/* * Copyright (C) 2009 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. */ //#define LOG_NDEBUG 0 #define LOG_TAG "MP3Extractor" #include #include "include/MP3Extractor.h" #include "include/avc_utils.h" #include "include/ID3.h" #include "include/VBRISeeker.h" #include "include/XINGSeeker.h" #include #include #include #include #include #include #include #include #include #include #include namespace android { // Everything must match except for // protection, bitrate, padding, private bits, mode, mode extension, // copyright bit, original bit and emphasis. // Yes ... there are things that must indeed match... static const uint32_t kMask = 0xfffe0c00; static bool Resync( const sp &source, uint32_t match_header, off64_t *inout_pos, off64_t *post_id3_pos, uint32_t *out_header) { if (post_id3_pos != NULL) { *post_id3_pos = 0; } if (*inout_pos == 0) { // Skip an optional ID3 header if syncing at the very beginning // of the datasource. for (;;) { uint8_t id3header[10]; if (source->readAt(*inout_pos, id3header, sizeof(id3header)) < (ssize_t)sizeof(id3header)) { // If we can't even read these 10 bytes, we might as well bail // out, even if there _were_ 10 bytes of valid mp3 audio data... return false; } if (memcmp("ID3", id3header, 3)) { break; } // Skip the ID3v2 header. size_t len = ((id3header[6] & 0x7f) << 21) | ((id3header[7] & 0x7f) << 14) | ((id3header[8] & 0x7f) << 7) | (id3header[9] & 0x7f); len += 10; *inout_pos += len; ALOGV("skipped ID3 tag, new starting offset is %lld (0x%016llx)", *inout_pos, *inout_pos); } if (post_id3_pos != NULL) { *post_id3_pos = *inout_pos; } } off64_t pos = *inout_pos; bool valid = false; const size_t kMaxReadBytes = 1024; const size_t kMaxBytesChecked = 128 * 1024; uint8_t buf[kMaxReadBytes]; ssize_t bytesToRead = kMaxReadBytes; ssize_t totalBytesRead = 0; ssize_t remainingBytes = 0; bool reachEOS = false; uint8_t *tmp = buf; do { if (pos >= *inout_pos + kMaxBytesChecked) { // Don't scan forever. ALOGV("giving up at offset %lld", pos); break; } if (remainingBytes < 4) { if (reachEOS) { break; } else { memcpy(buf, tmp, remainingBytes); bytesToRead = kMaxReadBytes - remainingBytes; /* * The next read position should start from the end of * the last buffer, and thus should include the remaining * bytes in the buffer. */ totalBytesRead = source->readAt(pos + remainingBytes, buf + remainingBytes, bytesToRead); if (totalBytesRead <= 0) { break; } reachEOS = (totalBytesRead != bytesToRead); totalBytesRead += remainingBytes; remainingBytes = totalBytesRead; tmp = buf; continue; } } uint32_t header = U32_AT(tmp); if (match_header != 0 && (header & kMask) != (match_header & kMask)) { ++pos; ++tmp; --remainingBytes; continue; } size_t frame_size; int sample_rate, num_channels, bitrate; if (!GetMPEGAudioFrameSize( header, &frame_size, &sample_rate, &num_channels, &bitrate)) { ++pos; ++tmp; --remainingBytes; continue; } ALOGV("found possible 1st frame at %lld (header = 0x%08x)", pos, header); // We found what looks like a valid frame, // now find its successors. off64_t test_pos = pos + frame_size; valid = true; for (int j = 0; j < 3; ++j) { uint8_t tmp[4]; if (source->readAt(test_pos, tmp, 4) < 4) { valid = false; break; } uint32_t test_header = U32_AT(tmp); ALOGV("subsequent header is %08x", test_header); if ((test_header & kMask) != (header & kMask)) { valid = false; break; } size_t test_frame_size; if (!GetMPEGAudioFrameSize( test_header, &test_frame_size)) { valid = false; break; } ALOGV("found subsequent frame #%d at %lld", j + 2, test_pos); test_pos += test_frame_size; } if (valid) { *inout_pos = pos; if (out_header != NULL) { *out_header = header; } } else { ALOGV("no dice, no valid sequence of frames found."); } ++pos; ++tmp; --remainingBytes; } while (!valid); return valid; } class MP3Source : public MediaSource { public: MP3Source( const sp &meta, const sp &source, off64_t first_frame_pos, uint32_t fixed_header, const sp &seeker); virtual status_t start(MetaData *params = NULL); virtual status_t stop(); virtual sp getFormat(); virtual status_t read( MediaBuffer **buffer, const ReadOptions *options = NULL); protected: virtual ~MP3Source(); private: static const size_t kMaxFrameSize; sp mMeta; sp mDataSource; off64_t mFirstFramePos; uint32_t mFixedHeader; off64_t mCurrentPos; int64_t mCurrentTimeUs; bool mStarted; sp mSeeker; MediaBufferGroup *mGroup; int64_t mBasisTimeUs; int64_t mSamplesRead; MP3Source(const MP3Source &); MP3Source &operator=(const MP3Source &); }; MP3Extractor::MP3Extractor( const sp &source, const sp &meta) : mInitCheck(NO_INIT), mDataSource(source), mFirstFramePos(-1), mFixedHeader(0) { off64_t pos = 0; off64_t post_id3_pos; uint32_t header; bool success; int64_t meta_offset; uint32_t meta_header; int64_t meta_post_id3_offset; if (meta != NULL && meta->findInt64("offset", &meta_offset) && meta->findInt32("header", (int32_t *)&meta_header) && meta->findInt64("post-id3-offset", &meta_post_id3_offset)) { // The sniffer has already done all the hard work for us, simply // accept its judgement. pos = (off64_t)meta_offset; header = meta_header; post_id3_pos = (off64_t)meta_post_id3_offset; success = true; } else { success = Resync(mDataSource, 0, &pos, &post_id3_pos, &header); } if (!success) { // mInitCheck will remain NO_INIT return; } mFirstFramePos = pos; mFixedHeader = header; size_t frame_size; int sample_rate; int num_channels; int bitrate; GetMPEGAudioFrameSize( header, &frame_size, &sample_rate, &num_channels, &bitrate); unsigned layer = 4 - ((header >> 17) & 3); mMeta = new MetaData; switch (layer) { case 1: mMeta->setCString(kKeyMIMEType, MEDIA_MIMETYPE_AUDIO_MPEG_LAYER_I); break; case 2: mMeta->setCString(kKeyMIMEType, MEDIA_MIMETYPE_AUDIO_MPEG_LAYER_II); break; case 3: mMeta->setCString(kKeyMIMEType, MEDIA_MIMETYPE_AUDIO_MPEG); break; default: TRESPASS(); } mMeta->setInt32(kKeySampleRate, sample_rate); mMeta->setInt32(kKeyBitRate, bitrate * 1000); mMeta->setInt32(kKeyChannelCount, num_channels); sp seeker = XINGSeeker::CreateFromSource(mDataSource, mFirstFramePos); if (seeker == NULL) { mSeeker = VBRISeeker::CreateFromSource(mDataSource, post_id3_pos); } else { mSeeker = seeker; int encd = seeker->getEncoderDelay(); int encp = seeker->getEncoderPadding(); if (encd != 0 || encp != 0) { mMeta->setInt32(kKeyEncoderDelay, encd); mMeta->setInt32(kKeyEncoderPadding, encp); } } if (mSeeker != NULL) { // While it is safe to send the XING/VBRI frame to the decoder, this will // result in an extra 1152 samples being output. The real first frame to // decode is after the XING/VBRI frame, so skip there. mFirstFramePos += frame_size; } int64_t durationUs; if (mSeeker == NULL || !mSeeker->getDuration(&durationUs)) { off64_t fileSize; if (mDataSource->getSize(&fileSize) == OK) { durationUs = 