ref: 9e77c6995cae212a482c784fbe2529e0f7b2b636
dir: /Engine/src/cache1d.c/
/* * "Build Engine & Tools" Copyright (c) 1993-1997 Ken Silverman * Ken Silverman's official web site: "http://www.advsys.net/ken" * See the included license file "BUILDLIC.TXT" for license info. * This file has been modified from Ken Silverman's original release */ #include <stdio.h> #include <stdlib.h> #include <string.h> #include <fcntl.h> #include <sys/types.h> #include <sys/stat.h> #include "platform.h" #include "display.h" #include "pragmas.h" #include "cache1d.h" #include "build.h" #include "../../Game/src/cvar_defs.h" #include "types.h" /* * This module keeps track of a standard linear cacheing system. * To use this module, here's all you need to do: * * Step 1: Allocate a nice BIG buffer, like from 1MB-4MB and * Call initcache(int32_t cachestart, int32_t cachesize) where * * cachestart = (int32_t )(pointer to start of BIG buffer) * cachesize = length of BIG buffer * * Step 2: Call allocache(int32_t *bufptr, int32_t bufsiz, uint8_t *lockptr) * whenever you need to allocate a buffer, where: * * *bufptr = pointer to 4-byte pointer to buffer * Confused? Using this method, cache2d can remove * previously allocated things from the cache safely by * setting the 4-byte pointer to 0. * bufsiz = number of bytes to allocate * *lockptr = pointer to locking uint8_t which tells whether * the region can be removed or not. If *lockptr = 0 then * the region is not locked else its locked. * * Step 3: If you need to remove everything from the cache, or every * unlocked item from the cache, you can call uninitcache(); * Call uninitcache(0) to remove all unlocked items, or * Call uninitcache(1) to remove everything. * After calling uninitcache, it is still ok to call allocache * without first calling initcache. */ #define MAXCACHEOBJECTS 9216 static int32_t cachesize = 0; int32_t cachecount = 0; uint8_t zerochar = 0; int32_t cachestart = 0, cacnum = 0, agecount = 0; typedef struct { int32_t *hand, leng; uint8_t *lock; } cactype; cactype cac[MAXCACHEOBJECTS]; int32_t lockrecip[200]; // TC game directory char game_dir[512] = { '\0' }; void initcache(int32_t dacachestart, int32_t dacachesize) { int32_t i; for(i=1;i<200;i++) lockrecip[i] = (1<<28)/(200-i); cachestart = dacachestart; cachesize = dacachesize; cac[0].leng = cachesize; cac[0].lock = &zerochar; cacnum = 1; } void allocache (int32_t *newhandle, int32_t newbytes, uint8_t *newlockptr) { int32_t i, z, zz, bestz=0, daval, bestval, besto=0, o1, o2, sucklen, suckz; newbytes = newbytes+15; if ((uint32_t)newbytes > (uint32_t)cachesize) { printf("Cachesize: %d\n",cachesize); printf("*Newhandle: 0x%x, Newbytes: %d, *Newlock: %d\n",(unsigned int)newhandle,newbytes,*newlockptr); reportandexit("BUFFER TOO BIG TO FIT IN CACHE!\n"); } if (*newlockptr == 0) { reportandexit("ALLOCACHE CALLED WITH LOCK OF 0!