blob: 879308552e4c9f25c823189a5d327cb5fd67fa05 [file] [log] [blame]
/******************************************************************************
*
* Copyright (C) 2021 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at:
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*
******************************************************************************/
#include <stdint.h>
#include <sys/wait.h>
#include <unistd.h>
#include <algorithm>
#include <memory>
#include <string>
#include <utility>
#include <vector>
#include <Serializer.h>
#include <android-base/file.h>
#include <android/content/AttributionSourceState.h>
#include <libxml/parser.h>
#include <libxml/xinclude.h>
#include <media/AudioPolicy.h>
#include <media/AudioProfile.h>
#include <media/PatchBuilder.h>
#include <media/RecordingActivityTracker.h>
#include <AudioPolicyInterface.h>
#include <android_audio_policy_configuration_V7_0-enums.h>
#include <fuzzer/FuzzedDataProvider.h>
#include <tests/AudioPolicyManagerTestClient.h>
#include <tests/AudioPolicyTestClient.h>
#include <tests/AudioPolicyTestManager.h>
#include <xsdc/XsdcSupport.h>
using namespace android;
namespace xsd {
using namespace ::android::audio::policy::configuration::V7_0;
}
using content::AttributionSourceState;
static const std::vector<audio_format_t> kAudioFormats = [] {
std::vector<audio_format_t> result;
for (const auto enumVal : xsdc_enum_range<xsd::AudioFormat>{}) {
audio_format_t audioFormatHal;
std::string audioFormat = toString(enumVal);
if (audio_format_from_string(audioFormat.c_str(), &audioFormatHal)) {
result.push_back(audioFormatHal);
}
}
return result;
}();
static const std::vector<audio_channel_mask_t> kAudioChannelOutMasks = [] {
std::vector<audio_channel_mask_t> result;
for (const auto enumVal : xsdc_enum_range<xsd::AudioChannelMask>{}) {
audio_channel_mask_t audioChannelMaskHal;
std::string audioChannelMask = toString(enumVal);
if (enumVal != xsd::AudioChannelMask::AUDIO_CHANNEL_NONE &&
audioChannelMask.find("_IN_") == std::string::npos &&
audio_channel_mask_from_string(audioChannelMask.c_str(), &audioChannelMaskHal)) {
result.push_back(audioChannelMaskHal);
}
}
return result;
}();
static const std::vector<audio_channel_mask_t> kAudioChannelInMasks = [] {
std::vector<audio_channel_mask_t> result;
for (const auto enumVal : xsdc_enum_range<xsd::AudioChannelMask>{}) {
audio_channel_mask_t audioChannelMaskHal;
std::string audioChannelMask = toString(enumVal);
if (enumVal != xsd::AudioChannelMask::AUDIO_CHANNEL_NONE &&
audioChannelMask.find("_OUT_") == std::string::npos &&
audio_channel_mask_from_string(audioChannelMask.c_str(), &audioChannelMaskHal)) {
result.push_back(audioChannelMaskHal);
}
}
return result;
}();
static const std::vector<audio_output_flags_t> kAudioOutputFlags = [] {
std::vector<audio_output_flags_t> result;
for (const auto enumVal : xsdc_enum_range<xsd::AudioInOutFlag>{}) {
audio_output_flags_t audioOutputFlagHal;
std::string audioOutputFlag = toString(enumVal);
if (audioOutputFlag.find("_OUTPUT_") != std::string::npos &&
audio_output_flag_from_string(audioOutputFlag.c_str(), &audioOutputFlagHal)) {
result.push_back(audioOutputFlagHal);
}
}
return result;
}();
static const std::vector<audio_devices_t> kAudioDevices = [] {
std::vector<audio_devices_t> result;
for (const auto enumVal : xsdc_enum_range<xsd::AudioDevice>{}) {
audio_devices_t audioDeviceHal;
std::string audioDevice = toString(enumVal);
if (audio_device_from_string(audioDevice.c_str(), &audioDeviceHal)) {
result.push_back(audioDeviceHal);
}
}
return result;
}();
static const std::vector<audio_usage_t> kAudioUsages = [] {
std::vector<audio_usage_t> result;
for (const auto enumVal : xsdc_enum_range<xsd::AudioUsage>{}) {
audio_usage_t audioUsageHal;
std::string audioUsage = toString(enumVal);
if (audio_usage_from_string(audioUsage.c_str(), &audioUsageHal)) {
result.push_back(audioUsageHal);
}
}
return result;
}();
/**
* AudioSource - AUDIO_SOURCE_VOICE_COMMUNICATION and AUDIO_SOURCE_HOTWORD
* are excluded from kAudioSources[] in order to avoid the abort triggered
* for these two types of AudioSource in Engine::getDeviceForInputSource()
*/
static const std::vector<audio_source_t> kAudioSources = [] {
std::vector<audio_source_t> result;
for (const auto enumVal : xsdc_enum_range<xsd::AudioSource>{}) {
audio_source_t audioSourceHal;
std::string audioSource = toString(enumVal);
if (enumVal != xsd::AudioSource::AUDIO_SOURCE_VOICE_COMMUNICATION &&
enumVal != xsd::AudioSource::AUDIO_SOURCE_HOTWORD &&
audio_source_from_string(audioSource.c_str(), &audioSourceHal)) {
result.push_back(audioSourceHal);
}
}
return result;
}();
static const std::vector<audio_content_type_t> kAudioContentTypes = [] {
std::vector<audio_content_type_t> result;
for (const auto enumVal : xsdc_enum_range<xsd::AudioContentType>{}) {
