#include "config.h" #include #include #include #include #ifdef HAVE_UNISTD_H #include #endif #include "d10v_sim.h" #include "simops.h" #include "sys/syscall.h" extern char *strrchr (); enum op_types { OP_VOID, OP_REG, OP_REG_OUTPUT, OP_DREG, OP_DREG_OUTPUT, OP_ACCUM, OP_ACCUM_OUTPUT, OP_ACCUM_REVERSE, OP_CR, OP_CR_OUTPUT, OP_CR_REVERSE, OP_FLAG, OP_FLAG_OUTPUT, OP_CONSTANT16, OP_CONSTANT8, OP_CONSTANT3, OP_CONSTANT4, OP_MEMREF, OP_MEMREF2, OP_POSTDEC, OP_POSTINC, OP_PREDEC, OP_R2, OP_R3, OP_R4, OP_R2R3 }; #ifdef DEBUG static void trace_input_func PARAMS ((char *name, enum op_types in1, enum op_types in2, enum op_types in3)); #define trace_input(name, in1, in2, in3) do { if (d10v_debug) trace_input_func (name, in1, in2, in3); } while (0) static void trace_output_func PARAMS ((enum op_types result)); #define trace_output(result) do { if (d10v_debug) trace_output_func (result); } while (0) #ifndef SIZE_INSTRUCTION #define SIZE_INSTRUCTION 8 #endif #ifndef SIZE_OPERANDS #define SIZE_OPERANDS 18 #endif #ifndef SIZE_VALUES #define SIZE_VALUES 13 #endif #ifndef SIZE_LOCATION #define SIZE_LOCATION 20 #endif #ifndef SIZE_PC #define SIZE_PC 6 #endif #ifndef SIZE_LINE_NUMBER #define SIZE_LINE_NUMBER 4 #endif static void trace_input_func (name, in1, in2, in3) char *name; enum op_types in1; enum op_types in2; enum op_types in3; { char *comma; enum op_types in[3]; int i; char buf[1024]; char *p; long tmp; char *type; const char *filename; const char *functionname; unsigned int linenumber; bfd_vma byte_pc; if ((d10v_debug & DEBUG_TRACE) == 0) return; switch (State.ins_type) { default: case INS_UNKNOWN: type = " ?"; break; case INS_LEFT: type = " L"; break; case INS_RIGHT: type = " R"; break; case INS_LEFT_PARALLEL: type = "*L"; break; case INS_RIGHT_PARALLEL: type = "*R"; break; case INS_LEFT_COND_TEST: type = "?L"; break; case INS_RIGHT_COND_TEST: type = "?R"; break; case INS_LEFT_COND_EXE: type = "&L"; break; case INS_RIGHT_COND_EXE: type = "&R"; break; case INS_LONG: type = " B"; break; } if ((d10v_debug & DEBUG_LINE_NUMBER) == 0) (*d10v_callback->printf_filtered) (d10v_callback, "0x%.*x %s: %-*s ", SIZE_PC, (unsigned)PC, type, SIZE_INSTRUCTION, name); else { buf[0] = '\0'; byte_pc = decode_pc (); if (text && byte_pc >= text_start && byte_pc < text_end) { filename = (const char *)0; functionname = (const char *)0; linenumber = 0; if (bfd_find_nearest_line (prog_bfd, text, (struct symbol_cache_entry **)0, byte_pc - text_start, &filename, &functionname, &linenumber)) { p = buf; if (linenumber) { sprintf (p, "#%-*d ", SIZE_LINE_NUMBER, linenumber); p += strlen (p); } else { sprintf (p, "%-*s ", SIZE_LINE_NUMBER+1, "---"); p += SIZE_LINE_NUMBER+2; } if (functionname) { sprintf (p, "%s ", functionname); p += strlen (p); } else if (filename) { char *q = strrchr (filename, '/'); sprintf (p, "%s ", (q) ? q+1 : filename); p += strlen (p); } if (*p == ' ') *p = '\0'; } } (*d10v_callback->printf_filtered) (d10v_callback, "0x%.*x %s: %-*.*s %-*s ", SIZE_PC, (unsigned)PC, type, SIZE_LOCATION, SIZE_LOCATION, buf, SIZE_INSTRUCTION, name); } in[0] = in1; in[1] = in2; in[2] = in3; comma = ""; p = buf; for (i = 0; i < 3; i++) { switch (in[i]) { case OP_VOID: case OP_R2: case OP_R3: case OP_R4: case OP_R2R3: break; case OP_REG: case OP_REG_OUTPUT: case OP_DREG: case OP_DREG_OUTPUT: sprintf (p, "%sr%d", comma, OP[i]); p += strlen (p); comma = ","; break; case OP_CR: case OP_CR_OUTPUT: case OP_CR_REVERSE: sprintf (p, "%scr%d", comma, OP[i]); p += strlen (p); comma = ","; break; case OP_ACCUM: case OP_ACCUM_OUTPUT: case OP_ACCUM_REVERSE: sprintf (p, "%sa%d", comma, OP[i]); p += strlen (p); comma = ","; break; case OP_CONSTANT16: sprintf (p, "%s%d", comma, OP[i]); p += strlen (p); comma = ","; break; case OP_CONSTANT8: sprintf (p, "%s%d", comma, SEXT8(OP[i])); p += strlen (p); comma = ","; break; case OP_CONSTANT4: sprintf (p, "%s%d", comma, SEXT4(OP[i])); p += strlen (p); comma = ","; break; case OP_CONSTANT3: sprintf (p, "%s%d", comma, SEXT3(OP[i])); p += strlen (p); comma = ","; break; case OP_MEMREF: sprintf (p, "%s@r%d", comma, OP[i]); p += strlen (p); comma = ","; break; case OP_MEMREF2: sprintf (p, "%s@(%d,r%d)", comma, (int16)OP[i], OP[i+1]); p += strlen (p); comma = ","; break; case OP_POSTINC: sprintf (p, "%s@r%d+", comma, OP[i]); p += strlen (p); comma = ","; break; case OP_POSTDEC: sprintf (p, "%s@r%d-", comma, OP[i]); p += strlen (p); comma = ","; break; case OP_PREDEC: sprintf (p, "%s@-r%d", comma, OP[i]); p += strlen (p); comma = ","; break; case OP_FLAG: case OP_FLAG_OUTPUT: if (OP[i] == 0) sprintf (p, "%sf0", comma); else if (OP[i] == 1) sprintf (p, "%sf1", comma); else sprintf (p, "%sc", comma); p += strlen (p); comma = ","; break; } } if ((d10v_debug & DEBUG_VALUES) == 0) { *p++ = '\n'; *p = '\0'; (*d10v_callback->printf_filtered) (d10v_callback, "%s", buf); } else { *p = '\0'; (*d10v_callback->printf_filtered) (d10v_callback, "%-*s", SIZE_OPERANDS, buf); p = buf; for (i = 0; i < 3; i++) { buf[0] = '\0'; switch (in[i]) { case OP_VOID: (*d10v_callback->printf_filtered) (d10v_callback, "%*s", SIZE_VALUES, ""); break; case OP_REG_OUTPUT: case OP_DREG_OUTPUT: case OP_CR_OUTPUT: case OP_ACCUM_OUTPUT: case OP_FLAG_OUTPUT: (*d10v_callback->printf_filtered) (d10v_callback, "%*s", SIZE_VALUES, "---"); break; case OP_REG: case OP_MEMREF: case OP_POSTDEC: case OP_POSTINC: case OP_PREDEC: (*d10v_callback->printf_filtered) (d10v_callback, "%*s0x%.4x", SIZE_VALUES-6, "", (uint16)State.regs[OP[i]]); break; case OP_DREG: tmp = (long)((((uint32) State.regs[OP[i]]) << 16) | ((uint32) State.regs[OP[i]+1])); (*d10v_callback->printf_filtered) (d10v_callback, "%*s0x%.8lx", SIZE_VALUES-10, "", tmp); break; case OP_CR: case OP_CR_REVERSE: (*d10v_callback->printf_filtered) (d10v_callback, "%*s0x%.4x", SIZE_VALUES-6, "", (uint16)State.cregs[OP[i]]); break; case OP_ACCUM: case OP_ACCUM_REVERSE: (*d10v_callback->printf_filtered) (d10v_callback, "%*s0x%.2x%.8lx", SIZE_VALUES-12, "", ((int)(State.a[OP[i]] >> 32) & 0xff), ((unsigned long)State.a[OP[i]]) & 0xffffffff); break; case OP_CONSTANT16: (*d10v_callback->printf_filtered) (d10v_callback, "%*s0x%.4x", SIZE_VALUES-6, "", (uint16)OP[i]); break; case OP_CONSTANT4: (*d10v_callback->printf_filtered) (d10v_callback, "%*s0x%.4x", SIZE_VALUES-6, "", (uint16)SEXT4(OP[i])); break; case OP_CONSTANT8: (*d10v_callback->printf_filtered) (d10v_callback, "%*s0x%.4x", SIZE_VALUES-6, "", (uint16)SEXT8(OP[i])); break; case OP_CONSTANT3: (*d10v_callback->printf_filtered) (d10v_callback, "%*s0x%.4x", SIZE_VALUES-6, "", (uint16)SEXT3(OP[i])); break; case OP_FLAG: if (OP[i] == 0) (*d10v_callback->printf_filtered) (d10v_callback, "%*sF0 = %d", SIZE_VALUES-6, "", State.F0 != 0); else if (OP[i] == 1) (*d10v_callback->printf_filtered) (d10v_callback, "%*sF1 = %d", SIZE_VALUES-6, "", State.F1 != 0); else (*d10v_callback->printf_filtered) (d10v_callback, "%*sC = %d", SIZE_VALUES-5, "", State.C != 0); break; case OP_MEMREF2: (*d10v_callback->printf_filtered) (d10v_callback, "%*s0x%.4x", SIZE_VALUES-6, "", (uint16)OP[i]); (*d10v_callback->printf_filtered) (d10v_callback, "%*s0x%.4x", SIZE_VALUES-6, "", (uint16)State.regs[OP[++i]]); break; case OP_R2: (*d10v_callback->printf_filtered) (d10v_callback, "%*s0x%.4x", SIZE_VALUES-6, "", (uint16)State.regs[2]); break; case OP_R3: (*d10v_callback->printf_filtered) (d10v_callback, "%*s0x%.4x", SIZE_VALUES-6, "", (uint16)State.regs[3]); break; case OP_R4: (*d10v_callback->printf_filtered) (d10v_callback, "%*s0x%.4x", SIZE_VALUES-6, "", (uint16)State.regs[4]); break; case OP_R2R3: (*d10v_callback->printf_filtered) (d10v_callback, "%*s0x%.4x", SIZE_VALUES-6, "", (uint16)State.regs[2]); (*d10v_callback->printf_filtered) (d10v_callback, "%*s0x%.4x", SIZE_VALUES-6, "", (uint16)State.regs[3]); i++; break; } } } (*d10v_callback->flush_stdout) (d10v_callback); } static void trace_output_func (result) enum op_types result; { if ((d10v_debug & (DEBUG_TRACE | DEBUG_VALUES)) == (DEBUG_TRACE | DEBUG_VALUES)) { long tmp; switch (result) { default: putchar ('\n'); break; case OP_REG: case OP_REG_OUTPUT: (*d10v_callback->printf_filtered) (d10v_callback, " :: %*s0x%.4x F0=%d F1=%d C=%d\n", SIZE_VALUES-6, "", (uint16)State.regs[OP[0]], State.F0 != 0, State.F1 != 0, State.C != 0); break; case OP_DREG: case OP_DREG_OUTPUT: tmp = (long)((((uint32) State.regs[OP[0]]) << 16) | ((uint32) State.regs[OP[0]+1])); (*d10v_callback->printf_filtered) (d10v_callback, " :: %*s0x%.8lx F0=%d F1=%d C=%d\n", SIZE_VALUES-10, "", tmp, State.F0 != 0, State.F1 != 0, State.C != 0); break; case OP_CR: case OP_CR_OUTPUT: (*d10v_callback->printf_filtered) (d10v_callback, " :: %*s0x%.4x F0=%d F1=%d C=%d\n", SIZE_VALUES-6, "", (uint16)State.cregs[OP[0]], State.F0 != 0, State.F1 != 0, State.C != 0); break; case OP_CR_REVERSE: (*d10v_callback->printf_filtered) (d10v_callback, " :: %*s0x%.4x F0=%d F1=%d C=%d\n", SIZE_VALUES-6, "", (uint16)State.cregs[OP[1]], State.F0 != 0, State.F1 != 0, State.C != 0); break; case OP_ACCUM: case OP_ACCUM_OUTPUT: (*d10v_callback->printf_filtered) (d10v_callback, " :: %*s0x%.2x%.8lx F0=%d F1=%d C=%d\n", SIZE_VALUES-12, "", ((int)(State.a[OP[0]] >> 32) & 0xff), ((unsigned long)State.a[OP[0]]) & 0xffffffff, State.F0 != 0, State.F1 != 0, State.C != 0); break; case OP_ACCUM_REVERSE: (*d10v_callback->printf_filtered) (d10v_callback, " :: %*s0x%.2x%.8lx F0=%d F1=%d C=%d\n", SIZE_VALUES-12, "", ((int)(State.a[OP[1]] >> 32) & 0xff), ((unsigned long)State.a[OP[1]]) & 0xffffffff, State.F0 != 0, State.F1 != 0, State.C != 0); break; case OP_FLAG: case OP_FLAG_OUTPUT: (*d10v_callback->printf_filtered) (d10v_callback, " :: %*s F0=%d F1=%d C=%d\n", SIZE_VALUES, "", State.F0 != 0, State.F1 != 0, State.C != 0); break; case OP_R2: (*d10v_callback->printf_filtered) (d10v_callback, " :: %*s0x%.4x F0=%d F1=%d C=%d\n", SIZE_VALUES-6, "", (uint16)State.regs[2], State.F0 != 0, State.F1 != 0, State.C != 0); break; case OP_R2R3: (*d10v_callback->printf_filtered) (d10v_callback, " :: %*s0x%.4x%.4x F0=%d F1=%d C=%d\n", SIZE_VALUES-10, "", (uint16)State.regs[2], (uint16)State.regs[3], State.F0 != 0, State.F1 != 0, State.C != 0); break; } } (*d10v_callback->flush_stdout) (d10v_callback); } #else #define trace_input(NAME, IN1, IN2, IN3) #define trace_output(RESULT) #endif /* abs */ void OP_4607 () { trace_input ("abs", OP_REG, OP_VOID, OP_VOID); State.F1 = State.F0; if ((int16)(State.regs[OP[0]]) < 0) { State.regs[OP[0]] = -(int16)(State.regs[OP[0]]); State.F0 = 1; } else State.F0 = 0; trace_output (OP_REG); } /* abs */ void OP_5607 () { int64 tmp; trace_input ("abs", OP_ACCUM, OP_VOID, OP_VOID); State.F1 = State.F0; State.a[OP[0]] = SEXT40(State.a[OP[0]]); if (State.a[OP[0]] < 0 ) { tmp = -State.a[OP[0]]; if (State.ST) { if (tmp > MAX32) State.a[OP[0]] = MAX32; else if (tmp < MIN32) State.a[OP[0]] = MIN32; else State.a[OP[0]] = tmp & MASK40; } else State.a[OP[0]] = tmp & MASK40; State.F0 = 1; } else State.F0 = 0; trace_output (OP_ACCUM); } /* add */ void OP_200 () { uint16 tmp = State.regs[OP[0]]; trace_input ("add", OP_REG, OP_REG, OP_VOID); State.regs[OP[0]] += State.regs[OP[1]]; if ( tmp > State.regs[OP[0]]) State.C = 1; else State.C = 0; trace_output (OP_REG); } /* add */ void OP_1201 () { int64 tmp; tmp = SEXT40(State.a[OP[0]]) + (SEXT16 (State.regs[OP[1]]) << 16 | State.regs[OP[1]+1]); trace_input ("add", OP_ACCUM, OP_REG, OP_VOID); if (State.ST) { if ( tmp > MAX32) State.a[OP[0]] = MAX32; else if ( tmp < MIN32) State.a[OP[0]] = MIN32; else State.a[OP[0]] = tmp & MASK40; } else State.a[OP[0]] = tmp & MASK40; trace_output (OP_ACCUM); } /* add */ void OP_1203 () { int64 tmp; tmp = SEXT40(State.a[OP[0]]) + SEXT40(State.a[OP[1]]); trace_input ("add", OP_ACCUM, OP_ACCUM, OP_VOID); if (State.ST) { if (tmp > MAX32) State.a[OP[0]] = MAX32; else if ( tmp < MIN32) State.a[OP[0]] = MIN32; else State.a[OP[0]] = tmp & MASK40; } else State.a[OP[0]] = tmp & MASK40; trace_output (OP_ACCUM); } /* add2w */ void OP_1200 () { uint32 tmp; uint32 a = (State.regs[OP[0]]) << 16 | State.regs[OP[0]+1]; uint32 b = (State.regs[OP[1]]) << 16 | State.regs[OP[1]+1]; trace_input ("add2w", OP_DREG, OP_DREG, OP_VOID); tmp = a + b; State.C = (tmp < a); State.regs[OP[0]] = tmp >> 16; State.regs[OP[0]+1] = tmp & 0xFFFF; trace_output (OP_DREG); } /* add3 */ void OP_1000000 () { uint16 tmp = State.regs[OP[1]]; State.regs[OP[0]] = tmp + OP[2]; trace_input ("add3", OP_REG_OUTPUT, OP_REG, OP_CONSTANT16); State.C = (State.regs[OP[0]] < tmp); trace_output (OP_REG); } /* addac3 */ void OP_17000200 () { int64 tmp; tmp = SEXT40(State.a[OP[2]]) + SEXT40 ((State.regs[OP[1]] << 16) | State.regs[OP[1]+1]); trace_input ("addac3", OP_DREG_OUTPUT, OP_DREG, OP_ACCUM); State.regs[OP[0]] = (tmp >> 16) & 0xffff; State.regs[OP[0]+1] = tmp & 0xffff; trace_output (OP_DREG); } /* addac3 */ void OP_17000202 () { int64 tmp; tmp = SEXT40(State.a[OP[1]]) + SEXT40(State.a[OP[2]]); trace_input ("addac3", OP_DREG_OUTPUT, OP_ACCUM, OP_ACCUM); State.regs[OP[0]] = (tmp >> 16) & 0xffff; State.regs[OP[0]+1] = tmp & 0xffff; trace_output (OP_DREG); } /* addac3s */ void OP_17001200 () { int64 tmp; State.F1 = State.F0; trace_input ("addac3s", OP_DREG_OUTPUT, OP_DREG, OP_ACCUM); tmp = SEXT40(State.a[OP[2]]) + SEXT40 ((State.regs[OP[1]] << 16) | State.regs[OP[1]+1]); if ( tmp > MAX32) { State.regs[OP[0]] = 0x7fff; State.regs[OP[0]+1] = 0xffff; State.F0 = 1; } else if (tmp < MIN32) { State.regs[OP[0]] = 0x8000; State.regs[OP[0]+1] = 0; State.F0 = 1; } else { State.regs[OP[0]] = (tmp >> 16) & 0xffff; State.regs[OP[0]+1] = tmp & 0xffff; State.F0 = 0; } trace_output (OP_DREG); } /* addac3s */ void OP_17001202 () { int64 tmp; State.F1 = State.F0; trace_input ("addac3s", OP_DREG_OUTPUT, OP_ACCUM, OP_ACCUM); tmp = SEXT40(State.a[OP[1]]) + SEXT40(State.a[OP[2]]); if ( tmp > MAX32) { State.regs[OP[0]] = 0x7fff; State.regs[OP[0]+1] = 0xffff; State.F0 = 1; } else if (tmp < MIN32) { State.regs[OP[0]] = 0x8000; State.regs[OP[0]+1] = 0; State.F0 = 1; } else { State.regs[OP[0]] = (tmp >> 16) & 0xffff; State.regs[OP[0]+1] = tmp & 0xffff; State.F0 = 0; } trace_output (OP_DREG); } /* addi */ void OP_201 () { uint tmp = State.regs[OP[0]]; if (OP[1] == 0) OP[1] = 16; trace_input ("addi", OP_REG, OP_CONSTANT16, OP_VOID); State.regs[OP[0]] += OP[1]; State.C = (State.regs[OP[0]] < tmp); trace_output (OP_REG); } /* and */ void OP_C00 () { trace_input ("and", OP_REG, OP_REG, OP_VOID); State.regs[OP[0]] &= State.regs[OP[1]]; trace_output (OP_REG); } /* and3 */ void OP_6000000 () { trace_input ("and3", OP_REG_OUTPUT, OP_REG, OP_CONSTANT16); State.regs[OP[0]] = State.regs[OP[1]] & OP[2]; trace_output (OP_REG); } /* bclri */ void OP_C01 () { trace_input ("bclri", OP_REG, OP_CONSTANT16, OP_VOID); State.regs[OP[0]] &= ~(0x8000 >> OP[1]); trace_output (OP_REG); } /* bl.s */ void OP_4900 () { trace_input ("bl.s", OP_CONSTANT8, OP_R2, OP_R3); State.regs[13] = PC+1; JMP( PC + SEXT8 (OP[0])); trace_output (OP_VOID); } /* bl.l */ void OP_24800000 () { trace_input ("bl.l", OP_CONSTANT16, OP_R2, OP_R3); State.regs[13] = PC+1; JMP (PC + OP[0]); trace_output (OP_VOID); } /* bnoti */ void OP_A01 () { trace_input ("bnoti", OP_REG, OP_CONSTANT16, OP_VOID); State.regs[OP[0]] ^= 0x8000 >> OP[1]; trace_output (OP_REG); } /* bra.s */ void OP_4800 () { trace_input ("bra.s", OP_CONSTANT8, OP_VOID, OP_VOID); JMP (PC + SEXT8 (OP[0])); trace_output (OP_VOID); } /* bra.l */ void OP_24000000 () { trace_input ("bra.l", OP_CONSTANT16, OP_VOID, OP_VOID); JMP (PC + OP[0]); trace_output (OP_VOID); } /* brf0f.s */ void OP_4A00 () { trace_input ("brf0f.s", OP_CONSTANT8, OP_VOID, OP_VOID); if (State.F0 == 0) JMP (PC + SEXT8 (OP[0])); trace_output (OP_FLAG); } /* brf0f.l */ void OP_25000000 () { trace_input ("brf0f.l", OP_CONSTANT16, OP_VOID, OP_VOID); if (State.F0 == 0) JMP (PC + OP[0]); trace_output (OP_FLAG); } /* brf0t.s */ void OP_4B00 () { trace_input ("brf0t.s", OP_CONSTANT8, OP_VOID, OP_VOID); if (State.F0) JMP (PC + SEXT8 (OP[0])); trace_output (OP_FLAG); } /* brf0t.l */ void OP_25800000 () { trace_input ("brf0t.l", OP_CONSTANT16, OP_VOID, OP_VOID); if (State.F0) JMP (PC + OP[0]); trace_output (OP_FLAG); } /* bseti */ void OP_801 () { trace_input ("bseti", OP_REG, OP_CONSTANT16, OP_VOID); State.regs[OP[0]] |= 0x8000 >> OP[1]; trace_output (OP_REG); } /* btsti */ void OP_E01 () { trace_input ("btsti", OP_REG, OP_CONSTANT16, OP_VOID); State.F1 = State.F0; State.F0 = (State.regs[OP[0]] & (0x8000 >> OP[1])) ? 1 : 0; trace_output (OP_FLAG); } /* clrac */ void OP_5601 () { trace_input ("clrac", OP_ACCUM_OUTPUT, OP_VOID, OP_VOID); State.a[OP[0]] = 0; trace_output (OP_ACCUM); } /* cmp */ void OP_600 () { trace_input ("cmp", OP_REG, OP_REG, OP_VOID); State.F1 = State.F0; State.F0 = ((int16)(State.regs[OP[0]]) < (int16)(State.regs[OP[1]])) ? 1 : 0; trace_output (OP_FLAG); } /* cmp */ void OP_1603 () { trace_input ("cmp", OP_ACCUM, OP_ACCUM, OP_VOID); State.F1 = State.F0; State.F0 = (SEXT40(State.a[OP[0]]) < SEXT40(State.a[OP[1]])) ? 1 : 0; trace_output (OP_FLAG); } /* cmpeq */ void OP_400 () { trace_input ("cmpeq", OP_REG, OP_REG, OP_VOID); State.F1 = State.F0; State.F0 = (State.regs[OP[0]] == State.regs[OP[1]]) ? 1 : 0; trace_output (OP_FLAG); } /* cmpeq */ void OP_1403 () { trace_input ("cmpeq", OP_ACCUM, OP_ACCUM, OP_VOID); State.F1 = State.F0; State.F0 = ((State.a[OP[0]] & MASK40) == (State.a[OP[1]] & MASK40)) ? 1 : 0; trace_output (OP_FLAG); } /* cmpeqi.s */ void OP_401 () { trace_input ("cmpeqi.s", OP_REG, OP_CONSTANT4, OP_VOID); State.F1 = State.F0; State.F0 = (State.regs[OP[0]] == (reg_t)SEXT4(OP[1])) ? 1 : 0; trace_output (OP_FLAG); } /* cmpeqi.l */ void OP_2000000 () { trace_input ("cmpeqi.l", OP_REG, OP_CONSTANT16, OP_VOID); State.F1 = State.F0; State.F0 = (State.regs[OP[0]] == (reg_t)OP[1]) ? 1 : 0; trace_output (OP_FLAG); } /* cmpi.s */ void OP_601 () { trace_input ("cmpi.s", OP_REG, OP_CONSTANT4, OP_VOID); State.F1 = State.F0; State.F0 = ((int16)(State.regs[OP[0]]) < (int16)SEXT4(OP[1])) ? 1 : 0; trace_output (OP_FLAG); } /* cmpi.l */ void OP_3000000 () { trace_input ("cmpi.l", OP_REG, OP_CONSTANT16, OP_VOID); State.F1 = State.F0; State.F0 = ((int16)(State.regs[OP[0]]) < (int16)(OP[1])) ? 1 : 0; trace_output (OP_FLAG); } /* cmpu */ void OP_4600 () { trace_input ("cmpu", OP_REG, OP_REG, OP_VOID); State.F1 = State.F0; State.F0 = (State.regs[OP[0]] < State.regs[OP[1]]) ? 1 : 0; trace_output (OP_FLAG); } /* cmpui */ void OP_23000000 () { trace_input ("cmpui", OP_REG, OP_CONSTANT16, OP_VOID); State.F1 = State.F0; State.F0 = (State.regs[OP[0]] < (reg_t)OP[1]) ? 1 : 0; trace_output (OP_FLAG); } /* cpfg */ void OP_4E09 () { uint8 *src, *dst; trace_input ("cpfg", OP_FLAG_OUTPUT, OP_FLAG, OP_VOID); if (OP[0] == 0) dst = &State.F0; else dst = &State.F1; if (OP[1] == 0) src = &State.F0; else if (OP[1] == 1) src = &State.F1; else src = &State.C; *dst = *src; trace_output (OP_FLAG); } /* dbt */ void OP_5F20 () { /* d10v_callback->printf_filtered(d10v_callback, "***** DBT ***** PC=%x\n",PC); */ State.exception = SIGTRAP; } /* divs */ void OP_14002800 () { uint16 foo, tmp, tmpf; trace_input ("divs", OP_DREG, OP_REG, OP_VOID); foo = (State.regs[OP[0]] << 1) | (State.regs[OP[0]+1] >> 15); tmp = (int16)foo - (int16)(State.regs[OP[1]]); tmpf = (foo >= State.regs[OP[1]]) ? 1 : 0; State.regs[OP[0]] = (tmpf == 1) ? tmp : foo; State.regs[OP[0]+1] = (State.regs[OP[0]+1] << 1) | tmpf; trace_output (OP_DREG); } /* exef0f */ void OP_4E04 () { trace_input ("exef0f", OP_VOID, OP_VOID, OP_VOID); State.exe = (State.F0 == 0); trace_output (OP_FLAG); } /* exef0t */ void OP_4E24 () { trace_input ("exef0t", OP_VOID, OP_VOID, OP_VOID); State.exe = (State.F0 != 0); trace_output (OP_FLAG); } /* exef1f */ void OP_4E40 () { trace_input ("exef1f", OP_VOID, OP_VOID, OP_VOID); State.exe = (State.F1 == 0); trace_output (OP_FLAG); } /* exef1t */ void OP_4E42 () { trace_input ("exef1t", OP_VOID, OP_VOID, OP_VOID); State.exe = (State.F1 != 0); trace_output (OP_FLAG); } /* exefaf */ void OP_4E00 () { trace_input ("exefaf", OP_VOID, OP_VOID, OP_VOID); State.exe = (State.F0 == 0) & (State.F1 == 0); trace_output (OP_FLAG); } /* exefat */ void OP_4E02 () { trace_input ("exefat", OP_VOID, OP_VOID, OP_VOID); State.exe = (State.F0 == 0) & (State.F1 != 0); trace_output (OP_FLAG); } /* exetaf */ void OP_4E20 () { trace_input ("exetaf", OP_VOID, OP_VOID, OP_VOID); State.exe = (State.F0 != 0) & (State.F1 == 0); trace_output (OP_FLAG); } /* exetat */ void OP_4E22 () { trace_input ("exetat", OP_VOID, OP_VOID, OP_VOID); State.exe = (State.F0 != 0) & (State.F1 != 0); trace_output (OP_FLAG); } /* exp */ void OP_15002A00 () { uint32 tmp, foo; int i; trace_input ("exp", OP_REG_OUTPUT, OP_DREG, OP_VOID); if (((int16)State.regs[OP[1]]) >= 0) tmp = (State.regs[OP[1]] << 16) | State.regs[OP[1]+1]; else tmp = ~((State.regs[OP[1]] << 16) | State.regs[OP[1]+1]); foo = 0x40000000; for (i=1;i<17;i++) { if (tmp & foo) { State.regs[OP[0]] = i-1; trace_output (OP_REG); return; } foo >>= 1; } State.regs[OP[0]] = 16; trace_output (OP_REG); } /* exp */ void OP_15002A02 () { int64 tmp, foo; int i; trace_input ("exp", OP_REG_OUTPUT, OP_ACCUM, OP_VOID); tmp = SEXT40(State.a[OP[1]]); if (tmp < 0) tmp = ~tmp & MASK40; foo = 0x4000000000LL; for (i=1;i<25;i++) { if (tmp & foo) { State.regs[OP[0]] = i-9; trace_output (OP_REG); return; } foo >>= 1; } State.regs[OP[0]] = 16; trace_output (OP_REG); } /* jl */ void OP_4D00 () { trace_input ("jl", OP_REG, OP_R2, OP_R3); State.regs[13] = PC+1; JMP (State.regs[OP[0]]); trace_output (OP_VOID); } /* jmp */ void OP_4C00 () { trace_input ("jmp", OP_REG, (OP[0] == 13) ? OP_R2 : OP_VOID, (OP[0] == 13) ? OP_R3 : OP_VOID); JMP (State.regs[OP[0]]); trace_output (OP_VOID); } /* ld */ void OP_30000000 () { trace_input ("ld", OP_REG_OUTPUT, OP_MEMREF2, OP_VOID); State.regs[OP[0]] = RW (OP[1] + State.regs[OP[2]]); trace_output (OP_REG); } /* ld */ void OP_6401 () { trace_input ("ld", OP_REG_OUTPUT, OP_POSTDEC, OP_VOID); State.regs[OP[0]] = RW (State.regs[OP[1]]); INC_ADDR(State.regs[OP[1]],-2); trace_output (OP_REG); } /* ld */ void OP_6001 () { trace_input ("ld", OP_REG_OUTPUT, OP_POSTINC, OP_VOID); State.regs[OP[0]] = RW (State.regs[OP[1]]); INC_ADDR(State.regs[OP[1]],2); trace_output (OP_REG); } /* ld */ void OP_6000 () { trace_input ("ld", OP_REG_OUTPUT, OP_MEMREF, OP_VOID); State.regs[OP[0]] = RW (State.regs[OP[1]]); trace_output (OP_REG); } /* ld2w */ void OP_31000000 () { uint16 addr = State.regs[OP[2]]; trace_input ("ld2w", OP_REG_OUTPUT, OP_MEMREF2, OP_VOID); State.regs[OP[0]] = RW (OP[1] + addr); State.regs[OP[0]+1] = RW (OP[1] + addr + 2); trace_output (OP_DREG); } /* ld2w */ void OP_6601 () { uint16 addr = State.regs[OP[1]]; trace_input ("ld2w", OP_REG_OUTPUT, OP_POSTDEC, OP_VOID); State.regs[OP[0]] = RW (addr); State.regs[OP[0]+1] = RW (addr+2); INC_ADDR(State.regs[OP[1]],-4); trace_output (OP_DREG); } /* ld2w */ void OP_6201 () { uint16 addr = State.regs[OP[1]]; trace_input ("ld2w", OP_REG_OUTPUT, OP_POSTINC, OP_VOID); State.regs[OP[0]] = RW (addr); State.regs[OP[0]+1] = RW (addr+2); INC_ADDR(State.regs[OP[1]],4); trace_output (OP_DREG); } /* ld2w */ void OP_6200 () { uint16 addr = State.regs[OP[1]]; trace_input ("ld2w", OP_REG_OUTPUT, OP_MEMREF, OP_VOID); State.regs[OP[0]] = RW (addr); State.regs[OP[0]+1] = RW (addr+2); trace_output (OP_DREG); } /* ldb */ void OP_38000000 () { trace_input ("ldb", OP_REG_OUTPUT, OP_MEMREF2, OP_VOID); State.regs[OP[0]] = SEXT8 (RB (OP[1] + State.regs[OP[2]])); trace_output (OP_REG); } /* ldb */ void OP_7000 () { trace_input ("ldb", OP_REG_OUTPUT, OP_MEMREF, OP_VOID); State.regs[OP[0]] = SEXT8 (RB (State.regs[OP[1]])); trace_output (OP_REG); } /* ldi.s */ void OP_4001 () { trace_input ("ldi.s", OP_REG_OUTPUT, OP_CONSTANT4, OP_VOID); State.regs[OP[0]] = SEXT4(OP[1]); trace_output (OP_REG); } /* ldi.l */ void OP_20000000 () { trace_input ("ldi.l", OP_REG_OUTPUT, OP_CONSTANT16, OP_VOID); State.regs[OP[0]] = OP[1]; trace_output (OP_REG); } /* ldub */ void OP_39000000 () { trace_input ("ldub", OP_REG_OUTPUT, OP_MEMREF2, OP_VOID); State.regs[OP[0]] = RB (OP[1] + State.regs[OP[2]]); trace_output (OP_REG); } /* ldub */ void OP_7200 () { trace_input ("ldub", OP_REG_OUTPUT, OP_MEMREF, OP_VOID); State.regs[OP[0]] = RB (State.regs[OP[1]]); trace_output (OP_REG); } /* mac */ void OP_2A00 () { int64 tmp; trace_input ("mac", OP_ACCUM, OP_REG, OP_REG); tmp = SEXT40 ((int16)(State.regs[OP[1]]) * (int16)(State.regs[OP[2]])); if (State.FX) tmp = SEXT40( (tmp << 1) & MASK40); if (State.ST && tmp > MAX32) tmp = MAX32; tmp += SEXT40(State.a[OP[0]]); if (State.ST) { if (tmp > MAX32) State.a[OP[0]] = MAX32; else if (tmp < MIN32) State.a[OP[0]] = MIN32; else State.a[OP[0]] = tmp & MASK40; } else State.a[OP[0]] = tmp & MASK40; trace_output (OP_ACCUM); } /* macsu */ void OP_1A00 () { int64 tmp; trace_input ("macsu", OP_ACCUM, OP_REG, OP_REG); tmp = SEXT40 ((int16)State.regs[OP[1]] * State.regs[OP[2]]); if (State.FX) tmp = SEXT40( (tmp << 1) & MASK40); State.a[OP[0]] = (SEXT40 (State.a[OP[0]]) + tmp) & MASK40; trace_output (OP_ACCUM); } /* macu */ void OP_3A00 () { uint64 tmp; uint32 src1; uint32 src2; trace_input ("macu", OP_ACCUM, OP_REG, OP_REG); src1 = (uint16) State.regs[OP[1]]; src2 = (uint16) State.regs[OP[2]]; tmp = src1 * src2; if (State.FX) tmp = (tmp << 1); State.a[OP[0]] = (State.a[OP[0]] + tmp) & MASK40; trace_output (OP_ACCUM); } /* max */ void OP_2600 () { trace_input ("max", OP_REG, OP_REG, OP_VOID); State.F1 = State.F0; if ((int16)State.regs[OP[1]] > (int16)State.regs[OP[0]]) { State.regs[OP[0]] = State.regs[OP[1]]; State.F0 = 1; } else State.F0 = 0; trace_output (OP_REG); } /* max */ void OP_3600 () { int64 tmp; trace_input ("max", OP_ACCUM, OP_DREG, OP_VOID); State.F1 = State.F0; tmp = SEXT16 (State.regs[OP[1]]) << 16 | State.regs[OP[1]+1]; if (tmp > SEXT40(State.a[OP[0]])) { State.a[OP[0]] = tmp & MASK40; State.F0 = 1; } else State.F0 = 0; trace_output (OP_ACCUM); } /* max */ void OP_3602 () { trace_input ("max", OP_ACCUM, OP_ACCUM, OP_VOID); State.F1 = State.F0; if (SEXT40(State.a[OP[1]]) > SEXT40(State.a[OP[0]])) { State.a[OP[0]] = State.a[OP[1]]; State.F0 = 1; } else State.F0 = 0; trace_output (OP_ACCUM); } /* min */ void OP_2601 () { trace_input ("min", OP_REG, OP_REG, OP_VOID); State.F1 = State.F0; if ((int16)State.regs[OP[1]] < (int16)State.regs[OP[0]]) { State.regs[OP[0]] = State.regs[OP[1]]; State.F0 = 1; } else State.F0 = 0; trace_output (OP_REG); } /* min */ void OP_3601 () { int64 tmp; trace_input ("min", OP_ACCUM, OP_DREG, OP_VOID); State.F1 = State.F0; tmp = SEXT16 (State.regs[OP[1]]) << 16 | State.regs[OP[1]+1]; if (tmp < SEXT40(State.a[OP[0]])) { State.a[OP[0]] = tmp & MASK40; State.F0 = 1; } else State.F0 = 0; trace_output (OP_ACCUM); } /* min */ void OP_3603 () { trace_input ("min", OP_ACCUM, OP_ACCUM, OP_VOID); State.F1 = State.F0; if (SEXT40(State.a[OP[1]]) < SEXT40(State.a[OP[0]])) { State.a[OP[0]] = State.a[OP[1]]; State.F0 = 1; } else State.F0 = 0; trace_output (OP_ACCUM); } /* msb */ void OP_2800 () { int64 tmp; trace_input ("msb", OP_ACCUM, OP_REG, OP_REG); tmp = SEXT40 ((int16)(State.regs[OP[1]]) * (int16)(State.regs[OP[2]])); if (State.FX) tmp = SEXT40 ((tmp << 1) & MASK40); if (State.ST && tmp > MAX32) tmp = MAX32; tmp = SEXT40(State.a[OP[0]]) - tmp; if (State.ST) { if (tmp > MAX32) State.a[OP[0]] = MAX32; else if (tmp < MIN32) State.a[OP[0]] = MIN32; else State.a[OP[0]] = tmp & MASK40; } else State.a[OP[0]] = tmp & MASK40; trace_output (OP_ACCUM); } /* msbsu */ void OP_1800 () { int64 tmp; trace_input ("msbsu", OP_ACCUM, OP_REG, OP_REG); tmp = SEXT40 ((int16)State.regs[OP[1]] * State.regs[OP[2]]); if (State.FX) tmp = SEXT40( (tmp << 1) & MASK40); State.a[OP[0]] = (SEXT40 (State.a[OP[0]]) - tmp) & MASK40; trace_output (OP_ACCUM); } /* msbu */ void OP_3800 () { uint64 tmp; uint32 src1; uint32 src2; trace_input ("msbu", OP_ACCUM, OP_REG, OP_REG); src1 = (uint16) State.regs[OP[1]]; src2 = (uint16) State.regs[OP[2]]; tmp = src1 * src2; if (State.FX) tmp = (tmp << 1); State.a[OP[0]] = (State.a[OP[0]] - tmp) & MASK40; trace_output (OP_ACCUM); } /* mul */ void OP_2E00 () { trace_input ("mul", OP_REG, OP_REG, OP_VOID); State.regs[OP[0]] *= State.regs[OP[1]]; trace_output (OP_REG); } /* mulx */ void OP_2C00 () { int64 tmp; trace_input ("mulx", OP_ACCUM_OUTPUT, OP_REG, OP_REG); tmp = SEXT40 ((int16)(State.regs[OP[1]]) * (int16)(State.regs[OP[2]])); if (State.FX) tmp = SEXT40 ((tmp << 1) & MASK40); if (State.ST && tmp > MAX32) State.a[OP[0]] = MAX32; else State.a[OP[0]] = tmp & MASK40; trace_output (OP_ACCUM); } /* mulxsu */ void OP_1C00 () { int64 tmp; trace_input ("mulxsu", OP_ACCUM_OUTPUT, OP_REG, OP_REG); tmp = SEXT40 ((int16)(State.regs[OP[1]]) * State.regs[OP[2]]); if (State.FX) tmp <<= 1; State.a[OP[0]] = tmp & MASK40; trace_output (OP_ACCUM); } /* mulxu */ void OP_3C00 () { uint64 tmp; uint32 src1; uint32 src2; trace_input ("mulxu", OP_ACCUM_OUTPUT, OP_REG, OP_REG); src1 = (uint16) State.regs[OP[1]]; src2 = (uint16) State.regs[OP[2]]; tmp = src1 * src2; if (State.FX) tmp <<= 1; State.a[OP[0]] = tmp & MASK40; trace_output (OP_ACCUM); } /* mv */ void OP_4000 () { trace_input ("mv", OP_REG_OUTPUT, OP_REG, OP_VOID); State.regs[OP[0]] = State.regs[OP[1]]; trace_output (OP_REG); } /* mv2w */ void OP_5000 () { trace_input ("mv2w", OP_DREG_OUTPUT, OP_DREG, OP_VOID); State.regs[OP[0]] = State.regs[OP[1]]; State.regs[OP[0]+1] = State.regs[OP[1]+1]; trace_output (OP_DREG); } /* mv2wfac */ void OP_3E00 () { trace_input ("mv2wfac", OP_DREG_OUTPUT, OP_ACCUM, OP_VOID); State.regs[OP[0]] = (State.a[OP[1]] >> 16) & 0xffff; State.regs[OP[0]+1] = State.a[OP[1]] & 0xffff; trace_output (OP_DREG); } /* mv2wtac */ void OP_3E01 () { trace_input ("mv2wtac", OP_DREG, OP_ACCUM_OUTPUT, OP_VOID); State.a[OP[1]] = (SEXT16 (State.regs[OP[0]]) << 16 | State.regs[OP[0]+1]) & MASK40; trace_output (OP_ACCUM_REVERSE); } /* mvac */ void OP_3E03 () { trace_input ("mvac", OP_ACCUM_OUTPUT, OP_ACCUM, OP_VOID); State.a[OP[0]] = State.a[OP[1]]; trace_output (OP_ACCUM); } /* mvb */ void OP_5400 () { trace_input ("mvb", OP_REG_OUTPUT, OP_REG, OP_VOID); State.regs[OP[0]] = SEXT8 (State.regs[OP[1]] & 0xff); trace_output (OP_REG); } /* mvf0f */ void OP_4400 () { trace_input ("mf0f", OP_REG_OUTPUT, OP_REG, OP_VOID); if (State.F0 == 0) State.regs[OP[0]] = State.regs[OP[1]]; trace_output (OP_REG); } /* mvf0t */ void OP_4401 () { trace_input ("mf0t", OP_REG_OUTPUT, OP_REG, OP_VOID); if (State.F0) State.regs[OP[0]] = State.regs[OP[1]]; trace_output (OP_REG); } /* mvfacg */ void OP_1E04 () { trace_input ("mvfacg", OP_REG_OUTPUT, OP_ACCUM, OP_VOID); State.regs[OP[0]] = (State.a[OP[1]] >> 32) & 0xff; trace_output (OP_ACCUM); } /* mvfachi */ void OP_1E00 () { trace_input ("mvfachi", OP_REG_OUTPUT, OP_ACCUM, OP_VOID); State.regs[OP[0]] = (State.a[OP[1]] >> 16) & 0xffff; trace_output (OP_REG); } /* mvfaclo */ void OP_1E02 () { trace_input ("mvfaclo", OP_REG_OUTPUT, OP_ACCUM, OP_VOID); State.regs[OP[0]] = State.a[OP[1]] & 0xffff; trace_output (OP_REG); } /* mvfc */ void OP_5200 () { trace_input ("mvfc", OP_REG_OUTPUT, OP_CR, OP_VOID); if (OP[1] == 0) { /* PSW is treated specially */ PSW = 0; if (State.SM) PSW |= 0x8000; if (State.EA) PSW |= 0x2000; if (State.DB) PSW |= 0x1000; if (State.DM) PSW |= 0x800; if (State.IE) PSW |= 0x400; if (State.RP) PSW |= 0x200; if (State.MD) PSW |= 0x100; if (State.FX) PSW |= 0x80; if (State.ST) PSW |= 0x40; if (State.F0) PSW |= 8; if (State.F1) PSW |= 4; if (State.C) PSW |= 1; } State.regs[OP[0]] = State.cregs[OP[1]]; trace_output (OP_REG); } /* mvtacg */ void OP_1E41 () { trace_input ("mvtacg", OP_REG, OP_ACCUM, OP_VOID); State.a[OP[1]] &= MASK32; State.a[OP[1]] |= (int64)(State.regs[OP[0]] & 0xff) << 32; trace_output (OP_ACCUM_REVERSE); } /* mvtachi */ void OP_1E01 () { uint16 tmp; trace_input ("mvtachi", OP_REG, OP_ACCUM, OP_VOID); tmp = State.a[OP[1]] & 0xffff; State.a[OP[1]] = (SEXT16 (State.regs[OP[0]]) << 16 | tmp) & MASK40; trace_output (OP_ACCUM_REVERSE); } /* mvtaclo */ void OP_1E21 () { trace_input ("mvtaclo", OP_REG, OP_ACCUM, OP_VOID); State.a[OP[1]] = (SEXT16 (State.regs[OP[0]])) & MASK40; trace_output (OP_ACCUM_REVERSE); } /* mvtc */ void OP_5600 () { trace_input ("mvtc", OP_REG, OP_CR_OUTPUT, OP_VOID); State.cregs[OP[1]] = State.regs[OP[0]]; if (OP[1] == 0) { /* PSW is treated specially */ State.SM = (PSW & 0x8000) ? 1 : 0; State.EA = (PSW & 0x2000) ? 1 : 0; State.DB = (PSW & 0x1000) ? 1 : 0; State.DM = (PSW & 0x800) ? 1 : 0; State.IE = (PSW & 0x400) ? 1 : 0; State.RP = (PSW & 0x200) ? 1 : 0; State.MD = (PSW & 0x100) ? 1 : 0; State.FX = (PSW & 0x80) ? 1 : 0; State.ST = (PSW & 0x40) ? 1 : 0; State.F0 = (PSW & 8) ? 1 : 0; State.F1 = (PSW & 4) ? 1 : 0; State.C = PSW & 1; if (State.ST && !State.FX) { (*d10v_callback->printf_filtered) (d10v_callback, "ERROR at PC 0x%x: ST can only be set when FX is set.\n", PC<<2); State.exception = SIGILL; } } trace_output (OP_CR_REVERSE); } /* mvub */ void OP_5401 () { trace_input ("mvub", OP_REG_OUTPUT, OP_REG, OP_VOID); State.regs[OP[0]] = State.regs[OP[1]] & 0xff; trace_output (OP_REG); } /* neg */ void OP_4605 () { trace_input ("neg", OP_REG, OP_VOID, OP_VOID); State.regs[OP[0]] = 0 - State.regs[OP[0]]; trace_output (OP_REG); } /* neg */ void OP_5605 () { int64 tmp; trace_input ("neg", OP_ACCUM, OP_VOID, OP_VOID); tmp = -SEXT40(State.a[OP[0]]); if (State.ST) { if ( tmp > MAX32) State.a[OP[0]] = MAX32; else if (tmp < MIN32) State.a[OP[0]] = MIN32; else State.a[OP[0]] = tmp & MASK40; } else State.a[OP[0]] = tmp & MASK40; trace_output (OP_ACCUM); } /* nop */ void OP_5E00 () { trace_input ("nop", OP_VOID, OP_VOID, OP_VOID); ins_type_counters[ (int)State.ins_type ]--; /* don't count nops as normal instructions */ switch (State.ins_type) { default: ins_type_counters[ (int)INS_UNKNOWN ]++; break; case INS_LEFT_PARALLEL: /* Don't count a parallel op that includes a NOP as a true parallel op */ ins_type_counters[ (int)INS_RIGHT_PARALLEL ]--; ins_type_counters[ (int)INS_RIGHT ]++; ins_type_counters[ (int)INS_LEFT_NOPS ]++; break; case INS_LEFT: case INS_LEFT_COND_EXE: ins_type_counters[ (int)INS_LEFT_NOPS ]++; break; case INS_RIGHT_PARALLEL: /* Don't count a parallel op that includes a NOP as a true parallel op */ ins_type_counters[ (int)INS_LEFT_PARALLEL ]--; ins_type_counters[ (int)INS_LEFT ]++; ins_type_counters[ (int)INS_RIGHT_NOPS ]++; break; case INS_RIGHT: case INS_RIGHT_COND_EXE: ins_type_counters[ (int)INS_RIGHT_NOPS ]++; break; } trace_output (OP_VOID); } /* not */ void OP_4603 () { trace_input ("not", OP_REG, OP_VOID, OP_VOID); State.regs[OP[0]] = ~(State.regs[OP[0]]); trace_output (OP_REG); } /* or */ void OP_800 () { trace_input ("or", OP_REG, OP_REG, OP_VOID); State.regs[OP[0]] |= State.regs[OP[1]]; trace_output (OP_REG); } /* or3 */ void OP_4000000 () { trace_input ("or3", OP_REG_OUTPUT, OP_REG, OP_CONSTANT16); State.regs[OP[0]] = State.regs[OP[1]] | OP[2]; trace_output (OP_REG); } /* rac */ void OP_5201 () { int64 tmp; int shift = SEXT3 (OP[2]); trace_input ("rac", OP_DREG_OUTPUT, OP_ACCUM, OP_CONSTANT3); if (OP[1] != 0) { (*d10v_callback->printf_filtered) (d10v_callback, "ERROR at PC 0x%x: instruction only valid for A0\n", PC<<2); State.exception = SIGILL; } State.F1 = State.F0; tmp = SEXT56 ((State.a[0] << 16) | (State.a[1] & 