| Index: src/ia32/codegen-ia32.cc
|
| ===================================================================
|
| --- src/ia32/codegen-ia32.cc (revision 2087)
|
| +++ src/ia32/codegen-ia32.cc (working copy)
|
| @@ -776,27 +776,20 @@
|
| }
|
|
|
|
|
| -// A deferred code class implementing binary operations on likely smis.
|
| -// This class generates both inline code and deferred code.
|
| -// The fastest path is implemented inline. Deferred code calls
|
| -// the GenericBinaryOpStub stub for slow cases.
|
| +// Call the specialized stub for a binary operation.
|
| class DeferredInlineBinaryOperation: public DeferredCode {
|
| public:
|
| DeferredInlineBinaryOperation(Token::Value op,
|
| - OverwriteMode mode,
|
| - GenericBinaryFlags flags)
|
| - : stub_(op, mode, flags), op_(op) {
|
| + OverwriteMode mode)
|
| + : op_(op), mode_(mode) {
|
| set_comment("[ DeferredInlineBinaryOperation");
|
| }
|
|
|
| - // Consumes its arguments, left and right, leaving them invalid.
|
| - Result GenerateInlineCode(Result* left, Result* right);
|
| -
|
| virtual void Generate();
|
|
|
| private:
|
| - GenericBinaryOpStub stub_;
|
| Token::Value op_;
|
| + OverwriteMode mode_;
|
| };
|
|
|
|
|
| @@ -806,7 +799,8 @@
|
| enter()->Bind(&left, &right);
|
| cgen()->frame()->Push(&left);
|
| cgen()->frame()->Push(&right);
|
| - Result answer = cgen()->frame()->CallStub(&stub_, 2);
|
| + GenericBinaryOpStub stub(op_, mode_, SMI_CODE_INLINED);
|
| + Result answer = cgen()->frame()->CallStub(&stub, 2);
|
| exit_.Jump(&answer);
|
| }
|
|
|
| @@ -1007,13 +1001,343 @@
|
| Result* left,
|
| Result* right,
|
| OverwriteMode overwrite_mode) {
|
| - // Implements a binary operation using a deferred code object
|
| - // and some inline code to operate on smis quickly.
|
| + // Implements a binary operation using a deferred code object and
|
| + // some inline code to operate on smis quickly.
|
| DeferredInlineBinaryOperation* deferred =
|
| - new DeferredInlineBinaryOperation(op, overwrite_mode, SMI_CODE_INLINED);
|
| - // Generate the inline code that handles some smi operations,
|
| - // and jumps to the deferred code for everything else.
|
| - Result answer = deferred->GenerateInlineCode(left, right);
|
| + new DeferredInlineBinaryOperation(op, overwrite_mode);
|
| +
|
| + // Special handling of div and mod because they use fixed registers.
|
| + if (op == Token::DIV || op == Token::MOD) {
|
| + // We need eax as the quotient register, edx as the remainder
|
| + // register, neither left nor right in eax or edx, and left copied
|
| + // to eax.
|
| + Result quotient;
|
| + Result remainder;
|
| + bool left_is_in_eax = false;
|
| + // Step 1: get eax for quotient.
|
| + if ((left->is_register() && left->reg().is(eax)) ||
|
| + (right->is_register() && right->reg().is(eax))) {
|
| + // One or both is in eax. Use a fresh non-edx register for
|
| + // them.
|
| + Result fresh = allocator_->Allocate();
|
| + ASSERT(fresh.is_valid());
|
| + if (fresh.reg().is(edx)) {
|
| + remainder = fresh;
|
| + fresh = allocator_->Allocate();
|
| + ASSERT(fresh.is_valid());
|
| + }
|
| + if (left->is_register() && left->reg().is(eax)) {
|
| + quotient = *left;
|
| + *left = fresh;
|
| + left_is_in_eax = true;
|
| + }
|
| + if (right->is_register() && right->reg().is(eax)) {
|
| + quotient = *right;
|
| + *right = fresh;
|
| + }
|
| + __ mov(fresh.reg(), eax);
|
| + } else {
|
| + // Neither left nor right is in eax.
|
| + quotient = allocator_->Allocate(eax);
|
| + }
|
| + ASSERT(quotient.is_register() && quotient.reg().is(eax));
|
| + ASSERT(!(left->is_register() && left->reg().is(eax)));
|
| + ASSERT(!(right->is_register() && right->reg().is(eax)));
|
| +
|
| + // Step 2: get edx for remainder if necessary.