\n"); } /* Find best place */ bestval = 0x7fffffff; o1 = cachesize; for(z=cacnum-1;z>=0;z--) { o1 -= cac[z].leng; o2 = o1+newbytes; if (o2 > cachesize) continue; daval = 0; for(i=o1,zz=z;i<o2;i+=cac[zz++].leng) { if (*cac[zz].lock == 0) continue; if (*cac[zz].lock >= 200) { daval = 0x7fffffff; break; } daval += (int32_t ) mulscale32(cac[zz].leng+65536,lockrecip[*cac[zz].lock]); if (daval >= bestval) break; } if (daval < bestval) { bestval = daval; besto = o1; bestz = z; if (bestval == 0) break; } } /*printf("%ld %ld %ld\n",besto,newbytes,*newlockptr);*/ if (bestval == 0x7fffffff) reportandexit("CACHE SPACE ALL LOCKED UP!\n"); /* Suck things out */ for(sucklen=-newbytes,suckz=bestz;sucklen<0;sucklen+=cac[suckz++].leng) if (*cac[suckz].lock) *cac[suckz].hand = 0; /* Remove all blocks except 1 */ suckz -= (bestz+1); cacnum -= suckz; copybufbyte(&cac[bestz+suckz],&cac[bestz],(cacnum-bestz)*sizeof(cactype)); cac[bestz].hand = newhandle; *newhandle = cachestart+besto; cac[bestz].leng = newbytes; cac[bestz].lock = newlockptr; cachecount++; /* Add new empty block if necessary */ if (sucklen <= 0) return; bestz++; if (bestz == cacnum) { cacnum++; if (cacnum > MAXCACHEOBJECTS) reportandexit("Too many objects in cache! (cacnum > MAXCACHEOBJECTS)\n"); cac[bestz].leng = sucklen; cac[bestz].lock = &zerochar; return; } if (*cac[bestz].lock == 0) { cac[bestz].leng += sucklen; return; } cacnum++; if (cacnum > MAXCACHEOBJECTS) reportandexit("Too many objects in cache! (cacnum > MAXCACHEOBJECTS)\n"); for(z=cacnum-1;z>bestz;z--) cac[z] = cac[z-1]; cac[bestz].leng = sucklen; cac[bestz].lock = &zerochar; } void suckcache (int32_t *suckptr) { int32_t i; /* Can't exit early, because invalid pointer might be same even though lock = 0 */ for(i=0;i<cacnum;i++) if ((int32_t )(*cac[i].hand) == (int32_t )suckptr) { if (*cac[i].lock) *cac[i].hand = 0; cac[i].lock = &zerochar; cac[i].hand = 0; /* Combine empty blocks */ if ((i > 0) && (*cac[i-1].lock == 0)) { cac[i-1].leng += cac[i].leng; cacnum--; copybuf(&cac[i+1],&cac[i],(cacnum-i)*sizeof(cactype)); } else if ((i < cacnum-1) && (*cac[i+1].lock == 0)) { cac[i+1].leng += cac[i].leng; cacnum--; copybuf(&cac[i+1],&cac[i],(cacnum-i)*sizeof(cactype)); } } } void agecache(void) { int32_t cnt; uint8_t ch; if (agecount >= cacnum) agecount = cacnum-1; assert(agecount >= 0); for(cnt=(cacnum>>4);cnt>=0;cnt--) { ch = (*cac[agecount].lock); if (((ch-2)&255) < 198) (*cac[agecount].lock) = (uint8_t ) (ch-1); agecount--; if (agecount < 0) agecount = cacnum-1; } } void reportandexit(char *errormessage) { int32_t i, j; setvmode(0x3); j = 0; for(i=0;i<cacnum;i++) { printf("%d- ",i); printf("ptr: 0x%x, ",*cac[i].hand); printf("leng: %d, ",cac[i].leng); printf("lock: %d\n",*cac[i].lock); j += cac[i].leng; } printf("Cachesize = %d\n",cachesize); printf("Cacnum = %d\n",cacnum); printf("Cache length sum = %d\n",j); printf("ERROR: %s",errormessage); Error(EXIT_FAILURE, ""); } uint8_t