FreeCalypso > hg > freecalypso-tools
view rvinterf/tmsh/tmcore.c @ 300:0cfb2e3aeda4
started documenting c1xx-calextr
author | Mychaela Falconia <falcon@freecalypso.org> |
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date | Sun, 19 Nov 2017 21:45:12 +0000 |
parents | 2159f260ed13 |
children | 4c7f3778dc24 |
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/* * In this module we are going to implement commands which send requests * to ETM_CORE and the handling of responses from that target module. */ #include <sys/types.h> #include <stdio.h> #include <string.h> #include <strings.h> #include <stdlib.h> #include "pktmux.h" #include "limits.h" #include "localtypes.h" #include "etm.h" #include "exitcodes.h" extern u_char rvi_msg[]; extern int rvi_msg_len; static void rw8_response() { char buf[MAX_PKT_FROM_TARGET*3+80], *dp; int num, i; if (rvi_msg[3]) { print_etm_pkt_raw("rw8 error"); return; } num = rvi_msg_len - 7; if (!num) { async_msg_output("w8 OK"); return; } strcpy(buf, "r8:"); dp = buf + 3; for (i = 0; i < num; i++) { sprintf(dp, " %02X", rvi_msg[i+6]); dp += 3; } async_msg_output(buf); } static void rw16_response() { char buf[MAX_PKT_FROM_TARGET*3+80], *dp; int num, i, d, off; if (rvi_msg[3]) { print_etm_pkt_raw("rw16 error"); return; } num = rvi_msg_len - 7; if (!num) { async_msg_output("w16 OK"); return; } if (num & 1) { print_etm_pkt_raw("rw16 malformed resp"); return; } num >>= 1; strcpy(buf, "r16:"); dp = buf + 4; off = 6; for (i = 0; i < num; i++) { d = rvi_msg[off] | rvi_msg[off+1] << 8; off += 2; sprintf(dp, " %04X", d); dp += 5; } async_msg_output(buf); } static void rw32_response() { char buf[MAX_PKT_FROM_TARGET*3+80], *dp; int num, i, d, off; if (rvi_msg[3]) { print_etm_pkt_raw("rw32 error"); return; } num = rvi_msg_len - 7; if (!num) { async_msg_output("w32 OK"); return; } if (num & 3) { print_etm_pkt_raw("rw32 malformed resp"); return; } num >>= 2; strcpy(buf, "r32:"); dp = buf + 4; off = 6; for (i = 0; i < num; i++) { d = rvi_msg[off] | rvi_msg[off+1] << 8 | rvi_msg[off+2] << 16 | rvi_msg[off+3] << 24; off += 4; sprintf(dp, " %08X", d); dp += 9; } async_msg_output(buf); } static void dieid_response() { char buf[MAX_PKT_FROM_TARGET*3+80], *dp; int num, i; if (rvi_msg[3]) { print_etm_pkt_raw("dieid error"); return; } num = rvi_msg_len - 6; strcpy(buf, "dieid resp:"); dp = buf + 11; for (i = 0; i < num; i++) { sprintf(dp, " %02X", rvi_msg[i+5]); dp += 3; } async_msg_output(buf); } static void echo_response() { if (rvi_msg[3]) print_etm_pkt_raw("echo error"); else print_etm_pkt_raw("echo resp"); } static void version_response() { char buf[80]; if (rvi_msg[3]) { print_etm_pkt_raw("version error"); return; } if (rvi_msg_len != 10) { print_etm_pkt_raw("version malformed resp"); return; } sprintf(buf, "version resp: %02X%02X%02X%02X", rvi_msg[8], rvi_msg[7], rvi_msg[6], rvi_msg[5]); async_msg_output(buf); } void tmcore_msg_rx() { switch (rvi_msg[4]) { case TMCORE_OPC_MEM: if (rvi_msg_len < 7) goto unknown; switch (rvi_msg[5]) { case 0x00: case 0x04: rw32_response(); return; case 0x01: rw8_response(); return; case 0x02: rw16_response(); return; default: goto unknown; } case TMCORE_OPC_ECHO: echo_response(); return; case TMCORE_OPC_VERSION: version_response(); return; case TMCORE_OPC_CODEC_RD: abbr_response(); return; case TMCORE_OPC_CODEC_WR: abbw_response(); return; case TMCORE_OPC_DIEID: dieid_response(); return; default: unknown: print_etm_pkt_raw("ETM_CORE resp"); } } cmd_r8(argc, argv) char **argv; { u32 addr; int count; u_char cmdpkt[10]; addr = strtoul(argv[1], 0, 16); if (argv[2]) count = strtoul(argv[2], 0, 0); else count = 1; if (count < 1 || count > 253) { printf("error: count argument outside valid range\n"); return(ERROR_USAGE); } cmdpkt[1] = ETM_CORE; cmdpkt[2] = TMCORE_OPC_MEM; cmdpkt[3] = 0x01; cmdpkt[4] = count; cmdpkt[5] = addr; cmdpkt[6] = addr >> 8; cmdpkt[7] = addr >> 