|
| + if (!remainder.is_valid()) {
|
| + if ((left->is_register() && left->reg().is(edx)) ||
|
| + (right->is_register() && right->reg().is(edx))) {
|
| + Result fresh = allocator_->Allocate();
|
| + ASSERT(fresh.is_valid());
|
| + if (left->is_register() && left->reg().is(edx)) {
|
| + remainder = *left;
|
| + *left = fresh;
|
| + }
|
| + if (right->is_register() && right->reg().is(edx)) {
|
| + remainder = *right;
|
| + *right = fresh;
|
| + }
|
| + __ mov(fresh.reg(), edx);
|
| + } else {
|
| + // Neither left nor right is in edx.
|
| + remainder = allocator_->Allocate(edx);
|
| + }
|
| + }
|
| + ASSERT(remainder.is_register() && remainder.reg().is(edx));
|
| + ASSERT(!(left->is_register() && left->reg().is(edx)));
|
| + ASSERT(!(right->is_register() && right->reg().is(edx)));
|
| +
|
| + left->ToRegister();
|
| + right->ToRegister();
|
| + frame_->Spill(quotient.reg());
|
| + frame_->Spill(remainder.reg());
|
| +
|
| + // Check that left and right are smi tagged.
|
| + if (left->reg().is(right->reg())) {
|
| + __ test(left->reg(), Immediate(kSmiTagMask));
|
| + } else {
|
| + // Use the quotient register as a scratch for the tag check.
|
| + if (!left_is_in_eax) __ mov(quotient.reg(), left->reg());
|
| + left_is_in_eax = false;
|
| + __ or_(quotient.reg(), Operand(right->reg()));
|
| + ASSERT(kSmiTag == 0); // Adjust test if not the case.
|
| + __ test(quotient.reg(), Immediate(kSmiTagMask));
|
| + }
|
| + deferred->SetEntryFrame(left, right);
|
| + deferred->enter()->Branch(not_zero, left, right);
|
| +
|
| + if (!left_is_in_eax) __ mov(quotient.reg(), left->reg());
|
| +
|
| + // Sign extend eax into edx:eax.
|
| + __ cdq();
|
| + // Check for 0 divisor.
|
| + __ test(right->reg(), Operand(right->reg()));
|
| + deferred->enter()->Branch(zero, left, right);
|
| + // Divide edx:eax by the right operand.
|
| + __ idiv(right->reg());
|
| +
|
| + // Complete the operation.
|
| + if (op == Token::DIV) {
|
| + // Check for negative zero result. If result is zero, and divisor
|
| + // is negative, return a floating point negative zero. The
|
| + // virtual frame is unchanged in this block, so local control flow
|
| + // can use a Label rather than a JumpTarget.
|
| + Label non_zero_result;
|
| + __ test(left->reg(), Operand(left->reg()));
|
| + __ j(not_zero, &non_zero_result);
|
| + __ test(right->reg(), Operand(right->reg()));
|
| + deferred->enter()->Branch(negative, left, right);
|
| + __ bind(&non_zero_result);
|
| + // Check for the corner case of dividing the most negative smi by
|
| + // -1. We cannot use the overflow flag, since it is not set by
|
| + // idiv instruction.
|
| + ASSERT(kSmiTag == 0 && kSmiTagSize == 1);
|
| + __ cmp(quotient.reg(), 0x40000000);
|
| + deferred->enter()->Branch(equal, left, right);
|
| + // Check that the remainder is zero.
|
| + __ test(remainder.reg(), Operand(remainder.reg()));
|
| + remainder.Unuse();
|
| + deferred->enter()->Branch(not_zero, left, right);
|
| + left->Unuse();
|
| + right->Unuse();
|
| + // Tag the result and store it in the quotient register.
|
| + ASSERT(kSmiTagSize == times_2); // adjust code if not the case
|
| + __ lea(quotient.reg(),
|
| + Operand(quotient.reg(), quotient.reg(), times_1, kSmiTag));
|
| + deferred->BindExit("ient);
|
| + frame_->Push("ient);
|
| + } else {
|
| + ASSERT(op == Token::MOD);
|
| + quotient.Unuse();
|
| + // Check for a negative zero result. If the result is zero, and
|
| + // the dividend is negative, return a floating point negative
|
| + // zero. The frame is unchanged in this block, so local control
|
| + // flow can use a Label rather than a JumpTarget.
