#include <cassert>
#include <cerrno>
#include <cstring>
#include <fstream>
#include <memory>
#include <random>
#include <sstream>
#include <string>
#include "source/fuzz/force_render_red.h"
#include "source/fuzz/fuzzer.h"
#include "source/fuzz/fuzzer_util.h"
#include "source/fuzz/protobufs/spirvfuzz_protobufs.h"
#include "source/fuzz/pseudo_random_generator.h"
#include "source/fuzz/replayer.h"
#include "source/fuzz/shrinker.h"
#include "source/opt/build_module.h"
#include "source/opt/ir_context.h"
#include "source/opt/log.h"
#include "source/spirv_fuzzer_options.h"
#include "source/util/make_unique.h"
#include "source/util/string_utils.h"
#include "tools/io.h"
#include "tools/util/cli_consumer.h"
namespace {
enum class FuzzingTarget { kSpirv, kWgsl };
bool ExecuteCommand(const std::string& command) {
errno = 0;
int status = std::system(command.c_str());
assert(errno == 0 && "failed to execute command");
return status == 0;
}
enum class FuzzActions {
FORCE_RENDER_RED, FUZZ, REPLAY, SHRINK, STOP };
struct FuzzStatus {
FuzzActions action;
int code;
};
void PrintUsage(const char* program) {
printf(
R"(%s - Fuzzes an equivalent SPIR-V binary based on a given binary.
USAGE: %s [options] <input.spv> -o <output.spv> \
--donors=<donors.txt>
USAGE: %s [options] <input.spv> -o <output.spv> \
--shrink=<input.transformations> -- <interestingness_test> [args...]
The SPIR-V binary is read from <input.spv>. If <input.facts> is also present,
facts about the SPIR-V binary are read from this file.
The transformed SPIR-V binary is written to <output.spv>. Human-readable and
binary representations of the transformations that were applied are written to
<output.transformations_json> and <output.transformations>, respectively.
When passing --shrink=<input.transformations> an <interestingness_test>
must also be provided; this is the path to a script that returns 0 if and only
if a given SPIR-V binary is interesting. The SPIR-V binary will be passed to
the script as an argument after any other provided arguments [args...]. The
"--" characters are optional but denote that all arguments that follow are
positional arguments and thus will be forwarded to the interestingness script,
and not parsed by %s.
NOTE: The fuzzer is a work in progress.
Options (in lexicographical order):
-h, --help
Print this help.
--donors=
File specifying a series of donor files, one per line. Must be
provided if the tool is invoked in fuzzing mode; incompatible
with replay and shrink modes. The file should be empty if no
donors are to be used.
--enable-all-passes
By default, spirv-fuzz follows the philosophy of "swarm testing"
(Groce et al., 2012): only a subset of fuzzer passes are enabled
on any given fuzzer run, with the subset being chosen randomly.
This flag instead forces *all* fuzzer passes to be enabled. When
running spirv-fuzz many times this is likely to produce *less*
diverse fuzzed modules than when swarm testing is used. The
purpose of the flag is to allow that hypothesis to be tested.
--force-render-red
Transforms the input shader into a shader that writes red to the
output buffer, and then captures the original shader as the body
of a conditional with a dynamically false guard. Exploits input
facts to make the guard non-obviously false. This option is a
helper for massaging crash-inducing tests into a runnable
format; it does not perform any fuzzing.
--fuzzer-pass-validation
Run the validator after applying each fuzzer pass during
fuzzing. Aborts fuzzing early if an invalid binary is created.
Useful for debugging spirv-fuzz.
--repeated-pass-strategy=
Available strategies are:
- looped (the default): a sequence of fuzzer passes is chosen at
the start of fuzzing, via randomly choosing enabled passes, and
augmenting these choices with fuzzer passes that it is
recommended to run subsequently. Fuzzing then involves
repeatedly applying this fixed sequence of passes.
- random: each time a fuzzer pass is requested, this strategy
either provides one at random from the set of enabled passes,
or provides a pass that has been recommended based on a pass
that was used previously.
- simple: each time a fuzzer pass is requested, one is provided
at random from the set of enabled passes.
--fuzzing-target=
This option will adjust probabilities of applying certain
transformations s.t. the module always remains valid according
to the semantics of some fuzzing target. Available targets:
- spir-v - module is valid according to the SPIR-V spec.
- wgsl - module is valid according to the WGSL spec.