toupperlookup[256] = { 0x00,0x01,0x02,0x03,0x04,0x05,0x06,0x07,0x08,0x09,0x0a,0x0b,0x0c,0x0d,0x0e,0x0f, 0x10,0x11,0x12,0x13,0x14,0x15,0x16,0x17,0x18,0x19,0x1a,0x1b,0x1c,0x1d,0x1e,0x1f, 0x20,0x21,0x22,0x23,0x24,0x25,0x26,0x27,0x28,0x29,0x2a,0x2b,0x2c,0x2d,0x2e,0x2f, 0x30,0x31,0x32,0x33,0x34,0x35,0x36,0x37,0x38,0x39,0x3a,0x3b,0x3c,0x3d,0x3e,0x3f, 0x40,0x41,0x42,0x43,0x44,0x45,0x46,0x47,0x48,0x49,0x4a,0x4b,0x4c,0x4d,0x4e,0x4f, 0x50,0x51,0x52,0x53,0x54,0x55,0x56,0x57,0x58,0x59,0x5a,0x5b,0x5c,0x5d,0x5e,0x5f, 0x60,0x41,0x42,0x43,0x44,0x45,0x46,0x47,0x48,0x49,0x4a,0x4b,0x4c,0x4d,0x4e,0x4f, 0x50,0x51,0x52,0x53,0x54,0x55,0x56,0x57,0x58,0x59,0x5a,0x7b,0x7c,0x7d,0x7e,0x7f, 0x80,0x81,0x82,0x83,0x84,0x85,0x86,0x87,0x88,0x89,0x8a,0x8b,0x8c,0x8d,0x8e,0x8f, 0x90,0x91,0x92,0x93,0x94,0x95,0x96,0x97,0x98,0x99,0x9a,0x9b,0x9c,0x9d,0x9e,0x9f, 0xa0,0xa1,0xa2,0xa3,0xa4,0xa5,0xa6,0xa7,0xa8,0xa9,0xaa,0xab,0xac,0xad,0xae,0xaf, 0xb0,0xb1,0xb2,0xb3,0xb4,0xb5,0xb6,0xb7,0xb8,0xb9,0xba,0xbb,0xbc,0xbd,0xbe,0xbf, 0xc0,0xc1,0xc2,0xc3,0xc4,0xc5,0xc6,0xc7,0xc8,0xc9,0xca,0xcb,0xcc,0xcd,0xce,0xcf, 0xd0,0xd1,0xd2,0xd3,0xd4,0xd5,0xd6,0xd7,0xd8,0xd9,0xda,0xdb,0xdc,0xdd,0xde,0xdf, 0xe0,0xe1,0xe2,0xe3,0xe4,0xe5,0xe6,0xe7,0xe8,0xe9,0xea,0xeb,0xec,0xed,0xee,0xef, 0xf0,0xf1,0xf2,0xf3,0xf4,0xf5,0xf6,0xf7,0xf8,0xf9,0xfa,0xfb,0xfc,0xfd,0xfe,0xff, }; int32_t numgroupfiles = 0; // number of GRP files actually used. int32_t gnumfiles[MAXGROUPFILES]; // number of files on grp int32_t groupfil[MAXGROUPFILES] = {-1,-1,-1,-1}; // grp file handles int32_t groupfilpos[MAXGROUPFILES]; uint8_t *gfilelist[MAXGROUPFILES]; // name list + size list of all the files in grp int32_t *gfileoffs[MAXGROUPFILES]; // offset of the files uint8_t *groupfil_memory[MAXGROUPFILES]; // addresses of raw GRP files in memory int32_t groupefil_crc32[MAXGROUPFILES]; uint8_t filegrp[MAXOPENFILES]; int32_t filepos[MAXOPENFILES]; int32_t filehan[MAXOPENFILES] = { -1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1, -1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1, -1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1, -1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1,-1, }; int32_t initgroupfile(const char *filename) { uint8_t buf[16]; int32_t i, j, k; printf("Loading %s ...\n", filename); if (numgroupfiles >= MAXGROUPFILES) return(-1); groupfil_memory[numgroupfiles] = NULL; // addresses of raw GRP files in memory groupefil_crc32[numgroupfiles] = 0; groupfil[numgroupfiles] = open(filename,O_BINARY|O_RDWR,S_IREAD); if (groupfil[numgroupfiles] >= 0) { groupfilpos[numgroupfiles] = 0; read(groupfil[numgroupfiles],buf,16); if ((buf[0] != 'K') || (buf[1] != 'e') || (buf[2] != 'n') || (buf[3] != 'S') || (buf[4] != 'i') || (buf[5] != 'l') || (buf[6] != 'v') || (buf[7] != 'e') || (buf[8] != 'r') || (buf[9] != 'm') || (buf[10] != 'a') || (buf[11] != 'n')) { close(groupfil[numgroupfiles]); groupfil[numgroupfiles] = -1; return(-1); } //FCS: The ".grp" file format is just a collection of a lot of files stored into 1 big one. //I tried to make the format as simple as possible: The first 12 bytes contains my name, //"KenSilverman". The next 4 bytes is the number of files that were compacted into the //group file. Then for each file, there is a 16 byte structure, where the first 12 //bytes are the filename, and the last 4 bytes are the file's size. The rest of the //group file is just the raw data packed one after the other in the same order as the list //of files. - ken gnumfiles[numgroupfiles] = BUILDSWAP_INTEL32(*((int32_t *)&buf[12])); if ((gfilelist[numgroupfiles] = (uint8_t *)kmalloc(gnumfiles[numgroupfiles]<<4)) == 0) { Error(EXIT_FAILURE, "Not enough memory for file grouping system\n"); } if ((gfileoffs[numgroupfiles] = (int32_t *)kmalloc((gnumfiles[numgroupfiles]+1)<<2)) == 0) { Error(EXIT_FAILURE, "Not enough memory for file grouping system\n"); } // load index (name+size) read(groupfil[numgroupfiles],gfilelist[numgroupfiles],gnumfiles[numgroupfiles]<<4); j = 0; for(i=0;i<gnumfiles[numgroupfiles];i++) { k = BUILDSWAP_INTEL32(*((int32_t *)&gfilelist[numgroupfiles][(i<<4)+12])); // get size gfilelist[numgroupfiles][(i<<4)+12] = 0; gfileoffs[numgroupfiles][i] = j; // absolute offset list of all files. 0 for 1st file j += k; } gfileoffs[numgroupfiles][gnumfiles[numgroupfiles]] = j; } else { printf("Unable to find GRP file %s.\n",filename); //Let user see the message getchar(); exit(0); } // Compute CRC32 of thw whole grp and implicitely caches the GRP in memory through windows lseek(groupfil[numgroupfiles], 0, SEEK_SET); i = 1000000; // FIX_00086: grp loaded by smaller sucessive chunks to avoid overloading low ram computers groupfil_memory[numgroupfiles] = malloc(i); while((j=read(groupfil[numgroupfiles], groupfil_memory[numgroupfiles], i))) { groupefil_crc32[numgroupfiles] = crc32_update((uint8_t *)groupfil_memory[numgroupfiles], j, groupefil_crc32[numgroupfiles]); } free(groupfil_memory[numgroupfiles]); groupfil_memory[numgroupfiles] = 0; numgroupfiles++; return(groupfil[numgroupfiles-1]); } void uninitgroupfile(void) { int32_t i; for(i=numgroupfiles-1;i>=0;i--) if (groupfil[i] != -1) { kfree(gfilelist[i]); kfree(gfileoffs[i]); close(groupfil[i]); groupfil[i] = -1; } } void crc32_table_gen(unsigned int* crc32_table) /* build CRC32 table */ { unsigned int crc, poly; int i, j; poly = 0xEDB88320L; for (i = 0; i < 256; i++) { crc = i; for (j = 8; j > 0; j--) { if (crc & 1) crc = (crc >> 1) ^ poly; else crc >>= 1; } crc32_table[i] = crc; } } unsigned int crc32(uint8_t *buf, unsigned int length) { unsigned int initial_crc; initial_crc = 0; return(crc32_update(buf, length, initial_crc)); } unsigned int crc32_update(uint8_t *buf, unsigned int length, unsigned int crc_to_update) { unsigned int crc32_table[256]; crc32_table_gen(crc32_table); crc_to_update ^= 0xFFFFFFFF; while (length--) crc_to_update = crc32_table[(crc_to_update ^ *buf++) & 0xFF] ^ (crc_to_update >> 8); return crc_to_update ^ 0xFFFFFFFF; } /* * 16 12 5 * this is the CCITT CRC 16 polynomial X + X + X + 1. * This is 0x1021 when x is 2, but the way the algorithm works * we use 0x8408 (the reverse of the bit pattern). The high * bit is always assumed to be set, thus we only use 16 bits to * represent the 17 bit value. */ #define POLY 0x8408 /* 1021H bit reversed */ uint16_t crc16(uint8_t *data_p, uint16_t length) { uint8_t i; unsigned int data; unsigned int crc = 0xffff; if (length == 0) return (~crc); do { for (i=0, data=(unsigned int)0xff & *data_p++; i < 8; i++, data >>= 1) { if ((crc & 0x0001) ^ (data & 0x0001)) crc = (crc >> 1) ^ POLY; else crc >>= 1; } } while (--length); crc = ~crc; data = crc; crc = (crc << 8) | (data >> 8 & 0xff); return (crc); } int32_t kopen4load(const char *filename, int readfromGRP) { // FIX_00072: all files are now 1st searched in Duke's root folder and then in the GRP. int32_t i, j, k, fil, newhandle; uint8_t bad; uint8_t *gfileptr; newhandle = MAXOPENFILES-1; while (filehan[newhandle] != -1) { newhandle--; if (newhandle < 0) { Error(EXIT_FAILURE, "Too Many files open!\n"); } } if(!readfromGRP) if ((fil = open(filename,O_BINARY|O_RDONLY)) != -1) { filegrp[newhandle] = 255; filehan[newhandle] = fil; filepos[newhandle] = 0; printf("Reading external %s \n", filename); return(newhandle); } for(k=numgroupfiles-1;k>=0;k--) { if (groupfil[k] != -1) { for(i=gnumfiles[k]-1;i>=0;i--) { gfileptr = (uint8_t *)&gfilelist[k][i<<4]; bad = 0; for(j=0;j<13;j++) { if (!filename[j]) break; if (toupperlookup[(int) filename[j]] != toupperlookup[(int) gfileptr[j]]) { bad = 1; break; } } if (bad) continue; filegrp[newhandle] = (uint8_t ) k; filehan[newhandle] = i; filepos[newhandle] = 0; return(newhandle); } } } return(-1); } int32_t kread(int32_t handle, void *buffer, int32_t leng) { int32_t i, filenum, groupnum; filenum = filehan[handle]; groupnum = filegrp[handle]; if (groupnum == 255) // Reading external { return(read(filenum,buffer,leng)); } if (groupfil[groupnum] != -1) { i = gfileoffs[groupnum][filenum]+filepos[handle]; if (i != groupfilpos[groupnum]) { lseek(groupfil[groupnum],i+((gnumfiles[groupnum]+1)<<4),SEEK_SET); groupfilpos[groupnum] = i; } leng = min(leng,(gfileoffs[groupnum][filenum+1]-gfileoffs[groupnum][filenum])-filepos[handle]); leng = read(groupfil[groupnum],buffer,leng); filepos[handle] += leng; groupfilpos[groupnum] += leng; return(leng); } return(0); } int kread16(int32_t handle, short *buffer) { if (kread(handle, buffer, 2) != 2) return(0); *buffer = BUILDSWAP_INTEL16(*buffer); return(1); } int kread32(int32_t handle, int32_t *buffer) { if (kread(handle, buffer, 4) != 4) return(0); *buffer = BUILDSWAP_INTEL32(*buffer); return(1); } int kread8(int32_t handle, uint8_t *buffer) { if (kread(handle, buffer, 1) != 