90c8932596
Our own ARRAY_SIZE() was pretty bad at error checking. If you use arrasize() in a wrong way, the compiler will issue an error instead of silently doing the wrong thing. The previous ARRAY_SIZE() macro is still available as ARRAYSIZE_UNSAFE() similar to Chrome. R=yangguo@chromium.org Review URL: https://codereview.chromium.org/501323002 git-svn-id: https://v8.googlecode.com/svn/branches/bleeding_edge@23389 ce2b1a6d-e550-0410-aec6-3dcde31c8c00
304 lines
9.7 KiB
C++
304 lines
9.7 KiB
C++
// Copyright 2014 the V8 project authors. All rights reserved.
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// Use of this source code is governed by a BSD-style license that can be
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// found in the LICENSE file.
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#include <limits>
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#include "src/v8.h"
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#include "test/cctest/cctest.h"
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#include "test/cctest/compiler/graph-builder-tester.h"
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#include "src/compiler/node-matchers.h"
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#include "src/compiler/representation-change.h"
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#include "src/compiler/typer.h"
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using namespace v8::internal;
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using namespace v8::internal::compiler;
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namespace v8 { // for friendiness.
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namespace internal {
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namespace compiler {
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class RepresentationChangerTester : public HandleAndZoneScope,
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public GraphAndBuilders {
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public:
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explicit RepresentationChangerTester(int num_parameters = 0)
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: GraphAndBuilders(main_zone()),
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typer_(main_zone()),
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jsgraph_(main_graph_, &main_common_, &typer_),
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changer_(&jsgraph_, &main_simplified_, &main_machine_, main_isolate()) {
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Node* s = graph()->NewNode(common()->Start(num_parameters));
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graph()->SetStart(s);
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}
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Typer typer_;
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JSGraph jsgraph_;
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RepresentationChanger changer_;
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Isolate* isolate() { return main_isolate(); }
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Graph* graph() { return main_graph_; }
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CommonOperatorBuilder* common() { return &main_common_; }
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JSGraph* jsgraph() { return &jsgraph_; }
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RepresentationChanger* changer() { return &changer_; }
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// TODO(titzer): use ValueChecker / ValueUtil
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void CheckInt32Constant(Node* n, int32_t expected) {
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ValueMatcher<int32_t> m(n);
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CHECK(m.HasValue());
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CHECK_EQ(expected, m.Value());
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}
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void CheckHeapConstant(Node* n, Object* expected) {
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ValueMatcher<Handle<Object> > m(n);
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CHECK(m.HasValue());
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CHECK_EQ(expected, *m.Value());
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}
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void CheckNumberConstant(Node* n, double expected) {
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ValueMatcher<double> m(n);
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CHECK_EQ(IrOpcode::kNumberConstant, n->opcode());
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CHECK(m.HasValue());
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CHECK_EQ(expected, m.Value());
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}
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Node* Parameter(int index = 0) {
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return graph()->NewNode(common()->Parameter(index), graph()->start());
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}
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void CheckTypeError(MachineTypeUnion from, MachineTypeUnion to) {
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changer()->testing_type_errors_ = true;
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changer()->type_error_ = false;
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Node* n = Parameter(0);
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Node* c = changer()->GetRepresentationFor(n, from, to);
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CHECK(changer()->type_error_);
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CHECK_EQ(n, c);
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}
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void CheckNop(MachineTypeUnion from, MachineTypeUnion to) {
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Node* n = Parameter(0);
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Node* c = changer()->GetRepresentationFor(n, from, to);
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CHECK_EQ(n, c);
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}
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};
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}
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}
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} // namespace v8::internal::compiler
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static const MachineType all_reps[] = {kRepBit, kRepWord32, kRepWord64,
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kRepFloat64, kRepTagged};
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// TODO(titzer): lift this to ValueHelper
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static const double double_inputs[] = {
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0.0, -0.0, 1.0, -1.0, 0.1, 1.4, -1.7,
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2, 5, 6, 982983, 888, -999.8, 3.1e7,
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-2e66, 2.3e124, -12e73, V8_INFINITY, -V8_INFINITY};
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static const int32_t int32_inputs[] = {
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0, 1, -1,
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2, 5, 6,
