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[/] [or1k/] [trunk/] [insight/] [utils/] [amd-udi/] [mondfe/] [xcmd.c] - Rev 1765
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static char _[] = "@(#)xcmd.c 5.20 93/07/30 16:39:02, Srini, AMD"; /****************************************************************************** * Copyright 1991 Advanced Micro Devices, Inc. * * This software is the property of Advanced Micro Devices, Inc (AMD) which * specifically grants the user the right to modify, use and distribute this * software provided this notice is not removed or altered. All other rights * are reserved by AMD. * * AMD MAKES NO WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, WITH REGARD TO THIS * SOFTWARE. IN NO EVENT SHALL AMD BE LIABLE FOR INCIDENTAL OR CONSEQUENTIAL * DAMAGES IN CONNECTION WITH OR ARISING FROM THE FURNISHING, PERFORMANCE, OR * USE OF THIS SOFTWARE. * * So that all may benefit from your experience, please report any problems * or suggestions about this software to the 29K Technical Support Center at * 800-29-29-AMD (800-292-9263) in the USA, or 0800-89-1131 in the UK, or * 0031-11-1129 in Japan, toll free. The direct dial number is 512-462-4118. * * Advanced Micro Devices, Inc. * 29K Support Products * Mail Stop 573 * 5900 E. Ben White Blvd. * Austin, TX 78741 * 800-292-9263 ***************************************************************************** * Engineer: Srini Subramanian. ***************************************************************************** ** This code implements a subset of the MON29K-like "x" ** commands. ***************************************************************************** */ #include <stdio.h> #include <ctype.h> #include <memory.h> #include "main.h" #include "macros.h" #include "miniint.h" #include "memspcs.h" #include "error.h" #ifdef MSDOS #include <stdlib.h> #include <string.h> #else #include <string.h> #endif INT32 xp_cmd PARAMS((char **, int)); INT32 xc_cmd PARAMS((char **, int)); int get_addr_29k PARAMS((char *, struct addr_29k_t *)); int addr_29k_ok PARAMS((struct addr_29k_t *)); int print_addr_29k PARAMS((INT32, ADDR32)); int get_word PARAMS((char *buffer, INT32 *data_word)); void convert32 PARAMS(( BYTE *byte)); void dasm_instr PARAMS((ADDR32, struct instr_t *)); /* Variable definitions */ struct xp_cmd_t { INT32 vtb; INT32 ops; INT32 cps; INT32 cfg; INT32 cha; INT32 chd; INT32 chc; INT32 rbp; INT32 tmc; INT32 tmr; INT32 pc0; INT32 pc1; INT32 pc2; INT32 mmuc; INT32 lru; }; #define XP_CMD_SZ 15 * sizeof (INT32) /* #define XP_CMD_SZ sizeof(struct xp_cmd_t) */ /* ** The function below is used to implement the MON29K-like ** "x" commands. the function below, x_cmd() is called ** in the main command loop parser of the monitor. The ** parameters passed to this function are: ** ** token - This is an array of pointers to strings. Each string ** referenced by this array is a "token" of the user's ** input, translated to lower case. ** ** token_count - This is the number of tokens in "token". ** ** This function then calls the specific "x" commands, ** such as "xp" or "xc". */ INT32 x_cmd(token, token_count) char *token[]; int token_count; { INT32 result; if (strcmp(token[0], "xp") == 0) result = xp_cmd(token, token_count); else if (strcmp(token[0], "xc") == 0) result = xc_cmd(token, token_count); else result = EMSYNTAX; return (result); } /* end xcmd() */ /* ** This command is used to print out formatted information ** about protected special registers. The format is borrowed ** from MON29K, and produces a full screen of data, giving ** bit fields of the various registers. */ INT32 xp_cmd(token, token_count) char *token[]; int token_count; { INT32 byte_count; int prl; INT32 vtb; INT32 ops; INT32 cps; INT32 cfg; INT32 cha; INT32 chd; INT32 chc; INT32 rbp; INT32 tmc; INT32 tmr; INT32 pc0; INT32 pc1; INT32 pc2; INT32 mmuc; INT32 lru; INT32 retval; INT32 bytes_ret; INT32 hostendian; union { struct