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Issue 97543002: Refactor BinaryOpIC to be able to use different stubs. (Closed) Base URL: https://v8.googlecode.com/svn/branches/bleeding_edge
Patch Set: Drop unused ToHandlerState() function. Created 7 years ago
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1 // Copyright 2012 the V8 project authors. All rights reserved. 1 // Copyright 2012 the V8 project authors. All rights reserved.
2 // Redistribution and use in source and binary forms, with or without 2 // Redistribution and use in source and binary forms, with or without
3 // modification, are permitted provided that the following conditions are 3 // modification, are permitted provided that the following conditions are
4 // met: 4 // met:
5 // 5 //
6 // * Redistributions of source code must retain the above copyright 6 // * Redistributions of source code must retain the above copyright
7 // notice, this list of conditions and the following disclaimer. 7 // notice, this list of conditions and the following disclaimer.
8 // * Redistributions in binary form must reproduce the above 8 // * Redistributions in binary form must reproduce the above
9 // copyright notice, this list of conditions and the following 9 // copyright notice, this list of conditions and the following
10 // disclaimer in the documentation and/or other materials provided 10 // disclaimer in the documentation and/or other materials provided
(...skipping 2312 matching lines...) Expand 10 before | Expand all | Expand 10 after
2323 } 2323 }
2324 Handle<Object> result = Runtime::SetObjectProperty(isolate, object, key, 2324 Handle<Object> result = Runtime::SetObjectProperty(isolate, object, key,
2325 value, 2325 value,
2326 NONE, 2326 NONE,
2327 strict_mode); 2327 strict_mode);
2328 RETURN_IF_EMPTY_HANDLE(isolate, result); 2328 RETURN_IF_EMPTY_HANDLE(isolate, result);
2329 return *result; 2329 return *result;
2330 } 2330 }
2331 2331
2332 2332
2333 const char* BinaryOpIC::GetName(TypeInfo type_info) { 2333 BinaryOpIC::State::State(ExtraICState extra_ic_state) {
2334 switch (type_info) { 2334 // We don't deserialize the SSE2 Field, since this is only used to be able
2335 case UNINITIALIZED: return "Uninitialized"; 2335 // to include SSE2 as well as non-SSE2 versions in the snapshot. For code
2336 // generation we always want it to reflect the current state.
2337 op_ = static_cast<Token::Value>(
2338 FIRST_TOKEN + OpField::decode(extra_ic_state));
2339 mode_ = OverwriteModeField::decode(extra_ic_state);
2340 fixed_right_arg_ = Maybe<int>(
2341 HasFixedRightArgField::decode(extra_ic_state),
2342 1 << FixedRightArgValueField::decode(extra_ic_state));
2343 left_kind_ = LeftKindField::decode(extra_ic_state);
2344 if (fixed_right_arg_.has_value) {
2345 right_kind_ = Smi::IsValid(fixed_right_arg_.value) ? SMI : INT32;
2346 } else {
2347 right_kind_ = RightKindField::decode(extra_ic_state);
2348 }
2349 result_kind_ = ResultKindField::decode(extra_ic_state);
2350 ASSERT_LE(FIRST_TOKEN, op_);
2351 ASSERT_LE(op_, LAST_TOKEN);
2352 }
2353
2354
2355 ExtraICState BinaryOpIC::State::GetExtraICState() const {
2356 bool sse2 = (Max(result_kind_, Max(left_kind_, right_kind_)) > SMI &&
2357 CpuFeatures::IsSafeForSnapshot(SSE2));
2358 ExtraICState extra_ic_state =
2359 SSE2Field::encode(sse2) |
2360 OpField::encode(op_ - FIRST_TOKEN) |
2361 OverwriteModeField::encode(mode_) |
2362 LeftKindField::encode(left_kind_) |
2363 ResultKindField::encode(result_kind_) |
2364 HasFixedRightArgField::encode(fixed_right_arg_.has_value);
2365 if (fixed_right_arg_.has_value) {
2366 extra_ic_state = FixedRightArgValueField::update(
2367 extra_ic_state, WhichPowerOf2(fixed_right_arg_.value));
2368 } else {
2369 extra_ic_state = RightKindField::update(extra_ic_state, right_kind_);
2370 }
2371 return extra_ic_state;
2372 }
2373
2374
2375 // static
2376 void BinaryOpIC::State::GenerateAheadOfTime(
2377 Isolate* isolate, void (*Generate)(Isolate*, const State&)) {
2378 // TODO(olivf) We should investigate why adding stubs to the snapshot is so
2379 // expensive at runtime. When solved we should be able to add most binops to
2380 // the snapshot instead of hand-picking them.
