v8/test/unittests/compiler/int64-lowering-unittest.cc

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// Copyright 2016 the V8 project authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "src/compiler/int64-lowering.h"
#include "src/compiler/common-operator.h"
#include "src/compiler/linkage.h"
#include "src/compiler/machine-operator.h"
#include "src/compiler/node.h"
#include "src/compiler/wasm-compiler.h"
#include "src/compiler/node-properties.h"
#include "src/objects-inl.h"
#include "src/signature.h"
#include "src/wasm/wasm-module.h"
#include "test/unittests/compiler/graph-unittest.h"
#include "test/unittests/compiler/node-test-utils.h"
#include "testing/gmock-support.h"
using testing::AllOf;
using testing::Capture;
using testing::CaptureEq;
namespace v8 {
namespace internal {
namespace compiler {
class Int64LoweringTest : public GraphTest {
public:
Int64LoweringTest()
: GraphTest(),
machine_(zone(), MachineRepresentation::kWord32,
MachineOperatorBuilder::Flag::kAllOptionalOps) {
value_[0] = 0x1234567890ABCDEF;
value_[1] = 0x1EDCBA098765432F;
value_[2] = 0x1133557799886644;
}
MachineOperatorBuilder* machine() { return &machine_; }
void LowerGraph(Node* node, Signature<MachineRepresentation>* signature) {
Node* zero = graph()->NewNode(common()->Int32Constant(0));
Node* ret = graph()->NewNode(common()->Return(), zero, node,
graph()->start(), graph()->start());
NodeProperties::MergeControlToEnd(graph(), common(), ret);
Int64Lowering lowering(graph(), machine(), common(), zone(), signature);
lowering.LowerGraph();
}
void LowerGraph(Node* node, MachineRepresentation return_type,
MachineRepresentation rep = MachineRepresentation::kWord32,
int num_params = 0) {
Signature<MachineRepresentation>::Builder sig_builder(zone(), 1,
num_params);
sig_builder.AddReturn(return_type);
for (int i = 0; i < num_params; i++) {
sig_builder.AddParam(rep);
}
LowerGraph(node, sig_builder.Build());
}
void CompareCallDescriptors(const CallDescriptor* lhs,
const CallDescriptor* rhs) {
EXPECT_THAT(lhs->CalleeSavedFPRegisters(), rhs->CalleeSavedFPRegisters());
EXPECT_THAT(lhs->CalleeSavedRegisters(), rhs->CalleeSavedRegisters());
EXPECT_THAT(lhs->FrameStateCount(), rhs->FrameStateCount());
EXPECT_THAT(lhs->InputCount(), rhs->InputCount());
for (size_t i = 0; i < lhs->InputCount(); i++) {
EXPECT_THAT(lhs->GetInputLocation(i), rhs->GetInputLocation(i));
EXPECT_THAT(lhs->GetInputType(i), rhs->GetInputType(i));
}
EXPECT_THAT(lhs->ReturnCount(), rhs->ReturnCount());
for (size_t i = 0; i < lhs->ReturnCount(); i++) {
EXPECT_THAT(lhs->GetReturnLocation(i), rhs->GetReturnLocation(i));
EXPECT_THAT(lhs->GetReturnType(i), rhs->GetReturnType(i));
}
EXPECT_THAT(lhs->flags(), rhs->flags());
EXPECT_THAT(lhs->kind(), rhs->kind());
}
int64_t value(int i) { return value_[i]; }
int32_t low_word_value(int i) {
return static_cast<int32_t>(value_[i] & 0xFFFFFFFF);
}
int32_t high_word_value(int i) {
return static_cast<int32_t>(value_[i] >> 32);
}
void TestComparison(
const Operator* op,
Matcher<Node*> (*high_word_matcher)(const Matcher<Node*>& lhs_matcher,
const Matcher<Node*>& rhs_matcher),
Matcher<Node*> (*low_word_matcher)(const Matcher<Node*>& lhs_matcher,
const Matcher<Node*>& rhs_matcher)) {
LowerGraph(
graph()->NewNode(op, Int64Constant(value(0)), Int64Constant(value(1))),
MachineRepresentation::kWord32);
EXPECT_THAT(
graph()->end()->InputAt(1),
IsReturn(IsWord32Or(
high_word_matcher(IsInt32Constant(high_word_value(0)),
IsInt32Constant(high_word_value(1))),
IsWord32And(
IsWord32Equal(IsInt32Constant(high_word_value(0)),
IsInt32Constant(high_word_value(1))),
low_word_matcher(IsInt32Constant(low_word_value(0)),
IsInt32Constant(low_word_value(1))))),
start(), start()));
}
private:
MachineOperatorBuilder machine_;
int64_t value_[3];
};
TEST_F(Int64LoweringTest, Int64Constant) {
LowerGraph(Int64Constant(value(0)), MachineRepresentation::kWord64);
EXPECT_THAT(graph()->end()->InputAt(1),
IsReturn2(IsInt32Constant(low_word_value(0)),
IsInt32Constant(high_word_value(0)), start(), start()));
}
#if defined(V8_TARGET_LITTLE_ENDIAN)
#define LOAD_VERIFY(kLoad) \
Matcher<Node*> high_word_load_matcher = \
Is##kLoad(MachineType::Int32(), IsInt32Constant(base), \
IsInt32Add(IsInt32Constant(index), IsInt32Constant(0x4)), \
start(), start()); \
\
EXPECT_THAT( \
graph()->end()->InputAt(1), \
IsReturn2( \
Is##kLoad(MachineType::Int32(), IsInt32Constant(base), \
IsInt32Constant(index), \
AllOf(CaptureEq(&high_word_load), high_word_load_matcher), \
start()), \
AllOf(CaptureEq(&high_word_load), high_word_load_matcher), start(), \
start()));
#elif defined(V8_TARGET_BIG_ENDIAN)
#define LOAD_VERIFY(kLoad) \
Matcher<Node*> high_word_load_matcher = \
Is##kLoad(MachineType::Int32(), IsInt32Constant(base), \
IsInt32Constant(index), start(), start()); \
\
EXPECT_THAT( \
graph()->end()->InputAt(1), \
IsReturn2( \
Is##kLoad(MachineType::Int32(), IsInt32Constant(base), \
IsInt32Add(IsInt32Constant(index), IsInt32Constant(0x4)), \
AllOf(CaptureEq(&high_word_load), high_word_load_matcher), \
start()), \
AllOf(CaptureEq(&high_word_load), high_word_load_matcher), start(), \
start()));
#endif
#define INT64_LOAD_LOWERING(kLoad) \
int32_t base = 0x1234; \
int32_t index = 0x5678; \
\
LowerGraph(graph()->NewNode(machine()->kLoad(MachineType::Int64()), \
Int32Constant(base), Int32Constant(index), \
start(), start()), \
MachineRepresentation::kWord64); \
\
Capture<Node*> high_word_load; \
LOAD_VERIFY(kLoad)
TEST_F(Int64LoweringTest, Int64Load) { INT64_LOAD_LOWERING(Load); }
TEST_F(Int64LoweringTest, UnalignedInt64Load) {
INT64_LOAD_LOWERING(UnalignedLoad);
}
#if defined(V8_TARGET_LITTLE_ENDIAN)
#define STORE_VERIFY(kStore, kRep) \
EXPECT_THAT( \
graph()->end()->InputAt(1), \
IsReturn(IsInt32Constant(return_value), \
Is##kStore( \
kRep, IsInt32Constant(base), IsInt32Constant(index), \
IsInt32Constant(low_word_value(0)), \
Is##kStore( \
kRep, IsInt32Constant(base), \
IsInt32Add(IsInt32Constant(index), IsInt32Constant(4)), \
IsInt32Constant(high_word_value(0)), start(), start()), \
start()), \
start()));
#elif defined(V8_TARGET_BIG_ENDIAN)
#define STORE_VERIFY(kStore, kRep) \
EXPECT_THAT( \
graph()->end()->InputAt(1), \
IsReturn(IsInt32Constant(return_value), \
Is##kStore( \
kRep, IsInt32Constant(base), \
IsInt32Add(IsInt32Constant(index), IsInt32Constant(4)), \
IsInt32Constant(low_word_value(0)), \
Is##kStore( \
kRep, IsInt32Constant(base), IsInt32Constant(index), \
IsInt32Constant(high_word_value(0)), start(), start()), \
start()), \
start()));
#endif
#define INT64_STORE_LOWERING(kStore, kRep32, kRep64) \
int32_t base = 1111; \
int32_t index = 2222; \
int32_t return_value = 0x5555; \
\
Signature<MachineRepresentation>::Builder sig_builder(zone(), 1, 0); \
sig_builder.AddReturn(MachineRepresentation::kWord32); \
\
Node* store = graph()->NewNode(machine()->kStore(kRep64), \
Int32Constant(base), Int32Constant(index), \
Int64Constant(value(0)), start(), start()); \
\
Node* zero = graph()->NewNode(common()->Int32Constant(0)); \
Node* ret = graph()->NewNode(common()->Return(), zero, \
Int32Constant(return_value), store, start()); \
\
NodeProperties::MergeControlToEnd(graph(), common(), ret); \
\
Int64Lowering lowering(graph(), machine(), common(), zone(), \
sig_builder.Build()); \
lowering.LowerGraph(); \
\
STORE_VERIFY(kStore, kRep32)
TEST_F(Int64LoweringTest, Int64Store) {
const StoreRepresentation rep64(MachineRepresentation::kWord64,
WriteBarrierKind::kNoWriteBarrier);
const StoreRepresentation rep32(MachineRepresentation::kWord32,
WriteBarrierKind::kNoWriteBarrier);
INT64_STORE_LOWERING(Store, rep32, rep64);
}
TEST_F(Int64LoweringTest, Int32Store) {
const StoreRepresentation rep32(MachineRepresentation::kWord32,
WriteBarrierKind::kNoWriteBarrier);
int32_t base = 1111;
int32_t index = 2222;
int32_t return_value = 0x5555;
Signature<MachineRepresentation>::Builder sig_builder(zone(), 1, 0);
