/* * Copyright (C) 2014 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 "private/private.h" /* * Clamps a 24-bit value from a 32-bit sample */ static inline int32_t clamp24(int32_t sample) { if ((sample>>23) ^ (sample>>31)) { sample = 0x007FFFFF ^ (sample>>31); } return sample; } /* * Converts a uint8x3_t into an int32_t */ static inline int32_t uint8x3_to_int32(uint8x3_t val) { #if HAVE_BIG_ENDIAN int32_t temp = (val.c[0] << 24 | val.c[1] << 16 | val.c[2] << 8) >> 8; #else int32_t temp = (val.c[2] << 24 | val.c[1] << 16 | val.c[0] << 8) >> 8; #endif return clamp24(temp); } /* * Converts an int32_t to a uint8x3_t */ static inline uint8x3_t int32_to_uint8x3(int32_t in) { uint8x3_t out; #if HAVE_BIG_ENDIAN out.c[2] = in; out.c[1] = in >> 8; out.c[0] = in >> 16; #else out.c[0] = in; out.c[1] = in >> 8; out.c[2] = in >> 16; #endif return out; } /* This is written as a C macro because it operates on generic types, * which in a C++ file could be alternatively achieved by a "template" * or an "auto" declaration. * TODO: convert this from a C file to a C++ file. */ /* Channel expands (adds zeroes to audio frame end) from an input buffer to an output buffer. * See expand_channels() function below for parameter definitions. * * Move from back to front so that the conversion can be done in-place * i.e. in_buff == out_buff * NOTE: num_in_bytes must be a multiple of in_buff_channels * in_buff_sample_size. * * Macro has a return statement. */ #define EXPAND_CHANNELS(in_buff, in_buff_chans, out_buff, out_buff_chans, num_in_bytes, zero) \ { \ size_t num_in_samples = (num_in_bytes) / sizeof(*(in_buff)); \ size_t num_out_samples = (num_in_samples * (out_buff_chans)) / (in_buff_chans); \ typeof(out_buff) dst_ptr = (out_buff) + num_out_samples - 1; \ size_t src_index; \ typeof(in_buff) src_ptr = (in_buff) + num_in_samples - 1; \ size_t num_zero_chans = (out_buff_chans) - (in_buff_chans); \ for (src_index = 0; src_index < num_in_samples; src_index += (in_buff_chans)) { \ size_t dst_offset; \ for (dst_offset = 0; dst_offset < num_zero_chans; dst_offset++) { \ *dst_ptr-- = zero; \ } \ for (; dst_offset < (out_buff_chans); dst_offset++) { \ *dst_ptr-- = *src_ptr--; \ } \ } \ /* return number of *bytes* generated */ \ return num_out_samples * sizeof(*(out_buff)); \ } /* Channel expands from an input buffer to an output buffer. * See expand_selected_channels() function below for parameter definitions. * Selected channels are replaced in the output buffer, with any extra channels * per frame left alone. * * Move from back to front so that the conversion can be done in-place * i.e. in_buff == out_buff * NOTE: num_in_bytes must be a multiple of in_buff_channels * in_buff_sample_size. * * Macro has a return statement. */ #define EXPAND_SELECTED_CHANNELS( \ in_buff, in_buff_chans, out_buff, out_buff_chans, num_in_bytes) \ { \ size_t num_in_samples = (num_in_bytes) / sizeof(*(in_buff)); \ size_t num_out_samples = (num_in_samples * (out_buff_chans)) / (in_buff_chans); \ typeof(out_buff) dst_ptr = (out_buff) + num_out_samples - 1; \ size_t src_index; \ typeof(in_buff) src_ptr = (in_buff) + num_in_samples - 1; \ size_t num_extra_chans = (out_buff_chans) - (in_buff_chans); \ for (src_index = 0; src_index < num_in_samples; src_index += (in_buff_chans)) { \ dst_ptr -= num_extra_chans; \ for (size_t dst_offset = num_extra_chans; dst_offset < (out_buff_chans); dst_offset++) { \ *dst_ptr-- = *src_ptr--; \ } \ } \ /* return number of *bytes* generated */ \ return num_out_samples * sizeof(*(out_buff)); \ } /* Expand number of channels from an input buffer to an output buffer. * See expand_channels_non_destructive() function below for parameter definitions. * * Input channels are copied to the output buffer, with extra output * channels interleaved from back of input buffer. * * So for in_chans = 2, out_chans = 4: [1|2|1|2...