ref: 647cc7f95737633fcad12cb342ad149624372a22
dir: /src/hcom.c/
/* * Sound Tools Macintosh HCOM format. * These are really FSSD type files with Huffman compression, * in MacBinary format. * To do: make the MacBinary format optional (so that .data files * are also acceptable). (How to do this on output?) * * September 25, 1991 * Copyright 1991 Guido van Rossum And Sundry Contributors * This source code is freely redistributable and may be used for * any purpose. This copyright notice must be maintained. * Guido van Rossum And Sundry Contributors are not responsible for * the consequences of using this software. * * April 28, 1998 - Chris Bagwell (cbagwell@sprynet.com) * * Rearranged some functions so that they are declared before they are * used. Clears up some compiler warnings. Because this functions passed * foats, it helped out some dump compilers pass stuff on the stack * correctly. * */ #include "st.h" #include <string.h> #ifdef __STDC__ #include <stdlib.h> #else IMPORT char *malloc(), *realloc(); #endif /* Dictionary entry for Huffman (de)compression */ typedef struct { LONG frequ; short dict_leftson; short dict_rightson; } dictent; /* Private data used by reader */ struct readpriv { /* Static data from the header */ dictent *dictionary; LONG checksum; int deltacompression; /* Engine state */ LONG huffcount; LONG cksum; int dictentry; int nrbits; ULONG current; short sample; }; void skipbytes(P2(ft_t, int)); void hcomstartread(ft) ft_t ft; { struct readpriv *p = (struct readpriv *) ft->priv; int i; char buf[4]; ULONG datasize, rsrcsize; ULONG huffcount, checksum, compresstype, divisor; unsigned short dictsize; int littlendian = 1; char *endptr; endptr = (char *) &littlendian; /* hcom is in big endian format. Swap whats * read in on little machine */ if (*endptr) { ft->swap = ft->swap ? 0 : 1; } /* Skip first 65 bytes of header */ skipbytes(ft, 65); /* Check the file type (bytes 65-68) */ if (fread(buf, 1, 4, ft->fp) != 4 || strncmp(buf, "FSSD", 4) != 0) fail("Mac header type is not FSSD"); /* Skip to byte 83 */ skipbytes(ft, 83-69); /* Get essential numbers from the header */ datasize = rlong(ft); /* bytes 83-86 */ rsrcsize = rlong(ft); /* bytes 87-90 */ /* Skip the rest of the header (total 128 bytes) */ skipbytes(ft, 128-91); /* The data fork must contain a "HCOM" header */ if (fread(buf, 1, 4, ft->fp) != 4 || strncmp(buf, "HCOM", 4) != 0) fail("Mac data fork is not HCOM"); /* Then follow various parameters */ huffcount = rlong(ft); checksum = rlong(ft); compresstype = rlong(ft); if (compresstype > 1) fail("Bad compression type in HCOM header"); divisor = rlong(ft); if (divisor == 0 || divisor > 4) fail("Bad sampling rate divisor in HCOM header"); dictsize = rshort(ft); /* Translate to sox parameters */ ft->info.style = UNSIGNED; ft->info.size = BYTE; ft->info.rate = 22050 / divisor; ft->info.channels = 1; /* Allocate memory for the dictionary */ p->dictionary = (dictent *) malloc(511 * sizeof(dictent)); if (p->dictionary == NULL) fail("can't malloc memory for Huffman dictionary"); /* Read dictionary */ for(i = 0; i < dictsize; i++) { p->dictionary[i].dict_leftson = rshort(ft); p->dictionary[i].dict_rightson = rshort(ft); /* report("%d %d", p->dictionary[i].dict_leftson, p->dictionary[i].dict_rightson); */ } skipbytes(ft, 1); /* skip pad byte */ /* Initialized the decompression engine */ p->checksum = checksum; p->deltacompression = compresstype; if (!p->deltacompression) report("HCOM data using value compression"); p->huffcount = huffcount; p->cksum = 0; p->dictentry = 0; p->nrbits = -1; /* Special case to get first byte */ } void skipbytes(ft, n) ft_t ft; int n; { while (--n >= 0) { if (getc(ft->fp) == EOF) fail("unexpected EOF in Mac header"); } } int hcomread(ft, buf, len) ft_t ft; LONG *buf, len; { register struct readpriv *p = (struct readpriv *) ft->priv; int done = 0; if (p->nrbits < 0) { /* The first byte