sig_builder.AddReturn(MachineRepresentation::kWord32);
Node* store = graph()->NewNode(machine()->Store(rep32), Int32Constant(base),
Int32Constant(index), Int64Constant(value(0)),
start(), start());
Node* zero = graph()->NewNode(common()->Int32Constant(0));
Node* ret = graph()->NewNode(common()->Return(), zero,
Int32Constant(return_value), store, start());
NodeProperties::MergeControlToEnd(graph(), common(), ret);
Int64Lowering lowering(graph(), machine(), common(), zone(),
sig_builder.Build());
lowering.LowerGraph();
EXPECT_THAT(
graph()->end()->InputAt(1),
IsReturn(IsInt32Constant(return_value),
IsStore(rep32, IsInt32Constant(base), IsInt32Constant(index),
IsInt32Constant(low_word_value(0)), start(), start()),
start()));
}
TEST_F(Int64LoweringTest, Int64UnalignedStore) {
const UnalignedStoreRepresentation rep64(MachineRepresentation::kWord64);
const UnalignedStoreRepresentation rep32(MachineRepresentation::kWord32);
INT64_STORE_LOWERING(UnalignedStore, rep32, rep64);
}
TEST_F(Int64LoweringTest, Int64And) {
LowerGraph(graph()->NewNode(machine()->Word64And(), Int64Constant(value(0)),
Int64Constant(value(1))),
MachineRepresentation::kWord64);
EXPECT_THAT(graph()->end()->InputAt(1),
IsReturn2(IsWord32And(IsInt32Constant(low_word_value(0)),
IsInt32Constant(low_word_value(1))),
IsWord32And(IsInt32Constant(high_word_value(0)),
IsInt32Constant(high_word_value(1))),
start(), start()));
}
TEST_F(Int64LoweringTest, TruncateInt64ToInt32) {
LowerGraph(graph()->NewNode(machine()->TruncateInt64ToInt32(),
Int64Constant(value(0))),
MachineRepresentation::kWord32);
EXPECT_THAT(graph()->end()->InputAt(1),
IsReturn(IsInt32Constant(low_word_value(0)), start(), start()));
}
TEST_F(Int64LoweringTest, Parameter) {
[wasm] Introduce the WasmContext The WasmContext struct introduced in this CL is used to store the mem_size and mem_start address of the wasm memory. These variables can be accessed at C++ level at graph build time (e.g., initialized during instance building). When the GrowMemory runtime is invoked, the context variables can be changed in the WasmContext at C++ level so that the generated code will load the correct values. This requires to insert a relocatable pointer only in the JSToWasmWrapper (and in the other wasm entry points), the value is then passed from function to function as an automatically added additional parameter. The WasmContext is then dropped when creating an Interpreter Entry or when invoking a JavaScript function. This removes the need of patching the generated code at runtime (i.e., when the memory grows) with respect to WASM_MEMORY_REFERENCE and WASM_MEMORY_SIZE_REFERENCE. However, we still need to patch the code at instance build time to patch the JSToWasmWrappers; in fact the address of the WasmContext is not known during compilation, but only when the instance is built. The WasmContext address is passed as the first parameter. This has the advantage of not having to move the WasmContext around if the function does not use many registers. This CL also changes the wasm calling convention so that the first parameter register is different from the return value register. The WasmContext is attached to every WasmMemoryObject, to share the same context with multiple instances sharing the same memory. Moreover, the nodes representing the WasmContext variables are cached in the SSA environment, similarly to other local variables that might change during execution. The nodes are created when initializing the SSA environment and refreshed every time a grow_memory or a function call happens, so that we are sure that they always represent the correct mem_size and mem_start variables. This CL also removes the WasmMemorySize runtime (since it's now possible to directly retrieve mem_size from the context) and simplifies the GrowMemory runtime (since every instance now has a memory_object). R=ahaas@chromium.org,clemensh@chromium.org CC=gdeepti@chromium.org Change-Id: I3f058e641284f5a1bbbfc35a64c88da6ff08e240 Reviewed-on: https://chromium-review.googlesource.com/671008 Commit-Queue: Enrico Bacis <enricobacis@google.com> Reviewed-by: Clemens Hammacher <clemensh@chromium.org> Reviewed-by: Andreas Haas <ahaas@chromium.org> Cr-Commit-Position: refs/heads/master@{#48209}
2017-09-28 14:59:37 +00:00
LowerGraph(Parameter(1), MachineRepresentation::kWord64,
MachineRepresentation::kWord64, 1);
EXPECT_THAT(graph()->end()->InputAt(1),
[wasm] Introduce the WasmContext The WasmContext struct introduced in this CL is used to store the mem_size and mem_start address of the wasm memory. These variables can be accessed at C++ level at graph build time (e.g., initialized during instance building). When the GrowMemory runtime is invoked, the context variables can be changed in the WasmContext at C++ level so that the generated code will load the correct values. This requires to insert a relocatable pointer only in the JSToWasmWrapper (and in the other wasm entry points), the value is then passed from function to function as an automatically added additional parameter. The WasmContext is then dropped when creating an Interpreter Entry or when invoking a JavaScript function. This removes the need of patching the generated code at runtime (i.e., when the memory grows) with respect to WASM_MEMORY_REFERENCE and WASM_MEMORY_SIZE_REFERENCE. However, we still need to patch the code at instance build time to patch the JSToWasmWrappers; in fact the address of the WasmContext is not known during compilation, but only when the instance is built. The WasmContext address is passed as the first parameter. This has the advantage of not having to move the WasmContext around if the function does not use many registers. This CL also changes the wasm calling convention so that the first parameter register is different from the return value register. The WasmContext is attached to every WasmMemoryObject, to share the same context with multiple instances sharing the same memory. Moreover, the nodes representing the WasmContext variables are cached in the SSA environment, similarly to other local variables that might change during execution. The nodes are created when initializing the SSA environment and refreshed every time a grow_memory or a function call happens, so that we are sure that they always represent the correct mem_size and mem_start variables. This CL also removes the WasmMemorySize runtime (since it's now possible to directly retrieve mem_size from the context) and simplifies the GrowMemory runtime (since every instance now has a memory_object). R=ahaas@chromium.org,clemensh@chromium.org CC=gdeepti@chromium.org Change-Id: I3f058e641284f5a1bbbfc35a64c88da6ff08e240 Reviewed-on: https://chromium-review.googlesource.com/671008 Commit-Queue: Enrico Bacis <enricobacis@google.com> Reviewed-by: Clemens Hammacher <clemensh@chromium.org> Reviewed-by: Andreas Haas <ahaas@chromium.org> Cr-Commit-Position: refs/heads/master@{#48209}
2017-09-28 14:59:37 +00:00
IsReturn2(IsParameter(1), IsParameter(2), start(), start()));
}
TEST_F(Int64LoweringTest, Parameter2) {
Signature<MachineRepresentation>::Builder sig_builder(zone(), 1, 5);
sig_builder.AddReturn(MachineRepresentation::kWord32);
sig_builder.AddParam(MachineRepresentation::kWord32);
sig_builder.AddParam(MachineRepresentation::kWord64);
sig_builder.AddParam(MachineRepresentation::kFloat64);
sig_builder.AddParam(MachineRepresentation::kWord64);
sig_builder.AddParam(MachineRepresentation::kWord32);
int start_parameter = start()->op()->ValueOutputCount();