|3|4|3|4] => [1|2|3|4|1|2|3|4...] * * NOTE: in_buff must be same size as out_buff and num_in_bytes must * be a multiple of in_buff_channels * in_buff_sample_size. * * Uses a temporary buffer so that the conversion can be done in-place * i.e. in_buff == out_buff * * Macro has a return statement. */ #define EXPAND_CHANNELS_NON_DESTRUCTIVE(in_buff, in_buff_chans, \ out_buff, out_buff_chans, num_in_bytes) \ { \ size_t num_in_samples = (num_in_bytes) / sizeof(*(in_buff)); \ size_t num_out_samples = (num_in_samples * (out_buff_chans)) / (in_buff_chans); \ typeof(out_buff) dst_ptr = (out_buff); \ typeof(in_buff) src_ptr = (in_buff); \ typeof(*out_buff) temp_buff[num_in_samples]; \ typeof(out_buff) temp_ptr = temp_buff; \ /* if in-place, copy input channels to a temp buffer */ \ if ((in_buff) == (out_buff)) { \ memcpy(temp_buff, src_ptr, (num_in_bytes)); \ src_ptr += num_in_samples; \ } else { \ temp_ptr = (typeof(out_buff)) src_ptr; \ src_ptr += num_in_samples; \ } \ /* interleave channels from end of source buffer with those from front */ \ size_t src_index; \ for (src_index = 0; src_index < num_out_samples; src_index += (out_buff_chans)) { \ size_t dst_offset; \ for (dst_offset = 0; dst_offset < (in_buff_chans); dst_offset++) { \ *dst_ptr++ = *temp_ptr++; \ } \ for (;dst_offset < (out_buff_chans); dst_offset++) { \ *dst_ptr++ = *src_ptr++; \ } \ } \ /* return number of *bytes* generated */ \ return num_out_samples * sizeof(*(out_buff)); \ } /* Channel expands from a MONO input buffer to a MULTICHANNEL output buffer by duplicating the * single input channel to the first 2 output channels and 0-filling the remaining. * See expand_channels() function below for parameter definitions. * * in_buff_chans MUST be 1 and out_buff_chans MUST be >= 2 * * Move from back to front so that the conversion can be done in-place * i.e. in_buff == out_buff * NOTE: num_in_bytes must be a multiple of in_buff_channels * in_buff_sample_size. * * Macro has a return statement. */ #define EXPAND_MONO_TO_MULTI(in_buff, in_buff_chans, out_buff, out_buff_chans, num_in_bytes, zero) \ { \ size_t num_in_samples = (num_in_bytes) / sizeof(*(in_buff)); \ size_t num_out_samples = (num_in_samples * (out_buff_chans)) / (in_buff_chans); \ typeof(out_buff) dst_ptr = (out_buff) + num_out_samples - 1; \ size_t src_index; \ typeof(in_buff) src_ptr = (in_buff) + num_in_samples - 1; \ size_t num_zero_chans = (out_buff_chans) - (in_buff_chans) - 1; \ for (src_index = 0; src_index < num_in_samples; src_index += (in_buff_chans)) { \ size_t dst_offset; \ for (dst_offset = 0; dst_offset < num_zero_chans; dst_offset++) { \ *dst_ptr-- = zero; \ } \ for (; dst_offset < (out_buff_chans); dst_offset++) { \ *dst_ptr-- = *src_ptr; \ } \ src_ptr--; \ } \ /* return number of *bytes* generated */ \ return num_out_samples * sizeof(*(out_buff)); \ } /* Channel contracts (removes from audio frame end) from an input buffer to an output buffer. * See contract_channels() function below