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982983, 888, -999,
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65535, static_cast<int32_t>(0xFFFFFFFF), static_cast<int32_t>(0x80000000)};
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static const uint32_t uint32_inputs[] = {
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0, 1, static_cast<uint32_t>(-1), 2, 5, 6,
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982983, 888, static_cast<uint32_t>(-999), 65535, 0xFFFFFFFF, 0x80000000};
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TEST(BoolToBit_constant) {
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RepresentationChangerTester r;
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Node* true_node = r.jsgraph()->TrueConstant();
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Node* true_bit =
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r.changer()->GetRepresentationFor(true_node, kRepTagged, kRepBit);
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r.CheckInt32Constant(true_bit, 1);
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Node* false_node = r.jsgraph()->FalseConstant();
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Node* false_bit =
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r.changer()->GetRepresentationFor(false_node, kRepTagged, kRepBit);
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r.CheckInt32Constant(false_bit, 0);
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}
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TEST(BitToBool_constant) {
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RepresentationChangerTester r;
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for (int i = -5; i < 5; i++) {
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Node* node = r.jsgraph()->Int32Constant(i);
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Node* val = r.changer()->GetRepresentationFor(node, kRepBit, kRepTagged);
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r.CheckHeapConstant(val, i == 0 ? r.isolate()->heap()->false_value()
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: r.isolate()->heap()->true_value());
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}
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}
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TEST(ToTagged_constant) {
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RepresentationChangerTester r;
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for (size_t i = 0; i < arraysize(double_inputs); i++) {
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Node* n = r.jsgraph()->Float64Constant(double_inputs[i]);
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Node* c = r.changer()->GetRepresentationFor(n, kRepFloat64, kRepTagged);
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r.CheckNumberConstant(c, double_inputs[i]);
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}
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for (size_t i = 0; i < arraysize(int32_inputs); i++) {
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Node* n = r.jsgraph()->Int32Constant(int32_inputs[i]);
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Node* c = r.changer()->GetRepresentationFor(n, kRepWord32 | kTypeInt32,
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kRepTagged);
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r.CheckNumberConstant(c, static_cast<double>(int32_inputs[i]));
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}
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for (size_t i = 0; i < arraysize(uint32_inputs); i++) {
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Node* n = r.jsgraph()->Int32Constant(uint32_inputs[i]);
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Node* c = r.changer()->GetRepresentationFor(n, kRepWord32 | kTypeUint32,
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kRepTagged);
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r.CheckNumberConstant(c, static_cast<double>(uint32_inputs[i]));
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}
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}
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static void CheckChange(IrOpcode::Value expected, MachineTypeUnion from,
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MachineTypeUnion to) {
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RepresentationChangerTester r;
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Node* n = r.Parameter();
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Node* c = r.changer()->GetRepresentationFor(n, from, to);
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CHECK_NE(c, n);
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CHECK_EQ(expected, c->opcode());
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CHECK_EQ(n, c->InputAt(0));
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}
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TEST(SingleChanges) {
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CheckChange(IrOpcode::kChangeBoolToBit, kRepTagged, kRepBit);
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CheckChange(IrOpcode::kChangeBitToBool, kRepBit, kRepTagged);
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CheckChange(IrOpcode::kChangeInt32ToTagged, kRepWord32 | kTypeInt32,
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kRepTagged);
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CheckChange(IrOpcode::kChangeUint32ToTagged, kRepWord32 | kTypeUint32,
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kRepTagged);
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CheckChange(IrOpcode::kChangeFloat64ToTagged, kRepFloat64, kRepTagged);
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CheckChange(IrOpcode::kChangeTaggedToInt32, kRepTagged | kTypeInt32,
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kRepWord32);
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CheckChange(IrOpcode::kChangeTaggedToUint32, kRepTagged | kTypeUint32,
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kRepWord32);
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CheckChange(IrOpcode::kChangeTaggedToFloat64, kRepTagged, kRepFloat64);
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// Int32,Uint32 <-> Float64 are actually machine conversions.
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CheckChange(IrOpcode::kChangeInt32ToFloat64, kRepWord32 | kTypeInt32,
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kRepFloat64);
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CheckChange(IrOpcode::kChangeUint32ToFloat64, kRepWord32 | kTypeUint32,
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kRepFloat64);
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CheckChange(IrOpcode::kChangeFloat64ToInt32, kRepFloat64 | kTypeInt32,
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kRepWord32);
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CheckChange(IrOpcode::kChangeFloat64ToUint32, kRepFloat64 | kTypeUint32,
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kRepWord32);
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}
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TEST(SignednessInWord32) {
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RepresentationChangerTester r;
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// TODO(titzer): assume that uses of a word32 without a sign mean kTypeInt32.
