/* Debug stub for Z80. Copyright (C) 2021 Free Software Foundation, Inc. This file is part of GDB. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . */ /* Usage: 1. Copy this file to project directory 2. Configure it commenting/uncommenting macros below or define DBG_CONFIGURED and all required macros and then include this file to one of your C-source files. 3. Implement getDebugChar() and putDebugChar(), functions must not return until data received or sent. 4. Implement all optional functions used to toggle breakpoints/watchpoints, if supported. Do not write fuctions to toggle software breakpoints if you unsure (GDB will do itself). 5. Implement serial port initialization routine called at program start. 6. Add necessary debugger entry points to your program, for example: .org 0x08 ;RST 8 handler jp _debug_swbreak ... .org 0x66 ;NMI handler jp _debug_nmi ... main_loop: halt call isDbgInterrupt jr z,101$ ld hl, 2 ;EX_SIGINT push hl call _debug_exception 101$: ... 7. Compile file using SDCC (supported ports are: z80, z180, z80n, gbz80 and ez80_z80), do not use --peep-asm option. For example: $ sdcc -mz80 --opt-code-size --max-allocs-per-node 50000 z80-stub.c */ /******************************************************************************\ Configuration \******************************************************************************/ #ifndef DBG_CONFIGURED /* Uncomment this line, if stub size is critical for you */ //#define DBG_MIN_SIZE /* Comment this line out if software breakpoints are unsupported. If you have special function to toggle software breakpoints, then provide here name of these function. Expected prototype: int toggle_swbreak(int set, void *addr); function must return 0 on success. */ //#define DBG_SWBREAK toggle_swbreak #define DBG_SWBREAK /* Define if one of standard RST handlers is used as software breakpoint entry point */ //#define DBG_SWBREAK_RST 0x08 /* if platform supports hardware breakpoints then define following macro by name of function. Fuction must have next prototype: int toggle_hwbreak(int set, void *addr); function must return 0 on success. */ //#define DBG_HWBREAK toggle_hwbreak /* if platform supports hardware watchpoints then define all or some of following macros by names of functions. Fuctions prototypes: int toggle_watch(int set, void *addr, size_t size); // memory write watch int toggle_rwatch(int set, void *addr, size_t size); // memory read watch int toggle_awatch(int set, void *addr, size_t size); // memory access watch function must return 0 on success. */ //#define DBG_WWATCH toggle_watch //#define DBG_RWATCH toggle_rwatch //#define DBG_AWATCH toggle_awatch /* Size of hardware breakpoint. Required to correct PC. */ #define DBG_HWBREAK_SIZE 0 /* Define following macro if you need custom memory read/write routine. Function should return non-zero on success, and zero on failure (for example, write to ROM area). Useful with overlays (bank switching). Do not forget to define: _ovly_table - overlay table _novlys - number of items in _ovly_table or _ovly_region_table - overlay regions table _novly_regions - number of items in _ovly_region_table _ovly_debug_prepare - function is called before overlay mapping _ovly_debug_event - function is called after overlay mapping */ //#define DBG_MEMCPY memcpy /* define dedicated stack size if