blob: 7e4a21edb4252268fccbd40d5c4c7066cd13f446 [file] [log] [blame]
// Copyright 2017 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 "components/zucchini/rel32_finder.h"
#include <stddef.h>
#include <stdint.h>
#include <algorithm>
#include <iterator>
#include <string>
#include <utility>
#include <vector>
#include "base/check_op.h"
#include "base/format_macros.h"
#include "base/numerics/safe_conversions.h"
#include "base/strings/stringprintf.h"
#include "components/zucchini/arm_utils.h"
#include "components/zucchini/buffer_view.h"
#include "components/zucchini/disassembler_elf.h"
#include "components/zucchini/image_utils.h"
#include "testing/gtest/include/gtest/gtest.h"
namespace zucchini {
TEST(Abs32GapFinderTest, All) {
const size_t kRegionTotal = 99;
std::vector<uint8_t> buffer(kRegionTotal);
ConstBufferView image(buffer.data(), buffer.size());
// Common test code that returns the resulting segments as a string.
auto run_test = [&](size_t rlo, size_t rhi,
std::vector<offset_t> abs32_locations,
std::ptrdiff_t abs32_width) -> std::string {
CHECK_LE(rlo, kRegionTotal);
CHECK_LE(rhi, kRegionTotal);
CHECK(std::is_sorted(abs32_locations.begin(), abs32_locations.end()));
CHECK_GT(abs32_width, 0);
ConstBufferView region =
ConstBufferView::FromRange(image.begin() + rlo, image.begin() + rhi);
Abs32GapFinder gap_finder(image, region, abs32_locations, abs32_width);
std::string out_str;
while (gap_finder.FindNext()) {
ConstBufferView gap = gap_finder.GetGap();
size_t lo = base::checked_cast<size_t>(gap.begin() - image.begin());
size_t hi = base::checked_cast<size_t>(gap.end() - image.begin());
out_str.append(base::StringPrintf("[%" PRIuS ",%" PRIuS ")", lo, hi));
}
return out_str;
};
// Empty regions yield empty segments.
EXPECT_EQ("", run_test(0, 0, {}, 4));
EXPECT_EQ("", run_test(9, 9, {}, 4));
EXPECT_EQ("", run_test(8, 8, {8}, 4));
EXPECT_EQ("", run_test(8, 8, {0, 12}, 4));
// If no abs32 locations exist then the segment is the main range.
EXPECT_EQ("[0,99)", run_test(0, 99, {}, 4));
EXPECT_EQ("[20,21)", run_test(20, 21, {}, 4));
EXPECT_EQ("[51,55)", run_test(51, 55, {}, 4));
// abs32 locations found near start of main range.
EXPECT_EQ("[10,20)", run_test(10, 20, {5}, 4));
EXPECT_EQ("[10,20)", run_test(10, 20, {6}, 4));
EXPECT_EQ("[11,20)", run_test(10, 20, {7}, 4));
EXPECT_EQ("[12,20)", run_test(10, 20, {8}, 4));
EXPECT_EQ("[13,20)", run_test(10, 20, {9}, 4));
EXPECT_EQ("[14,20)", run_test(10, 20, {10}, 4));
EXPECT_EQ("[10,11)[15,20)", run_test(10, 20, {11}, 4));
// abs32 locations found near end of main range.
EXPECT_EQ("[10,15)[19,20)", run_test(10, 20, {15}, 4));
EXPECT_EQ("[10,16)", run_test(10, 20, {16}, 4));
EXPECT_EQ("[10,17)", run_test(10, 20, {17}, 4));
EXPECT_EQ("[10,18)", run_test(10, 20, {18}, 4));
EXPECT_EQ("[10,19)", run_test(10, 20, {19}, 4));
EXPECT_EQ("[10,20)", run_test(10, 20, {20}, 4));
EXPECT_EQ("[10,20)", run_test(10, 20, {21}, 4));
// Main range completely eclipsed by abs32 location.
EXPECT_EQ("", run_test(10, 11, {7}, 4));
EXPECT_EQ("", run_test(10, 11, {8}, 4));
EXPECT_EQ("", run_test(10, 11, {9}, 4));
EXPECT_EQ("", run_test(10, 11, {10}, 4));
EXPECT_EQ("", run_test(10, 12, {8}, 4));
EXPECT_EQ("", run_test(10, 12, {9}, 4));
EXPECT_EQ("", run_test(10, 12, {10}, 4));
EXPECT_EQ("", run_test(10, 13, {9}, 4));
EXPECT_EQ("", run_test(10, 13, {10}, 4));
EXPECT_EQ("", run_test(10, 14, {10}, 4));
EXPECT_EQ("", run_test(10, 14, {8, 12}, 4));
// Partial eclipses.
EXPECT_EQ("[24,25)", run_test(20, 25, {20}, 4));
EXPECT_EQ("[20,21)", run_test(20, 25, {21}, 4));
EXPECT_EQ("[20,21)[25,26)", run_test(20, 26, {21}, 4));
// abs32 location outside main range.