audio_content_type_t audioContentTypeHal;
std::string audioContentType = toString(enumVal);
if (audio_content_type_from_string(audioContentType.c_str(), &audioContentTypeHal)) {
result.push_back(audioContentTypeHal);
}
}
return result;
}();
std::vector<int> kMixTypes = {MIX_TYPE_PLAYERS, MIX_TYPE_RECORDERS};
std::vector<int> kMixRouteFlags = {MIX_ROUTE_FLAG_RENDER, MIX_ROUTE_FLAG_LOOP_BACK,
MIX_ROUTE_FLAG_LOOP_BACK_AND_RENDER, MIX_ROUTE_FLAG_ALL};
std::vector<audio_flags_mask_t> kAudioFlagMasks = {
AUDIO_FLAG_NONE, AUDIO_FLAG_AUDIBILITY_ENFORCED,
AUDIO_FLAG_SECURE, AUDIO_FLAG_SCO,
AUDIO_FLAG_BEACON, AUDIO_FLAG_HW_AV_SYNC,
AUDIO_FLAG_HW_HOTWORD, AUDIO_FLAG_BYPASS_INTERRUPTION_POLICY,
AUDIO_FLAG_BYPASS_MUTE, AUDIO_FLAG_LOW_LATENCY,
AUDIO_FLAG_DEEP_BUFFER, AUDIO_FLAG_NO_MEDIA_PROJECTION,
AUDIO_FLAG_MUTE_HAPTIC, AUDIO_FLAG_NO_SYSTEM_CAPTURE,
AUDIO_FLAG_CAPTURE_PRIVATE, AUDIO_FLAG_CONTENT_SPATIALIZED,
AUDIO_FLAG_NEVER_SPATIALIZE,
};
std::vector<audio_policy_dev_state_t> kAudioPolicyDeviceStates = {
AUDIO_POLICY_DEVICE_STATE_UNAVAILABLE,
AUDIO_POLICY_DEVICE_STATE_AVAILABLE,
AUDIO_POLICY_DEVICE_STATE_CNT,
};
std::vector<uint32_t> kSamplingRates = {8000, 16000, 44100, 48000, 88200, 96000};
template <typename T>
T getValueFromVector(FuzzedDataProvider *fdp, std::vector<T> arr) {
if (fdp->ConsumeBool()) {
return arr[fdp->ConsumeIntegralInRange<int32_t>(0, arr.size() - 1)];
} else {
return (T)fdp->ConsumeIntegral<uint32_t>();
}
}
class AudioPolicyManagerFuzzer {
public:
explicit AudioPolicyManagerFuzzer(FuzzedDataProvider *fdp);
virtual ~AudioPolicyManagerFuzzer() = default;
virtual bool initialize();
virtual void SetUpManagerConfig();
bool getOutputForAttr(audio_port_handle_t *selectedDeviceId, audio_format_t format,
audio_channel_mask_t channelMask, int sampleRate,
audio_output_flags_t flags = AUDIO_OUTPUT_FLAG_NONE,
audio_io_handle_t *output = nullptr,
audio_port_handle_t *portId = nullptr, audio_attributes_t attr = {});
bool getInputForAttr(const audio_attributes_t &attr, audio_unique_id_t riid,
audio_port_handle_t *selectedDeviceId, audio_format_t format,
audio_channel_mask_t channelMask, int sampleRate,
audio_input_flags_t flags = AUDIO_INPUT_FLAG_NONE,
audio_port_handle_t *portId = nullptr);
bool findDevicePort(audio_port_role_t role, audio_devices_t deviceType,
const std::string &address, audio_port_v7 *foundPort);
static audio_port_handle_t getDeviceIdFromPatch(const struct audio_patch *patch);
audio_patch createFuzzedPatch();
void fuzzPatchCreation();
virtual void process();
protected:
sp<AudioPolicyConfig> mConfig{AudioPolicyConfig::createWritableForTests()};
std::unique_ptr<AudioPolicyManagerTestClient> mClient{new AudioPolicyManagerTestClient};
std::unique_ptr<AudioPolicyTestManager> mManager;
FuzzedDataProvider *mFdp;
};
AudioPolicyManagerFuzzer::AudioPolicyManagerFuzzer(FuzzedDataProvider *fdp)
: mFdp(fdp) {}
bool AudioPolicyManagerFuzzer::initialize() {
if (mFdp->remaining_bytes() < 1) {
return false;
}
// init code
SetUpManagerConfig();
if (mConfig == nullptr) {
return false;
}
mManager.reset(new AudioPolicyTestManager(mConfig, mClient.get()));
if (mManager->initialize() != NO_ERROR) {
return false;
}
if (mManager->initCheck() != NO_ERROR) {
return false;
}
return true;
}
void AudioPolicyManagerFuzzer::SetUpManagerConfig() { mConfig->setDefault(); }
bool AudioPolicyManagerFuzzer::getOutputForAttr(
audio_port_handle_t *selectedDeviceId, audio_format_t format, audio_channel_mask_t channelMask,
int sampleRate, audio_output_flags_t flags, audio_io_handle_t *output,
audio_port_handle_t *portId, audio_attributes_t attr) {
audio_io_handle_t localOutput;
if (!output) output = &localOutput;
*output = AUDIO_IO_HANDLE_NONE;
audio_stream_type_t stream = AUDIO_STREAM_DEFAULT;
audio_config_t config = AUDIO_CONFIG_INITIALIZER;
config.sample_rate = sampleRate;
config.channel_mask = channelMask;
config.format = format;
audio_port_handle_t localPortId;
if (!portId) portId = &localPortId;
*portId = AUDIO_PORT_HANDLE_NONE;
AudioPolicyInterface::output_type_t outputType;
bool isSpatialized;
bool isBitPerfect;
// TODO b/182392769: use attribution source util
AttributionSourceState attributionSource;
attributionSource.uid = 0;
attributionSource.token = sp<BBinder>::make();
if (mManager->getOutputForAttr(&attr, output, AUDIO_SESSION_NONE, &stream, attributionSource,
&config, &flags, selectedDeviceId, portId, {}, &outputType, &isSpatialized,
&isBitPerfect) != OK) {
return false;
}
if (*output == AUDIO_IO_HANDLE_NONE || *portId == AUDIO_PORT_HANDLE_NONE) {
return false;
}
return true;
}
bool AudioPolicyManagerFuzzer::getInputForAttr(
const audio_attributes_t &attr, audio_unique_id_t riid, audio_port_handle_t *selectedDeviceId,
audio_format_t format, audio_channel_mask_t channelMask, int sampleRate,
