#include #include #include #include #include #include #include #include "../../sxmlc.h" #include "../../user_io.h" #include "../../input.h" #include "../../file_io.h" #include "../../menu.h" #include "../../fpga_io.h" #include "../../lib/md5/md5.h" #include "buffer.h" #include "romutils.h" #define kBigTextSize 1024 struct arc_struct { char md5[kBigTextSize]; char zipname[kBigTextSize]; char partzipname[kBigTextSize]; char partname[kBigTextSize]; char romname[kBigTextSize]; char error_msg[kBigTextSize]; int romindex; int offset; int length; int repeat; int insiderom; int patchaddr; int validrom0; int insidesw; int insideinterleave; int ifrom; int ito; int imap; uint32_t address; uint32_t crc; buffer_data *data; struct MD5Context context; }; static char arcade_error_msg[kBigTextSize] = {}; static char arcade_root[kBigTextSize]; static char mame_root[kBigTextSize]; static sw_struct switches = {}; sw_struct *arcade_sw() { return &switches; } void arcade_sw_send() { if (switches.dip_num) { user_io_set_index(254); user_io_set_download(1); user_io_file_tx_write((uint8_t*)&switches.dip_cur, sizeof(switches.dip_cur)); user_io_set_download(0); } } void arcade_sw_save() { if (switches.dip_saved != switches.dip_cur) { char path[256] = CONFIG_DIR"/dips/"; FileCreatePath(path); strcat(path, switches.name); if (FileSave(path, &switches.dip_cur, sizeof(switches.dip_cur))) { switches.dip_saved = switches.dip_cur; } } } void arcade_sw_load() { char path[256] = "dips/"; strcat(path, switches.name); FileLoadConfig(path, &switches.dip_cur, sizeof(switches.dip_cur)); } static void set_arcade_root(const char *path) { strcpy(arcade_root, path); char *p = strstr(arcade_root, "/_"); if (p) p = strchr(p + 1, '/'); if (p) *p = 0; else strcpy(arcade_root, getRootDir()); printf("arcade_root %s\n", arcade_root); strcpy(mame_root, "mame"); if (findPrefixDir(mame_root, sizeof(mame_root))) { char *p = strrchr(mame_root, '/'); if (p) *p = 0; else mame_root[0] = 0; } else { strcpy(mame_root, arcade_root); } printf("mame_root %s\n", mame_root); } static const char *get_arcade_root(int rbf) { static char path[kBigTextSize]; if (!rbf) strcpy(path, mame_root); else sprintf(path, "%s/cores", arcade_root); return path; } static int unitlen = 0; static int romlen[8] = {}; static int romblkl = 0; static uint8_t* romdata = 0; static uint8_t romindex = 0; static void rom_start(unsigned char index) { romindex = index; if (romdata) free(romdata); romdata = 0; memset(romlen, 0, sizeof(romlen)); romblkl = 0; unitlen = 1; } #define BLKL (1024*1024) static int rom_checksz(int idx, int chunk) { if ((romlen[idx] + chunk) > romblkl) { romblkl += BLKL; romdata = (uint8_t*)realloc(romdata, romblkl); if (!romdata) { romblkl = 0; memset(romlen, 0, sizeof(romlen)); return 0; } } return 1; } static int rom_data(const uint8_t *buf, int chunk, int map, struct MD5Context *md5context) { if (md5context) MD5Update(md5context, buf, chunk); int idx = 0; if (!map) map = 1; for (int i = 0; i> (i * 4)) & 0xF)) break; idx++; } if (idx >= unitlen) return 0; // illegal map if (!rom_checksz(idx, chunk*unitlen)) return 0; while (chunk) { for (int ord = 1; ord <= unitlen; ord++) { for (int i = 0; (i < unitlen && chunk); i++) { if (((map >> (i * 4)) & 0xF) == ord) { *(romdata + romlen[idx] + i) = *buf++; chunk--; } } } romlen[idx] += unitlen; } return 