2381 // Generated list of commonly used stubs
2382 #define GENERATE(op, left_kind, right_kind, result_kind, mode) \
2383 do { \
2384 State state(op, mode); \
2385 state.left_kind_ = left_kind; \
2386 state.fixed_right_arg_.has_value = false; \
2387 state.right_kind_ = right_kind; \
2388 state.result_kind_ = result_kind; \
2389 Generate(isolate, state); \
2390 } while (false)
2391 GENERATE(Token::ADD, INT32, INT32, INT32, NO_OVERWRITE);
2392 GENERATE(Token::ADD, INT32, INT32, INT32, OVERWRITE_LEFT);
2393 GENERATE(Token::ADD, INT32, INT32, NUMBER, NO_OVERWRITE);
2394 GENERATE(Token::ADD, INT32, INT32, NUMBER, OVERWRITE_LEFT);
2395 GENERATE(Token::ADD, INT32, NUMBER, NUMBER, NO_OVERWRITE);
2396 GENERATE(Token::ADD, INT32, NUMBER, NUMBER, OVERWRITE_LEFT);
2397 GENERATE(Token::ADD, INT32, NUMBER, NUMBER, OVERWRITE_RIGHT);
2398 GENERATE(Token::ADD, INT32, SMI, INT32, NO_OVERWRITE);
2399 GENERATE(Token::ADD, INT32, SMI, INT32, OVERWRITE_LEFT);
2400 GENERATE(Token::ADD, INT32, SMI, INT32, OVERWRITE_RIGHT);
2401 GENERATE(Token::ADD, NUMBER, INT32, NUMBER, NO_OVERWRITE);
2402 GENERATE(Token::ADD, NUMBER, INT32, NUMBER, OVERWRITE_LEFT);
2403 GENERATE(Token::ADD, NUMBER, INT32, NUMBER, OVERWRITE_RIGHT);
2404 GENERATE(Token::ADD, NUMBER, NUMBER, NUMBER, NO_OVERWRITE);
2405 GENERATE(Token::ADD, NUMBER, NUMBER, NUMBER, OVERWRITE_LEFT);
2406 GENERATE(Token::ADD, NUMBER, NUMBER, NUMBER, OVERWRITE_RIGHT);
2407 GENERATE(Token::ADD, NUMBER, SMI, NUMBER, NO_OVERWRITE);
2408 GENERATE(Token::ADD, NUMBER, SMI, NUMBER, OVERWRITE_LEFT);
2409 GENERATE(Token::ADD, NUMBER, SMI, NUMBER, OVERWRITE_RIGHT);
2410 GENERATE(Token::ADD, SMI, INT32, INT32, NO_OVERWRITE);
2411 GENERATE(Token::ADD, SMI, INT32, INT32, OVERWRITE_LEFT);
2412 GENERATE(Token::ADD, SMI, INT32, NUMBER, NO_OVERWRITE);
2413 GENERATE(Token::ADD, SMI, NUMBER, NUMBER, NO_OVERWRITE);
2414 GENERATE(Token::ADD, SMI, NUMBER, NUMBER, OVERWRITE_LEFT);
2415 GENERATE(Token::ADD, SMI, NUMBER, NUMBER, OVERWRITE_RIGHT);
2416 GENERATE(Token::ADD, SMI, SMI, INT32, OVERWRITE_LEFT);
2417 GENERATE(Token::ADD, SMI, SMI, SMI, OVERWRITE_RIGHT);
2418 GENERATE(Token::BIT_AND, INT32, INT32, INT32, NO_OVERWRITE);
2419 GENERATE(Token::BIT_AND, INT32, INT32, INT32, OVERWRITE_LEFT);
2420 GENERATE(Token::BIT_AND, INT32, INT32, INT32, OVERWRITE_RIGHT);
2421 GENERATE(Token::BIT_AND, INT32, INT32, SMI, NO_OVERWRITE);
2422 GENERATE(Token::BIT_AND, INT32, INT32, SMI, OVERWRITE_RIGHT);
2423 GENERATE(Token::BIT_AND, INT32, SMI, INT32, NO_OVERWRITE);
2424 GENERATE(Token::BIT_AND, INT32, SMI, INT32, OVERWRITE_RIGHT);
2425 GENERATE(Token::BIT_AND, INT32, SMI, SMI, NO_OVERWRITE);
2426 GENERATE(Token::BIT_AND, INT32, SMI, SMI, OVERWRITE_LEFT);
2427 GENERATE(Token::BIT_AND, INT32, SMI, SMI, OVERWRITE_RIGHT);
2428 GENERATE(Token::BIT_AND, NUMBER, INT32, INT32, OVERWRITE_RIGHT);
2429 GENERATE(Token::BIT_AND, NUMBER, SMI, SMI, NO_OVERWRITE);
2430 GENERATE(Token::BIT_AND, NUMBER, SMI, SMI, OVERWRITE_RIGHT);
2431 GENERATE(Token::BIT_AND, SMI, INT32, INT32, NO_OVERWRITE);