[wasm] Introduce the WasmContext The WasmContext struct introduced in this CL is used to store the mem_size and mem_start address of the wasm memory. These variables can be accessed at C++ level at graph build time (e.g., initialized during instance building). When the GrowMemory runtime is invoked, the context variables can be changed in the WasmContext at C++ level so that the generated code will load the correct values. This requires to insert a relocatable pointer only in the JSToWasmWrapper (and in the other wasm entry points), the value is then passed from function to function as an automatically added additional parameter. The WasmContext is then dropped when creating an Interpreter Entry or when invoking a JavaScript function. This removes the need of patching the generated code at runtime (i.e., when the memory grows) with respect to WASM_MEMORY_REFERENCE and WASM_MEMORY_SIZE_REFERENCE. However, we still need to patch the code at instance build time to patch the JSToWasmWrappers; in fact the address of the WasmContext is not known during compilation, but only when the instance is built. The WasmContext address is passed as the first parameter. This has the advantage of not having to move the WasmContext around if the function does not use many registers. This CL also changes the wasm calling convention so that the first parameter register is different from the return value register. The WasmContext is attached to every WasmMemoryObject, to share the same context with multiple instances sharing the same memory. Moreover, the nodes representing the WasmContext variables are cached in the SSA environment, similarly to other local variables that might change during execution. The nodes are created when initializing the SSA environment and refreshed every time a grow_memory or a function call happens, so that we are sure that they always represent the correct mem_size and mem_start variables. This CL also removes the WasmMemorySize runtime (since it's now possible to directly retrieve mem_size from the context) and simplifies the GrowMemory runtime (since every instance now has a memory_object). R=ahaas@chromium.org,clemensh@chromium.org CC=gdeepti@chromium.org Change-Id: I3f058e641284f5a1bbbfc35a64c88da6ff08e240 Reviewed-on: https://chromium-review.googlesource.com/671008 Commit-Queue: Enrico Bacis <enricobacis@google.com> Reviewed-by: Clemens Hammacher <clemensh@chromium.org> Reviewed-by: Andreas Haas <ahaas@chromium.org> Cr-Commit-Position: refs/heads/master@{#48209}
2017-09-28 14:59:37 +00:00
LowerGraph(Parameter(5), sig_builder.Build());
EXPECT_THAT(graph()->end()->InputAt(1),
[wasm] Introduce the WasmContext The WasmContext struct introduced in this CL is used to store the mem_size and mem_start address of the wasm memory. These variables can be accessed at C++ level at graph build time (e.g., initialized during instance building). When the GrowMemory runtime is invoked, the context variables can be changed in the WasmContext at C++ level so that the generated code will load the correct values. This requires to insert a relocatable pointer only in the JSToWasmWrapper (and in the other wasm entry points), the value is then passed from function to function as an automatically added additional parameter. The WasmContext is then dropped when creating an Interpreter Entry or when invoking a JavaScript function. This removes the need of patching the generated code at runtime (i.e., when the memory grows) with respect to WASM_MEMORY_REFERENCE and WASM_MEMORY_SIZE_REFERENCE. However, we still need to patch the code at instance build time to patch the JSToWasmWrappers; in fact the address of the WasmContext is not known during compilation, but only when the instance is built. The WasmContext address is passed as the first parameter. This has the advantage of not having to move the WasmContext around if the function does not use many registers. This CL also changes the wasm calling convention so that the first parameter register is different from the return value register. The WasmContext is attached to every WasmMemoryObject, to share the same context with multiple instances sharing the same memory. Moreover, the nodes representing the WasmContext variables are cached in the SSA environment, similarly to other local variables that might change during execution. The nodes are created when initializing the SSA environment and refreshed every time a grow_memory or a function call happens, so that we are sure that they always represent the correct mem_size and mem_start variables. This CL also removes the WasmMemorySize runtime (since it's now possible to directly retrieve mem_size from the context) and simplifies the GrowMemory runtime (since every instance now has a memory_object). R=ahaas@chromium.org,clemensh@chromium.org CC=gdeepti@chromium.org Change-Id: I3f058e641284f5a1bbbfc35a64c88da6ff08e240 Reviewed-on: https://chromium-review.googlesource.com/671008 Commit-Queue: Enrico Bacis <enricobacis@google.com> Reviewed-by: Clemens Hammacher <clemensh@chromium.org> Reviewed-by: Andreas Haas <ahaas@chromium.org> Cr-Commit-Position: refs/heads/master@{#48209}
2017-09-28 14:59:37 +00:00
IsReturn(IsParameter(7), start(), start()));
// The parameter of the start node should increase by 2, because we lowered
// two parameter nodes.
EXPECT_THAT(start()->op()->ValueOutputCount(), start_parameter + 2);
}
[wasm] Introduce the WasmContext The WasmContext struct introduced in this CL is used to store the mem_size and mem_start address of the wasm memory. These variables can be accessed at C++ level at graph build time (e.g., initialized during instance building). When the GrowMemory runtime is invoked, the context variables can be changed in the WasmContext at C++ level so that the generated code will load the correct values. This requires to insert a relocatable pointer only in the JSToWasmWrapper (and in the other wasm entry points), the value is then passed from function to function as an automatically added additional parameter. The WasmContext is then dropped when creating an Interpreter Entry or when invoking a JavaScript function. This removes the need of patching the generated code at runtime (i.e., when the memory grows) with respect to WASM_MEMORY_REFERENCE and WASM_MEMORY_SIZE_REFERENCE. However, we still need to patch the code at instance build time to patch the JSToWasmWrappers; in fact the address of the WasmContext is not known during compilation, but only when the instance is built. The WasmContext address is passed as the first parameter. This has the advantage of not having to move the WasmContext around if the function does not use many registers. This CL also changes the wasm calling convention so that the first parameter register is different from the return value register. The WasmContext is attached to every WasmMemoryObject, to share the same context with multiple instances sharing the same memory. Moreover, the nodes representing the WasmContext variables are cached in the SSA environment, similarly to other local variables that might change during execution. The nodes are created when initializing the SSA environment and refreshed every time a grow_memory or a function call happens, so that we are sure that they always represent the correct mem_size and mem_start variables. This CL also removes the WasmMemorySize runtime (since it's now possible to directly retrieve mem_size from the context) and simplifies the GrowMemory runtime (since every instance now has a memory_object). R=ahaas@chromium.org,clemensh@chromium.org CC=gdeepti@chromium.org Change-Id: I3f058e641284f5a1bbbfc35a64c88da6ff08e240 Reviewed-on: https://chromium-review.googlesource.com/671008 Commit-Queue: Enrico Bacis <enricobacis@google.com> Reviewed-by: Clemens Hammacher <clemensh@chromium.org> Reviewed-by: Andreas Haas <ahaas@chromium.org> Cr-Commit-Position: refs/heads/master@{#48209}
2017-09-28 14:59:37 +00:00
// The following tests assume that pointers are 32 bit and therefore pointers do
// not get lowered. This assumption does not hold on 64 bit platforms, which
// invalidates these tests.
