ref: eb897d844ffd9b8fabc50cdd619a07e7a89874d4
dir: /src/smploaders/ft2_load_aiff.c/
/* Apple AIFF sample loader ** ** Note: Vol/loop sanitation is done in the last stage ** of sample loading, so you don't need to do that here. ** Do NOT close the file handle! */ #include <stdio.h> #include <stdint.h> #include <stdbool.h> #include <math.h> #include "../ft2_header.h" #include "../ft2_audio.h" #include "../ft2_sample_ed.h" #include "../ft2_sysreqs.h" #include "../ft2_sample_loader.h" static uint32_t getAIFFSampleRate(uint8_t *in); static bool aiffIsStereo(FILE *f); // only ran on files that are confirmed to be AIFFs bool loadAIFF(FILE *f, uint32_t filesize) { char compType[4]; int8_t *audioDataS8; uint8_t sampleRateBytes[10], *audioDataU8; int16_t *audioDataS16, smp16; uint16_t numChannels, bitDepth; int32_t *audioDataS32; uint32_t i, blockName, blockSize; uint32_t offset, len32; sample_t *s = &tmpSmp; fseek(f, 8, SEEK_SET); fread(compType, 1, 4, f); rewind(f); if (filesize < 12) { loaderMsgBox("Error loading sample: The sample is not supported or is invalid!"); return false; } uint32_t commPtr = 0, commLen = 0; uint32_t ssndPtr = 0, ssndLen = 0; fseek(f, 12, SEEK_SET); while (!feof(f) && (uint32_t)ftell(f) < filesize-12) { fread(&blockName, 4, 1, f); if (feof(f)) break; fread(&blockSize, 4, 1, f); if (feof(f)) break; blockName = SWAP32(blockName); blockSize = SWAP32(blockSize); switch (blockName) { case 0x434F4D4D: // "COMM" { commPtr = ftell(f); commLen = blockSize; } break; case 0x53534E44: // "SSND" { ssndPtr = ftell(f); ssndLen = blockSize; } break; default: break; } fseek(f, blockSize + (blockSize & 1), SEEK_CUR); } if (commPtr == 0 || commLen < 18 || ssndPtr == 0) { loaderMsgBox("Error loading sample: The sample is not supported or is invalid!"); return false; } // kludge for strange AIFFs if (ssndLen == 0) ssndLen = filesize - ssndPtr; if (ssndPtr+ssndLen > (uint32_t)filesize) ssndLen = filesize - ssndPtr; fseek(f, commPtr, SEEK_SET); fread(&numChannels, 2, 1, f); numChannels = SWAP16(numChannels); fseek(f, 4, SEEK_CUR); fread(&bitDepth, 2, 1, f); bitDepth = SWAP16(bitDepth); fread(sampleRateBytes, 1, 10, f); if (numChannels != 1 && numChannels != 2) { loaderMsgBox("Error loading sample: Unsupported amounts of channels!"); return false; } // read compression type (if present) bool signedSample = true; bool floatSample = false; if (commLen > 18) { fread(&compType, 1, 4, f); if (!memcmp(compType, "raw ", 4)) { signedSample = false; } else if (!memcmp(compType, "FL32", 4) || !memcmp(compType, "fl32", 4) || !memcmp(compType, "FL64", 4) || !memcmp(compType, "fl64", 4)) { floatSample = true; } else { loaderMsgBox("Error loading sample: Unsupported AIFF type!"); return false; } } if (bitDepth != 8 && bitDepth != 16 && bitDepth != 24 && bitDepth != 32 && !(floatSample && bitDepth == 64) && !(floatSample && bitDepth == 32)) { loaderMsgBox("Error loading sample: Unsupported AIFF type!"); return false; } uint32_t sampleRate = getAIFFSampleRate(sampleRateBytes); // sample data chunk fseek(f, ssndPtr, SEEK_SET); fread(&offset, 4, 1, f); if (offset > 0) { loaderMsgBox("Error loading sample: The sample is not supported or is invalid!"); return false; } fseek(f, 4, SEEK_CUR); ssndLen -= 8; // don't include offset and blockSize datas uint32_t sampleLength = ssndLen; int16_t stereoSampleLoadMode = -1; if (aiffIsStereo(f)) stereoSampleLoadMode = loaderSysReq(4, "System request", "This is a stereo sample...", NULL); // read sample data if (!floatSample && bitDepth == 8) // 8-BIT INTEGER SAMPLE { if (!allocateSmpData(s, sampleLength, false)) { loaderMsgBox("Not enough memory!"); return false; } if (fread(s->dataPtr, sampleLength, 1, f) != 1) { loaderMsgBox("General I/O error during loading! Is the file in use?"); return false; } audioDataS8 = (int8_t *)s->dataPtr; if (!signedSample) { for (i = 0; i < sampleLength; i++) audioDataS8[i] ^= 0x80; } // stereo conversion if (numChannels == 2) { sampleLength /= 2; switch (stereoSampleLoadMode) { case STEREO_SAMPLE_READ_LEFT: { for (i = 1; i < sampleLength; i++) audioDataS8[i] = audioDataS8[(i * 2) + 0]; } break; case STEREO_SAMPLE_READ_RIGHT: { len32 = sampleLength - 1; for (i = 0; i < len32; i++) audioDataS8[i] = audioDataS8[(i * 2) + 1]; audioDataS8[i] = 0; } break; default: case STEREO_SAMPLE_CONVERT: { len32 = sampleLength - 1; for (i = 0; i < len32; i++) { smp16 = (audioDataS8[(i * 2) + 0] + audioDataS8[(i * 2) + 1]) >> 1; audioDataS8[i] = (int8_t)smp16; } audioDataS8[i] = 0; } break; } } } else if (!floatSample && bitDepth == 16) // 16-BIT INTEGER SAMPLE { sampleLength /= sizeof (int16_t); if (!allocateSmpData(s, sampleLength * sizeof (int16_t), false)) { loaderMsgBox("Not enough memory!"); return false; } if (fread(s->dataPtr, sampleLength, sizeof (int16_t), f) != sizeof (int16_t)) { loaderMsgBox("General I/O error during loading! Is the file in use?"); return false; } // change endianness audioDataS16 = (int16_t *)s->dataPtr; for (i = 0; i < sampleLength; i++) audioDataS16[i] = SWAP16(audioDataS16[i]); // stereo conversion if (numChannels == 2) { sampleLength /= 2; switch (stereoSampleLoadMode) { case STEREO_SAMPLE_READ_LEFT: { for (i = 1; i < sampleLength; i++) audioDataS16[i] = audioDataS16[(i * 2) + 0]; } break; case STEREO_SAMPLE_READ_RIGHT: { len32 = sampleLength - 1; for (i = 0; i < len32; i++) audioDataS16[i] = audioDataS16[(i * 2) + 1]; audioDataS16[i] = 0; } break; default: case STEREO_SAMPLE_CONVERT: { len32 = sampleLength - 1; for (i = 0; i < len32; i++) { int32_t smp32 = (audioDataS16[(i * 2) + 0] + audioDataS16[(i * 2) + 1]) >> 1; audioDataS16[i] = (int16_t)smp32; } audioDataS16[i] = 0; } break; } } s->flags |= SAMPLE_16BIT; } else if (!floatSample && bitDepth == 24) // 24-BIT INTEGER SAMPLE { sampleLength /= 3; if (!allocateSmpData(s, sampleLength * sizeof (int32_t), false)) { loaderMsgBox("Not enough memory!"); return false; } if (fread(&s->dataPtr[sampleLength], sampleLength, 3, f) != 3) { loaderMsgBox("General I/O error during loading! Is the file in use?"); return false; } audioDataS32 = (int32_t *)s->dataPtr; // convert to 32-bit audioDataU8 = (uint8_t *)s->dataPtr + sampleLength; for (i = 0; i < sampleLength; i++) { audioDataS32[i] = (audioDataU8[0] << 24) | (audioDataU8[1] << 16) | (audioDataU8[2] << 8); audioDataU8 += 3; } // stereo conversion if (numChannels == 2) { sampleLength /= 2; switch (stereoSampleLoadMode) { case STEREO_SAMPLE_READ_LEFT: { for (i = 1; i < sampleLength; i++) audioDataS32[i] = audioDataS32[(i * 2) + 0]; } break; case STEREO_SAMPLE_READ_RIGHT: { len32 = sampleLength - 1; for (i = 0; i < len32; i++) audioDataS32[i] = audioDataS32[(i * 2) + 1]; audioDataS32[i] = 0; } break; default: case