--replay
File from which to read a sequence of transformations to replay
(instead of fuzzing)
--replay-range=
Signed 32-bit integer. If set to a positive value N, only the
first N transformations will be applied during replay. If set to
a negative value -N, all but the final N transformations will be
applied during replay. If set to 0 (the default), all
transformations will be applied during replay. Ignored unless
--replay is used.
--replay-validation
Run the validator after applying each transformation during
replay (including the replay that occurs during shrinking).
Aborts if an invalid binary is created. Useful for debugging
spirv-fuzz.
--seed=
Unsigned 32-bit integer seed to control random number
generation.
--shrink=
File from which to read a sequence of transformations to shrink
(instead of fuzzing)
--shrinker-step-limit=
Unsigned 32-bit integer specifying maximum number of steps the
shrinker will take before giving up. Ignored unless --shrink
is used.
--shrinker-temp-file-prefix=
Specifies a temporary file prefix that will be used to output
temporary shader files during shrinking. A number and .spv
extension will be added. The default is "temp_", which will
cause files like "temp_0001.spv" to be output to the current
directory. Ignored unless --shrink is used.
--version
Display fuzzer version information.
Supported validator options are as follows. See `spirv-val --help` for details.
--before-hlsl-legalization
--relax-block-layout
--relax-logical-pointer
--relax-struct-store
--scalar-block-layout
--skip-block-layout
)",
program, program, program, program);
}
void FuzzDiagnostic(spv_message_level_t level, const char* ,
const spv_position_t& , const char* message) {
if (level == SPV_MSG_ERROR) {
fprintf(stderr, "error: ");
}
fprintf(stderr, "%s\n", message);
}
FuzzStatus ParseFlags(
int argc, const char** argv, std::string* in_binary_file,
std::string* out_binary_file, std::string* donors_file,
std::string* replay_transformations_file,
std::vector<std::string>* interestingness_test,
std::string* shrink_transformations_file,
std::string* shrink_temp_file_prefix,
spvtools::fuzz::RepeatedPassStrategy* repeated_pass_strategy,
FuzzingTarget* fuzzing_target, spvtools::FuzzerOptions* fuzzer_options,
spvtools::ValidatorOptions* validator_options) {
uint32_t positional_arg_index = 0;
bool only_positional_arguments_remain = false;
bool force_render_red = false;
*repeated_pass_strategy =
spvtools::fuzz::RepeatedPassStrategy::kLoopedWithRecommendations;
for (int argi = 1; argi < argc; ++argi) {
const char* cur_arg = argv[argi];
if ('-' == cur_arg[0] && !only_positional_arguments_remain) {
if (0 == strcmp(cur_arg, "--version")) {
spvtools::Logf(FuzzDiagnostic, SPV_MSG_INFO, nullptr, {}, "%s\n",
spvSoftwareVersionDetailsString());
return {FuzzActions::STOP, 0};
} else if (0 == strcmp(cur_arg, "--help") || 0 == strcmp(cur_arg, "-h")) {
PrintUsage(argv[0]);
return {FuzzActions::STOP, 0};
} else if (0 == strcmp(cur_arg, "-o")) {
if (out_binary_file->empty() && argi + 1 < argc) {
*out_binary_file = std::string(argv[++argi]);
} else {
PrintUsage(argv[0]);
return {FuzzActions::STOP, 1};
}
} else if (0 == strncmp(cur_arg, "--donors=", sizeof("--donors=") - 1)) {
const auto split_flag = spvtools::utils::SplitFlagArgs(cur_arg);
*donors_file = std::string(split_flag.second);
} else if (0 == strncmp(cur_arg, "--enable-all-passes",
sizeof("--enable-all-passes") - 1)) {
fuzzer_options->enable_all_passes();
} else if (0 == strncmp(cur_arg, "--force-render-red",
sizeof("--force-render-red") - 1)) {
force_render_red = true;
} else if (0 == strncmp(cur_arg, "--fuzzer-pass-validation",
sizeof("--fuzzer-pass-validation") - 1)) {
fuzzer_options->enable_fuzzer_pass_validation();
} else if (0 == strncmp(cur_arg, "--replay=", sizeof("--replay=") - 1)) {
const auto split_flag = spvtools::utils::SplitFlagArgs(cur_arg);