EXPECT_EQ("[40,60)", run_test(40, 60, {36, 60}, 4));
EXPECT_EQ("[41,61)", run_test(41, 61, {0, 10, 20, 30, 34, 62, 68, 80}, 4));
// Change abs32 width.
EXPECT_EQ("[10,11)[12,14)[16,19)", run_test(10, 20, {9, 11, 14, 15, 19}, 1));
EXPECT_EQ("", run_test(10, 11, {10}, 1));
EXPECT_EQ("[18,23)[29,31)", run_test(17, 31, {15, 23, 26, 31}, 3));
EXPECT_EQ("[17,22)[25,26)[29,30)", run_test(17, 31, {14, 22, 26, 30}, 3));
EXPECT_EQ("[10,11)[19,20)", run_test(10, 20, {11}, 8));
// Mixed cases with abs32 width = 4.
EXPECT_EQ("[10,15)[19,20)[24,25)", run_test(8, 25, {2, 6, 15, 20, 27}, 4));
EXPECT_EQ("[0,25)[29,45)[49,50)", run_test(0, 50, {25, 45}, 4));
EXPECT_EQ("[10,20)[28,50)", run_test(10, 50, {20, 24}, 4));
EXPECT_EQ("[49,50)[54,60)[64,70)[74,80)[84,87)",
run_test(49, 87, {10, 20, 30, 40, 50, 60, 70, 80, 90}, 4));
EXPECT_EQ("[0,10)[14,20)[24,25)[29,50)", run_test(0, 50, {10, 20, 25}, 4));
}
namespace {
// A mock Rel32Finder to inject next search result on Scan().
class TestRel32Finder : public Rel32Finder {
public:
using Rel32Finder::Rel32Finder;
// Rel32Finder:
NextIterators Scan(ConstBufferView region) override { return next_result; }
NextIterators next_result;
};
AddressTranslator GetTrivialTranslator(size_t size) {
AddressTranslator translator;
EXPECT_EQ(AddressTranslator::kSuccess,
translator.Initialize({{0, base::checked_cast<offset_t>(size), 0U,
base::checked_cast<rva_t>(size)}}));
return translator;
}
} // namespace
TEST(Rel32FinderTest, Scan) {
const size_t kRegionTotal = 99;
std::vector<uint8_t> buffer(kRegionTotal);
ConstBufferView image(buffer.data(), buffer.size());
AddressTranslator translator(GetTrivialTranslator(image.size()));
TestRel32Finder finder(image, translator);
finder.SetRegion(image);
auto check_finder_state = [&](const TestRel32Finder& finder,
size_t expected_cursor,
size_t expected_accept_it) {
CHECK_LE(expected_cursor, kRegionTotal);
CHECK_LE(expected_accept_it, kRegionTotal);
EXPECT_EQ(image.begin() + expected_cursor, finder.region().begin());
EXPECT_EQ(image.begin() + expected_accept_it, finder.accept_it());
};
check_finder_state(finder, 0, 0);
finder.next_result = {image.begin() + 1, image.begin() + 1};
EXPECT_TRUE(finder.FindNext());
check_finder_state(finder, 1, 1);
finder.next_result = {image.begin() + 2, image.begin() + 2};
EXPECT_TRUE(finder.FindNext());
check_finder_state(finder, 2, 2);
finder.next_result = {image.begin() + 5, image.begin() + 6};
EXPECT_TRUE(finder.FindNext());
check_finder_state(finder, 5, 6);
finder.Accept();
check_finder_state(finder, 6, 6);
finder.next_result = {image.begin() + 7, image.begin() + 7};
EXPECT_TRUE(finder.FindNext());
check_finder_state(finder, 7, 7);
finder.next_result = {image.begin() + 8, image.begin() + 8};
EXPECT_TRUE(finder.FindNext());
check_finder_state(finder, 8, 8);
finder.next_result = {image.begin() + 99, image.begin() + 99};
EXPECT_TRUE(finder.FindNext());
check_finder_state(finder, 99, 99);
finder.next_result = {nullptr, nullptr};
EXPECT_FALSE(finder.FindNext());
check_finder_state(finder, 99, 99);
}
namespace {
// X86 test data. (x) and +x entries are covered by abs32 references, which have
// width = 4.
constexpr uint8_t kDataX86[] = {
0x55, // 00: push ebp
0x8B, 0xEC, // 01: mov ebp,esp
0xE8, 0, 0, 0, 0, // 03: call 08
(0xE9), +0, +0, +0, 0, // 08: jmp 0D
0x0F, 0x80, 0, 0, 0, 0, // 0D: jo 13
0x0F, 0x81, 0, 0, (0), +0, // 13: jno 19
+0x0F, +0x82, 0, 0, 0, 0, // 19: jb 1F
0x0F, 0x83, 0, 0, 0, 0, // 1F: jae 25
0x0F, (0x84), +0, +0, +0, (0), // 25: je 2B
+0x0F, +0x85, +0, 0, 0, 0, // 2B: jne 31
0x0F, 0x86, 0, 0, 0, 0, // 31: jbe 37
0x0F, 0x87, 0, 0, 0, 0, // 37: ja 3D
0x0F, 0x88, 0, (0), +0, +0, // 3D: js 43
+0x0F, 0x89, 0, 0, 0, 0, // 43: jns 49
0x0F, 0x8A, 0, 0, 0, 0, // 49: jp 4F
0x0F, 0x8B, (0), +0, +0, +0, // 4F: jnp 55
0x0F, 0x8C, 0, 0, 0, 0, // 55: jl 5B
0x0F, 0x8D, 0, 0, (0), +0, // 5B: jge 61
+0x0F, +0x8E, (0), +0, +0, +0, // 61: jle 67
0x0F, 0x8F, 0, 0, 0, 0, // 67: jg 6D
0x5D, // 6D: pop ebp
0xC3, // C3: ret
};
// Abs32 locations corresponding to |kDataX86|, with width = 4.