|
| + Label non_zero_result;
|
| + __ test(remainder.reg(), Operand(remainder.reg()));
|
| + __ j(not_zero, &non_zero_result, taken);
|
| + __ test(left->reg(), Operand(left->reg()));
|
| + deferred->enter()->Branch(negative, left, right);
|
| + left->Unuse();
|
| + right->Unuse();
|
| + __ bind(&non_zero_result);
|
| + deferred->BindExit(&remainder);
|
| + frame_->Push(&remainder);
|
| + }
|
| + return;
|
| + }
|
| +
|
| + // Handle the other binary operations.
|
| + left->ToRegister();
|
| + right->ToRegister();
|
| + // A newly allocated register answer is used to hold the answer. The
|
| + // registers containing left and right are not modified in most cases,
|
| + // so they usually don't need to be spilled in the fast case.
|
| + Result answer = allocator_->Allocate();
|
| +
|
| + ASSERT(answer.is_valid());
|
| + // Perform the smi tag check.
|
| + if (left->reg().is(right->reg())) {
|
| + __ test(left->reg(), Immediate(kSmiTagMask));
|
| + } else {
|
| + __ mov(answer.reg(), left->reg());
|
| + __ or_(answer.reg(), Operand(right->reg()));
|
| + ASSERT(kSmiTag == 0); // Adjust test if not the case.
|
| + __ test(answer.reg(), Immediate(kSmiTagMask));
|
| + }
|
| + switch (op) {
|
| + case Token::ADD:
|
| + deferred->SetEntryFrame(left, right);
|
| + deferred->enter()->Branch(not_zero, left, right, not_taken);
|
| + __ mov(answer.reg(), left->reg());
|
| + __ add(answer.reg(), Operand(right->reg())); // Add optimistically.
|
| + deferred->enter()->Branch(overflow, left, right, not_taken);
|
| + break;
|
| +
|
| + case Token::SUB:
|
| + deferred->SetEntryFrame(left, right);
|
| + deferred->enter()->Branch(not_zero, left, right, not_taken);
|
| + __ mov(answer.reg(), left->reg());
|
| + __ sub(answer.reg(), Operand(right->reg())); // Subtract optimistically.
|
| + deferred->enter()->Branch(overflow, left, right, not_taken);
|
| + break;
|
| +
|
| + case Token::MUL: {
|
| + deferred->SetEntryFrame(left, right);
|
| + deferred->enter()->Branch(not_zero, left, right, not_taken);
|
| + __ mov(answer.reg(), left->reg());
|
| + // If the smi tag is 0 we can just leave the tag on one operand.
|
| + ASSERT(kSmiTag == 0); // Adjust code below if not the case.
|
| + // Remove smi tag from the left operand (but keep sign).
|
| + // Left-hand operand has been copied into answer.
|
| + __ sar(answer.reg(), kSmiTagSize);
|
| + // Do multiplication of smis, leaving result in answer.
|
| + __ imul(answer.reg(), Operand(right->reg()));
|
| + // Go slow on overflows.
|
| + deferred->enter()->Branch(overflow, left, right, not_taken);
|
| + // Check for negative zero result. If product is zero, and one
|
| + // argument is negative, go to slow case. The frame is unchanged
|
| + // in this block, so local control flow can use a Label rather
|
| + // than a JumpTarget.
|
| + Label non_zero_result;
|
| + __ test(answer.reg(), Operand(answer.reg()));
|
| + __ j(not_zero, &non_zero_result, taken);
|
| + __ mov(answer.reg(), left->reg());
|
| + __ or_(answer.reg(), Operand(right->reg()));
|
| + deferred->enter()->Branch(negative, left, right, not_taken);
|
| + __ xor_(answer.reg(), Operand(answer.reg())); // Positive 0 is correct.
