ref: 668549e1df4f77e7850e0081908c2e50f6f70c06
dir: /src/lpc10.c/
/* * libSoX lpc-10 format. * * Copyright 2007 Reuben Thomas <rrt@sc3d.org> * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library. If not, write to the Free Software * Foundation, Fifth Floor, 51 Franklin Street, Boston, MA 02111-1301, * USA. */ #include "sox_i.h" #include "../lpc10/lpc10.h" /* Private data */ typedef struct lpcpriv { struct lpc10_encoder_state *encst; float speech[LPC10_SAMPLES_PER_FRAME]; unsigned samples; struct lpc10_decoder_state *decst; } *lpcpriv_t; /* Write the bits in bits[0] through bits[len-1] to file f, in "packed" format. bits is expected to be an array of len integer values, where each integer is 0 to represent a 0 bit, and any other value represents a 1 bit. This bit string is written to the file f in the form of several 8 bit characters. If len is not a multiple of 8, then the last character is padded with 0 bits -- the padding is in the least significant bits of the last byte. The 8 bit characters are "filled" in order from most significant bit to least significant. */ static void write_bits(ft_t ft, INT32 *bits, int len) { int i; uint8_t mask; /* The next bit position within the variable "data" to place the next bit. */ uint8_t data; /* The contents of the next byte to place in the output. */ /* Fill in the array bits. * The first compressed output bit will be the most significant * bit of the byte, so initialize mask to 0x80. The next byte of * compressed data is initially 0, and the desired bits will be * turned on below. */ mask = 0x80; data = 0; for (i = 0; i < len; i++) { /* Turn on the next bit of output data, if necessary. */ if (bits[i]) { data |= mask; } /* * If the byte data is full, determined by mask becoming 0, * then write the byte to the output file, and reinitialize * data and mask for the next output byte. Also add the byte * if (i == len-1), because if len is not a multiple of 8, * then mask won't yet be 0. */ mask >>= 1; if ((mask == 0) || (i == len-1)) { sox_writeb(ft, data); data = 0; mask = 0x80; } } } /* Read bits from file f into bits[0] through bits[len-1], in "packed" format. Read ceiling(len/8) characters from file f, if that many are available to read, otherwise read to the end of the file. The first character's 8 bits, in order from MSB to LSB, are used to fill bits[0] through bits[7]. The second character's bits are used to fill bits[8] through bits[15], and so on. If ceiling(len/8) characters are available to read, and len is not a multiple of 8, then some of the least significant bits of the last character read are completely ignored. Every entry of bits[] that is modified is changed to either a 0 or a 1. The number of bits successfully read is returned, and is always in the range 0 to len, inclusive. If it is less than len, it will always be a multiple of 8. */ static int read_bits(ft_t ft, INT32 *bits, int len) { int i; uint8_t c; /* Unpack the array bits into coded_frame. */ for (i = 0; i < len; i++) { if (i % 8 == 0) { sox_readb(ft, &c); if (sox_eof(ft)) { return (i); } } if (c & (0x80 >> (i & 7))) { bits[i] = 1; } else { bits[i] = 0; } } return (len); } static int startread(ft_t ft) { lpcpriv_t lpc = (lpcpriv_t)ft->priv; if ((lpc->decst = create_lpc10_decoder_state()) == NULL) { fprintf(stderr, "lpc10 could not allocate decoder state"); return SOX_EOF; } lpc->samples = LPC10_SAMPLES_PER_FRAME; return SOX_SUCCESS; } static int startwrite(ft_t ft) { lpcpriv_t lpc = (lpcpriv_t)ft->priv; if ((lpc->encst = create_lpc10_encoder_state()) == NULL) { fprintf(stderr, "lpc10 could not allocate encoder state"); return SOX_EOF; } lpc->samples = 0; return SOX_SUCCESS; } static sox_size_t read(ft_t ft, sox_ssample_t *buf, sox_size_t len) { lpcpriv_t lpc = (lpcpriv_t)ft->priv; sox_size_t nread = 0; while (nread < len) { /* Read more data if buffer is empty */ if (lpc->samples == LPC10_SAMPLES_PER_FRAME) { INT32 bits[LPC10_BITS_IN_COMPRESSED_FRAME]; if (read_bits(ft, bits, LPC10_BITS_IN_COMPRESSED_FRAME) != LPC10_BITS_IN_COMPRESSED_FRAME) break; lpc10_decode(bits, lpc->speech, lpc->decst); lpc->samples = 0; } while (nread < len && lpc->samples < LPC10_SAMPLES_PER_FRAME) buf[nread++] = SOX_FLOAT_32BIT_TO_SAMPLE(lpc->speech[lpc->samples++], ft->clips); } return nread; } static sox_size_t write(ft_t ft, const sox_ssample_t *buf, sox_size_t len) { lpcpriv_t lpc = (lpcpriv_t)ft->priv; sox_size_t nwritten = 0; while (len + lpc->samples >= LPC10_SAMPLES_PER_FRAME) { INT32 bits[LPC10_BITS_IN_COMPRESSED_FRAME]; while (lpc->samples < LPC10_SAMPLES_PER_FRAME) { lpc->speech[lpc->samples++] = SOX_SAMPLE_TO_FLOAT_32BIT(buf[nwritten++], ft->clips); len--; } lpc10_encode(lpc->speech, bits, lpc->encst); write_bits(ft, bits, LPC10_BITS_IN_COMPRESSED_FRAME); lpc->samples = 0; } return nwritten; } static int stopread(ft_t ft) { lpcpriv_t lpc = (lpcpriv_t)ft->priv; free(lpc->decst); return SOX_SUCCESS; } static int stopwrite(ft_t ft) { lpcpriv_t lpc = (lpcpriv_t)ft->priv; free(lpc->encst); return SOX_SUCCESS; } /* LPC-10 */ static const char *lpc10names[] = { "lpc", "lpc10", NULL }; static sox_format_t sox_lpc10_format = { lpc10names, 0, startread, read, stopread, startwrite, write, stopwrite, sox_format_nothing_seek }; const sox_format_t *sox_lpc10_format_fn(void); const sox_format_t *sox_lpc10_format_fn(void) { return &sox_lpc10_format; }