1) return(0); return(1); } int32_t klseek(int32_t handle, int32_t offset, int32_t whence) { int32_t i, groupnum; groupnum = filegrp[handle]; if (groupnum == 255) return((int32_t )lseek(filehan[handle],offset,whence)); if (groupfil[groupnum] != -1) { switch(whence) { case SEEK_SET: filepos[handle] = offset; break; case SEEK_END: i = filehan[handle]; filepos[handle] = (gfileoffs[groupnum][i+1]-gfileoffs[groupnum][i])+offset; break; case SEEK_CUR: filepos[handle] += offset; break; } return(filepos[handle]); } return(-1); } #ifdef __APPLE__ int32_t filelength(int32_t fd) { struct stat stats; fstat(fd, &stats); return (int32_t )stats.st_size; } #endif int32_t kfilelength(int32_t handle) { int32_t i, groupnum; groupnum = filegrp[handle]; if (groupnum == 255) return(filelength(filehan[handle])); i = filehan[handle]; return(gfileoffs[groupnum][i+1]-gfileoffs[groupnum][i]); } void kclose(int32_t handle) { if (handle < 0) return; if (filegrp[handle] == 255) close(filehan[handle]); filehan[handle] = -1; } /* Internal LZW variables */ #define LZWSIZE 16384 /* Watch out for shorts! */ static uint8_t *lzwbuf1, *lzwbuf4, *lzwbuf5; static uint8_t lzwbuflock[5]; static short *lzwbuf2, *lzwbuf3; void kdfread(void *buffer, size_t dasizeof, size_t count, int32_t fil) { size_t i, j; int32_t k, kgoal; short leng; uint8_t *ptr; lzwbuflock[0] = lzwbuflock[1] = lzwbuflock[2] = lzwbuflock[3] = lzwbuflock[4] = 200; if (lzwbuf1 == NULL) allocache((int32_t *)&lzwbuf1,LZWSIZE+(LZWSIZE>>4),&lzwbuflock[0]); if (lzwbuf2 == NULL) allocache((int32_t *)&lzwbuf2,(LZWSIZE+(LZWSIZE>>4))*2,&lzwbuflock[1]); if (lzwbuf3 == NULL) allocache((int32_t *)&lzwbuf3,(LZWSIZE+(LZWSIZE>>4))*2,&lzwbuflock[2]); if (lzwbuf4 == NULL) allocache((int32_t *)&lzwbuf4,LZWSIZE,&lzwbuflock[3]); if (lzwbuf5 == NULL) allocache((int32_t *)&lzwbuf5,LZWSIZE+(LZWSIZE>>4),&lzwbuflock[4]); if (dasizeof > LZWSIZE) { count *= dasizeof; dasizeof = 1; } ptr = (uint8_t *)buffer; kread(fil,&leng,2); kread(fil,lzwbuf5,(int32_t )leng); k = 0; kgoal = uncompress(lzwbuf5,(int32_t )leng,lzwbuf4); copybufbyte(lzwbuf4,ptr,(int32_t )dasizeof); k += (int32_t )dasizeof; for(i=1;i<count;i++) { if (k >= kgoal) { kread(fil,&leng,2); kread(fil,lzwbuf5,(int32_t )leng); k = 0; kgoal = uncompress(lzwbuf5,(int32_t )leng,lzwbuf4); } for(j=0;j<dasizeof;j++) ptr[j+dasizeof] = (uint8_t ) ((ptr[j]+lzwbuf4[j+k])&255); k += dasizeof; ptr += dasizeof; } lzwbuflock[0] = lzwbuflock[1] = lzwbuflock[2] = lzwbuflock[3] = lzwbuflock[4] = 1; } void dfread(void *buffer, size_t dasizeof, size_t count, FILE *fil) { size_t i, j; int32_t k, kgoal; short leng; uint8_t *ptr; lzwbuflock[0] = lzwbuflock[1] = lzwbuflock[2] = lzwbuflock[3] = lzwbuflock[4] = 200; if (lzwbuf1 == NULL) allocache((int32_t *)&lzwbuf1,LZWSIZE+(LZWSIZE>>4),&lzwbuflock[0]); if (lzwbuf2 == NULL) allocache((int32_t *)&lzwbuf2,(LZWSIZE+(LZWSIZE>>4))*2,&lzwbuflock[1]); if (lzwbuf3 == NULL) allocache((int32_t *)&lzwbuf3,(LZWSIZE+(LZWSIZE>>4))*2,&lzwbuflock[2]); if (lzwbuf4 == NULL) allocache((int32_t *)&lzwbuf4,LZWSIZE,&lzwbuflock[3]); if (lzwbuf5 == NULL) allocache((int32_t *)&lzwbuf5,LZWSIZE+(LZWSIZE>>4),&lzwbuflock[4]); if (dasizeof > LZWSIZE) { count *= dasizeof; dasizeof = 1; } ptr = (uint8_t *)buffer; fread(&leng,2,1,fil); fread(lzwbuf5,(int32_t )leng,1,fil); k = 0; kgoal = uncompress(lzwbuf5,(int32_t )leng,lzwbuf4); copybufbyte(lzwbuf4,ptr,(int32_t )dasizeof); k += (int32_t )dasizeof; for(i=1;i<count;i++) { if (k >= kgoal) { fread(&leng,2,1,fil); fread(lzwbuf5,(int32_t )leng,1,fil); k = 0; kgoal = uncompress(lzwbuf5,(int32_t )leng,lzwbuf4); } for(j=0;j<dasizeof;j++) ptr[j+dasizeof] = (uint8_t ) ((ptr[j]+lzwbuf4[j+k])&255); k += dasizeof; ptr += dasizeof; } lzwbuflock[0] = lzwbuflock[1] = lzwbuflock[2] = lzwbuflock[3] = lzwbuflock[4] = 1; } void dfwrite(void *buffer, size_t dasizeof, size_t count, FILE *fil) { size_t i, j, k; short leng; uint8_t *ptr; lzwbuflock[0] = lzwbuflock[1] = lzwbuflock[2] = lzwbuflock[3] = lzwbuflock[4] = 200; if (lzwbuf1 == NULL) allocache((int32_t *)&lzwbuf1,LZWSIZE+(LZWSIZE>>4),&lzwbuflock[0]); if (lzwbuf2 == NULL) allocache((int32_t *)&lzwbuf2,(LZWSIZE+(LZWSIZE>>4))*2,&lzwbuflock[1]); if (lzwbuf3 == NULL) allocache((int32_t *)&lzwbuf3,(LZWSIZE+(LZWSIZE>>4))*2,&lzwbuflock[2]); if (lzwbuf4 == NULL) allocache((int32_t *)&lzwbuf4,LZWSIZE,&lzwbuflock[3]); if (lzwbuf5 == NULL) allocache((int32_t *)&lzwbuf5,LZWSIZE+(LZWSIZE>>4),&lzwbuflock[4]); if (dasizeof > LZWSIZE) { count *= dasizeof; dasizeof = 1; } ptr = (uint8_t *)buffer; copybufbyte(ptr,lzwbuf4,(int32_t )dasizeof); k = dasizeof; if (k > LZWSIZE-dasizeof) { leng = (short)compress(lzwbuf4,k,lzwbuf5); k = 0; fwrite(&leng,2,1,fil); fwrite(lzwbuf5,(int32_t )leng,1,fil); } for(i=1;i<count;i++) { for(j=0;j<dasizeof;j++) lzwbuf4[j+k] = (uint8_t ) ((ptr[j+dasizeof]-ptr[j])&255); k += dasizeof; if (k > LZWSIZE-dasizeof) { leng = (short)compress(lzwbuf4,k,lzwbuf5); k = 0; fwrite(&leng,2,1,fil); fwrite(lzwbuf5,(int32_t )leng,1,fil); } ptr += dasizeof; } if (k > 0) { leng = (short)compress(lzwbuf4,k,lzwbuf5); fwrite(&leng,2,1,fil); fwrite(lzwbuf5,(int32_t )leng,1,fil); } lzwbuflock[0] = lzwbuflock[1] = lzwbuflock[2] = lzwbuflock[3] = lzwbuflock[4] = 1; } int32_t compress(uint8_t *lzwinbuf, int32_t uncompleng, uint8_t *lzwoutbuf) { int32_t i, addr, newaddr, addrcnt, zx, *longptr; int32_t bytecnt1, bitcnt, numbits, oneupnumbits; short *shortptr; for(i=255;i>=0;i--) { lzwbuf1[i] = (uint8_t ) i; lzwbuf3[i] = (short) ((i+1)&255); } clearbuf((void *) FP_OFF(lzwbuf2),256>>1,0xffffffff); clearbuf((void *) FP_OFF(lzwoutbuf),((uncompleng+15)+3)>>2,0L); addrcnt = 256; bytecnt1 = 0; bitcnt = (4<<3); numbits = 8; oneupnumbits = (1<<8); do { addr = lzwinbuf[bytecnt1]; do { bytecnt1++; if (bytecnt1 == uncompleng) break; if (lzwbuf2[addr] < 0) {lzwbuf2[addr] = (short) addrcnt; break;} newaddr = lzwbuf2[addr]; while (lzwbuf1[newaddr] != lzwinbuf[bytecnt1]) { zx = lzwbuf3[newaddr]; if (zx < 0) {lzwbuf3[newaddr] = (short) addrcnt; break;} newaddr = zx; } if (lzwbuf3[newaddr] == addrcnt) break; addr = newaddr; } while (addr >= 0); lzwbuf1[addrcnt] = lzwinbuf[bytecnt1]; lzwbuf2[addrcnt] = -1; lzwbuf3[addrcnt] = -1; longptr = (int32_t *)&lzwoutbuf[bitcnt>>3]; longptr[0] |= (addr<<(bitcnt&7)); bitcnt += numbits; if ((addr&((oneupnumbits>>1)-1)) > ((addrcnt-1)&((oneupnumbits>>1)-1))) bitcnt--; addrcnt++; if (addrcnt > oneupnumbits) { numbits++; oneupnumbits <<= 1; } } while ((bytecnt1 < uncompleng) && (bitcnt < (uncompleng<<3))); longptr = (int32_t *)&lzwoutbuf[bitcnt>>3]; longptr[0] |= (addr<<(bitcnt&7)); bitcnt += numbits; if ((addr&((oneupnumbits>>1)-1)) > ((addrcnt-1)&((oneupnumbits>>1)-1))) bitcnt--; shortptr = (short *)lzwoutbuf; shortptr[0] = (short)uncompleng; if (((bitcnt+7)>>3) < uncompleng) { shortptr[1] = (short)addrcnt; return((bitcnt+7)>>3); } shortptr[1] = (short)0; for(i=0;i<uncompleng;i++) lzwoutbuf[i+4] = lzwinbuf[i]; return(uncompleng+4); } int32_t uncompress(uint8_t *lzwinbuf, int32_t compleng, uint8_t *lzwoutbuf) { int32_t strtot, currstr, numbits, oneupnumbits; int32_t i, dat, leng, bitcnt, outbytecnt, *longptr; short *shortptr; shortptr = (short *)lzwinbuf; strtot = (int32_t )shortptr[1]; if (strtot == 0) { copybuf((void *)(FP_OFF(lzwinbuf)+4),(void *)(FP_OFF(lzwoutbuf)),((compleng-4)+3)>>2); return((int32_t )shortptr[0]); /* uncompleng */ } for(i=255;i>=0;i--) { lzwbuf2[i] = (short) i; lzwbuf3[i] = (short) i; } currstr = 256; bitcnt = (4<<3); outbytecnt = 0; numbits = 8; oneupnumbits = (1<<8); do { longptr = (int32_t *)&lzwinbuf[bitcnt>>3]; dat = ((longptr[0]>>(bitcnt&7)) & (oneupnumbits-1)); bitcnt += numbits; if ((dat&((oneupnumbits>>1)-1)) > ((currstr-1)&((oneupnumbits>>1)-1))) { dat &= ((oneupnumbits>>1)-1); bitcnt--; } lzwbuf3[currstr] = (short) dat; for(leng=0;dat>=256;leng++,dat=lzwbuf3[dat]) lzwbuf1[leng] = (uint8_t ) lzwbuf2[dat]; lzwoutbuf[outbytecnt++] = (uint8_t ) dat; for(i=leng-1;i>=0;i--) lzwoutbuf[outbytecnt++] = lzwbuf1[i]; lzwbuf2[currstr-1] = (short) dat; lzwbuf2[currstr] = (short) dat; currstr++; if (currstr > oneupnumbits) { numbits++; oneupnumbits <<= 1; } } while (currstr < strtot); return((int32_t )shortptr[0]); /* uncompleng */ } int SafeFileExists ( const char * _filename ); int32_t TCkopen4load(const char *filename, int readfromGRP) { char fullfilename[512]; int32_t result = 0; if(game_dir[0] != '\0' && !readfromGRP) { sprintf(fullfilename, "%s\\%s", game_dir, filename); if (!SafeFileExists(fullfilename)) // try root sprintf(fullfilename, "%s", filename); } else { sprintf(fullfilename, "%s", filename); } result = kopen4load(fullfilename, readfromGRP); if(g_CV_DebugFileAccess != 0) { printf("FILE ACCESS: [read] File: (%s) Result: %d, clock: %d\n", fullfilename, result, totalclock); } return result; }