/* armrdi.c -- ARMulator RDI interface: ARM6 Instruction Emulator. Copyright (C) 1994 Advanced RISC Machines Ltd. 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 2 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, write to the Free Software Foundation, Inc., 51 Franklin Street - Fifth Floor, Boston, MA 02110-1301, USA. */ #include #include #include "armdefs.h" #include "armemu.h" #include "armos.h" #include "dbg_cp.h" #include "dbg_conf.h" #include "dbg_rdi.h" #include "dbg_hif.h" #include "communicate.h" /***************************************************************************\ * Declarations * \***************************************************************************/ #define Watch_AnyRead (RDIWatch_ByteRead+RDIWatch_HalfRead+RDIWatch_WordRead) #define Watch_AnyWrite (RDIWatch_ByteWrite+RDIWatch_HalfWrite+RDIWatch_WordWrite) static unsigned FPRegsAddr; /* last known address of FPE regs */ #define FPESTART 0x2000L #define FPEEND 0x8000L #define IGNORE(d) (d = d) #ifdef RDI_VERBOSE #define TracePrint(s) \ if (rdi_log & 1) ARMul_DebugPrint s #else #define TracePrint(s) #endif static ARMul_State *state = NULL; static unsigned BreaksSet; /* The number of breakpoints set */ static int rdi_log = 0; /* debugging ? */ #define LOWEST_RDI_LEVEL 0 #define HIGHEST_RDI_LEVEL 1 static int MYrdi_level = LOWEST_RDI_LEVEL; typedef struct BreakNode BreakNode; typedef struct WatchNode WatchNode; struct BreakNode { /* A breakpoint list node */ BreakNode *next; ARMword address; /* The address of this breakpoint */ unsigned type; /* The type of comparison */ ARMword bound; /* The other address for a range */ ARMword inst; }; struct WatchNode { /* A watchpoint list node */ WatchNode *next; ARMword address; /* The address of this watchpoint */ unsigned type; /* The type of comparison */ unsigned datatype; /* The type of access to watch for */ ARMword bound; /* The other address for a range */ }; BreakNode *BreakList = NULL; WatchNode *WatchList = NULL; void ARMul_DebugPrint_i (const Dbg_HostosInterface * hostif, const char *format, ...) { va_list ap; va_start (ap, format); hostif->dbgprint (hostif->dbgarg, format, ap); va_end (ap); } void ARMul_DebugPrint (ARMul_State * state, const char *format, ...) { va_list ap; va_start (ap, format); if (!(rdi_log & 8)) state->hostif->dbgprint (state->hostif->dbgarg, format, ap); va_end (ap); } #define CONSOLE_PRINT_MAX_LEN 128 void ARMul_ConsolePrint (ARMul_State * state, const char *format, ...) { va_list ap; int ch; char *str, buf[CONSOLE_PRINT_MAX_LEN]; int i, j; ARMword junk; va_start (ap, format); vsprintf (buf, format, ap); for (i = 0; buf[i]; i++); /* The string is i chars long */ str = buf; while (i >= 32) { MYwrite_char (kidmum[1], RDP_OSOp); MYwrite_word (kidmum[1], SWI_Write0); MYwrite_char (kidmum[1], OS_SendString); MYwrite_char (kidmum[1], 32); /* Send string 32bytes at a time */ for (j = 0; j < 32; j++, str++) MYwrite_char (kidmum[1], *str); wait_for_osreply (&junk); i -= 32; } if (i > 0) { MYwrite_char (kidmum[1], RDP_OSOp); MYwrite_word (kidmum[1], SWI_Write0); MYwrite_char (kidmum[1], OS_SendString); MYwrite_char (kidmum[1], (unsigned char) i); /* Send remainder of string */ for (j = 0; j < i; j++, str++) MYwrite_char (kidmum[1], *str); wait_for_osreply (&junk); } va_end (ap); return; /* str = buf; */ /* while ((ch=*str++) != 0) */ /* state->hostif->writec(state->hostif->hostosarg, ch); */ } void ARMul_DebugPause (ARMul_State * state) { if (!