is special */ if (p->huffcount == 0) return 0; /* Don't know if this can happen... */ p->sample = getc(ft->fp); if (p->sample == EOF) fail("unexpected EOF at start of HCOM data"); *buf++ = (p->sample - 128) * 0x1000000L; p->huffcount--; p->nrbits = 0; done++; len--; if (len == 0) return done; } while (p->huffcount > 0) { if(p->nrbits == 0) { p->current = rlong(ft); if (feof(ft->fp)) fail("unexpected EOF in HCOM data"); p->cksum += p->current; p->nrbits = 32; } if(p->current & 0x80000000L) { p->dictentry = p->dictionary[p->dictentry].dict_rightson; } else { p->dictentry = p->dictionary[p->dictentry].dict_leftson; } p->current = p->current << 1; p->nrbits--; if(p->dictionary[p->dictentry].dict_leftson < 0) { short datum; datum = p->dictionary[p->dictentry].dict_rightson; if (!p->deltacompression) p->sample = 0; p->sample = (p->sample + datum) & 0xff; p->huffcount--; if (p->sample == 0) *buf++ = -127 * 0x1000000L; else *buf++ = (p->sample - 128) * 0x1000000L; p->dictentry = 0; done++; len--; if (len == 0) break; } } return done; } void hcomstopread(ft) ft_t ft; { register struct readpriv *p = (struct readpriv *) ft->priv; if (p->huffcount != 0) fail("not all HCOM data read"); if(p->cksum != p->checksum) fail("checksum error in HCOM data"); free((char *)p->dictionary); p->dictionary = NULL; } struct writepriv { unsigned char *data; /* Buffer allocated with malloc */ unsigned int size; /* Size of allocated buffer */ unsigned int pos; /* Where next byte goes */ }; #define BUFINCR (10*BUFSIZ) void hcomstartwrite(ft) ft_t ft; { register struct writepriv *p = (struct writepriv *) ft->priv; int littlendian = 1; char *endptr; endptr = (char *) &littlendian; /* hcom is inbigendian format. Swap whats * read in on little endian machines. */ if (*endptr) { ft->swap = ft->swap ? 0 : 1; } switch (ft->info.rate) { case 22050: case 22050/2: case 22050/3: case 22050/4: break; default: fail("unacceptable output rate for HCOM: try 5512, 7350, 11025 or 22050 hertz"); } ft->info.size = BYTE; ft->info.style = UNSIGNED; ft->info.channels = 1; p->size = BUFINCR; p->pos = 0; p->data = (unsigned char *) malloc(p->size); if (p->data == NULL) fail("can't malloc buffer for uncompressed HCOM data"); } void hcomwrite(ft, buf, len) ft_t ft; LONG *buf, len; { register struct writepriv *p = (struct writepriv *) ft->priv; LONG datum; if (p->pos + len > p->size) { p->size = ((p->pos + len) / BUFINCR + 1) * BUFINCR; p->data = (unsigned char *) realloc(p->data, p->size); if (p->data == NULL) fail("can't realloc buffer for uncompressed HCOM data"); } while (--len >= 0) { datum = *buf++; datum >>= 24; datum ^= 128; p->data[p->pos++] = datum; } } /* Some global compression stuff hcom uses. hcom currently has problems */ /* compiling here. It could really use some cleaning up by someone that */ /* understands this format. */ /* XXX This uses global variables -- one day these should all be passed around in a structure instead. */ dictent dictionary[511]; dictent *de; LONG codes[256]; LONG codesize[256]; LONG checksum; void makecodes(e, c, s, b) int e, c, s, b; { if(dictionary[e].dict_leftson < 0) { codes[dictionary[e].dict_rightson] = c; codesize[dictionary[e].dict_rightson] = s; } else { makecodes(dictionary[e].dict_leftson, c, s + 1, b << 1); makecodes(dictionary[e].dict_rightson, c + b, s + 1, b << 1); } } LONG curword; int nbits; void putlong(c, v) unsigned char *c; LONG v; { *c++ = (v >> 24) & 0xff; *c++ = (v >> 16) & 0xff; *c++ = (v >> 8) & 0xff; *c++ = v & 0xff; } void putshort(c, v) unsigned char *c; short v; { *c++ = (v >> 8) & 0xff; *c++ = v & 0xff; } void putcode(c, df) unsigned char c; unsigned char ** df; { LONG code, size; int i; code = codes[c]; size = codesize[c]; for(i = 0; i < size; i++) { curword = (curword << 1); if(code & 1) curword += 1; nbits++; if(nbits == 32) { putlong(*df, curword); checksum += curword; (*df) += 4; nbits = 0; curword = 