v8/test/cctest/compiler/test-jump-threading.cc
jochen cb7aa79b12 Expose a lower bound of malloc'd memory via heap statistics
We expect that the majority of malloc'd memory held by V8 is allocated
in Zone objects. Introduce an Allocator class that is used by Zones to
manage memory, and allows for querying the current usage.

BUG=none
R=titzer@chromium.org,bmeurer@chromium.org,jarin@chromium.org
LOG=n
TBR=rossberg@chromium.org

Review URL: https://codereview.chromium.org/1847543002

Cr-Commit-Position: refs/heads/master@{#35196}
2016-04-01 10:01:56 +00:00

770 lines
16 KiB
C++

// Copyright 2014 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/instruction.h"
#include "src/compiler/instruction-codes.h"
#include "src/compiler/jump-threading.h"
#include "test/cctest/cctest.h"
namespace v8 {
namespace internal {
namespace compiler {
class TestCode : public HandleAndZoneScope {
public:
TestCode()
: HandleAndZoneScope(),
blocks_(main_zone()),
sequence_(main_isolate(), main_zone(), &blocks_),
rpo_number_(RpoNumber::FromInt(0)),
current_(NULL) {}
ZoneVector<InstructionBlock*> blocks_;
InstructionSequence sequence_;
RpoNumber rpo_number_;
InstructionBlock* current_;
int Jump(int target) {
Start();
InstructionOperand ops[] = {UseRpo(target)};
sequence_.AddInstruction(
Instruction::New(main_zone(), kArchJmp, 0, NULL, 1, ops, 0, NULL));
int pos = static_cast<int>(sequence_.instructions().size() - 1);
End();
return pos;
}
void Fallthru() {
Start();
End();
}
int Branch(int ttarget, int ftarget) {
Start();
InstructionOperand ops[] = {UseRpo(ttarget), UseRpo(ftarget)};
InstructionCode code = 119 | FlagsModeField::encode(kFlags_branch) |
FlagsConditionField::encode(kEqual);
sequence_.AddInstruction(
Instruction::New(main_zone(), code, 0, NULL, 2, ops, 0, NULL));
int pos = static_cast<int>(sequence_.instructions().size() - 1);
End();
return pos;
}
void Nop() {
Start();
sequence_.AddInstruction(Instruction::New(main_zone(), kArchNop));
}
void RedundantMoves() {
Start();
sequence_.AddInstruction(Instruction::New(main_zone(), kArchNop));
int index = static_cast<int>(sequence_.instructions().size()) - 1;
AddGapMove(index, AllocatedOperand(LocationOperand::REGISTER,
MachineRepresentation::kWord32, 13),
AllocatedOperand(LocationOperand::REGISTER,
MachineRepresentation::kWord32, 13));
}
void NonRedundantMoves() {
Start();
sequence_.AddInstruction(Instruction::New(main_zone(), kArchNop));
int index = static_cast<int>(sequence_.instructions().size()) - 1;
AddGapMove(index, ConstantOperand(11),
AllocatedOperand(LocationOperand::REGISTER,
MachineRepresentation::kWord32, 11));
}
void Other() {
Start();
sequence_.AddInstruction(Instruction::New(main_zone(), 155));
}
void End() {
Start();
sequence_.EndBlock(current_->rpo_number());
current_ = NULL;
rpo_number_ = RpoNumber::FromInt(rpo_number_.ToInt() + 1);
}
InstructionOperand UseRpo(int num) {
return sequence_.AddImmediate(Constant(RpoNumber::FromInt(num)));
}
void Start(bool deferred = false) {
if (current_ == NULL) {
current_ = new (main_zone())
InstructionBlock(main_zone(), rpo_number_, RpoNumber::Invalid(),
RpoNumber::Invalid(), deferred, false);
blocks_.push_back(current_);
sequence_.StartBlock(rpo_number_);
}
}
void Defer() {
CHECK(current_ == NULL);
Start(true);
}
void AddGapMove(int index, const InstructionOperand& from,
const InstructionOperand& to) {
sequence_.InstructionAt(index)
->GetOrCreateParallelMove(Instruction::START, main_zone())
->AddMove(from, to);
}
};
void VerifyForwarding(TestCode& code, int count, int* expected) {