STEREO_SAMPLE_CONVERT: { len32 = sampleLength - 1; for (i = 0; i < len32; i++) { int64_t smp64 = audioDataS32[(i * 2) + 0]; smp64 += audioDataS32[(i * 2) + 1]; smp64 >>= 1; audioDataS32[i] = (int32_t)smp64; } audioDataS32[i] = 0; } break; } } normalizeSigned32Bit(audioDataS32, sampleLength); audioDataS16 = (int16_t *)s->dataPtr; for (i = 0; i < sampleLength; i++) audioDataS16[i] = audioDataS32[i] >> 16; s->flags |= SAMPLE_16BIT; } else if (!floatSample && bitDepth == 32) // 32-BIT INTEGER SAMPLE { sampleLength /= sizeof (int32_t); if (!allocateSmpData(s, sampleLength * sizeof (int32_t), false)) { loaderMsgBox("Not enough memory!"); return false; } if (fread(s->dataPtr, sampleLength, sizeof (int32_t), f) != sizeof (int32_t)) { loaderMsgBox("General I/O error during loading! Is the file in use?"); return false; } // change endianness audioDataS32 = (int32_t *)s->dataPtr; for (i = 0; i < sampleLength; i++) audioDataS32[i] = SWAP32(audioDataS32[i]); // stereo conversion if (numChannels == 2) { sampleLength /= 2; switch (stereoSampleLoadMode) { case STEREO_SAMPLE_READ_LEFT: { for (i = 1; i < sampleLength; i++) audioDataS32[i] = audioDataS32[(i * 2) + 0]; } break; case STEREO_SAMPLE_READ_RIGHT: { len32 = sampleLength - 1; for (i = 0; i < len32; i++) audioDataS32[i] = audioDataS32[(i * 2) + 1]; audioDataS32[i] = 0; } break; default: case STEREO_SAMPLE_CONVERT: { len32 = sampleLength - 1; for (i = 0; i < len32; i++) { int64_t smp64 = audioDataS32[(i * 2) + 0]; smp64 += audioDataS32[(i * 2) + 1]; smp64 >>= 1; audioDataS32[i] = (int32_t)smp64; } audioDataS32[i] = 0; } break; } } normalizeSigned32Bit(audioDataS32, sampleLength); audioDataS16 = (int16_t *)s->dataPtr; for (i = 0; i < sampleLength; i++) audioDataS16[i] = audioDataS32[i] >> 16; s->flags |= SAMPLE_16BIT; } else if (floatSample && bitDepth == 32) // 32-BIT FLOAT SAMPLE { sampleLength /= sizeof (float); if (!allocateSmpData(s, sampleLength * sizeof (float), false)) { loaderMsgBox("Not enough memory!"); return false; } if (fread(s->dataPtr, sampleLength, sizeof (float), f) != sizeof (float)) { loaderMsgBox("General I/O error during loading! Is the file in use?"); return false; } // change endianness audioDataS32 = (int32_t *)s->dataPtr; for (i = 0; i < sampleLength; i++) audioDataS32[i] = SWAP32(audioDataS32[i]); float *fAudioDataFloat = (float *)s->dataPtr; // stereo conversion if (numChannels == 2) { sampleLength /= 2; switch (stereoSampleLoadMode) { case STEREO_SAMPLE_READ_LEFT: { // remove right channel data for (i = 1; i < sampleLength; i++) fAudioDataFloat[i] = fAudioDataFloat[(i * 2) + 0]; } break; case STEREO_SAMPLE_READ_RIGHT: { // remove left channel data len32 = sampleLength - 1; for (i = 0; i < len32; i++) fAudioDataFloat[i] = fAudioDataFloat[(i * 2) + 1]; fAudioDataFloat[i] = 0.0f; } break; default: case STEREO_SAMPLE_CONVERT: { // mix stereo to mono len32 = sampleLength - 1; for (i = 0; i < len32; i++) fAudioDataFloat[i] = (fAudioDataFloat[(i * 2) + 0] + fAudioDataFloat[(i * 2) + 1]) * 0.5f; fAudioDataFloat[i] = 0.0f; } break; } } normalize32BitFloatToSigned16Bit(fAudioDataFloat, sampleLength); int16_t *ptr16 = (int16_t *)s->dataPtr; for (i = 0; i < sampleLength; i++) { const int32_t smp32 = (const int32_t)fAudioDataFloat[i]; ptr16[i] = (int16_t)smp32; } s->flags |= SAMPLE_16BIT; } else if (floatSample && bitDepth == 64) // 64-BIT FLOAT