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encoded_program_unittest.cc
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encoded_program_unittest.cc
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// Copyright (c) 2012 The Chromium 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 "courgette/encoded_program.h"
#include <stddef.h>
#include <stdint.h>
#include <memory>
#include <vector>
#include "base/macros.h"
#include "courgette/image_utils.h"
#include "courgette/label_manager.h"
#include "courgette/streams.h"
#include "testing/gtest/include/gtest/gtest.h"
namespace courgette {
namespace {
// Helper class to instantiate RVAToLabel while managing allocation.
class TestLabelManager : public LabelManager {
public:
void RawAddLabel(int index, RVA rva) {
labels_.push_back(Label(rva, index)); // Don't care about |count_|.
}
};
// Creates a simple new program with given addresses. The orders of elements
// in |abs32_specs| and |rel32_specs| are important.
std::unique_ptr<EncodedProgram> CreateTestProgram(
const TestLabelManager& abs32_label_manager,
const TestLabelManager& rel32_label_manager) {
std::unique_ptr<EncodedProgram> program(new EncodedProgram());
uint32_t base = 0x00900000;
program->set_image_base(base);
EXPECT_TRUE(program->ImportLabels(abs32_label_manager, rel32_label_manager));
EXPECT_TRUE(program->AddOrigin(0)); // Start at base.
// Add instructions. Since we're using TestLabelManager, Labels are sorted in
// the order they're added via Add().
for (const Label& label : abs32_label_manager.Labels())
EXPECT_TRUE(program->AddAbs32(label.index_));
for (const Label& label : rel32_label_manager.Labels())
EXPECT_TRUE(program->AddRel32(label.index_));
return program;
}
bool CompareSink(const uint8_t expected[],
size_t num_expected,
SinkStream* ss) {
size_t n = ss->Length();
if (num_expected != n)
return false;
const uint8_t* buffer = ss->Buffer();
return memcmp(&expected[0], buffer, n) == 0;
}
} // namespace
// Create a simple program with a few addresses and references and
// check that the bits produced are as expected.
TEST(EncodedProgramTest, Test) {
// ABS32 index 7 <-- base + 4.
TestLabelManager abs32_label_manager;
abs32_label_manager.RawAddLabel(7, 4);
// REL32 index 5 <-- base + 0.
TestLabelManager rel32_label_manager;
rel32_label_manager.RawAddLabel(5, 0);
std::unique_ptr<EncodedProgram> program(
CreateTestProgram(abs32_label_manager, rel32_label_manager));
// Serialize and deserialize.
SinkStreamSet sinks;
EXPECT_TRUE(program->WriteTo(&sinks));
program.reset();
SinkStream sink;
bool can_collect = sinks.CopyTo(&sink);
EXPECT_TRUE(can_collect);
const void* buffer = sink.Buffer();
size_t length = sink.Length();
SourceStreamSet sources;
bool can_get_source_streams = sources.Init(buffer, length);
EXPECT_TRUE(can_get_source_streams);
std::unique_ptr<EncodedProgram> encoded2(new EncodedProgram());
bool can_read = encoded2->ReadFrom(&sources);
EXPECT_TRUE(can_read);
// Finally, try to assemble.
SinkStream assembled;
bool can_assemble = encoded2->AssembleTo(&assembled);
EXPECT_TRUE(can_assemble);
encoded2.reset();
const uint8_t golden[] = {
0x04, 0x00, 0x90,
0x00, // ABS32 to base + 4
0xF8, 0xFF, 0xFF,
0xFF // REL32 from next line to base + 2
};
EXPECT_TRUE(CompareSink(golden, arraysize(golden), &assembled));
}
// A larger test with multiple addresses. We encode the program and check the
// contents of the address streams.
TEST(EncodedProgramTest, TestWriteAddress) {
// Absolute addresses by index: [_, _, _, 2, _, 23, _, 11].
TestLabelManager abs32_label_manager;
abs32_label_manager.RawAddLabel(7, 11);
abs32_label_manager.RawAddLabel(3, 2);
abs32_label_manager.RawAddLabel(5, 23);
// Relative addresses by index: [16, 7, _, 32].
TestLabelManager rel32_label_manager;
rel32_label_manager.RawAddLabel(0, 16);
rel32_label_manager.RawAddLabel(3, 32);
rel32_label_manager.RawAddLabel(1, 7);
std::unique_ptr<EncodedProgram> program(
CreateTestProgram(abs32_label_manager, rel32_label_manager));
SinkStreamSet sinks;
EXPECT_TRUE(program->WriteTo(&sinks));
program.reset();
// Check indexes and addresses in sinks.
const uint8_t golden_abs32_indexes[] = {
0x03, 0x07, 0x03, 0x05 // 3 indexes: [7, 3, 5].
};
EXPECT_TRUE(CompareSink(golden_abs32_indexes,
arraysize(golden_abs32_indexes),
sinks.stream(kStreamAbs32Indexes)));
const uint8_t golden_rel32_indexes[] = {
0x03, 0x00, 0x03, 0x01 // 3 indexes: [0, 3, 1].
};
EXPECT_TRUE(CompareSink(golden_rel32_indexes,
arraysize(golden_rel32_indexes),
sinks.stream(kStreamRel32Indexes)));
// Addresses: [_, _, _, 2, _, 23, _, 11].
// Padded: [0, 0, 0, 2, 2, 23, 23, 11].
// Delta: [0, 0, 0, 2, 0, 21, 0, -12].
// Hex: [0, 0, 0, 0x02, 0, 0x15, 0, 0xFFFFFFF4].
// Complement neg: [0, 0, 0, 0x02, 0, 0x15, 0, (0x0B)].
// Varint32 Signed: [0, 0, 0, 0x04, 0, 0x2A, 0, 0x17].
const uint8_t golden_abs32_addresses[] = {
0x08, // 8 address deltas.
0x00, 0x00, 0x00, 0x04, 0x00, 0x2A, 0x00, 0x17,
};
EXPECT_TRUE(CompareSink(golden_abs32_addresses,
arraysize(golden_abs32_addresses),
sinks.stream(kStreamAbs32Addresses)));
// Addresses: [16, 7, _, 32].
// Padded: [16, 7, 7, 32].
// Delta: [16, -9, 0, 25].
// Hex: [0x10, 0xFFFFFFF7, 0, 0x19].
// Complement Neg: [0x10, (0x08), 0, 0x19].
// Varint32 Signed: [0x20, 0x11, 0, 0x32].
const uint8_t golden_rel32_addresses[] = {
0x04, // 4 address deltas.
0x20, 0x11, 0x00, 0x32,
};
EXPECT_TRUE(CompareSink(golden_rel32_addresses,
arraysize(golden_rel32_addresses),
sinks.stream(kStreamRel32Addresses)));
}
} // namespace courgette