audio_input_flags_t flags, audio_port_handle_t *portId) {
audio_io_handle_t input = AUDIO_IO_HANDLE_NONE;
audio_config_base_t config = AUDIO_CONFIG_BASE_INITIALIZER;
config.sample_rate = sampleRate;
config.channel_mask = channelMask;
config.format = format;
audio_port_handle_t localPortId;
if (!portId) portId = &localPortId;
*portId = AUDIO_PORT_HANDLE_NONE;
AudioPolicyInterface::input_type_t inputType;
AttributionSourceState attributionSource;
attributionSource.uid = 0;
attributionSource.token = sp<BBinder>::make();
if (mManager->getInputForAttr(&attr, &input, riid, AUDIO_SESSION_NONE, attributionSource,
&config, flags, selectedDeviceId, &inputType, portId) != OK) {
return false;
}
if (*portId == AUDIO_PORT_HANDLE_NONE || input == AUDIO_IO_HANDLE_NONE) {
return false;
}
return true;
}
bool AudioPolicyManagerFuzzer::findDevicePort(audio_port_role_t role, audio_devices_t deviceType,
const std::string &address,
audio_port_v7 *foundPort) {
uint32_t numPorts = 0;
uint32_t generation1;
status_t ret;
ret = mManager->listAudioPorts(role, AUDIO_PORT_TYPE_DEVICE, &numPorts, nullptr, &generation1);
if (ret != NO_ERROR) {
return false;
}
uint32_t generation2;
struct audio_port_v7 ports[numPorts];
ret = mManager->listAudioPorts(role, AUDIO_PORT_TYPE_DEVICE, &numPorts, ports, &generation2);
if (ret != NO_ERROR) {
return false;
}
for (const auto &port : ports) {
if (port.role == role && port.ext.device.type == deviceType &&
(strncmp(port.ext.device.address, address.c_str(), AUDIO_DEVICE_MAX_ADDRESS_LEN) ==
0)) {
if (foundPort) *foundPort = port;
return true;
}
}
return false;
}
audio_port_handle_t AudioPolicyManagerFuzzer::getDeviceIdFromPatch(
const struct audio_patch *patch) {
if (patch->num_sources != 0 && patch->num_sinks != 0) {
if (patch->sources[0].type == AUDIO_PORT_TYPE_MIX) {
return patch->sinks[0].id;
} else {
return patch->sources[0].id;
}
}
return AUDIO_PORT_HANDLE_NONE;
}
audio_patch AudioPolicyManagerFuzzer::createFuzzedPatch() {
audio_patch patch{};
patch.id = mFdp->ConsumeIntegral<uint32_t>();
patch.num_sources = mFdp->ConsumeIntegralInRange(0, AUDIO_PATCH_PORTS_MAX);
for (int i = 0; i < patch.num_sources; ++i) {
audio_port_config config{};
std::vector<uint8_t> bytes = mFdp->ConsumeBytes<uint8_t>(sizeof(config));
memcpy(reinterpret_cast<uint8_t *>(&config), &bytes[0], bytes.size());
patch.sources[i] = config;
}
patch.num_sinks = mFdp->ConsumeIntegralInRange(0, AUDIO_PATCH_PORTS_MAX);
for (int i = 0; i < patch.num_sinks; ++i) {
audio_port_config config{};
std::vector<uint8_t> bytes = mFdp->ConsumeBytes<uint8_t>(sizeof(config));
memcpy(reinterpret_cast<uint8_t *>(&config), &bytes[0], bytes.size());
patch.sinks[i] = config;
}
return patch;
}
void AudioPolicyManagerFuzzer::fuzzPatchCreation() {
if (mFdp->remaining_bytes()) {
audio_patch_handle_t handle = AUDIO_PATCH_HANDLE_NONE;
uid_t uid = mFdp->ConsumeIntegral<uint32_t>();
// create a fuzzed patch
handle = AUDIO_PATCH_HANDLE_NONE;
audio_patch patch = createFuzzedPatch();
uid = mFdp->ConsumeIntegral<uint32_t>();
if (mManager->createAudioPatch(&patch, &handle, uid) == NO_ERROR) {
mManager->releaseAudioPatch(handle, uid);
}
}
}
void AudioPolicyManagerFuzzer::process() {
if (initialize()) {
fuzzPatchCreation();
}
}
class AudioPolicyManagerFuzzerWithConfigurationFile : public AudioPolicyManagerFuzzer {
public:
explicit AudioPolicyManagerFuzzerWithConfigurationFile(FuzzedDataProvider *fdp)
: AudioPolicyManagerFuzzer(fdp){};
protected:
void SetUpManagerConfig() override;
virtual std::string getConfigFile();
void traverseAndFuzzXML(xmlDocPtr pDoc, xmlNodePtr curr);
std::string fuzzXML(std::string xmlPath);
static inline const std::string sExecutableDir = base::GetExecutableDirectory() + "/";
static inline const std::string sDefaultConfig =
sExecutableDir + "data/test_audio_policy_configuration.xml";
static inline const std::string sFuzzedConfig = sExecutableDir + "fuzzed.xml";;
};
std::string AudioPolicyManagerFuzzerWithConfigurationFile::getConfigFile() {
return fuzzXML(sDefaultConfig);
}
void AudioPolicyManagerFuzzerWithConfigurationFile::SetUpManagerConfig() {
const std::string configFilePath = getConfigFile();
auto result = AudioPolicyConfig::loadFromCustomXmlConfigForTests(configFilePath);
mConfig = result.ok() ? mConfig = result.value() : nullptr;
ALOGE_IF(!result.ok(), "%s: Failed to deserialize \"%s\": %d",
__func__, configFilePath.c_str(), result.error());
}
void AudioPolicyManagerFuzzerWithConfigurationFile::traverseAndFuzzXML(xmlDocPtr pDoc,
xmlNodePtr curr) {
if (curr == nullptr) {
return;
}
xmlAttr *attribute = curr->properties;
while (attribute) {
if (!xmlStrcmp(attribute->name, reinterpret_cast<const xmlChar *>("format"))) {
const char *newFormat =
audio_format_to_string(getValueFromVector<audio_format_t>(mFdp, kAudioFormats));