constexpr offset_t kAbs32X86[] = {0x08, 0x17, 0x26, 0x2A,
0x40, 0x51, 0x5F, 0x63};
} // namespace
TEST(Rel32FinderX86Test, FindNext) {
ConstBufferView image =
ConstBufferView::FromRange(std::begin(kDataX86), std::end(kDataX86));
AddressTranslator translator(GetTrivialTranslator(image.size()));
Rel32FinderX86 rel_finder(image, translator);
rel_finder.SetRegion(image);
// List of expected locations as pairs of {cursor offset, rel32 offset},
// ignoring |kAbs32X86|.
std::vector<std::pair<size_t, size_t>> expected_locations = {
{0x04, 0x04}, {0x09, 0x09}, {0x0E, 0x0F}, {0x14, 0x15}, {0x1A, 0x1B},
{0x20, 0x21}, {0x26, 0x27}, {0x2C, 0x2D}, {0x32, 0x33}, {0x38, 0x39},
{0x3E, 0x3F}, {0x44, 0x45}, {0x4A, 0x4B}, {0x50, 0x51}, {0x56, 0x57},
{0x5C, 0x5D}, {0x62, 0x63}, {0x68, 0x69},
};
for (auto location : expected_locations) {
EXPECT_TRUE(rel_finder.FindNext());
auto rel32 = rel_finder.GetRel32();
EXPECT_EQ(location.first,
size_t(rel_finder.region().begin() - image.begin()));
EXPECT_EQ(location.second, rel32.location);
EXPECT_EQ(image.begin() + (rel32.location + 4), rel_finder.accept_it());
EXPECT_FALSE(rel32.can_point_outside_section);
rel_finder.Accept();
}
EXPECT_FALSE(rel_finder.FindNext());
}
TEST(Rel32FinderX86Test, Integrated) {
// Truncated form of Rel32FinderIntel::Result.
using TruncatedResults = std::pair<offset_t, rva_t>;
ConstBufferView image =
ConstBufferView::FromRange(std::begin(kDataX86), std::end(kDataX86));
std::vector<offset_t> abs32_locations(std::begin(kAbs32X86),
std::end(kAbs32X86));
std::vector<TruncatedResults> results;
Abs32GapFinder gap_finder(image, image, abs32_locations,
DisassemblerElfX86::Traits::kVAWidth);
AddressTranslator translator(GetTrivialTranslator(image.size()));
Rel32FinderX86 rel_finder(image, translator);
while (gap_finder.FindNext()) {
rel_finder.SetRegion(gap_finder.GetGap());
while (rel_finder.FindNext()) {
auto rel32 = rel_finder.GetRel32();
rel_finder.Accept();
results.emplace_back(TruncatedResults{rel32.location, rel32.target_rva});
}
}
std::vector<TruncatedResults> expected_results = {
{0x04, 0x08},
/* {0x09, 0x0D}, */ {0x0F, 0x13},
/* {0x15, 0x19}, */ /*{0x1B, 0x1F}, */
{0x21, 0x25},
/* {0x27, 0x2B}, */ /* {0x2D, 0x31}, */ {0x33, 0x37},
{0x39, 0x3D},
/* {0x3F, 0x43}, */ /* {0x45, 0x49}, */ {0x4B, 0x4F},
/* {0x51, 0x55}, */ {0x57, 0x5B},
/* {0x5D, 0x61}, */ /* {0x63, 0x67}, */ {0x69, 0x6D},
};
EXPECT_EQ(expected_results, results);
}
TEST(Rel32FinderX86Test, Accept) {
constexpr uint8_t data[] = {
0xB9, 0x00, 0x00, 0x00, 0xE9, // 00: mov E9000000
0xE8, 0x00, 0x00, 0x00, 0xE9, // 05: call E900000A
0xE8, 0x00, 0x00, 0x00, 0xE9, // 0A: call E900000F
};
ConstBufferView image =
ConstBufferView::FromRange(std::begin(data), std::end(data));
auto next_location = [](Rel32FinderX86& rel_finder) -> offset_t {
EXPECT_TRUE(rel_finder.FindNext());
auto rel32 = rel_finder.GetRel32();
return rel32.location;
};
AddressTranslator translator(GetTrivialTranslator(image.size()));
Rel32FinderX86 rel_finder(image, translator);
rel_finder.SetRegion(image);
EXPECT_EQ(0x05U, next_location(rel_finder)); // False positive.
rel_finder.Accept();
// False negative: shadowed by 0x05
// EXPECT_EQ(0x06, next_location(rel_finder));
EXPECT_EQ(0x0AU, next_location(rel_finder)); // False positive.