xp_cmd_t xp_cmd; char read_buffer[XP_CMD_SZ]; } xp_cmd_val; char prtbuf[256]; if ((strcmp(token[0], "xp") != 0) || (token_count != 1)) return (EMSYNTAX); /* ** Get data */ byte_count = XP_CMD_SZ; /* Will the data overflow the message buffer? Done in TIP */ hostendian = FALSE; if ((retval = Mini_read_req (SPECIAL_REG, (ADDR32) 0, byte_count/4, (INT16) 4, /* size */ &bytes_ret, xp_cmd_val.read_buffer, hostendian)) != SUCCESS) { return(FAILURE); }; /* The following is executed if SUCCESSful */ vtb = xp_cmd_val.xp_cmd.vtb; ops = xp_cmd_val.xp_cmd.ops; cps = xp_cmd_val.xp_cmd.cps; cfg = xp_cmd_val.xp_cmd.cfg; cha = xp_cmd_val.xp_cmd.cha; chd = xp_cmd_val.xp_cmd.chd; chc = xp_cmd_val.xp_cmd.chc; rbp = xp_cmd_val.xp_cmd.rbp; tmc = xp_cmd_val.xp_cmd.tmc; tmr = xp_cmd_val.xp_cmd.tmr; pc0 = xp_cmd_val.xp_cmd.pc0; pc1 = xp_cmd_val.xp_cmd.pc1; pc2 = xp_cmd_val.xp_cmd.pc2; mmuc = xp_cmd_val.xp_cmd.mmuc; lru = xp_cmd_val.xp_cmd.lru; if (host_config.host_endian != host_config.target_endian) { convert32((BYTE *)&vtb); convert32((BYTE *)&ops); convert32((BYTE *)&cps); convert32((BYTE *)&cfg); convert32((BYTE *)&cha); convert32((BYTE *)&chd); convert32((BYTE *)&chc); convert32((BYTE *)&rbp); convert32((BYTE *)&tmc); convert32((BYTE *)&tmr); convert32((BYTE *)&pc0); convert32((BYTE *)&pc1); convert32((BYTE *)&pc2); convert32((BYTE *)&mmuc); convert32((BYTE *)&lru); } /* Print CPS */ sprintf(&prtbuf[0], "\n"); sprintf(&prtbuf[strlen(prtbuf)], " TD MM CA IP TE TP TU FZ LK RE WM PD PI SM IM DI DA\n"); if (io_config.echo_mode == (INT32) TRUE) fprintf (io_config.echo_file, "%s", &prtbuf[0]); fprintf (stderr, "%s", &prtbuf[0]); sprintf(&prtbuf[0], "CPS:"); sprintf(&prtbuf[strlen(prtbuf)], " %3x", ((cps >> 17) & 0x01)); /* td */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((cps >> 16) & 0x01)); /* mm */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((cps >> 15) & 0x01)); /* ca */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((cps >> 14) & 0x01)); /* ip */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((cps >> 13) & 0x01)); /* te */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((cps >> 12) & 0x01)); /* tp */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((cps >> 11) & 0x01)); /* tu */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((cps >> 10) & 0x01)); /* fz */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((cps >> 9) & 0x01)); /* lk */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((cps >> 8) & 0x01)); /* re */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((cps >> 7) & 0x01)); /* wm */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((cps >> 6) & 0x01)); /* pd */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((cps >> 5) & 0x01)); /* pi */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((cps >> 4) & 0x01)); /* sm */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((cps >> 2) & 0x03)); /* im */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((cps >> 1) & 0x01)); /* di */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((cps >> 0) & 0x01)); /* da */ sprintf(&prtbuf[strlen(prtbuf)], "\n"); if (io_config.echo_mode == (INT32) TRUE) fprintf (io_config.echo_file, "%s", &prtbuf[0]); fprintf (stderr, "%s", &prtbuf[0]); /* Print OPS */ sprintf(&prtbuf[0], "OPS:"); sprintf(&prtbuf[strlen(prtbuf)], " %3x", ((ops >> 17) & 0x01)); /* td */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((ops >> 16) & 0x01)); /* mm */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((ops >> 15) & 0x01)); /* ca */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((ops >> 14) & 0x01)); /* ip */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((ops >> 13) & 0x01)); /* te */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((ops >> 12) & 0x01)); /* tp */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((ops >> 11) & 0x01)); /* tu */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((ops >> 10) & 0x01)); /* fz */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((ops >> 9) & 0x01)); /* lk */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((ops >> 8) & 0x01)); /* re */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((ops >> 7) & 0x01)); /* wm */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((ops >> 6) & 0x01)); /* pd */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((ops >> 5) & 0x01)); /* pi */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((ops >> 4) & 0x01)); /* sm */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((ops >> 2) & 0x03)); /* im */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((ops >> 1) & 0x01)); /* di */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((ops >> 0) & 0x01)); /* da */ sprintf(&prtbuf[strlen(prtbuf)], "\n"); sprintf(&prtbuf[strlen(prtbuf)], "\n"); if (io_config.echo_mode == (INT32) TRUE) fprintf (io_config.echo_file, "%s", &prtbuf[0]); fprintf (stderr, "%s", &prtbuf[0]); /* Get Processor Revision Number */ prl = (int) ((cfg >> 24) & 0xff); /* Print VAB / CFG */ if (PROCESSOR(prl) == PROC_AM29030) { sprintf(&prtbuf[0], " VAB CFG: PRL PMB IL ID VF BO\n"); sprintf(&prtbuf[strlen(prtbuf)], "%08lx ", vtb); sprintf(&prtbuf[strlen(prtbuf)], "%02lx", ((cfg >> 24) & 0xff)); /* prl */ sprintf(&prtbuf[strlen(prtbuf)], "%4x", ((cfg >> 16) & 0x03)); /* pmb */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((cfg >> 9) & 0x03)); /* il */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((cfg >> 8) & 0x01)); /* id */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((cfg >> 4) & 0x01)); /* vf */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((cfg >> 2) & 0x01)); /* bo */ sprintf(&prtbuf[strlen(prtbuf)], "\n"); sprintf(&prtbuf[strlen(prtbuf)], "\n"); } else { /* Am29000 or Am29050 */ sprintf(&prtbuf[0], " VAB CFG: PRL DW VF RV BO CP CD\n"); sprintf(&prtbuf[strlen(prtbuf)], "%08lx ", vtb); sprintf(&prtbuf[strlen(prtbuf)], "%02lx", ((cfg >> 24) & 0xff)); /* prl */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((cfg >> 5) & 0x01)); /* dw */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((cfg >> 4) & 0x01)); /* vf */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((cfg >> 3) & 0x01)); /* rv */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((cfg >> 2) & 0x01)); /* bo */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((cfg >> 1) & 0x01)); /* cp */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((cfg >> 0) & 0x01)); /* cd */ sprintf(&prtbuf[strlen(prtbuf)], "\n"); sprintf(&prtbuf[strlen(prtbuf)], "\n"); } if (io_config.echo_mode == (INT32) TRUE) fprintf (io_config.echo_file, "%s", &prtbuf[0]); fprintf (stderr, "%s", &prtbuf[0]); /* Print CHA / CHD / CHC */ sprintf(&prtbuf[0], " CHA CHD CHC: CE CNTL CR LS ML ST LA TF TR NN CV\n"); if (io_config.echo_mode == (INT32) TRUE) fprintf (io_config.echo_file, "%s", &prtbuf[0]); fprintf (stderr, "%s", &prtbuf[0]); sprintf(&prtbuf[0], "%08lx ", cha); /* cha */ sprintf(&prtbuf[strlen(prtbuf)], "%08lx ", chd); /* chd */ sprintf(&prtbuf[strlen(prtbuf)], "%2x", ((chc >> 31) & 0x01)); /* ce */ sprintf(&prtbuf[strlen(prtbuf)], "%5x", ((chc >> 24) & 0xff)); /* cntl */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((chc >> 16) & 0xff)); /* cr */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((chc >> 15) & 0x01)); /* ls */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((chc >> 14) & 0x01)); /* ml */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((chc >> 13) & 0x01)); /* st */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((chc >> 12) & 0x01)); /* la */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((chc >> 10) & 0x01)); /* tf */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((chc >> 2) & 0xff)); /* tr */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((chc >> 1) & 0x01)); /* nn */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((chc >> 0) & 0x01)); /* cv */ sprintf(&prtbuf[strlen(prtbuf)], "\n"); sprintf(&prtbuf[strlen(prtbuf)], "\n"); if (io_config.echo_mode == (INT32) TRUE) fprintf (io_config.echo_file, "%s", &prtbuf[0]); fprintf (stderr, "%s", &prtbuf[0]); /* Print RBP */ sprintf(&prtbuf[0], "RBP: BF BE BD BC BB BA B9 B8 B7 B6 B5 B4 B3 B2 B1 B0\n"); if (io_config.echo_mode == (INT32) TRUE) fprintf (io_config.echo_file, "%s", &prtbuf[0]); fprintf (stderr, "%s", &prtbuf[0]); sprintf(&prtbuf[0], " %3x", ((rbp >> 15) & 0x01)); sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((rbp >> 14) & 0x01)); sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((rbp >> 13) & 0x01)); sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((rbp >> 12) & 0x01)); sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((rbp >> 11) & 0x01)); sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((rbp >> 10) & 0x01)); sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((rbp >> 9) & 0x01)); sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((rbp >> 8) & 0x01)); sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((rbp >> 7) & 0x01)); sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((rbp >> 6) & 0x01)); sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((rbp >> 5) & 0x01)); sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((rbp >> 4) & 0x01)); sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((rbp >> 3) & 0x01)); sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((rbp >> 2) & 0x01)); sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((rbp >> 1) & 0x01)); sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((rbp >> 0) & 0x01)); sprintf(&prtbuf[strlen(prtbuf)], "\n"); sprintf(&prtbuf[strlen(prtbuf)], "\n"); if (io_config.echo_mode == (INT32) TRUE) fprintf (io_config.echo_file, "%s", &prtbuf[0]); fprintf (stderr, "%s", &prtbuf[0]); /* Print TMC / TMR / PC0 / PC1 / PC2 */ sprintf(&prtbuf[0], " TCV TR: OV IN IE TRV PC0 PC1 PC2\n"); if (io_config.echo_mode == (INT32) TRUE) fprintf (io_config.echo_file, "%s", &prtbuf[0]); fprintf (stderr, "%s", &prtbuf[0]); sprintf(&prtbuf[0], "%06lx", (tmc & 0x00ffffff)); /* tcv */ sprintf(&prtbuf[strlen(prtbuf)], "%5x", ((tmr >> 26) & 0x01)); /* ov */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((tmr >> 25) & 0x01)); /* in */ sprintf(&prtbuf[strlen(prtbuf)], "%3x", ((tmr >> 24) & 0x01)); /* ie */ sprintf(&prtbuf[strlen(prtbuf)], " %06lx", (tmr & 0x00ffffff)); /* trv */ sprintf(&prtbuf[strlen(prtbuf)], " %08lx", pc0); /* pc0 */ sprintf(&prtbuf[strlen(prtbuf)], " %08lx", pc1); /* pc1 */ sprintf(&prtbuf[strlen(prtbuf)], " %08lx", pc2); /* pc2 */ sprintf(&prtbuf[strlen(prtbuf)], "\n"); sprintf(&prtbuf[strlen(prtbuf)], "\n"); if (io_config.echo_mode == (INT32) TRUE) fprintf (io_config.echo_file, "%s", &prtbuf[0]); fprintf (stderr, "%s", &prtbuf[0]); /* Print MMUC / LRU */ sprintf(&prtbuf[0], "MMU: PS PID LRU\n"); if (io_config.echo_mode == (INT32) TRUE) fprintf (io_config.echo_file, "%s", &prtbuf[0]); fprintf (stderr, "%s", &prtbuf[0]); sprintf(&prtbuf[0], " %02x", ((mmuc >> 8) & 0x03)); /* ps */ sprintf(&prtbuf[strlen(prtbuf)], " %02x", (mmuc & 0xff)); /* pid */ sprintf(&prtbuf[strlen(prtbuf)], " %02x", (lru & 0xff)); /* lru */ sprintf(&prtbuf[strlen(prtbuf)], "\n"); sprintf(&prtbuf[strlen(prtbuf)], "\n"); if (io_config.echo_mode == (INT32) TRUE) fprintf (io_config.echo_file, "%s", &prtbuf[0]); fprintf (stderr, "%s", &prtbuf[0]); return (0); } /* end xp_cmd() */ /* ** This command is used to examine the contents of the cache ** in the Am29030. First set 0 is printed, starting with the ** tag, followed by a disassembly of four instructions in ** the set. Set 1 for the line follows similarly. ** ** The data comes in from the READ_ACK message in the following ** order: ** ** tag (data[0-3] (set 0) ** instr1 (data[4-7] ** instr1 (data[8-11] ** instr1 (data[12-15] ** instr1 (data[16-19] ** ** tag (data[20-23] (set 1) ** instr1 (data[24-27] ** instr1 (data[28-31] ** instr1 (data[32-35] ** instr1 (data[36-39] */ INT32 