*replay_transformations_file = std::string(split_flag.second);
} else if (0 == strncmp(cur_arg, "--repeated-pass-strategy=",
sizeof("--repeated-pass-strategy=") - 1)) {
std::string strategy = spvtools::utils::SplitFlagArgs(cur_arg).second;
if (strategy == "looped") {
*repeated_pass_strategy =
spvtools::fuzz::RepeatedPassStrategy::kLoopedWithRecommendations;
} else if (strategy == "random") {
*repeated_pass_strategy =
spvtools::fuzz::RepeatedPassStrategy::kRandomWithRecommendations;
} else if (strategy == "simple") {
*repeated_pass_strategy =
spvtools::fuzz::RepeatedPassStrategy::kSimple;
} else {
std::stringstream ss;
ss << "Unknown repeated pass strategy '" << strategy << "'"
<< std::endl;
ss << "Valid options are 'looped', 'random' and 'simple'.";
spvtools::Error(FuzzDiagnostic, nullptr, {}, ss.str().c_str());
return {FuzzActions::STOP, 1};
}
} else if (0 == strncmp(cur_arg, "--fuzzing-target=",
sizeof("--fuzzing-target=") - 1)) {
std::string target = spvtools::utils::SplitFlagArgs(cur_arg).second;
if (target == "spir-v") {
*fuzzing_target = FuzzingTarget::kSpirv;
} else if (target == "wgsl") {
*fuzzing_target = FuzzingTarget::kWgsl;
} else {
std::stringstream ss;
ss << "Unknown fuzzing target '" << target << "'" << std::endl;
ss << "Valid options are 'spir-v' and 'wgsl'.";
spvtools::Error(FuzzDiagnostic, nullptr, {}, ss.str().c_str());
return {FuzzActions::STOP, 1};
}
} else if (0 == strncmp(cur_arg, "--replay-range=",
sizeof("--replay-range=") - 1)) {
const auto split_flag = spvtools::utils::SplitFlagArgs(cur_arg);
char* end = nullptr;
errno = 0;
const auto replay_range =
static_cast<int32_t>(strtol(split_flag.second.c_str(), &end, 10));
assert(end != split_flag.second.c_str() && errno == 0);
fuzzer_options->set_replay_range(replay_range);
} else if (0 == strncmp(cur_arg, "--replay-validation",
sizeof("--replay-validation") - 1)) {
fuzzer_options->enable_replay_validation();
} else if (0 == strncmp(cur_arg, "--shrink=", sizeof("--shrink=") - 1)) {
const auto split_flag = spvtools::utils::SplitFlagArgs(cur_arg);
*shrink_transformations_file = std::string(split_flag.second);
} else if (0 == strncmp(cur_arg, "--seed=", sizeof("--seed=") - 1)) {
const auto split_flag = spvtools::utils::SplitFlagArgs(cur_arg);
char* end = nullptr;
errno = 0;
const auto seed =
static_cast<uint32_t>(strtol(split_flag.second.c_str(), &end, 10));
assert(end != split_flag.second.c_str() && errno == 0);
fuzzer_options->set_random_seed(seed);
} else if (0 == strncmp(cur_arg, "--shrinker-step-limit=",
sizeof("--shrinker-step-limit=") - 1)) {
const auto split_flag = spvtools::utils::SplitFlagArgs(cur_arg);
char* end = nullptr;
errno = 0;
const auto step_limit =
static_cast<uint32_t>(strtol(split_flag.second.c_str(), &end, 10));
assert(end != split_flag.second.c_str() && errno == 0);
fuzzer_options->set_shrinker_step_limit(step_limit);
} else if (0 == strncmp(cur_arg, "--shrinker-temp-file-prefix=",
sizeof("--shrinker-temp-file-prefix=") - 1)) {
const auto split_flag = spvtools::utils::SplitFlagArgs(cur_arg);
*shrink_temp_file_prefix = std::string(split_flag.second);
} else if (0 == strcmp(cur_arg, "--before-hlsl-legalization")) {
validator_options->SetBeforeHlslLegalization(true);
} else if (0 == strcmp(cur_arg, "--relax-logical-pointer")) {
validator_options->SetRelaxLogicalPointer(true);
} else if (0 == strcmp(cur_arg, "--relax-block-layout")) {
validator_options->SetRelaxBlockLayout(true);
} else if (0 == strcmp(cur_arg, "--scalar-block-layout")) {
validator_options->SetScalarBlockLayout(true);
} else if (0 == strcmp(cur_arg, "--skip-block-layout")) {
validator_options->SetSkipBlockLayout(true);
} else if (0 == strcmp(cur_arg, "--relax-struct-store")) {
validator_options->SetRelaxStructStore(true);
} else if (0 == strcmp(cur_arg, "--")) {
only_positional_arguments_remain = true;