xmlSetProp(curr, attribute->name, reinterpret_cast<const xmlChar *>(newFormat));
}
if (!xmlStrcmp(attribute->name, reinterpret_cast<const xmlChar *>("flags"))) {
std::string newFlag = "";
uint16_t numFlags = std::max((uint16_t)1, mFdp->ConsumeIntegral<uint16_t>());
for (uint16_t i = 0; i < numFlags; ++i) {
newFlag += std::string(audio_output_flag_to_string(
getValueFromVector<audio_output_flags_t>(mFdp, kAudioOutputFlags)));
if (i != (numFlags - 1)) {
newFlag += std::string("|");
}
}
xmlSetProp(curr, attribute->name, reinterpret_cast<const xmlChar *>(newFlag.c_str()));
}
if (!xmlStrcmp(attribute->name, reinterpret_cast<const xmlChar *>("samplingRates"))) {
std::string newRate = "";
uint16_t numRates = std::max((uint16_t)1, mFdp->ConsumeIntegral<uint16_t>());
for (uint16_t i = 0; i < numRates; ++i) {
newRate += std::to_string(getValueFromVector<uint32_t>(mFdp, kSamplingRates));
if (i != (numRates - 1)) {
newRate += std::string(",");
}
}
xmlSetProp(curr, attribute->name, reinterpret_cast<const xmlChar *>(newRate.c_str()));
}
if (!xmlStrcmp(attribute->name, reinterpret_cast<const xmlChar *>("channelMasks"))) {
int isOutMask = -1;
char *value =
reinterpret_cast<char *>(xmlNodeListGetString(pDoc, attribute->children, 1));
if (std::string(value).find(std::string("_OUT_")) != std::string::npos) {
// OUT mask
isOutMask = 1;
} else if (std::string(value).find(std::string("_IN_")) != std::string::npos) {
// IN mask
isOutMask = 0;
}
if (isOutMask != -1) {
std::string newMask = "";
uint16_t numMasks = std::max((uint16_t)1, mFdp->ConsumeIntegral<uint16_t>());
for (uint16_t i = 0; i < numMasks; ++i) {
if (isOutMask) {
newMask += std::string(audio_channel_out_mask_to_string(
getValueFromVector<audio_channel_mask_t>(mFdp, kAudioChannelOutMasks)));
} else {
newMask += std::string(audio_channel_in_mask_to_string(
getValueFromVector<audio_channel_mask_t>(mFdp, kAudioChannelInMasks)));
}
if (i != (numMasks - 1)) {
newMask += std::string(",");
}
}
xmlSetProp(curr, attribute->name,
reinterpret_cast<const xmlChar *>(newMask.c_str()));
}
xmlFree(value);
}
attribute = attribute->next;
}
curr = curr->xmlChildrenNode;
while (curr != nullptr) {
traverseAndFuzzXML(pDoc, curr);
curr = curr->next;
}
}
std::string AudioPolicyManagerFuzzerWithConfigurationFile::fuzzXML(std::string xmlPath) {
std::string outPath = sFuzzedConfig;
// Load in the xml file from disk
xmlDocPtr pDoc = xmlParseFile(xmlPath.c_str());
xmlNodePtr root = xmlDocGetRootElement(pDoc);
traverseAndFuzzXML(pDoc, root);
// Save the document back out to disk.
xmlSaveFileEnc(outPath.c_str(), pDoc, "UTF-8");
xmlFreeDoc(pDoc);
return outPath;
}
class AudioPolicyManagerFuzzerMsd : public AudioPolicyManagerFuzzerWithConfigurationFile {
public:
explicit AudioPolicyManagerFuzzerMsd(FuzzedDataProvider *fdp)
: AudioPolicyManagerFuzzerWithConfigurationFile(fdp) {}
protected:
std::string getConfigFile() override;
static inline const std::string sMsdConfig =
sExecutableDir + "data/test_audio_policy_msd_configuration.xml";
};
std::string AudioPolicyManagerFuzzerMsd::getConfigFile() { return fuzzXML(sMsdConfig); }
using PolicyMixTuple = std::tuple<audio_usage_t, audio_source_t, uint32_t>;
class AudioPolicyManagerFuzzerDynamicPolicy : public AudioPolicyManagerFuzzerWithConfigurationFile {
public:
explicit AudioPolicyManagerFuzzerDynamicPolicy(FuzzedDataProvider *fdp)
: AudioPolicyManagerFuzzerWithConfigurationFile(fdp){};
~AudioPolicyManagerFuzzerDynamicPolicy() override;
void process() override;
protected:
status_t addPolicyMix(int mixType, int mixFlag, audio_devices_t deviceType,
std::string mixAddress, const audio_config_t &audioConfig,
const std::vector<PolicyMixTuple> &rules);
void clearPolicyMix();
void registerPolicyMixes();
void unregisterPolicyMixes();
Vector<AudioMix> mAudioMixes;
const std::string mMixAddress = "remote_submix_media";
};
AudioPolicyManagerFuzzerDynamicPolicy::~AudioPolicyManagerFuzzerDynamicPolicy() {
clearPolicyMix();
}
status_t AudioPolicyManagerFuzzerDynamicPolicy::addPolicyMix(
int mixType, int mixFlag, audio_devices_t deviceType, std::string mixAddress,
const audio_config_t &audioConfig, const std::vector<PolicyMixTuple> &rules) {
std::vector<AudioMixMatchCriterion> myMixMatchCriteria;
myMixMatchCriteria.reserve(rules.size());
for (const auto &rule : rules) {
myMixMatchCriteria.push_back(
AudioMixMatchCriterion(std::get<0>(rule), std::get<1>(rule), std::get<2>(rule)));
}
AudioMix myAudioMix(myMixMatchCriteria, mixType, audioConfig, mixFlag,
String8(mixAddress.c_str()), 0);
myAudioMix.mDeviceType = deviceType;
// Clear mAudioMix before add new one to make sure we don't add already existing mixes.
mAudioMixes.clear();
mAudioMixes.add(myAudioMix);
// As the policy mixes registration may fail at some case,
// caller need to check the returned status.
