URL
https://opencores.org/ocsvn/openrisc/openrisc/trunk
Subversion Repositories openrisc
[/] [openrisc/] [trunk/] [gnu-old/] [gdb-6.8/] [sim/] [arm/] [maverick.c] - Rev 840
Compare with Previous | Blame | View Log
/* maverick.c -- Cirrus/DSP co-processor interface. Copyright (C) 2003, 2007, 2008 Free Software Foundation, Inc. Contributed by Aldy Hernandez (aldyh@redhat.com). This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see <http://www.gnu.org/licenses/>. */ #include <assert.h> #include "armdefs.h" #include "ansidecl.h" #include "armemu.h" /*#define CIRRUS_DEBUG 1 /**/ #if CIRRUS_DEBUG # define printfdbg printf #else # define printfdbg printf_nothing #endif #define POS64(i) ( (~(i)) >> 63 ) #define NEG64(i) ( (i) >> 63 ) /* Define Co-Processor instruction handlers here. */ /* Here's ARMulator's DSP definition. A few things to note: 1) it has 16 64-bit registers and 4 72-bit accumulators 2) you can only access its registers with MCR and MRC. */ /* We can't define these in here because this file might not be linked unless the target is arm9e-*. They are defined in wrapper.c. Eventually the simulator should be made to handle any coprocessor at run time. */ struct maverick_regs { union { int i; float f; } upper; union { int i; float f; } lower; }; union maverick_acc_regs { long double ld; /* Acc registers are 72-bits. */ }; struct maverick_regs DSPregs[16]; union maverick_acc_regs DSPacc[4]; ARMword DSPsc; #define DEST_REG (BITS (12, 15)) #define SRC1_REG (BITS (16, 19)) #define SRC2_REG (BITS (0, 3)) static int lsw_int_index, msw_int_index; static int lsw_float_index, msw_float_index; static double mv_getRegDouble (int); static long long mv_getReg64int (int); static void mv_setRegDouble (int, double val); static void mv_setReg64int (int, long long val); static union { double d; long long ll; int ints[2]; } reg_conv; static void printf_nothing (void * foo, ...) { } static void cirrus_not_implemented (char * insn) { fprintf (stderr, "Cirrus instruction '%s' not implemented.\n", insn); fprintf (stderr, "aborting!\n"); exit (1); } static unsigned DSPInit (ARMul_State * state) { ARMul_ConsolePrint (state, ", DSP present"); return TRUE; } unsigned DSPMRC4 (ARMul_State * state ATTRIBUTE_UNUSED, unsigned type ATTRIBUTE_UNUSED, ARMword instr, ARMword * value) { switch (BITS (5, 7)) { case 0: /* cfmvrdl */ /* Move lower half of a DF stored in a DSP reg into an Arm reg. */ printfdbg ("cfmvrdl\n"); printfdbg ("\tlower half=0x%x\n", DSPregs[SRC1_REG].lower.i); printfdbg ("\tentire thing=%g\n", mv_getRegDouble (SRC1_REG)); *value = (ARMword) DSPregs[SRC1_REG].lower.i; break; case 1: /* cfmvrdh */ /* Move upper half of a DF stored in a DSP reg into an Arm reg. */ printfdbg ("cfmvrdh\n"); printfdbg ("\tupper half=0x%x\n", DSPregs[SRC1_REG].upper.i); printfdbg ("\tentire thing=%g\n", mv_getRegDouble (SRC1_REG)); *value = (ARMword) DSPregs[SRC1_REG].upper.i; break; case 2: /* cfmvrs */ /* Move SF from upper half of a DSP register to an Arm register. */ *value = (ARMword) DSPregs[SRC1_REG].upper.i; printfdbg ("cfmvrs = mvf%d <-- %f\n", SRC1_REG, DSPregs[SRC1_REG].upper.f); break; #ifdef doesnt_work case 4: /* cfcmps */ { float a, b; int n, z, c, v; a = DSPregs[SRC1_REG].upper.f; b = DSPregs[SRC2_REG].upper.f; printfdbg ("cfcmps\n"); printfdbg ("\tcomparing %f and %f\n", a, b); z = a == b; /* zero */ n = a != b; /* negative */ v = a > b; /* overflow */ c = 0; /* carry */ *value = (n << 31) | (z << 30) | (c << 29) | (v << 28); break; } case 5: /* cfcmpd */ { double a, b; int n, z, c, v; a = mv_getRegDouble (SRC1_REG); b = mv_getRegDouble (SRC2_REG); printfdbg ("cfcmpd\n"); printfdbg ("\tcomparing %g and %g\n", a, b); z = a == b; /* zero */ n = a != b; /* negative */ v = a > b; /* overflow */ c = 0; /* carry */ *value = (n << 31) | (z << 30) | (c << 29) | (v << 28); break; } #else case 4: /* cfcmps */ { float a, b; int n, z, c, v; a = DSPregs[SRC1_REG].upper.f; b = DSPregs[SRC2_REG].upper.f; printfdbg ("cfcmps\n"); printfdbg ("\tcomparing %f and %f\n", a, b); z = a == b; /* zero */ n = a < b; /* negative */ c = a > b; /* carry */ v = 0; /* fixme */ printfdbg ("\tz = %d, n = %d\n", z, n); *value = (n << 31) | (z << 30) | (c << 29) | (v << 28); break; } case 5: /* cfcmpd */ { double a, b; int n, z, c, v; a = mv_getRegDouble (SRC1_REG); b = mv_getRegDouble (SRC2_REG); printfdbg ("cfcmpd\n"); printfdbg ("\tcomparing %g and %g\n", a, b); z = a == b; /* zero */ n = a < b; /* negative */ c = a > b; /* carry */ v = 0; /* fixme */ *value = (n << 31) | (z << 30) | (c << 29) | (v << 28); break; } #endif default: fprintf (stderr, "unknown opcode in DSPMRC4 0x%x\n", instr); cirrus_not_implemented ("unknown"); break; } return ARMul_DONE; } unsigned DSPMRC5 (ARMul_State * state ATTRIBUTE_UNUSED, unsigned type ATTRIBUTE_UNUSED, ARMword instr, ARMword * value) { switch (BITS (5, 7)) { case 0: /* cfmvr64l */ /* Move lower half of 64bit int from Cirrus to Arm. */ *value = (ARMword) DSPregs[SRC1_REG].lower.i; printfdbg ("cfmvr64l ARM_REG = mvfx%d <-- %d\n", DEST_REG, (int) *value); break; case 1: /* cfmvr64h */ /* Move upper half of 64bit int from Cirrus to Arm. */ *value = (ARMword) DSPregs[SRC1_REG].upper.i; printfdbg ("cfmvr64h <-- %d\n", (int) *value); break; case 4: /* cfcmp32 */ { int res; int n, z, c, v; unsigned int a, b; printfdbg ("cfcmp32 mvfx%d - mvfx%d\n", SRC1_REG, SRC2_REG); /* FIXME: see comment for cfcmps. */ a = DSPregs[SRC1_REG].lower.i; b = DSPregs[SRC2_REG].lower.i; res = DSPregs[SRC1_REG].lower.i - DSPregs[SRC2_REG].lower.i; /* zero */ z = res == 0; /* negative */ n = res < 0; /* overflow */ v = SubOverflow (DSPregs[SRC1_REG].lower.i, DSPregs[SRC2_REG].lower.i, res); /* carry */ c = (NEG (a) && POS (b) || (NEG (a) && POS (res)) || (POS (b) && POS (res))); *value = (n << 31) | (z << 30) | (c << 29) | (v << 28); break; } case 5: /* cfcmp64 */ { long long res; int n, z, c, v; unsigned long long a, b; printfdbg ("cfcmp64 mvdx%d - mvdx%d\n", SRC1_REG, SRC2_REG); /* fixme: see comment for cfcmps. */ a = mv_getReg64int (SRC1_REG); b = mv_getReg64int (SRC2_REG); res = mv_getReg64int (SRC1_REG) - mv_getReg64int (SRC2_REG); /* zero */ z = res == 0; /* negative */ n = res < 0; /* overflow */ v = ((NEG64 (a) && POS64 (b) && POS64 (res)) || (POS64 (a) && NEG64 (b) && NEG64 (res))); /* carry */ c = (NEG64 (a) && POS64 (b) || (NEG64 (a) && POS64 (res)) || (POS64 (b) && POS64 (res))); *value = (n << 31) | (z << 30) | (c << 29) | (v << 28); break; } default: fprintf (stderr, "unknown opcode in DSPMRC5 0x%x\n", instr); cirrus_not_implemented ("unknown"); break; } return ARMul_DONE; } unsigned DSPMRC6 (ARMul_State * state ATTRIBUTE_UNUSED, unsigned type ATTRIBUTE_UNUSED, ARMword instr, ARMword * value) { switch (BITS (5, 7)) { case 0: /* cfmval32 */ cirrus_not_implemented ("cfmval32"); break; case 1: /* cfmvam32 */ cirrus_not_implemented ("cfmvam32"); break; case 2: /* cfmvah32 */ cirrus_not_implemented ("cfmvah32"); break; case 3: /* cfmva32 */ cirrus_not_implemented ("cfmva32"); break; case 4: /* cfmva64 */ cirrus_not_implemented ("cfmva64"); break; case 5: /* cfmvsc32 */ cirrus_not_implemented ("cfmvsc32"); break; default: fprintf (stderr, "unknown opcode in DSPMRC6 0x%x\n", instr); cirrus_not_implemented ("unknown"); break; } return ARMul_DONE; } unsigned DSPMCR4 (ARMul_State * state, unsigned type ATTRIBUTE_UNUSED, ARMword instr, ARMword value) { switch (BITS (5, 7)) { case 0: /* cfmvdlr */ /* Move the lower half of a DF value from an Arm register into the lower half of a Cirrus register. */ printfdbg ("cfmvdlr <-- 0x%x\n", (int) value); DSPregs[SRC1_REG].lower.i = (int) value; break; case 1: /* cfmvdhr */ /* Move the upper half of a DF value from an Arm register into the upper half of a Cirrus register. */ printfdbg ("cfmvdhr <-- 0x%x\n", (int) value); DSPregs[SRC1_REG].upper.i = (int) value; break; case 2: /* cfmvsr */ /* Move SF from Arm register into upper half of Cirrus register. */ printfdbg ("cfmvsr <-- 0x%x\n", (int) value); DSPregs[SRC1_REG].upper.i = (int) value; break; default: fprintf (stderr, "unknown opcode in DSPMCR4 0x%x\n", instr); cirrus_not_implemented ("unknown"); break; } return ARMul_DONE; } unsigned DSPMCR5 (ARMul_State * state, unsigned type ATTRIBUTE_UNUSED, ARMword instr, ARMword value) { union { int s; unsigned int us; } val; switch (BITS (5, 7)) { case 0: /* cfmv64lr */ /* Move lower half of a 64bit int from an ARM register into the lower half of a DSP register and sign extend it. */ printfdbg ("cfmv64lr mvdx%d <-- 0x%x\n", SRC1_REG, (int) value); DSPregs[SRC1_REG].lower.i = (int) value; break; case 1: /* cfmv64hr */ /* Move upper half of a 64bit int from an ARM register into the upper half of a DSP register. */ printfdbg ("cfmv64hr ARM_REG = mvfx%d <-- 0x%x\n", SRC1_REG, (int) value); DSPregs[SRC1_REG].upper.i = (int) value; break; case 2: /* cfrshl32 */ printfdbg ("cfrshl32\n"); val.us = value; if (val.s > 0) DSPregs[SRC2_REG].lower.i = DSPregs[SRC1_REG].lower.i << value; else DSPregs[SRC2_REG].lower.i = DSPregs[SRC1_REG].lower.i >> -value; break; case 3: /* cfrshl64 */ printfdbg ("cfrshl64\n"); val.us = value; if (val.s > 0) mv_setReg64int (SRC2_REG, mv_getReg64int (SRC1_REG) << value); else mv_setReg64int (SRC2_REG, mv_getReg64int (SRC1_REG) >> -value); break; default: fprintf (stderr, "unknown opcode in DSPMCR5 0x%x\n", instr); cirrus_not_implemented ("unknown"); break; } return ARMul_DONE; } unsigned DSPMCR6 (ARMul_State * state, unsigned type ATTRIBUTE_UNUSED, ARMword instr, ARMword value) { switch (BITS (5, 7)) { case 0: /* cfmv32al */ cirrus_not_implemented ("cfmv32al"); break; case 1: /* cfmv32am */ cirrus_not_implemented ("cfmv32am"); break; case 2: /* cfmv32ah */ cirrus_not_implemented ("cfmv32ah"); break; case 3: /* cfmv32a */ cirrus_not_implemented ("cfmv32a"); break; case 4: /* cfmv64a */ cirrus_not_implemented ("cfmv64a"); break; case 5: /* cfmv32sc */ cirrus_not_implemented ("cfmv32sc"); break; default: fprintf (stderr, "unknown opcode in DSPMCR6 0x%x\n", instr); cirrus_not_implemented ("unknown"); break; } return ARMul_DONE; } unsigned DSPLDC4 (ARMul_State * state ATTRIBUTE_UNUSED, unsigned type, ARMword instr, ARMword data) { static unsigned words; if (type != ARMul_DATA) { words = 0; return ARMul_DONE; } if (BIT (22)) { /* it's a long access, get two words */ /* cfldrd */ printfdbg ("cfldrd: %x (words = %d) (bigend = %d) DESTREG = %d\n", data, words, state->bigendSig, DEST_REG); if (words == 0) { if (state->bigendSig) DSPregs[DEST_REG].upper.i = (int) data; else DSPregs[DEST_REG].lower.i = (int) data; } else { if (state->bigendSig) DSPregs[DEST_REG].lower.i = (int) data; else DSPregs[DEST_REG].upper.i = (int) data; } ++ words; if (words == 2) { printfdbg ("\tmvd%d <-- mem = %g\n", DEST_REG, mv_getRegDouble (DEST_REG)); return ARMul_DONE; } else return ARMul_INC; } else { /* Get just one word. */ /* cfldrs */ printfdbg ("cfldrs\n"); DSPregs[DEST_REG].upper.i = (int) data; printfdbg ("\tmvf%d <-- mem = %f\n", DEST_REG, DSPregs[DEST_REG].upper.f); return ARMul_DONE; } } unsigned DSPLDC5 (ARMul_State * state ATTRIBUTE_UNUSED, unsigned type, ARMword instr, ARMword data) { static unsigned words; if (type != ARMul_DATA) { words = 0; return ARMul_DONE; } if (BIT (22)) { /* It's a long access, get two words. */ /* cfldr64 */ printfdbg ("cfldr64: %d\n", data); if (words == 0) { if (state->bigendSig) DSPregs[DEST_REG].upper.i = (int) data; else DSPregs[DEST_REG].lower.i = (int) data; } else { if (state->bigendSig) DSPregs[DEST_REG].lower.i = (int) data; else DSPregs[DEST_REG].upper.i = (int) data; } ++ words; if (words == 2) { printfdbg ("\tmvdx%d <-- mem = %lld\n", DEST_REG, mv_getReg64int (DEST_REG)); return ARMul_DONE; } else return ARMul_INC; } else { /* Get just one word. */ /* cfldr32 */ printfdbg ("cfldr32 mvfx%d <-- %d\n", DEST_REG, (int) data); /* 32bit ints should be sign extended to 64bits when loaded. */ mv_setReg64int (DEST_REG, (long long) data); return ARMul_DONE; } } unsigned DSPSTC4 (ARMul_State * state ATTRIBUTE_UNUSED, unsigned type, ARMword instr, ARMword * data) { static unsigned words; if (type != ARMul_DATA) { words = 0; return ARMul_DONE; } if (BIT (22)) { /* It's a long access, get two words. */ /* cfstrd */ printfdbg ("cfstrd\n"); if (words == 0) { if (state->bigendSig) *data = (ARMword) DSPregs[DEST_REG].upper.i; else *data = (ARMword) DSPregs[DEST_REG].lower.i; } else { if (state->bigendSig) *data = (ARMword) DSPregs[DEST_REG].lower.i; else *data = (ARMword) DSPregs[DEST_REG].upper.i; } ++ words; if (words == 2) { printfdbg ("\tmem = mvd%d = %g\n", DEST_REG, mv_getRegDouble (DEST_REG)); return ARMul_DONE; } else return ARMul_INC; } else { /* Get just one word. */ /* cfstrs */ printfdbg ("cfstrs mvf%d <-- %f\n", DEST_REG, DSPregs[DEST_REG].upper.f); *data = (ARMword) DSPregs[DEST_REG].upper.i; return ARMul_DONE; } } unsigned DSPSTC5 (ARMul_State * state ATTRIBUTE_UNUSED, unsigned type, ARMword instr, ARMword * data) { static unsigned words; if (type != ARMul_DATA) { words = 0; return ARMul_DONE; } if (BIT (22)) { /* It's a long access, store two words. */ /* cfstr64 */ printfdbg ("cfstr64\n"); if (words == 0) { if (state->bigendSig) *data = (ARMword) DSPregs[DEST_REG].upper.i; else *data = (ARMword) DSPregs[DEST_REG].lower.i; } else { if (state->bigendSig) *data = (ARMword) DSPregs[DEST_REG].lower.i; else *data = (ARMword) DSPregs[DEST_REG].upper.i; } ++ words; if (words == 2) { printfdbg ("\tmem = mvd%d = %lld\n", DEST_REG, mv_getReg64int (DEST_REG)); return ARMul_DONE; } else return ARMul_INC; } else { /* Store just one word. */ /* cfstr32 */ *data = (ARMword) DSPregs[DEST_REG].lower.i; printfdbg ("cfstr32 MEM = %d\n", (int) *data); return ARMul_DONE; } } unsigned DSPCDP4 (ARMul_State * state, unsigned type, ARMword instr) { int opcode2; opcode2 = BITS (5,7); switch (BITS (20,21)) { case 0: switch (opcode2) { case 0: /* cfcpys */ printfdbg ("cfcpys mvf%d = mvf%d = %f\n", DEST_REG, SRC1_REG, DSPregs[SRC1_REG].upper.f); DSPregs[DEST_REG].upper.f = DSPregs[SRC1_REG].upper.f; break; case 1: /* cfcpyd */ printfdbg ("cfcpyd mvd%d = mvd%d = %g\n", DEST_REG, SRC1_REG, mv_getRegDouble (SRC1_REG)); mv_setRegDouble (DEST_REG, mv_getRegDouble (SRC1_REG)); break; case 2: /* cfcvtds */ printfdbg ("cfcvtds mvf%d = (float) mvd%d = %f\n", DEST_REG, SRC1_REG, (float) mv_getRegDouble (SRC1_REG)); DSPregs[DEST_REG].upper.f = (float) mv_getRegDouble (SRC1_REG); break; case 3: /* cfcvtsd */ printfdbg ("cfcvtsd mvd%d = mvf%d = %g\n", DEST_REG, SRC1_REG, (double) DSPregs[SRC1_REG].upper.f); mv_setRegDouble (DEST_REG, (double) DSPregs[SRC1_REG].upper.f); break; case 4: /* cfcvt32s */ printfdbg ("cfcvt32s mvf%d = mvfx%d = %f\n", DEST_REG, SRC1_REG, (float) DSPregs[SRC1_REG].lower.i); DSPregs[DEST_REG].upper.f = (float) DSPregs[SRC1_REG].lower.i; break; case 5: /* cfcvt32d */ printfdbg ("cfcvt32d mvd%d = mvfx%d = %g\n", DEST_REG, SRC1_REG, (double) DSPregs[SRC1_REG].lower.i); mv_setRegDouble (DEST_REG, (double) DSPregs[SRC1_REG].lower.i); break; case 6: /* cfcvt64s */ printfdbg ("cfcvt64s mvf%d = mvdx%d = %f\n", DEST_REG, SRC1_REG, (float) mv_getReg64int (SRC1_REG)); DSPregs[DEST_REG].upper.f = (float) mv_getReg64int (SRC1_REG); break; case 7: /* cfcvt64d */ printfdbg ("cfcvt64d mvd%d = mvdx%d = %g\n", DEST_REG, SRC1_REG, (double) mv_getReg64int (SRC1_REG)); mv_setRegDouble (DEST_REG, (double) mv_getReg64int (SRC1_REG)); break; } break; case 1: switch (opcode2) { case 0: /* cfmuls */ printfdbg ("cfmuls mvf%d = mvf%d = %f\n", DEST_REG, SRC1_REG, DSPregs[SRC1_REG].upper.f * DSPregs[SRC2_REG].upper.f); DSPregs[DEST_REG].upper.f = DSPregs[SRC1_REG].upper.f * DSPregs[SRC2_REG].upper.f; break; case 1: /* cfmuld */ printfdbg ("cfmuld mvd%d = mvd%d = %g\n", DEST_REG, SRC1_REG, mv_getRegDouble (SRC1_REG) * mv_getRegDouble (SRC2_REG)); mv_setRegDouble (DEST_REG, mv_getRegDouble (SRC1_REG) * mv_getRegDouble (SRC2_REG)); break; default: fprintf (stderr, "unknown opcode in DSPCDP4 0x%x\n", instr); cirrus_not_implemented ("unknown"); break; } break; case 3: switch (opcode2) { case 0: /* cfabss */ DSPregs[DEST_REG].upper.f = (DSPregs[SRC1_REG].upper.f < 0.0F ? -DSPregs[SRC1_REG].upper.f : DSPregs[SRC1_REG].upper.f); printfdbg ("cfabss mvf%d = |mvf%d| = %f\n", DEST_REG, SRC1_REG, DSPregs[DEST_REG].upper.f); break; case 1: /* cfabsd */ mv_setRegDouble (DEST_REG, (mv_getRegDouble (SRC1_REG) < 0.0 ? -mv_getRegDouble (SRC1_REG) : mv_getRegDouble (SRC1_REG))); printfdbg ("cfabsd mvd%d = |mvd%d| = %g\n", DEST_REG, SRC1_REG, mv_getRegDouble (DEST_REG)); break; case 2: /* cfnegs */ DSPregs[DEST_REG].upper.f = -DSPregs[SRC1_REG].upper.f; printfdbg ("cfnegs mvf%d = -mvf%d = %f\n", DEST_REG, SRC1_REG, DSPregs[DEST_REG].upper.f); break; case 3: /* cfnegd */ mv_setRegDouble (DEST_REG, -mv_getRegDouble (SRC1_REG)); printfdbg ("cfnegd mvd%d = -mvd%d = %g\n", DEST_REG, mv_getRegDouble (DEST_REG)); break; case 4: /* cfadds */ DSPregs[DEST_REG].upper.f = DSPregs[SRC1_REG].upper.f + DSPregs[SRC2_REG].upper.f; printfdbg ("cfadds mvf%d = mvf%d + mvf%d = %f\n", DEST_REG, SRC1_REG, SRC2_REG, DSPregs[DEST_REG].upper.f); break; case 5: /* cfaddd */ mv_setRegDouble (DEST_REG, mv_getRegDouble (SRC1_REG) + mv_getRegDouble (SRC2_REG)); printfdbg ("cfaddd: mvd%d = mvd%d + mvd%d = %g\n", DEST_REG, SRC1_REG, SRC2_REG, mv_getRegDouble (DEST_REG)); break; case 6: /* cfsubs */ DSPregs[DEST_REG].upper.f = DSPregs[SRC1_REG].upper.f - DSPregs[SRC2_REG].upper.f; printfdbg ("cfsubs: mvf%d = mvf%d - mvf%d = %f\n", DEST_REG, SRC1_REG, SRC2_REG, DSPregs[DEST_REG].upper.f); break; case 7: /* cfsubd */ mv_setRegDouble (DEST_REG, mv_getRegDouble (SRC1_REG) - mv_getRegDouble (SRC2_REG)); printfdbg ("cfsubd: mvd%d = mvd%d - mvd%d = %g\n", DEST_REG, SRC1_REG, SRC2_REG, mv_getRegDouble (DEST_REG)); break; } break; default: fprintf (stderr, "unknown opcode in DSPCDP4 0x%x\n", instr); cirrus_not_implemented ("unknown"); break; } return ARMul_DONE; } unsigned DSPCDP5 (ARMul_State * state, unsigned type, ARMword instr) { int opcode2; char shift; opcode2 = BITS (5,7); /* Shift constants are 7bit signed numbers in bits 0..3|5..7. */ shift = BITS (0, 3) | (BITS (5, 7)) << 4; if (shift & 0x40) shift |= 0xc0; switch (BITS (20,21)) { case 0: /* cfsh32 */ printfdbg ("cfsh32 %s amount=%d\n", shift < 0 ? "right" : "left", shift); if (shift < 0) /* Negative shift is a right shift. */ DSPregs[DEST_REG].lower.i = DSPregs[SRC1_REG].lower.i >> -shift; else /* Positive shift is a left shift. */ DSPregs[DEST_REG].lower.i = DSPregs[SRC1_REG].lower.i << shift; break; case 1: switch (opcode2) { case 0: /* cfmul32 */ DSPregs[DEST_REG].lower.i = DSPregs[SRC1_REG].lower.i * DSPregs[SRC2_REG].lower.i; printfdbg ("cfmul32 mvfx%d = mvfx%d * mvfx%d = %d\n", DEST_REG, SRC1_REG, SRC2_REG, DSPregs[DEST_REG].lower.i); break; case 1: /* cfmul64 */ mv_setReg64int (DEST_REG, mv_getReg64int (SRC1_REG) * mv_getReg64int (SRC2_REG)); printfdbg ("cfmul64 mvdx%d = mvdx%d * mvdx%d = %lld\n", DEST_REG, SRC1_REG, SRC2_REG, mv_getReg64int (DEST_REG)); break; case 2: /* cfmac32 */ DSPregs[DEST_REG].lower.i += DSPregs[SRC1_REG].lower.i * DSPregs[SRC2_REG].lower.i; printfdbg ("cfmac32 mvfx%d += mvfx%d * mvfx%d = %d\n", DEST_REG, SRC1_REG, SRC2_REG, DSPregs[DEST_REG].lower.i); break; case 3: /* cfmsc32 */ DSPregs[DEST_REG].lower.i -= DSPregs[SRC1_REG].lower.i * DSPregs[SRC2_REG].lower.i; printfdbg ("cfmsc32 mvfx%d -= mvfx%d * mvfx%d = %d\n", DEST_REG, SRC1_REG, SRC2_REG, DSPregs[DEST_REG].lower.i); break; case 4: /* cfcvts32 */ /* fixme: this should round */ DSPregs[DEST_REG].lower.i = (int) DSPregs[SRC1_REG].upper.f; printfdbg ("cfcvts32 mvfx%d = mvf%d = %d\n", DEST_REG, SRC1_REG, DSPregs[DEST_REG].lower.i); break; case 5: /* cfcvtd32 */ /* fixme: this should round */ DSPregs[DEST_REG].lower.i = (int) mv_getRegDouble (SRC1_REG); printfdbg ("cfcvtd32 mvdx%d = mvd%d = %d\n", DEST_REG, SRC1_REG, DSPregs[DEST_REG].lower.i); break; case 6: /* cftruncs32 */ DSPregs[DEST_REG].lower.i = (int) DSPregs[SRC1_REG].upper.f; printfdbg ("cftruncs32 mvfx%d = mvf%d = %d\n", DEST_REG, SRC1_REG, DSPregs[DEST_REG].lower.i); break; case 7: /* cftruncd32 */ DSPregs[DEST_REG].lower.i = (int) mv_getRegDouble (SRC1_REG); printfdbg ("cftruncd32 mvfx%d = mvd%d = %d\n", DEST_REG, SRC1_REG, DSPregs[DEST_REG].lower.i); break; } break; case 2: /* cfsh64 */ printfdbg ("cfsh64\n"); if (shift < 0) /* Negative shift is a right shift. */ mv_setReg64int (DEST_REG, mv_getReg64int (SRC1_REG) >> -shift); else /* Positive shift is a left shift. */ mv_setReg64int (DEST_REG, mv_getReg64int (SRC1_REG) << shift); printfdbg ("\t%llx\n", mv_getReg64int(DEST_REG)); break; case 3: switch (opcode2) { case 0: /* cfabs32 */ DSPregs[DEST_REG].lower.i = (DSPregs[SRC1_REG].lower.i < 0 ? -DSPregs[SRC1_REG].lower.i : DSPregs[SRC1_REG].lower.i); printfdbg ("cfabs32 mvfx%d = |mvfx%d| = %d\n", DEST_REG, SRC1_REG, SRC2_REG, DSPregs[DEST_REG].lower.i); break; case 1: /* cfabs64 */ mv_setReg64int (DEST_REG, (mv_getReg64int (SRC1_REG) < 0 ? -mv_getReg64int (SRC1_REG) : mv_getReg64int (SRC1_REG))); printfdbg ("cfabs64 mvdx%d = |mvdx%d| = %lld\n", DEST_REG, SRC1_REG, SRC2_REG, mv_getReg64int (DEST_REG)); break; case 2: /* cfneg32 */ DSPregs[DEST_REG].lower.i = -DSPregs[SRC1_REG].lower.i; printfdbg ("cfneg32 mvfx%d = -mvfx%d = %d\n", DEST_REG, SRC1_REG, SRC2_REG, DSPregs[DEST_REG].lower.i); break; case 3: /* cfneg64 */ mv_setReg64int (DEST_REG, -mv_getReg64int (SRC1_REG)); printfdbg ("cfneg64 mvdx%d = -mvdx%d = %lld\n", DEST_REG, SRC1_REG, SRC2_REG, mv_getReg64int (DEST_REG)); break; case 4: /* cfadd32 */ DSPregs[DEST_REG].lower.i = DSPregs[SRC1_REG].lower.i + DSPregs[SRC2_REG].lower.i; printfdbg ("cfadd32 mvfx%d = mvfx%d + mvfx%d = %d\n", DEST_REG, SRC1_REG, SRC2_REG, DSPregs[DEST_REG].lower.i); break; case 5: /* cfadd64 */ mv_setReg64int (DEST_REG, mv_getReg64int (SRC1_REG) + mv_getReg64int (SRC2_REG)); printfdbg ("cfadd64 mvdx%d = mvdx%d + mvdx%d = %lld\n", DEST_REG, SRC1_REG, SRC2_REG, mv_getReg64int (DEST_REG)); break; case 6: /* cfsub32 */ DSPregs[DEST_REG].lower.i = DSPregs[SRC1_REG].lower.i - DSPregs[SRC2_REG].lower.i; printfdbg ("cfsub32 mvfx%d = mvfx%d - mvfx%d = %d\n", DEST_REG, SRC1_REG, SRC2_REG, DSPregs[DEST_REG].lower.i); break; case 7: /* cfsub64 */ mv_setReg64int (DEST_REG, mv_getReg64int (SRC1_REG) - mv_getReg64int (SRC2_REG)); printfdbg ("cfsub64 mvdx%d = mvdx%d - mvdx%d = %d\n", DEST_REG, SRC1_REG, SRC2_REG, mv_getReg64int (DEST_REG)); break; } break; default: fprintf (stderr, "unknown opcode in DSPCDP5 0x%x\n", instr); cirrus_not_implemented ("unknown"); break; } return ARMul_DONE; } unsigned DSPCDP6 (ARMul_State * state, unsigned type, ARMword instr) { int opcode2; opcode2 = BITS (5,7); switch (BITS (20,21)) { case 0: /* cfmadd32 */ cirrus_not_implemented ("cfmadd32"); break; case 1: /* cfmsub32 */ cirrus_not_implemented ("cfmsub32"); break; case 2: /* cfmadda32 */ cirrus_not_implemented ("cfmadda32"); break; case 3: /* cfmsuba32 */ cirrus_not_implemented ("cfmsuba32"); break; default: fprintf (stderr, "unknown opcode in DSPCDP6 0x%x\n", instr); } return ARMul_DONE; } /* Conversion functions. 32-bit integers are stored in the LOWER half of a 64-bit physical register. Single precision floats are stored in the UPPER half of a 64-bit physical register. */ static double mv_getRegDouble (int regnum) { reg_conv.ints[lsw_float_index] = DSPregs[regnum].upper.i; reg_conv.ints[msw_float_index] = DSPregs[regnum].lower.i; return reg_conv.d; } static void mv_setRegDouble (int regnum, double val) { reg_conv.d = val; DSPregs[regnum].upper.i = reg_conv.ints[lsw_float_index]; DSPregs[regnum].lower.i = reg_conv.ints[msw_float_index]; } static long long mv_getReg64int (int regnum) { reg_conv.ints[lsw_int_index] = DSPregs[regnum].lower.i; reg_conv.ints[msw_int_index] = DSPregs[regnum].upper.i; return reg_conv.ll; } static void mv_setReg64int (int regnum, long long val) { reg_conv.ll = val; DSPregs[regnum].lower.i = reg_conv.ints[lsw_int_index]; DSPregs[regnum].upper.i = reg_conv.ints[msw_int_index]; } /* Compute LSW in a double and a long long. */ void mv_compute_host_endianness (ARMul_State * state) { static union { long long ll; long ints[2]; long i; double d; float floats[2]; float f; } conv; /* Calculate where's the LSW in a 64bit int. */ conv.ll = 45; if (conv.ints[0] == 0) { msw_int_index = 0; lsw_int_index = 1; } else { assert (conv.ints[1] == 0); msw_int_index = 1; lsw_int_index = 0; } /* Calculate where's the LSW in a double. */ conv.d = 3.0; if (conv.ints[0] == 0) { msw_float_index = 0; lsw_float_index = 1; } else { assert (conv.ints[1] == 0); msw_float_index = 1; lsw_float_index = 0; } printfdbg ("lsw_int_index %d\n", lsw_int_index); printfdbg ("lsw_float_index %d\n", lsw_float_index); }