} else {
std::stringstream ss;
ss << "Unrecognized argument: " << cur_arg << std::endl;
spvtools::Error(FuzzDiagnostic, nullptr, {}, ss.str().c_str());
PrintUsage(argv[0]);
return {FuzzActions::STOP, 1};
}
} else if (positional_arg_index == 0) {
assert(in_binary_file->empty());
*in_binary_file = std::string(cur_arg);
positional_arg_index++;
} else {
interestingness_test->push_back(std::string(cur_arg));
}
}
if (in_binary_file->empty()) {
spvtools::Error(FuzzDiagnostic, nullptr, {}, "No input file specified");
return {FuzzActions::STOP, 1};
}
if (out_binary_file->empty()) {
spvtools::Error(FuzzDiagnostic, nullptr, {}, "-o required");
return {FuzzActions::STOP, 1};
}
auto const_fuzzer_options =
static_cast<spv_const_fuzzer_options>(*fuzzer_options);
if (force_render_red) {
if (!replay_transformations_file->empty() ||
!shrink_transformations_file->empty() ||
const_fuzzer_options->replay_validation_enabled) {
spvtools::Error(FuzzDiagnostic, nullptr, {},
"The --force-render-red argument cannot be used with any "
"other arguments except -o.");
return {FuzzActions::STOP, 1};
}
return {FuzzActions::FORCE_RENDER_RED, 0};
}
if (replay_transformations_file->empty() &&
shrink_transformations_file->empty() &&
static_cast<spv_const_fuzzer_options>(*fuzzer_options)
->replay_validation_enabled) {
spvtools::Error(FuzzDiagnostic, nullptr, {},
"The --replay-validation argument can only be used with "
"one of the --replay or --shrink arguments.");
return {FuzzActions::STOP, 1};
}
if (shrink_transformations_file->empty() && !interestingness_test->empty()) {
spvtools::Error(FuzzDiagnostic, nullptr, {},
"Too many positional arguments specified; extra positional "
"arguments are used as the interestingness function, which "
"are only valid with the --shrink option.");
return {FuzzActions::STOP, 1};
}
if (!shrink_transformations_file->empty() && interestingness_test->empty()) {
spvtools::Error(
FuzzDiagnostic, nullptr, {},
"The --shrink option requires an interestingness function.");
return {FuzzActions::STOP, 1};
}
if (!replay_transformations_file->empty() ||
!shrink_transformations_file->empty()) {
if (!donors_file->empty()) {
spvtools::Error(FuzzDiagnostic, nullptr, {},
"The --donors argument is not compatible with --replay "
"nor --shrink.");
return {FuzzActions::STOP, 1};
}
}
if (!replay_transformations_file->empty()) {
if (!shrink_transformations_file->empty()) {
spvtools::Error(
FuzzDiagnostic, nullptr, {},
"The --replay and --shrink arguments are mutually exclusive.");
return {FuzzActions::STOP, 1};
}
return {FuzzActions::REPLAY, 0};
}
if (!shrink_transformations_file->empty()) {
assert(!interestingness_test->empty() &&
"An error should have been raised if --shrink was provided without "
"an interestingness test.");
return {FuzzActions::SHRINK, 0};
}
if (donors_file->empty()) {
spvtools::Error(FuzzDiagnostic, nullptr, {},
"Fuzzing requires that the --donors option is used.");
return {FuzzActions::STOP, 1};
}
return {FuzzActions::FUZZ, 0};
}
bool ParseTransformations(
const std::string& transformations_file,
spvtools::fuzz::protobufs::TransformationSequence* transformations) {
std::ifstream transformations_stream;
transformations_stream.open(transformations_file,
std::ios::in | std::ios::binary);
auto parse_success =
transformations->ParseFromIstream(&transformations_stream);
transformations_stream.close();
if (!parse_success) {
spvtools::Error(FuzzDiagnostic, nullptr, {},
("Error reading transformations from file '" +
transformations_file + "'")
.c_str());
return false;
}
return true;
}
bool Replay(const spv_target_env& target_env,
spv_const_fuzzer_options fuzzer_options,
spv_validator_options validator_options,
const std::vector<uint32_t>& binary_in,
const spvtools::fuzz::protobufs::FactSequence& initial_facts,
const std::string& replay_transformations_file,