(rdi_log & 8)) state->hostif->dbgpause (state->hostif->dbgarg); } /***************************************************************************\ * RDI_open * \***************************************************************************/ static void InitFail (int exitcode, char const *which) { ARMul_ConsolePrint (state, "%s interface failed to initialise. Exiting\n", which); exit (exitcode); } static void RDIInit (unsigned type) { if (type == 0) { /* cold start */ state->CallDebug = state->MemReadDebug = state->MemWriteDebug = 0; BreaksSet = 0; } } #define UNKNOWNPROC 0 typedef struct { char name[16]; unsigned properties; } Processor; Processor const p_arm2 = { "ARM2", ARM_Fix26_Prop }; Processor const p_arm2as = { "ARM2AS", ARM_Fix26_Prop }; Processor const p_arm61 = { "ARM61", ARM_Fix26_Prop }; Processor const p_arm3 = { "ARM3", ARM_Fix26_Prop }; Processor const p_arm6 = { "ARM6", ARM_Lock_Prop }; Processor const p_arm60 = { "ARM60", ARM_Lock_Prop }; Processor const p_arm600 = { "ARM600", ARM_Lock_Prop }; Processor const p_arm610 = { "ARM610", ARM_Lock_Prop }; Processor const p_arm620 = { "ARM620", ARM_Lock_Prop }; Processor const p_unknown = { "", 0 }; Processor const *const processors[] = { &p_arm6, /* default: must come first */ &p_arm2, &p_arm2as, &p_arm61, &p_arm3, &p_arm60, &p_arm600, &p_arm610, &p_arm620, &p_unknown }; typedef struct ProcessorConfig ProcessorConfig; struct ProcessorConfig { long id[2]; ProcessorConfig const *self; long count; Processor const *const *processors; }; ProcessorConfig const processorconfig = { {((((((long) 'x' << 8) | ' ') << 8) | 'c') << 8) | 'p', ((((((long) 'u' << 8) | 's') << 8) | ' ') << 8) | 'x'}, &processorconfig, 16, processors }; static int RDI_open (unsigned type, const Dbg_ConfigBlock * config, const Dbg_HostosInterface * hostif, struct Dbg_MCState *dbg_state) /* Initialise everything */ { int virgin = (state == NULL); IGNORE (dbg_state); #ifdef RDI_VERBOSE if (rdi_log & 1) { if (virgin) ARMul_DebugPrint_i (hostif, "RDI_open: type = %d\n", type); else ARMul_DebugPrint (state, "RDI_open: type = %d\n", type); } #endif if (type & 1) { /* Warm start */ ARMul_Reset (state); RDIInit (1); } else { if (virgin) { ARMul_EmulateInit (); state = ARMul_NewState (); state->hostif = hostif; { int req = config->processor; unsigned processor = processors[req]->val; ARMul_SelectProcessor (state, processor); ARMul_Reset (state); ARMul_ConsolePrint (state, "ARMulator V1.50, %s", processors[req]->name); } if (ARMul_MemoryInit (state, config->memorysize) == FALSE) InitFail (1, "Memory"); if (config->bytesex != RDISex_DontCare) state->bigendSig = config->bytesex; if (ARMul_CoProInit (state) == FALSE) InitFail (2, "Co-Processor"); if (ARMul_OSInit (state) == FALSE) InitFail (3, "Operating System"); } ARMul_Reset (state); RDIInit (0); } if (type & 2) { /* Reset the comms link */ /* what comms link ? */ } if (virgin && (type & 1) == 0) /* Cold start */ ARMul_ConsolePrint (state, ", %s endian.\n", state->bigendSig ? "Big" : "Little"); if (config->bytesex == RDISex_DontCare) return (state->bigendSig ? RDIError_BigEndian : RDIError_LittleEndian); else return (RDIError_NoError); } /***************************************************************************\ * RDI_close * \***************************************************************************/ static int RDI_close (void) { TracePrint ((state, "RDI_close\n")); ARMul_OSExit (state); ARMul_CoProExit (state); ARMul_MemoryExit (state); return (RDIError_NoError); } /***************************************************************************\ * RDI_read * \***************************************************************************/ static int RDI_read (ARMword