|
| + __ bind(&non_zero_result);
|
| + break;
|
| + }
|
| +
|
| + case Token::BIT_OR:
|
| + deferred->enter()->Branch(not_zero, left, right, not_taken);
|
| + __ mov(answer.reg(), left->reg());
|
| + __ or_(answer.reg(), Operand(right->reg()));
|
| + break;
|
| +
|
| + case Token::BIT_AND:
|
| + deferred->enter()->Branch(not_zero, left, right, not_taken);
|
| + __ mov(answer.reg(), left->reg());
|
| + __ and_(answer.reg(), Operand(right->reg()));
|
| + break;
|
| +
|
| + case Token::BIT_XOR:
|
| + deferred->enter()->Branch(not_zero, left, right, not_taken);
|
| + __ mov(answer.reg(), left->reg());
|
| + __ xor_(answer.reg(), Operand(right->reg()));
|
| + break;
|
| +
|
| + case Token::SHL:
|
| + case Token::SHR:
|
| + case Token::SAR:
|
| + deferred->enter()->Branch(not_zero, left, right, not_taken);
|
| + __ mov(answer.reg(), left->reg());
|
| + // Move right into ecx.
|
| + // Left is in two registers already, so even if left or answer is ecx,
|
| + // we can move right to it, and use the other one.
|
| + // Right operand must be in register cl because x86 likes it that way.
|
| + if (right->reg().is(ecx)) {
|
| + // Right is already in the right place. Left may be in the
|
| + // same register, which causes problems. Always use answer
|
| + // instead of left, even if left is not ecx, since this avoids
|
| + // spilling left.
|
| + *left = answer;
|
| + } else if (left->reg().is(ecx)) {
|
| + frame_->Spill(left->reg());
|
| + __ mov(left->reg(), right->reg());
|
| + *right = *left;
|
| + *left = answer; // Use copy of left in answer as left.
|
| + } else if (answer.reg().is(ecx)) {
|
| + __ mov(answer.reg(), right->reg());
|
| + *right = answer;
|
| + } else {
|
| + Result reg_ecx = allocator_->Allocate(ecx);
|
| + ASSERT(reg_ecx.is_valid());
|
| + __ mov(ecx, right->reg());
|
| + *right = reg_ecx;
|
| + // Answer and left both contain the left operand. Use answer, so
|
| + // left is not spilled.
|
| + *left = answer;
|
| + }
|
| + ASSERT(left->reg().is_valid());
|
| + ASSERT(!left->reg().is(ecx));
|
| + ASSERT(right->reg().is(ecx));
|
| + answer.Unuse(); // Answer may now be being used for left or right.
|
| + // We will modify left and right, which we do not do in any other
|
| + // binary operation. The exits to slow code need to restore the
|
| + // original values of left and right, or at least values that give
|
| + // the same answer.
|
| +
|
| + // We are modifying left and right. They must be spilled!
|
| + frame_->Spill(left->reg());
|
| + frame_->Spill(right->reg());
|
| +
|
| + // Remove tags from operands (but keep sign).
|
| + __ sar(left->reg(), kSmiTagSize);
|
| + __ sar(ecx, kSmiTagSize);
|
| + // Perform the operation.
|
| + switch (op) {
|
| + case Token::SAR:
|
| + __ sar(left->reg());
|
| + // No checks of result necessary
|
| + break;
|
| + case Token::SHR: {
|
| + __ shr(left->reg());
|
| + // Check that the *unsigned* result fits in a smi.
|
| + // Neither of the two high-order bits can be set:
|
| + // - 0x80000000: high bit would be lost when smi tagging.
|
| + // - 0x40000000: this number would convert to negative when
|
| + // Smi tagging these two cases can only happen with shifts
|
| + // by 0 or 1 when handed a valid smi.
|
| + // If the answer cannot be represented by a SMI, restore
|
| + // the left and right arguments, and jump to slow case.
|
| + // The low bit of the left argument may be lost, but only
|
| + // in a case where it is dropped anyway.
|
| + JumpTarget result_ok;
|
| + __ test(left->reg(), Immediate(0xc0000000));
|
| + result_ok.Branch(zero, left, taken);
|
| + __ shl(left->reg());
|
| + ASSERT(kSmiTag == 0);
|
| + __ shl(left->reg(), kSmiTagSize);
|
| + __ shl(right->reg(), kSmiTagSize);
|
| + deferred->enter()->Jump(left, right);
|
| + result_ok.Bind(left);
|
| + break;
|
| + }
|
| + case Token::SHL: {
|
| + __ shl(left->reg());
|
| + // Check that the *signed* result fits in a smi.
