/* * Copyright (C) 2020 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 #include #include #define LOG_TAG "HidlUtils" #include #include #include #include #include "HidlUtils.h" namespace android { namespace hardware { namespace audio { namespace common { namespace CPP_VERSION { namespace implementation { namespace xsd { using namespace ::android::audio::policy::configuration::V7_0; } #define CONVERT_CHECKED(expr, result) \ if (status_t status = (expr); status != NO_ERROR) { \ result = status; \ } status_t HidlUtils::audioIndexChannelMaskFromHal(audio_channel_mask_t halChannelMask, AudioChannelMask* channelMask) { *channelMask = audio_channel_index_mask_to_string(halChannelMask); if (!channelMask->empty() && !xsd::isUnknownAudioChannelMask(*channelMask)) { return NO_ERROR; } ALOGE("Unknown index channel mask value 0x%X", halChannelMask); *channelMask = toString(xsd::AudioChannelMask::AUDIO_CHANNEL_NONE); return BAD_VALUE; } status_t HidlUtils::audioInputChannelMaskFromHal(audio_channel_mask_t halChannelMask, AudioChannelMask* channelMask) { *channelMask = audio_channel_in_mask_to_string(halChannelMask); if (!channelMask->empty() && !xsd::isUnknownAudioChannelMask(*channelMask)) { return NO_ERROR; } ALOGE("Unknown input channel mask value 0x%X", halChannelMask); *channelMask = toString(xsd::AudioChannelMask::AUDIO_CHANNEL_NONE); return BAD_VALUE; } status_t HidlUtils::audioOutputChannelMaskFromHal(audio_channel_mask_t halChannelMask, AudioChannelMask* channelMask) { *channelMask = audio_channel_out_mask_to_string(halChannelMask); if (!channelMask->empty() && !xsd::isUnknownAudioChannelMask(*channelMask)) { return NO_ERROR; } ALOGE("Unknown output channel mask value 0x%X", halChannelMask); *channelMask = toString(xsd::AudioChannelMask::AUDIO_CHANNEL_NONE); return BAD_VALUE; } status_t HidlUtils::audioChannelMaskFromHal(audio_channel_mask_t halChannelMask, bool isInput, AudioChannelMask* channelMask) { if (halChannelMask != AUDIO_CHANNEL_NONE) { if (audio_channel_mask_is_valid(halChannelMask)) { switch (audio_channel_mask_get_representation(halChannelMask)) { case AUDIO_CHANNEL_REPRESENTATION_POSITION: return isInput ? audioInputChannelMaskFromHal(halChannelMask, channelMask) : audioOutputChannelMaskFromHal(halChannelMask, channelMask); case AUDIO_CHANNEL_REPRESENTATION_INDEX: // Index masks do not have direction. return audioIndexChannelMaskFromHal(halChannelMask, channelMask); // no default } } *channelMask = toString(xsd::AudioChannelMask::AUDIO_CHANNEL_NONE); return BAD_VALUE; } *channelMask = toString(xsd::AudioChannelMask::AUDIO_CHANNEL_NONE); return NO_ERROR; } status_t HidlUtils::audioChannelMasksFromHal(const std::vector& halChannelMasks, hidl_vec* channelMasks) { hidl_vec tempChannelMasks; tempChannelMasks.resize(halChannelMasks.size()); size_t tempPos = 0; for (const auto& halChannelMask : halChannelMasks) { if (!halChannelMask.empty() && !xsd::isUnknownAudioChannelMask(halChannelMask)) { tempChannelMasks[tempPos++] = halChannelMask; } } if (tempPos == tempChannelMasks.size()) { *channelMasks = std::move(tempChannelMasks); } else { *channelMasks = hidl_vec(tempChannelMasks.begin(), tempChannelMasks.begin() + tempPos); } return halChannelMasks.size() == channelMasks->size() ? NO_ERROR : BAD_VALUE; } status_t HidlUtils::audioChannelMaskToHal(const AudioChannelMask& channelMask, audio_channel_mask_t* halChannelMask) { if (!xsd::isUnknownAudioChannelMask(channelMask) && audio_channel_mask_from_string(channelMask.c_str(), halChannelMask)) { return NO_ERROR; } ALOGE("Unknown channel mask \"%s\"", channelMask.c_str()); *halChannelMask = AUDIO_CHANNEL_NONE; return BAD_VALUE; } status_t HidlUtils::audioConfigBaseFromHal(const audio_config_base_t& halConfigBase, bool isInput, AudioConfigBase* configBase) { status_t result = NO_ERROR; configBase->sampleRateHz = halConfigBase.sample_rate; CONVERT_CHECKED( audioChannelMaskFromHal(halConfigBase.channel_mask, isInput, &configBase->channelMask), result); CONVERT_CHECKED(audioFormatFromHal(halConfigBase.format, &configBase->format), result); return result; } status_t HidlUtils::audioConfigBaseToHal(const AudioConfigBase& configBase, audio_config_base_t* halConfigBase) { status_t result = NO_ERROR; halConfigBase->sample_rate = configBase.sampleRateHz; CONVERT_CHECKED(audioChannelMaskToHal(configBase.channelMask, &halConfigBase->channel_mask), result); CONVERT_CHECKED(audioFormatToHal(configBase.format, &halConfigBase->format), result); return result; } status_t HidlUtils::audioConfigBaseOptionalFromHal(const audio_config_base_t& halConfigBase, bool isInput, bool formatSpecified, bool sampleRateSpecified, bool channelMaskSpecified, AudioConfigBaseOptional* configBase) { status_t result = NO_ERROR; if (formatSpecified) { AudioFormat value; CONVERT_CHECKED(audioFormatFromHal(halConfigBase.format, &value), result); configBase->format.value(std::move(value)); } else { configBase->format.unspecified({}); } if (sampleRateSpecified) { configBase->sampleRateHz.value(halConfigBase.sample_rate); } else { configBase->sampleRateHz.unspecified({}); } if (channelMaskSpecified) { AudioChannelMask value; CONVERT_CHECKED(audioChannelMaskFromHal(halConfigBase.channel_mask, isInput, &value), result); configBase->channelMask.value(std::move(value)); } return result; } status_t HidlUtils::audioConfigBaseOptionalToHal(const AudioConfigBaseOptional& configBase, audio_config_base_t* halConfigBase, bool* formatSpecified, bool* sampleRateSpecified, bool* channelMaskSpecified) { status_t result = NO_ERROR; *formatSpecified = configBase.format.getDiscriminator() == AudioConfigBaseOptional::Format::hidl_discriminator::value; if (*formatSpecified) { CONVERT_CHECKED(audioFormatToHal(configBase.format.value(), &halConfigBase->format), result); } *sampleRateSpecified = configBase.sampleRateHz.getDiscriminator() == AudioConfigBaseOptional::SampleRate::hidl_discriminator::value; if (*sampleRateSpecified) { halConfigBase->sample_rate = configBase.sampleRateHz.value(); } *channelMaskSpecified = configBase.channelMask.getDiscriminator() == AudioConfigBaseOptional::ChannelMask::hidl_discriminator::value; if (*channelMaskSpecified) { CONVERT_CHECKED( audioChannelMaskToHal(configBase.channelMask.value(), &halConfigBase->channel_mask), result); } return result; } status_t HidlUtils::audioContentTypeFromHal(const audio_content_type_t halContentType, AudioContentType* contentType) { *contentType = audio_content_type_to_string(halContentType); if (!contentType->empty() && !xsd::isUnknownAudioContentType(*contentType)) { return NO_ERROR; } ALOGE("Unknown audio content type value 0x%X", halContentType); *contentType = toString(xsd::AudioContentType::AUDIO_CONTENT_TYPE_UNKNOWN); return BAD_VALUE; } status_t HidlUtils::audioContentTypeToHal(const AudioContentType& contentType, audio_content_type_t* halContentType) { if (!xsd::isUnknownAudioContentType(contentType) && audio_content_type_from_string(contentType.c_str(), halContentType)) { return NO_ERROR; } ALOGE("Unknown audio content type \"%s\"", contentType.c_str()); *halContentType = AUDIO_CONTENT_TYPE_UNKNOWN; return BAD_VALUE; } status_t HidlUtils::audioDeviceTypeFromHal(audio_devices_t halDevice, AudioDevice* device) { *device = audio_device_to_string(halDevice); if (!device->empty() && !xsd::isUnknownAudioDevice(*device)) { return NO_ERROR; } ALOGE("Unknown audio device value 0x%X", halDevice); *device = toString(xsd::AudioDevice::AUDIO_DEVICE_NONE); return BAD_VALUE; } status_t HidlUtils::audioDeviceTypeToHal(const AudioDevice& device, audio_devices_t* halDevice) { if (!xsd::isUnknownAudioDevice(device) && audio_device_from_string(device.c_str(), halDevice)) { return NO_ERROR; } ALOGE("Unknown audio device \"%s\"", device.c_str()); *halDevice = AUDIO_DEVICE_NONE; return BAD_VALUE; } status_t HidlUtils::audioFormatFromHal(audio_format_t halFormat, AudioFormat* format) { *format = audio_format_to_string(halFormat); if (!format->empty() && !xsd::isUnknownAudioFormat(*format)) { return NO_ERROR; } ALOGE("Unknown audio format value 0x%X", halFormat); return BAD_VALUE; } status_t HidlUtils::audioFormatsFromHal(const std::vector& halFormats, hidl_vec* formats) { hidl_vec tempFormats; tempFormats.resize(halFormats.size()); size_t tempPos = 0; for (const auto& halFormat : halFormats) { if (!halFormat.empty() && !xsd::isUnknownAudioFormat(halFormat)) { tempFormats[tempPos++] = halFormat; } } if (tempPos == tempFormats.size()) { *formats = std::move(tempFormats); } else { *formats = hidl_vec(tempFormats.begin(), tempFormats.begin() + tempPos); } return halFormats.size() == formats->size() ? NO_ERROR : BAD_VALUE; } status_t HidlUtils::audioFormatToHal(const AudioFormat& format, audio_format_t* halFormat) { if (!xsd::isUnknownAudioFormat(format) && audio_format_from_string(format.c_str(), halFormat)) { return NO_ERROR; } ALOGE("Unknown audio format \"%s\"", format.c_str()); *halFormat = AUDIO_FORMAT_DEFAULT; return BAD_VALUE; } status_t HidlUtils::audioGainModeMaskFromHal(audio_gain_mode_t halGainModeMask, hidl_vec* gainModeMask) { status_t status = NO_ERROR; std::vector result; for (uint32_t bit = 0; halGainModeMask != 0 && bit < sizeof(audio_gain_mode_t) * 8; ++bit) { audio_gain_mode_t flag = static_cast(1u << bit); if ((flag & halGainModeMask) == flag) { AudioGainMode flagStr = audio_gain_mode_to_string(flag); if (!flagStr.empty() && !xsd::isUnknownAudioGainMode(flagStr)) { result.push_back(flagStr); } else { ALOGE("Unknown audio gain mode value 0x%X", flag); status = BAD_VALUE; } halGainModeMask = static_cast(halGainModeMask & ~flag); } } *gainModeMask = result; return status; } status_t HidlUtils::audioGainModeMaskToHal(const hidl_vec& gainModeMask, audio_gain_mode_t* halGainModeMask) { status_t status = NO_ERROR; *halGainModeMask = {}; for (const auto& gainMode : gainModeMask) { audio_gain_mode_t halGainMode; if (!xsd::isUnknownAudioGainMode(gainMode) && audio_gain_mode_from_string(gainMode.c_str(), &halGainMode)) { *halGainModeMask = static_cast(*halGainModeMask | halGainMode); } else { ALOGE("Unknown audio gain mode \"%s\"", gainMode.c_str()); status = BAD_VALUE; } } return status; } status_t HidlUtils::audioSourceFromHal(audio_source_t