ref: 99adb24d9994bbb63c5f26003632ed94d9e4eaab
dir: /src/cvsd.c/
/* libSoX CVSD (Continuously Variable Slope Delta modulation) * conversion routines * * The CVSD format is described in the MIL Std 188 113, which is * available from http://bbs.itsi.disa.mil:5580/T3564 * * Copyright (C) 1996 * Thomas Sailer (sailer@ife.ee.ethz.ch) (HB9JNX/AE4WA) * Swiss Federal Institute of Technology, Electronics Lab * * 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 2.1 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, * Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA * * Change History: * * June 1, 1998 - Chris Bagwell (cbagwell@sprynet.com) * Fixed compile warnings reported by Kjetil Torgrim Homme * <kjetilho@ifi.uio.no> * * June 20, 2006 - Kimberly Rockwell (pyxis13317 (at) yahoo.com) * Speed optimization: Unrolled float_conv() loop in seperate * functions for encoding and decoding. 15% speed up decoding. * * Aug. 24, 2009 - P. Chaintreuil (sox-cvsd-peep (at) parallaxshift.com) * Speed optimization: Replaced calls to memmove() with a * mirrored circular buffer. This doubles the size of the * dec.output_filter (48 -> 96 floats) and enc.input_filter * (16 -> 32 floats), but keeps the memory from having to * be copied so many times. 56% speed increase decoding; * less than 5% encoding speed increase. */ #include "sox_i.h" #include "cvsd.h" #include "cvsdfilt.h" #include <string.h> #include <time.h> /* ---------------------------------------------------------------------- */ /* * private data structures */ typedef cvsd_priv_t priv_t; static int debug_count = 0; /* ---------------------------------------------------------------------- */ /* This float_conv() function is not used as more specialized/optimized * versions exist below. However, those new versions are tied to * very percise filters defined in cvsdfilt.h. If those are modified * or different filters are found to be required, this function may * be needed. Thus I leave it here for possible future use, but commented * out to avoid compiler warnings about it not being used. static float float_conv(float const *fp1, float const *fp2,int n) { float res = 0; for(; n > 0; n--) res += (*fp1++) * (*fp2++); return res; } */ static float float_conv_enc(float const *fp1, float const *fp2) { /* This is a specialzed version of float_conv() for encoding * which simply assumes a CVSD_ENC_FILTERLEN (16) length of * the two arrays and unrolls that loop. * * fp1 should be the enc.input_filter array and must be * CVSD_ENC_FILTERLEN (16) long. * * fp2 should be one of the enc_filter_xx_y() tables listed * in cvsdfilt.h. At minimum, fp2 must be CVSD_ENC_FILTERLEN * (16) entries long. */ float res = 0; /* unrolling loop */ res += fp1[0] * fp2[0]; res += fp1[1] * fp2[1]; res += fp1[2] * fp2[2]; res += fp1[3] * fp2[3]; res += fp1[4] * fp2[4]; res += fp1[5] * fp2[5]; res += fp1[6] * fp2[6]; res += fp1[7] * fp2[7]; res += fp1[8] * fp2[8]; res += fp1[9] * fp2[9]; res += fp1[10] * fp2[10]; res += fp1[11] * fp2[11]; res += fp1[12] * fp2[12]; res += fp1[13] * fp2[13]; res += fp1[14] * fp2[14]; res += fp1[15] * fp2[15]; return res; } static float float_conv_dec(float const *fp1, float const *fp2) { /* This is a specialzed version of float_conv() for decoding * which assumes a specific length and structure to the data * in fp2. * * fp1 should be the dec.output_filter array and must be * CVSD_DEC_FILTERLEN (48) long. * * fp2 should be one of the dec_filter_xx() tables listed * in cvsdfilt.h. fp2 is assumed to be CVSD_DEC_FILTERLEN * (48) entries long, is assumed to have 0.0 in the last * entry, and is a symmetrical mirror around fp2[23] (ie, * fp2[22] == fp2[24], fp2[0] == fp2[47], etc). */ float res = 0; /* unrolling loop, also taking advantage of the symmetry * of the sampling rate array*/ res += (fp1[0] + fp1[46]) * fp2[0]; res += (fp1[1] + fp1[45]) * fp2[1]; res += (fp1[2] + fp1[44]) * fp2[2]; res += (fp1[3] + fp1[43]) * fp2[3]; res += (fp1[4] + fp1[42]) * fp2[4]; res += (fp1[5] + fp1[41]) * fp2[5]; res += (fp1[6] + fp1[40]) * fp2[6]; res += (fp1[7] + fp1[39]) * fp2[7]; res += (fp1[8] + fp1[38]) * fp2[8]; res += (fp1[9] + fp1[37]) * fp2[9]; res += (fp1[10] + fp1[36]) * fp2[10]; res += (fp1[11] + fp1[35]) * fp2[11]; res += (fp1[12] + fp1[34]) * fp2[12]; res += (fp1[13] + fp1[33]) * fp2[13]; res += (fp1[14] + fp1[32]) * fp2[14]; res += (fp1[15] + fp1[31]) * fp2[15]; res += (fp1[16] + fp1[30]) * fp2[16]; res += (fp1[17] + fp1[29]) * fp2[17]; res += (fp1[18] + fp1[28]) * fp2[18]; res += (fp1[19] + fp1[27]) * fp2[19]; res += (fp1[20] + fp1[26]) * fp2[20]; res += (fp1[21] + fp1[25]) * fp2[21]; res += (fp1[22] + fp1[24]) * fp2[22]; res += (fp1[23]) * fp2[23]; return res; } /* ---------------------------------------------------------------------- */ /* * some remarks about the implementation of the CVSD decoder * the principal integrator is integrated into the output filter * to achieve this, the coefficients of the output filter are multiplied * with (1/(1-1/z)) in the initialisation code. * the output filter must have a sharp zero at f=0 (i.e. the sum of the * filter parameters must be zero). This prevents an accumulation of * DC voltage at the principal integration. */ /* ---------------------------------------------------------------------- */ static void cvsdstartcommon(sox_format_t * ft) { priv_t *p = (priv_t *) ft->priv; p->cvsd_rate = (ft->signal.rate <= 24000) ? 16000 : 32000; ft->signal.rate = 8000; ft->signal.channels = 1; lsx_rawstart(ft, sox_true, sox_false, sox_true, SOX_ENCODING_CVSD, 1); /* * initialize the decoder */ p->com.overload = 0x5; p->com.mla_int = 0; /* * timeconst = (1/e)^(200 / SR) = exp(-200/SR) * SR is the sampling rate */ p->com.mla_tc0 = exp((-200.0)/((float)(p->cvsd_rate))); /* * phase_inc = 32000 / SR */ p->com.phase_inc = 32000 / p->cvsd_rate; /* * initialize bit shift register */ p->bit.shreg = p->bit.cnt = 0; p->bit.mask = 1; /* * count the bytes written */ p->bytes_written = 0; p->com.v_min = 1; p->com.v_max = -1; lsx_report("cvsd: bit rate %dbit/s, bits from %s", p->cvsd_rate, ft->encoding.reverse_bits ? "msb to lsb" : "lsb to msb"); } /* ---------------------------------------------------------------------- */ int lsx_cvsdstartread(sox_format_t * ft) { priv_t *p = (priv_t *) ft->priv; float *fp1; int i; cvsdstartcommon(ft); p->com.mla_tc1 = 0.1 * (1 - p->com.mla_tc0); p->com.phase = 0; /* * initialize the output filter coeffs (i.e. multiply * the coeffs with (1/(1-1/z)) to achieve integration * this is now done in the filter parameter generation utility */ /* * zero the filter */ for(fp1 = p->c.dec.output_filter, i = CVSD_DEC_FILTERLEN*2; i > 0; i--) *fp1++ = 0; /* initialize mirror circular buffer offset to anything sane. */ p->c.dec.offset = CVSD_DEC_FILTERLEN - 1; return (SOX_SUCCESS); } /* ---------------------------------------------------------------------- */ int lsx_cvsdstartwrite(sox_format_t * ft) { priv_t *p = (priv_t *) ft->priv; float *fp1; int i; cvsdstartcommon(ft); p->com.mla_tc1 = 0.1 * (1 - p->com.mla_tc0); p->com.phase = 4; /* * zero the filter */ for(fp1 = p->c.enc.input_filter, i = CVSD_ENC_FILTERLEN*2; i > 0; i--) *fp1++ = 0; p->c.enc.recon_int = 0; /* initialize mirror circular buffer offset to anything sane. */ p->c.enc.offset = CVSD_ENC_FILTERLEN - 1; return(SOX_SUCCESS); } /* ---------------------------------------------------------------------- */ int lsx_cvsdstopwrite(sox_format_t * ft) { priv_t *p = (priv_t *) ft->priv; if (p->bit.cnt) { lsx_writeb(ft, p->bit.shreg); p->bytes_written++; } lsx_debug("cvsd: min slope %f, max slope %f", p->com.v_min, p->com.v_max); return (SOX_SUCCESS); } /* ---------------------------------------------------------------------- */ int lsx_cvsdstopread(sox_format_t * ft) { priv_t *p = (priv_t *) ft->priv; lsx_debug("cvsd: min value %f, max value %f", p->com.v_min, p->com.v_max); return(SOX_SUCCESS); } /* ---------------------------------------------------------------------- */ size_t lsx_cvsdread(sox_format_t * ft, sox_sample_t *buf, size_t nsamp) { priv_t *p = (priv_t *) ft->priv; size_t done = 0; float oval; while (done < nsamp) { if (!p->bit.cnt) { if (lsx_read_b_buf(ft, &(p->bit.shreg), (size_t) 1) != 1) return done; p->bit.cnt = 8; p->bit.mask = 1; } /* * handle one bit */ p->bit.cnt--; p->com.overload = ((p->com.overload << 1) | (!!(p->bit.shreg & p->bit.mask))) & 7; p->bit.mask <<= 1; p->com.mla_int *= p->com.mla_tc0; if ((p->com.overload == 0) || (p->com.overload == 7)) p->com.mla_int += p->com.mla_tc1; /* shift output filter window in mirror cirular buffer. */ if (p->c.dec.offset != 0) --p->c.dec.offset; else p->c.dec.offset = CVSD_DEC_FILTERLEN - 1; /* write into both halves of the mirror circular buffer */ if (p->com.overload & 1) { p->c.dec.output_filter[p->c.dec.offset] = p->com.mla_int; p->c.dec.output_filter[p->c.dec.offset + CVSD_DEC_FILTERLEN] = p->com.mla_int; } else { p->c.dec.output_filter[p->c.dec.offset] = -p->com.mla_int; p->c.dec.output_filter[p->c.dec.offset + CVSD_DEC_FILTERLEN] = -p->com.mla_int; } /* * check if the next output is due */ p->com.phase += p->com.phase_inc; if (p->com.phase >= 4) { oval = float_conv_dec( p->c.dec.output_filter + p->c.dec.offset, (p->cvsd_rate < 24000) ? dec_filter_16 : dec_filter_32); lsx_debug_more("input %d %f\n", debug_count, p->com.mla_int); lsx_debug_more("recon %d %f\n", debug_count, oval); debug_count++; if (oval > p->com.v_max) p->com.v_max = oval; if (oval < p->com.v_min) p->com.v_min = oval; *buf++ = (oval * ((float)SOX_SAMPLE_MAX)); done++; } p->com.phase &= 3; } return done; } /* ---------------------------------------------------------------------- */ size_t lsx_cvsdwrite(sox_format_t * ft, const sox_sample_t *buf, size_t nsamp) { priv_t *p = (priv_t *) ft->priv; size_t done = 0; float inval; for(;;) { /* * check if the next input is due */ if (p->com.phase >= 4) { if (done >= nsamp) return done; /* shift input filter window in mirror cirular buffer. */ if (p->c.enc.offset != 0) --p->c.enc.offset; else p->c.enc.offset = CVSD_ENC_FILTERLEN - 1; /* write into both halves of the mirror circular buffer */ p->c.enc.input_filter[p->c.enc.offset] = p->c.enc.input_filter[p->c.enc.offset + CVSD_ENC_FILTERLEN] = (*buf++) / ((float)SOX_SAMPLE_MAX); done++; } p->com.phase &= 3; /* insert input filter here! */ inval = float_conv_enc( p->c.enc.input_filter + p->c.enc.offset, (p->cvsd_rate < 24000) ? (enc_filter_16[(p->com.phase >= 2)]) : (enc_filter_32[p->com.phase])); /* * encode one bit */ p->com.overload = (((p->com.overload << 1) | (inval > p->c.enc.recon_int)) & 