EXPECT_EQ(0x0BU, next_location(rel_finder)); // Found if 0x0A is discarded.
}
namespace {
// X64 test data. (x) and +x entries are covered by abs32 references, which have
// width = 8.
constexpr uint8_t kDataX64[] = {
0x55, // 00: push ebp
0x8B, 0xEC, // 01: mov ebp,esp
0xE8, 0, 0, 0, 0, // 03: call 08
0xE9, 0, 0, 0, (0), // 08: jmp 0D
+0x0F, +0x80, +0, +0, +0, +0, // 0D: jo 13
+0x0F, 0x81, 0, 0, 0, 0, // 13: jno 19
0x0F, 0x82, 0, 0, 0, 0, // 19: jb 1F
(0x0F), +0x83, +0, +0, +0, +0, // 1F: jae 25
+0x0F, +0x84, 0, 0, 0, 0, // 25: je 2B
0x0F, 0x85, 0, 0, 0, 0, // 2B: jne 31
0x0F, 0x86, (0), +0, +0, +0, // 31: jbe 37
+0x0F, +0x87, +0, +0, (0), +0, // 37: ja 3D
+0x0F, +0x88, +0, +0, +0, +0, // 3D: js 43
0x0F, 0x89, 0, 0, 0, 0, // 43: jns 49
(0x0F), +0x8A, +0, +0, +0, +0, // 49: jp 4F
+0x0F, +0x8B, 0, 0, 0, 0, // 4F: jnp 55
0x0F, 0x8C, 0, 0, 0, 0, // 55: jl 5B
0x0F, 0x8D, 0, 0, 0, 0, // 5B: jge 61
0x0F, 0x8E, 0, 0, 0, 0, // 61: jle 67
0x0F, 0x8F, 0, (0), +0, +0, // 67: jg 6F
+0xFF, +0x15, +0, +0, +0, 0, // 6D: call [rip+00] # 73
0xFF, 0x25, 0, 0, 0, 0, // 73: jmp [rip+00] # 79
0x8B, 0x05, 0, 0, 0, 0, // 79: mov eax,[rip+00] # 7F
0x8B, 0x3D, 0, 0, 0, 0, // 7F: mov edi,[rip+00] # 85
0x8D, 0x05, 0, 0, 0, 0, // 85: lea eax,[rip+00] # 8B
0x8D, 0x3D, 0, 0, 0, 0, // 8B: lea edi,[rip+00] # 91
0x48, 0x8B, 0x05, 0, 0, 0, 0, // 91: mov rax,[rip+00] # 98
0x48, (0x8B), +0x3D, +0, +0, +0, +0, // 98: mov rdi,[rip+00] # 9F
+0x48, +0x8D, 0x05, 0, 0, 0, 0, // 9F: lea rax,[rip+00] # A6
0x48, 0x8D, 0x3D, 0, 0, 0, 0, // A6: lea rdi,[rip+00] # AD
0x4C, 0x8B, 0x05, 0, 0, 0, (0), // AD: mov r8,[rip+00] # B4
+0x4C, +0x8B, +0x3D, +0, +0, +0, +0, // B4: mov r15,[rip+00] # BB
0x4C, 0x8D, 0x05, 0, 0, 0, 0, // BB: lea r8,[rip+00] # C2
0x4C, 0x8D, 0x3D, 0, 0, 0, 0, // C2: lea r15,[rip+00] # C9
0x66, 0x8B, 0x05, (0), +0, +0, +0, // C9: mov ax,[rip+00] # D0
+0x66, +0x8B, +0x3D, +0, 0, 0, 0, // D0: mov di,[rip+00] # D7
0x66, 0x8D, 0x05, 0, 0, 0, 0, // D7: lea ax,[rip+00] # DE
0x66, 0x8D, 0x3D, 0, 0, 0, 0, // DE: lea di,[rip+00] # E5
0x5D, // E5: pop ebp
0xC3, // E6: ret
};
// Abs32 locations corresponding to |kDataX64|, with width = 8.
constexpr offset_t kAbs32X64[] = {0x0C, 0x1F, 0x33, 0x3B, 0x49,
0x6A, 0x99, 0xB3, 0xCC};
} // namespace
TEST(Rel32FinderX64Test, FindNext) {
ConstBufferView image =
ConstBufferView::FromRange(std::begin(kDataX64), std::end(kDataX64));
AddressTranslator translator(GetTrivialTranslator(image.size()));
Rel32FinderX64 rel_finder(image, translator);
rel_finder.SetRegion(image);
// Lists of expected locations as pairs of {cursor offset, rel32 offset},
// ignoring |kAbs32X64|.