1; } static int rom_file(const char *name, uint32_t crc32, int start, int len, int map, struct MD5Context *md5context) { fileTYPE f = {}; static uint8_t buf[4096]; if (!FileOpenZip(&f, name, crc32)) return 0; if (start) FileSeek(&f, start, SEEK_SET); unsigned long bytes2send = f.size; if (len > 0 && len < (int)bytes2send) bytes2send = len; while (bytes2send) { uint16_t chunk = (bytes2send > sizeof(buf)) ? sizeof(buf) : bytes2send; FileReadAdv(&f, buf, chunk); if (!rom_data(buf, chunk, map, md5context)) { FileClose(&f); return 0; }; bytes2send -= chunk; } FileClose(&f); return 1; } static int rom_patch(const uint8_t *buf, int offset, uint16_t len) { if ((offset + len) > romlen[0]) return 0; memcpy(romdata + offset, buf, len); return 1; } static void send_to_ddr(uint32_t address, void* buf, uint32_t len) { int memfd = open("/dev/mem", O_RDWR | O_SYNC); if (memfd == -1) { printf("Unable to open /dev/mem!\n"); return; } //make sure it's in FPGA address space uint32_t map_addr = 0x20000000 | address; void *base = mmap(0, len, PROT_READ | PROT_WRITE, MAP_SHARED, memfd, map_addr); if (base == (void *)-1) { printf("Unable to mmap (0x%X, %d)!\n", map_addr, len); close(memfd); return; } memcpy(base, buf, len); munmap(base, len); close(memfd); return; } static void rom_finish(int send, uint32_t address) { if (romlen[0] && romdata) { if (send) { // set index byte (0=bios rom, 1-n=OSD entry index) user_io_set_index(romindex); // prepare transmission of new file user_io_set_download(1); uint8_t *data = romdata; int len = romlen[0]; if (address) { send_to_ddr(address, data, len); } else { while (romlen[0] > 0) { uint16_t chunk = (romlen[0] > 4096) ? 4096 : romlen[0]; user_io_file_tx_write(data, chunk); romlen[0] -= chunk; data += chunk; } } // signal end of transmission user_io_set_download(0); printf("file_finish: 0x%X bytes sent to FPGA\n\n", len); } else { printf("file_finish: discard the ROM\n\n"); } free(romdata); romdata = 0; return; } if (romdata) { free(romdata); romdata = 0; } printf("file_finish: no data, discarded\n\n"); } /* * adapted from https://gist.github.com/xsleonard/7341172 * * hexstr_to_char will take hex strings in two types: * * 00 01 02 * 000102 * 00 01 2 03 * 0001 0203 * * and return an array and a length of binary values * * caller must free string that is returned * * */ unsigned char* hexstr_to_char(const char* hexstr, size_t *out_len) { size_t len = strlen(hexstr); unsigned char* chrs = (unsigned char*)malloc(len + 1); int dest = 0; // point to the beginning of the array const char *ptr = hexstr; while (*ptr) { // check to see if we have a space while (*ptr == '\n' || *ptr == '\r' || *ptr == ' ' || *ptr == ',' || *ptr == '\t' || *ptr == 9 /*horiz tab*/) ptr++; if (*ptr == 0) break; // pull two characters off int val1 = (*ptr % 32 + 9) % 25 * 16; ptr++; /* check to odd numbers of characters*/ if (*ptr == 0) { int val = (ptr[-1] % 32 + 9) % 25; chrs[dest++] = val; break; } int val2 = (*ptr % 32 + 9) % 25; ptr++; chrs[dest++] = val1 + val2; } chrs[dest] = 0; *out_len = dest; /* dest is 0 based, so we don't need to subtract 1*/ return chrs; } /* * xml_send_rom * * This is a callback from the XML parser of the MRA file * * It parses the MRA, and sends commands to send rom parts to the fpga * */ static int xml_send_rom(XMLEvent evt, const