required */ //#define DBG_STACK_SIZE 256 /* max GDB packet size should be much less that DBG_STACK_SIZE because it will be allocated on stack */ #define DBG_PACKET_SIZE 150 /* Uncomment if required to use trampoline when resuming operation. Useful with dedicated stack when stack pointer do not point to the stack or stack is not writable */ //#define DBG_USE_TRAMPOLINE /* Uncomment following macro to enable debug printing to debugger console */ //#define DBG_PRINT #define DBG_NMI_EX EX_HWBREAK #define DBG_INT_EX EX_SIGINT /* Define following macro to statement, which will be exectuted after entering to stub_main function. Statement should include semicolon. */ //#define DBG_ENTER debug_enter(); /* Define following macro to instruction(s), which will be execute before return control to the program. It is useful when gdb-stub is placed in one of overlays. This procedure must not change any register. On top of stack before invocation will be return address of the program. */ //#define DBG_RESUME jp _restore_bank /* Define following macro to the string containing memory map definition XML. GDB will use it to select proper breakpoint type (HW or SW). */ /*#define DBG_MEMORY_MAP "\ \ \ \ \ \ " */ #endif /* DBG_CONFIGURED */ /******************************************************************************\ Public Interface \******************************************************************************/ /* Enter to debug mode from software or hardware breakpoint. Assume address of next instruction after breakpoint call is on top of stack. Do JP _debug_swbreak or JP _debug_hwbreak from RST handler, for example. */ void debug_swbreak (void); void debug_hwbreak (void); /* Jump to this function from NMI handler. Just replace RETN instruction by JP _debug_nmi Use if NMI detects request to enter to debug mode. */ void debug_nmi (void); /* Jump to this function from INT handler. Just replace EI+RETI instructions by JP _debug_int Use if INT detects request to enter to debug mode. */ void debug_int (void); #define EX_SWBREAK 0 /* sw breakpoint */ #define EX_HWBREAK -1 /* hw breakpoint */ #define EX_WWATCH -2 /* memory write watch */ #define EX_RWATCH -3 /* memory read watch */ #define EX_AWATCH -4 /* memory access watch */ #define EX_SIGINT 2 #define EX_SIGTRAP 5 #define EX_SIGABRT 6 #define EX_SIGBUS 10 #define EX_SIGSEGV 11 /* or any standard *nix signal value */ /* Enter to debug mode (after receiving BREAK from GDB, for example) * Assume: * program PC in (SP+0) * caught signal in (SP+2) * program SP is SP+4 */ void debug_exception (int ex); /* Prints to debugger console. */ void debug_print(const char *str); /******************************************************************************\ Required functions \******************************************************************************/ extern int getDebugChar (void); extern void putDebugChar (int ch); #ifdef DBG_SWBREAK #define DO_EXPAND(VAL) VAL ## 123456 #define EXPAND(VAL) DO_EXPAND(VAL) #if EXPAND(DBG_SWBREAK) != 123456 #define DBG_SWBREAK_PROC DBG_SWBREAK extern int DBG_SWBREAK(int set, void *addr); #endif #undef EXPAND #undef DO_EXPAND #endif /* DBG_SWBREAK */ #ifdef DBG_HWBREAK extern int DBG_HWBREAK(int set, void *addr); #endif #ifdef DBG_MEMCPY extern void* DBG_MEMCPY (void *dest, const void *src, unsigned n); #endif #ifdef DBG_WWATCH