std::vector<std::pair<size_t, size_t>> expected_locations = {
{0x04, 0x04}, {0x09, 0x09}, {0x0E, 0x0F}, {0x14, 0x15}, {0x1A, 0x1B},
{0x20, 0x21}, {0x26, 0x27}, {0x2C, 0x2D}, {0x32, 0x33}, {0x38, 0x39},
{0x3E, 0x3F}, {0x44, 0x45}, {0x4A, 0x4B}, {0x50, 0x51}, {0x56, 0x57},
{0x5C, 0x5D}, {0x62, 0x63}, {0x68, 0x69},
};
std::vector<std::pair<size_t, size_t>> expected_locations_rip = {
{0x6E, 0x6F}, {0x74, 0x75}, {0x7A, 0x7B}, {0x80, 0x81}, {0x86, 0x87},
{0x8C, 0x8D}, {0x93, 0x94}, {0x9A, 0x9B}, {0xA1, 0xA2}, {0xA8, 0xA9},
{0xAF, 0xB0}, {0xB6, 0xB7}, {0xBD, 0xBE}, {0xC4, 0xC5}, {0xCB, 0xCC},
{0xD2, 0xD3}, {0xD9, 0xDA}, {0xE0, 0xE1},
};
// Jump instructions, which cannot point outside section.
for (auto location : expected_locations) {
EXPECT_TRUE(rel_finder.FindNext());
auto rel32 = rel_finder.GetRel32();
EXPECT_EQ(location.first,
size_t(rel_finder.region().begin() - image.begin()));
EXPECT_EQ(location.second, rel32.location);
EXPECT_EQ(image.begin() + (rel32.location + 4), rel_finder.accept_it());
EXPECT_FALSE(rel32.can_point_outside_section);
rel_finder.Accept();
}
// PC-relative data access instructions, which can point outside section.
for (auto location : expected_locations_rip) {
EXPECT_TRUE(rel_finder.FindNext());
auto rel32 = rel_finder.GetRel32();
EXPECT_EQ(location.first,
size_t(rel_finder.region().begin() - image.begin()));
EXPECT_EQ(location.second, rel32.location);
EXPECT_EQ(image.begin() + (rel32.location + 4), rel_finder.accept_it());
EXPECT_TRUE(rel32.can_point_outside_section); // Different from before.
rel_finder.Accept();
}
EXPECT_FALSE(rel_finder.FindNext());
}
TEST(Rel32FinderX64Test, Integrated) {
// Truncated form of Rel32FinderIntel::Result.
using TruncatedResults = std::pair<offset_t, rva_t>;
ConstBufferView image =
ConstBufferView::FromRange(std::begin(kDataX64), std::end(kDataX64));
std::vector<offset_t> abs32_locations(std::begin(kAbs32X64),
std::end(kAbs32X64));
std::vector<TruncatedResults> results;
Abs32GapFinder gap_finder(image, image, abs32_locations,
DisassemblerElfX64::Traits::kVAWidth);
AddressTranslator translator(GetTrivialTranslator(image.size()));
Rel32FinderX64 rel_finder(image, translator);
while (gap_finder.FindNext()) {
rel_finder.SetRegion(gap_finder.GetGap());
while (rel_finder.FindNext()) {
auto rel32 = rel_finder.GetRel32();
rel_finder.Accept();
results.emplace_back(TruncatedResults{rel32.location, rel32.target_rva});
}
}
std::vector<TruncatedResults> expected_results = {
{0x04, 0x08},
/* {0x09, 0x0D}, */
/* {0x0F, 0x13}, */ /* {0x15, 0x19}, */ {0x1B, 0x1F},
/* {0x21, 0x25}, */ /* {0x27, 0x2B}, */ {0x2D, 0x31},
/* {0x33, 0x37}, */ /* {0x39, 0x3D}, */
/* {0x3F, 0x43}, */ {0x45, 0x49},
/* {0x4B, 0x4F}, */ /* {0x51, 0x55}, */
{0x57, 0x5B},
{0x5D, 0x61},
{0x63, 0x67}, /* {0x69, 0x6F}, */
/* {0x6F, 0x73}, */ {0x75, 0x79},
{0x7B, 0x7F},
{0x81, 0x85},
{0x87, 0x8B},
{0x8D, 0x91},
{0x94, 0x98},
/* {0x9B, 0x9F}, */ /* {0xA2, 0xA6}, */ {0xA9, 0xAD},
/* {0xB0, 0xB4}, */ /* {0xB7, 0xBB}, */ {0xBE, 0xC2},
{0xC5, 0xC9},
/* {0xCC, 0xD0}, */ /* {0xD3, 0xD7}, */ {0xDA, 0xDE},
{0xE1, 0xE5},
};
EXPECT_EQ(expected_results, results);
}
namespace {
// Runs the ARM rel32 extraction (nested) loop on |image| using |rel32_finder|,
// given |abs32_locations| for abs32 references each having |abs32_width|.