2432 GENERATE(Token::BIT_AND, SMI, INT32, SMI, OVERWRITE_RIGHT);
2433 GENERATE(Token::BIT_AND, SMI, NUMBER, SMI, OVERWRITE_RIGHT);
2434 GENERATE(Token::BIT_AND, SMI, SMI, SMI, NO_OVERWRITE);
2435 GENERATE(Token::BIT_AND, SMI, SMI, SMI, OVERWRITE_LEFT);
2436 GENERATE(Token::BIT_AND, SMI, SMI, SMI, OVERWRITE_RIGHT);
2437 GENERATE(Token::BIT_OR, INT32, INT32, INT32, OVERWRITE_LEFT);
2438 GENERATE(Token::BIT_OR, INT32, INT32, INT32, OVERWRITE_RIGHT);
2439 GENERATE(Token::BIT_OR, INT32, INT32, SMI, OVERWRITE_LEFT);
2440 GENERATE(Token::BIT_OR, INT32, SMI, INT32, NO_OVERWRITE);
2441 GENERATE(Token::BIT_OR, INT32, SMI, INT32, OVERWRITE_LEFT);
2442 GENERATE(Token::BIT_OR, INT32, SMI, INT32, OVERWRITE_RIGHT);
2443 GENERATE(Token::BIT_OR, INT32, SMI, SMI, NO_OVERWRITE);
2444 GENERATE(Token::BIT_OR, INT32, SMI, SMI, OVERWRITE_RIGHT);
2445 GENERATE(Token::BIT_OR, NUMBER, SMI, INT32, NO_OVERWRITE);
2446 GENERATE(Token::BIT_OR, NUMBER, SMI, INT32, OVERWRITE_LEFT);
2447 GENERATE(Token::BIT_OR, NUMBER, SMI, INT32, OVERWRITE_RIGHT);
2448 GENERATE(Token::BIT_OR, NUMBER, SMI, SMI, NO_OVERWRITE);
2449 GENERATE(Token::BIT_OR, NUMBER, SMI, SMI, OVERWRITE_LEFT);
2450 GENERATE(Token::BIT_OR, SMI, INT32, INT32, OVERWRITE_LEFT);
2451 GENERATE(Token::BIT_OR, SMI, INT32, INT32, OVERWRITE_RIGHT);
2452 GENERATE(Token::BIT_OR, SMI, INT32, SMI, OVERWRITE_RIGHT);
2453 GENERATE(Token::BIT_OR, SMI, SMI, SMI, OVERWRITE_LEFT);
2454 GENERATE(Token::BIT_OR, SMI, SMI, SMI, OVERWRITE_RIGHT);
2455 GENERATE(Token::BIT_XOR, INT32, INT32, INT32, NO_OVERWRITE);
2456 GENERATE(Token::BIT_XOR, INT32, INT32, INT32, OVERWRITE_LEFT);
2457 GENERATE(Token::BIT_XOR, INT32, INT32, INT32, OVERWRITE_RIGHT);
2458 GENERATE(Token::BIT_XOR, INT32, INT32, SMI, NO_OVERWRITE);
2459 GENERATE(Token::BIT_XOR, INT32, INT32, SMI, OVERWRITE_LEFT);
2460 GENERATE(Token::BIT_XOR, INT32, NUMBER, SMI, NO_OVERWRITE);
2461 GENERATE(Token::BIT_XOR, INT32, SMI, INT32, NO_OVERWRITE);
2462 GENERATE(Token::BIT_XOR, INT32, SMI, INT32, OVERWRITE_LEFT);
2463 GENERATE(Token::BIT_XOR, INT32, SMI, INT32, OVERWRITE_RIGHT);
2464 GENERATE(Token::BIT_XOR, NUMBER, INT32, INT32, NO_OVERWRITE);
2465 GENERATE(Token::BIT_XOR, NUMBER, SMI, INT32, NO_OVERWRITE);
2466 GENERATE(Token::BIT_XOR, NUMBER, SMI, SMI, NO_OVERWRITE);
2467 GENERATE(Token::BIT_XOR, SMI, INT32, INT32, NO_OVERWRITE);
2468 GENERATE(Token::BIT_XOR, SMI, INT32, INT32, OVERWRITE_LEFT);
2469 GENERATE(Token::BIT_XOR, SMI, INT32, SMI, OVERWRITE_LEFT);
2470 GENERATE(Token::BIT_XOR, SMI, SMI, SMI, NO_OVERWRITE);
2471 GENERATE(Token::BIT_XOR, SMI, SMI, SMI, OVERWRITE_LEFT);
2472 GENERATE(Token::BIT_XOR, SMI, SMI, SMI, OVERWRITE_RIGHT);
2473 GENERATE(Token::DIV, INT32, INT32, INT32, NO_OVERWRITE);
2474 GENERATE(Token::DIV, INT32, INT32, NUMBER, NO_OVERWRITE);
2475 GENERATE(Token::DIV, INT32, NUMBER, NUMBER, NO_OVERWRITE);
2476 GENERATE(Token::DIV, INT32, NUMBER, NUMBER, OVERWRITE_LEFT);
2477 GENERATE(Token::DIV, INT32, SMI, INT32, NO_OVERWRITE);
2478 GENERATE(Token::DIV, INT32, SMI, NUMBER, NO_OVERWRITE);