|
| + JumpTarget result_ok;
|
| + __ cmp(left->reg(), 0xc0000000);
|
| + result_ok.Branch(positive, left, taken);
|
| +
|
| + __ shr(left->reg());
|
| + ASSERT(kSmiTag == 0);
|
| + __ shl(left->reg(), kSmiTagSize);
|
| + __ shl(right->reg(), kSmiTagSize);
|
| + deferred->enter()->Jump(left, right);
|
| + result_ok.Bind(left);
|
| + break;
|
| + }
|
| + default:
|
| + UNREACHABLE();
|
| + }
|
| + // Smi-tag the result, in left, and make answer an alias for left->
|
| + answer = *left;
|
| + answer.ToRegister();
|
| + ASSERT(kSmiTagSize == times_2); // adjust code if not the case
|
| + __ lea(answer.reg(),
|
| + Operand(answer.reg(), answer.reg(), times_1, kSmiTag));
|
| + break;
|
| +
|
| + default:
|
| + UNREACHABLE();
|
| + break;
|
| + }
|
| + left->Unuse();
|
| + right->Unuse();
|
| deferred->BindExit(&answer);
|
| frame_->Push(&answer);
|
| }
|
| @@ -5732,341 +6056,6 @@
|
| }
|
|
|
|
|
| -Result DeferredInlineBinaryOperation::GenerateInlineCode(Result* left,
|
| - Result* right) {
|
| - MacroAssembler* masm = cgen()->masm();
|
| -
|
| - // Special handling of div and mod because they use fixed registers.
|
| - if (op_ == Token::DIV || op_ == Token::MOD) {
|
| - // We need eax as the quotient register, edx as the remainder
|
| - // register, neither left nor right in eax or edx, and left copied
|
| - // to eax.
|
| - Result quotient;
|
| - Result remainder;
|
| - bool left_is_in_eax = false;
|
| - // Step 1: get eax for quotient.
|
| - if ((left->is_register() && left->reg().is(eax)) ||
|
| - (right->is_register() && right->reg().is(eax))) {
|
| - // One or both is in eax. Use a fresh non-edx register for
|
| - // them.
|
| - Result fresh = cgen()->allocator()->Allocate();
|
| - ASSERT(fresh.is_valid());
|
| - if (fresh.reg().is(edx)) {
|
| - remainder = fresh;
|
| - fresh = cgen()->allocator()->Allocate();
|
| - ASSERT(fresh.is_valid());
|
| - }
|
| - if (left->is_register() && left->reg().is(eax)) {
|
| - quotient = *left;
|
| - *left = fresh;
|
| - left_is_in_eax = true;
|
| - }
|
| - if (right->is_register() && right->reg().is(eax)) {
|
| - quotient = *right;
|
| - *right = fresh;
|
| - }
|
| - __ mov(fresh.reg(), eax);
|
| - } else {
|
| - // Neither left nor right is in eax.
|
| - quotient = cgen()->allocator()->Allocate(eax);
|
| - }
|
| - ASSERT(quotient.is_register() && quotient.reg().is(eax));
|
| - ASSERT(!(left->is_register() && left->reg().is(eax)));
|
| - ASSERT(!(right->is_register() && right->reg().is(eax)));
|
| -
|
| - // Step 2: get edx for remainder if necessary.
|
| - if (!remainder.is_valid()) {
|
| - if ((left->is_register() && left->reg().is(edx)) ||
|
| - (right->is_register() && right->reg().is(edx))) {
|
| - Result fresh = cgen()->allocator()->Allocate();
|
| - ASSERT(fresh.is_valid());
|
| - if (left->is_register() && left->reg().is(edx)) {
|
| - remainder = *left;
|
| - *left = fresh;
|
| - }
|
| - if (right->is_register() && right->reg().is(edx)) {
|
| - remainder = *right;
|
| - *right = fresh;
|
| - }
|
| - __ mov(fresh.reg(), edx);
|
| - } else {
|
| - // Neither left nor right is in edx.
|
| - remainder = cgen()->allocator()->Allocate(edx);
|
| - }
|
| - }
|
| - ASSERT(remainder.is_register() && remainder.reg().is(edx));
|
| - ASSERT(!(left->is_register() && left->reg().is(edx)));
|
| - ASSERT(!(right->is_register() && right->reg().is(edx)));
|
| -
|
| - left->ToRegister();
|
| - right->ToRegister();
|
| - cgen()->frame()->Spill(quotient.reg());
|
| - cgen()->frame()->Spill(remainder.reg());
|
| -
|
| - // Check that left and right are smi tagged.