// TODO(wasm): We can find an alternative to re-activate these tests.
#if V8_TARGET_ARCH_32_BIT
TEST_F(Int64LoweringTest, CallI64Return) {
int32_t function = 0x9999;
[wasm] Introduce the WasmContext The WasmContext struct introduced in this CL is used to store the mem_size and mem_start address of the wasm memory. These variables can be accessed at C++ level at graph build time (e.g., initialized during instance building). When the GrowMemory runtime is invoked, the context variables can be changed in the WasmContext at C++ level so that the generated code will load the correct values. This requires to insert a relocatable pointer only in the JSToWasmWrapper (and in the other wasm entry points), the value is then passed from function to function as an automatically added additional parameter. The WasmContext is then dropped when creating an Interpreter Entry or when invoking a JavaScript function. This removes the need of patching the generated code at runtime (i.e., when the memory grows) with respect to WASM_MEMORY_REFERENCE and WASM_MEMORY_SIZE_REFERENCE. However, we still need to patch the code at instance build time to patch the JSToWasmWrappers; in fact the address of the WasmContext is not known during compilation, but only when the instance is built. The WasmContext address is passed as the first parameter. This has the advantage of not having to move the WasmContext around if the function does not use many registers. This CL also changes the wasm calling convention so that the first parameter register is different from the return value register. The WasmContext is attached to every WasmMemoryObject, to share the same context with multiple instances sharing the same memory. Moreover, the nodes representing the WasmContext variables are cached in the SSA environment, similarly to other local variables that might change during execution. The nodes are created when initializing the SSA environment and refreshed every time a grow_memory or a function call happens, so that we are sure that they always represent the correct mem_size and mem_start variables. This CL also removes the WasmMemorySize runtime (since it's now possible to directly retrieve mem_size from the context) and simplifies the GrowMemory runtime (since every instance now has a memory_object). R=ahaas@chromium.org,clemensh@chromium.org CC=gdeepti@chromium.org Change-Id: I3f058e641284f5a1bbbfc35a64c88da6ff08e240 Reviewed-on: https://chromium-review.googlesource.com/671008 Commit-Queue: Enrico Bacis <enricobacis@google.com> Reviewed-by: Clemens Hammacher <clemensh@chromium.org> Reviewed-by: Andreas Haas <ahaas@chromium.org> Cr-Commit-Position: refs/heads/master@{#48209}
2017-09-28 14:59:37 +00:00
Node* context_address = Int32Constant(0);
Signature<MachineRepresentation>::Builder sig_builder(zone(), 1, 0);
sig_builder.AddReturn(MachineRepresentation::kWord64);
compiler::CallDescriptor* desc =
compiler::GetWasmCallDescriptor(zone(), sig_builder.Build());
LowerGraph(graph()->NewNode(common()->Call(desc), Int32Constant(function),
[wasm] Introduce the WasmContext The WasmContext struct introduced in this CL is used to store the mem_size and mem_start address of the wasm memory. These variables can be accessed at C++ level at graph build time (e.g., initialized during instance building). When the GrowMemory runtime is invoked, the context variables can be changed in the WasmContext at C++ level so that the generated code will load the correct values. This requires to insert a relocatable pointer only in the JSToWasmWrapper (and in the other wasm entry points), the value is then passed from function to function as an automatically added additional parameter. The WasmContext is then dropped when creating an Interpreter Entry or when invoking a JavaScript function. This removes the need of patching the generated code at runtime (i.e., when the memory grows) with respect to WASM_MEMORY_REFERENCE and WASM_MEMORY_SIZE_REFERENCE. However, we still need to patch the code at instance build time to patch the JSToWasmWrappers; in fact the address of the WasmContext is not known during compilation, but only when the instance is built. The WasmContext address is passed as the first parameter. This has the advantage of not having to move the WasmContext around if the function does not use many registers. This CL also changes the wasm calling convention so that the first parameter register is different from the return value register. The WasmContext is attached to every WasmMemoryObject, to share the same context with multiple instances sharing the same memory. Moreover, the nodes representing the WasmContext variables are cached in the SSA environment, similarly to other local variables that might change during execution. The nodes are created when initializing the SSA environment and refreshed every time a grow_memory or a function call happens, so that we are sure that they always represent the correct mem_size and mem_start variables. This CL also removes the WasmMemorySize runtime (since it's now possible to directly retrieve mem_size from the context) and simplifies the GrowMemory runtime (since every instance now has a memory_object). R=ahaas@chromium.org,clemensh@chromium.org CC=gdeepti@chromium.org Change-Id: I3f058e641284f5a1bbbfc35a64c88da6ff08e240 Reviewed-on: https://chromium-review.googlesource.com/671008 Commit-Queue: Enrico Bacis <enricobacis@google.com> Reviewed-by: Clemens Hammacher <clemensh@chromium.org> Reviewed-by: Andreas Haas <ahaas@chromium.org> Cr-Commit-Position: refs/heads/master@{#48209}
2017-09-28 14:59:37 +00:00
context_address, start(), start()),
MachineRepresentation::kWord64);
Capture<Node*> call;
Matcher<Node*> call_matcher =
IsCall(testing::_, IsInt32Constant(function), start(), start());
EXPECT_THAT(graph()->end()->InputAt(1),
IsReturn2(IsProjection(0, AllOf(CaptureEq(&call), call_matcher)),
IsProjection(1, AllOf(CaptureEq(&call), call_matcher)),
start(), start()));
CompareCallDescriptors(
OpParameter<const CallDescriptor*>(
graph()->end()->InputAt(1)->InputAt(1)->InputAt(0)),
compiler::GetI32WasmCallDescriptor(zone(), desc));
}
TEST_F(Int64LoweringTest, CallI64Parameter) {
int32_t function = 0x9999;