halSource, AudioSource* source) { *source = audio_source_to_string(halSource); if (!source->empty() && !xsd::isUnknownAudioSource(*source)) { return NO_ERROR; } ALOGE("Unknown audio source value 0x%X", halSource); *source = toString(xsd::AudioSource::AUDIO_SOURCE_DEFAULT); return BAD_VALUE; } status_t HidlUtils::audioSourceToHal(const AudioSource& source, audio_source_t* halSource) { if (!xsd::isUnknownAudioSource(source) && audio_source_from_string(source.c_str(), halSource)) { return NO_ERROR; } ALOGE("Unknown audio source \"%s\"", source.c_str()); *halSource = AUDIO_SOURCE_DEFAULT; return BAD_VALUE; } // The "default" value of audio_stream_type_t is represented by an empty string. status_t HidlUtils::audioStreamTypeFromHal(audio_stream_type_t halStreamType, AudioStreamType* streamType) { if (halStreamType != AUDIO_STREAM_DEFAULT) { *streamType = audio_stream_type_to_string(halStreamType); if (!streamType->empty() && !xsd::isUnknownAudioStreamType(*streamType)) { return NO_ERROR; } ALOGE("Unknown audio stream type value 0x%X", halStreamType); return BAD_VALUE; } else { *streamType = ""; return NO_ERROR; } } status_t HidlUtils::audioStreamTypeToHal(const AudioStreamType& streamType, audio_stream_type_t* halStreamType) { if (!streamType.empty()) { if (!xsd::isUnknownAudioStreamType(streamType) && audio_stream_type_from_string(streamType.c_str(), halStreamType)) { return NO_ERROR; } ALOGE("Unknown audio stream type \"%s\"", streamType.c_str()); return BAD_VALUE; } else { *halStreamType = AUDIO_STREAM_DEFAULT; return NO_ERROR; } } status_t HidlUtils::audioConfigFromHal(const audio_config_t& halConfig, bool isInput, AudioConfig* config) { status_t result = NO_ERROR; audio_config_base_t halConfigBase = {halConfig.sample_rate, halConfig.channel_mask, halConfig.format}; CONVERT_CHECKED(audioConfigBaseFromHal(halConfigBase, isInput, &config->base), result); if (halConfig.offload_info.sample_rate != 0) { config->offloadInfo.info({}); CONVERT_CHECKED( audioOffloadInfoFromHal(halConfig.offload_info, &config->offloadInfo.info()), result); } config->frameCount = halConfig.frame_count; return result; } status_t HidlUtils::audioConfigToHal(const AudioConfig& config, audio_config_t* halConfig) { status_t result = NO_ERROR; *halConfig = AUDIO_CONFIG_INITIALIZER; audio_config_base_t halConfigBase = AUDIO_CONFIG_BASE_INITIALIZER; CONVERT_CHECKED(audioConfigBaseToHal(config.base, &halConfigBase), result); halConfig->sample_rate = halConfigBase.sample_rate; halConfig->channel_mask = halConfigBase.channel_mask; halConfig->format = halConfigBase.format; if (config.offloadInfo.getDiscriminator() == AudioConfig::OffloadInfo::hidl_discriminator::info) { CONVERT_CHECKED(audioOffloadInfoToHal(config.offloadInfo.info(), &halConfig->offload_info), result); } halConfig->frame_count = config.frameCount; return result; } status_t HidlUtils::audioGainConfigFromHal(const struct audio_gain_config& halConfig, bool isInput, AudioGainConfig* config) { status_t result = NO_ERROR; config->index = halConfig.index; CONVERT_CHECKED(audioGainModeMaskFromHal(halConfig.mode, &config->mode), result); CONVERT_CHECKED(audioChannelMaskFromHal(halConfig.channel_mask, isInput, &config->channelMask), result); if (halConfig.mode & AUDIO_GAIN_MODE_JOINT) { config->values.resize(1); config->values[0] = halConfig.values[0]; } if (halConfig.mode & (AUDIO_GAIN_MODE_CHANNELS | AUDIO_GAIN_MODE_RAMP)) { config->values.resize(__builtin_popcount(halConfig.channel_mask)); for (size_t i = 0; i < config->values.size(); ++i) { config->values[i] = halConfig.values[i]; } } config->rampDurationMs = halConfig.ramp_duration_ms; return result; } status_t HidlUtils::audioGainConfigToHal(const AudioGainConfig& config, struct audio_gain_config* halConfig) { status_t result = NO_ERROR; halConfig->index = config.index; CONVERT_CHECKED(audioGainModeMaskToHal(config.mode, &halConfig->mode), result); CONVERT_CHECKED(audioChannelMaskToHal(config.channelMask, &halConfig->channel_mask), result); memset(halConfig->values, 0, sizeof(halConfig->values)); if (halConfig->mode & AUDIO_GAIN_MODE_JOINT) { if (config.values.size() > 0) { halConfig->values[0] = config.values[0]; } else { ALOGE("Empty values vector in AudioGainConfig"); result = BAD_VALUE; } } if (halConfig->mode & (AUDIO_GAIN_MODE_CHANNELS | AUDIO_GAIN_MODE_RAMP)) { size_t channelCount = __builtin_popcount(halConfig->channel_mask); size_t valuesCount = config.values.size(); if (channelCount != valuesCount) { ALOGE("Wrong number of values in AudioGainConfig, expected: %zu, found: %zu", channelCount, valuesCount); result = BAD_VALUE; if (channelCount < valuesCount) { valuesCount = channelCount; } } for (size_t i = 0; i < valuesCount; ++i) { halConfig->values[i] = config.values[i]; } } halConfig->ramp_duration_ms = config.rampDurationMs; return result; } status_t HidlUtils::audioGainFromHal(const struct audio_gain& halGain, bool isInput, AudioGain* gain) { status_t result = NO_ERROR; CONVERT_CHECKED(audioGainModeMaskFromHal(halGain.mode, &gain->mode), result); CONVERT_CHECKED(audioChannelMaskFromHal(halGain.channel_mask, isInput, &gain->channelMask), result); gain->minValue = halGain.min_value; gain->maxValue = halGain.max_value; gain->defaultValue = halGain.default_value; gain->stepValue = halGain.step_value; gain->minRampMs = halGain.min_ramp_ms; gain->maxRampMs = halGain.max_ramp_ms; return result; } status_t HidlUtils::audioGainToHal(const AudioGain& gain, struct audio_gain* halGain) { status_t result = NO_ERROR; CONVERT_CHECKED(audioGainModeMaskToHal(gain.mode, &halGain->mode), result); CONVERT_CHECKED(audioChannelMaskToHal(gain.channelMask, &halGain->channel_mask), result); halGain->min_value = gain.minValue; halGain->max_value = gain.maxValue; halGain->default_value = gain.defaultValue; halGain->step_value = gain.stepValue; halGain->min_ramp_ms = gain.minRampMs; halGain->max_ramp_ms = gain.maxRampMs; return result; } status_t HidlUtils::audioUsageFromHal(audio_usage_t halUsage, AudioUsage* usage) { if (halUsage == AUDIO_USAGE_NOTIFICATION_COMMUNICATION_REQUEST || halUsage == AUDIO_USAGE_NOTIFICATION_COMMUNICATION_INSTANT || halUsage == AUDIO_USAGE_NOTIFICATION_COMMUNICATION_DELAYED || halUsage == AUDIO_USAGE_NOTIFICATION_EVENT) { halUsage = AUDIO_USAGE_NOTIFICATION; } *usage = audio_usage_to_string(halUsage); if (!usage->empty() && !xsd::isUnknownAudioUsage(*usage)) { return NO_ERROR; } ALOGE("Unknown audio usage %d", halUsage); *usage = toString(xsd::AudioUsage::AUDIO_USAGE_UNKNOWN); return BAD_VALUE; } status_t HidlUtils::audioUsageToHal(const AudioUsage& usage, audio_usage_t* halUsage) { if (!xsd::isUnknownAudioUsage(usage) && audio_usage_from_string(usage.c_str(), halUsage)) { return NO_ERROR; } ALOGE("Unknown audio usage \"%s\"", usage.c_str()); *halUsage = AUDIO_USAGE_UNKNOWN; return BAD_VALUE; } status_t HidlUtils::audioOffloadInfoFromHal(const audio_offload_info_t& halOffload, AudioOffloadInfo* offload) { status_t result = NO_ERROR; audio_config_base_t halConfigBase = {halOffload.sample_rate, halOffload.channel_mask, halOffload.format}; CONVERT_CHECKED(audioConfigBaseFromHal(halConfigBase, false /*isInput*/, &offload->base), result); CONVERT_CHECKED(audioStreamTypeFromHal(halOffload.stream_type, &offload->streamType), result); offload->bitRatePerSecond = halOffload.bit_rate; offload->durationMicroseconds = halOffload.duration_us; offload->hasVideo = halOffload.has_video; offload->isStreaming = halOffload.is_streaming; offload->bitWidth = halOffload.bit_width; offload->bufferSize = halOffload.offload_buffer_size; CONVERT_CHECKED(audioUsageFromHal(halOffload.usage, &offload->usage), result); if (halOffload.version >= AUDIO_OFFLOAD_INFO_VERSION_0_2) { offload->encapsulationMode = static_cast(halOffload.encapsulation_mode); offload->contentId = halOffload.content_id; offload->syncId = halOffload.sync_id; } else { offload->encapsulationMode = AudioEncapsulationMode::NONE; offload->contentId = 0; offload->syncId = 0; } return result; } status_t HidlUtils::audioOffloadInfoToHal(const AudioOffloadInfo& offload, audio_offload_info_t* halOffload) { status_t result = NO_ERROR; *halOffload = AUDIO_INFO_INITIALIZER; audio_config_base_t halConfigBase = AUDIO_CONFIG_BASE_INITIALIZER; CONVERT_CHECKED(audioConfigBaseToHal(offload.base, &halConfigBase), result); halOffload->sample_rate = halConfigBase.sample_rate; halOffload->channel_mask = halConfigBase.channel_mask; halOffload->format = halConfigBase.format; CONVERT_CHECKED(audioStreamTypeToHal(offload.streamType, &halOffload->stream_type), result); halOffload->bit_rate = offload.bitRatePerSecond; halOffload->duration_us = offload.durationMicroseconds; halOffload->has_video = offload.hasVideo; halOffload->is_streaming = offload.isStreaming; halOffload->bit_width = offload.bitWidth; halOffload->offload_buffer_size = offload.bufferSize; CONVERT_CHECKED(audioUsageToHal(offload.usage, &halOffload->usage), result); halOffload->encapsulation_mode = static_cast(offload.encapsulationMode); halOffload->content_id = offload.contentId; halOffload->sync_id = offload.syncId; return result; } status_t HidlUtils::audioPortConfigFromHal(const struct audio_port_config& halConfig, AudioPortConfig* config) { status_t result = NO_ERROR; bool isInput = false; config->id = halConfig.id; CONVERT_CHECKED(audioPortExtendedInfoFromHal(halConfig.role, halConfig.type, halConfig.ext.device, halConfig.ext.mix, halConfig.ext.session, &config->ext, &isInput), result); if (audio_port_config_has_input_direction(&halConfig) != isInput) { ALOGE("Inconsistent port config direction data, is input: %d (hal) != %d (converter)", audio_port_config_has_input_direction(&halConfig), isInput); result = BAD_VALUE; } audio_config_base_t halConfigBase = {halConfig.sample_rate, halConfig.channel_mask, halConfig.format}; CONVERT_CHECKED( audioConfigBaseOptionalFromHal( halConfigBase, isInput, halConfig.config_mask & AUDIO_PORT_CONFIG_FORMAT, halConfig.config_mask & AUDIO_PORT_CONFIG_SAMPLE_RATE, halConfig.config_mask & AUDIO_PORT_CONFIG_CHANNEL_MASK, &config->base), result); if (halConfig.config_mask & AUDIO_PORT_CONFIG_GAIN) { config->gain.config({}); CONVERT_CHECKED(audioGainConfigFromHal(halConfig.gain, isInput, &config->gain.config()), result); } else { config->gain.unspecified({}); } return result; } status_t HidlUtils::audioPortConfigToHal(const AudioPortConfig& config, struct audio_port_config* halConfig) { status_t result = NO_ERROR; memset(halConfig, 0, sizeof(audio_port_config)); halConfig->id = config.id; halConfig->config_mask = 0; audio_config_base_t halConfigBase = AUDIO_CONFIG_BASE_INITIALIZER; bool formatSpecified = false, sRateSpecified = false, channelMaskSpecified = false; CONVERT_CHECKED(audioConfigBaseOptionalToHal(config.base, &halConfigBase, &formatSpecified, &sRateSpecified, &channelMaskSpecified), result); if (sRateSpecified) { halConfig->config_mask |= AUDIO_PORT_CONFIG_SAMPLE_RATE; halConfig->sample_rate = halConfigBase.sample_rate; } if (channelMaskSpecified) { halConfig->config_mask |= AUDIO_PORT_CONFIG_CHANNEL_MASK; halConfig->channel_mask = halConfigBase.channel_mask; } if (formatSpecified) { halConfig->config_mask |= AUDIO_PORT_CONFIG_FORMAT; halConfig->format = halConfigBase.format; } if (config.gain.getDiscriminator() == AudioPortConfig::OptionalGain::hidl_discriminator::config) { halConfig->config_mask |= AUDIO_PORT_CONFIG_GAIN; CONVERT_CHECKED(audioGainConfigToHal(config.gain.config(), &halConfig->gain), result); } CONVERT_CHECKED(audioPortExtendedInfoToHal(config.ext, &halConfig->role, &halConfig->type, &halConfig->ext.device, &halConfig->ext.mix, &halConfig->ext.session), result); return result; } status_t HidlUtils::audioPortExtendedInfoFromHal( audio_port_role_t role, audio_port_type_t type, const struct audio_port_config_device_ext& device, const struct audio_port_config_mix_ext& mix, const struct audio_port_config_session_ext& session, AudioPortExtendedInfo* ext, bool* isInput) { status_t result = NO_ERROR; *isInput = false; switch (type) { case AUDIO_PORT_TYPE_NONE: ext->unspecified({}); break; case AUDIO_PORT_TYPE_DEVICE: { *isInput = role == AUDIO_PORT_ROLE_SOURCE; ext->device({}); CONVERT_CHECKED(deviceAddressFromHal(device.type, device.address, &ext->device()), result); break; } case AUDIO_PORT_TYPE_MIX: { *isInput = role == AUDIO_PORT_ROLE_SINK; ext->mix({}); ext->mix().ioHandle = mix.handle; if (role == AUDIO_PORT_ROLE_SOURCE) { ext->mix().useCase.stream({}); CONVERT_CHECKED( audioStreamTypeFromHal(mix.usecase.stream, &ext->mix().useCase.stream()), result); } else if (role == AUDIO_PORT_ROLE_SINK) { ext->mix().useCase.source({}); CONVERT_CHECKED( audioSourceFromHal(mix.usecase.source, &ext->mix().useCase.source()), result); } break; } case AUDIO_PORT_TYPE_SESSION: { ext->session(session.session); break; } } return result; } status_t HidlUtils::audioPortExtendedInfoToHal(const AudioPortExtendedInfo& ext, audio_port_role_t* role, audio_port_type_t* type, struct audio_port_config_device_ext* device, struct audio_port_config_mix_ext* mix, struct audio_port_config_session_ext* session) { status_t result = NO_ERROR; switch (ext.getDiscriminator()) { case AudioPortExtendedInfo::hidl_discriminator::unspecified: *role = AUDIO_PORT_ROLE_NONE; *type = AUDIO_PORT_TYPE_NONE; break; case AudioPortExtendedInfo::hidl_discriminator::device: *role = xsd::isOutputDevice(ext.device().deviceType) ? AUDIO_PORT_ROLE_SINK : AUDIO_PORT_ROLE_SOURCE; *type = AUDIO_PORT_TYPE_DEVICE; CONVERT_CHECKED(deviceAddressToHal(ext.device(), &device->type, device->address), result); break; case AudioPortExtendedInfo::hidl_discriminator::mix: *type = AUDIO_PORT_TYPE_MIX; switch (ext.mix().useCase.getDiscriminator()) { case AudioPortExtendedInfo::AudioPortMixExt::UseCase::hidl_discriminator::stream: *role = AUDIO_PORT_ROLE_SOURCE; CONVERT_CHECKED( audioStreamTypeToHal(ext.mix().useCase.stream(), &mix->usecase.stream), result); break; case AudioPortExtendedInfo::AudioPortMixExt::UseCase::hidl_discriminator::source: *role = AUDIO_PORT_ROLE_SINK; CONVERT_CHECKED( audioSourceToHal(ext.mix().useCase.source(), &mix->usecase.source), result); break; } mix->handle = ext.mix().ioHandle; break; case AudioPortExtendedInfo::hidl_discriminator::session: *role = AUDIO_PORT_ROLE_NONE; *type = AUDIO_PORT_TYPE_SESSION; session->session = static_cast(ext.session()); break; } return result; } status_t HidlUtils::encapsulationTypeFromHal(audio_encapsulation_type_t halEncapsulationType, AudioEncapsulationType* encapsulationType) { *encapsulationType = audio_encapsulation_type_to_string(halEncapsulationType); if (!encapsulationType->empty() && !xsd::isUnknownAudioEncapsulationType(*encapsulationType)) { return NO_ERROR; } ALOGE("Unknown audio encapsulation type value 0x%X", halEncapsulationType); return BAD_VALUE; } status_t HidlUtils::encapsulationTypeToHal(const AudioEncapsulationType& encapsulationType, audio_encapsulation_type_t* halEncapsulationType) { if (!xsd::isUnknownAudioEncapsulationType(encapsulationType) && audio_encapsulation_type_from_string(encapsulationType.c_str(), halEncapsulationType)) { return NO_ERROR; } ALOGE("Unknown audio encapsulation type \"%s\"", encapsulationType.c_str()); *halEncapsulationType = AUDIO_ENCAPSULATION_TYPE_NONE; return BAD_VALUE; } status_t