status_t ret = mManager->registerPolicyMixes(mAudioMixes);
return ret;
}
void AudioPolicyManagerFuzzerDynamicPolicy::clearPolicyMix() {
if (mManager != nullptr) {
mManager->unregisterPolicyMixes(mAudioMixes);
}
mAudioMixes.clear();
}
void AudioPolicyManagerFuzzerDynamicPolicy::registerPolicyMixes() {
const uint32_t numPolicies = mFdp->ConsumeIntegralInRange<uint32_t>(1, MAX_MIXES_PER_POLICY);
for (int i = 0; i < numPolicies; ++i) {
audio_config_t audioConfig = AUDIO_CONFIG_INITIALIZER;
audioConfig.channel_mask = getValueFromVector<audio_channel_mask_t>(
mFdp, mFdp->ConsumeBool() ? kAudioChannelInMasks : kAudioChannelOutMasks);
audioConfig.format = getValueFromVector<audio_format_t>(mFdp, kAudioFormats);
audioConfig.sample_rate = getValueFromVector<uint32_t>(mFdp, kSamplingRates);
addPolicyMix(getValueFromVector<int>(mFdp, kMixTypes),
getValueFromVector<int>(mFdp, kMixRouteFlags),
getValueFromVector<audio_devices_t>(mFdp, kAudioDevices), "", audioConfig,
std::vector<PolicyMixTuple>());
}
}
void AudioPolicyManagerFuzzerDynamicPolicy::unregisterPolicyMixes() {
mManager->unregisterPolicyMixes(mAudioMixes);
}
void AudioPolicyManagerFuzzerDynamicPolicy::process() {
if (initialize()) {
registerPolicyMixes();
fuzzPatchCreation();
unregisterPolicyMixes();
}
}
class AudioPolicyManagerFuzzerDPNoRemoteSubmixModule
: public AudioPolicyManagerFuzzerDynamicPolicy {
public:
explicit AudioPolicyManagerFuzzerDPNoRemoteSubmixModule(FuzzedDataProvider *fdp)
: AudioPolicyManagerFuzzerDynamicPolicy(fdp){};
protected:
std::string getConfigFile() override;
static inline const std::string sPrimaryOnlyConfig =
sExecutableDir + "data/test_audio_policy_primary_only_configuration.xml";
};
std::string AudioPolicyManagerFuzzerDPNoRemoteSubmixModule::getConfigFile() {
return fuzzXML(sPrimaryOnlyConfig);
}
class AudioPolicyManagerFuzzerDPPlaybackReRouting : public AudioPolicyManagerFuzzerDynamicPolicy {
public:
explicit AudioPolicyManagerFuzzerDPPlaybackReRouting(FuzzedDataProvider *fdp);
~AudioPolicyManagerFuzzerDPPlaybackReRouting() override;
void process() override;
protected:
bool initialize() override;
void playBackReRouting();
std::unique_ptr<RecordingActivityTracker> mTracker;
std::vector<PolicyMixTuple> mUsageRules = {
{AUDIO_USAGE_MEDIA, AUDIO_SOURCE_DEFAULT, RULE_MATCH_ATTRIBUTE_USAGE},
{AUDIO_USAGE_ALARM, AUDIO_SOURCE_DEFAULT, RULE_MATCH_ATTRIBUTE_USAGE}};
struct audio_port_v7 mInjectionPort;
audio_port_handle_t mPortId = AUDIO_PORT_HANDLE_NONE;
audio_config_t mAudioConfig;
};
AudioPolicyManagerFuzzerDPPlaybackReRouting::AudioPolicyManagerFuzzerDPPlaybackReRouting(
FuzzedDataProvider *fdp)
: AudioPolicyManagerFuzzerDynamicPolicy(fdp) {
const uint32_t numRules = mFdp->ConsumeIntegralInRange<uint32_t>(1, 10);
for (int i = 0; i < numRules; ++i) {
PolicyMixTuple rule = {getValueFromVector<audio_usage_t>(mFdp, kAudioUsages),
getValueFromVector<audio_source_t>(mFdp, kAudioSources),
RULE_MATCH_ATTRIBUTE_USAGE};
mUsageRules.push_back(rule);
}
}
AudioPolicyManagerFuzzerDPPlaybackReRouting::~AudioPolicyManagerFuzzerDPPlaybackReRouting() {
mManager->stopInput(mPortId);
}
bool AudioPolicyManagerFuzzerDPPlaybackReRouting::initialize() {
if (!AudioPolicyManagerFuzzerDynamicPolicy::initialize()) {
return false;
}
mTracker.reset(new RecordingActivityTracker());
mAudioConfig = AUDIO_CONFIG_INITIALIZER;
mAudioConfig.channel_mask =
getValueFromVector<audio_channel_mask_t>(mFdp, kAudioChannelOutMasks);
mAudioConfig.format = getValueFromVector<audio_format_t>(mFdp, kAudioFormats);
mAudioConfig.sample_rate = getValueFromVector<uint32_t>(mFdp, kSamplingRates);
status_t ret = addPolicyMix(getValueFromVector<int>(mFdp, kMixTypes),
getValueFromVector<int>(mFdp, kMixRouteFlags),
getValueFromVector<audio_devices_t>(mFdp, kAudioDevices),
mMixAddress, mAudioConfig, mUsageRules);
if (ret != NO_ERROR) {
return false;
}
struct audio_port_v7 extractionPort;
findDevicePort(AUDIO_PORT_ROLE_SOURCE, getValueFromVector<audio_devices_t>(mFdp, kAudioDevices),
mMixAddress, &extractionPort);
audio_port_handle_t selectedDeviceId = AUDIO_PORT_HANDLE_NONE;
audio_source_t source = getValueFromVector<audio_source_t>(mFdp, kAudioSources);
audio_attributes_t attr = {AUDIO_CONTENT_TYPE_UNKNOWN, AUDIO_USAGE_UNKNOWN, source,
AUDIO_FLAG_NONE, ""};
std::string tags = "addr=" + mMixAddress;
strncpy(attr.tags, tags.c_str(), AUDIO_ATTRIBUTES_TAGS_MAX_SIZE - 1);
getInputForAttr(attr, mTracker->getRiid(), &selectedDeviceId, mAudioConfig.format,
mAudioConfig.channel_mask, mAudioConfig.sample_rate, AUDIO_INPUT_FLAG_NONE,