|
| - if (left->reg().is(right->reg())) {
|
| - __ test(left->reg(), Immediate(kSmiTagMask));
|
| - } else {
|
| - // Use the quotient register as a scratch for the tag check.
|
| - if (!left_is_in_eax) __ mov(quotient.reg(), left->reg());
|
| - left_is_in_eax = false;
|
| - __ or_(quotient.reg(), Operand(right->reg()));
|
| - ASSERT(kSmiTag == 0); // Adjust test if not the case.
|
| - __ test(quotient.reg(), Immediate(kSmiTagMask));
|
| - }
|
| - SetEntryFrame(left, right);
|
| - enter()->Branch(not_zero, left, right);
|
| -
|
| - if (!left_is_in_eax) __ mov(quotient.reg(), left->reg());
|
| -
|
| - // Sign extend eax into edx:eax.
|
| - __ cdq();
|
| - // Check for 0 divisor.
|
| - __ test(right->reg(), Operand(right->reg()));
|
| - enter()->Branch(zero, left, right);
|
| - // Divide edx:eax by the right operand.
|
| - __ idiv(right->reg());
|
| -
|
| - // Complete the operation.
|
| - if (op_ == Token::DIV) {
|
| - // Check for negative zero result. If result is zero, and divisor
|
| - // is negative, return a floating point negative zero. The
|
| - // virtual frame is unchanged in this block, so local control flow
|
| - // can use a Label rather than a JumpTarget.
|
| - Label non_zero_result;
|
| - __ test(left->reg(), Operand(left->reg()));
|
| - __ j(not_zero, &non_zero_result);
|
| - __ test(right->reg(), Operand(right->reg()));
|
| - enter()->Branch(negative, left, right);
|
| - __ bind(&non_zero_result);
|
| - // Check for the corner case of dividing the most negative smi by
|
| - // -1. We cannot use the overflow flag, since it is not set by
|
| - // idiv instruction.
|
| - ASSERT(kSmiTag == 0 && kSmiTagSize == 1);
|
| - __ cmp(quotient.reg(), 0x40000000);
|
| - enter()->Branch(equal, left, right);
|
| - // Check that the remainder is zero.
|
| - __ test(remainder.reg(), Operand(remainder.reg()));
|
| - enter()->Branch(not_zero, left, right);
|
| - left->Unuse();
|
| - right->Unuse();
|
| - // Tag the result and store it in the quotient register.
|
| - ASSERT(kSmiTagSize == times_2); // adjust code if not the case
|
| - __ lea(quotient.reg(),
|
| - Operand(quotient.reg(), quotient.reg(), times_1, kSmiTag));
|
| - return quotient;
|
| - } else {
|
| - ASSERT(op_ == Token::MOD);
|
| - // Check for a negative zero result. If the result is zero, and
|
| - // the dividend is negative, return a floating point negative
|
| - // zero. The frame is unchanged in this block, so local control
|
| - // flow can use a Label rather than a JumpTarget.
|
| - Label non_zero_result;
|
| - __ test(remainder.reg(), Operand(remainder.reg()));
|
| - __ j(not_zero, &non_zero_result, taken);
|
| - __ test(left->reg(), Operand(left->reg()));
|
| - enter()->Branch(negative, left, right);
|
| - left->Unuse();
|
| - right->Unuse();
|
| - __ bind(&non_zero_result);
|
| - return remainder;
|
| - }
|
| - }
|
| -
|
| - // Handle the other binary operations.
|
| - left->ToRegister();
|
| - right->ToRegister();
|
| - // A newly allocated register answer is used to hold the answer. The
|
| - // registers containing left and right are not modified in most cases,
|
| - // so they usually don't need to be spilled in the fast case.
|
| - Result answer = cgen()->allocator()->Allocate();
|
| -
|
| - ASSERT(answer.is_valid());
|
| - // Perform the smi tag check.
|
| - if (left->reg().is(right->reg())) {
|
| - __ test(left->reg(), Immediate(kSmiTagMask));
|
| - } else {
|
| - __ mov(answer.reg(), left->reg());
|
| - __ or_(answer.reg(), Operand(right->reg()));
|
| - ASSERT(kSmiTag == 0); // Adjust test if not the case.
