/* Simulation code for the CR16 processor. Copyright (C) 2008-2015 Free Software Foundation, Inc. Contributed by M Ranga Swami Reddy This file is part of GDB, the GNU debugger. 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, 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 . */ #include "config.h" #include #include #include #include #ifdef HAVE_UNISTD_H #include #endif #ifdef HAVE_STRING_H #include #endif #ifdef HAVE_TIME_H #include #endif #ifdef HAVE_SYS_TIME_H #include #endif #include "cr16_sim.h" #include "simops.h" #include "targ-vals.h" #ifdef TARGET_SYS_utime #include #endif #ifdef TARGET_SYS_wait #include #endif enum op_types { OP_VOID, OP_CONSTANT3, OP_UCONSTANT3, OP_CONSTANT4, OP_CONSTANT4_1, OP_CONSTANT5, OP_CONSTANT6, OP_CONSTANT16, OP_UCONSTANT16, OP_CONSTANT20, OP_UCONSTANT20, OP_CONSTANT32, OP_UCONSTANT32, OP_MEMREF, OP_MEMREF2, OP_MEMREF3, OP_DISP5, OP_DISP17, OP_DISP25, OP_DISPE9, //OP_ABS20, OP_ABS20_OUTPUT, //OP_ABS24, OP_ABS24_OUTPUT, OP_R_BASE_DISPS16, OP_R_BASE_DISP20, OP_R_BASE_DISPS20, OP_R_BASE_DISPE20, OP_RP_BASE_DISPE0, OP_RP_BASE_DISP4, OP_RP_BASE_DISPE4, OP_RP_BASE_DISP14, OP_RP_BASE_DISP16, OP_RP_BASE_DISP20, OP_RP_BASE_DISPS20, OP_RP_BASE_DISPE20, OP_R_INDEX7_ABS20, OP_R_INDEX8_ABS20, OP_RP_INDEX_DISP0, OP_RP_INDEX_DISP14, OP_RP_INDEX_DISP20, OP_RP_INDEX_DISPS20, OP_REG, OP_REGP, OP_PROC_REG, OP_PROC_REGP, OP_COND, OP_RA }; enum { PSR_MASK = (PSR_I_BIT | PSR_P_BIT | PSR_E_BIT | PSR_N_BIT | PSR_Z_BIT | PSR_F_BIT | PSR_U_BIT | PSR_L_BIT | PSR_T_BIT | PSR_C_BIT), /* The following bits in the PSR _can't_ be set by instructions such as mvtc. */ PSR_HW_MASK = (PSR_MASK) }; /* cond Code Condition True State * EQ Equal Z flag is 1 * NE Not Equal Z flag is 0 * CS Carry Set C flag is 1 * CC Carry Clear C flag is 0 * HI Higher L flag is 1 * LS Lower or Same L flag is 0 * GT Greater Than N flag is 1 * LE Less Than or Equal To N flag is 0 * FS Flag Set F flag is 1 * FC Flag Clear F flag is 0 * LO Lower Z and L flags are 0 * HS Higher or Same Z or L flag is 1 * LT Less Than Z and N flags are 0 * GE Greater Than or Equal To Z or N flag is 1. */ static int cond_stat(int cc) { switch (cc) { case 0: return PSR_Z; break; case 1: return !PSR_Z; break; case 2: return PSR_C; break; case 3: return !PSR_C; break; case 4: return PSR_L; break; case 5: return !PSR_L; break; case 6: return PSR_N; break; case 7: return !PSR_N; break; case 8: return PSR_F; break; case 9: return !PSR_F; break; case 10: return !PSR_Z && !PSR_L; break; case 11: return PSR_Z || PSR_L; break; case 12: return !PSR_Z && !PSR_N; break; case 13: return PSR_Z || PSR_N; break; case 14: return 1; break; /*ALWAYS. */ default: // case NEVER: return false; break; //case NO_COND_CODE: //panic("Shouldn't have NO_COND_CODE in an actual instruction!"); return 0; break; } return 0; } creg_t move_to_cr (int cr, creg_t mask, creg_t val, int psw_hw_p) { /* A MASK bit is set when the corresponding bit in the CR should be left alone. */ /* This assumes that (VAL & MASK) == 0. */ switch (cr) { case PSR_CR: if (psw_hw_p) val &= PSR_HW_MASK; #if 0 else val &= PSR_MASK; (*cr16_callback->printf_filtered) (cr16_callback, "ERROR at PC 0x%x: ST can only be set when FX is set.\n", PC); State.exception = SIGILL; #endif /* keep an up-to-date psw around for tracing. */ State.trace.psw = (State.trace.psw & mask) | val; break; default: break; } /* only issue an update if the register is being changed. */ if ((State.cregs[cr] & ~mask) != val) SLOT_PEND_MASK (State.cregs[cr], mask, val); return val; } #ifdef DEBUG static void trace_input_func (const char *name, enum op_types in1, enum op_types in2, enum op_types in3); #define trace_input(name, in1, in2, in3) do { if (cr16_debug) trace_input_func (name, in1, in2, in3); } 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 4 #endif #ifndef SIZE_LINE_NUMBER #define SIZE_LINE_NUMBER 2 #endif static void trace_input_func (const 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 ((cr16_debug & DEBUG_TRACE) == 0) return; switch (State.ins_type) { default: case INS_UNKNOWN: type = " ?"; break; } if ((cr16_debug & DEBUG_LINE_NUMBER) == 0) (*cr16_callback->printf_filtered) (cr16_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 bfd_symbol **)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'; } } (*cr16_callback->printf_filtered) (cr16_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: break; case OP_REG: case OP_REGP: sprintf (p, "%sr%d", comma, OP[i]); p += strlen (p); comma = ","; break; case OP_PROC_REG: sprintf (p, "%scr%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_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_MEMREF3: sprintf (p, "%s@%d", comma, OP[i]); p += strlen (p); comma = ","; break; } } if ((cr16_debug & DEBUG_VALUES) == 0) { *p++ = '\n'; *p = '\0'; (*cr16_callback->printf_filtered) (cr16_callback, "%s", buf); } else { *p = '\0'; (*cr16_callback->printf_filtered) (cr16_callback, "%-*s", SIZE_OPERANDS, buf); p = buf; for (i = 0; i < 3; i++) { buf[0] = '\0'; switch (in[i]) { case OP_VOID: (*cr16_callback->printf_filtered) (cr16_callback, "%*s", SIZE_VALUES, ""); break; case OP_REG: (*cr16_callback->printf_filtered) (cr16_callback, "%*s0x%.4x", SIZE_VALUES-6, "", (uint16) GPR (OP[i])); break; case OP_REGP: tmp = (long)((((uint32) GPR (OP[i])) << 16) | ((uint32) GPR (OP[i] + 1))); (*cr16_callback->printf_filtered) (cr16_callback, "%*s0x%.8lx", SIZE_VALUES-10, "", tmp); break; case OP_PROC_REG: (*cr16_callback->printf_filtered) (cr16_callback, "%*s0x%.4x", SIZE_VALUES-6, "", (uint16) CREG (OP[i])); break; case OP_CONSTANT16: (*cr16_callback->printf_filtered) (cr16_callback, "%*s0x%.4x", SIZE_VALUES-6, "", (uint16)OP[i]); break; case OP_CONSTANT4: (*cr16_callback->printf_filtered) (cr16_callback, "%*s0x%.4x", SIZE_VALUES-6, "", (uint16)SEXT4(OP[i])); break; case OP_CONSTANT3: (*cr16_callback->printf_filtered) (cr16_callback, "%*s0x%.4x", SIZE_VALUES-6, "", (uint16)SEXT3(OP[i])); break; case OP_MEMREF2: (*cr16_callback->printf_filtered) (cr16_callback, "%*s0x%.4x", SIZE_VALUES-6, "", (uint16)OP[i]); (*cr16_callback->printf_filtered) (cr16_callback, "%*s0x%.4x", SIZE_VALUES-6, "", (uint16)GPR (OP[i + 1])); i++; break; } } } (*cr16_callback->flush_stdout) (cr16_callback); } static void do_trace_output_flush (void) { (*cr16_callback->flush_stdout) (cr16_callback); } static void do_trace_output_finish (void) { (*cr16_callback->printf_filtered) (cr16_callback, " F0=%d F1=%d C=%d\n", (State.trace.psw & PSR_F_BIT) != 0, (State.trace.psw & PSR_F_BIT) != 0, (State.trace.psw & PSR_C_BIT) != 0); (*cr16_callback->flush_stdout) (cr16_callback); } #if 0 static void trace_output_40 (uint64 val) { if ((cr16_debug & (DEBUG_TRACE | DEBUG_VALUES)) == (DEBUG_TRACE | DEBUG_VALUES)) { (*cr16_callback->printf_filtered) (cr16_callback, " :: %*s0x%.2x%.8lx", SIZE_VALUES - 12, "", ((int)(val >> 32) & 0xff), ((unsigned long) val) & 0xffffffff); do_trace_output_finish (); } } #endif static void trace_output_32 (uint32 val) { if ((cr16_debug & (DEBUG_TRACE | DEBUG_VALUES)) == (DEBUG_TRACE | DEBUG_VALUES)) { (*cr16_callback->printf_filtered) (cr16_callback, " :: %*s0x%.8x", SIZE_VALUES - 10, "", (int) val); do_trace_output_finish (); } } static void trace_output_16 (uint16 val) { if ((cr16_debug & (DEBUG_TRACE | DEBUG_VALUES)) == (DEBUG_TRACE | DEBUG_VALUES)) { (*cr16_callback->printf_filtered) (cr16_callback, " :: %*s0x%.4x", SIZE_VALUES - 6, "", (int) val); do_trace_output_finish (); } } static void trace_output_void (void) { if ((cr16_debug & (DEBUG_TRACE | DEBUG_VALUES)) == (DEBUG_TRACE | DEBUG_VALUES)) { (*cr16_callback->printf_filtered) (cr16_callback, "\n"); do_trace_output_flush (); } } static void trace_output_flag (void) { if ((cr16_debug & (DEBUG_TRACE | DEBUG_VALUES)) == (DEBUG_TRACE | DEBUG_VALUES)) { (*cr16_callback->printf_filtered) (cr16_callback, " :: %*s", SIZE_VALUES, ""); do_trace_output_finish (); } } #else #define trace_input(NAME, IN1, IN2, IN3) #define trace_output(RESULT) #endif /* addub. */ void OP_2C_8 (void) { uint8 tmp; uint8 a = OP[0] & 0xff; uint16 b = (GPR (OP[1])) & 0xff; trace_input ("addub", OP_CONSTANT4_1, OP_REG, OP_VOID); tmp = (a + b) & 0xff; SET_GPR (OP[1], (tmp | ((GPR (OP[1])) & 0xff00))); trace_output_16 (tmp); } /* addub. */ void OP_2CB_C (void) { uint16 tmp; uint8 a = ((OP[0]) & 0xff), b = (GPR (OP[1])) & 0xff; trace_input ("addub", OP_CONSTANT16, OP_REG, OP_VOID); tmp = (a + b) & 0xff; SET_GPR (OP[1], (tmp | ((GPR (OP[1])) & 0xff00))); trace_output_16 (tmp); } /* addub. */ void OP_2D_8 (void) { uint8 a = (GPR (OP[0])) & 0xff; uint8 b = (GPR (OP[1])) & 0xff; uint16 tmp = (a + b) & 0xff; trace_input ("addub", OP_REG, OP_REG, OP_VOID); SET_GPR (OP[1], (tmp | ((GPR (OP[1])) & 0xff00))); trace_output_16 (tmp); } /* adduw. */ void OP_2E_8 (void) { uint16 a = OP[0]; uint16 b = GPR (OP[1]); uint16 tmp = (a + b); trace_input ("adduw", OP_CONSTANT4_1, OP_REG, OP_VOID); SET_GPR (OP[1], tmp); trace_output_16 (tmp); } /* adduw. */ void OP_2EB_C (void) { uint16 a = OP[0]; uint16 b = GPR (OP[1]); uint16 tmp = (a + b); trace_input ("adduw", OP_CONSTANT16, OP_REG, OP_VOID); SET_GPR (OP[1], tmp); trace_output_16 (tmp); } /* adduw. */ void OP_2F_8 (void) { uint16 a = GPR (OP[0]); uint16 b = GPR (OP[1]); uint16 tmp = (a + b); trace_input ("adduw", OP_REG, OP_REG, OP_VOID); SET_GPR (OP[1], tmp); trace_output_16 (tmp); } /* addb. */ void OP_30_8 (void) { uint8 a = OP[0]; uint8 b = (GPR (OP[1]) & 0xff); uint16 tmp = (a + b) & 0xff; trace_input ("addb", OP_CONSTANT4_1, OP_REG, OP_VOID); SET_GPR (OP[1], (tmp | ((GPR (OP[1])) & 0xff00))); SET_PSR_C (tmp > 0xFF); SET_PSR_F (((a & 0x80) == (b & 0x80)) && ((b & 0x80) != (tmp & 0x80))); trace_output_16 (tmp); } /* addb. */ void OP_30B_C (void) { uint8 a = (OP[0]) & 0xff; uint8 b = (GPR (OP[1]) & 0xff); uint16 tmp = (a + b) & 0xff; trace_input ("addb", OP_CONSTANT16, OP_REG, OP_VOID); SET_GPR (OP[1], (tmp | ((GPR (OP[1])) & 0xff00))); SET_PSR_C (tmp > 0xFF); SET_PSR_F (((a & 0x80) == (b & 0x80)) && ((b & 0x80) != (tmp & 0x80))); trace_output_16 (tmp); } /* addb. */ void OP_31_8 (void) { uint8 a = (GPR (OP[0]) & 0xff); uint8 b = (GPR (OP[1]) & 0xff); uint16 tmp = (a + b) & 0xff; trace_input ("addb", OP_REG, OP_REG, OP_VOID); SET_GPR (OP[1], (tmp | ((GPR (OP[1])) & 0xff00))); SET_PSR_C (tmp > 0xFF); SET_PSR_F (((a & 0x80) == (b & 0x80)) && ((b & 0x80) != (tmp & 0x80))); trace_output_16 (tmp); } /* addw. */ void OP_32_8 (void) { int16 a = OP[0]; uint16 tmp, b = GPR (OP[1]); tmp = (a + b); trace_input ("addw", OP_CONSTANT4_1, OP_REG, OP_VOID); SET_GPR (OP[1], tmp); SET_PSR_C (tmp > 0xFFFF); SET_PSR_F (((a & 0x8000) == (b & 0x8000)) && ((b & 0x8000) != (tmp & 0x8000))); trace_output_16 (tmp); } /* addw. */ void OP_32B_C (void) { int16 a = OP[0]; uint16 tmp, b = GPR (OP[1]); tmp = (a + b); trace_input ("addw", OP_CONSTANT16, OP_REG, OP_VOID); SET_GPR (OP[1], tmp); SET_PSR_C (tmp > 0xFFFF); SET_PSR_F (((a & 0x8000) == (b & 0x8000)) && ((b & 0x8000) != (tmp & 0x8000))); trace_output_16 (tmp); } /* addw. */ void OP_33_8 (void) { uint16 tmp, a = (GPR (OP[0])), b = (GPR (OP[1])); trace_input ("addw", OP_REG, OP_REG, OP_VOID); tmp = (a + b); SET_GPR (OP[1], tmp); SET_PSR_C (tmp > 0xFFFF); SET_PSR_F (((a & 0x8000) == (b & 0x8000)) && ((b & 0x8000) != (tmp & 0x8000))); trace_output_16 (tmp); } /* addcb. */ void OP_34_8 (void) { uint8 tmp, a = OP[0] & 0xff, b = (GPR (OP[1])) & 0xff; trace_input ("addcb", OP_CONSTANT4_1, OP_REG, OP_REG); tmp = (a + b + PSR_C) & 0xff; SET_GPR (OP[1], (tmp | ((GPR (OP[1])) & 0xff00))); SET_PSR_C (tmp > 0xFF); SET_PSR_F (((a & 0x80) == (b & 0x80)) && ((b & 0x80) != (tmp & 0x80))); trace_output_16 (tmp); } /* addcb. */ void OP_34B_C (void) { int8 a = OP[0] & 0xff; uint8 b = (GPR (OP[1])) & 0xff; uint8 tmp = (a + b + PSR_C) & 0xff; trace_input ("addcb", OP_CONSTANT16, OP_REG, OP_VOID); SET_GPR (OP[1], (tmp | ((GPR (OP[1])) & 0xff00))); SET_PSR_C (tmp > 0xFF); SET_PSR_F (((a & 0x80) == (b & 0x80)) && ((b & 0x80) != (tmp & 0x80))); trace_output_16 (tmp); } /* addcb. */ void OP_35_8 (void) { uint8 a = (GPR (OP[0])) & 0xff; uint8 b = (GPR (OP[1])) & 0xff; uint8 tmp = (a + b + PSR_C) & 0xff; trace_input ("addcb", OP_REG, OP_REG, OP_VOID); SET_GPR (OP[1], (tmp | ((GPR (OP[1])) & 0xff00))); SET_PSR_C (tmp > 0xFF); SET_PSR_F (((a & 0x80) == (b & 0x80)) && ((b & 0x80) != (tmp & 0x80))); trace_output_16 (tmp); } /* addcw. */ void OP_36_8 (void) { uint16 a = OP[0]; uint16 b = GPR (OP[1]); uint16 tmp = (a + b + PSR_C); trace_input ("addcw", OP_CONSTANT4_1, OP_REG, OP_VOID); SET_GPR (OP[1], tmp); SET_PSR_C (tmp > 0xFFFF); SET_PSR_F (((a & 0x8000) == (b & 0x8000)) && ((b & 0x8000) != (tmp & 0x8000))); trace_output_16 (tmp); } /* addcw. */ void OP_36B_C (void) { int16 a = OP[0]; uint16 b = GPR (OP[1]); uint16 tmp = (a + b + PSR_C); trace_input ("addcw", OP_CONSTANT16, OP_REG, OP_VOID); SET_GPR (OP[1], tmp); SET_PSR_C (tmp > 0xFFFF); SET_PSR_F (((a & 0x8000) == (b & 0x8000)) && ((b & 0x8000) != (tmp & 0x8000))); trace_output_16 (tmp); } /* addcw. */ void OP_37_8 (void) { uint16 a = GPR (OP[1]); uint16 b = GPR (OP[1]); uint16 tmp = (a + b + PSR_C); trace_input ("addcw", OP_REG, OP_REG, OP_VOID); SET_GPR (OP[1], tmp); SET_PSR_C (tmp > 0xFFFF); SET_PSR_F (((a & 0x8000) == (b & 0x8000)) && ((b & 0x8000) != (tmp & 0x8000))); trace_output_16 (tmp); } /* addd. */ void OP_60_8 (void) { int16 a = (OP[0]); uint32 b = GPR32 (OP[1]); uint32 tmp = (a + b); trace_input ("addd", OP_CONSTANT4_1, OP_REGP, OP_VOID); SET_GPR32 (OP[1], tmp); SET_PSR_C (tmp > 0xFFFFFFFF); SET_PSR_F (((a & 0x80000000) == (b & 0x80000000)) && ((b & 0x80000000) != (tmp & 0x80000000))); trace_output_32 (tmp); } /* addd. */ void OP_60B_C (void) { int32 a = (SEXT16(OP[0])); uint32 b = GPR32 (OP[1]); uint32 tmp = (a + b); trace_input ("addd", OP_CONSTANT16, OP_REGP, OP_VOID); SET_GPR32 (OP[1], tmp); SET_PSR_C (tmp > 0xFFFFFFFF); SET_PSR_F (((a & 0x80000000) == (b & 0x80000000)) && ((b & 0x80000000) != (tmp & 0x80000000))); trace_output_32 (tmp); } /* addd. */ void OP_61_8 (void) { uint32 a = GPR32 (OP[0]); uint32 b = GPR32 (OP[1]); uint32 tmp = (a + b); trace_input ("addd", OP_REGP, OP_REGP, OP_VOID); SET_GPR32 (OP[1], tmp); trace_output_32 (tmp); SET_PSR_C (tmp > 0xFFFFFFFF); SET_PSR_F (((a & 0x80000000) == (b & 0x80000000)) && ((b & 0x80000000) != (tmp & 0x80000000))); } /* addd. */ void OP_4_8 (void) { uint32 a = OP[0]; uint32 b = GPR32 (OP[1]); uint32 tmp; trace_input ("addd", OP_CONSTANT20, OP_REGP, OP_VOID); tmp = (a + b); SET_GPR32 (OP[1], tmp); SET_PSR_C (tmp > 0xFFFFFFFF); SET_PSR_F (((a & 0x80000000) == (b & 0x80000000)) && ((b & 0x80000000) != (tmp & 0x80000000))); trace_output_32 (tmp); } /* addd. */ void OP_2_C (void) { int32 a = OP[0]; uint32 b = GPR32 (OP[1]); uint32 tmp; trace_input ("addd", OP_CONSTANT32, OP_REGP, OP_VOID); tmp = (a + b); SET_GPR32 (OP[1], tmp); SET_PSR_C (tmp > 0xFFFFFFFF); SET_PSR_F (((a & 0x80000000) == (b & 0x80000000)) && ((b & 0x80000000) != (tmp & 0x80000000))); trace_output_32 (tmp); } /* andb. */ void OP_20_8 (void) { uint8 tmp, a = (OP[0]) & 0xff, b = (GPR (OP[1])) & 0xff; trace_input ("andb", OP_CONSTANT4, OP_REG, OP_VOID); tmp = a & b; SET_GPR (OP[1], (tmp | ((GPR (OP[1])) & 0xff00))); trace_output_16 (tmp); } /* andb. */ void OP_20B_C (void) { uint8 tmp, a = (OP[0]) & 0xff, b = (GPR (OP[1])) & 0xff; trace_input ("andb", OP_CONSTANT16, OP_REG, OP_VOID); tmp = a & b; SET_GPR (OP[1], (tmp | ((GPR (OP[1])) & 0xff00))); trace_output_16 (tmp); } /* andb. */ void OP_21_8 (void) { uint8 tmp, a = (GPR (OP[0])) & 0xff, b = (GPR (OP[1])) & 0xff; trace_input ("andb", OP_REG, OP_REG, OP_VOID); tmp = a & b; SET_GPR (OP[1], (tmp | ((GPR (OP[1])) & 0xff00))); trace_output_16 (tmp); } /* andw. */ void OP_22_8 (void) { uint16 tmp, a = OP[0], b = GPR (OP[1]); trace_input ("andw", OP_CONSTANT4, OP_REG, OP_VOID); tmp = a & b; SET_GPR (OP[1], tmp); trace_output_16 (tmp); } /* andw. */ void OP_22B_C (void) { uint16 tmp, a = OP[0], b = GPR (OP[1]); trace_input ("andw", OP_CONSTANT16, OP_REG, OP_VOID); tmp = a & b; SET_GPR (OP[1], tmp); trace_output_16 (tmp); } /* andw. */ void OP_23_8 (void) { uint16 tmp, a = GPR (OP[0]), b = GPR (OP[1]); trace_input ("andw", OP_REG, OP_REG, OP_VOID); tmp = a & b; SET_GPR (OP[1], tmp); trace_output_16 (tmp); } /* andd. */ void OP_4_C (void) { uint32 tmp, a = OP[0], b = GPR32 (OP[1]); trace_input ("andd", OP_CONSTANT32, OP_REGP, OP_VOID); tmp = a & b; SET_GPR32 (OP[1], tmp); trace_output_32 (tmp); } /* andd. */ void OP_14B_14 (void) { uint32 tmp, a = (GPR32 (OP[0])), b = (GPR32 (OP[1])); trace_input ("andd", OP_REGP, OP_REGP, OP_VOID); tmp = a & b; SET_GPR32 (OP[1], tmp); trace_output_32 (tmp); } /* ord. */ void OP_5_C (void) { uint32 tmp, a = (OP[0]), b = GPR32 (OP[1]); trace_input ("ord", OP_CONSTANT32, OP_REG, OP_VOID); tmp = a | b; SET_GPR32 (OP[1], tmp); trace_output_32 (tmp); } /* ord. */ void OP_149_14 (void) { uint32 tmp, a = GPR32 (OP[0]), b = GPR32 (OP[1]); trace_input ("ord", OP_REGP, OP_REGP, OP_VOID); tmp = a | b; SET_GPR32 (OP[1], tmp); trace_output_32 (tmp); } /* xord. */ void OP_6_C (void) { uint32 tmp, a = (OP[0]), b = GPR32 (OP[1]); trace_input ("xord", OP_CONSTANT32, OP_REG, OP_VOID); tmp = a ^ b; SET_GPR32 (OP[1], tmp); trace_output_32 (tmp); } /* xord. */ void OP_14A_14 (void) { uint32 tmp, a = GPR32 (OP[0]), b = GPR32 (OP[1]); trace_input ("xord", OP_REGP, OP_REGP, OP_VOID); tmp = a ^ b; SET_GPR32 (OP[1], tmp); trace_output_32 (tmp); } /* b. */ void OP_1_4 (void) { uint32 tmp = 0, cc = cond_stat (OP[0]); trace_input ("b", OP_CONSTANT4, OP_DISPE9, OP_VOID); if (cc) { if (sign_flag) tmp = (PC - (OP[1])); else tmp = (PC + (OP[1])); /* If the resulting PC value is less than 0x00_0000 or greater than 0xFF_FFFF, this instruction causes an IAD trap.*/ if ((tmp < 0x000000) || (tmp > 0xFFFFFF)) { State.exception = SIG_CR16_BUS; State.pc_changed = 1; /* Don't increment the PC. */ trace_output_void (); return; } else JMP (tmp); } sign_flag = 0; /* Reset sign_flag. */ trace_output_32 (tmp); } /* b. */ void OP_18_8 (void) { uint32 tmp = 0, cc = cond_stat (OP[0]); trace_input ("b", OP_CONSTANT4, OP_DISP17, OP_VOID); if (cc) { if (sign_flag) tmp = (PC - OP[1]); else tmp = (PC + OP[1]); /* If the resulting PC value is less than 0x00_0000 or greater than 0xFF_FFFF, this instruction causes an IAD trap.*/ if ((tmp < 0x000000) || (tmp > 0xFFFFFF)) { State.exception = SIG_CR16_BUS; State.pc_changed = 1; /* Don't increment the PC. */ trace_output_void (); return; } else JMP (tmp); } sign_flag = 0; /* Reset sign_flag. */ trace_output_32 (tmp); } /* b. */ void OP_10_10 (void) { uint32 tmp = 0, cc = cond_stat (OP[0]); trace_input ("b", OP_CONSTANT4, OP_DISP25, OP_VOID); if (cc) { if (sign_flag) tmp = (PC - (OP[1])); else tmp = (PC + (OP[1])); /* If the resulting PC value is less than 0x00_0000 or greater than 0xFF_FFFF, this instruction causes an IAD trap.*/ if ((tmp < 0x000000) || (tmp > 0xFFFFFF)) { State.exception = SIG_CR16_BUS; State.pc_changed = 1; /* Don't increment the PC. */ trace_output_void (); return; } else JMP (tmp); } sign_flag = 0; /* Reset sign_flag. */ trace_output_32 (tmp); } /* bal. */ void OP_C0_8 (void) { uint32 tmp; trace_input ("bal", OP_REG, OP_DISP17, OP_VOID); tmp = ((PC + 4) >> 1); /* Store PC in RA register. */ SET_GPR32 (14, tmp); if (sign_flag) tmp = (PC - (OP[1])); else tmp = (PC + (OP[1])); /* If the resulting PC value is less than 0x00_0000 or greater than 0xFF_FFFF, this instruction causes an IAD trap. */ if ((tmp < 0x000000) || (tmp > 0xFFFFFF)) { State.exception = SIG_CR16_BUS; State.pc_changed = 1; /* Don't increment the PC. */ trace_output_void (); return; } else JMP (tmp); sign_flag = 0; /* Reset sign_flag. */ trace_output_32 (tmp); } /* bal. */ void OP_102_14 (void) { uint32 tmp; trace_input ("bal", OP_REGP, OP_DISP25, OP_VOID); tmp = (((PC) + 4) >> 1); /* Store PC in reg pair. */ SET_GPR32 (OP[0], tmp); if (sign_flag) tmp = ((PC) - (OP[1])); else tmp = ((PC) + (OP[1])); /* If the resulting PC value is less than 0x00_0000 or greater than 0xFF_FFFF, this instruction causes an IAD trap.*/ if ((tmp < 0x000000) || (tmp > 0xFFFFFF)) { State.exception = SIG_CR16_BUS; State.pc_changed = 1; /* Don't increment the PC. */ trace_output_void (); return; } else JMP (tmp); sign_flag = 0; /* Reset sign_flag. */ trace_output_32 (tmp); } /* jal. */ void OP_148_14 (void) { uint32 tmp; trace_input ("jal", OP_REGP, OP_REGP, OP_VOID); SET_GPR32 (OP[0], (((PC) + 4) >> 1)); /* Store next PC in RA */ tmp = GPR32 (OP[1]); tmp = SEXT24(tmp << 1); /* If the resulting PC value is less than 0x00_0000 or greater than 0xFF_FFFF, this instruction causes an IAD trap.*/ if ((tmp < 0x0) || (tmp > 0xFFFFFF)) { State.exception = SIG_CR16_BUS; State.pc_changed = 1; /* Don't increment the PC. */ trace_output_void (); return; } else JMP (tmp); trace_output_32 (tmp); } /* jal. */ void OP_D_C (void) { uint32 tmp; trace_input ("jal", OP_REGP, OP_VOID, OP_VOID); SET_GPR32 (14, (((PC) + 2) >> 1)); /* Store next PC in RA */ tmp = GPR32 (OP[0]); tmp = SEXT24(tmp << 1); /* If the resulting PC value is less than 0x00_0000 or greater than 0xFF_FFFF, this instruction causes an IAD trap.*/ if ((tmp < 0x0) || (tmp > 0xFFFFFF)) { State.exception = SIG_CR16_BUS; State.pc_changed = 1; /* Don't increment the PC. */ trace_output_void (); return; } else JMP (tmp); trace_output_32 (tmp); } /* beq0b. */ void OP_C_8 (void) { uint32 addr; uint8 a = (GPR (OP[0]) & 0xFF); trace_input ("beq0b", OP_REG, OP_DISP5, OP_VOID); addr = OP[1]; if (a == 0) { if (sign_flag) addr = (PC - OP[1]); else addr = (PC + OP[1]); JMP (addr); } sign_flag = 0; /* Reset sign_flag. */ trace_output_void (); } /* bne0b. */ void OP_D_8 (void) { uint32 addr; uint8 a = (GPR (OP[0]) & 0xFF); trace_input ("bne0b", OP_REG, OP_DISP5, OP_VOID); addr = OP[1]; if (a != 0) { if (sign_flag) addr = (PC - OP[1]); else addr = (PC + OP[1]); JMP (addr); } sign_flag = 0; /* Reset sign_flag. */ trace_output_void (); } /* beq0w. */ void OP_E_8 (void) { uint32 addr; uint16 a = GPR (OP[0]); trace_input ("beq0w", OP_REG, OP_DISP5, OP_VOID); addr = OP[1]; if (a == 0) { if (sign_flag) addr = (PC - OP[1]); else addr = (PC + OP[1]); JMP (addr); } sign_flag = 0; /* Reset sign_flag. */ trace_output_void (); } /* bne0w. */ void OP_F_8 (void) { uint32 addr; uint16 a = GPR (OP[0]); trace_input ("bne0w", OP_REG, OP_DISP5, OP_VOID); addr = OP[1]; if (a != 0) { if (sign_flag) addr = (PC - OP[1]); else addr = (PC + OP[1]); JMP (addr); } sign_flag = 0; /* Reset sign_flag. */ trace_output_void (); } /* jeq. */ void OP_A0_C (void) { uint32 tmp = 0; trace_input ("jeq", OP_REGP, OP_VOID, OP_VOID); if ((PSR_Z) == 1) { tmp = (GPR32 (OP[0])) & 0x3fffff; /* Use only 0 - 22 bits. */ JMP (tmp << 1); /* Set PC's 1 - 23 bits and clear 0th bit. */ } trace_output_32 (tmp); } /* jne. */ void OP_A1_C (void) { uint32 tmp = 0; trace_input ("jne", OP_REGP, OP_VOID, OP_VOID); if ((PSR_Z) == 0) { tmp = (GPR32 (OP[0])) & 0x3fffff; /* Use only 0 - 22 bits. */ JMP (tmp << 1); /* Set PC's 1 - 23 bits and clear 0th bit. */ } trace_output_32 (tmp); } /* jcs. */ void OP_A2_C (void) { uint32 tmp = 0; trace_input ("jcs", OP_REGP, OP_VOID, OP_VOID); if ((PSR_C) == 1) { tmp = (GPR32 (OP[0])) & 0x3fffff; /* Use only 0 - 22 bits */ JMP (tmp << 1); /* Set PC's 1 - 23 bits and clear 0th bit*/ } trace_output_32 (tmp); } /* jcc. */ void OP_A3_C (void) { uint32 tmp = 0; trace_input ("jcc", OP_REGP, OP_VOID, OP_VOID); if ((PSR_C) == 0) { tmp = (GPR32 (OP[0])) & 0x3fffff; /* Use only 0 - 22 bits */ JMP (tmp << 1); /* Set PC's 1 - 23 bits and clear 0th bit*/ } trace_output_32 (tmp); } /* jhi. */ void OP_A4_C (void) { uint32 tmp = 0; trace_input ("jhi", OP_REGP, OP_VOID, OP_VOID); if ((PSR_L) == 1) { tmp = (GPR32 (OP[0])) & 0x3fffff; /* Use only 0 - 22 bits */ JMP (tmp << 1); /* Set PC's 1 - 23 bits and clear 0th bit*/ } trace_output_32 (tmp); } /* jls. */ void OP_A5_C (void) { uint32 tmp = 0; trace_input ("jls", OP_REGP, OP_VOID, OP_VOID); if ((PSR_L) == 0) { tmp = (GPR32 (OP[0])) & 0x3fffff; /* Use only 0 - 22 bits */ JMP (tmp << 1); /* Set PC's 1 - 23 bits and clear 0th bit*/ } trace_output_32 (tmp); } /* jgt. */ void OP_A6_C (void) { uint32 tmp = 0; trace_input ("jgt", OP_REGP, OP_VOID, OP_VOID); if ((PSR_N) == 1) { tmp = (GPR32 (OP[0])) & 0x3fffff; /* Use only 0 - 22 bits */ JMP (tmp << 1); /* Set PC's 1 - 23 bits and clear 0th bit*/ } trace_output_32 (tmp); } /* jle. */ void OP_A7_C (void) { uint32 tmp = 0; trace_input ("jle", OP_REGP, OP_VOID, OP_VOID); if ((PSR_N) == 0) { tmp = (GPR32 (OP[0])) & 0x3fffff; /* Use only 0 - 22 bits */ JMP (tmp << 1); /* Set PC's 1 - 23 bits and clear 0th bit*/ } trace_output_32 (tmp); } /* jfs. */ void OP_A8_C (void) { uint32 tmp = 0; trace_input ("jfs", OP_REGP, OP_VOID, OP_VOID); if ((PSR_F) == 1) { tmp = (GPR32 (OP[0])) & 0x3fffff; /* Use only 0 - 22 bits */ JMP (tmp << 1); /* Set PC's 1 - 23 bits and clear 0th bit*/ } trace_output_32 (tmp); } /* jfc. */ void OP_A9_C (void) { uint32 tmp = 0; trace_input ("jfc", OP_REGP, OP_VOID, OP_VOID); if ((PSR_F) == 0) { tmp = (GPR32 (OP[0])) & 0x3fffff; /* Use only 0 - 22 bits */ JMP (tmp << 1); /* Set PC's 1 - 23 bits and clear 0th bit*/ } trace_output_32 (tmp); } /* jlo. */ void OP_AA_C (void) { uint32 tmp = 0; trace_input ("jlo", OP_REGP, OP_VOID, OP_VOID); if (((PSR_Z) == 0) & ((PSR_L) == 0)) { tmp = (GPR32 (OP[0])) & 0x3fffff; /* Use only 0 - 22 bits */ JMP (tmp << 1); /* Set PC's 1 - 23 bits and clear 0th bit*/ } trace_output_32 (tmp); } /* jhs. */ void OP_AB_C (void) { uint32 tmp = 0; trace_input ("jhs", OP_REGP, OP_VOID, OP_VOID); if (((PSR_Z) == 1) | ((PSR_L) == 1)) { tmp = (GPR32 (OP[0])) & 0x3fffff; /* Use only 0 - 22 bits */ JMP (tmp << 1); /* Set PC's 1 - 23 bits and clear 0th bit*/ } trace_output_32 (tmp); } /* jlt. */ void OP_AC_C (void) { uint32 tmp = 0; trace_input ("jlt", OP_REGP, OP_VOID, OP_VOID); if (((PSR_Z) == 0) & ((PSR_N) == 0)) { tmp = (GPR32 (OP[0])) & 0x3fffff; /* Use only 0 - 22 bits */ JMP (tmp << 1); /* Set PC's 1 - 23 bits and clear 0th bit*/ } trace_output_32 (tmp); } /* jge. */ void OP_AD_C (void) { uint32 tmp = 0; trace_input ("jge", OP_REGP, OP_VOID, OP_VOID); if (((PSR_Z) == 1) | ((PSR_N) == 1)) { tmp = (GPR32 (OP[0])) & 0x3fffff; /* Use only 0 - 22 bits */ JMP (tmp << 1); /* Set PC's 1 - 23 bits and clear 0th bit*/ } trace_output_32 (tmp); } /* jump. */ void OP_AE_C (void) { uint32 tmp; trace_input ("jump", OP_REGP, OP_VOID, OP_VOID); tmp = GPR32 (OP[0]) /*& 0x3fffff*/; /* Use only 0 - 22 bits */ JMP (tmp << 1); /* Set PC's 1 - 23 bits and clear 0th bit*/ trace_output_32 (tmp); } /* jusr. */ void OP_AF_C (void) { uint32 tmp; trace_input ("jusr", OP_REGP, OP_VOID, OP_VOID); tmp = (GPR32 (OP[0])) & 0x3fffff; /* Use only 0 - 22 bits */ JMP (tmp << 1); /* Set PC's 1 - 23 bits and clear 0th bit*/ SET_PSR_U(1); trace_output_32 (tmp); } /* seq. */ void OP_80_C (void) { trace_input ("seq", OP_REG, OP_VOID, OP_VOID); if ((PSR_Z) == 1) SET_GPR (OP[0], 1); else SET_GPR (OP[0], 0); trace_output_void (); } /* sne. */ void OP_81_C (void) { trace_input ("sne", OP_REG, OP_VOID, OP_VOID); if ((PSR_Z) == 0) SET_GPR (OP[0], 1); else SET_GPR (OP[0], 0); trace_output_void (); } /* scs. */ void OP_82_C (void) { trace_input ("scs", OP_REG, OP_VOID, OP_VOID); if ((PSR_C) == 1) SET_GPR (OP[0], 1); else SET_GPR (OP[0], 0); trace_output_void (); } /* scc. */ void OP_83_C (void) { trace_input ("scc", OP_REG, OP_VOID, OP_VOID); if ((PSR_C) == 0) SET_GPR (OP[0], 1); else SET_GPR (OP[0], 0); trace_output_void (); } /* shi. */ void OP_84_C (void) { trace_input ("shi", OP_REG, OP_VOID, OP_VOID); if ((PSR_L) == 1) SET_GPR (OP[0], 1); else SET_GPR (OP[0], 0); trace_output_void (); } /* sls. */ void OP_85_C (void) { trace_input ("sls", OP_REG, OP_VOID, OP_VOID); if ((PSR_L) == 0) SET_GPR (OP[0], 1); else SET_GPR (OP[0], 0); trace_output_void (); } /* sgt. */ void OP_86_C (void) { trace_input ("sgt", OP_REG, OP_VOID, OP_VOID); if ((PSR_N) == 1) SET_GPR (OP[0], 1); else SET_GPR (OP[0], 0); trace_output_void (); } /* sle. */ void OP_87_C (void) { trace_input ("sle", OP_REG, OP_VOID, OP_VOID); if ((PSR_N) == 0) SET_GPR (OP[0], 1); else SET_GPR (OP[0], 0); trace_output_void (); } /* sfs. */ void OP_88_C (void) { trace_input ("sfs", OP_REG, OP_VOID, OP_VOID); if ((PSR_F) == 1) SET_GPR (OP[0], 1); else SET_GPR (OP[0], 0); trace_output_void (); } /* sfc. */ void OP_89_C (void) { trace_input ("sfc", OP_REG, OP_VOID, OP_VOID); if ((PSR_F) == 0) SET_GPR (OP[0], 1); else SET_GPR (OP[0], 0); trace_output_void (); } /* slo. */ void OP_8A_C (void) { trace_input ("slo", OP_REG, OP_VOID, OP_VOID); if (((PSR_Z) == 0) & ((PSR_L) == 0)) SET_GPR (OP[0], 1); else SET_GPR (OP[0], 0); trace_output_void (); } /* shs. */ void OP_8B_C (void) { trace_input ("shs", OP_REG, OP_VOID, OP_VOID); if ( ((PSR_Z) == 1) | ((PSR_L) == 1)) SET_GPR (OP[0], 1); else SET_GPR (OP[0], 0); trace_output_void (); } /* slt. */ void OP_8C_C (void) { trace_input ("slt", OP_REG, OP_VOID, OP_VOID); if (((PSR_Z) == 0) & ((PSR_N) == 0)) SET_GPR (OP[0], 1); else SET_GPR (OP[0], 0); trace_output_void (); } /* sge. */ void OP_8D_C (void) { trace_input ("sge", OP_REG, OP_VOID, OP_VOID); if (((PSR_Z) == 1) | ((PSR_N) == 1)) SET_GPR (OP[0], 1); else SET_GPR (OP[0], 0); trace_output_void (); } /* cbitb. */ void OP_D7_9 (void) { uint8 a = OP[0] & 0xff; uint32 addr = OP[1], tmp; trace_input ("cbitb", OP_CONSTANT4, OP_ABS20_OUTPUT, OP_VOID); tmp = RB (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp & ~(1 << a); SB (addr, tmp); trace_output_32 (tmp); } /* cbitb. */ void OP_107_14 (void) { uint8 a = OP[0] & 0xff; uint32 addr = OP[1], tmp; trace_input ("cbitb", OP_CONSTANT4, OP_ABS24_OUTPUT, OP_VOID); tmp = RB (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp & ~(1 << a); SB (addr, tmp); trace_output_32 (tmp); } /* cbitb. */ void OP_68_8 (void) { uint8 a = (OP[0]) & 0xff; uint32 addr = (GPR (OP[2])) + OP[1], tmp; trace_input ("cbitb", OP_CONSTANT4, OP_R_INDEX7_ABS20, OP_VOID); tmp = RB (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp & ~(1 << a); SB (addr, tmp); trace_output_32 (addr); } /* cbitb. */ void OP_1AA_A (void) { uint8 a = (OP[0]) & 0xff; uint32 addr = (GPR32 (OP[2])) + OP[1], tmp; trace_input ("cbitb", OP_CONSTANT4, OP_RP_INDEX_DISP14, OP_VOID); tmp = RB (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp & ~(1 << a); SB (addr, tmp); trace_output_32 (addr); } /* cbitb. */ void OP_104_14 (void) { uint8 a = (OP[0]) & 0xff; uint32 addr = (GPR (OP[2])) + OP[1], tmp; trace_input ("cbitb", OP_CONSTANT4, OP_R_BASE_DISPS20, OP_VOID); tmp = RB (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp & ~(1 << a); SB (addr, tmp); trace_output_32 (addr); } /* cbitb. */ void OP_D4_9 (void) { uint8 a = (OP[0]) & 0xff; uint32 addr = (GPR32 (OP[2])) + OP[1], tmp; trace_input ("cbitb", OP_CONSTANT4, OP_RP_INDEX_DISP0, OP_VOID); tmp = RB (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp & ~(1 << a); SB (addr, tmp); trace_output_32 (addr); } /* cbitb. */ void OP_D6_9 (void) { uint8 a = (OP[0]) & 0xff; uint32 addr = (GPR32 (OP[2])) + OP[1], tmp; trace_input ("cbitb", OP_CONSTANT4, OP_RP_BASE_DISP16, OP_VOID); tmp = RB (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp & ~(1 << a); SB (addr, tmp); trace_output_32 (addr); } /* cbitb. */ void OP_105_14 (void) { uint8 a = (OP[0]) & 0xff; uint32 addr = (GPR32 (OP[2])) + OP[1], tmp; trace_input ("cbitb", OP_CONSTANT4, OP_RP_BASE_DISPS20, OP_VOID); tmp = RB (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp & ~(1 << a); SB (addr, tmp); trace_output_32 (addr); } /* cbitb. */ void OP_106_14 (void) { uint8 a = (OP[0]) & 0xff; uint32 addr = (GPR32 (OP[2])) + OP[1], tmp; trace_input ("cbitb", OP_CONSTANT4, OP_RP_INDEX_DISPS20, OP_VOID); tmp = RB (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp & ~(1 << a); SB (addr, tmp); trace_output_32 (addr); } /* cbitw. */ void OP_6F_8 (void) { uint16 a = OP[0]; uint32 addr = OP[1], tmp; trace_input ("cbitw", OP_CONSTANT4, OP_ABS20_OUTPUT, OP_VOID); tmp = RW (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp & ~(1 << a); SW (addr, tmp); trace_output_32 (tmp); } /* cbitw. */ void OP_117_14 (void) { uint16 a = OP[0]; uint32 addr = OP[1], tmp; trace_input ("cbitw", OP_CONSTANT4, OP_ABS24_OUTPUT, OP_VOID); tmp = RW (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp & ~(1 << a); SW (addr, tmp); trace_output_32 (tmp); } /* cbitw. */ void OP_36_7 (void) { uint32 addr; uint16 a = (OP[0]), tmp; trace_input ("cbitw", OP_CONSTANT4, OP_R_INDEX8_ABS20, OP_VOID); if (OP[1] == 0) addr = (GPR32 (12)) + OP[2]; else addr = (GPR32 (13)) + OP[2]; tmp = RW (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp & ~(1 << a); SW (addr, tmp); trace_output_32 (addr); } /* cbitw. */ void OP_1AB_A (void) { uint16 a = (OP[0]); uint32 addr = (GPR32 (OP[2])) + OP[1], tmp; trace_input ("cbitw", OP_CONSTANT4, OP_RP_INDEX_DISP14, OP_VOID); tmp = RW (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp & ~(1 << a); SW (addr, tmp); trace_output_32 (addr); } /* cbitw. */ void OP_114_14 (void) { uint16 a = (OP[0]); uint32 addr = (GPR (OP[2])) + OP[1], tmp; trace_input ("cbitw", OP_CONSTANT4, OP_R_BASE_DISPS20, OP_VOID); tmp = RW (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp & ~(1 << a); SW (addr, tmp); trace_output_32 (addr); } /* cbitw. */ void OP_6E_8 (void) { uint16 a = (OP[0]); uint32 addr = (GPR32 (OP[2])) + OP[1], tmp; trace_input ("cbitw", OP_CONSTANT4, OP_RP_INDEX_DISP0, OP_VOID); tmp = RW (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp & ~(1 << a); SW (addr, tmp); trace_output_32 (addr); } /* cbitw. */ void OP_69_8 (void) { uint16 a = (OP[0]); uint32 addr = (GPR32 (OP[2])) + OP[1], tmp; trace_input ("cbitw", OP_CONSTANT4, OP_RP_BASE_DISP16, OP_VOID); tmp = RW (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp & ~(1 << a); SW (addr, tmp); trace_output_32 (addr); } /* cbitw. */ void OP_115_14 (void) { uint16 a = (OP[0]); uint32 addr = (GPR32 (OP[2])) + OP[1], tmp; trace_input ("cbitw", OP_CONSTANT4, OP_RP_BASE_DISPS20, OP_VOID); tmp = RW (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp & ~(1 << a); SW (addr, tmp); trace_output_32 (addr); } /* cbitw. */ void OP_116_14 (void) { uint16 a = (OP[0]); uint32 addr = (GPR32 (OP[2])) + OP[1], tmp; trace_input ("cbitw", OP_CONSTANT4, OP_RP_INDEX_DISPS20, OP_VOID); tmp = RW (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp & ~(1 << a); SW (addr, tmp); trace_output_32 (addr); } /* sbitb. */ void OP_E7_9 (void) { uint8 a = OP[0] & 0xff; uint32 addr = OP[1], tmp; trace_input ("sbitb", OP_CONSTANT4, OP_ABS20_OUTPUT, OP_VOID); tmp = RB (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp | (1 << a); SB (addr, tmp); trace_output_32 (tmp); } /* sbitb. */ void OP_10B_14 (void) { uint8 a = OP[0] & 0xff; uint32 addr = OP[1], tmp; trace_input ("sbitb", OP_CONSTANT4, OP_ABS24_OUTPUT, OP_VOID); tmp = RB (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp | (1 << a); SB (addr, tmp); trace_output_32 (tmp); } /* sbitb. */ void OP_70_8 (void) { uint8 a = OP[0] & 0xff; uint32 addr = (GPR (OP[2])) + OP[1], tmp; trace_input ("sbitb", OP_CONSTANT4, OP_R_INDEX7_ABS20, OP_VOID); tmp = RB (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp | (1 << a); SB (addr, tmp); trace_output_32 (tmp); } /* sbitb. */ void OP_1CA_A (void) { uint8 a = OP[0] & 0xff; uint32 addr = (GPR32 (OP[2])) + OP[1], tmp; trace_input ("sbitb", OP_CONSTANT4, OP_RP_INDEX_DISP14, OP_VOID); tmp = RB (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp | (1 << a); SB (addr, tmp); trace_output_32 (tmp); } /* sbitb. */ void OP_108_14 (void) { uint8 a = OP[0] & 0xff; uint32 addr = (GPR (OP[2])) + OP[1], tmp; trace_input ("sbitb", OP_CONSTANT4, OP_R_BASE_DISPS20, OP_VOID); tmp = RB (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp | (1 << a); SB (addr, tmp); trace_output_32 (tmp); } /* sbitb. */ void OP_E4_9 (void) { uint8 a = OP[0] & 0xff; uint32 addr = (GPR32 (OP[2])) + OP[1], tmp; trace_input ("sbitb", OP_CONSTANT4, OP_RP_INDEX_DISP0, OP_VOID); tmp = RB (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp | (1 << a); SB (addr, tmp); trace_output_32 (tmp); } /* sbitb. */ void OP_E6_9 (void) { uint8 a = OP[0] & 0xff; uint32 addr = (GPR32 (OP[2])) + OP[1], tmp; trace_input ("sbitb", OP_CONSTANT4, OP_RP_BASE_DISP16, OP_VOID); tmp = RB (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp | (1 << a); SB (addr, tmp); trace_output_32 (tmp); } /* sbitb. */ void OP_109_14 (void) { uint8 a = OP[0] & 0xff; uint32 addr = (GPR32 (OP[2])) + OP[1], tmp; trace_input ("sbitb", OP_CONSTANT4, OP_RP_BASE_DISPS20, OP_VOID); tmp = RB (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp | (1 << a); SB (addr, tmp); trace_output_32 (tmp); } /* sbitb. */ void OP_10A_14 (void) { uint8 a = OP[0] & 0xff; uint32 addr = (GPR32 (OP[2])) + OP[1], tmp; trace_input ("sbitb", OP_CONSTANT4, OP_RP_INDEX_DISPS20, OP_VOID); tmp = RB (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp | (1 << a); SB (addr, tmp); trace_output_32 (tmp); } /* sbitw. */ void OP_77_8 (void) { uint16 a = OP[0]; uint32 addr = OP[1], tmp; trace_input ("sbitw", OP_CONSTANT4, OP_ABS20_OUTPUT, OP_VOID); tmp = RW (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp | (1 << a); SW (addr, tmp); trace_output_32 (tmp); } /* sbitw. */ void OP_11B_14 (void) { uint16 a = OP[0]; uint32 addr = OP[1], tmp; trace_input ("sbitw", OP_CONSTANT4, OP_ABS24_OUTPUT, OP_VOID); tmp = RW (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp | (1 << a); SW (addr, tmp); trace_output_32 (tmp); } /* sbitw. */ void OP_3A_7 (void) { uint32 addr; uint16 a = (OP[0]), tmp; trace_input ("sbitw", OP_CONSTANT4, OP_R_INDEX8_ABS20, OP_VOID); if (OP[1] == 0) addr = (GPR32 (12)) + OP[2]; else addr = (GPR32 (13)) + OP[2]; tmp = RW (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp | (1 << a); SW (addr, tmp); trace_output_32 (addr); } /* sbitw. */ void OP_1CB_A (void) { uint16 a = (OP[0]); uint32 addr = (GPR32 (OP[2])) + OP[1], tmp; trace_input ("sbitw", OP_CONSTANT4, OP_RP_INDEX_DISP14, OP_VOID); tmp = RW (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp | (1 << a); SW (addr, tmp); trace_output_32 (addr); } /* sbitw. */ void OP_118_14 (void) { uint16 a = (OP[0]); uint32 addr = (GPR (OP[2])) + OP[1], tmp; trace_input ("sbitw", OP_CONSTANT4, OP_R_BASE_DISPS20, OP_VOID); tmp = RW (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp | (1 << a); SW (addr, tmp); trace_output_32 (addr); } /* sbitw. */ void OP_76_8 (void) { uint16 a = (OP[0]); uint32 addr = (GPR32 (OP[2])) + OP[1], tmp; trace_input ("sbitw", OP_CONSTANT4, OP_RP_INDEX_DISP0, OP_VOID); tmp = RW (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp | (1 << a); SW (addr, tmp); trace_output_32 (addr); } /* sbitw. */ void OP_71_8 (void) { uint16 a = (OP[0]); uint32 addr = (GPR32 (OP[2])) + OP[1], tmp; trace_input ("sbitw", OP_CONSTANT4, OP_RP_BASE_DISP16, OP_VOID); tmp = RW (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp | (1 << a); SW (addr, tmp); trace_output_32 (addr); } /* sbitw. */ void OP_119_14 (void) { uint16 a = (OP[0]); uint32 addr = (GPR32 (OP[2])) + OP[1], tmp; trace_input ("sbitw", OP_CONSTANT4, OP_RP_BASE_DISPS20, OP_VOID); tmp = RW (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp | (1 << a); SW (addr, tmp); trace_output_32 (addr); } /* sbitw. */ void OP_11A_14 (void) { uint16 a = (OP[0]); uint32 addr = (GPR32 (OP[2])) + OP[1], tmp; trace_input ("sbitw", OP_CONSTANT4, OP_RP_INDEX_DISPS20, OP_VOID); tmp = RW (addr); SET_PSR_F (tmp & (1 << a)); tmp = tmp | (1 << a); SW (addr, tmp); trace_output_32 (addr); } /* tbitb. */ void OP_F7_9 (void) { uint8 a = OP[0] & 0xff; uint32 addr = OP[1], tmp; trace_input ("tbitb", OP_CONSTANT4, OP_ABS20_OUTPUT, OP_VOID); tmp = RB (addr); SET_PSR_F (tmp & (1 << a)); trace_output_32 (tmp); } /* tbitb. */ void OP_10F_14 (void) { uint8 a = OP[0] & 0xff; uint32 addr = OP[1], tmp; trace_input ("tbitb", OP_CONSTANT4, OP_ABS24_OUTPUT, OP_VOID); tmp = RB (addr); SET_PSR_F (tmp & (1 << a)); trace_output_32 (tmp); } /* tbitb. */ void OP_78_8 (void) { uint8 a = (OP[0]) & 0xff; uint32 addr = (GPR (OP[2])) + OP[1], tmp; trace_input ("tbitb", OP_CONSTANT4, OP_R_INDEX7_ABS20, OP_VOID); tmp = RB (addr); SET_PSR_F (tmp & (1 << a)); trace_output_32 (addr); } /* tbitb. */ void OP_1EA_A (void) { uint8 a = (OP[0]) & 0xff; uint32 addr = (GPR32 (OP[2])) + OP[1], tmp; trace_input ("tbitb", OP_CONSTANT4, OP_RP_INDEX_DISP14, OP_VOID); tmp = RB (addr); SET_PSR_F (tmp & (1 << a)); trace_output_32 (addr); } /* tbitb. */ void OP_10C_14 (void) { uint8 a = (OP[0]) & 0xff; uint32 addr = (GPR (OP[2])) + OP[1], tmp; trace_input ("tbitb", OP_CONSTANT4, OP_R_BASE_DISPS20, OP_VOID); tmp = RB (addr); SET_PSR_F (tmp & (1 << a)); trace_output_32 (addr); } /* tbitb. */ void OP_F4_9 (void) { uint8 a = (OP[0]) & 0xff; uint32 addr = (GPR32 (OP[2])) + OP[1], tmp; trace_input ("tbitb", OP_CONSTANT4, OP_RP_INDEX_DISP0, OP_VOID); tmp = RB (addr); SET_PSR_F (tmp & (1 << a)); trace_output_32 (addr); } /* tbitb. */ void OP_F6_9 (void) { uint8 a = (OP[0]) & 0xff; uint32 addr = (GPR32 (OP[2])) + OP[1], tmp; trace_input ("tbitb", OP_CONSTANT4, OP_RP_BASE_DISP16, OP_VOID); tmp = RB (addr); SET_PSR_F (tmp & (1 << a)); trace_output_32 (addr); } /* tbitb. */ void OP_10D_14 (void) { uint8 a = (OP[0]) & 0xff; uint32 addr = (GPR32 (OP[2])) + OP[1], tmp; trace_input ("tbitb", OP_CONSTANT4, OP_RP_BASE_DISPS20, OP_VOID); tmp = RB (addr); SET_PSR_F (tmp & (1 << a)); trace_output_32 (addr); } /* tbitb. */ void OP_10E_14 (void) { uint8 a = (OP[0]) & 0xff; uint32 addr = (GPR32 (OP[2])) + OP[1], tmp; trace_input ("tbitb", OP_CONSTANT4, OP_RP_INDEX_DISPS20, OP_VOID); tmp = RB (addr); SET_PSR_F (tmp & (1 << a)); trace_output_32 (addr); } /* tbitw. */ void OP_7F_8 (void) { uint16 a = OP[0]; uint32 addr = OP[1], tmp; trace_input ("tbitw", OP_CONSTANT4, OP_ABS20_OUTPUT, OP_VOID); tmp = RW (addr); SET_PSR_F (tmp & (1 << a)); trace_output_32 (tmp); } /* tbitw. */ void OP_11F_14 (void) { uint16 a = OP[0]; uint32 addr = OP[1], tmp; trace_input ("tbitw", OP_CONSTANT4, OP_ABS24_OUTPUT, OP_VOID); tmp = RW (addr); SET_PSR_F (tmp & (1 << a)); trace_output_32 (tmp); } /* tbitw. */ void OP_3E_7 (void) { uint32 addr; uint16 a = (OP[0]), tmp; trace_input ("tbitw", OP_CONSTANT4, OP_R_INDEX8_ABS20, OP_VOID); if (OP[1] == 0) addr = (GPR32 (12)) + OP[2]; else addr = (GPR32 (13)) + OP[2]; tmp = RW (addr); SET_PSR_F (tmp & (1 << a)); trace_output_32 (addr); } /* tbitw. */ void OP_1EB_A (void) { uint16 a = (OP[0]); uint32 addr = (GPR32 (OP[2])) + OP[1], tmp; trace_input ("tbitw", OP_CONSTANT4, OP_RP_INDEX_DISP14, OP_VOID); tmp = RW (addr); SET_PSR_F (tmp & (1 << a)); trace_output_32 (addr); } /* tbitw. */ void OP_11C_14 (void) { uint16 a = (OP[0]); uint32 addr = (GPR (OP[2])) + OP[1], tmp; trace_input ("tbitw", OP_CONSTANT4, OP_R_BASE_DISPS20, OP_VOID); tmp = RW (addr); SET_PSR_F (tmp & (1 << a)); trace_output_32 (addr); } /* tbitw. */ void OP_7E_8 (void) { uint16 a = (OP[0]); uint32 addr = (GPR32 (OP[2])) + OP[1], tmp; trace_input ("tbitw", OP_CONSTANT4, OP_RP_INDEX_DISP0, OP_VOID); tmp = RW (addr); SET_PSR_F (tmp & (1 << a)); trace_output_32 (addr); } /* tbitw. */ void OP_79_8 (void) { uint16 a = (OP[0]); uint32 addr = (GPR32 (OP[2])) + OP[1], tmp; trace_input ("tbitw", OP_CONSTANT4, OP_RP_BASE_DISP16, OP_VOID); tmp = RW (addr); SET_PSR_F (tmp & (1 << a)); trace_output_32 (addr); } /* tbitw. */ void OP_11D_14 (void) { uint16 a = (OP[0]); uint32 addr = (GPR32 (OP[2])) + OP[1], tmp; trace_input ("tbitw", OP_CONSTANT4, OP_RP_BASE_DISPS20, OP_VOID); tmp = RW (addr); SET_PSR_F (tmp & (1 << a)); trace_output_32 (addr); } /* tbitw. */ void OP_11E_14 (void) { uint16 a = (OP[0]); uint32 addr = (GPR32 (OP[2])) + OP[1], tmp; trace_input ("tbitw", OP_CONSTANT4, OP_RP_INDEX_DISPS20, OP_VOID); tmp = RW (addr); SET_PSR_F (tmp & (1 << a)); trace_output_32 (addr); } /* tbit. */ void OP_6_8 (void) { uint16 a = OP[0]; uint16 b = (GPR (OP[1])); trace_input ("tbit", OP_CONSTANT4, OP_REG, OP_VOID); SET_PSR_F (b & (1 << a)); trace_output_16 (b); } /* tbit. */ void OP_7_8 (void) { uint16 a = GPR (OP[0]); uint16 b = (GPR (OP[1])); trace_input ("tbit", OP_REG, OP_REG, OP_VOID); SET_PSR_F (b & (1 << a)); trace_output_16 (b); } /* cmpb. */ void OP_50_8 (void) { uint8 a = (OP[0]) & 0xFF; uint8 b = (GPR (OP[1])) & 0xFF; trace_input ("cmpb", OP_CONSTANT4, OP_REG, OP_VOID); SET_PSR_Z (a == b); SET_PSR_N ((int8)a > (int8)b); SET_PSR_L (a > b); trace_output_flag (); } /* cmpb. */ void OP_50B_C (void) { uint8 a = (OP[0]) & 0xFF; uint8 b = (GPR (OP[1])) & 0xFF; trace_input ("cmpb", OP_CONSTANT16, OP_REG, OP_VOID); SET_PSR_Z (a == b); SET_PSR_N ((int8)a > (int8)b); SET_PSR_L (a > b); trace_output_flag (); } /* cmpb. */ void OP_51_8 (void) { uint8 a = (GPR (OP[0])) & 0xFF; uint8 b = (GPR (OP[1])) & 0xFF; trace_input ("cmpb", OP_REG, OP_REG, OP_VOID); SET_PSR_Z (a == b); SET_PSR_N ((int8)a > (int8)b); SET_PSR_L (a > b); trace_output_flag (); } /* cmpw. */ void OP_52_8 (void) { uint16 a = (OP[0]); uint16 b = GPR (OP[1]); trace_input ("cmpw", OP_CONSTANT4, OP_REG, OP_VOID); SET_PSR_Z (a == b); SET_PSR_N ((int16)a > (int16)b); SET_PSR_L (a > b); trace_output_flag (); } /* cmpw. */ void OP_52B_C (void) { uint16 a = (OP[0]); uint16 b = GPR (OP[1]); trace_input ("cmpw", OP_CONSTANT16, OP_REG, OP_VOID); SET_PSR_Z (a == b); SET_PSR_N ((int16)a > (int16)b); SET_PSR_L (a > b); trace_output_flag (); } /* cmpw. */ void OP_53_8 (void) { uint16 a = GPR (OP[0]) ; uint16 b = GPR (OP[1]) ; trace_input ("cmpw", OP_REG, OP_REG, OP_VOID); SET_PSR_Z (a == b); SET_PSR_N ((int16)a > (int16)b); SET_PSR_L (a > b); trace_output_flag (); } /* cmpd. */ void OP_56_8 (void) { uint32 a = (OP[0]); uint32 b = GPR32 (OP[1]); trace_input ("cmpd", OP_CONSTANT4, OP_REGP, OP_VOID); SET_PSR_Z (a == b); SET_PSR_N ((int32)a > (int32)b); SET_PSR_L (a > b); trace_output_flag (); } /* cmpd. */ void OP_56B_C (void) { uint32 a = (SEXT16(OP[0])); uint32 b = GPR32 (OP[1]); trace_input ("cmpd", OP_CONSTANT16, OP_REGP, OP_VOID); SET_PSR_Z (a == b); SET_PSR_N ((int32)a > (int32)b); SET_PSR_L (a > b); trace_output_flag (); } /* cmpd. */ void OP_57_8 (void) { uint32 a = GPR32 (OP[0]) ; uint32 b = GPR32 (OP[1]) ; trace_input ("cmpd", OP_REGP, OP_REGP, OP_VOID); SET_PSR_Z (a == b); SET_PSR_N ((int32)a > (int32)b); SET_PSR_L (a > b); trace_output_flag (); } /* cmpd. */ void OP_9_C (void) { uint32 a = (OP[0]); uint32 b = GPR32 (OP[1]); trace_input ("cmpd", OP_CONSTANT32, OP_REGP, OP_VOID); SET_PSR_Z (a == b); SET_PSR_N ((int32)a > (int32)b); SET_PSR_L (a > b); trace_output_flag (); } /* movb. */ void OP_58_8 (void) { uint8 tmp = OP[0] & 0xFF; uint16 a = (GPR (OP[1])) & 0xFF00; trace_input ("movb", OP_CONSTANT4, OP_REG, OP_VOID); SET_GPR (OP[1], (a | tmp)); trace_output_16 (tmp); } /* movb. */ void OP_58B_C (void) { uint8 tmp = OP[0] & 0xFF; uint16 a = (GPR (OP[1])) & 0xFF00; trace_input ("movb", OP_CONSTANT16, OP_REG, OP_VOID); SET_GPR (OP[1], (a | tmp)); trace_output_16 (tmp); } /* movb. */ void OP_59_8 (void) { uint8 tmp = (GPR (OP[0])) & 0xFF; uint16 a = (GPR (OP[1])) & 0xFF00; trace_input ("movb", OP_REG, OP_REG, OP_VOID); SET_GPR (OP[1], (a | tmp)); trace_output_16 (tmp); } /* movw. */ void OP_5A_8 (void) { uint16 tmp = OP[0]; trace_input ("movw", OP_CONSTANT4_1, OP_REG, OP_VOID); SET_GPR (OP[1], (tmp & 0xffff)); trace_output_16 (tmp); } /* movw. */ void OP_5AB_C (void) { int16 tmp = OP[0]; trace_input ("movw", OP_CONSTANT16, OP_REG, OP_VOID); SET_GPR (OP[1], (tmp & 0xffff)); trace_output_16 (tmp); } /* movw. */ void OP_5B_8 (void) { uint16 tmp = GPR (OP[0]); uint32 a = GPR32 (OP[1]); trace_input ("movw", OP_REG, OP_REGP, OP_VOID); a = (a & 0xffff0000) | tmp; SET_GPR32 (OP[1], a); trace_output_16 (tmp); } /* movxb. */ void OP_5C_8 (void) { uint8 tmp = (GPR (OP[0])) & 0xFF; trace_input ("movxb", OP_REG, OP_REG, OP_VOID); SET_GPR (OP[1], ((SEXT8(tmp)) & 0xffff)); trace_output_16 (tmp); } /* movzb. */ void OP_5D_8 (void) { uint8 tmp = (GPR (OP[0])) & 0xFF; trace_input ("movzb", OP_REG, OP_REG, OP_VOID); SET_GPR (OP[1], tmp); trace_output_16 (tmp); } /* movxw. */ void OP_5E_8 (void) { uint16 tmp = GPR (OP[0]); trace_input ("movxw", OP_REG, OP_REGP, OP_VOID); SET_GPR32 (OP[1], SEXT16(tmp)); trace_output_16 (tmp); } /* movzw. */ void OP_5F_8 (void) { uint16 tmp = GPR (OP[0]); trace_input ("movzw", OP_REG, OP_REGP, OP_VOID); SET_GPR32 (OP[1], (tmp & 0x0000FFFF)); trace_output_16 (tmp); } /* movd. */ void OP_54_8 (void) { int32 tmp = OP[0]; trace_input ("movd", OP_CONSTANT4, OP_REGP, OP_VOID); SET_GPR32 (OP[1], tmp); trace_output_32 (tmp); } /* movd. */ void OP_54B_C (void) { int32 tmp = SEXT16(OP[0]); trace_input ("movd", OP_CONSTANT16, OP_REGP, OP_VOID); SET_GPR32 (OP[1], tmp); trace_output_32 (tmp); } /* movd. */ void OP_55_8 (void) { uint32 tmp = GPR32 (OP[0]); trace_input ("movd", OP_REGP, OP_REGP, OP_VOID); SET_GPR32 (OP[1], tmp); trace_output_32 (tmp); } /* movd. */ void OP_5_8 (void) { uint32 tmp = OP[0]; trace_input ("movd", OP_CONSTANT20, OP_REGP, OP_VOID); SET_GPR32 (OP[1], tmp); trace_output_32 (tmp); } /* movd. */ void OP_7_C (void) { int32 tmp = OP[0]; trace_input ("movd", OP_CONSTANT32, OP_REGP, OP_VOID); SET_GPR32 (OP[1], tmp); trace_output_32 (tmp); } /* loadm. */ void OP_14_D (void) { uint32 addr = GPR (0); uint16 count = OP[0], reg = 2, tmp; trace_input ("loadm", OP_CONSTANT4, OP_VOID, OP_VOID); if ((addr & 1)) { State.exception = SIG_CR16_BUS; State.pc_changed = 1; /* Don't increment the PC. */ trace_output_void (); return; } while (count) { tmp = RW (addr); SET_GPR (reg, tmp); addr +=2; --count; reg++; if (reg == 6) reg = 8; }; SET_GPR (0, addr); trace_output_void (); } /* loadmp. */ void OP_15_D (void) { uint32 addr = GPR32 (0); uint16 count = OP[0], reg = 2, tmp; trace_input ("loadm", OP_CONSTANT4, OP_VOID, OP_VOID); if ((addr & 1)) { State.exception = SIG_CR16_BUS; State.pc_changed = 1; /* Don't increment the PC. */ trace_output_void (); return; } while (count) { tmp = RW (addr); SET_GPR (reg, tmp); addr +=2; --count; reg++; if (reg == 6) reg = 8; }; SET_GPR32 (0, addr); trace_output_void (); } /* loadb. */ void OP_88_8 (void) { /* loadb ABS20, REG * ADDR = zext24(abs20) | remap (ie 0xF00000) * REG = [ADDR] * NOTE: remap is * If (abs20 > 0xEFFFF) the resulting address is logically ORed * with 0xF00000 i.e. addresses from 1M-64k to 1M are re-mapped * by the core to 16M-64k to 16M. */ uint16 tmp, a = (GPR (OP[1])) & 0xFF00; uint32 addr = OP[0]; trace_input ("loadb", OP_ABS20, OP_REG, OP_VOID); if (addr > 0xEFFFF) addr |= 0xF00000; tmp = (RB (addr)); SET_GPR (OP[1], (a | tmp)); trace_output_16 (tmp); } /* loadb. */ void OP_127_14 (void) { /* loadb ABS24, REG * ADDR = abs24 * REGR = [ADDR]. */ uint16 tmp, a = (GPR (OP[1])) & 0xFF00; uint32 addr = OP[0]; trace_input ("loadb", OP_ABS24, OP_REG, OP_VOID); tmp = (RB (addr)); SET_GPR (OP[1], (a | tmp)); trace_output_16 (tmp); } /* loadb. */ void OP_45_7 (void) { /* loadb [Rindex]ABS20 REG * ADDR = Rindex + zext24(disp20) * REGR = [ADDR]. */ uint32 addr; uint16 tmp, a = (GPR (OP[2])) & 0xFF00; trace_input ("loadb", OP_R_INDEX8_ABS20, OP_REG, OP_VOID); if (OP[0] == 0) addr = (GPR32 (12)) + OP[1]; else addr = (GPR32 (13)) + OP[1]; tmp = (RB (addr)); SET_GPR (OP[2], (a | tmp)); trace_output_16 (tmp); } /* loadb. */ void OP_B_4 (void) { /* loadb DIPS4(REGP) REG * ADDR = RPBASE + zext24(DISP4) * REG = [ADDR]. */ uint16 tmp, a = (GPR (OP[2])) & 0xFF00; uint32 addr = (GPR32 (OP[1])) + OP[0]; trace_input ("loadb", OP_RP_BASE_DISP4, OP_REG, OP_VOID); tmp = (RB (addr)); SET_GPR (OP[2], (a | tmp)); trace_output_16 (tmp); } /* loadb. */ void OP_BE_8 (void) { /* loadb [Rindex]disp0(RPbasex) REG * ADDR = Rpbasex + Rindex * REGR = [ADDR] */ uint32 addr; uint16 tmp, a = (GPR (OP[3])) & 0xFF00; trace_input ("loadb", OP_RP_INDEX_DISP0, OP_REG, OP_VOID); addr = (GPR32 (OP[2])) + OP[1]; if (OP[0] == 0) addr = (GPR32 (12)) + addr; else addr = (GPR32 (13)) + addr; tmp = (RB (addr)); SET_GPR (OP[3], (a | tmp)); trace_output_16 (tmp); } /* loadb. */ void OP_219_A (void) { /* loadb [Rindex]disp14(RPbasex) REG * ADDR = Rpbasex + Rindex + zext24(disp14) * REGR = [ADDR] */ uint32 addr; uint16 tmp, a = (GPR (OP[3])) & 0xFF00; addr = (GPR32 (OP[2])) + OP[1]; if (OP[0] == 0) addr = (GPR32 (12)) + addr; else addr = (GPR32 (13)) + addr; trace_input ("loadb", OP_RP_INDEX_DISP14, OP_REG, OP_VOID); tmp = (RB (addr)); SET_GPR (OP[3], (a | tmp)); trace_output_16 (tmp); } /* loadb. */ void OP_184_14 (void) { /* loadb DISPE20(REG) REG * zext24(Rbase) + zext24(dispe20) * REG = [ADDR] */ uint16 tmp,a = (GPR (OP[2])) & 0xFF00; uint32 addr = OP[0] + (GPR (OP[1])); trace_input ("loadb", OP_R_BASE_DISPE20, OP_REG, OP_VOID); tmp = (RB (addr)); SET_GPR (OP[2], (a | tmp)); trace_output_16 (tmp); } /* loadb. */ void OP_124_14 (void) { /* loadb DISP20(REG) REG * ADDR = zext24(Rbase) + zext24(disp20) * REG = [ADDR] */ uint16 tmp,a = (GPR (OP[2])) & 0xFF00; uint32 addr = OP[0] + (GPR (OP[1])); trace_input ("loadb", OP_R_BASE_DISP20, OP_REG, OP_VOID); tmp = (RB (addr)); SET_GPR (OP[2], (a | tmp)); trace_output_16 (tmp); } /* loadb. */ void OP_BF_8 (void) { /* loadb disp16(REGP) REG * ADDR = RPbase + zext24(disp16) * REGR = [ADDR] */ uint16 tmp,a = (GPR (OP[2])) & 0xFF00; uint32 addr = (GPR32 (OP[1])) + OP[0]; trace_input ("loadb", OP_RP_BASE_DISP16, OP_REG, OP_VOID); tmp = (RB (addr)); SET_GPR (OP[2], (a | tmp)); trace_output_16 (tmp); } /* loadb. */ void OP_125_14 (void) { /* loadb disp20(REGP) REG * ADDR = RPbase + zext24(disp20) * REGR = [ADDR] */ uint16 tmp,a = (GPR (OP[2])) & 0xFF00; uint32 addr = (GPR32 (OP[1])) + OP[0]; trace_input ("loadb", OP_RP_BASE_DISP20, OP_REG, OP_VOID); tmp = (RB (addr)); SET_GPR (OP[2], (a | tmp)); trace_output_16 (tmp); } /* loadb. */ void OP_185_14 (void) { /* loadb -disp20(REGP) REG * ADDR = RPbase + zext24(-disp20) * REGR = [ADDR] */ uint16 tmp,a = (GPR (OP[2])) & 0xFF00; uint32 addr = (GPR32 (OP[1])) + OP[1]; trace_input ("loadb", OP_RP_BASE_DISPE20, OP_REG, OP_VOID); tmp = (RB (addr)); SET_GPR (OP[2], (a | tmp)); trace_output_16 (tmp); } /* loadb. */ void OP_126_14 (void) { /* loadb [Rindex]disp20(RPbasexb) REG * ADDR = RPbasex + Rindex + zext24(disp20) * REGR = [ADDR] */ uint32 addr; uint16 tmp, a = (GPR (OP[3])) & 0xFF00; trace_input ("loadb", OP_RP_INDEX_DISP20, OP_REG, OP_VOID); addr = (GPR32 (OP[2])) + OP[1]; if (OP[0] == 0) addr = (GPR32 (12)) + addr; else addr = (GPR32 (13)) + addr; tmp = (RB (addr)); SET_GPR (OP[3], (a | tmp)); trace_output_16 (tmp); } /* loadw. */ void OP_89_8 (void) { /* loadw ABS20, REG * ADDR = zext24(abs20) | remap * REGR = [ADDR] * NOTE: remap is * If (abs20 > 0xEFFFF) the resulting address is logically ORed * with 0xF00000 i.e. addresses from 1M-64k to 1M are re-mapped * by the core to 16M-64k to 16M. */ uint16 tmp; uint32 addr = OP[0]; trace_input ("loadw", OP_ABS20, OP_REG, OP_VOID); if (addr > 0xEFFFF) addr |= 0xF00000; tmp = (RW (addr)); SET_GPR (OP[1], tmp); trace_output_16 (tmp); } /* loadw. */ void OP_12F_14 (void) { /* loadw ABS24, REG * ADDR = abs24 * REGR = [ADDR] */ uint16 tmp; uint32 addr = OP[0]; trace_input ("loadw", OP_ABS24, OP_REG, OP_VOID); tmp = (RW (addr)); SET_GPR (OP[1], tmp); trace_output_16 (tmp); } /* loadw. */ void OP_47_7 (void) { /* loadw [Rindex]ABS20 REG * ADDR = Rindex + zext24(disp20) * REGR = [ADDR] */ uint32 addr; uint16 tmp; trace_input ("loadw", OP_R_INDEX8_ABS20, OP_REG, OP_VOID); if (OP[0] == 0) addr = (GPR32 (12)) + OP[1]; else addr = (GPR32 (13)) + OP[1]; tmp = (RW (addr)); SET_GPR (OP[2], tmp); trace_output_16 (tmp); } /* loadw. */ void OP_9_4 (void) { /* loadw DIPS4(REGP) REGP * ADDR = RPBASE + zext24(DISP4) * REGP = [ADDR]. */ uint16 tmp; uint32 addr, a; trace_input ("loadw", OP_RP_BASE_DISP4, OP_REG, OP_VOID); addr = (GPR32 (OP[1])) + OP[0]; tmp = (RW (addr)); if (OP[2] > 11) { a = (GPR32 (OP[2])) & 0xffff0000; SET_GPR32 (OP[2], (a | tmp)); } else SET_GPR (OP[2], tmp); trace_output_16 (tmp); } /* loadw. */ void OP_9E_8 (void) { /* loadw [Rindex]disp0(RPbasex) REG * ADDR = Rpbasex + Rindex * REGR = [ADDR] */ uint32 addr; uint16 tmp; trace_input ("loadw", OP_RP_INDEX_DISP0, OP_REG, OP_VOID); addr = (GPR32 (OP[2])) + OP[1]; if (OP[0] == 0) addr = (GPR32 (12)) + addr; else addr = (GPR32 (13)) + addr; tmp = RW (addr); SET_GPR (OP[3], tmp); trace_output_16 (tmp); } /* loadw. */ void OP_21B_A (void) { /* loadw [Rindex]disp14(RPbasex) REG * ADDR = Rpbasex + Rindex + zext24(disp14) * REGR = [ADDR] */ uint32 addr; uint16 tmp; trace_input ("loadw", OP_RP_INDEX_DISP14, OP_REG, OP_VOID); addr = (GPR32 (OP[2])) + OP[1]; if (OP[0] == 0) addr = (GPR32 (12)) + addr; else addr = (GPR32 (13)) + addr; tmp = (RW (addr)); SET_GPR (OP[3], tmp); trace_output_16 (tmp); } /* loadw. */ void OP_18C_14 (void) { /* loadw dispe20(REG) REGP * REGP = [DISPE20+[REG]] */ uint16 tmp; uint32 addr, a; trace_input ("loadw", OP_R_BASE_DISPE20, OP_REGP, OP_VOID); addr = OP[0] + (GPR (OP[1])); tmp = (RW (addr)); if (OP[2] > 11) { a = (GPR32 (OP[2])) & 0xffff0000; SET_GPR32 (OP[2], (a | tmp)); } else SET_GPR (OP[2], tmp); trace_output_16 (tmp); } /* loadw. */ void OP_12C_14 (void) { /* loadw DISP20(REG) REGP * ADDR = zext24(Rbase) + zext24(disp20) * REGP = [ADDR] */ uint16 tmp; uint32 addr, a; trace_input ("loadw", OP_R_BASE_DISP20, OP_REGP, OP_VOID); addr = OP[0] + (GPR (OP[1])); tmp = (RW (addr)); if (OP[2] > 11) { a = (GPR32 (OP[2])) & 0xffff0000; SET_GPR32 (OP[2], (a | tmp)); } else SET_GPR (OP[2], tmp); trace_output_16 (tmp); } /* loadw. */ void OP_9F_8 (void) { /* loadw disp16(REGP) REGP * ADDR = RPbase + zext24(disp16) * REGP = [ADDR] */ uint16 tmp; uint32 addr, a; trace_input ("loadw", OP_RP_BASE_DISP16, OP_REGP, OP_VOID); addr = (GPR32 (OP[1])) + OP[0]; tmp = (RW (addr)); if (OP[2] > 11) { a = (GPR32 (OP[2])) & 0xffff0000; SET_GPR32 (OP[2], (a | tmp)); } else SET_GPR (OP[2], tmp); trace_output_16 (tmp); } /* loadw. */ void OP_12D_14 (void) { /* loadw disp20(REGP) REGP * ADDR = RPbase + zext24(disp20) * REGP = [ADDR] */ uint16 tmp; uint32 addr, a; trace_input ("loadw", OP_RP_BASE_DISP20, OP_REG, OP_VOID); addr = (GPR32 (OP[1])) + OP[0]; tmp = (RW (addr)); if (OP[2] > 11) { a = (GPR32 (OP[2])) & 0xffff0000; SET_GPR32 (OP[2], (a | tmp)); } else SET_GPR (OP[2], tmp); trace_output_16 (tmp); } /* loadw. */ void OP_18D_14 (void) { /* loadw -disp20(REGP) REG * ADDR = RPbase + zext24(-disp20) * REGR = [ADDR] */ uint16 tmp; uint32 addr, a; trace_input ("loadw", OP_RP_BASE_DISPE20, OP_REG, OP_VOID); addr = (GPR32 (OP[1])) + OP[0]; tmp = (RB (addr)); if (OP[2] > 11) { a = (GPR32 (OP[2])) & 0xffff0000; SET_GPR32 (OP[2], (a | tmp)); } else SET_GPR (OP[2], tmp); trace_output_16 (tmp); } /* loadw. */ void OP_12E_14 (void) { /* loadw [Rindex]disp20(RPbasexb) REG * ADDR = RPbasex + Rindex + zext24(disp20) * REGR = [ADDR] */ uint32 addr; uint16 tmp; trace_input ("loadw", OP_RP_INDEX_DISP20, OP_REG, OP_VOID); if (OP[0] == 0) addr = (GPR32 (12)) + OP[1] + (GPR32 (OP[2])); else addr = (GPR32 (13)) + OP[1] + (GPR32 (OP[2])); tmp = (RW (addr)); SET_GPR (OP[3], tmp); trace_output_16 (tmp); } /* loadd. */ void OP_87_8 (void) { /* loadd ABS20, REGP * ADDR = zext24(abs20) | remap * REGP = [ADDR] * NOTE: remap is * If (abs20 > 0xEFFFF) the resulting address is logically ORed * with 0xF00000 i.e. addresses from 1M-64k to 1M are re-mapped * by the core to 16M-64k to 16M. */ uint32 addr, tmp; addr = OP[0]; trace_input ("loadd", OP_ABS20, OP_REGP, OP_VOID); if (addr > 0xEFFFF) addr |= 0xF00000; tmp = RLW (addr); tmp = ((tmp << 16) & 0xffff)| ((tmp >> 16) & 0xffff); SET_GPR32 (OP[1], tmp); trace_output_32 (tmp); } /* loadd. */ void OP_12B_14 (void) { /* loadd ABS24, REGP * ADDR = abs24 * REGP = [ADDR] */ uint32 addr = OP[0]; uint32 tmp; trace_input ("loadd", OP_ABS24, OP_REGP, OP_VOID); tmp = RLW (addr); tmp = ((tmp & 0xffff) << 16)| ((tmp >> 16) & 0xffff); SET_GPR32 (OP[1],tmp); trace_output_32 (tmp); } /* loadd. */ void OP_46_7 (void) { /* loadd [Rindex]ABS20 REGP * ADDR = Rindex + zext24(disp20) * REGP = [ADDR] */ uint32 addr, tmp; trace_input ("loadd", OP_R_INDEX8_ABS20, OP_REGP, OP_VOID); if (OP[0] == 0) addr = (GPR32 (12)) + OP[1]; else addr = (GPR32 (13)) + OP[1]; tmp = RLW (addr); tmp = ((tmp & 0xffff) << 16)| ((tmp >> 16) & 0xffff); SET_GPR32 (OP[2], tmp); trace_output_32 (tmp); } /* loadd. */ void OP_A_4 (void) { /* loadd dips4(regp) REGP * ADDR = Rpbase + zext24(disp4) * REGP = [ADDR] */ uint32 tmp, addr = (GPR32 (OP[1])) + OP[0]; trace_input ("loadd", OP_RP_BASE_DISP4, OP_REGP, OP_VOID); tmp = RLW (addr); tmp = ((tmp & 0xffff) << 16)| ((tmp >> 16) & 0xffff); SET_GPR32 (OP[2], tmp); trace_output_32 (tmp); } /* loadd. */ void OP_AE_8 (void) { /* loadd [Rindex]disp0(RPbasex) REGP * ADDR = Rpbasex + Rindex * REGP = [ADDR] */ uint32 addr, tmp; trace_input ("loadd", OP_RP_INDEX_DISP0, OP_REGP, OP_VOID); if (OP[0] == 0) addr = (GPR32 (12)) + (GPR32 (OP[2])) + OP[1]; else addr = (GPR32 (13)) + (GPR32 (OP[2])) + OP[1]; tmp = RLW (addr); tmp = ((tmp & 0xffff) << 16)| ((tmp >> 16) & 0xffff); SET_GPR32 (OP[3], tmp); trace_output_32 (tmp); } /* loadd. */ void OP_21A_A (void) { /* loadd [Rindex]disp14(RPbasex) REGP * ADDR = Rpbasex + Rindex + zext24(disp14) * REGR = [ADDR] */ uint32 addr, tmp; trace_input ("loadd", OP_RP_INDEX_DISP14, OP_REGP, OP_VOID); if (OP[0] == 0) addr = (GPR32 (12)) + OP[1] + (GPR32 (OP[2])); else addr = (GPR32 (13)) + OP[1] + (GPR32 (OP[2])); tmp = RLW (addr); tmp = ((tmp & 0xffff) << 16)| ((tmp >> 16) & 0xffff); SET_GPR (OP[3],tmp); trace_output_32 (tmp); } /* loadd. */ void OP_188_14 (void) { /* loadd dispe20(REG) REG * zext24(Rbase) + zext24(dispe20) * REG = [ADDR] */ uint32 tmp, addr = OP[0] + (GPR (OP[1])); trace_input ("loadd", OP_R_BASE_DISPE20, OP_REGP, OP_VOID); tmp = RLW (addr); tmp = ((tmp & 0xffff) << 16)| ((tmp >> 16) & 0xffff); SET_GPR32 (OP[2], tmp); trace_output_32 (tmp); } /* loadd. */ void OP_128_14 (void) { /* loadd DISP20(REG) REG * ADDR = zext24(Rbase) + zext24(disp20) * REG = [ADDR] */ uint32 tmp, addr = OP[0] + (GPR (OP[1])); trace_input ("loadd", OP_R_BASE_DISP20, OP_REGP, OP_VOID); tmp = RLW (addr); tmp = ((tmp & 0xffff) << 16)| ((tmp >> 16) & 0xffff); SET_GPR32 (OP[2], tmp); trace_output_32 (tmp); } /* loadd. */ void OP_AF_8 (void) { /* loadd disp16(REGP) REGP * ADDR = RPbase + zext24(disp16) * REGR = [ADDR] */ uint32 tmp, addr = OP[0] + (GPR32 (OP[1])); trace_input ("loadd", OP_RP_BASE_DISP16, OP_REGP, OP_VOID); tmp = RLW (addr); tmp = ((tmp & 0xffff) << 16)| ((tmp >> 16) & 0xffff); SET_GPR32 (OP[2], tmp); trace_output_32 (tmp); } /* loadd. */ void OP_129_14 (void) { /* loadd disp20(REGP) REGP * ADDR = RPbase + zext24(disp20) * REGP = [ADDR] */ uint32 tmp, addr = OP[0] + (GPR32 (OP[1])); trace_input ("loadd", OP_RP_BASE_DISP20, OP_REGP, OP_VOID); tmp = RLW (addr); tmp = ((tmp & 