source, void *dest, unsigned *nbytes) { unsigned i; char *memptr = (char *) dest; TracePrint ((state, "RDI_read: source=%.8lx dest=%p nbytes=%.8x\n", source, dest, *nbytes)); for (i = 0; i < *nbytes; i++) *memptr++ = (char) ARMul_ReadByte (state, source++); if (state->abortSig) { state->abortSig = LOW; return (RDIError_DataAbort); } return (RDIError_NoError); } /***************************************************************************\ * RDI_write * \***************************************************************************/ static int RDI_write (const void *source, ARMword dest, unsigned *nbytes) { unsigned i; char *memptr = (char *) source; TracePrint ((state, "RDI_write: source=%p dest=%.8lx nbytes=%.8x\n", source, dest, *nbytes)); for (i = 0; i < *nbytes; i++) ARMul_WriteByte (state, (ARMword) dest++, (ARMword) * memptr++); if (state->abortSig) { state->abortSig = LOW; return (RDIError_DataAbort); } return (RDIError_NoError); } /***************************************************************************\ * RDI_CPUread * \***************************************************************************/ static int RDI_CPUread (unsigned mode, unsigned long mask, ARMword buffer[]) { unsigned i, upto; if (mode == RDIMode_Curr) mode = (unsigned) (ARMul_GetCPSR (state) & MODEBITS); for (upto = 0, i = 0; i < 15; i++) if (mask & (1L << i)) { buffer[upto++] = ARMul_GetReg (state, mode, i); } if (mask & RDIReg_R15) { buffer[upto++] = ARMul_GetR15 (state); } if (mask & RDIReg_PC) { buffer[upto++] = ARMul_GetPC (state); } if (mask & RDIReg_CPSR) buffer[upto++] = ARMul_GetCPSR (state); if (mask & RDIReg_SPSR) buffer[upto++] = ARMul_GetSPSR (state, mode); TracePrint ((state, "RDI_CPUread: mode=%.8x mask=%.8lx", mode, mask)); #ifdef RDI_VERBOSE if (rdi_log & 1) { for (upto = 0, i = 0; i <= 20; i++) if (mask & (1L << i)) { ARMul_DebugPrint (state, "%c%.8lx", upto % 4 == 0 ? '\n' : ' ', buffer[upto]); upto++; } ARMul_DebugPrint (state, "\n"); } #endif return (RDIError_NoError); } /***************************************************************************\ * RDI_CPUwrite * \***************************************************************************/ static int RDI_CPUwrite (unsigned mode, unsigned long mask, ARMword const buffer[]) { int i, upto; TracePrint ((state, "RDI_CPUwrite: mode=%.8x mask=%.8lx", mode, mask)); #ifdef RDI_VERBOSE if (rdi_log & 1) { for (upto = 0, i = 0; i <= 20; i++) if (mask & (1L << i)) { ARMul_DebugPrint (state, "%c%.8lx", upto % 4 == 0 ? '\n' : ' ', buffer[upto]); upto++; } ARMul_DebugPrint (state, "\n"); } #endif if (mode == RDIMode_Curr) mode = (unsigned) (ARMul_GetCPSR (state) & MODEBITS); for (upto = 0, i = 0; i < 15; i++) if (mask & (1L << i)) ARMul_SetReg (state, mode, i, buffer[upto++]); if (mask & RDIReg_R15) ARMul_SetR15 (state, buffer[upto++]); if (mask & RDIReg_PC) { ARMul_SetPC (state, buffer[upto++]); } if (mask & RDIReg_CPSR) ARMul_SetCPSR (state, buffer[upto++]); if (mask & RDIReg_SPSR) ARMul_SetSPSR (state, mode, buffer[upto++]); return (RDIError_NoError); } /***************************************************************************\ * RDI_CPread * \***************************************************************************/ static int RDI_CPread (unsigned CPnum, unsigned long mask, ARMword buffer[]) { ARMword fpregsaddr, word[4]; unsigned r, w; unsigned upto; if (CPnum != 1 && CPnum != 2) { unsigned char const *rmap = state->CPRegWords[CPnum]; if (rmap == NULL) return (RDIError_UnknownCoPro); for (upto = 0, r = 0; r < rmap[-1]; r++) if (mask & (1L << r)) { (void) state->CPRead[CPnum] (state, r, &buffer[upto]); upto += rmap[r]; } TracePrint ((state, "RDI_CPread: CPnum=%d mask=%.8lx", CPnum, mask)); #ifdef RDI_VERBOSE if (rdi_log & 1) { w = 0; for (upto = 0, r = 0; r < rmap[-1]; r++) if (mask & (1L << r)) { int words = rmap[r]; ARMul_DebugPrint (state, "%c%2d", (w >= 4 ? (w = 0, '\n') : ' '), r); while (--words >= 0) { ARMul_DebugPrint (state, " %.8lx", buffer[upto++]); w++; } } ARMul_DebugPrint (state, "\n"); } #endif return RDIError_NoError; } #ifdef NOFPE return RDIError_UnknownCoPro; #else if (FPRegsAddr == 0) { fpregsaddr = ARMul_ReadWord (state, 4L); if ((fpregsaddr & 0xff800000) != 0xea000000) /* Must be a forward branch */ return RDIError_UnknownCoPro; fpregsaddr = ((fpregsaddr & 0xffffff) << 2) + 8; /* address in __fp_decode - 4 */ if ((fpregsaddr < FPESTART) || (fpregsaddr >= FPEEND)) return RDIError_UnknownCoPro; fpregsaddr = ARMul_ReadWord (state, fpregsaddr); /* pointer to fp registers */ FPRegsAddr = fpregsaddr; } else fpregsaddr = FPRegsAddr; if (fpregsaddr == 0) return RDIError_UnknownCoPro; for (upto = 0, r = 0; r < 8; r++) if (mask & (1L << r)) { for (w = 0; w < 4; w++) word[w] = ARMul_ReadWord (state, fpregsaddr + (ARMword) r * 16 + (ARMword) w * 4); switch ((int) (word[3] >> 29)) { case 0: case 2: case 4: case 6: /* its unpacked, convert to extended */ buffer[upto++] = 2; /* mark as extended */ buffer[upto++] = (word[3] & 0x7fff) | (word[0] & 0x80000000); /* exp and sign */ buffer[upto++] = word[1]; /* mantissa 1 */ buffer[upto++] = word[2]; /* mantissa 2 */ break; case 1: /* packed single */ buffer[upto++] = 0; /* mark as single */ buffer[upto++] = word[0]; /* sign, exp and mantissa */ buffer[upto++] = word[1]; /* padding */ buffer[upto++] = word[2]; /* padding */ break; case 3: /* packed double */ buffer[upto++] = 1; /* mark as double */ buffer[upto++] = word[0]; /* sign, exp and mantissa1 */ buffer[upto++] = word[1]; /* mantissa 2 */ buffer[upto++] = word[2]; /* padding */ break; case 5: /* packed extended */ buffer[upto++] = 2; /* mark as extended */ buffer[upto++] = word[0]; /* sign and exp */ buffer[upto++] = word[1]; /* mantissa 1 */ buffer[upto++] = word[2]; /* mantissa 2 */ break; case 7: /* packed decimal */ buffer[upto++] = 3; /* mark as packed decimal */ buffer[upto++] = word[0]; /* sign, exp and mantissa1 */ buffer[upto++] = word[1]; /* mantissa 2 */ buffer[upto++] = word[2]; /* mantissa 3 */ break; } } if (mask & (1L << r)) buffer[upto++] = ARMul_ReadWord (state, fpregsaddr + 128); /* fpsr */ if (mask & (1L << (r + 1))) buffer[upto++] = 0; /* fpcr */ TracePrint ((state, "RDI_CPread: CPnum=%d mask=%.8lx\n", CPnum, mask)); #ifdef RDI_VERBOSE if (rdi_log & 1) { for (upto = 0, r = 0; r < 9; r++) if (mask & (1L << r)) { if (r != 8) { ARMul_DebugPrint (state, "%08lx ", buffer[upto++]); ARMul_DebugPrint (state, "%08lx ", buffer[upto++]); ARMul_DebugPrint (state, "%08lx ", buffer[upto++]); } ARMul_DebugPrint (state, "%08lx\n", buffer[upto++]); } ARMul_DebugPrint (state, "\n"); } #endif return (RDIError_NoError); #endif /* NOFPE */ } /***************************************************************************\ * RDI_CPwrite * \***************************************************************************/ static int RDI_CPwrite (unsigned CPnum, unsigned long mask, ARMword const buffer[]) { unsigned r; unsigned upto; ARMword fpregsaddr; if (CPnum != 1 && CPnum != 2) { unsigned char const *rmap = state->CPRegWords[CPnum]; if (rmap == NULL) return (RDIError_UnknownCoPro); TracePrint ((state, "RDI_CPwrite: CPnum=%d mask=%.8lx", CPnum, mask)); #ifdef RDI_VERBOSE if (rdi_log & 1) { int w = 0; for (upto = 0, r = 0; r < rmap[-1]; r++) if (mask & (1L << r)) { int words = rmap[r]; ARMul_DebugPrint (state, "%c%2d", (w >= 4 ? (w = 0, '\n') : ' '), r); while (--words >= 0) { ARMul_DebugPrint (state, " %.8lx", buffer[upto++]); w++; } } ARMul_DebugPrint (state, "\n"); } #endif for (upto = 0, r = 0; r < rmap[-1]; r++) if (mask & (1L << r)) { (void) state->CPWrite[CPnum] (state, r, &buffer[upto]); upto += rmap[r]; } return RDIError_NoError; } #ifdef NOFPE return RDIError_UnknownCoPro; #else TracePrint ((state, "RDI_CPwrite: CPnum=%d mask=%.8lx", CPnum, mask)); #ifdef RDI_VERBOSE if (rdi_log & 1) { for (upto = 0, r = 0; r < 9; r++) if (mask & (1L << r)) { if (r != 8) { ARMul_DebugPrint (state, "%08lx ", buffer[upto++]); ARMul_DebugPrint (state, "%08lx ", buffer[upto++]); ARMul_DebugPrint (state, "%08lx ", buffer[upto++]); } ARMul_DebugPrint (state, "%08lx\n", buffer[upto++]); } ARMul_DebugPrint (state, "\n"); } #endif if (FPRegsAddr == 0) { fpregsaddr = ARMul_ReadWord (state, 4L); if ((fpregsaddr & 0xff800000) != 0xea000000) /* Must be a forward branch */ return RDIError_UnknownCoPro; fpregsaddr = ((fpregsaddr & 0xffffff) << 2) + 8; /* address in __fp_decode - 4 */ if ((fpregsaddr < FPESTART) || (fpregsaddr >= FPEEND)) return RDIError_UnknownCoPro; fpregsaddr = ARMul_ReadWord (state, fpregsaddr); /* pointer to fp registers */ FPRegsAddr = fpregsaddr; } else fpregsaddr = FPRegsAddr; if (fpregsaddr == 0) return RDIError_UnknownCoPro; for (upto = 0, r = 0; r < 8; r++) if (mask & (1L << r)) { ARMul_WriteWord (state, fpregsaddr + (ARMword) r * 16, buffer[upto + 1]); ARMul_WriteWord (state, fpregsaddr + (ARMword) r * 16 + 4, buffer[upto + 2]); ARMul_WriteWord (state, fpregsaddr + (ARMword) r * 16 + 8, buffer[upto + 3]); ARMul_WriteWord (state, fpregsaddr + (ARMword) r * 16 + 12, (buffer[upto] * 2 + 1) << 29); /* mark type */ upto += 4; } if (mask & (1L << r)) ARMul_WriteWord (state, fpregsaddr + 128, buffer[upto++]); /* fpsr */ return (RDIError_NoError); #endif /* NOFPE */ } static void deletebreaknode (BreakNode ** prevp) { BreakNode *p = *prevp; *prevp = p->next; ARMul_WriteWord (state, p->address, p->inst); free ((char *) p); BreaksSet--; state->CallDebug--; } static int removebreak (ARMword address, unsigned type) { BreakNode *p, **prevp = &BreakList; for (; (p = *prevp) != NULL; prevp = &p->next) if (p->address == address && p->type == type) { deletebreaknode (prevp); return TRUE; } return FALSE; } /* This routine installs a breakpoint into the breakpoint table */ static BreakNode * installbreak (ARMword address, unsigned type, ARMword bound) { BreakNode *p = (BreakNode *) malloc (sizeof (BreakNode)); p->next = BreakList; BreakList = p; p->address = address; p->type = type; p->bound = bound; p->inst = ARMul_ReadWord (state, address); ARMul_WriteWord (state, address, 0xee000000L); return p; } /***************************************************************************\ * RDI_setbreak * \***************************************************************************/ static int RDI_setbreak (ARMword address, unsigned type, ARMword bound, PointHandle * handle) { BreakNode *p; TracePrint ((state, "RDI_setbreak: address=%.8lx type=%d bound=%.8lx\n", address, type, bound)); removebreak (address, type); p = installbreak (address, type, bound); BreaksSet++; state->CallDebug++; *handle = (PointHandle) p; TracePrint ((state, " returns %.8lx\n", *handle)); return RDIError_NoError; } /***************************************************************************\ * RDI_clearbreak * \***************************************************************************/ static int RDI_clearbreak (PointHandle handle) { TracePrint ((state, "RDI_clearbreak: address=%.8lx\n", handle)); { BreakNode *p, **prevp = &BreakList; for (; (p = *prevp) != NULL; prevp = &p->next) if (p == (BreakNode *) handle) break; if (p == NULL) return RDIError_NoSuchPoint; deletebreaknode (prevp); return RDIError_NoError; } } /***************************************************************************\ * Internal functions for breakpoint table manipulation * \***************************************************************************/ static void deletewatchnode (WatchNode ** prevp) { WatchNode *p = *prevp; if (p->datatype & Watch_AnyRead) state->MemReadDebug--; if (p->datatype & Watch_AnyWrite) state->MemWriteDebug--; *prevp = p->next; free ((char *) p); } int removewatch (ARMword address, unsigned type) { WatchNode *p, **prevp = &WatchList; for (; (p = *prevp) != NULL; prevp = &p->next) if (p->address == address && p->type == type) { /* found a match */ deletewatchnode (prevp); return TRUE; } return FALSE; /* never found a match */ } static WatchNode * installwatch (ARMword address, unsigned type, unsigned datatype, ARMword bound) { WatchNode *p = (WatchNode *) malloc (sizeof (WatchNode)); p->next = WatchList; WatchList = p; p->address = address; p->type = type; p->datatype = datatype; p->bound = bound; return p; } /***************************************************************************\ * RDI_setwatch * \***************************************************************************/ static int RDI_setwatch (ARMword address, unsigned type, unsigned datatype, ARMword bound, PointHandle * handle) { WatchNode *p; TracePrint ( (state, "RDI_setwatch: address=%.8lx type=%d datatype=%d bound=%.8lx", address, type, datatype, bound)); if (!state->CanWatch) return RDIError_UnimplementedMessage; removewatch (address, type); p = installwatch (address, type, datatype, bound); if (datatype & Watch_AnyRead) state->MemReadDebug++; if (datatype & Watch_AnyWrite) state->MemWriteDebug++; *handle = (PointHandle) p; TracePrint ((state, " returns %.8lx\n", *handle)); return RDIError_NoError; } /***************************************************************************\ * RDI_clearwatch * \***************************************************************************/ static int RDI_clearwatch (PointHandle handle) { TracePrint ((state, "RDI_clearwatch: address=%.8lx\n", handle)); { WatchNode *p, **prevp = &WatchList; for (; (p = *prevp) != NULL; prevp = &p->next) if (p == (WatchNode *) handle) break; if (p == NULL) return RDIError_NoSuchPoint; deletewatchnode (prevp); return RDIError_NoError; } } /***************************************************************************\ * RDI_execute * \***************************************************************************/ static int RDI_execute (PointHandle * handle) { TracePrint ((state, "RDI_execute\n")); if (rdi_log & 4) { state->CallDebug++; state->Debug = TRUE; } state->EndCondition = RDIError_NoError; state->StopHandle = 0; ARMul_DoProg (state); *handle = state->StopHandle; state->Reg[15] -= 8; /* undo the pipeline */ if (rdi_log & 4) { state->CallDebug--; state->Debug = FALSE; } return (state->EndCondition); } /***************************************************************************\ * RDI_step * \***************************************************************************/ static int RDI_step (unsigned ninstr, PointHandle * handle) { TracePrint ((state, "RDI_step\n")); if (ninstr != 1) return RDIError_UnimplementedMessage; if (rdi_log & 4) { state->CallDebug++; state->Debug = TRUE; } state->EndCondition = RDIError_NoError; state->StopHandle = 0; ARMul_DoInstr (state); *handle = state->StopHandle; state->Reg[15] -= 8; /* undo the pipeline */ if (rdi_log & 4) { state->CallDebug--; state->Debug = FALSE; } return (state->EndCondition); } /***************************************************************************\ * RDI_info * \***************************************************************************/ static int RDI_info (unsigned type, ARMword * arg1, ARMword * arg2) { switch (type) { case RDIInfo_Target: TracePrint ((state, "RDI_Info_Target\n")); /* Emulator, speed 10**5 IPS */ *arg1 = 5 | HIGHEST_RDI_LEVEL << 5 | LOWEST_RDI_LEVEL << 8; *arg2 = 1298224434; return RDIError_NoError; case RDIInfo_Points: { ARMword n = RDIPointCapability_Comparison | RDIPointCapability_Range | RDIPointCapability_Mask | RDIPointCapability_Status; TracePrint ((state, "RDI_Info_Points\n")); if (state->CanWatch) n |= (Watch_AnyRead + Watch_AnyWrite) << 2; *arg1 = n; return RDIError_NoError; } case RDIInfo_Step: TracePrint ((state, "RDI_Info_Step\n")); *arg1 = RDIStep_Single; return RDIError_NoError; case RDIInfo_MMU: TracePrint ((state, "RDI_Info_MMU\n")); *arg1 = 1313820229; return RDIError_NoError; case RDISignal_Stop: TracePrint ((state, "RDISignal_Stop\n")); state->CallDebug++; state->EndCondition = RDIError_UserInterrupt; return RDIError_NoError; case RDIVector_Catch: TracePrint ((state, "RDIVector_Catch %.8lx\n", *arg1)); state->VectorCatch = (unsigned) *arg1; return RDIError_NoError; case RDISet_Cmdline: TracePrint ((state, "RDI_Set_Cmdline %s\n", (char *) arg1)); state->CommandLine = (char *) malloc ((unsigned) strlen ((char *) arg1) + 1); (void) strcpy (state->CommandLine, (char *) arg1); return RDIError_NoError; case RDICycles: TracePrint ((state, "RDI_Info_Cycles\n")); arg1[0] = 0; arg1[1] = state->NumInstrs; arg1[2] = 0; arg1[3] = state->NumScycles; arg1[4] = 0; arg1[5] = state->NumNcycles; arg1[6] = 0; arg1[7] = state->NumIcycles; arg1[8] = 0; arg1[9] = state->NumCcycles; arg1[10] = 0; arg1[11] = state->NumFcycles; return RDIError_NoError; case RDIErrorP: *arg1 = ARMul_OSLastErrorP (state); TracePrint ((state, "RDI_ErrorP returns %ld\n", *arg1)); return RDIError_NoError; case RDIInfo_DescribeCoPro: { int cpnum = *(int *) arg1; struct Dbg_CoProDesc *cpd = (struct Dbg_CoProDesc *) arg2; int i; unsigned char const *map = state->CPRegWords[cpnum]; if (map == NULL) return RDIError_UnknownCoPro; for (i = 0; i < cpd->entries; i++) { unsigned r, w = cpd->regdesc[i].nbytes / sizeof (ARMword); for (r = cpd->regdesc[i].rmin; r <= cpd->regdesc[i].rmax; r++) if (map[r] != w) return RDIError_BadCoProState; } return RDIError_NoError; } case RDIInfo_RequestCoProDesc: { int cpnum = *(int *) arg1; struct Dbg_CoProDesc *cpd = (struct Dbg_CoProDesc *) arg2; int i = -1, lastw = -1, r; unsigned char const *map; if ((unsigned) cpnum >= 16) return RDIError_UnknownCoPro; map = state->CPRegWords[cpnum]; if (map == NULL) return RDIError_UnknownCoPro; for (r = 0; r < map[-1]; r++) { int words = map[r]; if (words == lastw) cpd->regdesc[i].rmax = r; else { if (++i >= cpd->entries) return RDIError_BufferFull; cpd->regdesc[i].rmax = cpd->regdesc[i].rmin = r; cpd->regdesc[i].nbytes = words * sizeof (ARMword); cpd->regdesc[i].access = Dbg_Access_Readable + Dbg_Access_Writable; } } cpd->entries = i + 1; return RDIError_NoError; } case RDIInfo_Log: *arg1 = (ARMword) rdi_log; return RDIError_NoError; case RDIInfo_SetLog: rdi_log = (int) *arg1; return