// Returns the list of extracted references.
template <class REL32_FINDER>
std::vector<typename REL32_FINDER::Result> ArmExtractRel32(
ConstBufferView image,
const std::vector<offset_t>& abs32_locations,
int abs32_width,
REL32_FINDER&& rel32_finder) {
std::vector<typename REL32_FINDER::Result> results;
Abs32GapFinder gap_finder(image, image, abs32_locations, abs32_width);
while (gap_finder.FindNext()) {
rel32_finder.SetRegion(gap_finder.GetGap());
while (rel32_finder.FindNext()) {
typename REL32_FINDER::Result rel32 = rel32_finder.GetRel32();
rel32_finder.Accept();
results.emplace_back(rel32);
}
}
return results;
}
} // namespace
namespace {
// AArch32 ARM mode test data. (x) and +x entries are covered by abs32
// references (if used), which have width = 4.
constexpr uint8_t kDataAarch32ArmMode[] = {
0x00, 0x01, 0x02, 0xEA, // 00: B 00080408 ; B encoding A1
0x00, 0x01, (0x02), +0xEA, // 04: B 0008040C ; B encoding A1
+0x00, +0x01, 0x02, 0xEA, // 08: B 00080410 ; B encoding A1
0x00, 0x01, 0x02, 0xEA, // 0C: B 00080414 ; B encoding A1
0x00, 0x01, 0x02, (0xEA), // 10: B 00080418 ; B encoding A1
+0x00, +0x01, +0x02, 0xEA, // 14: B 0008041C ; B encoding A1
0x00, 0x01, 0x02, 0xEA, // 18: B 00080420 ; B encoding A1
};
// Abs32 locations corresponding to |kDataAarch32ArmMode|, with width = 4.
constexpr offset_t kAbs32Aarch32ArmMode[] = {0x6, 0x13};
} // namespace
TEST(Rel32FinderAArch32Test, IntegratedArmModeWithoutAbs32) {
using AddrType = AArch32Rel32Translator::AddrType;
using Result = Rel32FinderAArch32::Result;
std::vector<Result> expected_results = {
{0x00, 0x80408, AddrType::ADDR_A24}, {0x04, 0x8040C, AddrType::ADDR_A24},
{0x08, 0x80410, AddrType::ADDR_A24}, {0x0C, 0x80414, AddrType::ADDR_A24},
{0x10, 0x80418, AddrType::ADDR_A24}, {0x14, 0x8041C, AddrType::ADDR_A24},
{0x18, 0x80420, AddrType::ADDR_A24},
};
ConstBufferView image = ConstBufferView::FromRange(
std::begin(kDataAarch32ArmMode), std::end(kDataAarch32ArmMode));
AddressTranslator translator(GetTrivialTranslator(image.size()));
Rel32FinderAArch32 rel32_finder(image, translator, /* is_thumb2 */ false);
std::vector<Result> results = ArmExtractRel32(
image, /* abs32_locations */ {}, DisassemblerElfAArch32::Traits::kVAWidth,
std::move(rel32_finder));
EXPECT_EQ(expected_results, results);
}
TEST(Rel32FinderAArch32Test, IntegratedArmModeWithAbs32) {
using AddrType = AArch32Rel32Translator::AddrType;
using Result = Rel32FinderAArch32::Result;
std::vector<Result> expected_results = {
{0x00, 0x80408, AddrType::ADDR_A24},
/* {0x04, 0x8040C, AddrType::ADDR_A24}, */
/* {0x08, 0x80410, AddrType::ADDR_A24}, */
{0x0C, 0x80414, AddrType::ADDR_A24},
/* {0x10, 0x80418, AddrType::ADDR_A24}, */
/* {0x14, 0x8041C, AddrType::ADDR_A24}, */
{0x18, 0x80420, AddrType::ADDR_A24},
};
ConstBufferView image = ConstBufferView::FromRange(
std::begin(kDataAarch32ArmMode), std::end(kDataAarch32ArmMode));
std::vector<offset_t> abs32_locations(std::begin(kAbs32Aarch32ArmMode),
std::end(kAbs32Aarch32ArmMode));
AddressTranslator translator(GetTrivialTranslator(image.size()));
Rel32FinderAArch32 rel32_finder(image, translator, /* is_thumb2 */ false);
std::vector<Result> results = ArmExtractRel32(
image, abs32_locations, DisassemblerElfAArch32::Traits::kVAWidth,
std::move(rel32_finder));
EXPECT_EQ(expected_results, results);
}
namespace {
// AArch32 THUMB2 mode test data. (x) and +x entries are covered by abs32
// references (if used), which have width = 4.