HidlUtils::audioPortFromHal(const struct audio_port& halPort, AudioPort* port) { struct audio_port_v7 halPortV7 = {}; audio_populate_audio_port_v7(&halPort, &halPortV7); return audioPortFromHal(halPortV7, port); } status_t HidlUtils::audioPortToHal(const AudioPort& port, struct audio_port* halPort) { status_t result = NO_ERROR; struct audio_port_v7 halPortV7 = {}; CONVERT_CHECKED(audioPortToHal(port, &halPortV7), result); if (!audio_populate_audio_port(&halPortV7, halPort)) { result = BAD_VALUE; } return result; } status_t HidlUtils::audioPortFromHal(const struct audio_port_v7& halPort, AudioPort* port) { status_t result = NO_ERROR; bool isInput = false; port->id = halPort.id; port->name.setToExternal(halPort.name, strlen(halPort.name)); // HAL uses slightly different but convertible structures for the extended info in port // and port config structures. struct audio_port_config_device_ext halDevice = {}; struct audio_port_config_mix_ext halMix = {}; struct audio_port_config_session_ext halSession = {}; switch (halPort.type) { case AUDIO_PORT_TYPE_NONE: break; case AUDIO_PORT_TYPE_DEVICE: halDevice.type = halPort.ext.device.type; memcpy(halDevice.address, halPort.ext.device.address, AUDIO_DEVICE_MAX_ADDRESS_LEN); break; case AUDIO_PORT_TYPE_MIX: halMix.handle = halPort.ext.mix.handle; break; case AUDIO_PORT_TYPE_SESSION: halSession.session = halPort.ext.session.session; break; } CONVERT_CHECKED(audioPortExtendedInfoFromHal(halPort.role, halPort.type, halDevice, halMix, halSession, &port->ext, &isInput), result); CONVERT_CHECKED(audioTransportsFromHal(halPort, isInput, &port->transports), result); port->gains.resize(halPort.num_gains); for (size_t i = 0; i < halPort.num_gains; ++i) { CONVERT_CHECKED(audioGainFromHal(halPort.gains[i], isInput, &port->gains[i]), result); } CONVERT_CHECKED(audioPortConfigFromHal(halPort.active_config, &port->activeConfig), result); return result; } status_t HidlUtils::audioPortToHal(const AudioPort& port, struct audio_port_v7* halPort) { status_t result = NO_ERROR; halPort->id = port.id; strncpy(halPort->name, port.name.c_str(), AUDIO_PORT_MAX_NAME_LEN); halPort->name[AUDIO_PORT_MAX_NAME_LEN - 1] = '\0'; if (port.name.size() >= AUDIO_PORT_MAX_NAME_LEN) { ALOGE("HIDL Audio Port name is too long: %zu", port.name.size()); result = BAD_VALUE; } CONVERT_CHECKED(audioTransportsToHal(port.transports, halPort), result); halPort->num_gains = port.gains.size(); if (halPort->num_gains > AUDIO_PORT_MAX_GAINS) { ALOGE("HIDL Audio Port has too many gains: %u", halPort->num_gains); halPort->num_gains = AUDIO_PORT_MAX_GAINS; result = BAD_VALUE; } for (size_t i = 0; i < halPort->num_gains; ++i) { CONVERT_CHECKED(audioGainToHal(port.gains[i], &halPort->gains[i]), result); } // HAL uses slightly different but convertible structures for the extended info in port // and port config structures. struct audio_port_config_device_ext halDevice = {}; struct audio_port_config_mix_ext halMix = {}; struct audio_port_config_session_ext halSession = {}; CONVERT_CHECKED(audioPortExtendedInfoToHal(port.ext, &halPort->role, &halPort->type, &halDevice, &halMix, &halSession), result); switch (halPort->type) { case AUDIO_PORT_TYPE_NONE: break; case AUDIO_PORT_TYPE_DEVICE: halPort->ext.device.type = halDevice.type; memcpy(halPort->ext.device.address, halDevice.address, AUDIO_DEVICE_MAX_ADDRESS_LEN); break; case AUDIO_PORT_TYPE_MIX: halPort->ext.mix.handle = halMix.handle; break; case AUDIO_PORT_TYPE_SESSION: halPort->ext.session.session = halSession.session; break; } CONVERT_CHECKED(audioPortConfigToHal(port.activeConfig, &halPort->active_config), result); return result; } status_t HidlUtils::audioTransportsFromHal(const struct audio_port_v7& halPort, bool isInput, hidl_vec* transports) { if (halPort.num_audio_profiles > AUDIO_PORT_MAX_AUDIO_PROFILES || halPort.num_extra_audio_descriptors > AUDIO_PORT_MAX_EXTRA_AUDIO_DESCRIPTORS) { ALOGE("%s, too many audio profiles(%u) or extra audio descriptors(%u)", __func__, halPort.num_audio_profiles, halPort.num_extra_audio_descriptors); return BAD_VALUE; } status_t result = NO_ERROR; transports->resize(halPort.num_audio_profiles + halPort.num_extra_audio_descriptors); size_t idx = 0; for (size_t i = 0; i < halPort.num_audio_profiles; ++i) { auto& transport = (*transports)[idx++]; transport.audioCapability.profile({}); CONVERT_CHECKED(audioProfileFromHal(halPort.audio_profiles[i], isInput, &transport.audioCapability.profile()), result); CONVERT_CHECKED(encapsulationTypeFromHal(halPort.audio_profiles[i].encapsulation_type, &transport.encapsulationType), result); } for (size_t i = 0; i < halPort.num_extra_audio_descriptors; ++i) { switch (halPort.extra_audio_descriptors[i].standard) { case AUDIO_STANDARD_EDID: { const struct audio_extra_audio_descriptor* extraAudioDescriptor = &halPort.extra_audio_descriptors[i]; if (extraAudioDescriptor->descriptor_length <= EXTRA_AUDIO_DESCRIPTOR_SIZE) { auto& transport = (*transports)[idx++]; transport.audioCapability.edid( hidl_vec(extraAudioDescriptor->descriptor, extraAudioDescriptor->descriptor + extraAudioDescriptor->descriptor_length)); CONVERT_CHECKED( encapsulationTypeFromHal(extraAudioDescriptor->encapsulation_type, &transport.encapsulationType), result); } else { ALOGE("%s, invalid descriptor length %u", __func__, extraAudioDescriptor->descriptor_length); result = BAD_VALUE; } } break; case AUDIO_STANDARD_NONE: default: ALOGE("%s, invalid standard %u", __func__, halPort.extra_audio_descriptors[i].standard); result = BAD_VALUE; break; } } return result; } status_t HidlUtils::audioTransportsToHal(const hidl_vec& transports, struct audio_port_v7* halPort) { status_t result = NO_ERROR; halPort->num_audio_profiles = 0; halPort->num_extra_audio_descriptors = 0; for (const auto& transport : transports) { switch (transport.audioCapability.getDiscriminator()) { case AudioTransport::AudioCapability::hidl_discriminator::profile: if (halPort->num_audio_profiles > AUDIO_PORT_MAX_AUDIO_PROFILES) { ALOGE("%s, too many audio profiles", __func__); result = BAD_VALUE; break; } CONVERT_CHECKED( audioProfileToHal(transport.audioCapability.profile(), &halPort->audio_profiles[halPort->num_audio_profiles]), result); CONVERT_CHECKED(encapsulationTypeToHal( transport.encapsulationType, &halPort->audio_profiles[halPort->num_audio_profiles++] .encapsulation_type), result); break; case AudioTransport::AudioCapability::hidl_discriminator::edid: if (halPort->num_extra_audio_descriptors > AUDIO_PORT_MAX_EXTRA_AUDIO_DESCRIPTORS) { ALOGE("%s, too many extra audio descriptors", __func__); result = BAD_VALUE; break; } if (transport.audioCapability.edid().size() > EXTRA_AUDIO_DESCRIPTOR_SIZE) { ALOGE("%s, wrong edid size %zu", __func__, transport.audioCapability.edid().size()); result = BAD_VALUE; break; } struct audio_extra_audio_descriptor* extraAudioDescriptor = &halPort->extra_audio_descriptors[halPort->num_extra_audio_descriptors++]; extraAudioDescriptor->standard = AUDIO_STANDARD_EDID; extraAudioDescriptor->descriptor_length = transport.audioCapability.edid().size(); memcpy(extraAudioDescriptor->descriptor, transport.audioCapability.edid().data(), transport.audioCapability.edid().size() * sizeof(uint8_t)); CONVERT_CHECKED(encapsulationTypeToHal(transport.encapsulationType, &extraAudioDescriptor->encapsulation_type), result); break; } } return result; } status_t HidlUtils::audioProfileFromHal(const struct audio_profile& halProfile, bool isInput, AudioProfile* profile) { status_t result = NO_ERROR; CONVERT_CHECKED(audioFormatFromHal(halProfile.format, &profile->format), result); profile->sampleRates.resize(halProfile.num_sample_rates); for (size_t i = 0; i < halProfile.num_sample_rates; ++i) { profile->sampleRates[i] = halProfile.sample_rates[i]; } profile->channelMasks.resize(halProfile.num_channel_masks); for (size_t i = 0; i < halProfile.num_channel_masks; ++i) { CONVERT_CHECKED(audioChannelMaskFromHal(halProfile.channel_masks[i], isInput, &profile->channelMasks[i]), result); } return result; } status_t HidlUtils::audioProfileToHal(const AudioProfile& profile, struct audio_profile* halProfile) { status_t result = NO_ERROR; CONVERT_CHECKED(audioFormatToHal(profile.format, &halProfile->format), result); memset(halProfile->sample_rates, 0, sizeof(halProfile->sample_rates)); halProfile->num_sample_rates = profile.sampleRates.size(); if (halProfile->num_sample_rates > AUDIO_PORT_MAX_SAMPLING_RATES) { ALOGE("HIDL Audio profile has too many sample rates: %u", halProfile->num_sample_rates); halProfile->num_sample_rates = AUDIO_PORT_MAX_SAMPLING_RATES; result = BAD_VALUE; } for (size_t i = 0; i < halProfile->num_sample_rates; ++i) { halProfile->sample_rates[i] = profile.sampleRates[i]; } memset(halProfile->channel_masks, 0, sizeof(halProfile->channel_masks)); halProfile->num_channel_masks = profile.channelMasks.size(); if (halProfile->num_channel_masks > AUDIO_PORT_MAX_CHANNEL_MASKS) { ALOGE("HIDL Audio profile has too many channel masks: %u", halProfile->num_channel_masks); halProfile->num_channel_masks = AUDIO_PORT_MAX_CHANNEL_MASKS; result = BAD_VALUE; } for (size_t i = 0; i < halProfile->num_channel_masks; ++i) { CONVERT_CHECKED( audioChannelMaskToHal(profile.channelMasks[i], &halProfile->channel_masks[i]), status); } return result; } status_t HidlUtils::audioTagsFromHal(const std::vector& strTags, hidl_vec* tags) { status_t result = NO_ERROR; tags->resize(strTags.size()); size_t to = 0; for (size_t from = 0; from < strTags.size(); ++from) { const auto& tag = strTags[from]; if (xsd::isVendorExtension(tag)) { (*tags)[to++] = tag; } else { ALOGE("Vendor extension tag is ill-formed: \"%s\"", tag.c_str()); result = BAD_VALUE; } } if (to != strTags.size()) { tags->resize(to); } return result; } status_t HidlUtils::audioTagsToHal(const hidl_vec& tags, char* halTags) { memset(halTags, 0, AUDIO_ATTRIBUTES_TAGS_MAX_SIZE); status_t result = NO_ERROR; std::ostringstream halTagsBuffer; bool hasValue = false; for (const auto& tag : tags) { if (hasValue) { halTagsBuffer << sAudioTagSeparator; } if (xsd::isVendorExtension(tag) && strchr(tag.c_str(), sAudioTagSeparator) == nullptr) { halTagsBuffer << tag; hasValue = true; } else { ALOGE("Vendor extension