0xffff)); if (shift >=0) tmp <<= shift; else tmp >>= -shift; tmp += 0x8000; tmp >>= 16; /* look at bits 0:43 */ if (tmp > SEXT44 (SIGNED64 (0x0007fffffff))) { State.regs[OP[0]] = 0x7fff; State.regs[OP[0]+1] = 0xffff; State.F0 = 1; } else if (tmp < SEXT44 (SIGNED64 (0xfff80000000))) { State.regs[OP[0]] = 0x8000; State.regs[OP[0]+1] = 0; State.F0 = 1; } else { State.regs[OP[0]] = (tmp >> 16) & 0xffff; State.regs[OP[0]+1] = tmp & 0xffff; State.F0 = 0; } trace_output (OP_DREG); } /* rachi */ void OP_4201 () { signed64 tmp; int shift = SEXT3 (OP[2]); trace_input ("rachi", OP_REG_OUTPUT, OP_ACCUM, OP_CONSTANT3); State.F1 = State.F0; if (shift >=0) tmp = SEXT40 (State.a[OP[1]]) << shift; else tmp = SEXT40 (State.a[OP[1]]) >> -shift; tmp += 0x8000; if (tmp > SEXT44 (SIGNED64 (0x0007fffffff))) { State.regs[OP[0]] = 0x7fff; State.F0 = 1; } else if (tmp < SEXT44 (SIGNED64 (0xfff80000000))) { State.regs[OP[0]] = 0x8000; State.F0 = 1; } else { State.regs[OP[0]] = (tmp >> 16) & 0xffff; State.F0 = 0; } trace_output (OP_REG); } /* rep */ void OP_27000000 () { trace_input ("rep", OP_REG, OP_CONSTANT16, OP_VOID); RPT_S = PC + 1; RPT_E = PC + OP[1]; RPT_C = State.regs[OP[0]]; State.RP = 1; if (RPT_C == 0) { (*d10v_callback->printf_filtered) (d10v_callback, "ERROR: rep with count=0 is illegal.\n"); State.exception = SIGILL; } if (OP[1] < 4) { (*d10v_callback->printf_filtered) (d10v_callback, "ERROR: rep must include at least 4 instructions.\n"); State.exception = SIGILL; } trace_output (OP_VOID); } /* repi */ void OP_2F000000 () { trace_input ("repi", OP_CONSTANT16, OP_CONSTANT16, OP_VOID); RPT_S = PC + 1; RPT_E = PC + OP[1]; RPT_C = OP[0]; State.RP = 1; if (RPT_C == 0) { (*d10v_callback->printf_filtered) (d10v_callback, "ERROR: repi with count=0 is illegal.\n"); State.exception = SIGILL; } if (OP[1] < 4) { (*d10v_callback->printf_filtered) (d10v_callback, "ERROR: repi must include at least 4 instructions.\n"); State.exception = SIGILL; } trace_output (OP_VOID); } /* rtd */ void OP_5F60 () { d10v_callback->printf_filtered(d10v_callback, "ERROR: rtd - NOT IMPLEMENTED\n"); State.exception = SIGILL; } /* rte */ void OP_5F40 () { trace_input ("rte", OP_VOID, OP_VOID, OP_VOID); PC = BPC; PSW = BPSW; trace_output (OP_VOID); } /* sadd */ void OP_1223 () { int64 tmp; trace_input ("sadd", OP_ACCUM, OP_ACCUM, OP_VOID); tmp = SEXT40(State.a[OP[0]]) + (SEXT40(State.a[OP[1]]) >> 16); if (State.ST) { if (tmp > MAX32) State.a[OP[0]] = MAX32; else if (tmp < MIN32) State.a[OP[0]] = MIN32; else State.a[OP[0]] = tmp & MASK40; } else State.a[OP[0]] = tmp & MASK40; trace_output (OP_ACCUM); } /* setf0f */ void OP_4611 () { trace_input ("setf0f", OP_REG_OUTPUT, OP_VOID, OP_VOID); State.regs[OP[0]] = (State.F0 == 0) ? 1 : 0; trace_output (OP_REG); } /* setf0t */ void OP_4613 () { trace_input ("setf0t", OP_REG_OUTPUT, OP_VOID, OP_VOID); State.regs[OP[0]] = (State.F0 == 1) ? 1 : 0; trace_output (OP_REG); } /* sleep */ void OP_5FC0 () { trace_input ("sleep", OP_VOID, OP_VOID, OP_VOID); State.IE = 1; trace_output (OP_VOID); } /* sll */ void OP_2200 () { trace_input ("sll", OP_REG, OP_REG, OP_VOID); State.regs[OP[0]] <<= (State.regs[OP[1]] & 0xf); trace_output (OP_REG); } /* sll */ void OP_3200 () { int64 tmp; trace_input ("sll", OP_ACCUM, OP_REG, OP_VOID); if ((State.regs[OP[1]] & 31) <= 16) tmp = SEXT40 (State.a[OP[0]]) << (State.regs[OP[1]] & 31); else { (*d10v_callback->printf_filtered) (d10v_callback, "ERROR: shift value %d too large.\n", State.regs[OP[1]] & 31); State.exception = SIGILL; return; } if (State.ST) { if (tmp > MAX32) State.a[OP[0]] = MAX32; else if (tmp < 0xffffff80000000LL) State.a[OP[0]] = MIN32; else State.a[OP[0]] = tmp & MASK40; } else State.a[OP[0]] = tmp & MASK40; trace_output (OP_ACCUM); } /* slli */ void OP_2201 () { trace_input ("slli", OP_REG, OP_CONSTANT16, OP_VOID); State.regs[OP[0]] <<= OP[1]; trace_output (OP_REG); } /* slli */ void OP_3201 () { int64 tmp; if (OP[1] == 0) OP[1] = 16; trace_input ("slli", OP_ACCUM, OP_CONSTANT16, OP_VOID); tmp = SEXT40(State.a[OP[0]]) << OP[1]; if (State.ST) { if (tmp > MAX32) State.a[OP[0]] = MAX32; else if (tmp < 0xffffff80000000LL) State.a[OP[0]] = MIN32; else State.a[OP[0]] = tmp & MASK40; } else State.a[OP[0]] = tmp & MASK40; trace_output (OP_ACCUM); } /* slx */ void OP_460B () { trace_input ("slx", OP_REG, OP_FLAG, OP_VOID); State.regs[OP[0]] = (State.regs[OP[0]] << 1) | State.F0; trace_output (OP_REG); } /* sra */ void OP_2400 () { trace_input ("sra", OP_REG, OP_REG, OP_VOID); State.regs[OP[0]] = ((int16)(State.regs[OP[0]])) >> (State.regs[OP[1]] & 0xf); trace_output (OP_REG); } /* sra */ void OP_3400 () { trace_input ("sra", OP_ACCUM, OP_REG, OP_VOID); if ((State.regs[OP[1]] & 31) <= 16) State.a[OP[0]] = (SEXT40(State.a[OP[0]]) >> (State.regs[OP[1]] & 31)) & MASK40; else { (*d10v_callback->printf_filtered) (d10v_callback, "ERROR: shift value %d too large.\n", State.regs[OP[1]] & 31); State.exception = SIGILL; return; } trace_output (OP_ACCUM); } /* srai */ void OP_2401 () { trace_input ("srai", OP_REG, OP_CONSTANT16, OP_VOID); State.regs[OP[0]] = ((int16)(State.regs[OP[0]])) >> OP[1]; trace_output (OP_REG); } /* srai */ void OP_3401 () { if (OP[1] == 0) OP[1] = 16; trace_input ("srai", OP_ACCUM, OP_CONSTANT16, OP_VOID); State.a[OP[0]] = (SEXT40(State.a[OP[0]]) >> OP[1]) & MASK40; trace_output (OP_ACCUM); } /* srl */ void OP_2000 () { trace_input ("srl", OP_REG, OP_REG, OP_VOID); State.regs[OP[0]] >>= (State.regs[OP[1]] & 0xf); trace_output (OP_REG); } /* srl */ void OP_3000 () { trace_input ("srl", OP_ACCUM, OP_REG, OP_VOID); if ((State.regs[OP[1]] & 31) <= 16) State.a[OP[0]] = (uint64)((State.a[OP[0]] & MASK40) >> (State.regs[OP[1]] & 31)); else { (*d10v_callback->printf_filtered) (d10v_callback, "ERROR: shift value %d too large.\n", State.regs[OP[1]] & 31); State.exception = SIGILL; return; } trace_output (OP_ACCUM); } /* srli */ void OP_2001 () { trace_input ("srli", OP_REG, OP_CONSTANT16, OP_VOID); State.regs[OP[0]] >>= OP[1]; trace_output (OP_REG); } /* srli */ void OP_3001 () { if (OP[1] == 0) OP[1] = 16; trace_input ("srli", OP_ACCUM, OP_CONSTANT16, OP_VOID); State.a[OP[0]] = (uint64)(State.a[OP[0]] & MASK40) >> OP[1]; trace_output (OP_ACCUM); } /* srx */ void OP_4609 () { uint16 tmp; trace_input ("srx", OP_REG, OP_FLAG, OP_VOID); tmp = State.F0 << 15; State.regs[OP[0]] = (State.regs[OP[0]] >> 1) | tmp; trace_output (OP_REG); } /* st */ void OP_34000000 () { trace_input ("st", OP_REG, OP_MEMREF2, OP_VOID); SW (OP[1] + State.regs[OP[2]], State.regs[OP[0]]); trace_output (OP_VOID); } /* st */ void OP_6800 () { trace_input ("st", OP_REG, OP_MEMREF, OP_VOID); SW (State.regs[OP[1]], State.regs[OP[0]]); trace_output (OP_VOID); } /* st */ void OP_6C1F () { trace_input ("st", OP_REG, OP_PREDEC, OP_VOID); if ( OP[1] != 15 ) { (*d10v_callback->printf_filtered) (d10v_callback, "ERROR: cannot pre-decrement any registers but r15 (SP).