Mercurial > repos > blastem
view gdb_remote.c @ 2201:2f8984ff5c85
Prevent Mode 5 selection when not emulating the Genesis VDP
author | Michael Pavone <pavone@retrodev.com> |
---|---|
date | Mon, 22 Aug 2022 20:43:19 -0700 |
parents | 8554751f17b5 |
children | 3350b3c8faa8 |
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/* Copyright 2013 Michael Pavone This file is part of BlastEm. BlastEm is free software distributed under the terms of the GNU General Public License version 3 or greater. See COPYING for full license text. */ #ifdef _WIN32 #define WINVER 0x501 #include <winsock2.h> #include <ws2tcpip.h> int gdb_sock; #define GDB_IN_FD gdb_sock #define GDB_OUT_FD gdb_sock #define GDB_READ(fd, buf, bufsize) recv(fd, buf, bufsize, 0) #define GDB_WRITE(fd, buf, bufsize) send(fd, buf, bufsize, 0) #else #define GDB_IN_FD STDIN_FILENO #define GDB_OUT_FD STDOUT_FILENO #define GDB_READ read #define GDB_WRITE write #include <unistd.h> #endif #include "gdb_remote.h" #include "68kinst.h" #include "debug.h" #include "util.h" #include <fcntl.h> #include <stddef.h> #include <stdlib.h> #include <stdio.h> #include <string.h> #define INITIAL_BUFFER_SIZE (16*1024) #ifdef DO_DEBUG_PRINT #define dfprintf fprintf #else #define dfprintf #endif char * buf = NULL; char * curbuf = NULL; char * end = NULL; size_t bufsize; int cont = 0; int expect_break_response=0; uint32_t resume_pc; void hex_32(uint32_t num, char * out) { for (int32_t shift = 28; shift >= 0; shift -= 4) { uint8_t nibble = num >> shift & 0xF; *(out++) = nibble > 9 ? nibble - 0xA + 'A' : nibble + '0'; } } void hex_16(uint16_t num, char * out) { for (int16_t shift = 14; shift >= 0; shift -= 4) { uint8_t nibble = num >> shift & 0xF; *(out++) = nibble > 9 ? nibble - 0xA + 'A' : nibble + '0'; } } void hex_8(uint8_t num, char * out) { uint8_t nibble = num >> 4; *(out++) = nibble > 9 ? nibble - 0xA + 'A' : nibble + '0'; nibble = num & 0xF; *out = nibble > 9 ? nibble - 0xA + 'A' : nibble + '0'; } void gdb_calc_checksum(char * command, char *out) { uint8_t checksum = 0; while (*command) { checksum += *(command++); } hex_8(checksum, out); } void write_or_die(int fd, const void *buf, size_t count) { if (GDB_WRITE(fd, buf, count) < count) { fatal_error("Error writing to stdout\n"); } } void gdb_send_command(char * command) { char end[3]; write_or_die(GDB_OUT_FD, "$", 1); write_or_die(GDB_OUT_FD, command, strlen(command)); end[0] = '#'; gdb_calc_checksum(command, end+1); write_or_die(GDB_OUT_FD, end, 3); dfprintf(stderr, "Sent $%s#%c%c\n", command, end[1], end[2]); } uint32_t calc_status(m68k_context * context) { uint32_t status = context->status << 3; for (int i = 0; i < 5; i++) { status <<= 1; status |= context->flags[i]; } return status; } void update_status(m68k_context * context, uint16_t value) { context->status = value >> 8; for (int i = 4; i >= 0; i--) { context->flags[i] = value & 1; value >>= 1; } } static uint8_t m68k_read_byte(m68k_context *context, uint32_t address) { //TODO: share this implementation with builtin debugger return read_byte(address, (void **)context->mem_pointers, &context->options->gen, context); } void m68k_write_byte(m68k_context * context, uint32_t address, uint8_t value) { genesis_context *gen = context->system; //TODO: Use generated read/write functions so that memory map is properly respected uint16_t * word = get_native_pointer(address & 0xFFFFFFFE, (void **)context->mem_pointers, &context->options->gen); if (word) { if (address & 1) { *word = (*word & 0xFF00) | value; } else { *word = (*word & 0xFF) | value << 8; } //TODO: Deal with this more generally once m68k_handle_code_write can handle it if (address >= 0xE00000) { m68k_handle_code_write(address, context); } return; } if (address >= 0xA00000 && address < 0xA04000) { gen->zram[address & 0x1FFF] = value; genesis_context * gen = context->system; #if !defined(NO_Z80) && !defined(NEW_CORE) z80_handle_code_write(address & 0x1FFF, gen->z80); #endif return; } else { return; } } void gdb_run_command(m68k_context * context, uint32_t pc, char * command) { char send_buf[512]; dfprintf(stderr, "Received command %s\n", command); debug_root *root = find_root(context); if (!root) { fatal_error("Could not find debug root for CPU %p\n", context); } switch(*command) { case 'c': if (*(command+1) != 0) { //TODO: implement resuming at an arbitrary address goto not_impl; } cont = 1; expect_break_response = 1; break; case 's': { if (*(command+1) != 0) { //TODO: implement resuming at an arbitrary address goto not_impl; } m68kinst inst; genesis_context *gen = context->system; uint32_t after = m68k_decode(m68k_instruction_fetch, context, &inst, pc & 0xFFFFFF); if (inst.op == M68K_RTS) { after = (read_dma_value(context->aregs[7]/2) << 16) | read_dma_value(context->aregs[7]/2 + 1); } else if (inst.op == M68K_RTE || inst.op == M68K_RTR) { after = (read_dma_value((context->aregs[7]+2)/2) << 16) | read_dma_value((context->aregs[7]+2)/2 + 1); } else if(m68k_is_branch(&inst)) { if (inst.op == M68K_BCC && inst.extra.cond != COND_TRUE) { root->branch_f = after; root->branch_t = m68k_branch_target(&inst, context->dregs, context->aregs) & 0xFFFFFF; insert_breakpoint(context, root->branch_t, gdb_debug_enter); } else if(inst.op == M68K_DBCC && inst.extra.cond != COND_FALSE) { root->branch_t = after; root->branch_f = m68k_branch_target(&inst, context->dregs, context->aregs) & 0xFFFFFF; insert_breakpoint(context, root->branch_f, gdb_debug_enter); } else { after = m68k_branch_target(&inst, context->dregs, context->aregs) & 0xFFFFFF; } } insert_breakpoint(context, after, gdb_debug_enter); cont = 1; expect_break_response = 1; break; } case 'H': if (command[1] == 'g' || command[1] == 'c') {; //no thread suport, just acknowledge gdb_send_command("OK"); } else { goto not_impl; } break; case 'Z': { uint8_t type = command[1]; if (type < '2') { uint32_t address = strtoul(command+3, NULL, 16); insert_breakpoint(context, address, gdb_debug_enter); bp_def *new_bp = malloc(sizeof(bp_def)); new_bp->next = root->breakpoints; new_bp->address = address; new_bp->index = root->bp_index++; root->breakpoints = new_bp; gdb_send_command("OK"); } else { //watchpoints are not currently supported gdb_send_command(""); } break; } case 'z': { uint8_t type = command[1]; if (type < '2') { uint32_t address = strtoul(command+3, NULL, 16); remove_breakpoint(context, address); bp_def **found = find_breakpoint(&root->breakpoints, address); if (*found) { bp_def * to_remove = *found; *found = to_remove->next; free(to_remove); } gdb_send_command("OK"); } else { //watchpoints are not currently supported gdb_send_command(""); } break; } case 'g': { char * cur = send_buf; for (int i = 0; i < 8; i++) { hex_32(context->dregs[i], cur); cur += 8; } for (int i = 0; i < 8; i++) { hex_32(context->aregs[i], cur); cur += 8; } hex_32(calc_status(context), cur); cur += 8; hex_32(pc, cur); cur += 8; *cur = 0; gdb_send_command(send_buf); break; } case 'm': { char * rest; uint32_t address = strtoul(command+1, &rest, 16); uint32_t size = strtoul(rest+1, NULL, 16); if (size > (sizeof(send_buf)-1)/2) { size = (sizeof(send_buf)-1)/2; } char *cur = send_buf; while (size) { hex_8(m68k_read_byte(context, address), cur); cur += 2; address++; size--; } *cur = 0; gdb_send_command(send_buf); break; } case 'M': { char * rest; uint32_t address = strtoul(command+1, &rest, 16); uint32_t size = strtoul(rest+1, &rest, 