for parameter definitions. * * Move from front to back so that the conversion can be done in-place * i.e. in_buff == out_buff * NOTE: num_in_bytes must be a multiple of in_buff_channels * in_buff_sample_size. * * Macro has a return statement. */ #define CONTRACT_CHANNELS(in_buff, in_buff_chans, out_buff, out_buff_chans, num_in_bytes) \ { \ size_t num_in_samples = (num_in_bytes) / sizeof(*(in_buff)); \ size_t num_out_samples = (num_in_samples * (out_buff_chans)) / (in_buff_chans); \ size_t num_skip_samples = (in_buff_chans) - (out_buff_chans); \ typeof(out_buff) dst_ptr = out_buff; \ typeof(in_buff) src_ptr = in_buff; \ size_t src_index; \ for (src_index = 0; src_index < num_in_samples; src_index += (in_buff_chans)) { \ size_t dst_offset; \ for (dst_offset = 0; dst_offset < (out_buff_chans); dst_offset++) { \ *dst_ptr++ = *src_ptr++; \ } \ src_ptr += num_skip_samples; \ } \ /* return number of *bytes* generated */ \ return num_out_samples * sizeof(*(out_buff)); \ } /* Contract number of channels from an input buffer to an output buffer, * storing removed channels at end of buffer. * * See contract_channels_non_destructive() function below for parameter definitions. * * So for in_chans = 4, out_chans = 2: [1|2|3|4|1|2|3|4...] => [1|2|1|2...|3|4|3|4] * * NOTE: in_buff must be same size as out_buff and num_in_bytes must * be a multiple of in_buff_channels * in_buff_sample_size. * * Uses a temporary buffer so that the conversion can be done in-place * i.e. in_buff == out_buff * * Macro has a return statement. */ #define CONTRACT_CHANNELS_NON_DESTRUCTIVE(in_buff, in_buff_chans, out_buff, \ out_buff_chans, num_in_bytes) \ { \ size_t num_in_samples = (num_in_bytes) / sizeof(*(in_buff)); \ size_t num_out_samples = (num_in_samples * (out_buff_chans)) / (in_buff_chans); \ typeof(out_buff) dst_ptr = (out_buff); \ typeof(in_buff) src_ptr = (in_buff); \ size_t num_temp_samples = num_in_samples - num_out_samples; \ typeof(*out_buff) temp_buff[num_temp_samples]; \ typeof(out_buff) temp_ptr; \ /* if in-place, copy input channels to a temp buffer instead of out buffer */ \ if ((in_buff) == (out_buff)) { \ temp_ptr = temp_buff; \ } else { \ temp_ptr = dst_ptr + num_out_samples; \ } \ size_t src_index; \ for (src_index = 0; src_index < num_in_samples; src_index += (in_buff_chans)) { \ size_t dst_offset; \ for (dst_offset = 0; dst_offset < (out_buff_chans); dst_offset++) { \ *dst_ptr++ = *src_ptr++; \ } \ for (;dst_offset < (in_buff_chans); dst_offset++) { \ *temp_ptr++ = *src_ptr++; \ } \ } \ /* if in-place, interleave channels from the temp buffer */ \ if ((in_buff) == (out_buff)) { \ temp_ptr = temp_buff; \ memcpy(dst_ptr, temp_ptr, num_temp_samples * sizeof(*(in_buff))); \ } \ /* return number of *bytes* generated */ \ return num_out_samples * sizeof(*(out_buff)); \ } /* Channel contracts from a MULTICHANNEL input buffer to a MONO output buffer by mixing the * first two input channels into the single output channel (and skipping the rest). * See contract_channels() function below for parameter definitions. * * in_buff_chans MUST be >= 2 and out_buff_chans MUST be 1 * * Move from front to back so that the conversion can be done in-place * i.e. in_buff == out_buff * NOTE: num_in_bytes must be a multiple of in_buff_channels * in_buff_sample_size. * NOTE: Overload of the summed channels is avoided by averaging the two input channels. * NOTE: Can not be used for uint8x3_t