[wasm] Introduce the WasmContext The WasmContext struct introduced in this CL is used to store the mem_size and mem_start address of the wasm memory. These variables can be accessed at C++ level at graph build time (e.g., initialized during instance building). When the GrowMemory runtime is invoked, the context variables can be changed in the WasmContext at C++ level so that the generated code will load the correct values. This requires to insert a relocatable pointer only in the JSToWasmWrapper (and in the other wasm entry points), the value is then passed from function to function as an automatically added additional parameter. The WasmContext is then dropped when creating an Interpreter Entry or when invoking a JavaScript function. This removes the need of patching the generated code at runtime (i.e., when the memory grows) with respect to WASM_MEMORY_REFERENCE and WASM_MEMORY_SIZE_REFERENCE. However, we still need to patch the code at instance build time to patch the JSToWasmWrappers; in fact the address of the WasmContext is not known during compilation, but only when the instance is built. The WasmContext address is passed as the first parameter. This has the advantage of not having to move the WasmContext around if the function does not use many registers. This CL also changes the wasm calling convention so that the first parameter register is different from the return value register. The WasmContext is attached to every WasmMemoryObject, to share the same context with multiple instances sharing the same memory. Moreover, the nodes representing the WasmContext variables are cached in the SSA environment, similarly to other local variables that might change during execution. The nodes are created when initializing the SSA environment and refreshed every time a grow_memory or a function call happens, so that we are sure that they always represent the correct mem_size and mem_start variables. This CL also removes the WasmMemorySize runtime (since it's now possible to directly retrieve mem_size from the context) and simplifies the GrowMemory runtime (since every instance now has a memory_object). R=ahaas@chromium.org,clemensh@chromium.org CC=gdeepti@chromium.org Change-Id: I3f058e641284f5a1bbbfc35a64c88da6ff08e240 Reviewed-on: https://chromium-review.googlesource.com/671008 Commit-Queue: Enrico Bacis <enricobacis@google.com> Reviewed-by: Clemens Hammacher <clemensh@chromium.org> Reviewed-by: Andreas Haas <ahaas@chromium.org> Cr-Commit-Position: refs/heads/master@{#48209}
2017-09-28 14:59:37 +00:00
Node* context_address = Int32Constant(0);
Signature<MachineRepresentation>::Builder sig_builder(zone(), 1, 3);
sig_builder.AddReturn(MachineRepresentation::kWord32);
sig_builder.AddParam(MachineRepresentation::kWord64);
sig_builder.AddParam(MachineRepresentation::kWord32);
sig_builder.AddParam(MachineRepresentation::kWord64);
compiler::CallDescriptor* desc =
compiler::GetWasmCallDescriptor(zone(), sig_builder.Build());
LowerGraph(graph()->NewNode(common()->Call(desc), Int32Constant(function),
[wasm] Introduce the WasmContext The WasmContext struct introduced in this CL is used to store the mem_size and mem_start address of the wasm memory. These variables can be accessed at C++ level at graph build time (e.g., initialized during instance building). When the GrowMemory runtime is invoked, the context variables can be changed in the WasmContext at C++ level so that the generated code will load the correct values. This requires to insert a relocatable pointer only in the JSToWasmWrapper (and in the other wasm entry points), the value is then passed from function to function as an automatically added additional parameter. The WasmContext is then dropped when creating an Interpreter Entry or when invoking a JavaScript function. This removes the need of patching the generated code at runtime (i.e., when the memory grows) with respect to WASM_MEMORY_REFERENCE and WASM_MEMORY_SIZE_REFERENCE. However, we still need to patch the code at instance build time to patch the JSToWasmWrappers; in fact the address of the WasmContext is not known during compilation, but only when the instance is built. The WasmContext address is passed as the first parameter. This has the advantage of not having to move the WasmContext around if the function does not use many registers. This CL also changes the wasm calling convention so that the first parameter register is different from the return value register. The WasmContext is attached to every WasmMemoryObject, to share the same context with multiple instances sharing the same memory. Moreover, the nodes representing the WasmContext variables are cached in the SSA environment, similarly to other local variables that might change during execution. The nodes are created when initializing the SSA environment and refreshed every time a grow_memory or a function call happens, so that we are sure that they always represent the correct mem_size and mem_start variables. This CL also removes the WasmMemorySize runtime (since it's now possible to directly retrieve mem_size from the context) and simplifies the GrowMemory runtime (since every instance now has a memory_object). R=ahaas@chromium.org,clemensh@chromium.org CC=gdeepti@chromium.org Change-Id: I3f058e641284f5a1bbbfc35a64c88da6ff08e240 Reviewed-on: https://chromium-review.googlesource.com/671008 Commit-Queue: Enrico Bacis <enricobacis@google.com> Reviewed-by: Clemens Hammacher <clemensh@chromium.org> Reviewed-by: Andreas Haas <ahaas@chromium.org> Cr-Commit-Position: refs/heads/master@{#48209}
2017-09-28 14:59:37 +00:00
context_address, Int64Constant(value(0)),
Int32Constant(low_word_value(1)),
Int64Constant(value(2)), start(), start()),
MachineRepresentation::kWord32);
EXPECT_THAT(
graph()->end()->InputAt(1),
[wasm] Introduce the WasmContext The WasmContext struct introduced in this CL is used to store the mem_size and mem_start address of the wasm memory. These variables can be accessed at C++ level at graph build time (e.g., initialized during instance building). When the GrowMemory runtime is invoked, the context variables can be changed in the WasmContext at C++ level so that the generated code will load the correct values. This requires to insert a relocatable pointer only in the JSToWasmWrapper (and in the other wasm entry points), the value is then passed from function to function as an automatically added additional parameter. The WasmContext is then dropped when creating an Interpreter Entry or when invoking a JavaScript function. This removes the need of patching the generated code at runtime (i.e., when the memory grows) with respect to WASM_MEMORY_REFERENCE and WASM_MEMORY_SIZE_REFERENCE. However, we still need to patch the code at instance build time to patch the JSToWasmWrappers; in fact the address of the WasmContext is not known during compilation, but only when the instance is built. The WasmContext address is passed as the first parameter. This has the advantage of not having to move the WasmContext around if the function does not use many registers. This CL also changes the wasm calling convention so that the first parameter register is different from the return value register. The WasmContext is attached to every WasmMemoryObject, to share the same context with multiple instances sharing the same memory. Moreover, the nodes representing the WasmContext variables are cached in the SSA environment, similarly to other local variables that might change during execution. The nodes are created when initializing the SSA environment and refreshed every time a grow_memory or a function call happens, so that we are sure that they always represent the correct mem_size and mem_start variables. This CL also removes the WasmMemorySize runtime (since it's now possible to directly retrieve mem_size from the context) and simplifies the GrowMemory runtime (since every instance now has a memory_object). R=ahaas@chromium.org,clemensh@chromium.org CC=gdeepti@chromium.org Change-Id: I3f058e641284f5a1bbbfc35a64c88da6ff08e240 Reviewed-on: https://chromium-review.googlesource.com/671008 Commit-Queue: Enrico Bacis <enricobacis@google.com> Reviewed-by: Clemens Hammacher <clemensh@chromium.org> Reviewed-by: Andreas Haas <ahaas@chromium.org> Cr-Commit-Position: refs/heads/master@{#48209}
