1;
- lastMove = lastBadCapture;
+ cur = moves + MAX_MOVES - 1;
+ end = endBadCaptures;
return;
case EVASIONS_S2:
- lastMove = generate<MV_EVASION>(pos, moves);
+ end = generate<EVASIONS>(pos, moves);
score_evasions();
return;
case QUIET_CHECKS_S3:
- lastMove = generate<MV_QUIET_CHECK>(pos, moves);
+ end = generate<QUIET_CHECKS>(pos, moves);
return;
case EVASION: case QSEARCH_0: case QSEARCH_1: case PROBCUT: case RECAPTURE:
phase = STOP;
case STOP:
- lastMove = curMove + 1; // Avoid another next_phase() call
+ end = cur + 1; // Avoid another next_phase() call
return;
default:
/// It returns a new pseudo legal move every time it is called, until there
/// are no more moves left. It picks the move with the biggest score from a list
/// of generated moves taking care not to return the tt move if has already been
-/// searched previously. Note that this function is not thread safe so should be
-/// lock protected by caller when accessed through a shared MovePicker object.
-
-Move MovePicker::next_move() {
+/// searched previously.
+template<>
+Move MovePicker::next_move<false>() {
Move move;
while (true)
{
- while (curMove == lastMove)
+ while (cur == end)
generate_next();
switch (phase) {
case MAIN_SEARCH: case EVASION: case QSEARCH_0: case QSEARCH_1: case PROBCUT:
- curMove++;
+ cur++;
return ttMove;
case CAPTURES_S1:
- move = pick_best(curMove++, lastMove)->move;
+ move = pick_best(cur++, end)->move;
if (move != ttMove)
{
assert(captureThreshold <= 0); // Otherwise we cannot use see_sign()
return move;
// Losing capture, move it to the tail of the array
- (lastBadCapture--)->move = move;
+ (endBadCaptures--)->move = move;
}
break;
case KILLERS_S1:
- move = (curMove++)->move;
- if ( move != MOVE_NONE
- && pos.is_pseudo_legal(move)
- && move != ttMove
+ move = (cur++)->move;
+ if ( move != MOVE_NONE
+ && pos.is_pseudo_legal(move)
+ && move != ttMove
&& !pos.is_capture(move))
return move;
break;
case QUIETS_1_S1: case QUIETS_2_S1:
- move = (curMove++)->move;
+ move = (cur++)->move;
if ( move != ttMove
&& move != killers[0].move
&& move != killers[1].move)
break;
case BAD_CAPTURES_S1:
- return (curMove--)->move;
+ return (cur--)->move;
case EVASIONS_S2: case CAPTURES_S3: case CAPTURES_S4:
- move = pick_best(curMove++, lastMove)->move;
+ move = pick_best(cur++, end)->move;
if (move != ttMove)
return move;
break;
case CAPTURES_S5:
- move = pick_best(curMove++, lastMove)->move;
+ move = pick_best(cur++, end)->move;
if (move != ttMove && pos.see(move) > captureThreshold)
return move;
break;
case CAPTURES_S6:
- move = pick_best(curMove++, lastMove)->move;
+ move = pick_best(cur++, end)->move;
if (to_sq(move) == recaptureSquare)
return move;
break;
case QUIET_CHECKS_S3:
- move = (curMove++)->move;
+ move = (cur++)->move;
if (move != ttMove)
return move;
break;
}
}
}
+
+
+/// Version of next_move() to use at split point nodes where the move is grabbed
+/// from the split point's shared MovePicker object. This function is not thread
+/// safe so should be lock protected by the caller.
+template<>
+Move MovePicker::next_move<true>() { return ss->sp->mp->next_move<false>(); }
projects / stockfish / blobdiff