7); p->com.mla_int *= p->com.mla_tc0; if ((p->com.overload == 0) || (p->com.overload == 7)) p->com.mla_int += p->com.mla_tc1; if (p->com.mla_int > p->com.v_max) p->com.v_max = p->com.mla_int; if (p->com.mla_int < p->com.v_min) p->com.v_min = p->com.mla_int; if (p->com.overload & 1) { p->c.enc.recon_int += p->com.mla_int; p->bit.shreg |= p->bit.mask; } else p->c.enc.recon_int -= p->com.mla_int; if ((++(p->bit.cnt)) >= 8) { lsx_writeb(ft, p->bit.shreg); p->bytes_written++; p->bit.shreg = p->bit.cnt = 0; p->bit.mask = 1; } else p->bit.mask <<= 1; p->com.phase += p->com.phase_inc; lsx_debug_more("input %d %f\n", debug_count, inval); lsx_debug_more("recon %d %f\n", debug_count, p->c.enc.recon_int); debug_count++; } } /* ---------------------------------------------------------------------- */ /* * DVMS file header */ /* FIXME: eliminate these 4 functions */ static uint32_t get32_le(unsigned char **p) { uint32_t val = (((*p)[3]) << 24) | (((*p)[2]) << 16) | (((*p)[1]) << 8) | (**p); (*p) += 4; return val; } static uint16_t get16_le(unsigned char **p) { unsigned val = (((*p)[1]) << 8) | (**p); (*p) += 2; return val; } static void put32_le(unsigned char **p, uint32_t val) { *(*p)++ = val & 0xff; *(*p)++ = (val >> 8) & 0xff; *(*p)++ = (val >> 16) & 0xff; *(*p)++ = (val >> 24) & 0xff; } static void put16_le(unsigned char **p, unsigned val) { *(*p)++ = val & 0xff; *(*p)++ = (val >> 8) & 0xff; } struct dvms_header { char Filename[14]; unsigned Id; unsigned State; time_t Unixtime; unsigned Usender; unsigned Ureceiver; size_t Length; unsigned Srate; unsigned Days; unsigned Custom1; unsigned Custom2; char Info[16]; char extend[64]; unsigned Crc; }; #define DVMS_HEADER_LEN 120 /* ---------------------------------------------------------------------- */ static int dvms_read_header(sox_format_t * ft, struct dvms_header *hdr) { unsigned char hdrbuf[DVMS_HEADER_LEN]; unsigned char *pch = hdrbuf; int i; unsigned sum; if (lsx_readbuf(ft, hdrbuf, sizeof(hdrbuf)) != sizeof(hdrbuf)) { return (SOX_EOF); } for(i = sizeof(hdrbuf), sum = 0; i > /*2*/3; i--) /* Deti bug */ sum += *pch++; pch = hdrbuf; memcpy(hdr->Filename, pch, sizeof(hdr->Filename)); pch += sizeof(hdr->Filename); hdr->Id = get16_le(&pch); hdr->State = get16_le(&pch); hdr->Unixtime = get32_le(&pch); hdr->Usender = get16_le(&pch); hdr->Ureceiver = get16_le(&pch); hdr->Length = get32_le(&pch); hdr->Srate = get16_le(&pch); hdr->Days = get16_le(&pch); hdr->Custom1 = get16_le(&pch); hdr->Custom2 = get16_le(&pch); memcpy(hdr->Info, pch, sizeof(hdr->Info)); pch += sizeof(hdr->Info); memcpy(hdr->extend, pch, sizeof(hdr->extend)); pch += sizeof(hdr->extend); hdr->Crc = get16_le(&pch); if (sum != hdr->Crc) { lsx_report("DVMS header checksum error, read %u, calculated %u", hdr->Crc, sum); return (SOX_EOF); } return (SOX_SUCCESS); } /* ---------------------------------------------------------------------- */ /* * note! file must be seekable */ static int dvms_write_header(sox_format_t * ft, struct dvms_header *hdr) { unsigned char hdrbuf[DVMS_HEADER_LEN]; unsigned char *pch = hdrbuf; unsigned char *pchs = hdrbuf; int i; unsigned sum; memcpy(pch, hdr->Filename, sizeof(hdr->Filename)); pch += sizeof(hdr->Filename); put16_le(&pch, hdr->Id); put16_le(&pch, hdr->State); put32_le(&pch, (unsigned)hdr->Unixtime); put16_le(&pch, hdr->Usender); put16_le(&pch, hdr->Ureceiver); put32_le(&pch, (unsigned) hdr->Length); put16_le(&pch, hdr->Srate); put16_le(&pch, hdr->Days); put16_le(&pch, hdr->Custom1); put16_le(&pch, hdr->Custom2); memcpy(pch, hdr->Info, sizeof(hdr->Info)); pch += sizeof(hdr->Info); memcpy(pch, hdr->extend, sizeof(hdr->extend)); pch += sizeof(hdr->extend); for(i = sizeof(hdrbuf), sum = 0; i > /*2*/3; i--) /* Deti bug */ sum += *pchs++; hdr->Crc = sum; put16_le(&pch, hdr->Crc); if (lsx_seeki(ft, (off_t)0, SEEK_SET) < 0) { lsx_report("seek failed\n: %s",strerror(errno)); return (SOX_EOF); } if (lsx_writebuf(ft, hdrbuf, sizeof(hdrbuf)) != sizeof(hdrbuf)) { lsx_report("%s",strerror(errno)); return (SOX_EOF); } return (SOX_SUCCESS); } /* ---------------------------------------------------------------------- */ static void make_dvms_hdr(sox_format_t * ft, struct dvms_header *hdr) { priv_t *p = (priv_t *) ft->priv; size_t len; char * comment = lsx_cat_comments(ft->oob.comments); memset(hdr->Filename, 0, sizeof(hdr->Filename)); len = strlen(ft->filename); if (len >= sizeof(hdr->Filename)) len = sizeof(hdr->Filename)-1; memcpy(hdr->Filename, ft->filename, len); hdr->Id = hdr->State = 0; hdr->Unixtime = sox_globals.repeatable? 0 : time(NULL); hdr->Usender = hdr->Ureceiver = 0; hdr->Length = p->bytes_written; hdr->Srate = p->cvsd_rate/100; hdr->Days = hdr->Custom1 = hdr->Custom2 = 0; memset(hdr->Info, 0, sizeof(hdr->Info)); len = strlen(comment); if (len >= sizeof(hdr->Info)) len = sizeof(hdr->Info)-1; memcpy(hdr->Info, comment, len); memset(hdr->extend, 0, sizeof(hdr->extend)); free(comment); } /* ---------------------------------------------------------------------- */ int lsx_dvmsstartread(sox_format_t * ft) { struct dvms_header hdr; int rc; rc = dvms_read_header(ft, &hdr); if (rc){ lsx_fail_errno(ft,SOX_EHDR,"unable to read DVMS header"); return rc; } lsx_debug("DVMS header of source file \"%s\":", ft->filename); lsx_debug(" filename \"%.14s\"", hdr.Filename); lsx_debug(" id 0x%x", hdr.Id); lsx_debug(" state 0x%x", hdr.State); lsx_debug(" time %s", #ifdef __plan9__ ctime(hdr.Unixtime) #else ctime(&hdr.Unixtime) #endif ); /* ctime generates lf */ lsx_debug(" usender %u", hdr.Usender); lsx_debug(" ureceiver %u", hdr.Ureceiver); lsx_debug(" length %" PRIuPTR, hdr.Length); lsx_debug(" srate %u", hdr.Srate); lsx_debug(" days %u", hdr.Days); lsx_debug(" custom1 %u", hdr.Custom1); lsx_debug(" custom2 %u", hdr.Custom2); lsx_debug(" info \"%.16s\"", hdr.Info); ft->signal.rate = (hdr.Srate < 240) ? 16000 : 32000; lsx_debug("DVMS rate %dbit/s using %gbit/s deviation %g%%", hdr.Srate*100, ft->signal.rate, ((ft->signal.rate - hdr.Srate*100) * 100) / ft->signal.rate); rc = lsx_cvsdstartread(ft); if (rc) return rc; return(SOX_SUCCESS); } /* ---------------------------------------------------------------------- */ int lsx_dvmsstartwrite(sox_format_t * ft) { struct dvms_header hdr; int rc; rc = lsx_cvsdstartwrite(ft); if (rc) return rc; make_dvms_hdr(ft, &hdr); rc = dvms_write_header(ft, &hdr); if (rc){ lsx_fail_errno(ft,rc,"cannot write DVMS header"); return rc; } if (!ft->seekable) lsx_warn("Length in output .DVMS header will wrong since can't seek to fix it"); return(SOX_SUCCESS); } /* ---------------------------------------------------------------------- */ int lsx_dvmsstopwrite(sox_format_t * ft) { struct dvms_header hdr; int rc; lsx_cvsdstopwrite(ft); if (!ft->seekable) { lsx_warn("File not seekable"); return (SOX_EOF); } if (lsx_seeki(ft, (off_t)0, 0) != 0) { lsx_fail_errno(ft,errno,"Can't rewind output file to rewrite DVMS header."); return(SOX_EOF); } make_dvms_hdr(ft, &hdr); rc = dvms_write_header(ft, &hdr); if(rc){ lsx_fail_errno(ft,rc,"cannot write DVMS header"); return rc; } return rc; }