tag is ill-formed: \"%s\"", tag.c_str()); result = BAD_VALUE; } } std::string fullHalTags{std::move(halTagsBuffer.str())}; strncpy(halTags, fullHalTags.c_str(), AUDIO_ATTRIBUTES_TAGS_MAX_SIZE); CONVERT_CHECKED(fullHalTags.length() <= AUDIO_ATTRIBUTES_TAGS_MAX_SIZE ? NO_ERROR : BAD_VALUE, result); return result; } hidl_vec HidlUtils::filterOutNonVendorTags(const hidl_vec& tags) { hidl_vec result; result.resize(tags.size()); size_t resultIdx = 0; for (const auto& tag : tags) { if (xsd::maybeVendorExtension(tag)) { result[resultIdx++] = tag; } } if (resultIdx != result.size()) { result.resize(resultIdx); } return result; } std::vector HidlUtils::filterOutNonVendorTags(const std::vector& tags) { std::vector result; std::copy_if(tags.begin(), tags.end(), std::back_inserter(result), xsd::maybeVendorExtension); return result; } std::vector HidlUtils::splitAudioTags(const char* halTags) { return utils::splitString(halTags, sAudioTagSeparator); } status_t HidlUtils::deviceAddressFromHal(audio_devices_t halDeviceType, const char* halDeviceAddress, DeviceAddress* device) { status_t result = NO_ERROR; CONVERT_CHECKED(audioDeviceTypeFromHal(halDeviceType, &device->deviceType), result); if (audio_is_a2dp_out_device(halDeviceType) || audio_is_a2dp_in_device(halDeviceType)) { device->address.mac({}); if (halDeviceAddress != nullptr) { auto& mac = device->address.mac(); int status = sscanf(halDeviceAddress, "%hhX:%hhX:%hhX:%hhX:%hhX:%hhX", &mac[0], &mac[1], &mac[2], &mac[3], &mac[4], &mac[5]); if (status != 6) { ALOGE("BT A2DP device \"%s\" MAC address \"%s\" is invalid", device->deviceType.c_str(), halDeviceAddress); result = BAD_VALUE; } } else { ALOGE("BT A2DP device \"%s\" does not have a MAC address", halDeviceAddress); result = BAD_VALUE; } } else if (halDeviceType == AUDIO_DEVICE_OUT_IP || halDeviceType == AUDIO_DEVICE_IN_IP) { device->address.ipv4({}); if (halDeviceAddress != nullptr) { auto& ipv4 = device->address.ipv4(); int status = sscanf(halDeviceAddress, "%hhu.%hhu.%hhu.%hhu", &ipv4[0], &ipv4[1], &ipv4[2], &ipv4[3]); if (status != 4) { ALOGE("IP device \"%s\" IPv4 address \"%s\" is invalid", device->deviceType.c_str(), halDeviceAddress); result = BAD_VALUE; } } else { ALOGE("IP device \"%s\" does not have an IPv4 address", device->deviceType.c_str()); result = BAD_VALUE; } } else if (audio_is_usb_out_device(halDeviceType) || audio_is_usb_in_device(halDeviceType)) { device->address.alsa({}); if (halDeviceAddress != nullptr) { auto& alsa = device->address.alsa(); int status = sscanf(halDeviceAddress, "card=%d;device=%d", &alsa.card, &alsa.device); if (status != 2) { ALOGE("USB device \"%s\" ALSA address \"%s\" is invalid", device->deviceType.c_str(), halDeviceAddress); result = BAD_VALUE; } } else { ALOGE("USB device \"%s\" does not have ALSA address", device->deviceType.c_str()); result = BAD_VALUE; } } else { // Any other device type uses the 'id' field. device->address.id(halDeviceAddress != nullptr ? halDeviceAddress : ""); } return result; } status_t HidlUtils::deviceAddressToHal(const DeviceAddress& device, audio_devices_t* halDeviceType, char* halDeviceAddress) { status_t result = NO_ERROR; CONVERT_CHECKED(audioDeviceTypeToHal(device.deviceType, halDeviceType), result); memset(halDeviceAddress, 0, AUDIO_DEVICE_MAX_ADDRESS_LEN); if (audio_is_a2dp_out_device(*halDeviceType) || audio_is_a2dp_in_device(*halDeviceType)) { if (device.address.getDiscriminator() == DeviceAddress::Address::hidl_discriminator::mac) { const auto& mac = device.address.mac(); snprintf(halDeviceAddress, AUDIO_DEVICE_MAX_ADDRESS_LEN, "%02X:%02X:%02X:%02X:%02X:%02X", mac[0], mac[1], mac[2], mac[3], mac[4], mac[5]); } else { ALOGE("BT A2DP device \"%s\" does not have MAC address set", device.deviceType.c_str()); result = BAD_VALUE; } } else if (*halDeviceType == AUDIO_DEVICE_OUT_IP || *halDeviceType == AUDIO_DEVICE_IN_IP) { if (device.address.getDiscriminator() == DeviceAddress::Address::hidl_discriminator::ipv4) { const auto& ipv4 = device.address.ipv4(); snprintf(halDeviceAddress, AUDIO_DEVICE_MAX_ADDRESS_LEN, "%d.%d.%d.%d", ipv4[0], ipv4[1], ipv4[2], ipv4[3]); } else { ALOGE("IP device \"%s\" does not have IPv4 address set", device.deviceType.c_str()); result = BAD_VALUE; } } else if (audio_is_usb_out_device(*halDeviceType) || audio_is_usb_in_device(*halDeviceType)) { if (device.address.getDiscriminator() == DeviceAddress::Address::hidl_discriminator::alsa) { const auto& alsa = device.address.alsa(); snprintf(halDeviceAddress, AUDIO_DEVICE_MAX_ADDRESS_LEN, "card=%d;device=%d", alsa.card, alsa.device); } else { ALOGE("USB device \"%s\" does not have ALSA address set", device.deviceType.c_str()); result = BAD_VALUE; } } else { // Any other device type uses the 'id' field. if (device.address.getDiscriminator() == DeviceAddress::Address::hidl_discriminator::id) { snprintf(halDeviceAddress, AUDIO_DEVICE_MAX_ADDRESS_LEN, "%s", device.address.id().c_str()); } } return result; } } // namespace implementation } // namespace CPP_VERSION } // namespace common } // namespace audio } // namespace hardware } // namespace android