\n"); State.exception = SIGILL; return; } State.regs[OP[1]] -= 2; SW (State.regs[OP[1]], State.regs[OP[0]]); trace_output (OP_VOID); } /* st */ void OP_6801 () { trace_input ("st", OP_REG, OP_POSTINC, OP_VOID); SW (State.regs[OP[1]], State.regs[OP[0]]); INC_ADDR (State.regs[OP[1]],2); trace_output (OP_VOID); } /* st */ void OP_6C01 () { trace_input ("st", OP_REG, OP_POSTDEC, OP_VOID); if ( OP[1] == 15 ) { (*d10v_callback->printf_filtered) (d10v_callback, "ERROR: cannot post-decrement register r15 (SP).\n"); State.exception = SIGILL; return; } SW (State.regs[OP[1]], State.regs[OP[0]]); INC_ADDR (State.regs[OP[1]],-2); trace_output (OP_VOID); } /* st2w */ void OP_35000000 () { trace_input ("st2w", OP_DREG, OP_MEMREF2, OP_VOID); SW (State.regs[OP[2]]+OP[1], State.regs[OP[0]]); SW (State.regs[OP[2]]+OP[1]+2, State.regs[OP[0]+1]); trace_output (OP_VOID); } /* st2w */ void OP_6A00 () { trace_input ("st2w", OP_DREG, OP_MEMREF, OP_VOID); SW (State.regs[OP[1]], State.regs[OP[0]]); SW (State.regs[OP[1]]+2, State.regs[OP[0]+1]); trace_output (OP_VOID); } /* st2w */ void OP_6E1F () { trace_input ("st2w", OP_DREG, OP_PREDEC, OP_VOID); if ( OP[1] != 15 ) { (*d10v_callback->printf_filtered) (d10v_callback, "ERROR: cannot pre-decrement any registers but r15 (SP).\n"); State.exception = SIGILL; return; } State.regs[OP[1]] -= 4; SW (State.regs[OP[1]], State.regs[OP[0]]); SW (State.regs[OP[1]]+2, State.regs[OP[0]+1]); trace_output (OP_VOID); } /* st2w */ void OP_6A01 () { trace_input ("st2w", OP_DREG, OP_POSTINC, OP_VOID); SW (State.regs[OP[1]], State.regs[OP[0]]); SW (State.regs[OP[1]]+2, State.regs[OP[0]+1]); INC_ADDR (State.regs[OP[1]],4); trace_output (OP_VOID); } /* st2w */ void OP_6E01 () { trace_input ("st2w", OP_DREG, OP_POSTDEC, OP_VOID); if ( OP[1] == 15 ) { (*d10v_callback->printf_filtered) (d10v_callback, "ERROR: cannot post-decrement register r15 (SP).\n"); State.exception = SIGILL; return; } SW (State.regs[OP[1]], State.regs[OP[0]]); SW (State.regs[OP[1]]+2, State.regs[OP[0]+1]); INC_ADDR (State.regs[OP[1]],-4); trace_output (OP_VOID); } /* stb */ void OP_3C000000 () { trace_input ("stb", OP_REG, OP_MEMREF2, OP_VOID); SB (State.regs[OP[2]]+OP[1], State.regs[OP[0]]); trace_output (OP_VOID); } /* stb */ void OP_7800 () { trace_input ("stb", OP_REG, OP_MEMREF, OP_VOID); SB (State.regs[OP[1]], State.regs[OP[0]]); trace_output (OP_VOID); } /* stop */ void OP_5FE0 () { trace_input ("stop", OP_VOID, OP_VOID, OP_VOID); State.exception = SIG_D10V_STOP; trace_output (OP_VOID); } /* sub */ void OP_0 () { uint16 tmp; trace_input ("sub", OP_REG, OP_REG, OP_VOID); /* see ../common/sim-alu.h for a more extensive discussion on how to compute the carry/overflow bits. */ tmp = State.regs[OP[0]] - State.regs[OP[1]]; State.C = ((uint16) State.regs[OP[0]] >= (uint16) State.regs[OP[1]]); State.regs[OP[0]] = tmp; trace_output (OP_REG); } /* sub */ void OP_1001 () { int64 tmp; trace_input ("sub", OP_ACCUM, OP_DREG, OP_VOID); tmp = SEXT40(State.a[OP[0]]) - (SEXT16 (State.regs[OP[1]]) << 16 | State.regs[OP[1]+1]); if (State.ST) { if ( tmp > MAX32) State.a[OP[0]] = MAX32; else if ( tmp < MIN32) State.a[OP[0]] = MIN32; else State.a[OP[0]] = tmp & MASK40; } else State.a[OP[0]] = tmp & MASK40; trace_output (OP_ACCUM); } /* sub */ void OP_1003 () { int64 tmp; trace_input ("sub", OP_ACCUM, OP_ACCUM, OP_VOID); tmp = SEXT40(State.a[OP[0]]) - SEXT40(State.a[OP[1]]); if (State.ST) { if (tmp > MAX32) State.a[OP[0]] = MAX32; else if ( tmp < MIN32) State.a[OP[0]] = MIN32; else State.a[OP[0]] = tmp & MASK40; } else State.a[OP[0]] = tmp & MASK40; trace_output (OP_ACCUM); } /* sub2w */ void OP_1000 () { uint32 tmp,a,b; trace_input ("sub2w", OP_DREG, OP_DREG, OP_VOID); a = (uint32)((State.regs[OP[0]] << 16) | State.regs[OP[0]+1]); b = (uint32)((State.regs[OP[1]] << 16) | State.regs[OP[1]+1]); /* see ../common/sim-alu.h for a more extensive discussion on how to compute the carry/overflow bits */ tmp = a - b; State.C = (a >= b); State.regs[OP[0]] = (tmp >> 16) & 0xffff; State.regs[OP[0]+1] = tmp & 0xffff; trace_output (OP_DREG); } /* subac3 */ void OP_17000000 () { int64 tmp; trace_input ("subac3", OP_DREG_OUTPUT, OP_DREG, OP_ACCUM); tmp = SEXT40 ((State.regs[OP[1]] << 16) | State.regs[OP[1]+1]) - SEXT40 (State.a[OP[2]]); State.regs[OP[0]] = (tmp >> 16) & 0xffff; State.regs[OP[0]+1] = tmp & 0xffff; trace_output (OP_DREG); } /* subac3 */ void OP_17000002 () { int64 tmp; trace_input ("subac3", OP_DREG_OUTPUT, OP_ACCUM, OP_ACCUM); tmp = SEXT40(State.a[OP[1]]) - SEXT40(State.a[OP[2]]); State.regs[OP[0]] = (tmp >> 16) & 0xffff; State.regs[OP[0]+1] = tmp & 0xffff; trace_output (OP_DREG); } /* subac3s */ void OP_17001000 () { int64 tmp; trace_input ("subac3s", OP_DREG_OUTPUT, OP_DREG, OP_ACCUM); State.F1 = State.F0; tmp = SEXT40 ((State.regs[OP[1]] << 16) | State.regs[OP[1]+1]) - SEXT40(State.a[OP[2]]); if ( tmp > MAX32) { State.regs[OP[0]] = 0x7fff; State.regs[OP[0]+1] = 0xffff; State.F0 = 1; } else if (tmp < MIN32) { State.regs[OP[0]] = 0x8000; State.regs[OP[0]+1] = 0; State.F0 = 1; } else { State.regs[OP[0]] = (tmp >> 16) & 0xffff; State.regs[OP[0]+1] = tmp & 0xffff; State.F0 = 0; } trace_output (OP_DREG); } /* subac3s */ void OP_17001002 () { int64 tmp; trace_input ("subac3s", OP_DREG_OUTPUT, OP_ACCUM, OP_ACCUM); State.F1 = State.F0; tmp = SEXT40(State.a[OP[1]]) - SEXT40(State.a[OP[2]]); if ( tmp > MAX32) { State.regs[OP[0]] = 0x7fff; State.regs[OP[0]+1] = 0xffff; State.F0 = 1; } else if (tmp < MIN32) { State.regs[OP[0]] = 0x8000; State.regs[OP[0]+1] = 0; State.F0 = 1; } else { State.regs[OP[0]] = (tmp >> 16) & 0xffff; State.regs[OP[0]+1] = tmp & 0xffff; State.F0 = 0; } trace_output (OP_DREG); } /* subi */ void OP_1 () { unsigned tmp; if (OP[1] == 0) OP[1] = 16; trace_input ("subi", OP_REG, OP_CONSTANT16, OP_VOID); /* see ../common/sim-alu.h for a more extensive discussion on how to compute the carry/overflow bits. */ /* since OP[1] is never <= 0, -OP[1] == ~OP[1]+1 can never overflow */ tmp = ((unsigned)(unsigned16) State.regs[OP[0]] + (unsigned)(unsigned16) ( - OP[1])); State.C = (tmp >= (1 << 16)); State.regs[OP[0]] = tmp; trace_output (OP_REG); } /* trap */ void OP_5F00 () { trace_input ("trap", OP_CONSTANT4, OP_VOID, OP_VOID); trace_output (OP_VOID); switch (OP[0]) { default: #if 0 (*d10v_callback->printf_filtered) (d10v_callback, "Unknown trap code %d\n", OP[0]); State.exception = SIGILL; #else /* Use any other traps for batch debugging. */ { int i; static int first_time = 1; if (first_time) { first_time = 0; (*d10v_callback->printf_filtered) (d10v_callback, "Trap # PC "); for (i = 0; i < 16; i++) (*d10v_callback->printf_filtered) (d10v_callback, " %sr%d", (i > 9) ? "" : " ", i); (*d10v_callback->printf_filtered) (d10v_callback, " a0 a1 f0 f1 c\n"); } (*d10v_callback->printf_filtered) (d10v_callback, "Trap %2d 0x%.4x:", (int)OP[0], (int)PC); for (i = 0; i < 16; i++) (*d10v_callback->printf_filtered) (d10v_callback, " %.4x", (int) State.regs[i]); for (i = 0; i < 2; i++) (*d10v_callback->printf_filtered) (d10v_callback, " %.2x%.8lx", ((int)(State.a[i] >> 32) & 0xff), ((unsigned long)State.a[i]) & 0xffffffff); (*d10v_callback->printf_filtered) (d10v_callback, " %d %d %d\n", State.F0 != 0, State.F1 != 0, State.C != 0); (*d10v_callback->flush_stdout) (d10v_callback); break; } #endif case 0: /* old system call trap, to be deleted */ case 15: /* new system call trap */ /* Trap 15 is used for simulating low-level I/O */ { errno = 0; /* Registers passed to trap 0 */ #define FUNC State.regs[6] /* function number */ #define PARM1 State.regs[2] /* optional parm 1 */ #define PARM2 State.regs[3] /* optional parm 2 */ #define PARM3 State.regs[4] /* optional parm 3 */ #define PARM4 State.regs[5] /* optional parm 3 */ /* Registers set by trap 0 */ #define RETVAL State.regs[2] /* return value */ #define RETVAL_HIGH State.regs[2] /* return value */ #define RETVAL_LOW State.regs[3] /* return value */ #define RETERR State.regs[4] /* return error code */ /* Turn a pointer in a register into a pointer into real memory. */ #define MEMPTR(x) ((char *)(dmem_addr(x))) switch (FUNC) { #if !defined(__GO32__) && !defined(_WIN32) case SYS_fork: RETVAL = fork (); trace_input ("", OP_VOID, OP_VOID, OP_VOID); trace_output (OP_R2); break; case SYS_getpid: trace_input ("", OP_VOID, OP_VOID, OP_VOID); RETVAL = getpid (); trace_output (OP_R2); break; case SYS_kill: trace_input ("", OP_REG, OP_REG, OP_VOID); if (PARM1 == getpid ()) { trace_output (OP_VOID); State.exception = PARM2; } else { int os_sig = -1; switch (PARM2) { #ifdef SIGHUP case 1: os_sig = SIGHUP; break; #endif #ifdef SIGINT case 2: os_sig = SIGINT; break; #endif #ifdef SIGQUIT case 3: os_sig = SIGQUIT; break; #endif #ifdef SIGILL case 4: os_sig = SIGILL; break; #endif #ifdef SIGTRAP case 5: os_sig = SIGTRAP; break; #endif #ifdef SIGABRT case 6: os_sig = SIGABRT; break; #elif defined(SIGIOT) case 6: os_sig = SIGIOT; break; #endif #ifdef SIGEMT case 7: os_sig = SIGEMT; break; #endif #ifdef SIGFPE case 8: os_sig = SIGFPE; break; #endif #ifdef SIGKILL case 9: os_sig = SIGKILL; break; #endif #ifdef SIGBUS case 10: os_sig = SIGBUS; break; #endif #ifdef SIGSEGV case 11: os_sig = SIGSEGV; break; #endif #ifdef SIGSYS case 12: os_sig = SIGSYS; break; #endif #ifdef SIGPIPE case 13: os_sig = SIGPIPE; break; #endif #ifdef SIGALRM case 14: os_sig = SIGALRM; break; #endif #ifdef SIGTERM case 15: os_sig = SIGTERM; break; #endif #ifdef SIGURG case 16: os_sig = SIGURG; break; #endif #ifdef SIGSTOP case 17: os_sig = SIGSTOP; break; #endif #ifdef SIGTSTP case 18: os_sig = SIGTSTP; break; #endif #ifdef SIGCONT case 19: os_sig = SIGCONT; break; #endif #ifdef SIGCHLD case 20: os_sig = SIGCHLD; break; #elif defined(SIGCLD) case 20: os_sig = SIGCLD; break; #endif #ifdef SIGTTIN case 21: os_sig = SIGTTIN; break; #endif #ifdef SIGTTOU case 22: os_sig = SIGTTOU; break; #endif #ifdef SIGIO case 23: os_sig = SIGIO; break; #elif defined (SIGPOLL) case 23: os_sig = SIGPOLL; break; #endif #ifdef SIGXCPU case 24: os_sig = SIGXCPU; break; #endif #ifdef SIGXFSZ case 25: os_sig = SIGXFSZ; break; #endif #ifdef SIGVTALRM case 26: os_sig = SIGVTALRM; break; #endif #ifdef SIGPROF case 27: os_sig = SIGPROF; break; #endif #ifdef SIGWINCH case 28: os_sig = SIGWINCH; break; #endif #ifdef SIGLOST case 29: os_sig = SIGLOST; break; #endif #ifdef SIGUSR1 case 30: os_sig = SIGUSR1; break; #endif #ifdef SIGUSR2 case 31: os_sig = SIGUSR2; break; #endif } if (os_sig == -1) { trace_output (OP_VOID); (*d10v_callback->printf_filtered) (d10v_callback, "Unknown signal %d\n", PARM2); (*d10v_callback->flush_stdout) (d10v_callback); State.exception = SIGILL; } else { RETVAL = kill (PARM1, PARM2); trace_output (OP_R2); } } break; case SYS_execve: RETVAL = execve (MEMPTR (PARM1), (char **) MEMPTR (PARM2), (char **)MEMPTR (PARM3)); trace_input ("", OP_R2, OP_R3, OP_R4); trace_output (OP_R2); break; #ifdef SYS_execv case SYS_execv: RETVAL = execve (MEMPTR (PARM1), (char **) MEMPTR (PARM2), NULL); trace_input ("", OP_R2, OP_R3, OP_VOID); trace_output (OP_R2); break; #endif case SYS_pipe: { reg_t buf; int host_fd[2]; buf = PARM1; RETVAL = pipe (host_fd); SW (buf, host_fd[0]); buf += sizeof(uint16); SW (buf, host_fd[1]); trace_input ("", OP_R2, OP_VOID, OP_VOID); trace_output (OP_R2); } break; #ifdef SYS_wait case SYS_wait: { int status; RETVAL = wait (&status); if (PARM1) SW (PARM1, status); trace_input ("", OP_R2, OP_VOID, OP_VOID); trace_output (OP_R2); } break; #endif #else case SYS_getpid: trace_input ("", OP_VOID, OP_VOID, OP_VOID); RETVAL = 1; trace_output (OP_R2); break; case SYS_kill: trace_input ("", OP_REG, OP_REG, OP_VOID); trace_output (OP_VOID); State.exception = PARM2; break; #endif case SYS_read: RETVAL = d10v_callback->read (d10v_callback, PARM1, MEMPTR (PARM2), PARM3); trace_input ("", OP_R2, OP_R3, OP_R4); trace_output (OP_R2); break; case SYS_write: if (PARM1 == 1) RETVAL = (int)d10v_callback->write_stdout (d10v_callback, MEMPTR (PARM2), PARM3); else RETVAL = (int)d10v_callback->write (d10v_callback, PARM1, MEMPTR (PARM2), PARM3); trace_input ("", OP_R2, OP_R3, OP_R4); trace_output (OP_R2); break; case SYS_lseek: { unsigned long ret = d10v_callback->lseek (d10v_callback, PARM1, (((unsigned long)PARM2) << 16) || (unsigned long)PARM3, PARM4); RETVAL_HIGH = ret >> 16; RETVAL_LOW = ret & 0xffff; } trace_input ("", OP_R2, OP_R3, OP_R4); trace_output (OP_R2R3); break; case SYS_close: RETVAL = d10v_callback->close (d10v_callback, PARM1); trace_input ("", OP_R2, OP_VOID, OP_VOID); trace_output (OP_R2); break; case SYS_open: RETVAL = d10v_callback->open (d10v_callback, MEMPTR (PARM1), PARM2); trace_input ("", OP_R2, OP_R3, OP_R4); trace_output (OP_R2); trace_input ("", OP_R2, OP_R3, OP_R4); trace_output (OP_R2); break; case SYS_exit: State.exception = SIG_D10V_EXIT; trace_input ("", OP_R2, OP_VOID, OP_VOID); trace_output (OP_VOID); break; case SYS_stat: /* stat system call */ { struct stat host_stat; reg_t buf; RETVAL = stat (MEMPTR (PARM1), &host_stat); buf = PARM2; /* The hard-coded offsets and sizes were determined by using * the D10V compiler on a test program that used struct stat. */ SW (buf, host_stat.st_dev); SW (buf+2, host_stat.st_ino); SW (buf+4, host_stat.st_mode); SW (buf+6, host_stat.st_nlink); SW (buf+8, host_stat.st_uid); SW (buf+10, host_stat.st_gid); SW (buf+12, host_stat.st_rdev); SLW (buf+16, host_stat.st_size); SLW (buf+20, host_stat.st_atime); SLW (buf+28, host_stat.st_mtime); SLW (buf+36, host_stat.st_ctime); } trace_input ("", OP_R2, OP_R3, OP_VOID); trace_output (OP_R2); break; case SYS_chown: RETVAL = chown (MEMPTR (PARM1), PARM2, PARM3); trace_input ("", OP_R2, OP_R3, OP_R4); trace_output (OP_R2); break; case SYS_chmod: RETVAL = chmod (MEMPTR (PARM1), PARM2); trace_input ("", OP_R2, OP_R3, OP_R4); trace_output (OP_R2); break; #ifdef SYS_utime case SYS_utime: /* Cast the second argument to void *, to avoid type mismatch if a prototype is present. */ RETVAL = utime (MEMPTR (PARM1), (void *) MEMPTR (PARM2)); trace_input ("", OP_R2, OP_R3, OP_R4); trace_output (OP_R2); break; #endif #ifdef SYS_time case SYS_time: { unsigned long ret = time (PARM1 ? MEMPTR (PARM1) : NULL); RETVAL_HIGH = ret >> 16; RETVAL_LOW = ret & 0xffff; } trace_input ("