&mPortId);
ret = mManager->startInput(mPortId);
if (ret != NO_ERROR) {
return false;
}
if (!findDevicePort(AUDIO_PORT_ROLE_SINK,
getValueFromVector<audio_devices_t>(mFdp, kAudioDevices), mMixAddress,
&mInjectionPort)) {
return false;
}
return true;
}
void AudioPolicyManagerFuzzerDPPlaybackReRouting::playBackReRouting() {
const uint32_t numTestCases = mFdp->ConsumeIntegralInRange<uint32_t>(1, 10);
for (int i = 0; i < numTestCases; ++i) {
audio_attributes_t attr;
attr.content_type = getValueFromVector<audio_content_type_t>(mFdp, kAudioContentTypes);
attr.usage = getValueFromVector<audio_usage_t>(mFdp, kAudioUsages);
attr.source = getValueFromVector<audio_source_t>(mFdp, kAudioSources);
attr.flags = getValueFromVector<audio_flags_mask_t>(mFdp, kAudioFlagMasks);
std::string tags(mFdp->ConsumeBool() ? "" : "addr=remote_submix_media");
strncpy(attr.tags, tags.c_str(), AUDIO_ATTRIBUTES_TAGS_MAX_SIZE - 1);
audio_port_handle_t playbackRoutedPortId = AUDIO_PORT_HANDLE_NONE;
getOutputForAttr(&playbackRoutedPortId, mAudioConfig.format, mAudioConfig.channel_mask,
mAudioConfig.sample_rate, AUDIO_OUTPUT_FLAG_NONE, nullptr /*output*/,
nullptr /*portId*/, attr);
}
}
void AudioPolicyManagerFuzzerDPPlaybackReRouting::process() {
if (initialize()) {
playBackReRouting();
registerPolicyMixes();
fuzzPatchCreation();
unregisterPolicyMixes();
}
}
class AudioPolicyManagerFuzzerDPMixRecordInjection : public AudioPolicyManagerFuzzerDynamicPolicy {
public:
explicit AudioPolicyManagerFuzzerDPMixRecordInjection(FuzzedDataProvider *fdp);
~AudioPolicyManagerFuzzerDPMixRecordInjection() override;
void process() override;
protected:
bool initialize() override;
void recordingInjection();
std::unique_ptr<RecordingActivityTracker> mTracker;
std::vector<PolicyMixTuple> mSourceRules = {
{AUDIO_USAGE_UNKNOWN, AUDIO_SOURCE_CAMCORDER, RULE_MATCH_ATTRIBUTE_CAPTURE_PRESET},
{AUDIO_USAGE_UNKNOWN, AUDIO_SOURCE_MIC, RULE_MATCH_ATTRIBUTE_CAPTURE_PRESET},
{AUDIO_USAGE_UNKNOWN, AUDIO_SOURCE_VOICE_COMMUNICATION,
RULE_MATCH_ATTRIBUTE_CAPTURE_PRESET}};
struct audio_port_v7 mExtractionPort;
audio_port_handle_t mPortId = AUDIO_PORT_HANDLE_NONE;
audio_config_t mAudioConfig;
};
AudioPolicyManagerFuzzerDPMixRecordInjection::AudioPolicyManagerFuzzerDPMixRecordInjection(
FuzzedDataProvider *fdp)
: AudioPolicyManagerFuzzerDynamicPolicy(fdp) {
const uint32_t numRules = mFdp->ConsumeIntegralInRange<uint32_t>(1, 10);
for (int i = 0; i < numRules; ++i) {
PolicyMixTuple rule = {getValueFromVector<audio_usage_t>(mFdp, kAudioUsages),
getValueFromVector<audio_source_t>(mFdp, kAudioSources),
RULE_MATCH_ATTRIBUTE_CAPTURE_PRESET};
mSourceRules.push_back(rule);
}
}
AudioPolicyManagerFuzzerDPMixRecordInjection::~AudioPolicyManagerFuzzerDPMixRecordInjection() {
mManager->stopOutput(mPortId);
}
bool AudioPolicyManagerFuzzerDPMixRecordInjection::initialize() {
if (!AudioPolicyManagerFuzzerDynamicPolicy::initialize()) {
return false;
}
mTracker.reset(new RecordingActivityTracker());
mAudioConfig = AUDIO_CONFIG_INITIALIZER;
mAudioConfig.channel_mask =
getValueFromVector<audio_channel_mask_t>(mFdp, kAudioChannelInMasks);
mAudioConfig.format = getValueFromVector<audio_format_t>(mFdp, kAudioFormats);
mAudioConfig.sample_rate = getValueFromVector<uint32_t>(mFdp, kSamplingRates);
status_t ret = addPolicyMix(getValueFromVector<int>(mFdp, kMixTypes),
getValueFromVector<int>(mFdp, kMixRouteFlags),
getValueFromVector<audio_devices_t>(mFdp, kAudioDevices),
mMixAddress, mAudioConfig, mSourceRules);
if (ret != NO_ERROR) {
return false;
}
struct audio_port_v7 injectionPort;
findDevicePort(AUDIO_PORT_ROLE_SINK, getValueFromVector<audio_devices_t>(mFdp, kAudioDevices),
mMixAddress, &injectionPort);
audio_port_handle_t selectedDeviceId = AUDIO_PORT_HANDLE_NONE;
audio_usage_t usage = getValueFromVector<audio_usage_t>(mFdp, kAudioUsages);
audio_attributes_t attr = {AUDIO_CONTENT_TYPE_UNKNOWN, usage, AUDIO_SOURCE_DEFAULT,
AUDIO_FLAG_NONE, ""};
std::string tags = std::string("addr=") + mMixAddress;
strncpy(attr.tags, tags.c_str(), AUDIO_ATTRIBUTES_TAGS_MAX_SIZE - 1);
getOutputForAttr(&selectedDeviceId, mAudioConfig.format, mAudioConfig.channel_mask,
mAudioConfig.sample_rate /*sampleRate*/, AUDIO_OUTPUT_FLAG_NONE,
nullptr /*output*/, &mPortId, attr);
ret = mManager->startOutput(mPortId);
if (ret != NO_ERROR) {
return false;
}
getDeviceIdFromPatch(mClient->getLastAddedPatch());
if (!findDevicePort(AUDIO_PORT_ROLE_SOURCE,
getValueFromVector<audio_devices_t>(mFdp, kAudioDevices), mMixAddress,