|
| - __ test(answer.reg(), Immediate(kSmiTagMask));
|
| - }
|
| - switch (op_) {
|
| - case Token::ADD:
|
| - SetEntryFrame(left, right);
|
| - enter()->Branch(not_zero, left, right, not_taken);
|
| - __ mov(answer.reg(), left->reg());
|
| - __ add(answer.reg(), Operand(right->reg())); // Add optimistically.
|
| - enter()->Branch(overflow, left, right, not_taken);
|
| - break;
|
| -
|
| - case Token::SUB:
|
| - SetEntryFrame(left, right);
|
| - enter()->Branch(not_zero, left, right, not_taken);
|
| - __ mov(answer.reg(), left->reg());
|
| - __ sub(answer.reg(), Operand(right->reg())); // Subtract optimistically.
|
| - enter()->Branch(overflow, left, right, not_taken);
|
| - break;
|
| -
|
| - case Token::MUL: {
|
| - SetEntryFrame(left, right);
|
| - enter()->Branch(not_zero, left, right, not_taken);
|
| - __ mov(answer.reg(), left->reg());
|
| - // If the smi tag is 0 we can just leave the tag on one operand.
|
| - ASSERT(kSmiTag == 0); // Adjust code below if not the case.
|
| - // Remove smi tag from the left operand (but keep sign).
|
| - // Left-hand operand has been copied into answer.
|
| - __ sar(answer.reg(), kSmiTagSize);
|
| - // Do multiplication of smis, leaving result in answer.
|
| - __ imul(answer.reg(), Operand(right->reg()));
|
| - // Go slow on overflows.
|
| - enter()->Branch(overflow, left, right, not_taken);
|
| - // Check for negative zero result. If product is zero, and one
|
| - // argument is negative, go to slow case. The frame is unchanged
|
| - // in this block, so local control flow can use a Label rather
|
| - // than a JumpTarget.
|
| - Label non_zero_result;
|
| - __ test(answer.reg(), Operand(answer.reg()));
|
| - __ j(not_zero, &non_zero_result, taken);
|
| - __ mov(answer.reg(), left->reg());
|
| - __ or_(answer.reg(), Operand(right->reg()));
|
| - enter()->Branch(negative, left, right, not_taken);
|
| - __ xor_(answer.reg(), Operand(answer.reg())); // Positive 0 is correct.
|
| - __ bind(&non_zero_result);
|
| - break;
|
| - }
|
| -
|
| - case Token::BIT_OR:
|
| - enter()->Branch(not_zero, left, right, not_taken);
|
| - __ mov(answer.reg(), left->reg());
|
| - __ or_(answer.reg(), Operand(right->reg()));
|
| - break;
|
| -
|
| - case Token::BIT_AND:
|
| - enter()->Branch(not_zero, left, right, not_taken);
|
| - __ mov(answer.reg(), left->reg());
|
| - __ and_(answer.reg(), Operand(right->reg()));
|
| - break;
|
| -
|
| - case Token::BIT_XOR:
|
| - enter()->Branch(not_zero, left, right, not_taken);
|
| - __ mov(answer.reg(), left->reg());
|
| - __ xor_(answer.reg(), Operand(right->reg()));
|
| - break;
|
| -
|
| - case Token::SHL:
|
| - case Token::SHR:
|
| - case Token::SAR:
|
| - enter()->Branch(not_zero, left, right, not_taken);
|
| - __ mov(answer.reg(), left->reg());
|
| - // Move right into ecx.
|
| - // Left is in two registers already, so even if left or answer is ecx,
|
| - // we can move right to it, and use the other one.
|
| - // Right operand must be in register cl because x86 likes it that way.
|
| - if (right->reg().is(ecx)) {
|
| - // Right is already in the right place. Left may be in the
|
| - // same register, which causes problems. Always use answer
|
| - // instead of left, even if left is not ecx, since this avoids
|
| - // spilling left.
|
| - *left = answer;
|
| - } else if (left->reg().is(ecx)) {
|
| - cgen()->frame()->Spill(left->reg());
|
| - __ mov(left->reg(), right->reg());
|
| - *right = *left;
|
| - *left = answer; // Use copy of left in answer as left.