8000LL * (fileSize - mFirstFramePos) / bitrate; } else { durationUs = -1; } } if (durationUs >= 0) { mMeta->setInt64(kKeyDuration, durationUs); } mInitCheck = OK; // Get iTunes-style gapless info if present. // When getting the id3 tag, skip the V1 tags to prevent the source cache // from being iterated to the end of the file. ID3 id3(mDataSource, true); if (id3.isValid()) { ID3::Iterator *com = new ID3::Iterator(id3, "COM"); if (com->done()) { delete com; com = new ID3::Iterator(id3, "COMM"); } while(!com->done()) { String8 commentdesc; String8 commentvalue; com->getString(&commentdesc, &commentvalue); const char * desc = commentdesc.string(); const char * value = commentvalue.string(); // first 3 characters are the language, which we don't care about if(strlen(desc) > 3 && strcmp(desc + 3, "iTunSMPB") == 0) { int32_t delay, padding; if (sscanf(value, " %*x %x %x %*x", &delay, &padding) == 2) { mMeta->setInt32(kKeyEncoderDelay, delay); mMeta->setInt32(kKeyEncoderPadding, padding); } break; } com->next(); } delete com; com = NULL; } } size_t MP3Extractor::countTracks() { return mInitCheck != OK ? 0 : 1; } sp MP3Extractor::getTrack(size_t index) { if (mInitCheck != OK || index != 0) { return NULL; } return new MP3Source( mMeta, mDataSource, mFirstFramePos, mFixedHeader, mSeeker); } sp MP3Extractor::getTrackMetaData( size_t index, uint32_t /* flags */) { if (mInitCheck != OK || index != 0) { return NULL; } return mMeta; } //////////////////////////////////////////////////////////////////////////////// // The theoretical maximum frame size for an MPEG audio stream should occur // while playing a Layer 2, MPEGv2.5 audio stream at 160kbps (with padding). // The size of this frame should be... // ((1152 samples/frame * 160000 bits/sec) / // (8000 samples/sec * 8 bits/byte)) + 1 padding byte/frame = 2881 bytes/frame. // Set our max frame size to the nearest power of 2 above this size (aka, 4kB) const size_t MP3Source::kMaxFrameSize = (1 << 12); /* 4096 bytes */ MP3Source::MP3Source( const sp &meta, const sp &source, off64_t first_frame_pos, uint32_t fixed_header, const sp &seeker) : mMeta(meta), mDataSource(source), mFirstFramePos(first_frame_pos), mFixedHeader(fixed_header), mCurrentPos(0), mCurrentTimeUs(0), mStarted(false), mSeeker(seeker), mGroup(NULL), mBasisTimeUs(0), mSamplesRead(0) { } MP3Source::~MP3Source() { if (mStarted) { stop(); } } status_t MP3Source::start(MetaData *) { CHECK(!mStarted); mGroup = new MediaBufferGroup; mGroup->add_buffer(new MediaBuffer(kMaxFrameSize)); mCurrentPos = mFirstFramePos; mCurrentTimeUs = 0; mBasisTimeUs = mCurrentTimeUs; mSamplesRead = 0; mStarted = true; return OK; } status_t MP3Source::stop() { CHECK(mStarted); delete mGroup; mGroup = NULL; mStarted = false; return OK; } sp MP3Source::getFormat() { return mMeta; } status_t MP3Source::read( MediaBuffer **out, const ReadOptions *options) { *out = NULL; int64_t seekTimeUs; ReadOptions::SeekMode mode; bool seekCBR = false; if (options != NULL && options->getSeekTo(&seekTimeUs, &mode)) { int64_t actualSeekTimeUs = seekTimeUs; if (mSeeker == NULL || !mSeeker->getOffsetForTime(&actualSeekTimeUs, &mCurrentPos)) { int32_t bitrate; if (!mMeta->findInt32(kKeyBitRate, &bitrate)) { // bitrate is in bits/sec. ALOGI("no bitrate"); return ERROR_UNSUPPORTED; } mCurrentTimeUs = seekTimeUs; mCurrentPos = mFirstFramePos + seekTimeUs * bitrate / 8000000; seekCBR = true; } else { mCurrentTimeUs = actualSeekTimeUs; } mBasisTimeUs = mCurrentTimeUs; mSamplesRead = 0; } MediaBuffer *buffer; status_t err = mGroup->acquire_buffer(&buffer); if (err != OK) { return err; } size_t frame_size; int bitrate; int num_samples; int sample_rate; for (;;) { ssize_t n = mDataSource->readAt(mCurrentPos, buffer->data(), 4); if (n < 4) { buffer->release(); buffer = NULL; return ERROR_END_OF_STREAM; } uint32_t header = U32_AT((const uint8_t *)buffer->data()); if ((header & kMask) == (mFixedHeader & kMask) && GetMPEGAudioFrameSize( header, &frame_size, &sample_rate, NULL, &bitrate, &num_samples)) { // re-calculate mCurrentTimeUs because we might have called Resync() if (seekCBR) { mCurrentTimeUs = (mCurrentPos - mFirstFramePos) * 8000 / bitrate; mBasisTimeUs = mCurrentTimeUs; } break; } // Lost sync. ALOGV("lost sync! header = 0x%08x, old header = 0x%08x\n", header, mFixedHeader); off64_t pos = mCurrentPos; if (!Resync(mDataSource, mFixedHeader, &pos, NULL, NULL)) { ALOGE("Unable to resync. Signalling end of stream."); buffer->release(); buffer = NULL; return ERROR_END_OF_STREAM; } mCurrentPos = pos; // Try again with the new position. } CHECK(frame_size <= buffer->size()); ssize_t n = mDataSource->readAt(mCurrentPos, buffer->data(), frame_size); if (n < (ssize_t)frame_size) { buffer->release(); buffer = NULL; return ERROR_END_OF_STREAM; } buffer->set_range(0, frame_size); buffer->meta_data()->setInt64(kKeyTime, mCurrentTimeUs); buffer->meta_data()->setInt32(kKeyIsSyncFrame, 1); mCurrentPos += frame_size; mSamplesRead += num_samples; mCurrentTimeUs = mBasisTimeUs + ((mSamplesRead * 1000000) / sample_rate); *out = buffer; return OK; } sp MP3Extractor::getMetaData() { sp meta = new MetaData; if (mInitCheck != OK) { return meta; } meta->setCString(kKeyMIMEType, "audio/mpeg"); ID3 id3(mDataSource); if (!id3.isValid()) { return meta; } struct Map { int key; const char *tag1; const char *tag2; }; static const Map kMap[] = { { kKeyAlbum, "TALB", "TAL" }, { kKeyArtist, "TPE1", "TP1" }, { kKeyAlbumArtist, "TPE2", "TP2" }, { kKeyComposer, "TCOM", "TCM" }, { kKeyGenre, "TCON", "TCO" }, { kKeyTitle, "TIT2", "TT2" }, { kKeyYear, "TYE", "TYER" }, { kKeyAuthor, "TXT", "TEXT" }, { kKeyCDTrackNumber, "TRK", "TRCK" }, { kKeyDiscNumber, "TPA", "TPOS" }, { kKeyCompilation, "TCP", "TCMP" }, }; static const size_t kNumMapEntries = sizeof(kMap) / sizeof(kMap[0]); for (size_t i = 0; i < kNumMapEntries; ++i) { ID3::Iterator *it = new ID3::Iterator(id3, kMap[i].tag1); if (it->done()) { delete it; it = new ID3::Iterator(id3, kMap[i].tag2); } if (it->done()) { delete it; continue; } String8 s; it->getString(&s); delete it; meta->setCString(kMap[i].key, s); } size_t dataSize; String8 mime; const void *data = id3.getAlbumArt(&dataSize, &mime); if (data) { meta->setData(kKeyAlbumArt, MetaData::TYPE_NONE, data, dataSize); meta->setCString(kKeyAlbumArtMIME, mime.string()); } return meta; } bool SniffMP3( const sp &source, String8 *mimeType, float *confidence, sp *meta) { off64_t pos = 0; off64_t post_id3_pos; uint32_t header; if (!Resync(source, 0, &pos, &post_id3_pos, &header)) { return false; } *meta = new AMessage; (*meta)->setInt64("offset", pos); (*meta)->setInt32("header", header); (*meta)->setInt64("post-id3-offset", post_id3_pos); *mimeType = MEDIA_MIMETYPE_AUDIO_MPEG; *confidence = 0.2f; return true; } } // namespace android