SAMPLE { sampleLength /= sizeof (double); if (!allocateSmpData(s, sampleLength * sizeof (double), false)) { loaderMsgBox("Not enough memory!"); return false; } if (fread(s->dataPtr, sampleLength, sizeof (double), f) != sizeof (double)) { loaderMsgBox("General I/O error during loading! Is the file in use?"); return false; } // change endianness int64_t *audioDataS64 = (int64_t *)s->dataPtr; for (i = 0; i < sampleLength; i++) audioDataS64[i] = SWAP64(audioDataS64[i]); double *dAudioDataDouble = (double *)s->dataPtr; // stereo conversion if (numChannels == 2) { sampleLength /= 2; switch (stereoSampleLoadMode) { case STEREO_SAMPLE_READ_LEFT: { // remove right channel data for (i = 1; i < sampleLength; i++) dAudioDataDouble[i] = dAudioDataDouble[(i * 2) + 0]; } break; case STEREO_SAMPLE_READ_RIGHT: { // remove left channel data len32 = sampleLength - 1; for (i = 0; i < len32; i++) dAudioDataDouble[i] = dAudioDataDouble[(i * 2) + 1]; dAudioDataDouble[i] = 0.0; } break; default: case STEREO_SAMPLE_CONVERT: { // mix stereo to mono len32 = sampleLength - 1; for (i = 0; i < len32; i++) dAudioDataDouble[i] = (dAudioDataDouble[(i * 2) + 0] + dAudioDataDouble[(i * 2) + 1]) * 0.5; dAudioDataDouble[i] = 0.0; } break; } } normalize64BitFloatToSigned16Bit(dAudioDataDouble, sampleLength); int16_t *ptr16 = (int16_t *)s->dataPtr; for (i = 0; i < sampleLength; i++) { const int32_t smp32 = (const int32_t)dAudioDataDouble[i]; ptr16[i] = (int16_t)smp32; } s->flags |= SAMPLE_16BIT; } if (sampleLength > MAX_SAMPLE_LEN) sampleLength = MAX_SAMPLE_LEN; bool sample16Bit = !!(s->flags & SAMPLE_16BIT); reallocateSmpData(s, sampleLength, sample16Bit); // readjust memory needed s->length = sampleLength; s->volume = 64; s->panning = 128; tuneSample(s, sampleRate, audio.linearPeriodsFlag); return true; } static uint32_t getAIFFSampleRate(uint8_t *in) { /* 80-bit IEEE-754 to unsigned 32-bit integer (rounded). ** Sign bit is ignored. */ #define EXP_BIAS 16383 const uint16_t exp15 = ((in[0] & 0x7F) << 8) | in[1]; const uint64_t mantissaBits = *(uint64_t *)&in[2]; const uint64_t mantissa63 = SWAP64(mantissaBits) & INT64_MAX; double dExp = exp15 - EXP_BIAS; double dMantissa = mantissa63 / (INT64_MAX+1.0); double dResult = (1.0 + dMantissa) * exp2(dExp); return (uint32_t)round(dResult); } static bool aiffIsStereo(FILE *f) // only ran on files that are confirmed to be AIFFs { uint16_t numChannels; uint32_t chunkID, chunkSize; uint32_t oldPos = ftell(f); fseek(f, 0, SEEK_END); int32_t filesize = ftell(f); if (filesize < 12) { fseek(f, oldPos, SEEK_SET); return false; } fseek(f, 12, SEEK_SET); uint32_t commPtr = 0; uint32_t commLen = 0; int32_t bytesRead = 0; while (!feof(f) && bytesRead < filesize-12) { fread(&chunkID, 4, 1, f); chunkID = SWAP32(chunkID); if (feof(f)) break; fread(&chunkSize, 4, 1, f); chunkSize = SWAP32(chunkSize); if (feof(f)) break; int32_t endOfChunk = (ftell(f) + chunkSize) + (chunkSize & 1); switch (chunkID) { case 0x434F4D4D: // "COMM" { commPtr = ftell(f); commLen = chunkSize; } break; default: break; } bytesRead += (chunkSize + (chunkSize & 1)); fseek(f, endOfChunk, SEEK_SET); } if (commPtr == 0 || commLen < 2) { fseek(f, oldPos, SEEK_SET); return false; } fseek(f, commPtr, SEEK_SET); fread(&numChannels, 2, 1, f); numChannels = SWAP16(numChannels); fseek(f, oldPos, SEEK_SET); return (numChannels == 2); }