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CheckChange(IrOpcode::kChangeTaggedToInt32, kRepTagged,
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kRepWord32 | kTypeInt32);
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CheckChange(IrOpcode::kChangeTaggedToUint32, kRepTagged,
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kRepWord32 | kTypeUint32);
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CheckChange(IrOpcode::kChangeInt32ToFloat64, kRepWord32, kRepFloat64);
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CheckChange(IrOpcode::kChangeFloat64ToInt32, kRepFloat64, kRepWord32);
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}
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TEST(Nops) {
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RepresentationChangerTester r;
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// X -> X is always a nop for any single representation X.
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for (size_t i = 0; i < arraysize(all_reps); i++) {
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r.CheckNop(all_reps[i], all_reps[i]);
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}
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// 32-bit or 64-bit words can be used as branch conditions (kRepBit).
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r.CheckNop(kRepWord32, kRepBit);
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r.CheckNop(kRepWord32, kRepBit | kTypeBool);
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r.CheckNop(kRepWord64, kRepBit);
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r.CheckNop(kRepWord64, kRepBit | kTypeBool);
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// 32-bit words can be used as smaller word sizes and vice versa, because
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// loads from memory implicitly sign or zero extend the value to the
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// full machine word size, and stores implicitly truncate.
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r.CheckNop(kRepWord32, kRepWord8);
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r.CheckNop(kRepWord32, kRepWord16);
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r.CheckNop(kRepWord32, kRepWord32);
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r.CheckNop(kRepWord8, kRepWord32);
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r.CheckNop(kRepWord16, kRepWord32);
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// kRepBit (result of comparison) is implicitly a wordish thing.
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r.CheckNop(kRepBit, kRepWord8);
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r.CheckNop(kRepBit | kTypeBool, kRepWord8);
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r.CheckNop(kRepBit, kRepWord16);
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r.CheckNop(kRepBit | kTypeBool, kRepWord16);
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r.CheckNop(kRepBit, kRepWord32);
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r.CheckNop(kRepBit | kTypeBool, kRepWord32);
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r.CheckNop(kRepBit, kRepWord64);
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r.CheckNop(kRepBit | kTypeBool, kRepWord64);
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}
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TEST(TypeErrors) {
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RepresentationChangerTester r;
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// Floats cannot be implicitly converted to/from comparison conditions.
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r.CheckTypeError(kRepFloat64, kRepBit);
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r.CheckTypeError(kRepFloat64, kRepBit | kTypeBool);
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r.CheckTypeError(kRepBit, kRepFloat64);
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r.CheckTypeError(kRepBit | kTypeBool, kRepFloat64);
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// Word64 is internal and shouldn't be implicitly converted.
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r.CheckTypeError(kRepWord64, kRepTagged | kTypeBool);
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r.CheckTypeError(kRepWord64, kRepTagged);
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r.CheckTypeError(kRepWord64, kRepTagged | kTypeBool);
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r.CheckTypeError(kRepTagged, kRepWord64);
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r.CheckTypeError(kRepTagged | kTypeBool, kRepWord64);
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// Word64 / Word32 shouldn't be implicitly converted.
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r.CheckTypeError(kRepWord64, kRepWord32);
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r.CheckTypeError(kRepWord32, kRepWord64);
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r.CheckTypeError(kRepWord64, kRepWord32 | kTypeInt32);
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r.CheckTypeError(kRepWord32 | kTypeInt32, kRepWord64);
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r.CheckTypeError(kRepWord64, kRepWord32 | kTypeUint32);
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r.CheckTypeError(kRepWord32 | kTypeUint32, kRepWord64);
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for (size_t i = 0; i < arraysize(all_reps); i++) {
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for (size_t j = 0; j < arraysize(all_reps); j++) {
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if (i == j) continue;
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// Only a single from representation is allowed.
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r.CheckTypeError(all_reps[i] | all_reps[j], kRepTagged);
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}
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}
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}
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TEST(CompleteMatrix) {
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// TODO(titzer): test all variants in the matrix.
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// rB
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// tBrB
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// tBrT
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// rW32
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// tIrW32
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// tUrW32
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// rW64
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// tIrW64
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// tUrW64
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// rF64
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// tIrF64
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// tUrF64
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// tArF64
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// rT
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// tArT
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}
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