base::AccountingAllocator allocator;
Zone local_zone(&allocator);
ZoneVector<RpoNumber> result(&local_zone);
JumpThreading::ComputeForwarding(&local_zone, result, &code.sequence_, true);
CHECK(count == static_cast<int>(result.size()));
for (int i = 0; i < count; i++) {
CHECK(expected[i] == result[i].ToInt());
}
}
TEST(FwEmpty1) {
TestCode code;
// B0
code.Jump(1);
// B1
code.Jump(2);
// B2
code.End();
static int expected[] = {2, 2, 2};
VerifyForwarding(code, 3, expected);
}
TEST(FwEmptyN) {
for (int i = 0; i < 9; i++) {
TestCode code;
// B0
code.Jump(1);
// B1
for (int j = 0; j < i; j++) code.Nop();
code.Jump(2);
// B2
code.End();
static int expected[] = {2, 2, 2};
VerifyForwarding(code, 3, expected);
}
}
TEST(FwNone1) {
TestCode code;
// B0
code.End();
static int expected[] = {0};
VerifyForwarding(code, 1, expected);
}
TEST(FwMoves1) {
TestCode code;
// B0
code.RedundantMoves();
code.End();
static int expected[] = {0};
VerifyForwarding(code, 1, expected);
}
TEST(FwMoves2) {
TestCode code;
// B0
code.RedundantMoves();
code.Fallthru();
// B1
code.End();
static int expected[] = {1, 1};
VerifyForwarding(code, 2, expected);
}
TEST(FwMoves2b) {
TestCode code;
// B0
code.NonRedundantMoves();
code.Fallthru();
// B1
code.End();
static int expected[] = {0, 1};
VerifyForwarding(code, 2, expected);
}
TEST(FwOther2) {
TestCode code;
// B0
code.Other();
code.Fallthru();
// B1
code.End();
static int expected[] = {0, 1};
VerifyForwarding(code, 2, expected);
}
TEST(FwNone2a) {
TestCode code;
// B0
code.Fallthru();
// B1
code.End();
static int expected[] = {1, 1};
VerifyForwarding(code, 2, expected);
}
TEST(FwNone2b) {
TestCode code;
// B0
code.Jump(1);
// B1
code.End();
static int expected[] = {1, 1};
VerifyForwarding(code, 2, expected);
}
TEST(FwLoop1) {
TestCode code;
// B0
code.Jump(0);
static int expected[] = {0};
VerifyForwarding(code, 1, expected);
}
TEST(FwLoop2) {
TestCode code;
// B0
code.Fallthru();
// B1
code.Jump(0);
static int expected[] = {0, 0};
VerifyForwarding(code, 2, expected);
}
TEST(FwLoop3) {
TestCode code;
// B0
code.Fallthru();
// B1
code.Fallthru();
// B2
code.Jump(0);
static int expected[] = {0, 0, 0};
VerifyForwarding(code, 3, expected);
}
TEST(FwLoop1b) {
TestCode code;
// B0
code.Fallthru();
// B1
code.Jump(1);
static int expected[] = {1, 1};
VerifyForwarding(code, 2, expected);
}
TEST(FwLoop2b) {
TestCode code;
// B0
code.Fallthru();
// B1
code.Fallthru();
// B2
code.Jump(1);
static int expected[] = {1, 1, 1};
VerifyForwarding(code, 3, expected);
}
TEST(FwLoop3b) {
TestCode code;
// B0
code.Fallthru();
// B1
code.Fallthru();
// B2
code.Fallthru();
// B3
code.Jump(1);
static int expected[] = {1, 1, 1, 1};
VerifyForwarding(code, 4, expected);
}
TEST(FwLoop2_1a) {
TestCode code;
// B0
code.Fallthru();
// B1
code.Fallthru();
// B2
code.Fallthru();
// B3
code.Jump(1);
// B4
code.Jump(2);
static int expected[] = {1, 1, 1, 1, 1};
VerifyForwarding(code, 5, expected);
}
TEST(FwLoop2_1b) {
TestCode code;
// B0
code.Fallthru();
// B1
code.Fallthru();
// B2
code.Jump(4);
// B3
code.Jump(1);
// B4
code.Jump(2);
static int expected[] = {2, 2, 2, 2, 2};
VerifyForwarding(code, 5, expected);
}
TEST(FwLoop2_1c) {
TestCode code;
// B0
code.Fallthru();
// B1
code.Fallthru();
// B2
code.Jump(4);
// B3
code.Jump(2);
// B4
code.Jump(1);
static int expected[] = {1, 1, 1, 1, 1};
VerifyForwarding(code, 5, expected);
}
TEST(FwLoop2_1d) {
TestCode code;
// B0
code.Fallthru();
// B1
code.Fallthru();
// B2
code.Jump(1);
// B3
code.Jump(1);
// B4
code.Jump(1);