extern int DBG_WWATCH(int set, void *addr, unsigned size); #endif #ifdef DBG_RWATCH extern int DBG_RWATCH(int set, void *addr, unsigned size); #endif #ifdef DBG_AWATCH extern int DBG_AWATCH(int set, void *addr, unsigned size); #endif /******************************************************************************\ IMPLEMENTATION \******************************************************************************/ #include #ifndef NULL # define NULL (void*)0 #endif typedef unsigned char byte; typedef unsigned short word; /* CPU state */ #ifdef __SDCC_ez80_adl # define REG_SIZE 3 #else # define REG_SIZE 2 #endif /* __SDCC_ez80_adl */ #define R_AF (0*REG_SIZE) #define R_BC (1*REG_SIZE) #define R_DE (2*REG_SIZE) #define R_HL (3*REG_SIZE) #define R_SP (4*REG_SIZE) #define R_PC (5*REG_SIZE) #ifndef __SDCC_gbz80 #define R_IX (6*REG_SIZE) #define R_IY (7*REG_SIZE) #define R_AF_ (8*REG_SIZE) #define R_BC_ (9*REG_SIZE) #define R_DE_ (10*REG_SIZE) #define R_HL_ (11*REG_SIZE) #define R_IR (12*REG_SIZE) #ifdef __SDCC_ez80_adl #define R_SPS (13*REG_SIZE) #define NUMREGBYTES (14*REG_SIZE) #else #define NUMREGBYTES (13*REG_SIZE) #endif /* __SDCC_ez80_adl */ #else #define NUMREGBYTES (6*REG_SIZE) #define FASTCALL #endif /*__SDCC_gbz80 */ static byte state[NUMREGBYTES]; #if DBG_PACKET_SIZE < (NUMREGBYTES*2+5) #error "Too small DBG_PACKET_SIZE" #endif #ifndef FASTCALL #define FASTCALL __z88dk_fastcall #endif /* dedicated stack */ #ifdef DBG_STACK_SIZE #define LOAD_SP ld sp, #_stack + DBG_STACK_SIZE static char stack[DBG_STACK_SIZE]; #else #undef DBG_USE_TRAMPOLINE #define LOAD_SP #endif #ifndef DBG_ENTER #define DBG_ENTER #endif #ifndef DBG_RESUME #define DBG_RESUME ret #endif static signed char sigval; static void stub_main (int sigval, int pc_adj); static char high_hex (byte v) FASTCALL; static char low_hex (byte v) FASTCALL; static char put_packet_info (const char *buffer) FASTCALL; static void save_cpu_state (void); static void rest_cpu_state (void); /******************************************************************************/ #ifdef DBG_SWBREAK #ifdef DBG_SWBREAK_RST #define DBG_SWBREAK_SIZE 1 #else #define DBG_SWBREAK_SIZE 3 #endif void debug_swbreak (void) __naked { __asm ld (#_state + R_SP), sp LOAD_SP call _save_cpu_state ld hl, #-DBG_SWBREAK_SIZE push hl ld hl, #EX_SWBREAK push hl call _stub_main .globl _break_handler #ifdef DBG_SWBREAK_RST _break_handler = DBG_SWBREAK_RST #else _break_handler = _debug_swbreak #endif __endasm; } #endif /* DBG_SWBREAK */ /******************************************************************************/ #ifdef DBG_HWBREAK #ifndef DBG_HWBREAK_SIZE #define DBG_HWBREAK_SIZE 0 #endif /* DBG_HWBREAK_SIZE */ void debug_hwbreak (void) __naked { __asm ld (#_state + R_SP), sp LOAD_SP call _save_cpu_state ld hl, #-DBG_HWBREAK_SIZE push hl ld hl, #EX_HWBREAK push hl call _stub_main __endasm; } #endif /* DBG_HWBREAK_SET */ /******************************************************************************/ void debug_exception (int ex) __naked { __asm ld (#_state + R_SP), sp LOAD_SP call _save_cpu_state ld hl, #0 push hl #ifdef __SDCC_gbz80 ld hl, #_state + R_SP ld a, (hl+) ld h, (hl) ld l, a #else ld hl, (#_state + R_SP) #endif inc hl inc hl ld e, (hl) inc hl ld d, (hl) push de call _stub_main __endasm; (void)ex; } /******************************************************************************/ #ifndef __SDCC_gbz80 void debug_nmi(void) __naked { __asm ld (#_state + R_SP), sp LOAD_SP call _save_cpu_state ld hl, #0 ;pc_adj push hl ld hl, #DBG_NMI_EX push hl ld hl, #_stub_main push hl push hl retn __endasm; } #endif /******************************************************************************/ void debug_int(void) __naked { __asm ld (#_state + R_SP), sp LOAD_SP call _save_cpu_state ld hl, #0 ;pc_adj push hl ld hl, #DBG_INT_EX push hl ld hl, #_stub_main push hl push hl ei reti __endasm; } /******************************************************************************/ #ifdef DBG_PRINT void debug_print(const char *str) { putDebugChar ('$'); putDebugChar ('O'); char csum = 'O'; for (; *str != '\0'; ) { char c = high_hex (*str); csum += c; putDebugChar (c); c = low_hex (*str++); csum += c; putDebugChar (c); } putDebugChar ('#'); putDebugChar (high_hex (csum)); putDebugChar (low_hex (csum)); } #endif /* DBG_PRINT */ /******************************************************************************/ static void store_pc_sp (int pc_adj) FASTCALL; #define get_reg_value(mem) (*(void* const*)(mem)) #define set_reg_value(mem,val) do { (*(void**)(mem) = (val)); } while (0) static char* byte2hex(char *buf, byte val); static int hex2int (const char **buf) FASTCALL; static char* int2hex (char *buf, int v); static void get_packet (char *buffer); static void put_packet (const char *buffer); static char process (char *buffer) FASTCALL; static void rest_cpu_state (void); static void stub_main (int ex, int pc_adj) { char buffer[DBG_PACKET_SIZE+1]; sigval = (signed char)ex; store_pc_sp (pc_adj); DBG_ENTER /* after starting gdb_stub must always return stop reason */ *buffer = '?'; for (; process (buffer);) { put_packet (buffer); get_packet (buffer); } put_packet (buffer); rest_cpu_state (); } static void get_packet (char *buffer) { byte csum; char ch; char *p; byte esc; #if DBG_PACKET_SIZE <= 256 byte count; /* it is OK to use up to 256 here */ #else unsigned count; #endif for (;; putDebugChar ('-')) { /* wait for packet start character */ while (getDebugChar () != '$'); retry: csum = 0; esc = 0; p = buffer; count = DBG_PACKET_SIZE; do { ch = getDebugChar (); switch (ch) { case '$': goto retry; case '#': goto finish; case '}': esc = 0x20; break; default: *p++ = ch ^ esc; esc = 0; --count; } csum += ch; } while (count != 0); finish: *p = '\0'; if (ch != '#') /* packet is too large */ continue; ch = getDebugChar (); if (ch != high_hex (csum)) continue; ch = getDebugChar (); if (ch != low_hex (csum)) continue; break; } putDebugChar ('+'); } static void put_packet (const char *buffer) { /* $#. */ for (;;) { putDebugChar ('$'); char checksum = put_packet_info (buffer); putDebugChar ('#'); putDebugChar (high_hex(checksum)); putDebugChar (low_hex(checksum)); for (;;) { char c = getDebugChar (); switch (c) { case '+': return; case '-': break; default: putDebugChar (c); continue; } break; } } } static char put_packet_info (const char *src) FASTCALL { char ch; char checksum = 0; for (;;) { ch = *src++; if (ch == '\0') break; if (ch == '}' || ch == '*' || ch == '#' || ch == '$') { /* escape special characters */ putDebugChar ('}'); checksum += '}'; ch ^= 0x20; } putDebugChar (ch); checksum += ch; } return checksum; } static void store_pc_sp (int pc_adj) FASTCALL { byte *sp = get_reg_value (&state[R_SP]); byte *pc = get_reg_value (sp); pc += pc_adj; set_reg_value (&state[R_PC], pc); set_reg_value (&state[R_SP], sp + REG_SIZE); } static char *mem2hex (char *buf, const byte *mem, unsigned bytes); static char *hex2mem (byte *mem, const char *buf, unsigned bytes); /* Command processors. Takes pointer to buffer (begins from command symbol), modifies buffer, returns: -1 - empty response (ignore), 0 - success, positive: error code. */ #ifdef DBG_MIN_SIZE static signed char process_question (char *p) FASTCALL { signed char sig; *p++ = 'S'; sig = sigval; if (sig <= 0) sig = EX_SIGTRAP; p = byte2hex (p, (byte)sig); *p = '\0'; return 0; } #else /* DBG_MIN_SIZE */ static char *format_reg_value (char *p, unsigned reg_num, const byte *value); static signed char process_question (char *p) FASTCALL { signed char sig; *p++ = 'T'; sig = sigval; if (sig <= 0) sig = EX_SIGTRAP; p = byte2hex (p, (byte)sig); p = format_reg_value(p, R_AF/REG_SIZE, &state[R_AF]); p = format_reg_value(p, R_SP/REG_SIZE, &state[R_SP]); p = format_reg_value(p, R_PC/REG_SIZE, &state[R_PC]); #if defined(DBG_SWBREAK_PROC) || defined(DBG_HWBREAK) || defined(DBG_WWATCH) || defined(DBG_RWATCH) || defined(DBG_AWATCH) const char *reason; unsigned addr = 0; switch (sigval) { #ifdef DBG_SWBREAK_PROC case EX_SWBREAK: reason = "swbreak"; break; #endif #ifdef DBG_HWBREAK case EX_HWBREAK: reason = "hwbreak"; break; #endif #ifdef DBG_WWATCH case EX_WWATCH: reason = "watch"; addr = 1; break; #endif #ifdef DBG_RWATCH case EX_RWATCH: reason = "rwatch"; addr = 1; break; #endif #ifdef DBG_AWATCH case EX_AWATCH: reason = "awatch"; addr = 1; break; #endif default: goto finish; } while ((*p++ = *reason++)) ; --p; *p++ = ':'; if (addr != 0) p = int2hex(p, addr); *p++ = ';'; finish: #endif /* DBG_HWBREAK, DBG_WWATCH, DBG_RWATCH, DBG_AWATCH */ *p++ = '\0'; return 0; } #endif /* DBG_MINSIZE */ #define STRING2(x) #x #define STRING1(x) STRING2(x) #define STRING(x) STRING1(x) #ifdef DBG_MEMORY_MAP static void read_memory_map (char *buffer, unsigned offset, unsigned length); #endif static signed char process_q (char *buffer) FASTCALL { char *p; if (memcmp (buffer + 1, "Supported", 9) == 0) { memcpy (buffer, "PacketSize=", 11); p = int2hex (&buffer[11], DBG_PACKET_SIZE); #ifndef DBG_MIN_SIZE #ifdef DBG_SWBREAK_PROC memcpy (p, ";swbreak+", 9); p += 9; #endif #ifdef DBG_HWBREAK memcpy (p, ";hwbreak+", 9); p += 9; #endif #endif /* DBG_MIN_SIZE */ #ifdef DBG_MEMORY_MAP memcpy (p, ";qXfer:memory-map:read+", 23); p += 23; #endif *p = '\0'; return 0; } #ifdef DBG_MEMORY_MAP if (memcmp (buffer + 1, "Xfer:memory-map:read:", 21) == 0) { p = strchr (buffer + 1 + 21, ':'); if (p == NULL) return 1; ++p; unsigned offset = hex2int (&p); if (*p++ != ',') return 2; unsigned length = hex2int (&p); if (length == 0) return 3; if (length > DBG_PACKET_SIZE) return 4; read_memory_map (buffer, offset, length); return 0; } #endif #ifndef DBG_MIN_SIZE if (memcmp (&buffer[1], "Attached", 9) == 0) { /* Just report that GDB attached to existing process if it is not applicable for you, then send patches */ memcpy(buffer, "1", 2); return 0; } #endif /* DBG_MIN_SIZE */ *buffer = '\0'; return -1; } static signed char process_g (char *buffer) FASTCALL { mem2hex (buffer, state, NUMREGBYTES); return 0; } static signed char process_G (char *buffer) FASTCALL { hex2mem (state, &buffer[1], NUMREGBYTES); /* OK response */ *buffer = '\0'; return 0; } static signed char process_m (char *buffer) FASTCALL {/* mAA..AA,LLLL Read LLLL bytes at address AA..AA */ char *p = &buffer[1]; byte *addr = (void*)hex2int(&p); if (*p++ != ',') return 1; unsigned len = (unsigned)hex2int(&p); if (len == 0) return 2; if (len > DBG_PACKET_SIZE/2) return 3; p = buffer; #ifdef DBG_MEMCPY do { byte tmp[16]; unsigned tlen = sizeof(tmp); if (tlen > len) tlen = len; if (!DBG_MEMCPY(tmp, addr, tlen)) return 4; p = mem2hex (p, tmp, tlen); addr += tlen; len -= tlen; } while (len); #else p = mem2hex (p, addr, len); #endif return 0; } static signed char process_M (char *buffer) FASTCALL {/* MAA..AA,LLLL: Write LLLL bytes at address AA.AA return OK */ char *p = &buffer[1]; byte *addr = (void*)hex2int(&p); if (*p != ',') return 1; ++p; unsigned len = (unsigned)hex2int(&p); if (*p++ != ':') return 2; if (len == 0) goto end; if (len*2 + (p - buffer) > DBG_PACKET_SIZE) return 3; #ifdef DBG_MEMCPY do { byte tmp[16]; unsigned tlen = sizeof(tmp); if (tlen > len) tlen = len; p = hex2mem (tmp, p, tlen); if (!DBG_MEMCPY(addr, tmp, tlen)) return 4; addr += tlen; len -= tlen; } while (len); #else hex2mem (addr, p, len); #endif end: /* OK response */ *buffer = '\0'; return 0; } #ifndef DBG_MIN_SIZE static signed char process_X (char *buffer) FASTCALL {/* XAA..AA,LLLL: Write LLLL binary bytes at address AA.AA return OK */ char *p = &buffer[1]; byte *addr = (void*)hex2int(&p); if (*p != ',') return 1; ++p; unsigned len = (unsigned)hex2int(&p); if (*p++ != ':') return 2; if (len == 0) goto end; if (len + (p - buffer) > DBG_PACKET_SIZE) return 3; #ifdef DBG_MEMCPY if (!DBG_MEMCPY(addr, p, len)) return 4; #else memcpy (addr, p, len); #endif end: /* OK response */ *buffer = '\0'; return 0; } #else /* DBG_MIN_SIZE */ static signed char process_X (char *buffer) FASTCALL { (void)buffer; return -1; } #endif /* DBG_MIN_SIZE */ static signed char process_c (char *buffer) FASTCALL {/* 'cAAAA' - Continue at address AAAA(optional) */ const char *p = &buffer[1]; if (*p != '\0') { void *addr = (void*)hex2int(&p); set_reg_value (&state[R_PC], addr); } rest_cpu_state (); return 0; } static signed char process_D (char *buffer) FASTCALL {/* 'D' - detach the program: continue execution */ *buffer = '\0'; return -2; } static signed char process_k (char *buffer) FASTCALL {/* 'k' - Kill the program */ set_reg_value (&state[R_PC], 0); rest_cpu_state (); (void)buffer; return 0; } static signed char process_v (char *buffer) FASTCALL { #ifndef DBG_MIN_SIZE if (memcmp (&buffer[1], "Cont", 4) == 0) { if (buffer[5] == '?') { /* result response will be "vCont;c;C"; C action must be supported too, because GDB reguires at lease both of them */ memcpy (&buffer[5], ";c;C", 5); return 0; } buffer[0] = '\0'; if (buffer[5] == ';' && (buffer[6] == 'c' || buffer[6] == 'C')) return -2; /* resume execution */ return 1; } #endif /* DBG_MIN_SIZE */ return -1; } static signed char process_zZ (char *buffer) FASTCALL { /* insert/remove breakpoint */ #if defined(DBG_SWBREAK_PROC) || defined(DBG_HWBREAK) || \ defined(DBG_WWATCH) || defined(DBG_RWATCH) || defined(DBG_AWATCH) const byte set = (*buffer == 'Z'); const char *p = &buffer[3]; void *addr = (void*)hex2int(&p); if (*p != ',') return 1; p++; int kind = hex2int(&p); *buffer = '\0'; switch (buffer[1]) { #ifdef DBG_SWBREAK_PROC case '0': /* sw break */ return DBG_SWBREAK_PROC(set, addr); #endif #ifdef DBG_HWBREAK case '1': /* hw break */ return DBG_HWBREAK(set, addr); #endif #ifdef DBG_WWATCH case '2': /* write watch */ return DBG_WWATCH(set, addr, kind); #endif #ifdef DBG_RWATCH case '3': /* read watch */ return DBG_RWATCH(set, addr, kind); #endif #ifdef DBG_AWATCH case '4': /* access watch */ return DBG_AWATCH(set, addr, kind); #endif default:; /* not supported */ } #endif (void)buffer; return -1; } static signed char do_process (char *buffer) FASTCALL { switch (*buffer) { case '?': return process_question (buffer); case 'G': return process_G (buffer); case 'k': return process_k (buffer); case 'M': return process_M (buffer); case 'X': return process_X (buffer); case 'Z': return process_zZ (buffer); case 'c': return process_c (buffer); case 'D': return process_D (buffer); case 'g': return process_g (buffer); case 'm': return process_m (buffer); case 'q': return process_q (buffer); case 'v': return process_v (buffer); case 'z': return process_zZ (buffer); default: return -1; /* empty response */ } } static char process (char *buffer) FASTCALL { signed char err = do_process (buffer); char *p = buffer; char ret = 1; if (err == -2) { ret = 0; err = 0; } if (err > 0) { *p++ = 'E'; p = byte2hex (p, err); *p = '\0'; } else if (err < 0) { *p = '\0'; } else if (*p == '\0') memcpy(p, "OK", 3); return ret; } static char * byte2hex (char *p, byte v) { *p++ = high_hex (v); *p++ = low_hex (v); return p; } static signed char hex2val (unsigned char hex) FASTCALL { if (hex <= '9') return hex - '0'; hex &= 0xdf; /* make uppercase */ hex -= 'A' - 10; return (hex >= 10 && hex < 16) ? hex : -1; } static int hex2byte (const char *p) FASTCALL { signed char h = hex2val (p[0]); signed char l = hex2val (p[1]); if (h < 0 || l < 0) return -1; return (byte)((byte)h << 4) | (byte)l; } static int hex2int (const char **buf) FASTCALL { word r = 0; for (;; (*buf)++) { signed char a = hex2val(**buf); if (a < 0) break; r <<= 4; r += (byte)a; } return (int)r; } static char * int2hex (char *buf, int v) { buf = byte2hex(buf, (word)v >> 8); return byte2hex(buf, (byte)v); } static char high_hex (byte v) FASTCALL { return low_hex(v >> 4); } static char low_hex (byte v) FASTCALL { /* __asm ld a, l and a, #0x0f add a, #0x90 daa adc a, #0x40 daa ld l, a __endasm; (void)v; */ v &= 0x0f; v += '0'; if (v < '9'+1) return v; return v + 'a' - '0' - 10; } /* convert the memory, pointed to by mem into hex, placing result in buf */ /* return a pointer to the last char put in buf (null) */ static char * mem2hex (char *buf, const byte *mem, unsigned bytes) { char *d = buf; if (bytes != 0) { do { d = byte2hex (d, *mem++); } while (--bytes); } *d = 0; return d; } /* convert the hex array pointed to by buf into binary, to be placed in mem return a pointer to the character after the last byte written */ static const char * hex2mem (byte *mem, const char *buf, unsigned bytes) { if (bytes != 0) { do { *mem++ = hex2byte (buf); buf += 2; } while (--bytes); } return buf; } #ifdef DBG_MEMORY_MAP static void read_memory_map (char *buffer, unsigned offset, unsigned length) { const char *map = DBG_MEMORY_MAP; const unsigned map_sz = strlen(map); if (offset >= map_sz) { buffer[0] = 'l'; buffer[1] = '\0'; return; } if (offset + length > map_sz) length = map_sz - offset; buffer[0] = 'm'; memcpy (&buffer[1], &map[offset], length); buffer[1+length] = '\0'; } #endif /* write string like " nn:0123" and return pointer after it */ #ifndef DBG_MIN_SIZE static char * format_reg_value (char *p, unsigned reg_num, const byte *value) { char *d = p; unsigned char i; d = byte2hex(d, reg_num); *d++ = ':'; value += REG_SIZE; i = REG_SIZE; do { d = byte2hex(d, *--value); } while (--i != 0); *d++ = ';'; return d; } #endif /* DBG_MIN_SIZE */ #ifdef __SDCC_gbz80 /* saves all state.except PC and SP */ static void save_cpu_state() __naked { __asm push af ld a, l ld (#_state + R_HL + 0), a ld a, h ld (#_state + R_HL + 1), a ld hl, #_state + R_HL - 1 ld (hl), d dec hl ld (hl), e dec hl ld (hl), b dec hl ld (hl), c dec hl pop bc ld (hl), b dec hl ld (hl), c ret __endasm; } /* restore CPU state and continue execution */ static void rest_cpu_state() __naked { __asm ;restore SP ld a, (#_state + R_SP + 0) ld l,a ld a, (#_state + R_SP + 1) ld h,a ld sp, hl ;push PC value as return address ld a, (#_state + R_PC + 0) ld l, a ld a, (#_state + R_PC + 1) ld h, a push hl ;restore registers ld hl, #_state + R_AF ld c, (hl) inc hl ld b, (hl) inc hl push bc ld c, (hl) inc hl ld b, (hl) inc hl ld e, (hl) inc hl ld d, (hl) inc hl ld a, (hl) inc hl ld h, (hl) ld l, a pop af ret __endasm; } #else /* saves all state.except PC and SP */ static void save_cpu_state() __naked { __asm ld (#_state + R_HL), hl ld (#_state + R_DE), de ld (#_state + R_BC), bc push af pop hl ld (#_state + R_AF), hl ld a, r ;R is increased by 7 or by 8 if called via RST ld l, a sub a, #7 xor a, l and a, #0x7f xor a, l #ifdef __SDCC_ez80_adl ld hl, i ex de, hl ld hl, #_state + R_IR ld (hl), a inc hl ld (hl), e inc hl ld (hl), d ld a, MB ld (#_state + R_AF+2), a #else ld l, a ld a, i ld h, a ld (#_state + R_IR), hl #endif /* __SDCC_ez80_adl */ ld (#_state + R_IX), ix ld (#_state + R_IY), iy ex af, af' ;' exx ld (#_state + R_HL_), hl ld (#_state + R_DE_), de ld (#_state + R_BC_), bc push af pop hl ld (#_state + R_AF_), hl ret __endasm; } /* restore CPU state and continue execution */ static void rest_cpu_state() __naked { __asm #ifdef DBG_USE_TRAMPOLINE ld sp, _stack + DBG_STACK_SIZE ld hl, (#_state + R_PC) push hl /* resume address */ #ifdef __SDCC_ez80_adl ld hl, 0xc30000 ; use 0xc34000 for jp.s #else ld hl, 0xc300 #endif push hl /* JP opcode */ #endif /* DBG_USE_TRAMPOLINE */ ld hl, (#_state + R_AF_) push hl pop af ld bc, (#_state + R_BC_) ld de, (#_state + R_DE_) ld hl, (#_state + R_HL_) exx ex af, af' ;' ld iy, (#_state + R_IY) ld ix, (#_state + R_IX) #ifdef __SDCC_ez80_adl ld a, (#_state + R_AF + 2) ld MB, a ld hl, (#_state + R_IR + 1) ;I register ld i, hl ld a, (#_state + R_IR + 0) ; R register ld l, a #else ld hl, (#_state + R_IR) ld a, h ld i, a ld a, l #endif /* __SDCC_ez80_adl */ sub a, #10 ;number of M1 cycles after ld r,a xor a, l and a, #0x7f xor a, l ld r, a ld de, (#_state + R_DE) ld bc, (#_state + R_BC) ld hl, (#_state + R_AF) push hl pop af ld sp, (#_state + R_SP) #ifndef DBG_USE_TRAMPOLINE ld hl, (#_state + R_PC) push hl ld hl, (#_state + R_HL) DBG_RESUME #else ld hl, (#_state + R_HL) #ifdef __SDCC_ez80_adl jp #_stack + DBG_STACK_SIZE - 4 #else jp #_stack + DBG_STACK_SIZE - 3 #endif #endif /* DBG_USE_TRAMPOLINE */ __endasm; } #endif /* __SDCC_gbz80 */