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-rw-r--r--src/codecs/miniflac.cpp.bak2266
1 files changed, 266 insertions, 0 deletions
diff --git a/src/codecs/miniflac.cpp.bak2 b/src/codecs/miniflac.cpp.bak2
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+++ b/src/codecs/miniflac.cpp.bak2
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+/*
+ * Copyright 2023 jacqueline <me@jacqueline.id.au>
+ *
+ * SPDX-License-Identifier: GPL-3.0-only
+ */
+
+#include "miniflac.hpp"
+
+#include <cstdint>
+#include <cstdlib>
+
+#include "esp_heap_caps.h"
+#include "esp_log.h"
+#include "miniflac.h"
+#include "result.hpp"
+#include "sample.hpp"
+
+namespace codecs {
+
+[[maybe_unused]] static const char kTag[] = "flac";
+
+static constexpr size_t kMaxFrameSize = 4608;
+
+MiniFlacDecoder::MiniFlacDecoder()
+ : input_(),
+ buffer_(),
+ flac_(reinterpret_cast<miniflac_t*>(
+ heap_caps_malloc(sizeof(miniflac_t),
+ MALLOC_CAP_INTERNAL | MALLOC_CAP_8BIT))),
+ current_sample_() {
+ miniflac_init(flac_.get(), MINIFLAC_CONTAINER_UNKNOWN);
+ for (int i = 0; i < samples_by_channel_.size(); i++) {
+ uint32_t caps;
+ if (i == 0) {
+ caps = MALLOC_CAP_8BIT | MALLOC_CAP_INTERNAL;
+ } else {
+ // FIXME: We can *almost* fit two channels into internal ram, but we're a
+ // few KiB shy of being able to do it safely.
+ caps = MALLOC_CAP_SPIRAM;
+ }
+ samples_by_channel_[i] = reinterpret_cast<int32_t*>(
+ heap_caps_malloc(kMaxFrameSize * sizeof(int32_t), caps));
+ }
+}
+
+MiniFlacDecoder::~MiniFlacDecoder() {
+ for (int i = 0; i < samples_by_channel_.size(); i++) {
+ heap_caps_free(samples_by_channel_[i]);
+ }
+}
+
+auto MiniFlacDecoder::OpenStream(std::shared_ptr<IStream> input,uint32_t offset)
+ -> cpp::result<OutputFormat, Error> {
+ input_ = input;
+
+ MINIFLAC_RESULT res;
+ bool is_eof;
+ auto read_until_result = [&](auto fn) {
+ while (true) {
+ is_eof = buffer_.Refill(input_.get());
+ buffer_.ConsumeBytes(fn);
+ if (res == MINIFLAC_CONTINUE && !eof) {
+ continue;
+ }
+ break;
+ }
+ };
+
+ uint16_t min_block_size = 0; // In samples
+
+ read_until_result([&](cpp::span<std::byte> buf) -> size_t {
+ uint32_t bytes_used = 0;
+ res = miniflac_streaminfo_min_block_size(
+ flac_.get(), reinterpret_cast<const uint8_t*>(buf.data()),
+ buf.size_bytes(), &bytes_used, &min_block_size);
+ return bytes_used;
+ });
+
+ if (res != MINIFLAC_OK) {
+ return cpp::fail(Error::kMalformedData);
+ }
+
+ uint16_t max_block_size = 0; // In samples
+ read_until_result([&](cpp::span<std::byte> buf) -> size_t {
+ uint32_t bytes_used = 0;
+ res = miniflac_streaminfo_min_block_size(
+ flac_.get(), reinterpret_cast<const uint8_t*>(buf.data()),
+ buf.size_bytes(), &bytes_used, &max_block_size);
+ return bytes_used;
+ });
+
+ if (res != MINIFLAC_OK) {
+ return cpp::fail(Error::kMalformedData);
+ }
+
+ ESP_LOGI(kTag, "Blocksize min: %u max %u", min_block_size, max_block_size);
+
+ uint32_t sample_rate = 0;
+
+ read_until_result([&](cpp::span<std::byte> buf) -> size_t {
+ uint32_t bytes_used = 0;
+ res = miniflac_streaminfo_sample_rate(
+ flac_.get(), reinterpret_cast<const uint8_t*>(buf.data()),
+ buf.size_bytes(), &bytes_used, &sample_rate);
+ return bytes_used;
+ });
+
+ if (res != MINIFLAC_OK) {
+ return cpp::fail(Error::kMalformedData);
+ }
+
+ uint8_t channels = 0;
+
+ read_until_result([&](cpp::span<std::byte> buf) -> size_t {
+ uint32_t bytes_used = 0;
+ res = miniflac_streaminfo_channels(
+ flac_.get(), reinterpret_cast<const uint8_t*>(buf.data()),
+ buf.size_bytes(), &bytes_used, &channels);
+ return bytes_used;
+ });
+
+ if (res != MINIFLAC_OK) {
+ return cpp::fail(Error::kMalformedData);
+ }
+
+ uint64_t total_samples = 0;
+
+ read_until_result([&](cpp::span<std::byte> buf) -> size_t {
+ uint32_t bytes_used = 0;
+ res = miniflac_streaminfo_total_samples(
+ flac_.get(), reinterpret_cast<const uint8_t*>(buf.data()),
+ buf.size_bytes(), &bytes_used, &total_samples);
+ return bytes_used;
+ });
+
+ if (res != MINIFLAC_OK) {
+ return cpp::fail(Error::kMalformedData);