0xffff) << 16)| ((tmp >> 16) & 0xffff); SET_GPR32 (OP[2], tmp); trace_output_32 (tmp); } /* loadd. */ void OP_189_14 (void) { /* loadd -disp20(REGP) REGP * ADDR = RPbase + zext24(-disp20) * REGP = [ADDR] */ uint32 tmp, addr = OP[0] + (GPR32 (OP[1])); trace_input ("loadd", OP_RP_BASE_DISPE20, OP_REGP, OP_VOID); tmp = RLW (addr); tmp = ((tmp & 0xffff) << 16)| ((tmp >> 16) & 0xffff); SET_GPR32 (OP[2], tmp); trace_output_32 (tmp); } /* loadd. */ void OP_12A_14 (void) { /* loadd [Rindex]disp20(RPbasexb) REGP * ADDR = RPbasex + Rindex + zext24(disp20) * REGP = [ADDR] */ uint32 addr, tmp; trace_input ("loadd", OP_RP_INDEX_DISP20, OP_REGP, OP_VOID); if (OP[0] == 0) addr = (GPR32 (12)) + OP[1] + (GPR32 (OP[2])); else addr = (GPR32 (13)) + OP[1] + (GPR32 (OP[2])); tmp = RLW (addr); tmp = ((tmp << 16) & 0xffff)| ((tmp >> 16) & 0xffff); SET_GPR32 (OP[3], tmp); trace_output_32 (tmp); } /* storb. */ void OP_C8_8 (void) { /* storb REG, ABS20 * ADDR = zext24(abs20) | remap * [ADDR] = REGR * NOTE: remap is * If (abs20 > 0xEFFFF) the resulting address is logically ORed * with 0xF00000 i.e. addresses from 1M-64k to 1M are re-mapped * by the core to 16M-64k to 16M. */ uint8 a = ((GPR (OP[0])) & 0xff); uint32 addr = OP[1]; trace_input ("storb", OP_REG, OP_ABS20_OUTPUT, OP_VOID); SB (addr, a); trace_output_32 (addr); } /* storb. */ void OP_137_14 (void) { /* storb REG, ABS24 * ADDR = abs24 * [ADDR] = REGR. */ uint8 a = ((GPR (OP[0])) & 0xff); uint32 addr = OP[1]; trace_input ("storb", OP_REG, OP_ABS24_OUTPUT, OP_VOID); SB (addr, a); trace_output_32 (addr); } /* storb. */ void OP_65_7 (void) { /* storb REG, [Rindex]ABS20 * ADDR = Rindex + zext24(disp20) * [ADDR] = REGR */ uint32 addr; uint8 a = ((GPR (OP[0])) & 0xff); trace_input ("storb", OP_REG, OP_R_INDEX8_ABS20, OP_VOID); if (OP[1] == 0) addr = (GPR32 (12)) + OP[2]; else addr = (GPR32 (13)) + OP[2]; SB (addr, a); trace_output_32 (addr); } /* storb. */ void OP_F_4 (void) { /* storb REG, DIPS4(REGP) * ADDR = RPBASE + zext24(DISP4) * [ADDR] = REG. */ uint16 a = ((GPR (OP[0])) & 0xff); uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("storb", OP_REG, OP_RP_BASE_DISPE4, OP_VOID); SB (addr, a); trace_output_32 (addr); } /* storb. */ void OP_FE_8 (void) { /* storb [Rindex]disp0(RPbasex) REG * ADDR = Rpbasex + Rindex * [ADDR] = REGR */ uint32 addr; uint8 a = ((GPR (OP[0])) & 0xff); trace_input ("storb", OP_REG, OP_RP_INDEX_DISP0, OP_VOID); if (OP[1] == 0) addr = (GPR32 (12)) + (GPR32 (OP[3])) + OP[2]; else addr = (GPR32 (13)) + (GPR32 (OP[3])) + OP[2]; SB (addr, a); trace_output_32 (addr); } /* storb. */ void OP_319_A (void) { /* storb REG, [Rindex]disp14(RPbasex) * ADDR = Rpbasex + Rindex + zext24(disp14) * [ADDR] = REGR */ uint8 a = ((GPR (OP[0])) & 0xff); uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("storb", OP_REG, OP_RP_INDEX_DISP14, OP_VOID); SB (addr, a); trace_output_32 (addr); } /* storb. */ void OP_194_14 (void) { /* storb REG, DISPE20(REG) * zext24(Rbase) + zext24(dispe20) * [ADDR] = REG */ uint8 a = ((GPR (OP[0])) & 0xff); uint32 addr = OP[1] + (GPR (OP[2])); trace_input ("storb", OP_REG, OP_R_BASE_DISPE20, OP_VOID); SB (addr, a); trace_output_32 (addr); } /* storb. */ void OP_134_14 (void) { /* storb REG, DISP20(REG) * ADDR = zext24(Rbase) + zext24(disp20) * [ADDR] = REG */ uint8 a = (GPR (OP[0]) & 0xff); uint32 addr = OP[1] + (GPR (OP[2])); trace_input ("storb", OP_REG, OP_R_BASE_DISPS20, OP_VOID); SB (addr, a); trace_output_32 (addr); } /* storb. */ void OP_FF_8 (void) { /* storb REG, disp16(REGP) * ADDR = RPbase + zext24(disp16) * [ADDR] = REGP */ uint8 a = ((GPR (OP[0])) & 0xff); uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("storb", OP_REG, OP_RP_BASE_DISP16, OP_VOID); SB (addr, a); trace_output_32 (addr); } /* storb. */ void OP_135_14 (void) { /* storb REG, disp20(REGP) * ADDR = RPbase + zext24(disp20) * [ADDR] = REGP */ uint8 a = ((GPR (OP[0])) & 0xff); uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("storb", OP_REG, OP_RP_BASE_DISPS20, OP_VOID); SB (addr, a); trace_output_32 (addr); } /* storb. */ void OP_195_14 (void) { /* storb REG, -disp20(REGP) * ADDR = RPbase + zext24(-disp20) * [ADDR] = REGP */ uint8 a = (GPR (OP[0]) & 0xff); uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("storb", OP_REG, OP_RP_BASE_DISPE20, OP_VOID); SB (addr, a); trace_output_32 (addr); } /* storb. */ void OP_136_14 (void) { /* storb REG, [Rindex]disp20(RPbase) * ADDR = RPbasex + Rindex + zext24(disp20) * [ADDR] = REGP */ uint8 a = (GPR (OP[0])) & 0xff; uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("storb", OP_REG, OP_RP_INDEX_DISPS20, OP_VOID); SB (addr, a); trace_output_32 (addr); } /* STR_IMM instructions. */ /* storb . */ void OP_81_8 (void) { uint8 a = (OP[0]) & 0xff; uint32 addr = OP[1]; trace_input ("storb", OP_CONSTANT4, OP_ABS20_OUTPUT, OP_VOID); SB (addr, a); trace_output_32 (addr); } /* storb. */ void OP_123_14 (void) { uint8 a = (OP[0]) & 0xff; uint32 addr = OP[1]; trace_input ("storb", OP_CONSTANT4, OP_ABS24_OUTPUT, OP_VOID); SB (addr, a); trace_output_32 (addr); } /* storb. */ void OP_42_7 (void) { uint32 addr; uint8 a = (OP[0]) & 0xff; trace_input ("storb", OP_CONSTANT4, OP_R_INDEX8_ABS20, OP_VOID); if (OP[1] == 0) addr = (GPR32 (12)) + OP[2]; else addr = (GPR32 (13)) + OP[2]; SB (addr, a); trace_output_32 (addr); } /* storb. */ void OP_218_A (void) { uint8 a = (OP[0]) & 0xff; uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("storb", OP_CONSTANT4, OP_RP_BASE_DISP14, OP_VOID); SB (addr, a); trace_output_32 (addr); } /* storb. */ void OP_82_8 (void) { uint8 a = (OP[0]) & 0xff; uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("storb", OP_CONSTANT4, OP_RP_INDEX_DISP0, OP_VOID); SB (addr, a); trace_output_32 (addr); } /* storb. */ void OP_120_14 (void) { uint8 a = (OP[0]) & 0xff; uint32 addr = (GPR (OP[2])) + OP[1]; trace_input ("storb", OP_CONSTANT4, OP_R_BASE_DISPS20, OP_VOID); SB (addr, a); trace_output_32 (addr); } /* storb. */ void OP_83_8 (void) { uint8 a = (OP[0]) & 0xff; uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("storb", OP_CONSTANT4, OP_RP_BASE_DISP16, OP_VOID); SB (addr, a); trace_output_32 (addr); } /* storb. */ void OP_121_14 (void) { uint8 a = (OP[0]) & 0xff; uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("storb", OP_CONSTANT4, OP_RP_BASE_DISPS20, OP_VOID); SB (addr, a); trace_output_32 (addr); } /* storb. */ void OP_122_14 (void) { uint8 a = (OP[0]) & 0xff; uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("storb", OP_CONSTANT4, OP_RP_INDEX_DISPS20, OP_VOID); SB (addr, a); trace_output_32 (addr); } /* endif for STR_IMM. */ /* storw . */ void OP_C9_8 (void) { uint16 a = GPR (OP[0]); uint32 addr = OP[1]; trace_input ("storw", OP_REG, OP_ABS20_OUTPUT, OP_VOID); SW (addr, a); trace_output_32 (addr); } /* storw. */ void OP_13F_14 (void) { uint16 a = GPR (OP[0]); uint32 addr = OP[1]; trace_input ("storw", OP_REG, OP_ABS24_OUTPUT, OP_VOID); SW (addr, a); trace_output_32 (addr); } /* storw. */ void OP_67_7 (void) { uint32 addr; uint16 a = GPR (OP[0]); trace_input ("storw", OP_REG, OP_R_INDEX8_ABS20, OP_VOID); if (OP[1] == 0) addr = (GPR32 (12)) + OP[2]; else addr = (GPR32 (13)) + OP[2]; SW (addr, a); trace_output_32 (addr); } /* storw. */ void OP_D_4 (void) { uint16 a = (GPR (OP[0])); uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("storw", OP_REGP, OP_RP_BASE_DISPE4, OP_VOID); SW (addr, a); trace_output_32 (addr); } /* storw. */ void OP_DE_8 (void) { uint16 a = GPR (OP[0]); uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("storw", OP_REG, OP_RP_INDEX_DISP0, OP_VOID); SW (addr, a); trace_output_32 (addr); } /* storw. */ void OP_31B_A (void) { uint16 a = GPR (OP[0]); uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("storw", OP_REG, OP_RP_INDEX_DISP14, OP_VOID); SW (addr, a); trace_output_32 (addr); } /* storw. */ void OP_19C_14 (void) { uint16 a = (GPR (OP[0])); uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("storw", OP_REGP, OP_RP_BASE_DISPE20, OP_VOID); SW (addr, a); trace_output_32 (addr); } /* storw. */ void OP_13C_14 (void) { uint16 a = (GPR (OP[0])); uint32 addr = (GPR (OP[2])) + OP[1]; trace_input ("storw", OP_REG, OP_R_BASE_DISPS20, OP_VOID); SW (addr, a); trace_output_32 (addr); } /* storw. */ void OP_DF_8 (void) { uint16 a = (GPR (OP[0])); uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("storw", OP_REG, OP_RP_BASE_DISP16, OP_VOID); SW (addr, a); trace_output_32 (addr); } /* storw. */ void OP_13D_14 (void) { uint16 a = (GPR (OP[0])); uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("storw", OP_REG, OP_RP_BASE_DISPS20, OP_VOID); SW (addr, a); trace_output_32 (addr); } /* storw. */ void OP_19D_14 (void) { uint16 a = (GPR (OP[0])); uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("storw", OP_REG, OP_RP_BASE_DISPE20, OP_VOID); SW (addr, a); trace_output_32 (addr); } /* storw. */ void OP_13E_14 (void) { uint16 a = (GPR (OP[0])); uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("storw", OP_REG, OP_RP_INDEX_DISPS20, OP_VOID); SW (addr, a); trace_output_32 (addr); } /* STORE-w IMM instruction *****/ /* storw . */ void OP_C1_8 (void) { uint16 a = OP[0]; uint32 addr = OP[1]; trace_input ("storw", OP_CONSTANT4, OP_ABS20_OUTPUT, OP_VOID); SW (addr, a); trace_output_32 (addr); } /* storw. */ void OP_133_14 (void) { uint16 a = OP[0]; uint32 addr = OP[1]; trace_input ("storw", OP_CONSTANT4, OP_ABS24_OUTPUT, OP_VOID); SW (addr, a); trace_output_32 (addr); } /* storw. */ void OP_62_7 (void) { uint32 addr; uint16 a = OP[0]; trace_input ("storw", OP_CONSTANT4, OP_R_INDEX8_ABS20, OP_VOID); if (OP[1] == 0) addr = (GPR32 (12)) + OP[2]; else addr = (GPR32 (13)) + OP[2]; SW (addr, a); trace_output_32 (addr); } /* storw. */ void OP_318_A (void) { uint16 a = OP[0]; uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("storw", OP_CONSTANT4, OP_RP_BASE_DISP14, OP_VOID); SW (addr, a); trace_output_32 (addr); } /* storw. */ void OP_C2_8 (void) { uint16 a = OP[0]; uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("storw", OP_CONSTANT4, OP_RP_INDEX_DISP0, OP_VOID); SW (addr, a); trace_output_32 (addr); } /* storw. */ void OP_130_14 (void) { uint16 a = OP[0]; uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("storw", OP_CONSTANT4, OP_R_BASE_DISPS20, OP_VOID); SW (addr, a); trace_output_32 (addr); } /* storw. */ void OP_C3_8 (void) { uint16 a = OP[0]; uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("storw", OP_CONSTANT4, OP_RP_BASE_DISP16, OP_VOID); SW (addr, a); trace_output_32 (addr); } /* storw. */ void OP_131_14 (void) { uint16 a = OP[0]; uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("storw", OP_CONSTANT4, OP_RP_BASE_DISPS20, OP_VOID); SW (addr, a); trace_output_32 (addr); } /* storw. */ void OP_132_14 (void) { uint16 a = OP[0]; uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("storw", OP_CONSTANT4, OP_RP_INDEX_DISPS20, OP_VOID); SW (addr, a); trace_output_32 (addr); } /* stord. */ void OP_C7_8 (void) { uint32 a = GPR32 (OP[0]); uint32 addr = OP[1]; trace_input ("stord", OP_REGP, OP_ABS20_OUTPUT, OP_VOID); SLW (addr, a); trace_output_32 (addr); } /* stord. */ void OP_13B_14 (void) { uint32 a = GPR32 (OP[0]); uint32 addr = OP[1]; trace_input ("stord", OP_REGP, OP_ABS24_OUTPUT, OP_VOID); SLW (addr, a); trace_output_32 (addr); } /* stord. */ void OP_66_7 (void) { uint32 addr, a = GPR32 (OP[0]); trace_input ("stord", OP_REGP, OP_R_INDEX8_ABS20, OP_VOID); if (OP[1] == 0) addr = (GPR32 (12)) + OP[2]; else addr = (GPR32 (13)) + OP[2]; SLW (addr, a); trace_output_32 (addr); } /* stord. */ void OP_E_4 (void) { uint32 a = GPR32 (OP[0]); uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("stord", OP_REGP, OP_RP_BASE_DISPE4, OP_VOID); SLW (addr, a); trace_output_32 (addr); } /* stord. */ void OP_EE_8 (void) { uint32 a = GPR32 (OP[0]); uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("stord", OP_REGP, OP_RP_INDEX_DISP0, OP_VOID); SLW (addr, a); trace_output_32 (addr); } /* stord. */ void OP_31A_A (void) { uint32 a = GPR32 (OP[0]); uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("stord", OP_REGP, OP_RP_INDEX_DISP14, OP_VOID); SLW (addr, a); trace_output_32 (addr); } /* stord. */ void OP_198_14 (void) { uint32 a = GPR32 (OP[0]); uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("stord", OP_REGP, OP_R_BASE_DISPE20, OP_VOID); SLW (addr, a); trace_output_32 (addr); } /* stord. */ void OP_138_14 (void) { uint32 a = GPR32 (OP[0]); uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("stord", OP_REGP, OP_R_BASE_DISPS20, OP_VOID); SLW (addr, a); trace_output_32 (addr); } /* stord. */ void OP_EF_8 (void) { uint32 a = GPR32 (OP[0]); uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("stord", OP_REGP, OP_RP_BASE_DISP16, OP_VOID); SLW (addr, a); trace_output_32 (addr); } /* stord. */ void OP_139_14 (void) { uint32 a = GPR32 (OP[0]); uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("stord", OP_REGP, OP_RP_BASE_DISPS20, OP_VOID); SLW (addr, a); trace_output_32 (addr); } /* stord. */ void OP_199_14 (void) { uint32 a = GPR32 (OP[0]); uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("stord", OP_REGP, OP_RP_BASE_DISPE20, OP_VOID); SLW (addr, a); trace_output_32 (addr); } /* stord. */ void OP_13A_14 (void) { uint32 a = GPR32 (OP[0]); uint32 addr = (GPR32 (OP[2])) + OP[1]; trace_input ("stord", OP_REGP, OP_RP_INDEX_DISPS20, OP_VOID); SLW (addr, a); trace_output_32 (addr); } /* macqu. */ void OP_14D_14 (void) { int32 tmp; int16 src1, src2; trace_input ("macuw", OP_REG, OP_REG, OP_REGP); src1 = GPR (OP[0]); src2 = GPR (OP[1]); tmp = src1 * src2; /*REVISIT FOR SATURATION and Q FORMAT. */ SET_GPR32 (OP[2], tmp); trace_output_32 (tmp); } /* macuw. */ void OP_14E_14 (void) { uint32 tmp; uint16 src1, src2; trace_input ("macuw", OP_REG, OP_REG, OP_REGP); src1 = GPR (OP[0]); src2 = GPR (OP[1]); tmp = src1 * src2; /*REVISIT FOR SATURATION. */ SET_GPR32 (OP[2], tmp); trace_output_32 (tmp); } /* macsw. */ void OP_14F_14 (void) { int32 tmp; int16 src1, src2; trace_input ("macsw", OP_REG, OP_REG, OP_REGP); src1 = GPR (OP[0]); src2 = GPR (OP[1]); tmp = src1 * src2; /*REVISIT FOR SATURATION. */ SET_GPR32 (OP[2], tmp); trace_output_32 (tmp); } /* mulb. */ void OP_64_8 (void) { int16 tmp; int8 a = (OP[0]) & 0xff; int8 b = (GPR (OP[1])) & 0xff; trace_input ("mulb", OP_CONSTANT4_1, OP_REG, OP_VOID); tmp = (a * b) & 0xff; SET_GPR (OP[1], (tmp | ((GPR (OP[1])) & 0xff00))); trace_output_16 (tmp); } /* mulb. */ void OP_64B_C (void) { int16 tmp; int8 a = (OP[0]) & 0xff, b = (GPR (OP[1])) & 0xff; trace_input ("mulb", OP_CONSTANT4, OP_REG, OP_VOID); tmp = (a * b) & 0xff; SET_GPR (OP[1], (tmp | ((GPR (OP[1])) & 0xff00))); trace_output_16 (tmp); } /* mulb. */ void OP_65_8 (void) { int16 tmp; int8 a = (GPR (OP[0])) & 0xff, b = (GPR (OP[1])) & 0xff; trace_input ("mulb", OP_REG, OP_REG, OP_VOID); tmp = (a * b) & 0xff; SET_GPR (OP[1], (tmp | ((GPR (OP[1])) & 0xff00))); trace_output_16 (tmp); } /* mulw. */ void OP_66_8 (void) { int32 tmp; uint16 a = OP[0]; int16 b = (GPR (OP[1])); trace_input ("mulw", OP_CONSTANT4_1, OP_REG, OP_VOID); tmp = (a * b) & 0xffff; SET_GPR (OP[1], tmp); trace_output_32 (tmp); } /* mulw. */ void OP_66B_C (void) { int32 tmp; int16 a = OP[0], b = (GPR (OP[1])); trace_input ("mulw", OP_CONSTANT4, OP_REG, OP_VOID); tmp = (a * b) & 0xffff; SET_GPR (OP[1], tmp); trace_output_32 (tmp); } /* mulw. */ void OP_67_8 (void) { int32 tmp; int16 a = (GPR (OP[0])), b = (GPR (OP[1])); trace_input ("mulw", OP_REG, OP_REG, OP_VOID); tmp = (a * b) & 0xffff; SET_GPR (OP[1], tmp); trace_output_32 (tmp); } /* mulsb. */ void OP_B_8 (void) { int16 tmp; int8 a = (GPR (OP[0])) & 0xff, b = (GPR (OP[1])) & 0xff; trace_input ("mulsb", OP_REG, OP_REG, OP_VOID); tmp = a * b; SET_GPR (OP[1], tmp); trace_output_32 (tmp); } /* mulsw. */ void OP_62_8 (void) { int32 tmp; int16 a = (GPR (OP[0])), b = (GPR (OP[1])); trace_input ("mulsw", OP_REG, OP_REGP, OP_VOID); tmp = a * b; SET_GPR32 (OP[1], tmp); trace_output_32 (tmp); } /* muluw. */ void OP_63_8 (void) { uint32 tmp; uint16 a = (GPR (OP[0])), b = (GPR (OP[1])); trace_input ("muluw", OP_REG, OP_REGP, OP_VOID); tmp = a * b; SET_GPR32 (OP[1], tmp); trace_output_32 (tmp); } /* nop. */ void OP_2C00_10 (void) { trace_input ("nop", OP_VOID, OP_VOID, OP_VOID); #if 0 State.exception = SIGTRAP; 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; } #endif trace_output_void (); } /* orb. */ void OP_24_8 (void) { uint8 tmp, a = (OP[0]) & 0xff, b = (GPR (OP[1])) & 0xff; trace_input ("orb", OP_CONSTANT4, OP_REG, OP_VOID); tmp = a | b; SET_GPR (OP[1], ((GPR (OP[1]) | tmp))); trace_output_16 (tmp); } /* orb. */ void OP_24B_C (void) { uint8 tmp, a = (OP[0]) & 0xff, b = (GPR (OP[1])) & 0xff; trace_input ("orb", OP_CONSTANT16, OP_REG, OP_VOID); tmp = a | b; SET_GPR (OP[1], ((GPR (OP[1]) | tmp))); trace_output_16 (tmp); } /* orb. */ void OP_25_8 (void) { uint8 tmp, a = (GPR (OP[0])) & 0xff, b = (GPR (OP[1])) & 0xff; trace_input ("orb", OP_REG, OP_REG, OP_VOID); tmp = a | b; SET_GPR (OP[1], ((GPR (OP[1]) | tmp))); trace_output_16 (tmp); } /* orw. */ void OP_26_8 (void) { uint16 tmp, a = (OP[0]), b = (GPR (OP[1])); trace_input ("orw", OP_CONSTANT4, OP_REG, OP_VOID); tmp = a | b; SET_GPR (OP[1], tmp); trace_output_16 (tmp); } /* orw. */ void OP_26B_C (void) { uint16 tmp, a = (OP[0]), b = (GPR (OP[1])); trace_input ("orw", OP_CONSTANT16, OP_REG, OP_VOID); tmp = a | b; SET_GPR (OP[1], tmp); trace_output_16 (tmp); } /* orw. */ void OP_27_8 (void) { uint16 tmp, a = (GPR (OP[0])), b = (GPR (OP[1])); trace_input ("orw", OP_REG, OP_REG, OP_VOID); tmp = a | b; SET_GPR (OP[1], tmp); trace_output_16 (tmp); } /* lshb. */ void OP_13_9 (void) { uint16 a = OP[0]; uint16 tmp, b = (GPR (OP[1])) & 0xFF; trace_input ("lshb", OP_CONSTANT4, OP_REG, OP_VOID); /* A positive count specifies a shift to the left; * A negative count specifies a shift to the right. */ if (sign_flag) tmp = b >> a; else tmp = b << a; sign_flag = 0; /* Reset sign_flag. */ SET_GPR (OP[1], ((tmp & 0xFF) | ((GPR (OP[1])) & 0xFF00))); trace_output_16 (tmp); } /* lshb. */ void OP_44_8 (void) { uint16 a = (GPR (OP[0])) & 0xff; uint16 tmp, b = (GPR (OP[1])) & 0xFF; trace_input ("lshb", OP_REG, OP_REG, OP_VOID); if (a & ((long)1 << 3)) { sign_flag = 1; a = ~(a) + 1; } a = (unsigned int) (a & 0x7); /* A positive count specifies a shift to the left; * A negative count specifies a shift to the right. */ if (sign_flag) tmp = b >> a; else tmp = b << a; sign_flag = 0; /* Reset sign_flag. */ SET_GPR (OP[1], ((tmp & 0xFF) | ((GPR (OP[1])) & 0xFF00))); trace_output_16 (tmp); } /* lshw. */ void OP_46_8 (void) { uint16 tmp, b = GPR (OP[1]); int16 a = GPR (OP[0]); trace_input ("lshw", OP_REG, OP_REG, OP_VOID); if (a & ((long)1 << 4)) { sign_flag = 1; a = ~(a) + 1; } a = (unsigned int) (a & 0xf); /* A positive count specifies a shift to the left; * A negative count specifies a shift to the right. */ if (sign_flag) tmp = b >> a; else tmp = b << a; sign_flag = 0; /* Reset sign_flag. */ SET_GPR (OP[1], (tmp & 0xffff)); trace_output_16 (tmp); } /* lshw. */ void OP_49_8 (void) { uint16 tmp, b = GPR (OP[1]); uint16 a = OP[0]; trace_input ("lshw", OP_CONSTANT5, OP_REG, OP_VOID); /* A positive count specifies a shift to the left; * A negative count specifies a shift to the right. */ if (sign_flag) tmp = b >> a; else tmp = b << a; sign_flag = 0; /* Reset sign_flag. */ SET_GPR (OP[1], (tmp & 0xffff)); trace_output_16 (tmp); } /* lshd. */ void OP_25_7 (void) { uint32 tmp, b = GPR32 (OP[1]); uint16 a = OP[0]; trace_input ("lshd", OP_CONSTANT6, OP_REGP, OP_VOID); /* A positive count specifies a shift to the left; * A negative count specifies a shift to the right. */ if (sign_flag) tmp = b >> a; else tmp = b << a; sign_flag = 0; /* Reset sign flag. */ SET_GPR32 (OP[1], tmp); trace_output_32 (tmp); } /* lshd. */ void OP_47_8 (void) { uint32 tmp, b = GPR32 (OP[1]); uint16 a = GPR (OP[0]); trace_input ("lshd", OP_REG, OP_REGP, OP_VOID); if (a & ((long)1 << 5)) { sign_flag = 1; a = ~(a) + 1; } a = (unsigned int) (a & 0x1f); /* A positive count specifies a shift to the left; * A negative count specifies a shift to the right. */ if (sign_flag) tmp = b >> a; else tmp = b << a; sign_flag = 0; /* Reset sign flag. */ SET_GPR32 (OP[1], tmp); trace_output_32 (tmp); } /* ashub. */ void OP_80_9 (void) { uint16 a = OP[0]; int8 tmp, b = (GPR (OP[1])) & 0xFF; trace_input ("ashub", OP_CONSTANT4, OP_REG, OP_VOID); /* A positive count specifies a shift to the left; * A negative count specifies a shift to the right. */ if (sign_flag) tmp = b >> a; else tmp = b << a; sign_flag = 0; /* Reset sign flag. */ SET_GPR (OP[1], ((tmp & 0xFF) | ((GPR (OP[1])) & 0xff00))); trace_output_16 (tmp); } /* ashub. */ void OP_81_9 (void) { uint16 a = OP[0]; int8 tmp, b = (GPR (OP[1])) & 0xFF; trace_input ("ashub", OP_CONSTANT4, OP_REG, OP_VOID); /* A positive count specifies a shift to the left; * A negative count specifies a shift to the right. */ if (sign_flag) tmp = b >> a; else tmp = b << a; sign_flag = 0; /* Reset sign flag. */ SET_GPR (OP[1], ((tmp & 0xFF) | ((GPR (OP[1])) & 0xFF00))); trace_output_16 (tmp); } /* ashub. */ void OP_41_8 (void) { int16 a = (GPR (OP[0])); int8 tmp, b = (GPR (OP[1])) & 0xFF; trace_input ("ashub", OP_REG, OP_REG, OP_VOID); if (a & ((long)1 << 3)) { sign_flag = 1; a = ~(a) + 1; } a = (unsigned int) (a & 0x7); /* A positive count specifies a shift to the left; * A negative count specifies a shift to the right. */ if (sign_flag) tmp = b >> a; else tmp = b << a; sign_flag = 0; /* Reset sign flag. */ SET_GPR (OP[1], ((tmp & 0xFF) | ((GPR (OP[1])) & 0xFF00))); trace_output_16 (tmp); } /* ashuw. */ void OP_42_8 (void) { int16 tmp, b = GPR (OP[1]); uint16 a = OP[0]; trace_input ("ashuw", OP_CONSTANT5, OP_REG, OP_VOID); /* A positive count specifies a shift to the left; * A negative count specifies a shift to the right. */ if (sign_flag) tmp = b >> a; else tmp = b << a; sign_flag = 0; /* Reset sign flag. */ SET_GPR (OP[1], (tmp & 0xffff)); trace_output_16 (tmp); } /* ashuw. */ void OP_43_8 (void) { int16 tmp, b = GPR (OP[1]); uint16 a = OP[0]; trace_input ("ashuw", OP_CONSTANT5, OP_REG, OP_VOID); /* A positive count specifies a shift to the left; * A negative count specifies a shift to the right. */ if (sign_flag) tmp = b >> a; else tmp = b << a; sign_flag = 0; /* Reset sign flag. */ SET_GPR (OP[1], (tmp & 0xffff)); trace_output_16 (tmp); } /* ashuw. */ void OP_45_8 (void) { int16 tmp; int16 a = GPR (OP[0]), b = GPR (OP[1]); trace_input ("ashuw", OP_REG, OP_REG, OP_VOID); if (a & ((long)1 << 4)) { sign_flag = 1; a = ~(a) + 1; } a = (unsigned int) (a & 0xf); /* A positive count specifies a shift to the left; * A negative count specifies a shift to the right. */ if (sign_flag) tmp = b >> a; else tmp = b << a; sign_flag = 0; /* Reset sign flag. */ SET_GPR (OP[1], (tmp & 0xffff)); trace_output_16 (tmp); } /* ashud. */ void OP_26_7 (void) { int32 tmp,b = GPR32 (OP[1]); uint32 a = OP[0]; trace_input ("ashud", OP_CONSTANT6, OP_REGP, OP_VOID); /* A positive count specifies a shift to the left; * A negative count specifies a shift to the right. */ if (sign_flag) tmp = b >> a; else tmp = b << a; sign_flag = 0; /* Reset sign flag. */ SET_GPR32 (OP[1], tmp); trace_output_32 (tmp); } /* ashud. */ void OP_27_7 (void) { int32 tmp; int32 a = OP[0], b = GPR32 (OP[1]); trace_input ("ashud", OP_CONSTANT6, OP_REGP, OP_VOID); /* A positive count specifies a shift to the left; * A negative count specifies a shift to the right. */ if (sign_flag) tmp = b >> a; else tmp = b << a; sign_flag = 0; /* Reset sign flag. */ SET_GPR32 (OP[1], tmp); trace_output_32 (tmp); } /* ashud. */ void OP_48_8 (void) { int32 tmp; int32 a = GPR32 (OP[0]), b = GPR32 (OP[1]); trace_input ("ashud", OP_REGP, OP_REGP, OP_VOID); if (a & ((long)1 << 5)) { sign_flag = 1; a = ~(a) + 1; } a = (unsigned int) (a & 0x1f); /* A positive count specifies a shift to the left; * A negative count specifies a shift to the right. */ if (sign_flag) tmp = b >> a; else tmp = b << a; sign_flag = 0; /* Reset sign flag. */ SET_GPR32 (OP[1], tmp); trace_output_32 (tmp); } /* storm. */ void OP_16_D (void) { uint32 addr = GPR (1); uint16 count = OP[0], reg = 2; trace_input ("storm", OP_CONSTANT4, OP_VOID, OP_VOID); if ((addr & 1)) { State.exception = SIG_CR16_BUS; State.pc_changed = 1; /* Don't increment the PC. */ trace_output_void (); return; } while (count) { SW (addr, (GPR (reg))); addr +=2; --count; reg++; if (reg == 6) reg = 8; }; SET_GPR (1, addr); trace_output_void (); } /* stormp. */ void OP_17_D (void) { uint32 addr = GPR32 (6); uint16 count = OP[0], reg = 2; trace_input ("stormp", OP_CONSTANT4, OP_VOID, OP_VOID); if ((addr & 1)) { State.exception = SIG_CR16_BUS; State.pc_changed = 1; /* Don't increment the PC. */ trace_output_void (); return; } while (count) { SW (addr, (GPR (reg))); addr +=2; --count; reg++; if (reg == 6) reg = 8; }; SET_GPR32 (6, addr); trace_output_void (); } /* subb. */ void OP_38_8 (void) { uint8 a = OP[0]; uint8 b = (GPR (OP[1])) & 0xff; uint16 tmp = (~a + 1 + b) & 0xff; trace_input ("subb", OP_CONSTANT4, OP_REG, OP_VOID); /* see ../common/sim-alu.h for a