samples, see CONTRACT_TO_MONO_24() below. * * Macro has a return statement. */ #define CONTRACT_TO_MONO(in_buff, out_buff, num_in_bytes) \ { \ size_t num_in_samples = (num_in_bytes) / sizeof(*(in_buff)); \ size_t num_out_samples = (num_in_samples * out_buff_chans) / in_buff_chans; \ size_t num_skip_samples = in_buff_chans - 2; \ typeof(out_buff) dst_ptr = out_buff; \ typeof(in_buff) src_ptr = in_buff; \ int32_t temp0, temp1; \ size_t src_index; \ for (src_index = 0; src_index < num_in_samples; src_index += in_buff_chans) { \ temp0 = *src_ptr++; \ temp1 = *src_ptr++; \ /* *dst_ptr++ = temp >> 1; */ \ /* This bit of magic adds and normalizes without overflow (or so claims hunga@) */ \ /* Bitwise half adder trick, see http://en.wikipedia.org/wiki/Adder_(electronics) */ \ /* Hacker's delight, p. 19 http://www.hackersdelight.org/basics2.pdf */ \ *dst_ptr++ = (temp0 & temp1) + ((temp0 ^ temp1) >> 1); \ src_ptr += num_skip_samples; \ } \ /* return number of *bytes* generated */ \ return num_out_samples * sizeof(*(out_buff)); \ } /* Channel contracts from a MULTICHANNEL uint8x3_t input buffer to a MONO uint8x3_t output buffer * by mixing the first two input channels into the single output channel (and skipping the rest). * See contract_channels() function below for parameter definitions. * * Move from front to back so that the conversion can be done in-place * i.e. in_buff == out_buff * NOTE: num_in_bytes must be a multiple of in_buff_channels * in_buff_sample_size. * NOTE: Overload of the summed channels is avoided by averaging the two input channels. * NOTE: Can not be used for normal, scalar samples, see CONTRACT_TO_MONO() above. * * Macro has a return statement. */ #define CONTRACT_TO_MONO_24(in_buff, out_buff, num_in_bytes) \ { \ size_t num_in_samples = (num_in_bytes) / sizeof(*(in_buff)); \ size_t num_out_samples = (num_in_samples * out_buff_chans) / in_buff_chans; \ size_t num_skip_samples = in_buff_chans - 2; \ typeof(out_buff) dst_ptr = out_buff; \ typeof(in_buff) src_ptr = in_buff; \ int32_t temp; \ size_t src_index; \ for (src_index = 0; src_index < num_in_samples; src_index += in_buff_chans) { \ temp = uint8x3_to_int32(*src_ptr++); \ temp += uint8x3_to_int32(*src_ptr++); \ *dst_ptr = int32_to_uint8x3(temp >> 1); \ src_ptr += num_skip_samples; \ } \ /* return number of *bytes* generated */ \ return num_out_samples * sizeof(*(out_buff)); \ } /* * Convert a buffer of N-channel, interleaved samples to M-channel * (where N > M). * in_buff points to the buffer of samples * in_buff_channels Specifies the number of channels in the input buffer. * out_buff points to the buffer to receive converted samples. * out_buff_channels Specifies the number of channels in the output buffer. * sample_size_in_bytes Specifies the number of bytes per sample. * num_in_bytes size of input buffer in BYTES * returns * the number of BYTES of output data. * NOTE * channels > M are thrown away. * The out and sums buffers must either be completely separate (non-overlapping), or * they must both start at the same address. Partially overlapping buffers are not supported. */ static size_t contract_channels(const void* in_buff, size_t in_buff_chans, void* out_buff, size_t out_buff_chans, unsigned sample_size_in_bytes, size_t num_in_bytes) { switch (sample_size_in_bytes) { case 1: if (out_buff_chans == 1) { /* Special case Multi to Mono */ CONTRACT_TO_MONO((const