+ }
+
+ if (channels == 0 || channels > 2) {
+ return cpp::fail(Error::kMalformedData);
+ }
+
+ // Seeking
+ offset = 0;
+ if (offset) {
+ // Super dumb approach, but lets try it first
+ // Go to the first frame
+ while(flac_.get()->state == MINIFLAC_METADATA) {
+ read_until_result([&](cpp::span<std::byte> buf) -> size_t {
+ uint32_t bytes_used = 0;
+ res = miniflac_sync(
+ flac_.get(), reinterpret_cast<const uint8_t*>(buf.data()),
+ buf.size_bytes(), &bytes_used);
+ return bytes_used;
+ });
+ if (res != MINIFLAC_OK) {
+ ESP_LOGI(kTag, "IT HAPPENED");
+ }
+ }
+ ESP_LOGI(kTag, "Flac state: %d", flac_->state);
+
+ // Naive approach
+ uint64_t byte_offset = offset; // TODO
+
+ ESP_LOGI(kTag, "Going to skip forward %llu bytes", byte_offset);
+ if (input_.get()->CanSeek()) {
+ ESP_LOGI(kTag, "Skipping forward %llu bytes", byte_offset);
+ buffer_.Empty();
+ input_.get()->SeekTo(byte_offset, IStream::SeekFrom::kCurrentPosition);
+ }
+ // buffer_.Refill(input_.get());
+
+ // // Sync again
+ // read_until_result([&](cpp::span<std::byte> buf) -> size_t {
+ // uint32_t bytes_used = 0;
+ // res = miniflac_sync(
+ // flac_.get(), reinterpret_cast<const uint8_t*>(buf.data()),
+ // buf.size_bytes(), &bytes_used);
+ // return bytes_used;
+ // });
+ // if (res != MINIFLAC_OK) {
+ // ESP_LOGI(kTag, "IT HAPPENED HERE! %d", res);
+ // }
+
+ // ESP_LOGI(kTag, "Decoder state: %d", flac_->state);
+ // ESP_LOGI(kTag, "Frame header state: %d", flac_->frame.header.state);
+
+ // // TODO: Sample number is not guaranteed, could be block index.
+ // ESP_LOGI(kTag, "Ended up... at sample %llu", flac_->frame.header.sample_number);
+ // ESP_LOGI(kTag, "and block index: %lu", flac_->frame.header.frame_number);
+ // ESP_LOGI(kTag, "total samples: %llu", total_samples);
+ }
+
+
+ OutputFormat format{
+ .num_channels = static_cast<uint8_t>(channels),
+ .sample_rate_hz = static_cast<uint32_t>(sample_rate),
+ .total_samples = total_samples * channels,
+ };
+
+ return format;
+}
+
+auto MiniFlacDecoder::DecodeTo(cpp::span<sample::Sample> output)
+ -> cpp::result<OutputInfo, Error> {
+ bool is_eof = false;
+
+ if (!current_sample_) {
+ MINIFLAC_RESULT res = MINIFLAC_CONTINUE;
+ while (res == MINIFLAC_CONTINUE && !is_eof) {
+ is_eof = buffer_.Refill(input_.get());
+ ESP_LOGI(kTag, "EOF? %s", is_eof ? "true" : "false");
+ buffer_.ConsumeBytes([&](cpp::span<std::byte> buf) -> size_t {
+ // FIXME: We should do a miniflac_sync first, in order to check that
+ // our sample buffers have enough space for the next frame.
+ uint32_t bytes_read = 0;
+ res = miniflac_decode(
+ flac_.get(), reinterpret_cast<const uint8_t*>(buf.data()),
+ buf.size_bytes(), &bytes_read, samples_by_channel_.data());
+ return bytes_read;
+ });
+ }
+
+ if (res == MINIFLAC_OK) {
+ current_sample_ = 0;
+ } else if (is_eof) {
+ return OutputInfo{
+ .samples_written = 0,
+ .is_stream_finished = true,
+ };
+ } else {
+ ESP_LOGI(kTag, "Failed: decoder result: %d", res);
+ return cpp::fail(Error::kMalformedData);
+ }
+ }
+
+ size_t samples_written = 0;
+ if (current_sample_) {
+ while (*current_sample_ < flac_->frame.header.block_size) {
+ if (samples_written + flac_->frame.header.channels >= output.size()) {
+ // We can't fit the next full PCM frame into the buffer.
+ return OutputInfo{.samples_written = samples_written,
+ .is_stream_finished = false};
+ }
+
+ for (int channel = 0; channel < flac_->frame.header.channels; channel++) {
+ output[samples_written++] =
+ sample::FromSigned(samples_by_channel_[channel][*current_sample_],
+ flac_->frame.header.bps);
+ }
+ (*current_sample_)++;
+ }
+ }
+
+ current_sample_.reset();
+ ESP_LOGI(kTag, "Samples written %lu", (uint32_t)samples_written);
+ return OutputInfo{.samples_written = samples_written,
+ .is_stream_finished = samples_written == 0 && is_eof};
+}
+
+auto MiniFlacDecoder::SeekTo(size_t target) -> cpp::result<void, Error> {
+ return {};
+}
+
+} // namespace codecs
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