2017-09-28 14:59:37 +00:00
IsReturn(IsCall(testing::_, IsInt32Constant(function), context_address,
IsInt32Constant(low_word_value(0)),
IsInt32Constant(high_word_value(0)),
IsInt32Constant(low_word_value(1)),
IsInt32Constant(low_word_value(2)),
IsInt32Constant(high_word_value(2)), start(), start()),
start(), start()));
CompareCallDescriptors(OpParameter<const CallDescriptor*>(
graph()->end()->InputAt(1)->InputAt(1)),
compiler::GetI32WasmCallDescriptor(zone(), desc));
}
TEST_F(Int64LoweringTest, Int64Add) {
LowerGraph(graph()->NewNode(machine()->Int64Add(), Int64Constant(value(0)),
Int64Constant(value(1))),
MachineRepresentation::kWord64);
Capture<Node*> add;
Matcher<Node*> add_matcher = IsInt32PairAdd(
IsInt32Constant(low_word_value(0)), IsInt32Constant(high_word_value(0)),
IsInt32Constant(low_word_value(1)), IsInt32Constant(high_word_value(1)));
EXPECT_THAT(graph()->end()->InputAt(1),
IsReturn2(IsProjection(0, AllOf(CaptureEq(&add), add_matcher)),
IsProjection(1, AllOf(CaptureEq(&add), add_matcher)),
start(), start()));
}
[wasm] Introduce the WasmContext The WasmContext struct introduced in this CL is used to store the mem_size and mem_start address of the wasm memory. These variables can be accessed at C++ level at graph build time (e.g., initialized during instance building). When the GrowMemory runtime is invoked, the context variables can be changed in the WasmContext at C++ level so that the generated code will load the correct values. This requires to insert a relocatable pointer only in the JSToWasmWrapper (and in the other wasm entry points), the value is then passed from function to function as an automatically added additional parameter. The WasmContext is then dropped when creating an Interpreter Entry or when invoking a JavaScript function. This removes the need of patching the generated code at runtime (i.e., when the memory grows) with respect to WASM_MEMORY_REFERENCE and WASM_MEMORY_SIZE_REFERENCE. However, we still need to patch the code at instance build time to patch the JSToWasmWrappers; in fact the address of the WasmContext is not known during compilation, but only when the instance is built. The WasmContext address is passed as the first parameter. This has the advantage of not having to move the WasmContext around if the function does not use many registers. This CL also changes the wasm calling convention so that the first parameter register is different from the return value register. The WasmContext is attached to every WasmMemoryObject, to share the same context with multiple instances sharing the same memory. Moreover, the nodes representing the WasmContext variables are cached in the SSA environment, similarly to other local variables that might change during execution. The nodes are created when initializing the SSA environment and refreshed every time a grow_memory or a function call happens, so that we are sure that they always represent the correct mem_size and mem_start variables. This CL also removes the WasmMemorySize runtime (since it's now possible to directly retrieve mem_size from the context) and simplifies the GrowMemory runtime (since every instance now has a memory_object). R=ahaas@chromium.org,clemensh@chromium.org CC=gdeepti@chromium.org Change-Id: I3f058e641284f5a1bbbfc35a64c88da6ff08e240 Reviewed-on: https://chromium-review.googlesource.com/671008 Commit-Queue: Enrico Bacis <enricobacis@google.com> Reviewed-by: Clemens Hammacher <clemensh@chromium.org> Reviewed-by: Andreas Haas <ahaas@chromium.org> Cr-Commit-Position: refs/heads/master@{#48209}
2017-09-28 14:59:37 +00:00
#endif
TEST_F(Int64LoweringTest, Int64Sub) {
LowerGraph(graph()->NewNode(machine()->Int64Sub(), Int64Constant(value(0)),
Int64Constant(value(1))),
MachineRepresentation::kWord64);
Capture<Node*> sub;
Matcher<Node*> sub_matcher = IsInt32PairSub(
IsInt32Constant(low_word_value(0)), IsInt32Constant(high_word_value(0)),
IsInt32Constant(low_word_value(1)), IsInt32Constant(high_word_value(1)));
EXPECT_THAT(graph()->end()->InputAt(1),
IsReturn2(IsProjection(0, AllOf(CaptureEq(&sub), sub_matcher)),
IsProjection(1, AllOf(CaptureEq(&sub), sub_matcher)),
start(), start()));
}
TEST_F(Int64LoweringTest, Int64Mul) {
LowerGraph(graph()->NewNode(machine()->Int64Mul(), Int64Constant(value(0)),
Int64Constant(value(1))),
MachineRepresentation::kWord64);
Capture<Node*> mul_capture;
Matcher<Node*> mul_matcher = IsInt32PairMul(
IsInt32Constant(low_word_value(0)), IsInt32Constant(high_word_value(0)),
IsInt32Constant(low_word_value(1)), IsInt32Constant(high_word_value(1)));
EXPECT_THAT(
graph()->end()->InputAt(1),
IsReturn2(IsProjection(0, AllOf(CaptureEq(&mul_capture), mul_matcher)),
IsProjection(1, AllOf(CaptureEq(&mul_capture), mul_matcher)),
start(), start()));
}
TEST_F(Int64LoweringTest, Int64Ior) {
LowerGraph(graph()->NewNode(machine()->Word64Or(), Int64Constant(value(0)),
Int64Constant(value(1))),
MachineRepresentation::kWord64);
EXPECT_THAT(graph()->end()->InputAt(1),
IsReturn2(IsWord32Or(IsInt32Constant(low_word_value(0)),
IsInt32Constant(low_word_value(1))),
IsWord32Or(IsInt32Constant(high_word_value(0)),
IsInt32Constant(high_word_value(1))),
start(), start()));
}
TEST_F(Int64LoweringTest, Int64Xor) {
LowerGraph(graph()->NewNode(machine()->Word64Xor(), Int64Constant(value(0)),
Int64Constant(value(1))),
MachineRepresentation::kWord64);
EXPECT_THAT(graph()->end()->InputAt(1),
IsReturn2(IsWord32Xor(IsInt32Constant(low_word_value(0)),
IsInt32Constant(low_word_value(1))),
IsWord32Xor(IsInt32Constant(high_word_value(0)),
IsInt32Constant(high_word_value(1))),
start(), start()));
}
TEST_F(Int64LoweringTest, Int64Shl) {
LowerGraph(graph()->NewNode(machine()->Word64Shl(), Int64Constant(value(0)),
Int64Constant(value(1))),
MachineRepresentation::kWord64);
Capture<Node*> shl;
Matcher<Node*> shl_matcher = IsWord32PairShl(
IsInt32Constant(low_word_value(0)), IsInt32Constant(high_word_value(0)),
IsInt32Constant(low_word_value(1)));
EXPECT_THAT(graph()->end()->InputAt(1),
IsReturn2(IsProjection(0, AllOf(CaptureEq(&shl), shl_matcher)),
IsProjection(1, AllOf(CaptureEq(&shl), shl_matcher)),
start(), start()));
}
TEST_F(Int64LoweringTest, Int64ShrU) {
LowerGraph(graph()->NewNode(machine()->Word64Shr(), Int64Constant(value(0)),
Int64Constant(value(1))),
MachineRepresentation::kWord64);
Capture<Node*> shr;
Matcher<Node*> shr_matcher = IsWord32PairShr(
IsInt32Constant(low_word_value(0)), IsInt32Constant(high_word_value(0)),
IsInt32Constant(low_word_value(1)));
EXPECT_THAT(graph()->end()->InputAt(1),
IsReturn2(IsProjection(0, AllOf(CaptureEq(&shr), shr_matcher)),