more extensive discussion on how to compute the carry/overflow bits. */ SET_PSR_C (tmp > 0xff); SET_PSR_F (((a & 0x80) != (b & 0x80)) && ((b & 0x80) != (tmp & 0x80))); SET_GPR (OP[1], (tmp | ((GPR (OP[1])) & 0xff00))); trace_output_16 (tmp); } /* subb. */ void OP_38B_C (void) { uint8 a = OP[0] & 0xFF; uint8 b = (GPR (OP[1])) & 0xFF; uint16 tmp = (~a + 1 + b) & 0xFF; trace_input ("subb", OP_CONSTANT16, OP_REG, OP_VOID); /* see ../common/sim-alu.h for a more extensive discussion on how to compute the carry/overflow bits. */ SET_PSR_C (tmp > 0xff); SET_PSR_F (((a & 0x80) != (b & 0x80)) && ((b & 0x80) != (tmp & 0x80))); SET_GPR (OP[1], (tmp | ((GPR (OP[1])) & 0xff00))); trace_output_16 (tmp); } /* subb. */ void OP_39_8 (void) { uint8 a = (GPR (OP[0])) & 0xFF; uint8 b = (GPR (OP[1])) & 0xFF; uint16 tmp = (~a + 1 + b) & 0xff; trace_input ("subb", OP_REG, OP_REG, OP_VOID); /* see ../common/sim-alu.h for a more extensive discussion on how to compute the carry/overflow bits. */ SET_PSR_C (tmp > 0xff); SET_PSR_F (((a & 0x80) != (b & 0x80)) && ((b & 0x80) != (tmp & 0x80))); SET_GPR (OP[1], (tmp | ((GPR (OP[1])) & 0xff00))); trace_output_16 (tmp); } /* subw. */ void OP_3A_8 (void) { uint16 a = OP[0]; uint16 b = GPR (OP[1]); uint16 tmp = (~a + 1 + b); trace_input ("subw", OP_CONSTANT4, OP_REG, OP_VOID); /* see ../common/sim-alu.h for a more extensive discussion on how to compute the carry/overflow bits. */ SET_PSR_C (tmp > 0xffff); SET_PSR_F (((a & 0x8000) != (b & 0x8000)) && ((b & 0x8000) != (tmp & 0x8000))); SET_GPR (OP[1], tmp); trace_output_16 (tmp); } /* subw. */ void OP_3AB_C (void) { uint16 a = OP[0]; uint16 b = GPR (OP[1]); uint32 tmp = (~a + 1 + b); trace_input ("subw", OP_CONSTANT16, OP_REG, OP_VOID); /* see ../common/sim-alu.h for a more extensive discussion on how to compute the carry/overflow bits. */ SET_PSR_C (tmp > 0xffff); SET_PSR_F (((a & 0x8000) != (b & 0x8000)) && ((b & 0x8000) != (tmp & 0x8000))); SET_GPR (OP[1], tmp & 0xffff); trace_output_16 (tmp); } /* subw. */ void OP_3B_8 (void) { uint16 a = GPR (OP[0]); uint16 b = GPR (OP[1]); uint32 tmp = (~a + 1 + b); trace_input ("subw", OP_REG, OP_REG, OP_VOID); /* see ../common/sim-alu.h for a more extensive discussion on how to compute the carry/overflow bits. */ SET_PSR_C (tmp > 0xffff); SET_PSR_F (((a & 0x8000) != (b & 0x8000)) && ((b & 0x8000) != (tmp & 0x8000))); SET_GPR (OP[1], tmp & 0xffff); trace_output_16 (tmp); } /* subcb. */ void OP_3C_8 (void) { uint8 a = OP[0]; uint8 b = (GPR (OP[1])) & 0xff; //uint16 tmp1 = a + 1; uint16 tmp1 = a + (PSR_C); uint16 tmp = (~tmp1 + 1 + b); trace_input ("subcb", OP_CONSTANT4, OP_REG, OP_VOID); /* see ../common/sim-alu.h for a more extensive discussion on how to compute the carry/overflow bits. */ SET_PSR_C (tmp > 0xff); SET_PSR_F (((a & 0x80) != (b & 0x80)) && ((b & 0x80) != (tmp & 0x80))); SET_GPR (OP[1], tmp); trace_output_16 (tmp); } /* subcb. */ void OP_3CB_C (void) { uint16 a = OP[0]; uint16 b = (GPR (OP[1])) & 0xff; //uint16 tmp1 = a + 1; uint16 tmp1 = a + (PSR_C); uint16 tmp = (~tmp1 + 1 + b); trace_input ("subcb", OP_CONSTANT16, OP_REG, OP_VOID); /* see ../common/sim-alu.h for a more extensive discussion on how to compute the carry/overflow bits. */ SET_PSR_C (tmp > 0xff); SET_PSR_F (((a & 0x80) != (b & 0x80)) && ((b & 0x80) != (tmp & 0x80))); SET_GPR (OP[1], tmp); trace_output_16 (tmp); } /* subcb. */ void OP_3D_8 (void) { uint16 a = (GPR (OP[0])) & 0xff; uint16 b = (GPR (OP[1])) & 0xff; uint16 tmp1 = a + (PSR_C); uint16 tmp = (~tmp1 + 1 + b); trace_input ("subcb", OP_REG, OP_REG, OP_VOID); /* see ../common/sim-alu.h for a more extensive discussion on how to compute the carry/overflow bits. */ SET_PSR_C (tmp > 0xff); SET_PSR_F (((a & 0x80) != (b & 0x80)) && ((b & 0x80) != (tmp & 0x80))); SET_GPR (OP[1], tmp); trace_output_16 (tmp); } /* subcw. */ void OP_3E_8 (void) { uint16 a = OP[0], b = (GPR (OP[1])); uint16 tmp1 = a + (PSR_C); uint16 tmp = (~tmp1 + 1 + b); trace_input ("subcw", OP_CONSTANT4, OP_REG, OP_VOID); /* see ../common/sim-alu.h for a more extensive discussion on how to compute the carry/overflow bits. */ SET_PSR_C (tmp > 0xffff); SET_PSR_F (((a & 0x8000) != (b & 0x8000)) && ((b & 0x8000) != (tmp & 0x8000))); SET_GPR (OP[1], tmp); trace_output_16 (tmp); } /* subcw. */ void OP_3EB_C (void) { int16 a = OP[0]; uint16 b = GPR (OP[1]); uint16 tmp1 = a + (PSR_C); uint16 tmp = (~tmp1 + 1 + b); trace_input ("subcw", OP_CONSTANT16, OP_REG, OP_VOID); /* see ../common/sim-alu.h for a more extensive discussion on how to compute the carry/overflow bits. */ SET_PSR_C (tmp > 0xffff); SET_PSR_F (((a & 0x8000) != (b & 0x8000)) && ((b & 0x8000) != (tmp & 0x8000))); SET_GPR (OP[1], tmp); trace_output_16 (tmp); } /* subcw. */ void OP_3F_8 (void) { uint16 a = (GPR (OP[0])), b = (GPR (OP[1])); uint16 tmp1 = a + (PSR_C); uint16 tmp = (~tmp1 + 1 + b); trace_input ("subcw", OP_REG, OP_REG, OP_VOID); /* see ../common/sim-alu.h for a more extensive discussion on how to compute the carry/overflow bits. */ SET_PSR_C (tmp > 0xffff); SET_PSR_F (((a & 0x8000) != (b & 0x8000)) && ((b & 0x8000) != (tmp & 0x8000))); SET_GPR (OP[1], tmp); trace_output_16 (tmp); } /* subd. */ void OP_3_C (void) { int32 a = OP[0]; uint32 b = GPR32 (OP[1]); uint32 tmp = (~a + 1 + b); trace_input ("subd", OP_CONSTANT32, OP_REGP, OP_VOID); /* see ../common/sim-alu.h for a more extensive discussion on how to compute the carry/overflow bits. */ SET_PSR_C (tmp > 0xffffffff); SET_PSR_F (((a & 0x80000000) != (b & 0x80000000)) && ((b & 0x80000000) != (tmp & 0x80000000))); SET_GPR32 (OP[1], tmp); trace_output_32 (tmp); } /* subd. */ void OP_14C_14 (void) { uint32 a = GPR32 (OP[0]); uint32 b = GPR32 (OP[1]); uint32 tmp = (~a + 1 + b); trace_input ("subd", OP_REGP, OP_REGP, OP_VOID); /* see ../common/sim-alu.h for a more extensive discussion on how to compute the carry/overflow bits. */ SET_PSR_C (tmp > 0xffffffff); SET_PSR_F (((a & 0x80000000) != (b & 0x80000000)) && ((b & 0x80000000) != (tmp & 0x80000000))); SET_GPR32 (OP[1], tmp); trace_output_32 (tmp); } /* excp. */ void OP_C_C (void) { uint32 tmp; uint16 a; trace_input ("excp", OP_CONSTANT4, OP_VOID, OP_VOID); switch (OP[0]) { default: #if (DEBUG & DEBUG_TRAP) == 0 { #if 0 uint16 vec = OP[0] + TRAP_VECTOR_START; SET_BPC (PC + 1); SET_BPSR (PSR); SET_PSR (PSR & PSR_SM_BIT); JMP (vec); break; #endif } #else /* if debugging use trap to print registers */ { int i; static int first_time = 1; if (first_time) { first_time = 0; (*cr16_callback->printf_filtered) (cr16_callback, "Trap # PC "); for (i = 0; i < 16; i++) (*cr16_callback->printf_filtered) (cr16_callback, " %sr%d", (i > 9) ? "" : " ", i); (*cr16_callback->printf_filtered) (cr16_callback, " a0 a1 f0 f1 c\n"); } (*cr16_callback->printf_filtered) (cr16_callback, "Trap %2d 0x%.4x:", (int)OP[0], (int)PC); for (i = 0; i < 16; i++) (*cr16_callback->printf_filtered) (cr16_callback, " %.4x", (int) GPR (i)); for (i = 0; i < 2; i++) (*cr16_callback->printf_filtered) (cr16_callback, " %.2x%.8lx", ((int)(ACC (i) >> 32) & 0xff), ((unsigned long) ACC (i)) & 0xffffffff); (*cr16_callback->printf_filtered) (cr16_callback, " %d %d %d\n", PSR_F != 0, PSR_F != 0, PSR_C != 0); (*cr16_callback->flush_stdout) (cr16_callback); break; } #endif case 8: /* new system call trap */ /* Trap 8 is used for simulating low-level I/O */ { unsigned32 result = 0; errno = 0; /* Registers passed to trap 0. */ #define FUNC GPR (0) /* function number. */ #define PARM1 GPR (2) /* optional parm 1. */ #define PARM2 GPR (3) /* optional parm 2. */ #define PARM3 GPR (4) /* optional parm 3. */ #define PARM4 GPR (5) /* optional parm 4. */ /* Registers set by trap 0 */ #define RETVAL(X) do { result = (0xffff & (X));SET_GPR (0, result);} while (0) #define RETVAL32(X) do { result = (X); SET_GPR32 (0, result);} while (0) #define RETERR(X) SET_GPR (4, (X)) /* 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) #ifdef TARGET_SYS_fork case TARGET_SYS_fork: trace_input ("", OP_VOID, OP_VOID, OP_VOID); RETVAL (fork ()); trace_output_16 (result); break; #endif #define getpid() 47 case TARGET_SYS_getpid: trace_input ("", OP_VOID, OP_VOID, OP_VOID); RETVAL (getpid ()); trace_output_16 (result); break; case TARGET_SYS_kill: trace_input ("", OP_REG, OP_REG, OP_VOID); if (PARM1 == getpid ()) { trace_output_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_void (); (*cr16_callback->printf_filtered) (cr16_callback, "Unknown signal %d\n", PARM2); (*cr16_callback->flush_stdout) (cr16_callback); State.exception = SIGILL; } else { RETVAL (kill (PARM1, PARM2)); trace_output_16 (result); } } break; #ifdef TARGET_SYS_execve case TARGET_SYS_execve: trace_input ("", OP_VOID, OP_VOID, OP_VOID); RETVAL (execve (MEMPTR (PARM1), (char **) MEMPTR (PARM2<<16|PARM3), (char **)MEMPTR (PARM4))); trace_output_16 (result); break; #endif #ifdef TARGET_SYS_execv case TARGET_SYS_execv: trace_input ("", OP_VOID, OP_VOID, OP_VOID); RETVAL (execve (MEMPTR (PARM1), (char **) MEMPTR (PARM2), NULL)); trace_output_16 (result); break; #endif #ifdef TARGET_SYS_pipe case TARGET_SYS_pipe: { reg_t buf; int host_fd[2]; trace_input ("", OP_VOID, OP_VOID, OP_VOID); buf = PARM1; RETVAL (pipe (host_fd)); SW (buf, host_fd[0]); buf += sizeof(uint16); SW (buf, host_fd[1]); trace_output_16 (result); } break; #endif #ifdef TARGET_SYS_wait case TARGET_SYS_wait: { int status; trace_input ("", OP_REG, OP_VOID, OP_VOID); RETVAL (wait (&status)); if (PARM1) SW (PARM1, status); trace_output_16 (result); } break; #endif #else case TARGET_SYS_getpid: trace_input ("", OP_VOID, OP_VOID, OP_VOID); RETVAL (1); trace_output_16 (result); break; case TARGET_SYS_kill: trace_input ("", OP_REG, OP_REG, OP_VOID); trace_output_void (); State.exception = PARM2; break; #endif case TARGET_SYS_read: trace_input ("", OP_REG, OP_MEMREF, OP_REG); RETVAL (cr16_callback->read (cr16_callback, PARM1, MEMPTR (((unsigned long)PARM3 << 16) |((unsigned long)PARM2)), PARM4)); trace_output_16 (result); break; case TARGET_SYS_write: trace_input ("", OP_REG, OP_MEMREF, OP_REG); RETVAL ((int)cr16_callback->write (cr16_callback, PARM1, MEMPTR (((unsigned long)PARM3 << 16) | PARM2), PARM4)); trace_output_16 (result); break; case TARGET_SYS_lseek: trace_input ("", OP_REG, OP_REGP, OP_REG); RETVAL32 (cr16_callback->lseek (cr16_callback, PARM1, ((((long) PARM3) << 16) | PARM2), PARM4)); trace_output_32 (result); break; case TARGET_SYS_close: trace_input ("", OP_REG, OP_VOID, OP_VOID); RETVAL (cr16_callback->close (cr16_callback, PARM1)); trace_output_16 (result); break; case TARGET_SYS_open: trace_input ("", OP_MEMREF, OP_REG, OP_VOID); RETVAL32 (cr16_callback->open (cr16_callback, MEMPTR ((((unsigned long)PARM2)<<16)|PARM1), PARM3)); trace_output_32 (result); break; #ifdef TARGET_SYS_rename case TARGET_SYS_rename: trace_input ("", OP_MEMREF, OP_MEMREF, OP_VOID); RETVAL (cr16_callback->rename (cr16_callback, MEMPTR ((((unsigned long)PARM2)<<16) |PARM1), MEMPTR ((((unsigned long)PARM4)<<16) |PARM3))); trace_output_16 (result); break; #endif case 0x408: /* REVISIT: Added a dummy getenv call. */ trace_input ("", OP_MEMREF, OP_MEMREF, OP_VOID); RETVAL32 (0); trace_output_32 (result); break; case TARGET_SYS_exit: trace_input ("", OP_VOID, OP_VOID, OP_VOID); State.exception = SIG_CR16_EXIT; trace_output_void (); break; case TARGET_SYS_unlink: trace_input ("", OP_MEMREF, OP_VOID, OP_VOID); RETVAL (cr16_callback->unlink (cr16_callback, MEMPTR (((unsigned long)PARM2<<16)|PARM1))); trace_output_16 (result); break; #ifdef TARGET_SYS_stat case TARGET_SYS_stat: trace_input ("", OP_VOID, OP_VOID, OP_VOID); /* stat system call. */ { struct stat host_stat; reg_t buf; RETVAL (stat (MEMPTR ((((unsigned long)PARM2) << 16)|PARM1), &host_stat)); buf = PARM2; /* The hard-coded offsets and sizes were determined by using * the CR16 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_output_16 (result); break; #endif #ifdef TARGET_SYS_chown case TARGET_SYS_chown: trace_input ("", OP_VOID, OP_VOID, OP_VOID); RETVAL (chown (MEMPTR (PARM1), PARM2, PARM3)); trace_output_16 (result); break; #endif case TARGET_SYS_chmod: trace_input ("", OP_VOID, OP_VOID, OP_VOID); RETVAL (chmod (MEMPTR (PARM1), PARM2)); trace_output_16 (result); break; #ifdef TARGET_SYS_utime case TARGET_SYS_utime: trace_input ("", OP_REG, OP_REG, OP_REG); /* Cast the second argument to void *, to avoid type mismatch if a prototype is present. */ RETVAL (utime (MEMPTR (PARM1), (void *) MEMPTR (PARM2))); trace_output_16 (result); break; #endif #ifdef TARGET_SYS_time case TARGET_SYS_time: trace_input ("