16; cmdpkt[8] = addr >> 24; send_etm_cmd(cmdpkt, 8); return(0); } cmd_r16(argc, argv) char **argv; { u32 addr; int count; u_char cmdpkt[10]; addr = strtoul(argv[1], 0, 16); if (argv[2]) count = strtoul(argv[2], 0, 0); else count = 1; if (addr & 1) { printf("error: address not aligned\n"); return(ERROR_USAGE); } if (count < 1 || count > 126) { printf("error: count argument outside valid range\n"); return(ERROR_USAGE); } cmdpkt[1] = ETM_CORE; cmdpkt[2] = TMCORE_OPC_MEM; cmdpkt[3] = 0x02; cmdpkt[4] = count; cmdpkt[5] = addr; cmdpkt[6] = addr >> 8; cmdpkt[7] = addr >> 16; cmdpkt[8] = addr >> 24; send_etm_cmd(cmdpkt, 8); return(0); } cmd_r32(argc, argv) char **argv; { u32 addr; int count; u_char cmdpkt[10]; addr = strtoul(argv[1], 0, 16); if (argv[2]) count = strtoul(argv[2], 0, 0); else count = 1; if (addr & 3) { printf("error: address not aligned\n"); return(ERROR_USAGE); } if (count < 1 || count > 63) { printf("error: count argument outside valid range\n"); return(ERROR_USAGE); } cmdpkt[1] = ETM_CORE; cmdpkt[2] = TMCORE_OPC_MEM; cmdpkt[3] = 0x04; cmdpkt[4] = count; cmdpkt[5] = addr; cmdpkt[6] = addr >> 8; cmdpkt[7] = addr >> 16; cmdpkt[8] = addr >> 24; send_etm_cmd(cmdpkt, 8); return(0); } cmd_w8(argc, argv) char **argv; { u32 addr, v; u_char cmdpkt[MAX_PKT_TO_TARGET]; int di; char **ap; addr = strtoul(argv[1], 0, 16); cmdpkt[1] = ETM_CORE; cmdpkt[2] = TMCORE_OPC_MEM; cmdpkt[3] = 0x11; cmdpkt[4] = argc - 2; cmdpkt[5] = addr; cmdpkt[6] = addr >> 8; cmdpkt[7] = addr >> 16; cmdpkt[8] = addr >> 24; di = 9; for (ap = argv + 2; *ap; ap++) { v = strtoul(*ap, 0, 16); cmdpkt[di++] = v; } send_etm_cmd(cmdpkt, di - 1); return(0); } cmd_w16(argc, argv) char **argv; { u32 addr, v; u_char cmdpkt[MAX_PKT_TO_TARGET]; int di; char **ap; addr = strtoul(argv[1], 0, 16); if (addr & 1) { printf("error: address not aligned\n"); return(ERROR_USAGE); } cmdpkt[1] = ETM_CORE; cmdpkt[2] = TMCORE_OPC_MEM; cmdpkt[3] = 0x12; cmdpkt[4] = argc - 2; cmdpkt[5] = addr; cmdpkt[6] = addr >> 8; cmdpkt[7] = addr >> 16; cmdpkt[8] = addr >> 24; di = 9; for (ap = argv + 2; *ap; ap++) { v = strtoul(*ap, 0, 16); cmdpkt[di++] = v; cmdpkt[di++] = v >> 8; } send_etm_cmd(cmdpkt, di - 1); return(0); } cmd_w32(argc, argv) char **argv; { u32 addr, v; u_char cmdpkt[MAX_PKT_TO_TARGET]; int di; char **ap; addr = strtoul(argv[1], 0, 16); if (addr & 3) { printf("error: address not aligned\n"); return(ERROR_USAGE); } cmdpkt[1] = ETM_CORE; cmdpkt[2] = TMCORE_OPC_MEM; cmdpkt[3] = 0x14; cmdpkt[4] = argc - 2; cmdpkt[5] = addr; cmdpkt[6] = addr >> 8; cmdpkt[7] = addr >> 16; cmdpkt[8] = addr >> 24; di = 9; for (ap = argv + 2; *ap; ap++) { v = strtoul(*ap, 0, 16); cmdpkt[di++] = v; cmdpkt[di++] = v >> 8; cmdpkt[di++] = v >> 16; cmdpkt[di++] = v >> 24; } send_etm_cmd(cmdpkt, di - 1); return(0); } cmd_dieid(argc, argv) char **argv; { u_char cmdpkt[4]; cmdpkt[1] = ETM_CORE; cmdpkt[2] = TMCORE_OPC_DIEID; send_etm_cmd(cmdpkt, 2); return(0); } cmd_ping(argc, argv) char **argv; { int delay, size; u_char cmdpkt[8]; if (argc > 1) { delay = strtoul(argv[1], 0, 0); if (delay > 65535) { printf("error: ping delay argument too big\n"); return(ERROR_USAGE); } } else delay = 0; if (argc > 2) { size = strtoul(argv[2], 0, 0); if (size > 240) { printf("error: ping size argument too big\n"); return(ERROR_USAGE); } } else size = 1; cmdpkt[1] = ETM_CORE; cmdpkt[2] = TMCORE_OPC_ECHO; cmdpkt[3] = delay; cmdpkt[4] = delay >> 8; cmdpkt[5] = size; cmdpkt[6] = size >> 8; send_etm_cmd(cmdpkt, 6); return(0); } cmd_tgtreset(argc, argv) char **argv; { u_char cmdpkt[4]; cmdpkt[1] = ETM_CORE; cmdpkt[2] = TMCORE_OPC_RESET; send_etm_cmd(cmdpkt, 2); return(0); } cmd_version(argc, argv) char **argv; { u32 arg; u_char cmdpkt[8]; arg = strtoul(argv[1], 0, 16); cmdpkt[1] = ETM_CORE; cmdpkt[2] = TMCORE_OPC_VERSION; cmdpkt[3] = arg; cmdpkt[4] = arg >> 8; cmdpkt[5] = arg >> 16; cmdpkt[6] = arg >> 24; send_etm_cmd(cmdpkt, 6); return(0); }