XMLNode* node, SXML_CHAR* text, const int n, SAX_Data* sd) { struct arc_struct *arc_info = (struct arc_struct *)sd->user; (void)(sd); switch (evt) { case XML_EVENT_START_DOC: arc_info->insiderom = 0; arc_info->insidesw = 0; break; case XML_EVENT_START_NODE: /* initialization */ // initialize things for each tag (node): buffer_destroy(arc_info->data); arc_info->data = buffer_init(kBigTextSize); arc_info->partname[0] = 0; arc_info->offset = 0; arc_info->length = -1; arc_info->repeat = 1; arc_info->crc = 0; /* on the beginning of a rom tag, we need to reset the state*/ if (!strcasecmp(node->tag, "rom")) { arc_info->insiderom = 1; arc_info->romname[0] = 0; arc_info->romindex = 0; arc_info->md5[0] = 0; arc_info->ifrom = 0; arc_info->ito = 0; arc_info->imap = 0; arc_info->zipname[0] = 0; arc_info->address = 0; arc_info->insideinterleave = 0; MD5Init(&arc_info->context); } if (!strcasecmp(node->tag, "switches")) { arc_info->insidesw = 1; switches.dip_cur = 0; switches.dip_def = 0; switches.dip_num = 0; memset(&switches.dip, 0, sizeof(switches.dip)); } if (!strcasecmp(node->tag, "interleave")) { arc_info->insideinterleave = 1; arc_info->ifrom = 8; // default 8. arc_info->ito = 0; arc_info->imap = 0; } // for each part tag, we clear the partzipname since it is optional and may not appear in the part tag if (!strcasecmp(node->tag, "part")) { arc_info->partzipname[0] = 0; arc_info->imap = 0; } if (!strcasecmp(node->tag, "patch")) arc_info->patchaddr = 0; //printf("XML_EVENT_START_NODE: tag [%s]\n",node->tag); // walk the attributes and save them in the data structure as appropriate for (int i = 0; i < node->n_attributes; i++) { //printf("attribute %d name [%s] value [%s]\n",i,node->attributes[i].name,node->attributes[i].value); if (!strcasecmp(node->attributes[i].name, "zip") && !strcasecmp(node->tag, "rom")) { strcpy(arc_info->zipname, node->attributes[i].value); } if (!strcasecmp(node->attributes[i].name, "name") && !strcasecmp(node->tag, "rom")) { strcpy(arc_info->romname, node->attributes[i].value); } if (!strcasecmp(node->attributes[i].name, "md5") && !strcasecmp(node->tag, "rom")) { strcpy(arc_info->md5, node->attributes[i].value); } if (!strcasecmp(node->attributes[i].name, "index") && !strcasecmp(node->tag, "rom")) { arc_info->romindex = atoi(node->attributes[i].value); } if (!strcasecmp(node->attributes[i].name, "address") && !strcasecmp(node->tag, "rom")) { arc_info->address = strtoul(node->attributes[i].value, NULL, 0); } if (!strcasecmp(node->attributes[i].name, "names") && !strcasecmp(node->tag, "buttons")) { set_ovr_buttons(node->attributes[i].value, 0); } if (!strcasecmp(node->attributes[i].name, "default") && !strcasecmp(node->tag, "buttons")) { set_ovr_buttons(node->attributes[i].value, 1); } /* these only exist if we are inside the rom tag, and in a part tag*/ if (arc_info->insiderom) { if (!strcasecmp(node->attributes[i].name, "input") && !strcasecmp(node->tag, "interleave")) { arc_info->ifrom = strtol(node->attributes[i].value, NULL, 0); } if (!strcasecmp(node->attributes[i].name, "output") && !strcasecmp(node->tag, "interleave")) { arc_info->ito = strtol(node->attributes[i].value, NULL, 0); } if (!strcasecmp(node->attributes[i].name, "zip") && !strcasecmp(node->tag, "part")) { strcpy(arc_info->partzipname, node->attributes[i].value); } if (!strcasecmp(node->attributes[i].name, "name") && !strcasecmp(node->tag, "part")) { strcpy(arc_info->partname, node->attributes[i].value); } if (!strcasecmp(node->attributes[i].name, "offset") && !strcasecmp(node->tag, "part")) { arc_info->offset = strtoul(node->attributes[i].value, NULL, 0); } if (!strcasecmp(node->attributes[i].name, "length") && !strcasecmp(node->tag, "part")) { arc_info->length = strtoul(node->attributes[i].value, NULL, 0); } if (!strcasecmp(node->attributes[i].name, "repeat") && !strcasecmp(node->tag, "part")) { arc_info->repeat = strtoul(node->attributes[i].value, NULL, 0); } if (!strcasecmp(node->attributes[i].name, "crc") && !strcasecmp(node->tag, "part")) { arc_info->crc = strtoul(node->attributes[i].value, NULL, 16); } if (!strcasecmp(node->attributes[i].name, "offset") && !strcasecmp(node->tag, "patch")) { arc_info->patchaddr = strtoul(node->attributes[i].value, NULL, 0); } if (!strcasecmp(node->attributes[i].name, "map") && !strcasecmp(node->tag, "part")) { arc_info->imap = strtoul(node->attributes[i].value, NULL, 16); if (!arc_info->insideinterleave && arc_info->imap) { unitlen = strlen(node->attributes[i].value); if (unitlen > 8) unitlen = 8; for (int i = 1; i < 8; i++) romlen[i] = romlen[0]; } } } if (arc_info->insidesw) { if (!strcasecmp(node->tag, "switches")) { if (!strcasecmp(node->attributes[i].name, "default")) { size_t len = 0; unsigned char* binary = hexstr_to_char(node->attributes[i].value, &len); for (size_t i = 0; i < len; i++) switches.dip_def |= binary[i] << (i * 8); free(binary); } } if (!strcasecmp(node->tag, "dip")) { if (!strcasecmp(node->attributes[i].name, "name")) { snprintf(switches.dip[switches.dip_num].name, sizeof(switches.dip[switches.dip_num].name), node->attributes[i].value); } if (!strcasecmp(node->attributes[i].name, "bits")) { int b = 0, e = 0; int num = sscanf(node->attributes[i].value, "%d,%d", &b, &e); if (num <= 0 || b < 0 || b > 63 || e < 0 || e > 63 || (num == 2 && e < b)) { printf("Invalid bits field: ""%s"" (%d, %d, %d)\n", node->attributes[i].value, num, b, e); } else { uint64_t mask = 1; if (num == 1) e = b; switches.dip[switches.dip_num].start = b; for (int i = 0; i < (e - b); i++) mask = (mask << 1) | 1; switches.dip[switches.dip_num].mask = mask << b; switches.dip[switches.dip_num].size = e - b + 1; } } if (!strcasecmp(node->attributes[i].name, "ids")) { int n = 0; char *val = node->attributes[i].value; while (*val && n < 32) { char *p = strchr(val, ','); size_t len = p ? p - val : strlen(val); size_t sz = len + 1; if (sz > sizeof(switches.dip[0].id[0])) sz = sizeof(switches.dip[0].id[0]); snprintf(switches.dip[switches.dip_num].id[n], sz, val); val += len; if (*val == ',') val++; n++; } switches.dip[switches.dip_num].num = n; } if (!strcasecmp(node->attributes[i].name, "values")) { int n = 0; char *val = node->attributes[i].value; while (*val && n < 32) { char *endp = 0; uint64_t v = strtoul(val, &endp, 0); if (endp <= val) { printf("Invalid values field: ""%s""\n", node->attributes[i].value); break; } switches.dip[switches.dip_num].val[n] = v; val = endp; while (*val && (*val == ' ' || *val == ',')) val++; n++; } switches.dip[switches.dip_num].has_val = 1; } } } } /* at the beginning of each rom - tell the user_io to start a new message */ if (!strcasecmp(node->tag, "rom")) { // clear an