16); char *cur = rest+1; while (size) { char tmp[3]; tmp[0] = *(cur++); tmp[1] = *(cur++); tmp[2] = 0; m68k_write_byte(context, address, strtoul(tmp, NULL, 16)); address++; size--; } gdb_send_command("OK"); break; } case 'X': //binary transfers aren't supported currently as I don't feel like dealing with the escaping gdb_send_command(""); break; case 'p': { unsigned long reg = strtoul(command+1, NULL, 16); if (reg < 8) { hex_32(context->dregs[reg], send_buf); } else if (reg < 16) { hex_32(context->aregs[reg-8], send_buf); } else if (reg == 16) { hex_32(calc_status(context), send_buf); } else if (reg == 17) { hex_32(pc, send_buf); } else { send_buf[0] = 0; } send_buf[8] = 0; gdb_send_command(send_buf); break; } case 'P': { char *after = NULL; unsigned long reg = strtoul(command+1, &after, 16); uint32_t value = strtoul(after+1, NULL, 16); if (reg < 8) { context->dregs[reg] = value; } else if (reg < 16) { context->aregs[reg-8] = value; } else if (reg == 16) { update_status(context, value); } else { //supporting updates to PC is going to be a pain gdb_send_command("E01"); break; } gdb_send_command("OK"); break; } case 'q': if (!memcmp("Supported", command+1, strlen("Supported"))) { sprintf(send_buf, "PacketSize=%X", (int)bufsize); gdb_send_command(send_buf); } else if (!memcmp("Attached", command+1, strlen("Attached"))) { //not really meaningful for us, but saying we spawned a new process //is probably closest to the truth gdb_send_command("0"); } else if (!memcmp("Offsets", command+1, strlen("Offsets"))) { //no relocations, so offsets are all 0 gdb_send_command("Text=0;Data=0;Bss=0"); } else if (!memcmp("Symbol", command+1, strlen("Symbol"))) { gdb_send_command(""); } else if (!memcmp("TStatus", command+1, strlen("TStatus"))) { //TODO: actual tracepoint support gdb_send_command("T0;tnotrun:0"); } else if (!memcmp("TfV", command+1, strlen("TfV")) || !memcmp("TfP", command+1, strlen("TfP"))) { //TODO: actual tracepoint support gdb_send_command(""); } else if (command[1] == 'C') { //we only support a single thread currently, so send 1 gdb_send_command("QC1"); } else if (!strcmp("fThreadInfo", command + 1)) { //we only support a single thread currently, so send 1 gdb_send_command("m1"); } else if (!strcmp("sThreadInfo", command + 1)) { gdb_send_command("l"); } else if (!memcmp("ThreadExtraInfo", command+1, strlen("ThreadExtraInfo"))) { gdb_send_command(""); } else if (command[1] == 'P') { gdb_send_command(""); } else { goto not_impl; } break; case 'v': if (!memcmp("Cont?", command+1, strlen("Cont?"))) { gdb_send_command("vCont;c;C;s;S"); } else if (!strcmp("MustReplyEmpty", command + 1)) { gdb_send_command(""); } else if (!memcmp("Cont;", command+1, strlen("Cont;"))) { switch (*(command + 1 + strlen("Cont;"))) { case 'c': case 'C': //might be interesting to have continue with signal fire a //trap exception or something, but for no we'll treat it as //a normal continue cont = 1; expect_break_response = 1; break; case 's': case 'S': { m68kinst inst; genesis_context *gen = context->system; uint32_t after = m68k_decode(m68k_instruction_fetch, context, &inst, pc & 0xFFFFFF); if (inst.op == M68K_RTS) { after = (read_dma_value(context->aregs[7]/2) << 16) | read_dma_value(context->aregs[7]/2 + 1); } else if (inst.op == M68K_RTE || inst.op == M68K_RTR) { after = (read_dma_value((context->aregs[7]+2)/2) << 16) | read_dma_value((context->aregs[7]+2)/2 + 1); } else if(m68k_is_branch(&inst)) { if (inst.op == M68K_BCC && inst.extra.cond != COND_TRUE) { root->branch_f = after; root->branch_t = m68k_branch_target(&inst, context->dregs, context->aregs) & 0xFFFFFF; insert_breakpoint(context, root->branch_t, gdb_debug_enter); } else