static int expected[] = {1, 1, 1, 1, 1};
VerifyForwarding(code, 5, expected);
}
TEST(FwLoop3_1a) {
TestCode code;
// B0
code.Fallthru();
// B1
code.Fallthru();
// B2
code.Fallthru();
// B3
code.Jump(2);
// B4
code.Jump(1);
// B5
code.Jump(0);
static int expected[] = {2, 2, 2, 2, 2, 2};
VerifyForwarding(code, 6, expected);
}
TEST(FwDiamonds) {
for (int i = 0; i < 2; i++) {
for (int j = 0; j < 2; j++) {
TestCode code;
// B0
code.Branch(1, 2);
// B1
if (i) code.Other();
code.Jump(3);
// B2
if (j) code.Other();
code.Jump(3);
// B3
code.End();
int expected[] = {0, i ? 1 : 3, j ? 2 : 3, 3};
VerifyForwarding(code, 4, expected);
}
}
}
TEST(FwDiamonds2) {
for (int i = 0; i < 2; i++) {
for (int j = 0; j < 2; j++) {
for (int k = 0; k < 2; k++) {
TestCode code;
// B0
code.Branch(1, 2);
// B1
if (i) code.Other();
code.Jump(3);
// B2
if (j) code.Other();
code.Jump(3);
// B3
if (k) code.NonRedundantMoves();
code.Jump(4);
// B4
code.End();
int merge = k ? 3 : 4;
int expected[] = {0, i ? 1 : merge, j ? 2 : merge, merge, 4};
VerifyForwarding(code, 5, expected);
}
}
}
}
TEST(FwDoubleDiamonds) {
for (int i = 0; i < 2; i++) {
for (int j = 0; j < 2; j++) {
for (int x = 0; x < 2; x++) {
for (int y = 0; y < 2; y++) {
TestCode code;
// B0
code.Branch(1, 2);
// B1
if (i) code.Other();
code.Jump(3);
// B2
if (j) code.Other();
code.Jump(3);
// B3
code.Branch(4, 5);
// B4
if (x) code.Other();
code.Jump(6);
// B5
if (y) code.Other();
code.Jump(6);
// B6
code.End();
int expected[] = {0, i ? 1 : 3, j ? 2 : 3, 3,
x ? 4 : 6, y ? 5 : 6, 6};
VerifyForwarding(code, 7, expected);
}
}
}
}
}
template <int kSize>
void RunPermutationsRecursive(int outer[kSize], int start,
void (*run)(int*, int)) {
int permutation[kSize];
for (int i = 0; i < kSize; i++) permutation[i] = outer[i];
int count = kSize - start;
if (count == 0) return run(permutation, kSize);
for (int i = start; i < kSize; i++) {
permutation[start] = outer[i];
permutation[i] = outer[start];
RunPermutationsRecursive<kSize>(permutation, start + 1, run);
permutation[i] = outer[i];
permutation[start] = outer[start];
}
}
template <int kSize>
void RunAllPermutations(void (*run)(int*, int)) {
int permutation[kSize];
for (int i = 0; i < kSize; i++) permutation[i] = i;
RunPermutationsRecursive<kSize>(permutation, 0, run);
}
void PrintPermutation(int* permutation, int size) {
printf("{ ");
for (int i = 0; i < size; i++) {
if (i > 0) printf(", ");
printf("%d", permutation[i]);
}
printf(" }\n");
}
int find(int x, int* permutation, int size) {
for (int i = 0; i < size; i++) {
if (permutation[i] == x) return i;
}
return size;
}
void RunPermutedChain(int* permutation, int size) {
TestCode code;
int cur = -1;
for (int i = 0; i < size; i++) {
code.Jump(find(cur + 1, permutation, size) + 1);
cur = permutation[i];
}
code.Jump(find(cur + 1, permutation, size) + 1);
code.End();
int expected[] = {size + 1, size + 1, size + 1, size + 1,
size + 1, size + 1, size + 1};
VerifyForwarding(code, size + 2, expected);
}
TEST(FwPermuted_chain) {
RunAllPermutations<3>(RunPermutedChain);
RunAllPermutations<4>(RunPermutedChain);
RunAllPermutations<5>(RunPermutedChain);
}
void RunPermutedDiamond(int* permutation, int size) {
TestCode code;
int br = 1 + find(0, permutation, size);
code.Jump(br);
for (int i = 0; i < size; i++) {
switch (permutation[i]) {
case 0:
code.Branch(1 + find(1, permutation, size),
1 + find(2, permutation, size));
break;
case 1:
code.Jump(1 + find(3, permutation, size));
break;
case 2:
code.Jump(1 + find(3, permutation, size));
break;
case 3:
code.Jump(5);