std::vector<uint32_t>* binary_out,
spvtools::fuzz::protobufs::TransformationSequence*
transformations_applied) {
spvtools::fuzz::protobufs::TransformationSequence transformation_sequence;
if (!ParseTransformations(replay_transformations_file,
&transformation_sequence)) {
return false;
}
uint32_t num_transformations_to_apply;
if (fuzzer_options->replay_range > 0) {
num_transformations_to_apply = static_cast<uint32_t>(
std::min(fuzzer_options->replay_range,
transformation_sequence.transformation_size()));
} else {
num_transformations_to_apply = static_cast<uint32_t>(
std::max(0, transformation_sequence.transformation_size() +
fuzzer_options->replay_range));
}
auto replay_result =
spvtools::fuzz::Replayer(
target_env, spvtools::utils::CLIMessageConsumer, binary_in,
initial_facts, transformation_sequence, num_transformations_to_apply,
fuzzer_options->replay_validation_enabled, validator_options)
.Run();
replay_result.transformed_module->module()->ToBinary(binary_out, false);
*transformations_applied = std::move(replay_result.applied_transformations);
return replay_result.status ==
spvtools::fuzz::Replayer::ReplayerResultStatus::kComplete;
}
bool Shrink(const spv_target_env& target_env,
spv_const_fuzzer_options fuzzer_options,
spv_validator_options validator_options,
const std::vector<uint32_t>& binary_in,
const spvtools::fuzz::protobufs::FactSequence& initial_facts,
const std::string& shrink_transformations_file,
const std::string& shrink_temp_file_prefix,
const std::vector<std::string>& interestingness_command,
std::vector<uint32_t>* binary_out,
spvtools::fuzz::protobufs::TransformationSequence*
transformations_applied) {
spvtools::fuzz::protobufs::TransformationSequence transformation_sequence;
if (!ParseTransformations(shrink_transformations_file,
&transformation_sequence)) {
return false;
}
assert(!interestingness_command.empty() &&
"An error should have been raised because the interestingness_command "
"is empty.");
std::stringstream joined;
joined << interestingness_command[0];
for (size_t i = 1, size = interestingness_command.size(); i < size; ++i) {
joined << " " << interestingness_command[i];
}
std::string interestingness_command_joined = joined.str();
spvtools::fuzz::Shrinker::InterestingnessFunction interestingness_function =
[interestingness_command_joined, shrink_temp_file_prefix](
std::vector<uint32_t> binary, uint32_t reductions_applied) -> bool {
std::stringstream ss;
ss << shrink_temp_file_prefix << std::setw(4) << std::setfill('0')
<< reductions_applied << ".spv";
const auto spv_file = ss.str();
const std::string command = interestingness_command_joined + " " + spv_file;
auto write_file_succeeded =
WriteFile(spv_file.c_str(), "wb", &binary[0], binary.size());
(void)(write_file_succeeded);
assert(write_file_succeeded);
return ExecuteCommand(command);
};
auto shrink_result =
spvtools::fuzz::Shrinker(
target_env, spvtools::utils::CLIMessageConsumer, binary_in,
initial_facts, transformation_sequence, interestingness_function,
fuzzer_options->shrinker_step_limit,
fuzzer_options->replay_validation_enabled, validator_options)
.Run();
*binary_out = std::move(shrink_result.transformed_binary);
*transformations_applied = std::move(shrink_result.applied_transformations);
return spvtools::fuzz::Shrinker::ShrinkerResultStatus::kComplete ==
shrink_result.status ||
spvtools::fuzz::Shrinker::ShrinkerResultStatus::kStepLimitReached ==
shrink_result.status;
}
bool Fuzz(const spv_target_env& target_env,
spv_const_fuzzer_options fuzzer_options,
spv_validator_options validator_options,
const std::vector<uint32_t>& binary_in,
const spvtools::fuzz::protobufs::FactSequence& initial_facts,
const std::string& donors,
spvtools::fuzz::RepeatedPassStrategy repeated_pass_strategy,
FuzzingTarget fuzzing_target, std::vector<uint32_t>* binary_out,
spvtools::fuzz::protobufs::TransformationSequence*