IsProjection(1, AllOf(CaptureEq(&shr), shr_matcher)),
start(), start()));
}
TEST_F(Int64LoweringTest, Int64ShrS) {
LowerGraph(graph()->NewNode(machine()->Word64Sar(), Int64Constant(value(0)),
Int64Constant(value(1))),
MachineRepresentation::kWord64);
Capture<Node*> sar;
Matcher<Node*> sar_matcher = IsWord32PairSar(
IsInt32Constant(low_word_value(0)), IsInt32Constant(high_word_value(0)),
IsInt32Constant(low_word_value(1)));
EXPECT_THAT(graph()->end()->InputAt(1),
IsReturn2(IsProjection(0, AllOf(CaptureEq(&sar), sar_matcher)),
IsProjection(1, AllOf(CaptureEq(&sar), sar_matcher)),
start(), start()));
}
TEST_F(Int64LoweringTest, Int64Eq) {
LowerGraph(graph()->NewNode(machine()->Word64Equal(), Int64Constant(value(0)),
Int64Constant(value(1))),
MachineRepresentation::kWord32);
EXPECT_THAT(
graph()->end()->InputAt(1),
IsReturn(IsWord32Equal(
IsWord32Or(IsWord32Xor(IsInt32Constant(low_word_value(0)),
IsInt32Constant(low_word_value(1))),
IsWord32Xor(IsInt32Constant(high_word_value(0)),
IsInt32Constant(high_word_value(1)))),
IsInt32Constant(0)),
start(), start()));
}
TEST_F(Int64LoweringTest, Int64LtS) {
TestComparison(machine()->Int64LessThan(), IsInt32LessThan, IsUint32LessThan);
}
TEST_F(Int64LoweringTest, Int64LeS) {
TestComparison(machine()->Int64LessThanOrEqual(), IsInt32LessThan,
IsUint32LessThanOrEqual);
}
TEST_F(Int64LoweringTest, Int64LtU) {
TestComparison(machine()->Uint64LessThan(), IsUint32LessThan,
IsUint32LessThan);
}
TEST_F(Int64LoweringTest, Int64LeU) {
TestComparison(machine()->Uint64LessThanOrEqual(), IsUint32LessThan,
IsUint32LessThanOrEqual);
}
TEST_F(Int64LoweringTest, I32ConvertI64) {
LowerGraph(graph()->NewNode(machine()->TruncateInt64ToInt32(),
Int64Constant(value(0))),
MachineRepresentation::kWord32);
EXPECT_THAT(graph()->end()->InputAt(1),
IsReturn(IsInt32Constant(low_word_value(0)), start(), start()));
}
TEST_F(Int64LoweringTest, I64SConvertI32) {
LowerGraph(graph()->NewNode(machine()->ChangeInt32ToInt64(),
Int32Constant(low_word_value(0))),
MachineRepresentation::kWord64);
EXPECT_THAT(graph()->end()->InputAt(1),
IsReturn2(IsInt32Constant(low_word_value(0)),
IsWord32Sar(IsInt32Constant(low_word_value(0)),
IsInt32Constant(31)),
start(), start()));
}
TEST_F(Int64LoweringTest, I64SConvertI32_2) {
LowerGraph(
graph()->NewNode(machine()->ChangeInt32ToInt64(),
graph()->NewNode(machine()->TruncateInt64ToInt32(),
Int64Constant(value(0)))),
MachineRepresentation::kWord64);
EXPECT_THAT(graph()->end()->InputAt(1),
IsReturn2(IsInt32Constant(low_word_value(0)),
IsWord32Sar(IsInt32Constant(low_word_value(0)),
IsInt32Constant(31)),
start(), start()));
}
TEST_F(Int64LoweringTest, I64UConvertI32) {
LowerGraph(graph()->NewNode(machine()->ChangeUint32ToUint64(),
Int32Constant(low_word_value(0))),
MachineRepresentation::kWord64);
EXPECT_THAT(graph()->end()->InputAt(1),
IsReturn2(IsInt32Constant(low_word_value(0)), IsInt32Constant(0),
start(), start()));
}
TEST_F(Int64LoweringTest, I64UConvertI32_2) {
LowerGraph(
graph()->NewNode(machine()->ChangeUint32ToUint64(),
graph()->NewNode(machine()->TruncateInt64ToInt32(),
Int64Constant(value(0)))),
MachineRepresentation::kWord64);
EXPECT_THAT(graph()->end()->InputAt(1),
IsReturn2(IsInt32Constant(low_word_value(0)), IsInt32Constant(0),
start(), start()));
}
TEST_F(Int64LoweringTest, F64ReinterpretI64) {
LowerGraph(graph()->NewNode(machine()->BitcastInt64ToFloat64(),
Int64Constant(value(0))),
MachineRepresentation::kFloat64);
Capture<Node*> stack_slot_capture;
Matcher<Node*> stack_slot_matcher =
IsStackSlot(StackSlotRepresentation(sizeof(int64_t), 0));
Capture<Node*> store_capture;
Matcher<Node*> store_matcher =
IsStore(StoreRepresentation(MachineRepresentation::kWord32,
WriteBarrierKind::kNoWriteBarrier),
AllOf(CaptureEq(&stack_slot_capture), stack_slot_matcher),
IsInt32Constant(kInt64LowerHalfMemoryOffset),
IsInt32Constant(low_word_value(0)),
IsStore(StoreRepresentation(MachineRepresentation::kWord32,
WriteBarrierKind::kNoWriteBarrier),
AllOf(CaptureEq(&stack_slot_capture), stack_slot_matcher),
IsInt32Constant(kInt64UpperHalfMemoryOffset),
IsInt32Constant(high_word_value(0)), start(), start()),
start());
EXPECT_THAT(
graph()->end()->InputAt(1),
IsReturn(IsLoad(MachineType::Float64(),
AllOf(CaptureEq(&stack_slot_capture), stack_slot_matcher),
IsInt32Constant(0),
AllOf(CaptureEq(&store_capture), store_matcher), start()),
start(), start()));
}
TEST_F(Int64LoweringTest, I64ReinterpretF64) {
LowerGraph(graph()->NewNode(machine()->BitcastFloat64ToInt64(),
Float64Constant(bit_cast<double>(value(0)))),
MachineRepresentation::kWord64);
Capture<Node*> stack_slot;
Matcher<Node*> stack_slot_matcher =
IsStackSlot(StackSlotRepresentation(sizeof(int64_t), 0));
Capture<Node*> store;
Matcher<Node*> store_matcher = IsStore(
StoreRepresentation(MachineRepresentation::kFloat64,
WriteBarrierKind::kNoWriteBarrier),
AllOf(CaptureEq(&stack_slot), stack_slot_matcher), IsInt32Constant(0),
IsFloat64Constant(bit_cast<double>(value(0))), start(), start());
EXPECT_THAT(
graph()->end()->InputAt(1),
IsReturn2(IsLoad(MachineType::Int32(),
AllOf(CaptureEq(&stack_slot), stack_slot_matcher),
IsInt32Constant(kInt64LowerHalfMemoryOffset),
AllOf(CaptureEq(&store), store_matcher), start()),
IsLoad(MachineType::Int32(),
AllOf(CaptureEq(&stack_slot), stack_slot_matcher),
IsInt32Constant(kInt64UpperHalfMemoryOffset),
AllOf(CaptureEq(&store), store_matcher), start()),
start(), start()));
}
TEST_F(Int64LoweringTest, I64Clz) {
LowerGraph(graph()->NewNode(machine()->Word64Clz(), Int64Constant(value(0))),
MachineRepresentation::kWord64);
Capture<Node*> branch_capture;
Matcher<Node*> branch_matcher = IsBranch(
IsWord32Equal(IsInt32Constant(high_word_value(0)), IsInt32Constant(0)),
start());
EXPECT_THAT(
graph()->end()->InputAt(1),
IsReturn2(
IsPhi(MachineRepresentation::kWord32,
IsInt32Add(IsWord32Clz(IsInt32Constant(low_word_value(0))),
IsInt32Constant(32)),
IsWord32Clz(IsInt32Constant(high_word_value(0))),
IsMerge(
IsIfTrue(AllOf(CaptureEq(&branch_capture), branch_matcher)),
IsIfFalse(
AllOf(CaptureEq(&branch_capture), branch_matcher)))),
IsInt32Constant(0), start(), start()));
}
TEST_F(Int64LoweringTest, I64Ctz) {
LowerGraph(graph()->NewNode(machine()->Word64Ctz().placeholder(),
Int64Constant(value(0))),
MachineRepresentation::kWord64);
Capture<Node*> branch_capture;
Matcher<Node*> branch_matcher = IsBranch(
IsWord32Equal(IsInt32Constant(low_word_value(0)), IsInt32Constant(0)),
start());
EXPECT_THAT(
graph()->end()->InputAt(1),
IsReturn2(
IsPhi(MachineRepresentation::kWord32,
IsInt32Add(IsWord32Ctz(IsInt32Constant(high_word_value(0))),
IsInt32Constant(32)),
IsWord32Ctz(IsInt32Constant(low_word_value(0))),
IsMerge(
IsIfTrue(AllOf(CaptureEq(&branch_capture), branch_matcher)),
IsIfFalse(
AllOf(CaptureEq(&branch_capture), branch_matcher)))),
IsInt32Constant(0), start(), start()));
}
TEST_F(Int64LoweringTest, Dfs) {
Node* common = Int64Constant(value(0));
LowerGraph(graph()->NewNode(machine()->Word64And(), common,
graph()->NewNode(machine()->Word64And(), common,
Int64Constant(value(1)))),