xc_cmd(token, token_count) char *token[]; int token_count; { static INT32 memory_space=I_CACHE; static ADDR32 cache_line=0; static INT32 byte_count=(10*sizeof(INST32)); static INT32 count=1; ADDR32 address; INT32 i; int j; int set; int index; int result; struct instr_t instr; INT32 cache_line_start; INT32 cache_line_end; INT32 retval; INT32 bytes_ret; INT32 host_endian; BYTE read_buffer[10*sizeof(INST32)]; char prtbuf[256]; /* Is it an 'xc' command? */ if (strcmp(token[0], "xc") != 0) return (EMSYNTAX); /* ** Parse parameters */ if (token_count == 1) { cache_line = cache_line + count; } else if (token_count == 2) { result = get_word(token[1], &cache_line_start); if (result != 0) return (EMSYNTAX); if ((cache_line_start < 0) || (cache_line_start >255)) return (EMBADADDR); cache_line = cache_line_start; } else if (token_count == 3) { /* Get first cache line to be dumped */ result = get_word(token[1], &cache_line_start); if (result != 0) return (EMSYNTAX); if ((cache_line_start < 0) || (cache_line_start > 255)) return (EMBADADDR); /* Get last cache line to be dumped */ result = get_word(token[2], &cache_line_end); if (result != 0) return (EMSYNTAX); if ((cache_line_end < 0) || (cache_line_end > 255)) return (EMBADADDR); if (cache_line_start > cache_line_end) return (EMBADADDR); cache_line = cache_line_start; count = (cache_line_end - cache_line_start) + 1; } else /* Too many args */ return (EMSYNTAX); i = 0; while (i < count) { host_endian = FALSE; if ((retval = Mini_read_req(memory_space, (cache_line + i), byte_count/4, (INT16) 4, /* size */ &bytes_ret, read_buffer, host_endian)) != SUCCESS) { return(FAILURE); }; /* The following is executed if SUCCESSful */ for (set=0; set<2; set++) { /* Print out formatted address tag and status information */ index = (set * 20); sprintf(&prtbuf[0], "\n"); sprintf(&prtbuf[strlen(prtbuf)], "Cache line 0x%lx, set %d.\n", (int) (cache_line+i), set); sprintf(&prtbuf[strlen(prtbuf)], "\n"); if (io_config.echo_mode == (INT32) TRUE) fprintf (io_config.echo_file, "%s", &prtbuf[0]); fprintf (stderr, "%s", &prtbuf[0]); sprintf(&prtbuf[0], "IATAG V P US\n"); if (io_config.echo_mode == (INT32) TRUE) fprintf (io_config.echo_file, "%s", &prtbuf[0]); fprintf (stderr, "%s", &prtbuf[0]); sprintf(&prtbuf[0], "%02x%02x%1x %1x %1x %1x\n", read_buffer[index], read_buffer[index + 1], ((read_buffer[index + 2] >> 4) & 0x0f), ((read_buffer[index + 3] >> 2) & 0x01), ((read_buffer[index + 3] >> 1) & 0x01), (read_buffer[index + 3] & 0x01)); sprintf(&prtbuf[strlen(prtbuf)], "\n"); if (io_config.echo_mode == (INT32) TRUE) fprintf (io_config.echo_file, "%s", &prtbuf[0]); fprintf (stderr, "%s", &prtbuf[0]); /* Address = IATAG + line_number + <16 byte adddress> */ address = ((read_buffer[index] << 24) | (read_buffer[index + 1] << 16) | (read_buffer[index + 2] << 8) | ((cache_line+i) << 4)); /* Disassemble four words */ for (j=0; j<4; j=j+1) { index = (set * 20) + ((j+1) * sizeof(INT32)); instr.op = read_buffer[index]; instr.c = read_buffer[index + 1]; instr.a = read_buffer[index + 2]; instr.b = read_buffer[index + 3]; /* Print address of instruction (in hex) */ address = (address & 0xfffffff0); /* Clear low four bits */ address = (address | (j << 2)); fprintf(stderr, "%08lx ", address); if (io_config.echo_mode == (INT32) TRUE) fprintf(io_config.echo_file, "%08lx ", address); /* Print instruction (in hex) */ if (io_config.echo_mode == (INT32) TRUE) fprintf(io_config.echo_file, "%02x%02x%02x%02x ", instr.op, instr.c, instr.a, instr.b); fprintf(stderr, "%02x%02x%02x%02x ", instr.op, instr.c, instr.a, instr.b); /* Disassemble instruction */ dasm_instr(address, &instr); fprintf(stderr, "\n"); if (io_config.echo_mode == (INT32) TRUE) fprintf(io_config.echo_file, "\n"); } /* end for(j) */ fprintf(stderr, "\n"); if (io_config.echo_mode == (INT32) TRUE) fprintf(io_config.echo_file, "\n"); } /* end for(set) */ i = i + 1; } /* end while loop */ return (0); } /* end xc_cmd() */