2479 GENERATE(Token::DIV, NUMBER, INT32, NUMBER, NO_OVERWRITE);
2480 GENERATE(Token::DIV, NUMBER, INT32, NUMBER, OVERWRITE_LEFT);
2481 GENERATE(Token::DIV, NUMBER, NUMBER, NUMBER, NO_OVERWRITE);
2482 GENERATE(Token::DIV, NUMBER, NUMBER, NUMBER, OVERWRITE_LEFT);
2483 GENERATE(Token::DIV, NUMBER, NUMBER, NUMBER, OVERWRITE_RIGHT);
2484 GENERATE(Token::DIV, NUMBER, SMI, NUMBER, NO_OVERWRITE);
2485 GENERATE(Token::DIV, NUMBER, SMI, NUMBER, OVERWRITE_LEFT);
2486 GENERATE(Token::DIV, SMI, INT32, INT32, NO_OVERWRITE);
2487 GENERATE(Token::DIV, SMI, INT32, NUMBER, NO_OVERWRITE);
2488 GENERATE(Token::DIV, SMI, INT32, NUMBER, OVERWRITE_LEFT);
2489 GENERATE(Token::DIV, SMI, NUMBER, NUMBER, NO_OVERWRITE);
2490 GENERATE(Token::DIV, SMI, NUMBER, NUMBER, OVERWRITE_LEFT);
2491 GENERATE(Token::DIV, SMI, NUMBER, NUMBER, OVERWRITE_RIGHT);
2492 GENERATE(Token::DIV, SMI, SMI, NUMBER, NO_OVERWRITE);
2493 GENERATE(Token::DIV, SMI, SMI, NUMBER, OVERWRITE_LEFT);
2494 GENERATE(Token::DIV, SMI, SMI, NUMBER, OVERWRITE_RIGHT);
2495 GENERATE(Token::DIV, SMI, SMI, SMI, NO_OVERWRITE);
2496 GENERATE(Token::DIV, SMI, SMI, SMI, OVERWRITE_LEFT);
2497 GENERATE(Token::DIV, SMI, SMI, SMI, OVERWRITE_RIGHT);
2498 GENERATE(Token::MOD, NUMBER, SMI, NUMBER, OVERWRITE_LEFT);
2499 GENERATE(Token::MOD, SMI, SMI, SMI, NO_OVERWRITE);
2500 GENERATE(Token::MOD, SMI, SMI, SMI, OVERWRITE_LEFT);
2501 GENERATE(Token::MUL, INT32, INT32, INT32, NO_OVERWRITE);
2502 GENERATE(Token::MUL, INT32, INT32, NUMBER, NO_OVERWRITE);
2503 GENERATE(Token::MUL, INT32, NUMBER, NUMBER, NO_OVERWRITE);
2504 GENERATE(Token::MUL, INT32, NUMBER, NUMBER, OVERWRITE_LEFT);
2505 GENERATE(Token::MUL, INT32, SMI, INT32, NO_OVERWRITE);
2506 GENERATE(Token::MUL, INT32, SMI, INT32, OVERWRITE_LEFT);
2507 GENERATE(Token::MUL, INT32, SMI, NUMBER, NO_OVERWRITE);
2508 GENERATE(Token::MUL, NUMBER, INT32, NUMBER, NO_OVERWRITE);
2509 GENERATE(Token::MUL, NUMBER, INT32, NUMBER, OVERWRITE_LEFT);
2510 GENERATE(Token::MUL, NUMBER, INT32, NUMBER, OVERWRITE_RIGHT);
2511 GENERATE(Token::MUL, NUMBER, NUMBER, NUMBER, NO_OVERWRITE);
2512 GENERATE(Token::MUL, NUMBER, NUMBER, NUMBER, OVERWRITE_LEFT);
2513 GENERATE(Token::MUL, NUMBER, SMI, NUMBER, NO_OVERWRITE);
2514 GENERATE(Token::MUL, NUMBER, SMI, NUMBER, OVERWRITE_LEFT);
2515 GENERATE(Token::MUL, NUMBER, SMI, NUMBER, OVERWRITE_RIGHT);
2516 GENERATE(Token::MUL, SMI, INT32, INT32, NO_OVERWRITE);
2517 GENERATE(Token::MUL, SMI, INT32, INT32, OVERWRITE_LEFT);
2518 GENERATE(Token::MUL, SMI, INT32, NUMBER, NO_OVERWRITE);
2519 GENERATE(Token::MUL, SMI, NUMBER, NUMBER, NO_OVERWRITE);
2520 GENERATE(Token::MUL, SMI, NUMBER, NUMBER, OVERWRITE_LEFT);
2521 GENERATE(Token::MUL, SMI, NUMBER, NUMBER, OVERWRITE_RIGHT);
2522 GENERATE(Token::MUL, SMI, SMI, INT32, NO_OVERWRITE);
2523 GENERATE(Token::MUL, SMI, SMI, NUMBER, NO_OVERWRITE);
2524 GENERATE(Token::MUL, SMI, SMI, NUMBER, OVERWRITE_LEFT);
2525 GENERATE(Token::MUL, SMI, SMI, SMI, NO_OVERWRITE);
2526 GENERATE(Token::MUL, SMI, SMI, SMI, OVERWRITE_LEFT);
2527 GENERATE(Token::MUL, SMI, SMI, SMI, OVERWRITE_RIGHT);