error message if we have a second rom0 // this is kind of a problem - you will never see the // error from the first rom0? // if (arc_info->romindex == 0 && strlen(arc_info->zipname)) arc_info->error_msg[0] = 0; rom_start(arc_info->romindex); } if (arc_info->insiderom && !strcasecmp(node->tag, "interleave")) { int valid = 1; if (arc_info->ifrom != 8) valid = 0; if (arc_info->ito < 8 || arc_info->ito>64 || (arc_info->ito & 7)) valid = 0; if (arc_info->ito < arc_info->ifrom) valid = 0; unitlen = arc_info->ifrom ? arc_info->ito / arc_info->ifrom : 1; if (unitlen < 0 && unitlen>8) valid = 0; if (!valid) { printf("Invalid interleave format (from=%d to %d)!\n", arc_info->ifrom, arc_info->ito); arc_info->ifrom = 0; arc_info->ito = 0; arc_info->imap = 0; unitlen = 1; } else { printf("Using interleave: input %d, output %d\n", arc_info->ifrom, arc_info->ito); } for (int i = 1; i < 8; i++) romlen[i] = romlen[0]; } break; case XML_EVENT_TEXT: /* the text node is the data between tags, ie: this text * * the buffer_append is part of a buffer library that will realloc automatically */ buffer_append(arc_info->data, text); //printf("XML_EVENT_TEXT: text [%s]\n",text); break; case XML_EVENT_END_NODE: //printf("XML_EVENT_END_NODE: tag [%s]\n",node->tag ); // At the end of a rom node (when it is closed) we need to calculate hash values and clean up if (!strcasecmp(node->tag, "rom")) { if (arc_info->insiderom) { unsigned char checksum[16]; MD5Final(checksum, &arc_info->context); char hex[40]; char *p = hex; for (int i = 0; i < 16; i++) { sprintf(p, "%02x", (unsigned int)checksum[i]); p += 2; } int checksumsame = !strlen(arc_info->zipname) || !strcasecmp(arc_info->md5, hex); if (checksumsame == 0) { printf("\n*** Checksum mismatch\n"); printf(" md5-orig = %s\n", arc_info->md5); printf(" md5-calc = %s\n\n", hex); } checksumsame |= !strcasecmp(arc_info->md5, "none"); if (checksumsame == 0) { if (!strlen(arc_info->error_msg)) snprintf(arc_info->error_msg, kBigTextSize, "md5 mismatch for rom %d", arc_info->romindex); } else { // this code sets the validerom0 and clears the message // if a rom with index 0 has a correct md5. It supresses // sending any further rom0 messages if (arc_info->romindex == 0) { arc_info->validrom0 = 1; arc_info->error_msg[0] = 0; } } rom_finish(checksumsame, arc_info->address); } arc_info->insiderom = 0; } // At the end of a part node, send the rom part if we are inside a rom tag //int user_io_file_tx_body_filepart(const char *name,int start, int len) if (!strcasecmp(node->tag, "part") && arc_info->insiderom) { // suppress rom0 if we already sent a valid one // this is useful for merged rom sets - if the first one was valid, use it // the second might not be if (arc_info->romindex == 0 && arc_info->validrom0 == 1) break; char fname[kBigTextSize * 2 + 16]; int start, length, repeat; uint32_t crc32; repeat = arc_info->repeat; start = arc_info->offset; crc32 = arc_info->crc; length = 0; if (arc_info->length > 0) length = arc_info->length; //printf("partname[%s]\n",arc_info->partname); //printf("zipname [%s]\n",arc_info->zipname); //printf("offset[%d]\n",arc_info->offset); //printf("length[%d]\n",arc_info->length); //printf("repeat[%d]\n",arc_info->repeat); // if (unitlen == 1 || (arc_info->imap & 0xF)) printf("%6X: ", romlen[0]); else