&mExtractionPort)) {
return false;
}
return true;
}
void AudioPolicyManagerFuzzerDPMixRecordInjection::recordingInjection() {
const uint32_t numTestCases = mFdp->ConsumeIntegralInRange<uint32_t>(1, 10);
for (int i = 0; i < numTestCases; ++i) {
audio_attributes_t attr;
attr.content_type = getValueFromVector<audio_content_type_t>(mFdp, kAudioContentTypes);
attr.usage = getValueFromVector<audio_usage_t>(mFdp, kAudioUsages);
attr.source = getValueFromVector<audio_source_t>(mFdp, kAudioSources);
attr.flags = getValueFromVector<audio_flags_mask_t>(mFdp, kAudioFlagMasks);
std::string tags(mFdp->ConsumeBool() ? "" : "addr=remote_submix_media");
strncpy(attr.tags, tags.c_str(), AUDIO_ATTRIBUTES_TAGS_MAX_SIZE - 1);
audio_port_handle_t captureRoutedPortId = AUDIO_PORT_HANDLE_NONE;
audio_port_handle_t portId = AUDIO_PORT_HANDLE_NONE;
getInputForAttr(attr, mTracker->getRiid(), &captureRoutedPortId, mAudioConfig.format,
mAudioConfig.channel_mask, mAudioConfig.sample_rate, AUDIO_INPUT_FLAG_NONE,
&portId);
}
}
void AudioPolicyManagerFuzzerDPMixRecordInjection::process() {
if (initialize()) {
recordingInjection();
registerPolicyMixes();
fuzzPatchCreation();
unregisterPolicyMixes();
}
}
using DeviceConnectionTestParams =
std::tuple<audio_devices_t /*type*/, std::string /*name*/, std::string /*address*/>;
class AudioPolicyManagerFuzzerDeviceConnection
: public AudioPolicyManagerFuzzerWithConfigurationFile {
public:
explicit AudioPolicyManagerFuzzerDeviceConnection(FuzzedDataProvider *fdp)
: AudioPolicyManagerFuzzerWithConfigurationFile(fdp){};
void process() override;
void fuzzGetDirectPlaybackSupport();
void fuzzGetDirectProfilesForAttributes();
protected:
void setDeviceConnectionState();
void explicitlyRoutingAfterConnection();
};
void AudioPolicyManagerFuzzerDeviceConnection::setDeviceConnectionState() {
const uint32_t numTestCases = mFdp->ConsumeIntegralInRange<uint32_t>(1, 10);
for (int i = 0; i < numTestCases; ++i) {
const audio_devices_t type = getValueFromVector<audio_devices_t>(mFdp, kAudioDevices);
const std::string name = mFdp->ConsumeRandomLengthString();
const std::string address = mFdp->ConsumeRandomLengthString();
mManager->setDeviceConnectionState(
type, getValueFromVector<audio_policy_dev_state_t>(mFdp, kAudioPolicyDeviceStates),
address.c_str(), name.c_str(), getValueFromVector<audio_format_t>(mFdp, kAudioFormats));
}
}
void AudioPolicyManagerFuzzerDeviceConnection::explicitlyRoutingAfterConnection() {
const uint32_t numTestCases = mFdp->ConsumeIntegralInRange<uint32_t>(1, 10);
for (int i = 0; i < numTestCases; ++i) {
const audio_devices_t type = getValueFromVector<audio_devices_t>(mFdp, kAudioDevices);
const std::string name = mFdp->ConsumeRandomLengthString();
const std::string address = mFdp->ConsumeRandomLengthString();
mManager->setDeviceConnectionState(
type, getValueFromVector<audio_policy_dev_state_t>(mFdp, kAudioPolicyDeviceStates),
address.c_str(), name.c_str(), getValueFromVector<audio_format_t>(mFdp, kAudioFormats));
audio_port_v7 devicePort;
const audio_port_role_t role =
audio_is_output_device(type) ? AUDIO_PORT_ROLE_SINK : AUDIO_PORT_ROLE_SOURCE;
findDevicePort(role, type, address, &devicePort);
audio_port_handle_t routedPortId = devicePort.id;
// Try start input or output according to the device type
if (audio_is_output_devices(type)) {
getOutputForAttr(&routedPortId, getValueFromVector<audio_format_t>(mFdp, kAudioFormats),
getValueFromVector<audio_channel_mask_t>(mFdp, kAudioChannelOutMasks),
getValueFromVector<uint32_t>(mFdp, kSamplingRates),
AUDIO_OUTPUT_FLAG_NONE);
} else if (audio_is_input_device(type)) {
RecordingActivityTracker tracker;
getInputForAttr({}, tracker.getRiid(), &routedPortId,
getValueFromVector<audio_format_t>(mFdp, kAudioFormats),
getValueFromVector<audio_channel_mask_t>(mFdp, kAudioChannelInMasks),
getValueFromVector<uint32_t>(mFdp, kSamplingRates),
AUDIO_INPUT_FLAG_NONE);
}
}
}
void AudioPolicyManagerFuzzerDeviceConnection::fuzzGetDirectPlaybackSupport() {
const uint32_t numTestCases = mFdp->ConsumeIntegralInRange<uint32_t>(1, 10);
for (int i = 0; i < numTestCases; ++i) {
audio_attributes_t attr = AUDIO_ATTRIBUTES_INITIALIZER;
attr.content_type = getValueFromVector<audio_content_type_t>(mFdp, kAudioContentTypes);
attr.usage = getValueFromVector<audio_usage_t>(mFdp, kAudioUsages);
attr.source = getValueFromVector<audio_source_t>(mFdp, kAudioSources);
attr.flags = getValueFromVector<audio_flags_mask_t>(mFdp, kAudioFlagMasks);