2528 GENERATE(Token::SAR, INT32, SMI, INT32, OVERWRITE_RIGHT);
2529 GENERATE(Token::SAR, INT32, SMI, SMI, NO_OVERWRITE);
2530 GENERATE(Token::SAR, INT32, SMI, SMI, OVERWRITE_RIGHT);
2531 GENERATE(Token::SAR, NUMBER, SMI, SMI, NO_OVERWRITE);
2532 GENERATE(Token::SAR, NUMBER, SMI, SMI, OVERWRITE_RIGHT);
2533 GENERATE(Token::SAR, SMI, SMI, SMI, OVERWRITE_LEFT);
2534 GENERATE(Token::SAR, SMI, SMI, SMI, OVERWRITE_RIGHT);
2535 GENERATE(Token::SHL, INT32, SMI, INT32, NO_OVERWRITE);
2536 GENERATE(Token::SHL, INT32, SMI, INT32, OVERWRITE_RIGHT);
2537 GENERATE(Token::SHL, INT32, SMI, SMI, NO_OVERWRITE);
2538 GENERATE(Token::SHL, INT32, SMI, SMI, OVERWRITE_RIGHT);
2539 GENERATE(Token::SHL, NUMBER, SMI, SMI, OVERWRITE_RIGHT);
2540 GENERATE(Token::SHL, SMI, SMI, INT32, NO_OVERWRITE);
2541 GENERATE(Token::SHL, SMI, SMI, INT32, OVERWRITE_LEFT);
2542 GENERATE(Token::SHL, SMI, SMI, INT32, OVERWRITE_RIGHT);
2543 GENERATE(Token::SHL, SMI, SMI, SMI, NO_OVERWRITE);
2544 GENERATE(Token::SHL, SMI, SMI, SMI, OVERWRITE_LEFT);
2545 GENERATE(Token::SHL, SMI, SMI, SMI, OVERWRITE_RIGHT);
2546 GENERATE(Token::SHR, INT32, SMI, SMI, NO_OVERWRITE);
2547 GENERATE(Token::SHR, INT32, SMI, SMI, OVERWRITE_LEFT);
2548 GENERATE(Token::SHR, INT32, SMI, SMI, OVERWRITE_RIGHT);
2549 GENERATE(Token::SHR, NUMBER, SMI, SMI, NO_OVERWRITE);
2550 GENERATE(Token::SHR, NUMBER, SMI, SMI, OVERWRITE_LEFT);
2551 GENERATE(Token::SHR, NUMBER, SMI, INT32, OVERWRITE_RIGHT);
2552 GENERATE(Token::SHR, SMI, SMI, SMI, NO_OVERWRITE);
2553 GENERATE(Token::SHR, SMI, SMI, SMI, OVERWRITE_LEFT);
2554 GENERATE(Token::SHR, SMI, SMI, SMI, OVERWRITE_RIGHT);
2555 GENERATE(Token::SUB, INT32, INT32, INT32, NO_OVERWRITE);
2556 GENERATE(Token::SUB, INT32, INT32, INT32, OVERWRITE_LEFT);
2557 GENERATE(Token::SUB, INT32, NUMBER, NUMBER, NO_OVERWRITE);
2558 GENERATE(Token::SUB, INT32, NUMBER, NUMBER, OVERWRITE_RIGHT);
2559 GENERATE(Token::SUB, INT32, SMI, INT32, OVERWRITE_LEFT);
2560 GENERATE(Token::SUB, INT32, SMI, INT32, OVERWRITE_RIGHT);
2561 GENERATE(Token::SUB, NUMBER, INT32, NUMBER, NO_OVERWRITE);
2562 GENERATE(Token::SUB, NUMBER, INT32, NUMBER, OVERWRITE_LEFT);
2563 GENERATE(Token::SUB, NUMBER, NUMBER, NUMBER, NO_OVERWRITE);
2564 GENERATE(Token::SUB, NUMBER, NUMBER, NUMBER, OVERWRITE_LEFT);
2565 GENERATE(Token::SUB, NUMBER, NUMBER, NUMBER, OVERWRITE_RIGHT);
2566 GENERATE(Token::SUB, NUMBER, SMI, NUMBER, NO_OVERWRITE);
2567 GENERATE(Token::SUB, NUMBER, SMI, NUMBER, OVERWRITE_LEFT);
2568 GENERATE(Token::SUB, NUMBER, SMI, NUMBER, OVERWRITE_RIGHT);
2569 GENERATE(Token::SUB, SMI, INT32, INT32, NO_OVERWRITE);
2570 GENERATE(Token::SUB, SMI, NUMBER, NUMBER, NO_OVERWRITE);
2571 GENERATE(Token::SUB, SMI, NUMBER, NUMBER, OVERWRITE_LEFT);
2572 GENERATE(Token::SUB, SMI, NUMBER, NUMBER, OVERWRITE_RIGHT);
2573 GENERATE(Token::SUB, SMI, SMI, SMI, NO_OVERWRITE);
2574 GENERATE(Token::SUB, SMI, SMI, SMI, OVERWRITE_LEFT);
2575 GENERATE(Token::SUB, SMI, SMI, SMI, OVERWRITE_RIGHT);
2576 #undef GENERATE
2577 #define GENERATE(op, left_kind, fixed_right_arg_value, result_kind, mode) \