MachineRepresentation::kWord64);
EXPECT_THAT(
graph()->end()->InputAt(1),
IsReturn2(IsWord32And(IsInt32Constant(low_word_value(0)),
IsWord32And(IsInt32Constant(low_word_value(0)),
IsInt32Constant(low_word_value(1)))),
IsWord32And(IsInt32Constant(high_word_value(0)),
IsWord32And(IsInt32Constant(high_word_value(0)),
IsInt32Constant(high_word_value(1)))),
start(), start()));
}
TEST_F(Int64LoweringTest, I64Popcnt) {
LowerGraph(graph()->NewNode(machine()->Word64Popcnt().placeholder(),
Int64Constant(value(0))),
MachineRepresentation::kWord64);
EXPECT_THAT(
graph()->end()->InputAt(1),
IsReturn2(IsInt32Add(IsWord32Popcnt(IsInt32Constant(low_word_value(0))),
IsWord32Popcnt(IsInt32Constant(high_word_value(0)))),
IsInt32Constant(0), start(), start()));
}
TEST_F(Int64LoweringTest, I64Ror) {
LowerGraph(graph()->NewNode(machine()->Word64Ror(), Int64Constant(value(0)),
Parameter(0)),
MachineRepresentation::kWord64, MachineRepresentation::kWord64, 1);
Matcher<Node*> branch_lt32_matcher =
IsBranch(IsInt32LessThan(IsParameter(0), IsInt32Constant(32)), start());
Matcher<Node*> low_input_matcher = IsPhi(
MachineRepresentation::kWord32, IsInt32Constant(low_word_value(0)),
IsInt32Constant(high_word_value(0)),
IsMerge(IsIfTrue(branch_lt32_matcher), IsIfFalse(branch_lt32_matcher)));
Matcher<Node*> high_input_matcher = IsPhi(
MachineRepresentation::kWord32, IsInt32Constant(high_word_value(0)),
IsInt32Constant(low_word_value(0)),
IsMerge(IsIfTrue(branch_lt32_matcher), IsIfFalse(branch_lt32_matcher)));
Matcher<Node*> shift_matcher =
IsWord32And(IsParameter(0), IsInt32Constant(0x1F));
Matcher<Node*> bit_mask_matcher = IsWord32Shl(
IsWord32Sar(IsInt32Constant(std::numeric_limits<int32_t>::min()),
shift_matcher),
IsInt32Constant(1));
Matcher<Node*> inv_mask_matcher =
IsWord32Xor(bit_mask_matcher, IsInt32Constant(-1));
EXPECT_THAT(
graph()->end()->InputAt(1),
IsReturn2(
IsWord32Or(IsWord32And(IsWord32Ror(low_input_matcher, shift_matcher),
inv_mask_matcher),
IsWord32And(IsWord32Ror(high_input_matcher, shift_matcher),
bit_mask_matcher)),
IsWord32Or(IsWord32And(IsWord32Ror(high_input_matcher, shift_matcher),
inv_mask_matcher),
IsWord32And(IsWord32Ror(low_input_matcher, shift_matcher),
bit_mask_matcher)),
start(), start()));
}
TEST_F(Int64LoweringTest, I64Ror_0) {
LowerGraph(graph()->NewNode(machine()->Word64Ror(), Int64Constant(value(0)),
Int32Constant(0)),
MachineRepresentation::kWord64);
EXPECT_THAT(graph()->end()->InputAt(1),
IsReturn2(IsInt32Constant(low_word_value(0)),
IsInt32Constant(high_word_value(0)), start(), start()));
}
TEST_F(Int64LoweringTest, I64Ror_32) {
LowerGraph(graph()->NewNode(machine()->Word64Ror(), Int64Constant(value(0)),
Int32Constant(32)),
MachineRepresentation::kWord64);
EXPECT_THAT(graph()->end()->InputAt(1),
IsReturn2(IsInt32Constant(high_word_value(0)),
IsInt32Constant(low_word_value(0)), start(), start()));
}
TEST_F(Int64LoweringTest, I64Ror_11) {
LowerGraph(graph()->NewNode(machine()->Word64Ror(), Int64Constant(value(0)),
Int32Constant(11)),
MachineRepresentation::kWord64);
EXPECT_THAT(
graph()->end()->InputAt(1),
IsReturn2(IsWord32Or(IsWord32Shr(IsInt32Constant(low_word_value(0)),
IsInt32Constant(11)),
IsWord32Shl(IsInt32Constant(high_word_value(0)),
IsInt32Constant(21))),
IsWord32Or(IsWord32Shr(IsInt32Constant(high_word_value(0)),
IsInt32Constant(11)),
IsWord32Shl(IsInt32Constant(low_word_value(0)),
IsInt32Constant(21))),
start(), start()));
}
TEST_F(Int64LoweringTest, I64Ror_43) {
LowerGraph(graph()->NewNode(machine()->Word64Ror(), Int64Constant(value(0)),
Int32Constant(43)),
MachineRepresentation::kWord64);
EXPECT_THAT(
graph()->end()->InputAt(1),
IsReturn2(IsWord32Or(IsWord32Shr(IsInt32Constant(high_word_value(0)),
IsInt32Constant(11)),
IsWord32Shl(IsInt32Constant(low_word_value(0)),
IsInt32Constant(21))),
IsWord32Or(IsWord32Shr(IsInt32Constant(low_word_value(0)),
IsInt32Constant(11)),
IsWord32Shl(IsInt32Constant(high_word_value(0)),
IsInt32Constant(21))),
start(), start()));
}
TEST_F(Int64LoweringTest, I64PhiWord64) {
LowerGraph(graph()->NewNode(common()->Phi(MachineRepresentation::kWord64, 2),
Int64Constant(value(0)), Int64Constant(value(1)),
start()),
MachineRepresentation::kWord64);
EXPECT_THAT(graph()->end()->InputAt(1),
IsReturn2(IsPhi(MachineRepresentation::kWord32,
IsInt32Constant(low_word_value(0)),
IsInt32Constant(low_word_value(1)), start()),
IsPhi(MachineRepresentation::kWord32,
IsInt32Constant(high_word_value(0)),
IsInt32Constant(high_word_value(1)), start()),
start(), start()));
}
void TestPhi(Int64LoweringTest* test, MachineRepresentation rep, Node* v1,
Node* v2) {
test->LowerGraph(test->graph()->NewNode(test->common()->Phi(rep, 2), v1, v2,
test->start()),
rep);
EXPECT_THAT(test->graph()->end()->InputAt(1),
IsReturn(IsPhi(rep, v1, v2, test->start()), test->start(),
test->start()));
}
TEST_F(Int64LoweringTest, I64PhiFloat32) {
TestPhi(this, MachineRepresentation::kFloat32, Float32Constant(1.5),
Float32Constant(2.5));
}
TEST_F(Int64LoweringTest, I64PhiFloat64) {
TestPhi(this, MachineRepresentation::kFloat64, Float32Constant(1.5),
Float32Constant(2.5));
}
TEST_F(Int64LoweringTest, I64PhiWord32) {
TestPhi(this, MachineRepresentation::kWord32, Float32Constant(1),
Float32Constant(2));
}
TEST_F(Int64LoweringTest, I64ReverseBytes) {
LowerGraph(graph()->NewNode(machine()->Word64ReverseBytes().placeholder(),
Int64Constant(value(0))),
MachineRepresentation::kWord64);
EXPECT_THAT(
graph()->end()->InputAt(1),
IsReturn2(IsWord32ReverseBytes(IsInt32Constant(high_word_value(0))),
IsWord32ReverseBytes(IsInt32Constant(low_word_value(0))),
start(), start()));
}
TEST_F(Int64LoweringTest, EffectPhiLoop) {
// Construct a cycle consisting of an EffectPhi, a Store, and a Load.
Node* eff_phi = graph()->NewNode(common()->EffectPhi(1), graph()->start(),
graph()->start());
StoreRepresentation store_rep(MachineRepresentation::kWord64,
WriteBarrierKind::kNoWriteBarrier);
LoadRepresentation load_rep(MachineType::Int64());
Node* load =
graph()->NewNode(machine()->Load(load_rep), Int64Constant(value(0)),
Int64Constant(value(1)), eff_phi, graph()->start());
Node* store =
graph()->NewNode(machine()->Store(store_rep), Int64Constant(value(0)),
Int64Constant(value(1)), load, load, graph()->start());
eff_phi->InsertInput(zone(), 1, store);
NodeProperties::ChangeOp(eff_phi,
common()->ResizeMergeOrPhi(eff_phi->op(), 2));
LowerGraph(load, MachineRepresentation::kWord64);
}
TEST_F(Int64LoweringTest, LoopCycle) {
// New node with two placeholders.
Node* compare = graph()->NewNode(machine()->Word64Equal(), Int64Constant(0),
Int64Constant(value(0)));
Node* load = graph()->NewNode(
machine()->Load(MachineType::Int64()), Int64Constant(value(1)),
Int64Constant(value(2)), graph()->start(),
graph()->NewNode(
common()->Loop(2), graph()->start(),
graph()->NewNode(common()->IfFalse(),
graph()->NewNode(common()->Branch(), compare,
graph()->start()))));
NodeProperties::ReplaceValueInput(compare, load, 0);
LowerGraph(load, MachineRepresentation::kWord64);
}
} // namespace compiler
} // namespace internal
} // namespace v8