uint8_t*)in_buff, (uint8_t*)out_buff, num_in_bytes); // returns in macro } else { CONTRACT_CHANNELS((const uint8_t*)in_buff, in_buff_chans, (uint8_t*)out_buff, out_buff_chans, num_in_bytes); // returns in macro } case 2: if (out_buff_chans == 1) { /* Special case Multi to Mono */ CONTRACT_TO_MONO((const int16_t*)in_buff, (int16_t*)out_buff, num_in_bytes); // returns in macro } else { CONTRACT_CHANNELS((const int16_t*)in_buff, in_buff_chans, (int16_t*)out_buff, out_buff_chans, num_in_bytes); // returns in macro } case 3: if (out_buff_chans == 1) { /* Special case Multi to Mono */ CONTRACT_TO_MONO_24((const uint8x3_t*)in_buff, (uint8x3_t*)out_buff, num_in_bytes); // returns in macro } else { CONTRACT_CHANNELS((const uint8x3_t*)in_buff, in_buff_chans, (uint8x3_t*)out_buff, out_buff_chans, num_in_bytes); // returns in macro } case 4: if (out_buff_chans == 1) { /* Special case Multi to Mono */ CONTRACT_TO_MONO((const int32_t*)in_buff, (int32_t*)out_buff, num_in_bytes); // returns in macro } else { CONTRACT_CHANNELS((const int32_t*)in_buff, in_buff_chans, (int32_t*)out_buff, out_buff_chans, num_in_bytes); // returns in macro } default: return 0; } } /* * Convert a buffer of N-channel, interleaved samples to M-channel * (where N > M). * in_buff points to the buffer of samples * in_buff_channels specifies the number of channels in the input buffer. * out_buff points to the buffer to receive converted samples. * out_buff_channels specifies the number of channels in the output buffer. * sample_size_in_bytes specifies the number of bytes per sample. * num_in_bytes size of input buffer in BYTES * returns * the number of BYTES of output data. * NOTE * channels > M are stored at the end of the output buffer. * The output and input buffers must be the same length. * The output and input buffers must either be completely separate (non-overlapping), or * they must both start at the same address. Partially overlapping buffers are not supported. */ static size_t contract_channels_non_destructive(const void* in_buff, size_t in_buff_chans, void* out_buff, size_t out_buff_chans, unsigned sample_size_in_bytes, size_t num_in_bytes) { switch (sample_size_in_bytes) { case 1: CONTRACT_CHANNELS_NON_DESTRUCTIVE((const uint8_t*)in_buff, in_buff_chans, (uint8_t*)out_buff, out_buff_chans, num_in_bytes); // returns in macro case 2: CONTRACT_CHANNELS_NON_DESTRUCTIVE((const int16_t*)in_buff, in_buff_chans, (int16_t*)out_buff, out_buff_chans, num_in_bytes); // returns in macro case 3: CONTRACT_CHANNELS_NON_DESTRUCTIVE((const uint8x3_t*)in_buff, in_buff_chans, (uint8x3_t*)out_buff, out_buff_chans, num_in_bytes); // returns in macro case 4: CONTRACT_CHANNELS_NON_DESTRUCTIVE((const int32_t*)in_buff, in_buff_chans, (int32_t*)out_buff, out_buff_chans, num_in_bytes); // returns in macro default: return 0; } } /* * Convert a buffer of N-channel, interleaved samples to M-channel * (where N < M). * in_buff points to the buffer of samples * in_buff_channels Specifies the number of channels in the input buffer. * out_buff points to the buffer to receive converted samples. * out_buff_channels Specifies the number of channels in the output buffer. * sample_size_in_bytes Specifies the number of bytes per sample. * num_in_bytes size of input buffer in BYTES * returns * the number of BYTES of output data. * NOTE * channels > N are filled with silence. * The out and sums buffers must either be completely separate (non-overlapping), or * they must both start at the same address. Partially overlapping buffers are not supported. */ static size_t expand_channels(const void* in_buff, size_t in_buff_chans, void* out_buff, size_t out_buff_chans, unsigned sample_size_in_bytes, size_t num_in_bytes) { static const uint8x3_t packed24_zero; /* zero 24 bit sample */ switch (sample_size_in_bytes) { case 1: if (in_buff_chans == 1) { /* special case of mono source to multi-channel */ EXPAND_MONO_TO_MULTI((const uint8_t*)in_buff, in_buff_chans, (uint8_t*)out_buff, out_buff_chans, num_in_bytes, 0); // returns in macro } else { EXPAND_CHANNELS((const uint8_t*)in_buff, in_buff_chans, (uint8_t*)out_buff, out_buff_chans, num_in_bytes, 0); // returns in macro } case 2: if (in_buff_chans == 1) { /* special case of mono source to multi-channel */ EXPAND_MONO_TO_MULTI((const int16_t*)in_buff, in_buff_chans, (int16_t*)out_buff, out_buff_chans, num_in_bytes, 0); // returns in macro } else { EXPAND_CHANNELS((const int16_t*)in_buff, in_buff_chans, (int16_t*)out_buff, out_buff_chans, num_in_bytes, 0); // returns in macro } case 3: if (in_buff_chans == 1) { /* special case of mono source to multi-channel */ EXPAND_MONO_TO_MULTI((const uint8x3_t*)in_buff, in_buff_chans, (uint8x3_t*)out_buff, out_buff_chans, num_in_bytes, packed24_zero); // returns in macro } else { EXPAND_CHANNELS((const uint8x3_t*)in_buff, in_buff_chans, (uint8x3_t*)out_buff, out_buff_chans, num_in_bytes, packed24_zero); // returns in macro } case 4: if (in_buff_chans == 1) { /* special case of mono source to multi-channel */ EXPAND_MONO_TO_MULTI((const int32_t*)in_buff, in_buff_chans, (int32_t*)out_buff, out_buff_chans, num_in_bytes, 0); // returns in macro } else { EXPAND_CHANNELS((const int32_t*)in_buff, in_buff_chans, (int32_t*)out_buff, out_buff_chans, num_in_bytes, 0); // returns in macro } default: return 0; } } /* * Convert a buffer of N-channel, interleaved samples to M-channel * (where N < M). * in_buff points to the buffer of samples * in_buff_channels Specifies the number of channels in the input buffer. * out_buff points to the buffer to receive converted samples. * out_buff_channels Specifies the number of channels in the output buffer. * sample_size_in_bytes Specifies the number of bytes per sample. * num_in_bytes size of input buffer in BYTES * returns * the number of BYTES of output data. * NOTE * channels > N are left alone in out_buff. * The out and in buffers must either be completely separate (non-overlapping), or * they must both start at the same address. Partially overlapping buffers are not supported. */ static size_t expand_selected_channels(const void* in_buff, size_t in_buff_chans, void* out_buff, size_t out_buff_chans, unsigned sample_size_in_bytes, size_t num_in_bytes) { switch (sample_size_in_bytes) { case 1: EXPAND_SELECTED_CHANNELS((const uint8_t*)in_buff, in_buff_chans, (uint8_t*)out_buff, out_buff_chans, num_in_bytes); // returns in macro case 2: EXPAND_SELECTED_CHANNELS((const int16_t*)in_buff, in_buff_chans, (int16_t*)out_buff, out_buff_chans, num_in_bytes); // returns in macro case 3: EXPAND_SELECTED_CHANNELS((const uint8x3_t*)in_buff, in_buff_chans, (uint8x3_t*)out_buff, out_buff_chans, num_in_bytes); // returns in macro case 4: EXPAND_SELECTED_CHANNELS((const int32_t*)in_buff, in_buff_chans, (int32_t*)out_buff, out_buff_chans, num_in_bytes); // returns in macro default: return 0; } } /* * Convert