2578 do { \
2579 State state(op, mode); \
2580 state.left_kind_ = left_kind; \
2581 state.fixed_right_arg_.has_value = true; \
2582 state.fixed_right_arg_.value = fixed_right_arg_value; \
2583 state.right_kind_ = SMI; \
2584 state.result_kind_ = result_kind; \
2585 Generate(isolate, state); \
2586 } while (false)
2587 GENERATE(Token::MOD, SMI, 2, SMI, NO_OVERWRITE);
2588 GENERATE(Token::MOD, SMI, 4, SMI, NO_OVERWRITE);
2589 GENERATE(Token::MOD, SMI, 4, SMI, OVERWRITE_LEFT);
2590 GENERATE(Token::MOD, SMI, 8, SMI, NO_OVERWRITE);
2591 GENERATE(Token::MOD, SMI, 16, SMI, OVERWRITE_LEFT);
2592 GENERATE(Token::MOD, SMI, 32, SMI, NO_OVERWRITE);
2593 GENERATE(Token::MOD, SMI, 2048, SMI, NO_OVERWRITE);
2594 #undef GENERATE
2595 }
2596
2597
2598 Handle<Type> BinaryOpIC::State::GetResultType(Isolate* isolate) const {
2599 Kind result_kind = result_kind_;
2600 if (HasSideEffects()) {
2601 result_kind = NONE;
2602 } else if (result_kind == GENERIC && op_ == Token::ADD) {
2603 return handle(Type::Union(handle(Type::Number(), isolate),
2604 handle(Type::String(), isolate)), isolate);
2605 } else if (result_kind == NUMBER && op_ == Token::SHR) {
2606 return handle(Type::Unsigned32(), isolate);
2607 }
2608 ASSERT_NE(GENERIC, result_kind);
2609 return KindToType(result_kind, isolate);
2610 }
2611
2612
2613 void BinaryOpIC::State::Print(StringStream* stream) const {
2614 stream->Add("(%s", Token::Name(op_));
2615 if (mode_ == OVERWRITE_LEFT) stream->Add("_ReuseLeft");
2616 else if (mode_ == OVERWRITE_RIGHT) stream->Add("_ReuseRight");
2617 stream->Add(":%s*", KindToString(left_kind_));
2618 if (fixed_right_arg_.has_value) {
2619 stream->Add("%d", fixed_right_arg_.value);
2620 } else {
2621 stream->Add("%s", KindToString(right_kind_));
2622 }
2623 stream->Add("->%s)", KindToString(result_kind_));
2624 }
2625
2626
2627 void BinaryOpIC::State::Update(Handle<Object> left,
2628 Handle<Object> right,
2629 Handle<Object> result) {
2630 ExtraICState old_extra_ic_state = GetExtraICState();
2631
2632 left_kind_ = UpdateKind(left, left_kind_);
2633 right_kind_ = UpdateKind(right, right_kind_);
2634
2635 int32_t fixed_right_arg_value;
2636 bool has_fixed_right_arg =
2637 op_ == Token::MOD &&
2638 right->ToInt32(&fixed_right_arg_value) &&
2639 fixed_right_arg_value > 0 &&
2640 IsPowerOf2(fixed_right_arg_value) &&
2641 FixedRightArgValueField::is_valid(fixed_right_arg_value) &&
2642 (left_kind_ == SMI || left_kind_ == INT32) &&
2643 (result_kind_ == NONE || !fixed_right_arg_.has_value);
2644 fixed_right_arg_ = Maybe<int32_t>(has_fixed_right_arg,
2645 fixed_right_arg_value);
2646
2647 result_kind_ = UpdateKind(result, result_kind_);
2648
2649 if (!Token::IsTruncatingBinaryOp(op_)) {
2650 Kind input_kind = Max(left_kind_, right_kind_);
2651 if (result_kind_ < input_kind && input_kind <= NUMBER) {
2652 result_kind_ = input_kind;
2653 }
2654 }
2655
2656 // Reset overwrite mode unless we can actually make use of it, or may be able
2657 // to make use of it at some point in the future.