audio_config_t config = AUDIO_CONFIG_INITIALIZER;
config.channel_mask = getValueFromVector<audio_channel_mask_t>(mFdp, kAudioChannelOutMasks);
config.format = getValueFromVector<audio_format_t>(mFdp, kAudioFormats);
config.sample_rate = getValueFromVector<uint32_t>(mFdp, kSamplingRates);
mManager->getDirectPlaybackSupport(&attr, &config);
}
}
void AudioPolicyManagerFuzzerDeviceConnection::fuzzGetDirectProfilesForAttributes() {
const uint32_t numTestCases = mFdp->ConsumeIntegralInRange<uint32_t>(1, 10);
for (int i = 0; i < numTestCases; ++i) {
AudioProfileVector audioProfiles;
audio_attributes_t attr = AUDIO_ATTRIBUTES_INITIALIZER;
attr.content_type = getValueFromVector<audio_content_type_t>(mFdp, kAudioContentTypes);
attr.usage = getValueFromVector<audio_usage_t>(mFdp, kAudioUsages);
attr.source = getValueFromVector<audio_source_t>(mFdp, kAudioSources);
attr.flags = getValueFromVector<audio_flags_mask_t>(mFdp, kAudioFlagMasks);
mManager->getDirectProfilesForAttributes(&attr, audioProfiles);
}
}
void AudioPolicyManagerFuzzerDeviceConnection::process() {
if (initialize()) {
setDeviceConnectionState();
explicitlyRoutingAfterConnection();
fuzzGetDirectPlaybackSupport();
fuzzGetDirectProfilesForAttributes();
fuzzPatchCreation();
}
}
class AudioPolicyManagerTVFuzzer : public AudioPolicyManagerFuzzerWithConfigurationFile {
public:
explicit AudioPolicyManagerTVFuzzer(FuzzedDataProvider *fdp)
: AudioPolicyManagerFuzzerWithConfigurationFile(fdp){};
void process() override;
protected:
std::string getConfigFile();
void testHDMIPortSelection(audio_output_flags_t flags);
static inline const std::string sTvConfig =
AudioPolicyManagerTVFuzzer::sExecutableDir + "data/test_tv_apm_configuration.xml";
};
std::string AudioPolicyManagerTVFuzzer::getConfigFile() { return fuzzXML(sTvConfig); }
void AudioPolicyManagerTVFuzzer::testHDMIPortSelection(audio_output_flags_t flags) {
audio_devices_t audioDevice = getValueFromVector<audio_devices_t>(mFdp, kAudioDevices);
audio_format_t audioFormat = getValueFromVector<audio_format_t>(mFdp, kAudioFormats);
status_t ret = mManager->setDeviceConnectionState(
audioDevice, AUDIO_POLICY_DEVICE_STATE_AVAILABLE, "" /*address*/, "" /*name*/, audioFormat);
if (ret != NO_ERROR) {
return;
}
audio_port_handle_t selectedDeviceId = AUDIO_PORT_HANDLE_NONE;
audio_io_handle_t output;
audio_port_handle_t portId;
getOutputForAttr(&selectedDeviceId, getValueFromVector<audio_format_t>(mFdp, kAudioFormats),
getValueFromVector<audio_channel_mask_t>(mFdp, kAudioChannelOutMasks),
getValueFromVector<uint32_t>(mFdp, kSamplingRates), flags, &output, &portId);
sp<SwAudioOutputDescriptor> outDesc = mManager->getOutputs().valueFor(output);
if (outDesc.get() == nullptr) {
return;
}
audio_port_v7 port = {};
outDesc->toAudioPort(&port);
mManager->releaseOutput(portId);
mManager->setDeviceConnectionState(audioDevice, AUDIO_POLICY_DEVICE_STATE_UNAVAILABLE,
"" /*address*/, "" /*name*/, audioFormat);
}
void AudioPolicyManagerTVFuzzer::process() {
if (initialize()) {
testHDMIPortSelection(getValueFromVector<audio_output_flags_t>(mFdp, kAudioOutputFlags));
fuzzPatchCreation();
}
}
extern "C" int LLVMFuzzerTestOneInput(const uint8_t *data, size_t size) {
if (size < 1) {
return 0;
}
FuzzedDataProvider fdp = FuzzedDataProvider(data, size);
while (fdp.remaining_bytes() > 0) {
AudioPolicyManagerFuzzer audioPolicyManagerFuzzer(&fdp);
audioPolicyManagerFuzzer.process();
AudioPolicyManagerFuzzerMsd audioPolicyManagerFuzzerMsd(&fdp);
audioPolicyManagerFuzzerMsd.process();
AudioPolicyManagerFuzzerWithConfigurationFile audioPolicyManagerFuzzerWithConfigurationFile(
&fdp);
audioPolicyManagerFuzzerWithConfigurationFile.process();
AudioPolicyManagerFuzzerDynamicPolicy audioPolicyManagerFuzzerDynamicPolicy(&fdp);
audioPolicyManagerFuzzerDynamicPolicy.process();
AudioPolicyManagerFuzzerDPNoRemoteSubmixModule
audioPolicyManagerFuzzerDPNoRemoteSubmixModule(&fdp);
audioPolicyManagerFuzzerDPNoRemoteSubmixModule.process();
AudioPolicyManagerFuzzerDPPlaybackReRouting audioPolicyManagerFuzzerDPPlaybackReRouting(
&fdp);
audioPolicyManagerFuzzerDPPlaybackReRouting.process();
AudioPolicyManagerFuzzerDPMixRecordInjection audioPolicyManagerFuzzerDPMixRecordInjection(
&fdp);
audioPolicyManagerFuzzerDPMixRecordInjection.process();
AudioPolicyManagerFuzzerDeviceConnection audioPolicyManagerFuzzerDeviceConnection(&fdp);
audioPolicyManagerFuzzerDeviceConnection.process();
AudioPolicyManagerTVFuzzer audioPolicyManagerTVFuzzer(&fdp);
audioPolicyManagerTVFuzzer.process();
}
return 0;
}