break;
}
}
code.End();
int expected[] = {br, 5, 5, 5, 5, 5};
expected[br] = br;
VerifyForwarding(code, 6, expected);
}
TEST(FwPermuted_diamond) { RunAllPermutations<4>(RunPermutedDiamond); }
void ApplyForwarding(TestCode& code, int size, int* forward) {
ZoneVector<RpoNumber> vector(code.main_zone());
for (int i = 0; i < size; i++) {
vector.push_back(RpoNumber::FromInt(forward[i]));
}
JumpThreading::ApplyForwarding(vector, &code.sequence_);
}
void CheckJump(TestCode& code, int pos, int target) {
Instruction* instr = code.sequence_.InstructionAt(pos);
CHECK_EQ(kArchJmp, instr->arch_opcode());
CHECK_EQ(1, static_cast<int>(instr->InputCount()));
CHECK_EQ(0, static_cast<int>(instr->OutputCount()));
CHECK_EQ(0, static_cast<int>(instr->TempCount()));
CHECK_EQ(target, code.sequence_.InputRpo(instr, 0).ToInt());
}
void CheckNop(TestCode& code, int pos) {
Instruction* instr = code.sequence_.InstructionAt(pos);
CHECK_EQ(kArchNop, instr->arch_opcode());
CHECK_EQ(0, static_cast<int>(instr->InputCount()));
CHECK_EQ(0, static_cast<int>(instr->OutputCount()));
CHECK_EQ(0, static_cast<int>(instr->TempCount()));
}
void CheckBranch(TestCode& code, int pos, int t1, int t2) {
Instruction* instr = code.sequence_.InstructionAt(pos);
CHECK_EQ(2, static_cast<int>(instr->InputCount()));
CHECK_EQ(0, static_cast<int>(instr->OutputCount()));
CHECK_EQ(0, static_cast<int>(instr->TempCount()));
CHECK_EQ(t1, code.sequence_.InputRpo(instr, 0).ToInt());
CHECK_EQ(t2, code.sequence_.InputRpo(instr, 1).ToInt());
}
void CheckAssemblyOrder(TestCode& code, int size, int* expected) {
int i = 0;
for (auto const block : code.sequence_.instruction_blocks()) {
CHECK_EQ(expected[i++], block->ao_number().ToInt());
}
}
TEST(Rewire1) {
TestCode code;
// B0
int j1 = code.Jump(1);
// B1
int j2 = code.Jump(2);
// B2
code.End();
static int forward[] = {2, 2, 2};
ApplyForwarding(code, 3, forward);
CheckJump(code, j1, 2);
CheckNop(code, j2);
static int assembly[] = {0, 1, 1};
CheckAssemblyOrder(code, 3, assembly);
}
TEST(Rewire1_deferred) {
TestCode code;
// B0
int j1 = code.Jump(1);
// B1
int j2 = code.Jump(2);
// B2
code.Defer();
int j3 = code.Jump(3);
// B3
code.End();
static int forward[] = {3, 3, 3, 3};
ApplyForwarding(code, 4, forward);
CheckJump(code, j1, 3);
CheckNop(code, j2);
CheckNop(code, j3);
static int assembly[] = {0, 1, 2, 1};
CheckAssemblyOrder(code, 4, assembly);
}
TEST(Rewire2_deferred) {
TestCode code;
// B0
code.Other();
int j1 = code.Jump(1);
// B1
code.Defer();
code.Fallthru();
// B2
code.Defer();
int j2 = code.Jump(3);
// B3
code.End();
static int forward[] = {0, 1, 2, 3};
ApplyForwarding(code, 4, forward);
CheckJump(code, j1, 1);
CheckJump(code, j2, 3);
static int assembly[] = {0, 2, 3, 1};
CheckAssemblyOrder(code, 4, assembly);
}
TEST(Rewire_diamond) {
for (int i = 0; i < 2; i++) {
for (int j = 0; j < 2; j++) {
TestCode code;
// B0
int j1 = code.Jump(1);
// B1
int b1 = code.Branch(2, 3);
// B2
int j2 = code.Jump(4);
// B3
int j3 = code.Jump(4);
// B5
code.End();
int forward[] = {0, 1, i ? 4 : 2, j ? 4 : 3, 4};
ApplyForwarding(code, 5, forward);
CheckJump(code, j1, 1);
CheckBranch(code, b1, i ? 4 : 2, j ? 4 : 3);
if (i) {
CheckNop(code, j2);
} else {
CheckJump(code, j2, 4);
}
if (j) {
CheckNop(code, j3);
} else {
CheckJump(code, j3, 4);
}
int assembly[] = {0, 1, 2, 3, 4};
if (i) {
for (int k = 3; k < 5; k++) assembly[k]--;
}
if (j) {
for (int k = 4; k < 5; k++) assembly[k]--;
}
CheckAssemblyOrder(code, 5, assembly);
}
}
}
} // namespace compiler
} // namespace internal
} // namespace v8