0; } code = code >> 1; } } void compress(df, dl, fr) unsigned char **df; LONG *dl; float fr; { LONG samplerate; unsigned char *datafork = *df; unsigned char *ddf; short dictsize; int frequtable[256]; int i, sample, j, k, d, l, frequcount; sample = *datafork; for(i = 0; i < 256; i++) frequtable[i] = 0; for(i = 1; i < *dl; i++) { d = (datafork[i] - (sample & 0xff)) & 0xff; /* creates absolute entries LMS */ sample = datafork[i]; datafork[i] = d; #if 0 /* checking our table is accessed correctly */ if(d < 0 || d > 255) printf("d is outside array bounds %d\n", d); #endif frequtable[d]++; } de = dictionary; for(i = 0; i < 256; i++) if(frequtable[i] != 0) { de->frequ = -frequtable[i]; de->dict_leftson = -1; de->dict_rightson = i; de++; } frequcount = de - dictionary; for(i = 0; i < frequcount; i++) { for(j = i + 1; j < frequcount; j++) { if(dictionary[i].frequ > dictionary[j].frequ) { k = dictionary[i].frequ; dictionary[i].frequ = dictionary[j].frequ; dictionary[j].frequ = k; k = dictionary[i].dict_leftson; dictionary[i].dict_leftson = dictionary[j].dict_leftson; dictionary[j].dict_leftson = k; k = dictionary[i].dict_rightson; dictionary[i].dict_rightson = dictionary[j].dict_rightson; dictionary[j].dict_rightson = k; } } } while(frequcount > 1) { j = frequcount - 1; de->frequ = dictionary[j - 1].frequ; de->dict_leftson = dictionary[j - 1].dict_leftson; de->dict_rightson = dictionary[j - 1].dict_rightson; l = dictionary[j - 1].frequ + dictionary[j].frequ; for(i = j - 2; i >= 0; i--) { if(l >= dictionary[i].frequ) break; dictionary[i + 1] = dictionary[i]; } i = i + 1; dictionary[i].frequ = l; dictionary[i].dict_leftson = j; dictionary[i].dict_rightson = de - dictionary; de++; frequcount--; } dictsize = de - dictionary; for(i = 0; i < 256; i++) { codes[i] = 0; codesize[i] = 0; } makecodes(0, 0, 0, 1); l = 0; for(i = 0; i < 256; i++) { l += frequtable[i] * codesize[i]; } l = (((l + 31) >> 5) << 2) + 24 + dictsize * 4; report(" Original size: %6d bytes", *dl); report("Compressed size: %6d bytes", l); if((datafork = (unsigned char *)malloc((unsigned)l)) == NULL) fail("can't malloc buffer for compressed HCOM data"); ddf = datafork + 22; for(i = 0; i < dictsize; i++) { putshort(ddf, dictionary[i].dict_leftson); ddf += 2; putshort(ddf, dictionary[i].dict_rightson); ddf += 2; } *ddf++ = 0; *ddf++ = *(*df)++; checksum = 0; nbits = 0; curword = 0; for(i = 1; i < *dl; i++) putcode(*(*df)++, &ddf); if(nbits != 0) { codes[0] = 0; codesize[0] = 32 - nbits; putcode(0, &ddf); } strncpy((char *) datafork, "HCOM", 4); putlong(datafork + 4, *dl); putlong(datafork + 8, checksum); putlong(datafork + 12, 1L); samplerate = 22050 / (LONG)fr; putlong(datafork + 16, samplerate); putshort(datafork + 20, dictsize); *df = datafork; /* reassign passed pointer to new datafork */ *dl = l; /* and its compressed length */ } void padbytes(ft, n) ft_t ft; int n; { while (--n >= 0) putc('\0', ft->fp); } /* End of hcom utility routines */ void hcomstopwrite(ft) ft_t ft; { register struct writepriv *p = (struct writepriv *) ft->priv; unsigned char *compressed_data = p->data; LONG compressed_len = p->pos; /* Compress it all at once */ compress(&compressed_data, &compressed_len, (double) ft->info.rate); free((char *) p->data); /* Write the header */ (void) fwrite("\000\001A", 1, 3, ft->fp); /* Dummy file name "A" */ padbytes(ft, 65-3); (void) fwrite("FSSD", 1, 4, ft->fp); padbytes(ft, 83-69); wlong(ft, (ULONG) compressed_len); /* compressed_data size */ wlong(ft, (ULONG) 0); /* rsrc size */ padbytes(ft, 128 - 91); if (ferror(ft->fp)) fail("write error in HCOM header"); /* Write the compressed_data fork */ if (fwrite((char *) compressed_data, 1, (int)compressed_len, ft->fp) != compressed_len) fail("can't write compressed HCOM data"); free((char *) compressed_data); /* Pad the compressed_data fork to a multiple of 128 bytes */ padbytes(ft, 128 - (int) (compressed_len%128)); }