a buffer of N-channel, interleaved samples to M-channel * (where N < M). * in_buff points to the buffer of samples * in_buff_channels Specifies the number of channels in the input buffer. * out_buff points to the buffer to receive converted samples. * out_buff_channels Specifies the number of channels in the output buffer. * sample_size_in_bytes Specifies the number of bytes per sample. * num_in_bytes size of input buffer in BYTES * returns * the number of BYTES of output data. * NOTE * channels > N are interleaved with data from the end of the input buffer. * The output and input buffers must be the same length. * The output and input buffers must either be completely separate (non-overlapping), or * they must both start at the same address. Partially overlapping buffers are not supported. */ static size_t expand_channels_non_destructive(const void* in_buff, size_t in_buff_chans, void* out_buff, size_t out_buff_chans, unsigned sample_size_in_bytes, size_t num_in_bytes) { switch (sample_size_in_bytes) { case 1: EXPAND_CHANNELS_NON_DESTRUCTIVE((const uint8_t*)in_buff, in_buff_chans, (uint8_t*)out_buff, out_buff_chans, num_in_bytes); // returns in macro case 2: EXPAND_CHANNELS_NON_DESTRUCTIVE((const int16_t*)in_buff, in_buff_chans, (int16_t*)out_buff, out_buff_chans, num_in_bytes); // returns in macro case 3: EXPAND_CHANNELS_NON_DESTRUCTIVE((const uint8x3_t*)in_buff, in_buff_chans, (uint8x3_t*)out_buff, out_buff_chans, num_in_bytes); // returns in macro case 4: EXPAND_CHANNELS_NON_DESTRUCTIVE((const int32_t*)in_buff, in_buff_chans, (int32_t*)out_buff, out_buff_chans, num_in_bytes); // returns in macro default: return 0; } } size_t adjust_channels(const void* in_buff, size_t in_buff_chans, void* out_buff, size_t out_buff_chans, unsigned sample_size_in_bytes, size_t num_in_bytes) { if (out_buff_chans > in_buff_chans) { return expand_channels(in_buff, in_buff_chans, out_buff, out_buff_chans, sample_size_in_bytes, num_in_bytes); } else if (out_buff_chans < in_buff_chans) { return contract_channels(in_buff, in_buff_chans, out_buff, out_buff_chans, sample_size_in_bytes, num_in_bytes); } else if (in_buff != out_buff) { memcpy(out_buff, in_buff, num_in_bytes); } return num_in_bytes; } size_t adjust_selected_channels(const void* in_buff, size_t in_buff_chans, void* out_buff, size_t out_buff_chans, unsigned sample_size_in_bytes, size_t num_in_bytes) { if (out_buff_chans > in_buff_chans) { return expand_selected_channels(in_buff, in_buff_chans, out_buff, out_buff_chans, sample_size_in_bytes, num_in_bytes); } else if (out_buff_chans < in_buff_chans) { return contract_channels(in_buff, in_buff_chans, out_buff, out_buff_chans, sample_size_in_bytes, num_in_bytes); } else if (in_buff != out_buff) { memcpy(out_buff, in_buff, num_in_bytes); } return num_in_bytes; } size_t adjust_channels_non_destructive(const void* in_buff, size_t in_buff_chans, void* out_buff, size_t out_buff_chans, unsigned sample_size_in_bytes, size_t num_in_bytes) { if (out_buff_chans > in_buff_chans) { return expand_channels_non_destructive(in_buff, in_buff_chans, out_buff, out_buff_chans, sample_size_in_bytes, num_in_bytes); } else if (out_buff_chans < in_buff_chans) { return contract_channels_non_destructive(in_buff, in_buff_chans, out_buff, out_buff_chans, sample_size_in_bytes, num_in_bytes); } else if (in_buff != out_buff) { memcpy(out_buff, in_buff, num_in_bytes); } return num_in_bytes; }