transformations_applied) {
auto message_consumer = spvtools::utils::CLIMessageConsumer;
std::vector<spvtools::fuzz::fuzzerutil::ModuleSupplier> donor_suppliers;
std::ifstream donors_file(donors);
if (!donors_file) {
spvtools::Error(FuzzDiagnostic, nullptr, {}, "Error opening donors file");
return false;
}
std::string donor_filename;
while (std::getline(donors_file, donor_filename)) {
donor_suppliers.emplace_back(
[donor_filename, message_consumer,
target_env]() -> std::unique_ptr<spvtools::opt::IRContext> {
std::vector<uint32_t> donor_binary;
if (!ReadBinaryFile(donor_filename.c_str(), &donor_binary)) {
return nullptr;
}
return spvtools::BuildModule(target_env, message_consumer,
donor_binary.data(),
donor_binary.size());
});
}
std::unique_ptr<spvtools::opt::IRContext> ir_context;
if (!spvtools::fuzz::fuzzerutil::BuildIRContext(target_env, message_consumer,
binary_in, validator_options,
&ir_context)) {
spvtools::Error(FuzzDiagnostic, nullptr, {}, "Initial binary is invalid");
return false;
}
assert((fuzzing_target == FuzzingTarget::kWgsl ||
fuzzing_target == FuzzingTarget::kSpirv) &&
"Not all fuzzing targets are handled");
auto fuzzer_context = spvtools::MakeUnique<spvtools::fuzz::FuzzerContext>(
spvtools::MakeUnique<spvtools::fuzz::PseudoRandomGenerator>(
fuzzer_options->has_random_seed
? fuzzer_options->random_seed
: static_cast<uint32_t>(std::random_device()())),
spvtools::fuzz::FuzzerContext::GetMinFreshId(ir_context.get()),
fuzzing_target == FuzzingTarget::kWgsl);
auto transformation_context =
spvtools::MakeUnique<spvtools::fuzz::TransformationContext>(
spvtools::MakeUnique<spvtools::fuzz::FactManager>(ir_context.get()),
validator_options);
transformation_context->GetFactManager()->AddInitialFacts(message_consumer,
initial_facts);
spvtools::fuzz::Fuzzer fuzzer(
std::move(ir_context), std::move(transformation_context),
std::move(fuzzer_context), message_consumer, donor_suppliers,
fuzzer_options->all_passes_enabled, repeated_pass_strategy,
fuzzer_options->fuzzer_pass_validation_enabled, validator_options, false);
auto fuzz_result = fuzzer.Run(0);
if (fuzz_result.status ==
spvtools::fuzz::Fuzzer::Status::kFuzzerPassLedToInvalidModule) {
spvtools::Error(FuzzDiagnostic, nullptr, {}, "Error running fuzzer");
return false;
}
fuzzer.GetIRContext()->module()->ToBinary(binary_out, true);
*transformations_applied = fuzzer.GetTransformationSequence();
return true;
}
}
void DumpShader(const std::vector<uint32_t>& binary, const char* filename) {
auto write_file_succeeded =
WriteFile(filename, "wb", &binary[0], binary.size());
if (!write_file_succeeded) {
std::cerr << "Failed to dump shader" << std::endl;
}
}
void DumpShader(spvtools::opt::IRContext* context, const char* filename) {
std::vector<uint32_t> binary;
context->module()->ToBinary(&binary, false);
DumpShader(binary, filename);
}
void DumpTransformationsBinary(
const spvtools::fuzz::protobufs::TransformationSequence& transformations,
const char* filename) {
std::ofstream transformations_file;
transformations_file.open(filename, std::ios::out | std::ios::binary);
transformations.SerializeToOstream(&transformations_file);
transformations_file.close();
}
void DumpTransformationsJson(
const spvtools::fuzz::protobufs::TransformationSequence& transformations,
const char* filename) {
std::string json_string;
auto json_options = google::protobuf::util::JsonPrintOptions();
json_options.add_whitespace = true;
auto json_generation_status = google::protobuf::util::MessageToJsonString(
transformations, &json_string, json_options);
if (json_generation_status.ok()) {
std::ofstream transformations_json_file(filename);
transformations_json_file << json_string;
transformations_json_file.close();
}
}
const auto kDefaultEnvironment = SPV_ENV_UNIVERSAL_1_3;
int main(int argc, const char** argv) {
std::string in_binary_file;