constexpr uint8_t kDataAarch32Thumb2Mode[] = {
0x00, 0xDE, // 00: B.AL 00000004 ; B encoding T1
0x00, 0xDE, // 02: B.AL 00000006 ; B encoding T1
0x00, (0xDE), // 04: B.AL 00000008 ; B encoding T1
+0x00, +0xDE, // 06: B.AL 0000000A ; B encoding T1
+0x00, 0xE0, // 08: B 0000000C ; B encoding T2
0x00, 0xE0, // 0A: B 0000000E ; B encoding T2
0x00, 0xE0, // 0C: B 00000010 ; B encoding T2
(0x00), +0xE0, // 0E: B 00000012 ; B encoding T2
+0x00, +0xF0, 0x00, 0x80, // 10: B 00000014 ; B encoding T3
0x00, 0xF0, 0x00, 0x80, // 14: B 00000018 ; B encoding T3
(0x00), +0xF0, +0x00, +0x80, // 18: B 0000001C ; B encoding T3
0x00, 0xF0, 0x00, 0x80, // 1C: B 00000020 ; B encoding T3
0x00, 0xF0, 0x00, 0xB8, // 20: B 00000024 ; B encoding T4
0x00, 0xF0, 0x00, (0xB8), // 24: B 00000028 ; B encoding T4
+0xFE, +0xDE, // 28: B.AL 00000028 ; B encoding T1
+0x00, 0xF0, 0x00, 0xF8, // 2A: BL 0000002E ; BL encoding T1
0x00, 0xF0, 0x00, 0xE8, // 2E: BLX 00000030 ; BLX encoding T2
0x00, 0x0B, // 32: NOP
0x00, 0xF0, 0x00, 0xE8, // 34: BLX 00000038 ; BLX encoding T2
0x00, 0xF0, 0x00, 0xB8, // 38: B 0000003C ; B encoding T4
};
// Abs32 locations corresponding to |kDataAarch32Thumb2Mode|, with width = 4.
constexpr offset_t kAbs32Aarch32Thumb2Mode[] = {0x05, 0x0E, 0x18, 0x27};
} // namespace
TEST(Rel32FinderAArch32Test, IntegratedThumb2ModeWithoutAbs32) {
using AddrType = AArch32Rel32Translator::AddrType;
using Result = Rel32FinderAArch32::Result;
std::vector<Result> expected_results = {
{0x00, 0x04, AddrType::ADDR_T8}, {0x02, 0x06, AddrType::ADDR_T8},
{0x04, 0x08, AddrType::ADDR_T8}, {0x06, 0x0A, AddrType::ADDR_T8},
{0x08, 0x0C, AddrType::ADDR_T11}, {0x0A, 0x0E, AddrType::ADDR_T11},
{0x0C, 0x10, AddrType::ADDR_T11}, {0x0E, 0x12, AddrType::ADDR_T11},
{0x10, 0x14, AddrType::ADDR_T20}, {0x14, 0x18, AddrType::ADDR_T20},
{0x18, 0x1C, AddrType::ADDR_T20}, {0x1C, 0x20, AddrType::ADDR_T20},
{0x20, 0x24, AddrType::ADDR_T24}, {0x24, 0x28, AddrType::ADDR_T24},
{0x28, 0x28, AddrType::ADDR_T8}, {0x2A, 0x2E, AddrType::ADDR_T24},
{0x2E, 0x30, AddrType::ADDR_T24}, {0x34, 0x38, AddrType::ADDR_T24},
{0x38, 0x3C, AddrType::ADDR_T24},
};
ConstBufferView image = ConstBufferView::FromRange(
std::begin(kDataAarch32Thumb2Mode), std::end(kDataAarch32Thumb2Mode));
AddressTranslator translator(GetTrivialTranslator(image.size()));
Rel32FinderAArch32 rel32_finder(image, translator, /* is_thumb2 */ true);
std::vector<Result> results = ArmExtractRel32(
image, /* abs32_locations */ {}, DisassemblerElfAArch32::Traits::kVAWidth,
std::move(rel32_finder));
EXPECT_EQ(expected_results, results);
}
TEST(Rel32FinderAArch32Test, IntegratedThumb2ModeWithAbs32) {
using AddrType = AArch32Rel32Translator::AddrType;
using Result = Rel32FinderAArch32::Result;
std::vector<Result> expected_results = {
{0x00, 0x04, AddrType::ADDR_T8},
{0x02, 0x06, AddrType::ADDR_T8},
/* {0x04, 0x08, AddrType::ADDR_T8}, */
/* {0x06, 0x0A, AddrType::ADDR_T8}, */
/* {0x08, 0x0C, AddrType::ADDR_T11}, */
{0x0A, 0x0E, AddrType::ADDR_T11},
{0x0C, 0x10, AddrType::ADDR_T11},
/* {0x0E, 0x12, AddrType::ADDR_T11}, */
/* {0x10, 0x14, AddrType::ADDR_T20}, */
{0x14, 0x18, AddrType::ADDR_T20},
/* {0x18, 0x1C, AddrType::ADDR_T20}, */
{0x1C, 0x20, AddrType::ADDR_T20},
{0x20, 0x24, AddrType::ADDR_T24},
/* {0x24, 0x28, AddrType::ADDR_T24}, */
/* {0x28, 0x28, AddrType::ADDR_T8}, */
/* {0x2A, 0x2E, AddrType::ADDR_T24}, */
// Abs32 reference 0x27 disrupts alignment, and THUMB2 disassembly starts
// at 0x2C, causing the following to be excluded!