printf(" "); //user_io_file_tx_body_filepart(getFullPath(fname),0,0); if (strlen(arc_info->partname)) { char zipnames_list[kBigTextSize]; if (strlen(arc_info->partzipname)) { strcpy(zipnames_list, arc_info->partzipname); } else { strcpy(zipnames_list, arc_info->zipname); } char *zipname = NULL; char *zipptr = zipnames_list; const char *root = get_arcade_root(0); int result = 0; while ((zipname = strsep(&zipptr, "|")) != NULL) { sprintf(fname, (zipname[0] == '/') ? "%s%s/%s" : "%s/mame/%s/%s", root, zipname, arc_info->partname); if(unitlen>1) printf("file: %s, start=%d, len=%d, map(%d)=%X\n", fname, start, length, unitlen, arc_info->imap); else printf("file: %s, start=%d, len=%d\n", fname, start, length); for (int i = 0; i < repeat; i++) { result = rom_file(fname, crc32, start, length, arc_info->imap, &arc_info->context); // we should check file not found error for the zip if (result == 0) { break; } } if (result) { break; } } if (result == 0) { printf("%s does not exist\n", arc_info->partname); snprintf(arc_info->error_msg, kBigTextSize, "%s\nFile Not Found", arc_info->partname); } } else // we have binary data? { //printf("we have bin.hex data [%s]\n",arc_info->data->content); size_t len = 0; unsigned char* binary = hexstr_to_char(arc_info->data->content, &len); //printf("len %d:\n",len); //for (size_t i=0;iimap, &arc_info->context); free(binary); } } if (!arc_info->insideinterleave) unitlen = 1; } if (!strcasecmp(node->tag, "patch") && arc_info->insiderom) { size_t len = 0; unsigned char* binary = hexstr_to_char(arc_info->data->content, &len); if (binary) { rom_patch(binary, arc_info->patchaddr, len); free(binary); } } if (!strcasecmp(node->tag, "dip")) { int n = switches.dip_num; for (int i = 0; i < switches.dip[n].num; i++) { switches.dip[n].val[i] = ((switches.dip[n].has_val) ? switches.dip[n].val[i] : i) << switches.dip[n].start; } if (switches.dip_num < 63) switches.dip_num++; } if (!strcasecmp(node->tag, "switches")) { arc_info->insidesw = 0; } if (!strcasecmp(node->tag, "interleave")) { arc_info->ifrom = 0; arc_info->ito = 0; arc_info->imap = 0; unitlen = 1; arc_info->insideinterleave = 0; printf("Disable interleave\n"); } break; case XML_EVENT_ERROR: printf("XML parse: %s: ERROR %d\n", text, n); snprintf(arc_info->error_msg, kBigTextSize, "XML parse: %s: ERROR %d\n", text, n); break; default: break; } return true; } static int xml_scan_rbf(XMLEvent evt, const XMLNode* node, SXML_CHAR* text, const int n, SAX_Data* sd) { static int insiderbf = 0; char *rbf = (char *)sd->user; switch (evt) { case XML_EVENT_START_DOC: insiderbf = 0; break; case XML_EVENT_START_NODE: if (!strcasecmp(node->tag, "rbf")) insiderbf = 1; break; case XML_EVENT_TEXT: if (insiderbf) { insiderbf = 0; strncpy(rbf, text, kBigTextSize); } break; case XML_EVENT_END_NODE: insiderbf = 0; break; case XML_EVENT_ERROR: printf("XML parse: %s: ERROR %d\n", text, n); break; default: break; } return true; } static int xml_read_setname(XMLEvent evt, const XMLNode* node, SXML_CHAR* text, const int n, SAX_Data* sd) { (void)(sd); static int insetname = 0; switch (evt) { case XML_EVENT_START_DOC: insetname = 0; break; case XML_EVENT_START_NODE: /* on the beginning of a rom tag, we need to reset the state*/ if (!strcasecmp(node->tag, "setname")) { insetname = 1; } break; case XML_EVENT_TEXT: if(insetname) user_io_name_override(text); break; case