std::string out_binary_file;
std::string donors_file;
std::string replay_transformations_file;
std::vector<std::string> interestingness_test;
std::string shrink_transformations_file;
std::string shrink_temp_file_prefix = "temp_";
spvtools::fuzz::RepeatedPassStrategy repeated_pass_strategy;
auto fuzzing_target = FuzzingTarget::kSpirv;
spvtools::FuzzerOptions fuzzer_options;
spvtools::ValidatorOptions validator_options;
FuzzStatus status =
ParseFlags(argc, argv, &in_binary_file, &out_binary_file, &donors_file,
&replay_transformations_file, &interestingness_test,
&shrink_transformations_file, &shrink_temp_file_prefix,
&repeated_pass_strategy, &fuzzing_target, &fuzzer_options,
&validator_options);
if (status.action == FuzzActions::STOP) {
return status.code;
}
std::vector<uint32_t> binary_in;
if (!ReadBinaryFile(in_binary_file.c_str(), &binary_in)) {
return 1;
}
spvtools::fuzz::protobufs::FactSequence initial_facts;
size_t dot_pos = in_binary_file.rfind('.');
std::string in_facts_file = in_binary_file.substr(0, dot_pos) + ".facts";
std::ifstream facts_input(in_facts_file);
if (facts_input) {
std::string facts_json_string((std::istreambuf_iterator<char>(facts_input)),
std::istreambuf_iterator<char>());
facts_input.close();
if (!google::protobuf::util::JsonStringToMessage(facts_json_string,
&initial_facts)
.ok()) {
spvtools::Error(FuzzDiagnostic, nullptr, {}, "Error reading facts data");
return 1;
}
}
std::vector<uint32_t> binary_out;
spvtools::fuzz::protobufs::TransformationSequence transformations_applied;
spv_target_env target_env = kDefaultEnvironment;
switch (status.action) {
case FuzzActions::FORCE_RENDER_RED:
if (!spvtools::fuzz::ForceRenderRed(
target_env, validator_options, binary_in, initial_facts,
spvtools::utils::CLIMessageConsumer, &binary_out)) {
return 1;
}
break;
case FuzzActions::FUZZ:
if (!Fuzz(target_env, fuzzer_options, validator_options, binary_in,
initial_facts, donors_file, repeated_pass_strategy,
fuzzing_target, &binary_out, &transformations_applied)) {
return 1;
}
break;
case FuzzActions::REPLAY:
if (!Replay(target_env, fuzzer_options, validator_options, binary_in,
initial_facts, replay_transformations_file, &binary_out,
&transformations_applied)) {
return 1;
}
break;
case FuzzActions::SHRINK: {
if (!Shrink(target_env, fuzzer_options, validator_options, binary_in,
initial_facts, shrink_transformations_file,
shrink_temp_file_prefix, interestingness_test, &binary_out,
&transformations_applied)) {
return 1;
}
} break;
default:
assert(false && "Unknown fuzzer action.");
break;
}
if (!WriteFile<uint32_t>(out_binary_file.c_str(), "wb", binary_out.data(),
binary_out.size())) {
spvtools::Error(FuzzDiagnostic, nullptr, {}, "Error writing out binary");
return 1;
}
if (status.action != FuzzActions::FORCE_RENDER_RED) {
dot_pos = out_binary_file.rfind('.');
std::string output_file_prefix = out_binary_file.substr(0, dot_pos);
std::ofstream transformations_file;
transformations_file.open(output_file_prefix + ".transformations",
std::ios::out | std::ios::binary);
bool success =
transformations_applied.SerializeToOstream(&transformations_file);
transformations_file.close();
if (!success) {
spvtools::Error(FuzzDiagnostic, nullptr, {},
"Error writing out transformations binary");
return 1;
}
std::string json_string;
auto json_options = google::protobuf::util::JsonPrintOptions();
json_options.add_whitespace = true;
auto json_generation_status = google::protobuf::util::MessageToJsonString(
transformations_applied, &json_string, json_options);
if (!json_generation_status.ok()) {
spvtools::Error(FuzzDiagnostic, nullptr, {},
"Error writing out transformations in JSON format");
return 1;
}
std::ofstream transformations_json_file(output_file_prefix +
".transformations_json");
transformations_json_file << json_string;
transformations_json_file.close();
}
return 0;
}