2658 if ((mode_ == OVERWRITE_LEFT && left_kind_ > NUMBER) ||
2659 (mode_ == OVERWRITE_RIGHT && right_kind_ > NUMBER) ||
2660 result_kind_ > NUMBER) {
2661 mode_ = NO_OVERWRITE;
2662 }
2663
2664 if (old_extra_ic_state == GetExtraICState()) {
2665 // Tagged operations can lead to non-truncating HChanges
2666 if (left->IsUndefined() || left->IsBoolean()) {
2667 left_kind_ = GENERIC;
2668 } else if (right->IsUndefined() || right->IsBoolean()) {
2669 right_kind_ = GENERIC;
2670 } else {
2671 // Since the X87 is too precise, we might bail out on numbers which
2672 // actually would truncate with 64 bit precision.
2673 ASSERT(!CpuFeatures::IsSupported(SSE2));
2674 ASSERT(result_kind_ < NUMBER);
2675 result_kind_ = NUMBER;
2676 }
2677 }
2678 }
2679
2680
2681 BinaryOpIC::State::Kind BinaryOpIC::State::UpdateKind(Handle<Object> object,
2682 Kind kind) const {
2683 Kind new_kind = GENERIC;
2684 bool is_truncating = Token::IsTruncatingBinaryOp(op());
2685 if (object->IsBoolean() && is_truncating) {
2686 // Booleans will be automatically truncated by HChange.
2687 new_kind = INT32;
2688 } else if (object->IsUndefined()) {
2689 // Undefined will be automatically truncated by HChange.
2690 new_kind = is_truncating ? INT32 : NUMBER;
2691 } else if (object->IsSmi()) {
2692 new_kind = SMI;
2693 } else if (object->IsHeapNumber()) {
2694 double value = Handle<HeapNumber>::cast(object)->value();
2695 new_kind = TypeInfo::IsInt32Double(value) ? INT32 : NUMBER;
2696 } else if (object->IsString() && op() == Token::ADD) {
2697 new_kind = STRING;
2698 }
2699 if (new_kind == INT32 && SmiValuesAre32Bits()) {
2700 new_kind = NUMBER;
2701 }
2702 if (kind != NONE &&
2703 ((new_kind <= NUMBER && kind > NUMBER) ||
2704 (new_kind > NUMBER && kind <= NUMBER))) {
2705 new_kind = GENERIC;
2706 }
2707 return Max(kind, new_kind);
2708 }
2709
2710
2711 // static
2712 const char* BinaryOpIC::State::KindToString(Kind kind) {
2713 switch (kind) {
2714 case NONE: return "None";
2336 case SMI: return "Smi"; 2715 case SMI: return "Smi";
2337 case INT32: return "Int32"; 2716 case INT32: return "Int32";
2338 case NUMBER: return "Number"; 2717 case NUMBER: return "Number";
2339 case ODDBALL: return "Oddball";
2340 case STRING: return "String"; 2718 case STRING: return "String";
2341 case GENERIC: return "Generic"; 2719 case GENERIC: return "Generic";
2342 default: return "Invalid"; 2720 }
2343 } 2721 UNREACHABLE();
2722 return NULL;
2723 }
2724
2725
2726 // static
2727 Handle<Type> BinaryOpIC::State::KindToType(Kind kind, Isolate* isolate) {
2728 Type* type = NULL;
2729 switch (kind) {
2730 case NONE: type = Type::None(); break;
2731 case SMI: type = Type::Smi(); break;
2732 case INT32: type = Type::Signed32(); break;
2733 case NUMBER: type = Type::Number(); break;
2734 case STRING: type = Type::String(); break;
2735 case GENERIC: type = Type::Any(); break;
2736 }
2737 return handle(type, isolate);
2344 } 2738 }
2345 2739
2346 2740
2347 MaybeObject* BinaryOpIC::Transition(Handle<Object> left, Handle<Object> right) { 2741 MaybeObject* BinaryOpIC::Transition(Handle<Object> left, Handle<Object> right) {
2348 ExtraICState extra_ic_state = target()->extended_extra_ic_state(); 2742 State state(target()->extended_extra_ic_state());
2349 BinaryOpStub stub(extra_ic_state); 2743
2350 2744 // Compute the actual result using the builtin for the binary operation.
2351 Handle<Type> left_type = stub.GetLeftType(isolate()); 2745 Object* builtin = isolate()->js_builtins_object()->javascript_builtin(
2352 Handle<Type> right_type = stub.GetRightType(isolate()); 2746 TokenToJSBuiltin(state.op()));
2353 bool smi_was_enabled = left_type->Maybe(Type::Smi()) && 2747 Handle<JSFunction> function = handle(JSFunction::cast(builtin), isolate());
2354 right_type->Maybe(Type::Smi()); 2748 bool caught_exception;
2355 2749 Handle<Object> result = Execution::Call(
2356 Maybe<Handle<Object> > result = stub.Result(left, right, isolate()); 2750 isolate(), function, left, 1, &right, &caught_exception);
2357 if (!result.has_value) return Failure::Exception(); 2751 if (caught_exception) return Failure::Exception();
2752
2753 // Compute the new state.
2754 State old_state = state;
2755 state.Update(left, right, result);
2756
2757 // Install the new stub.