/* {0x2E, 0x30, AddrType::ADDR_T24}, */
{0x34, 0x38, AddrType::ADDR_T24},
{0x38, 0x3C, AddrType::ADDR_T24},
};
ConstBufferView image = ConstBufferView::FromRange(
std::begin(kDataAarch32Thumb2Mode), std::end(kDataAarch32Thumb2Mode));
std::vector<offset_t> abs32_locations(std::begin(kAbs32Aarch32Thumb2Mode),
std::end(kAbs32Aarch32Thumb2Mode));
AddressTranslator translator(GetTrivialTranslator(image.size()));
Rel32FinderAArch32 rel32_finder(image, translator, /* is_thumb2 */ true);
std::vector<Result> results = ArmExtractRel32(
image, abs32_locations, DisassemblerElfAArch32::Traits::kVAWidth,
std::move(rel32_finder));
EXPECT_EQ(expected_results, results);
}
namespace {
// AArch32 THUMB2 mode test data. (x) and +x entries are covered by abs32
// references (if used), which have width = 8.
constexpr uint8_t kDataAarch64[] = {
0x0E, 0x00, 0x00, 0x36, // 00: TBZ X0,#0,00000000 ; Immd14
0x0E, 0x00, 0x00, (0x36), // 04: TBZ X0,#0,00000004 ; Immd14
+0x0E, +0x00, +0x00, +0x36, // 08: TBZ X0,#0,00000008 ; Immd14
+0x0E, +0x00, +0x00, 0x54, // 0C: B.AL 0000000C ; Immd19
0x0E, 0x00, 0x00, 0x54, // 10: B.AL 00000010 ; Immd19
(0x0E), +0x00, +0x00, +0x54, // 14: B.AL 00000014 ; Immd19
+0x00, +0x00, +0x00, +0x94, // 18: BL 00000018 ; Immd26
0x00, 0x00, 0x00, 0x14, // 1C: B 0000001C ; Immd26
0x00, 0x00, 0x00, 0x94, // 20: BL 00000020 ; Immd26
0x00, 0x00, 0x00, 0x14, // 24: B 00000024 ; Immd26
};
// Abs32 locations corresponding to |kDataAarch64|, with width = 8.
constexpr offset_t kAbs32Aarch64[] = {0x07, 0x14};
} // namespace
TEST(Rel32FinderAArch64Test, IntegratedWithoutAbs32) {
using AddrType = AArch64Rel32Translator::AddrType;
using Result = Rel32FinderAArch64::Result;
std::vector<Result> expected_results = {
{0x00, 0x00, AddrType::ADDR_IMMD14}, {0x04, 0x04, AddrType::ADDR_IMMD14},
{0x08, 0x08, AddrType::ADDR_IMMD14}, {0x0C, 0x0C, AddrType::ADDR_IMMD19},
{0x10, 0x10, AddrType::ADDR_IMMD19}, {0x14, 0x14, AddrType::ADDR_IMMD19},
{0x18, 0x18, AddrType::ADDR_IMMD26}, {0x1C, 0x1C, AddrType::ADDR_IMMD26},
{0x20, 0x20, AddrType::ADDR_IMMD26}, {0x24, 0x24, AddrType::ADDR_IMMD26},
};
ConstBufferView image = ConstBufferView::FromRange(std::begin(kDataAarch64),
std::end(kDataAarch64));
AddressTranslator translator(GetTrivialTranslator(image.size()));
Rel32FinderAArch64 rel32_finder(image, translator);
std::vector<Result> results = ArmExtractRel32(
image, /* abs32_locations */ {}, DisassemblerElfAArch64::Traits::kVAWidth,
std::move(rel32_finder));
EXPECT_EQ(expected_results, results);
}
TEST(Rel32FinderAArch64Test, IntegratedWithAbs32) {
using AddrType = AArch64Rel32Translator::AddrType;
using Result = Rel32FinderAArch64::Result;
std::vector<Result> expected_results = {
{0x00, 0x00, AddrType::ADDR_IMMD14},
/* {0x04, 0x04, AddrType::ADDR_IMMD14}, */
/* {0x08, 0x08, AddrType::ADDR_IMMD14}, */
/* {0x0C, 0x0C, AddrType::ADDR_IMMD19}, */
{0x10, 0x10, AddrType::ADDR_IMMD19},
/* {0x14, 0x14, AddrType::ADDR_IMMD19}, */
/* {0x18, 0x18, AddrType::ADDR_IMMD26}, */
{0x1C, 0x1C, AddrType::ADDR_IMMD26},
{0x20, 0x20, AddrType::ADDR_IMMD26},
{0x24, 0x24, AddrType::ADDR_IMMD26},
};
ConstBufferView image = ConstBufferView::FromRange(std::begin(kDataAarch64),
std::end(kDataAarch64));
std::vector<offset_t> abs32_locations(std::begin(kAbs32Aarch64),
std::end(kAbs32Aarch64));
AddressTranslator translator(GetTrivialTranslator(image.size()));
Rel32FinderAArch64 rel32_finder(image, translator);
std::vector<Result> results = ArmExtractRel32(
image, abs32_locations, DisassemblerElfAArch64::Traits::kVAWidth,
std::move(rel32_finder));
EXPECT_EQ(expected_results, results);
}
} // namespace zucchini