RDIError_NoError; case RDIInfo_CoPro: return RDIError_NoError; case RDIPointStatus_Watch: { WatchNode *p, *handle = (WatchNode *) * arg1; for (p = WatchList; p != NULL; p = p->next) if (p == handle) { *arg1 = -1; *arg2 = 1; return RDIError_NoError; } return RDIError_NoSuchPoint; } case RDIPointStatus_Break: { BreakNode *p, *handle = (BreakNode *) * arg1; for (p = BreakList; p != NULL; p = p->next) if (p == handle) { *arg1 = -1; *arg2 = 1; return RDIError_NoError; } return RDIError_NoSuchPoint; } case RDISet_RDILevel: if (*arg1 < LOWEST_RDI_LEVEL || *arg1 > HIGHEST_RDI_LEVEL) return RDIError_IncompatibleRDILevels; MYrdi_level = *arg1; return RDIError_NoError; default: return RDIError_UnimplementedMessage; } } /***************************************************************************\ * The emulator calls this routine at the beginning of every cycle when the * * CallDebug flag is set. The second parameter passed is the address of the * * currently executing instruction (i.e Program Counter - 8), the third * * parameter is the instruction being executed. * \***************************************************************************/ ARMword ARMul_Debug (ARMul_State * state, ARMword pc, ARMword instr) { if (state->EndCondition == RDIError_UserInterrupt) { TracePrint ((state, "User interrupt at %.8lx\n", pc)); state->CallDebug--; state->Emulate = STOP; } else { BreakNode *p = BreakList; for (; p != NULL; p = p->next) { switch (p->type) { case RDIPoint_EQ: if (pc == p->address) break; continue; case RDIPoint_GT: if (pc > p->address) break; continue; case RDIPoint_GE: if (pc >= p->address) break; continue; case RDIPoint_LT: if (pc < p->address) break; continue; case RDIPoint_LE: if (pc <= p->address) break; continue; case RDIPoint_IN: if (p->address <= pc && pc < p->address + p->bound) break; continue; case RDIPoint_OUT: if (p->address > pc || pc >= p->address + p->bound) break; continue; case RDIPoint_MASK: if ((pc & p->bound) == p->address) break; continue; } /* found a match */ TracePrint ((state, "Breakpoint reached at %.8lx\n", pc)); state->EndCondition = RDIError_BreakpointReached; state->Emulate = STOP; state->StopHandle = (ARMword) p; break; } } return instr; } void ARMul_CheckWatch (ARMul_State * state, ARMword addr, int access) { WatchNode *p; for (p = WatchList; p != NULL; p = p->next) if (p->datatype & access) { switch (p->type) { case RDIPoint_EQ: if (addr == p->address) break; continue; case RDIPoint_GT: if (addr > p->address) break; continue; case RDIPoint_GE: if (addr >= p->address) break; continue; case RDIPoint_LT: if (addr < p->address) break; continue; case RDIPoint_LE: if (addr <= p->address) break; continue; case RDIPoint_IN: if (p->address <= addr && addr < p->address + p->bound) break; continue; case RDIPoint_OUT: if (p->address > addr || addr >= p->address + p->bound) break; continue; case RDIPoint_MASK: if ((addr & p->bound) == p->address) break; continue; } /* found a match */ TracePrint ((state, "Watchpoint at %.8lx accessed\n", addr)); state->EndCondition = RDIError_WatchpointAccessed; state->Emulate = STOP; state->StopHandle = (ARMword) p; return; } } static RDI_NameList const * RDI_cpunames () { return (RDI_NameList const *) &processorconfig.count; } const struct RDIProcVec armul_rdi = { "ARMUL", RDI_open, RDI_close, RDI_read, RDI_write, RDI_CPUread, RDI_CPUwrite, RDI_CPread, RDI_CPwrite, RDI_setbreak, RDI_clearbreak, RDI_setwatch, RDI_clearwatch, RDI_execute, RDI_step, RDI_info, 0, /*pointinq */ 0, /*addconfig */ 0, /*loadconfigdata */ 0, /*selectconfig */ 0, /*drivernames */ RDI_cpunames };