if(inst.op == M68K_DBCC && inst.extra.cond != COND_FALSE) { root->branch_t = after; root->branch_f = m68k_branch_target(&inst, context->dregs, context->aregs) & 0xFFFFFF; insert_breakpoint(context, root->branch_f, gdb_debug_enter); } else { after = m68k_branch_target(&inst, context->dregs, context->aregs) & 0xFFFFFF; } } insert_breakpoint(context, after, gdb_debug_enter); cont = 1; expect_break_response = 1; break; } default: goto not_impl; } } else { goto not_impl; } break; case '?': gdb_send_command("S05"); break; default: goto not_impl; } return; not_impl: fatal_error("Command %s is not implemented, exiting...\n", command); } void gdb_debug_enter(m68k_context * context, uint32_t pc) { dfprintf(stderr, "Entered debugger at address %X\n", pc); if (expect_break_response) { gdb_send_command("S05"); expect_break_response = 0; } debug_root *root = find_root(context); if (!root) { fatal_error("Could not find debug root for CPU %p\n", context); } if ((pc & 0xFFFFFF) == root->branch_t) { bp_def ** f_bp = find_breakpoint(&root->breakpoints, root->branch_f); if (!*f_bp) { remove_breakpoint(context, root->branch_f); } root->branch_t = root->branch_f = 0; } else if((pc & 0xFFFFFF) == root->branch_f) { bp_def ** t_bp = find_breakpoint(&root->breakpoints, root->branch_t); if (!*t_bp) { remove_breakpoint(context, root->branch_t); } root->branch_t = root->branch_f = 0; } //Check if this is a user set breakpoint, or just a temporary one bp_def ** this_bp = find_breakpoint(&root->breakpoints, pc & 0xFFFFFF); if (!*this_bp) { remove_breakpoint(context, pc & 0xFFFFFF); } resume_pc = pc; cont = 0; uint8_t partial = 0; while(!cont) { if (!curbuf) { int numread = GDB_READ(GDB_IN_FD, buf, bufsize); if (numread < 0) { fatal_error("Failed to read on GDB input file descriptor\n"); } dfprintf(stderr, "read %d bytes\n", numread); curbuf = buf; end = buf + numread; } else if (partial) { if (curbuf != buf) { memmove(curbuf, buf, end-curbuf); end -= curbuf - buf; } int numread = GDB_READ(GDB_IN_FD, end, bufsize - (end-buf)); end += numread; curbuf = buf; } for (; curbuf < end; curbuf++) { if (*curbuf == '$') { curbuf++; char * start = curbuf; while (curbuf < end && *curbuf != '#') { curbuf++; } if (*curbuf == '#') { //check to make sure we've received the checksum bytes if (end-curbuf >= 2) { //TODO: verify checksum //Null terminate payload *curbuf = 0; //send acknowledgement if (GDB_WRITE(GDB_OUT_FD, "+", 1) < 1) { fatal_error("Error writing to stdout\n"); } gdb_run_command(context, pc, start); curbuf += 2; } } else { curbuf--; partial = 1; break; } } else { dfprintf(stderr, "Ignoring character %c\n", *curbuf); } } if (curbuf == end) { curbuf = NULL; } } } void gdb_remote_init(void) { buf = malloc(INITIAL_BUFFER_SIZE); curbuf = NULL; bufsize = INITIAL_BUFFER_SIZE; #ifdef _WIN32 socket_init(); struct addrinfo request, *result; memset(&request, 0, sizeof(request)); request.ai_family = AF_INET; request.ai_socktype = SOCK_STREAM; request.ai_flags = AI_PASSIVE; getaddrinfo("localhost", "1234", &request, &result); int listen_sock = socket(result->ai_family, result->ai_socktype, result->ai_protocol); if (listen_sock < 0) { fatal_error("Failed to open GDB remote debugging socket"); } if (bind(listen_sock, result->ai_addr, result->ai_addrlen) < 0) { fatal_error("Failed to bind GDB remote debugging socket"); } freeaddrinfo(result); if (listen(listen_sock, 1) < 0) { fatal_error("Failed to listen on GDB remote debugging socket"); } gdb_sock = accept(listen_sock, NULL, NULL); if (gdb_sock < 0) { fatal_error("accept returned an error while listening on GDB remote debugging socket"); } socket_close(listen_sock); #else disable_stdout_messages(); #endif }