|
| - } else if (answer.reg().is(ecx)) {
|
| - __ mov(answer.reg(), right->reg());
|
| - *right = answer;
|
| - } else {
|
| - Result reg_ecx = cgen()->allocator()->Allocate(ecx);
|
| - ASSERT(reg_ecx.is_valid());
|
| - __ mov(ecx, right->reg());
|
| - *right = reg_ecx;
|
| - // Answer and left both contain the left operand. Use answer, so
|
| - // left is not spilled.
|
| - *left = answer;
|
| - }
|
| - ASSERT(left->reg().is_valid());
|
| - ASSERT(!left->reg().is(ecx));
|
| - ASSERT(right->reg().is(ecx));
|
| - answer.Unuse(); // Answer may now be being used for left or right.
|
| - // We will modify left and right, which we do not do in any other
|
| - // binary operation. The exits to slow code need to restore the
|
| - // original values of left and right, or at least values that give
|
| - // the same answer.
|
| -
|
| - // We are modifying left and right. They must be spilled!
|
| - cgen()->frame()->Spill(left->reg());
|
| - cgen()->frame()->Spill(right->reg());
|
| -
|
| - // Remove tags from operands (but keep sign).
|
| - __ sar(left->reg(), kSmiTagSize);
|
| - __ sar(ecx, kSmiTagSize);
|
| - // Perform the operation.
|
| - switch (op_) {
|
| - case Token::SAR:
|
| - __ sar(left->reg());
|
| - // No checks of result necessary
|
| - break;
|
| - case Token::SHR: {
|
| - __ shr(left->reg());
|
| - // Check that the *unsigned* result fits in a smi.
|
| - // Neither of the two high-order bits can be set:
|
| - // - 0x80000000: high bit would be lost when smi tagging.
|
| - // - 0x40000000: this number would convert to negative when
|
| - // Smi tagging these two cases can only happen with shifts
|
| - // by 0 or 1 when handed a valid smi.
|
| - // If the answer cannot be represented by a SMI, restore
|
| - // the left and right arguments, and jump to slow case.
|
| - // The low bit of the left argument may be lost, but only
|
| - // in a case where it is dropped anyway.
|
| - JumpTarget result_ok;
|
| - __ test(left->reg(), Immediate(0xc0000000));
|
| - result_ok.Branch(zero, left, taken);
|
| - __ shl(left->reg());
|
| - ASSERT(kSmiTag == 0);
|
| - __ shl(left->reg(), kSmiTagSize);
|
| - __ shl(right->reg(), kSmiTagSize);
|
| - enter()->Jump(left, right);
|
| - result_ok.Bind(left);
|
| - break;
|
| - }
|
| - case Token::SHL: {
|
| - __ shl(left->reg());
|
| - // Check that the *signed* result fits in a smi.
|
| - JumpTarget result_ok;
|
| - __ cmp(left->reg(), 0xc0000000);
|
| - result_ok.Branch(positive, left, taken);
|
| -
|
| - __ shr(left->reg());
|
| - ASSERT(kSmiTag == 0);
|
| - __ shl(left->reg(), kSmiTagSize);
|
| - __ shl(right->reg(), kSmiTagSize);
|
| - enter()->Jump(left, right);
|
| - result_ok.Bind(left);
|
| - break;
|
| - }
|
| - default:
|
| - UNREACHABLE();
|
| - }
|
| - // Smi-tag the result, in left, and make answer an alias for left->
|
| - answer = *left;
|
| - answer.ToRegister();
|
| - ASSERT(kSmiTagSize == times_2); // adjust code if not the case
|
| - __ lea(answer.reg(),
|
| - Operand(answer.reg(), answer.reg(), times_1, kSmiTag));
|
| - break;
|
| -
|
| - default:
|
| - UNREACHABLE();
|
| - break;
|
| - }
|
| - left->Unuse();
|
| - right->Unuse();
|
| - return answer;
|
| -}
|
| -
|
| -
|
| void GenericBinaryOpStub::GenerateSmiCode(MacroAssembler* masm, Label* slow) {
|
| // Perform fast-case smi code for the operation (eax <op> ebx) and
|
| // leave result in register eax.
|
|
|
Chromium Code Reviews
Issue 119037:
As a simplification, manually inline the function... (Closed)
Base URL: http://v8.googlecode.com/svn/branches/bleeding_edge/