XML_EVENT_END_NODE: if (!strcasecmp(node->tag, "setname")) { insetname = 0; return false; } break; case XML_EVENT_ERROR: printf("XML parse: %s: ERROR %d\n", text, n); break; default: break; } return true; } static int arcade_type = 0; int is_arcade() { return arcade_type; } int arcade_send_rom(const char *xml) { arcade_type = 1; const char *p = strrchr(xml, '/'); p = p ? p + 1 : xml; snprintf(switches.name, sizeof(switches.name), p); char *ext = strcasestr(switches.name, ".mra"); if (ext) strcpy(ext, ".dip"); SAX_Callbacks sax; SAX_Callbacks_init(&sax); sax.all_event = xml_send_rom; set_arcade_root(xml); // create the structure we use for the XML parser struct arc_struct arc_info; arc_info.data = buffer_init(kBigTextSize); arc_info.error_msg[0] = 0; arc_info.validrom0 = 0; // parse XMLDoc_parse_file_SAX(xml, &sax, &arc_info); if (arc_info.validrom0 == 0 && strlen(arc_info.error_msg)) { strcpy(arcade_error_msg, arc_info.error_msg); printf("arcade_send_rom: pretty error: [%s]\n", arcade_error_msg); } buffer_destroy(arc_info.data); switches.dip_cur = switches.dip_def; arcade_sw_load(); switches.dip_saved = switches.dip_cur; arcade_sw_send(); return 0; } void arcade_override_name(const char *xml) { SAX_Callbacks sax; SAX_Callbacks_init(&sax); sax.all_event = xml_read_setname; XMLDoc_parse_file_SAX(xml, &sax, NULL); } void arcade_check_error() { if (arcade_error_msg[0] != 0) { printf("ERROR: [%s]\n", arcade_error_msg); Info(arcade_error_msg, 1000 * 30); arcade_error_msg[0] = 0; sleep(3); } } static const char *get_rbf(const char *xml) { static char rbfname[kBigTextSize]; rbfname[0] = 0; SAX_Callbacks sax; SAX_Callbacks_init(&sax); sax.all_event = xml_scan_rbf; XMLDoc_parse_file_SAX(xml, &sax, rbfname); /* once we have the rbfname fragment from the MRA xml file * search the arcade folder for the match */ struct dirent *entry; DIR *dir; const char *dirname = get_arcade_root(1); if (!(dir = opendir(dirname))) { printf("%s directory not found\n", dirname); return NULL; } int len; static char lastfound[256] = {}; while ((entry = readdir(dir)) != NULL) { len = strlen(entry->d_name); if (entry->d_type != DT_DIR && len > 4 && !strcasecmp(entry->d_name+len-4,".rbf")) { static char newstring[kBigTextSize]; //printf("entry name: %s\n",entry->d_name); snprintf(newstring, kBigTextSize, "Arcade-%s", rbfname); len = strlen(newstring); if (!strncasecmp(newstring, entry->d_name, len) && (entry->d_name[len] == '.' || entry->d_name[len] == '_')) { if (!lastfound[0] || strcmp(lastfound, entry->d_name) < 0) { strcpy(lastfound, entry->d_name); } } snprintf(newstring, kBigTextSize, "%s", rbfname); len = strlen(newstring); if (!strncasecmp(newstring, entry->d_name, len) && (entry->d_name[len] == '.' || entry->d_name[len] == '_')) { if (!lastfound[0] || strcmp(lastfound, entry->d_name) < 0) { strcpy(lastfound, entry->d_name); } } } } if (lastfound[0]) sprintf(rbfname, "%s/%s", dirname, lastfound); closedir(dir); return lastfound[0] ? rbfname : NULL; } int arcade_load(const char *xml) { MenuHide(); static char path[kBigTextSize]; strcpy(path, xml); set_arcade_root(path); printf("arcade_load [%s]\n", path); const char *rbf = get_rbf(path); if (rbf) { printf("MRA: %s, RBF: %s\n", path, rbf); fpga_load_rbf(rbf, NULL, path); } else { Info("No rbf found!"); } return 0; }