2758 BinaryOpICStub stub(state);
2759 set_target(*stub.GetCode(isolate()));
2358 2760
2359 if (FLAG_trace_ic) { 2761 if (FLAG_trace_ic) {
2360 char buffer[100]; 2762 char buffer[150];
2361 NoAllocationStringAllocator allocator(buffer, 2763 NoAllocationStringAllocator allocator(
2362 static_cast<unsigned>(sizeof(buffer))); 2764 buffer, static_cast<unsigned>(sizeof(buffer)));
2363 StringStream stream(&allocator); 2765 StringStream stream(&allocator);
2364 stream.Add("["); 2766 stream.Add("[BinaryOpIC");
2365 stub.PrintName(&stream); 2767 old_state.Print(&stream);
2366
2367 stub.UpdateStatus(left, right, result);
2368
2369 stream.Add(" => "); 2768 stream.Add(" => ");
2370 stub.PrintState(&stream); 2769 state.Print(&stream);
2371 stream.Add(" "); 2770 stream.Add(" @ %p <- ", static_cast<void*>(*target()));
2372 stream.OutputToStdOut(); 2771 stream.OutputToStdOut();
2373 PrintF(" @ %p <- ", static_cast<void*>(*stub.GetCode(isolate())));
2374 JavaScriptFrame::PrintTop(isolate(), stdout, false, true); 2772 JavaScriptFrame::PrintTop(isolate(), stdout, false, true);
2375 PrintF("]\n"); 2773 PrintF("]\n");
2376 } else { 2774 }
2377 stub.UpdateStatus(left, right, result); 2775
2378 } 2776 // Patch the inlined smi code as necessary.
2379 2777 if (!old_state.UseInlinedSmiCode() && state.UseInlinedSmiCode()) {
2380 Handle<Code> code = stub.GetCode(isolate());
2381 set_target(*code);
2382
2383 left_type = stub.GetLeftType(isolate());
2384 right_type = stub.GetRightType(isolate());
2385 bool enable_smi = left_type->Maybe(Type::Smi()) &&
2386 right_type->Maybe(Type::Smi());
2387
2388 if (!smi_was_enabled && enable_smi) {
2389 PatchInlinedSmiCode(address(), ENABLE_INLINED_SMI_CHECK); 2778 PatchInlinedSmiCode(address(), ENABLE_INLINED_SMI_CHECK);
2390 } else if (smi_was_enabled && !enable_smi) { 2779 } else if (old_state.UseInlinedSmiCode() && !state.UseInlinedSmiCode()) {
2391 PatchInlinedSmiCode(address(), DISABLE_INLINED_SMI_CHECK); 2780 PatchInlinedSmiCode(address(), DISABLE_INLINED_SMI_CHECK);
2392 } 2781 }
2393 2782
2394 ASSERT(result.has_value); 2783 return *result;
2395 return static_cast<MaybeObject*>(*result.value);
2396 } 2784 }
2397 2785
2398 2786
2399 RUNTIME_FUNCTION(MaybeObject*, BinaryOpIC_Miss) { 2787 RUNTIME_FUNCTION(MaybeObject*, BinaryOpIC_Miss) {
2400 HandleScope scope(isolate); 2788 HandleScope scope(isolate);
2401 Handle<Object> left = args.at<Object>(0); 2789 Handle<Object> left = args.at<Object>(BinaryOpICStub::kLeft);
2402 Handle<Object> right = args.at<Object>(1); 2790 Handle<Object> right = args.at<Object>(BinaryOpICStub::kRight);
2403 BinaryOpIC ic(isolate); 2791 BinaryOpIC ic(isolate);
2404 return ic.Transition(left, right); 2792 return ic.Transition(left, right);
2405 } 2793 }
2406 2794
2407 2795
2408 Code* CompareIC::GetRawUninitialized(Isolate* isolate, Token::Value op) { 2796 Code* CompareIC::GetRawUninitialized(Isolate* isolate, Token::Value op) {
2409 ICCompareStub stub(op, UNINITIALIZED, UNINITIALIZED, UNINITIALIZED); 2797 ICCompareStub stub(op, UNINITIALIZED, UNINITIALIZED, UNINITIALIZED);
2410 Code* code = NULL; 2798 Code* code = NULL;
2411 CHECK(stub.FindCodeInCache(&code, isolate)); 2799 CHECK(stub.FindCodeInCache(&code, isolate));
2412 return code; 2800 return code;
(...skipping 355 matching lines...) Expand 10 before | Expand all | Expand 10 after
2768 #undef ADDR 3156 #undef ADDR
2769 }; 3157 };
2770 3158
2771 3159
2772 Address IC::AddressFromUtilityId(IC::UtilityId id) { 3160 Address IC::AddressFromUtilityId(IC::UtilityId id) {
2773 return IC_utilities[id]; 3161 return IC_utilities[id];
2774 } 3162 }
2775 3163
2776 3164
2777 } } // namespace v8::internal 3165 } } // namespace v8::internal
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