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/* fpu.c --- FPU emulator for stand-alone RX simulator. Copyright (C) 2008, 2009, 2010 Free Software Foundation, Inc. Contributed by Red Hat, Inc. This file is part of the GNU simulators. 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 <stdio.h> #include <stdlib.h> #include "cpu.h" #include "fpu.h" /* FPU encodings are as follows: S EXPONENT MANTISSA 1 12345678 12345678901234567890123 0 00000000 00000000000000000000000 +0 1 00000000 00000000000000000000000 -0 X 00000000 00000000000000000000001 Denormals X 00000000 11111111111111111111111 X 00000001 XXXXXXXXXXXXXXXXXXXXXXX Normals X 11111110 XXXXXXXXXXXXXXXXXXXXXXX 0 11111111 00000000000000000000000 +Inf 1 11111111 00000000000000000000000 -Inf X 11111111 0XXXXXXXXXXXXXXXXXXXXXX SNaN (X != 0) X 11111111 1XXXXXXXXXXXXXXXXXXXXXX QNaN (X != 0) */ #define trace 0 #define tprintf if (trace) printf /* Some magic numbers. */ #define PLUS_MAX 0x7f7fffffUL #define MINUS_MAX 0xff7fffffUL #define PLUS_INF 0x7f800000UL #define MINUS_INF 0xff800000UL #define PLUS_ZERO 0x00000000UL #define MINUS_ZERO 0x80000000UL #define FP_RAISE(e) fp_raise(FPSWBITS_C##e) static void fp_raise (int mask) { regs.r_fpsw |= mask; if (mask != FPSWBITS_CE) { if (regs.r_fpsw & (mask << FPSW_CESH)) regs.r_fpsw |= (mask << FPSW_CFSH); if (regs.r_fpsw & FPSWBITS_FMASK) regs.r_fpsw |= FPSWBITS_FSUM; else regs.r_fpsw &= ~FPSWBITS_FSUM; } } /* We classify all numbers as one of these. They correspond to the rows/colums in the exception tables. */ typedef enum { FP_NORMAL, FP_PZERO, FP_NZERO, FP_PINFINITY, FP_NINFINITY, FP_DENORMAL, FP_QNAN, FP_SNAN } FP_Type; #if defined DEBUG0 static const char *fpt_names[] = { "Normal", "+0", "-0", "+Inf", "-Inf", "Denormal", "QNaN", "SNaN" }; #endif #define EXP_BIAS 127 #define EXP_ZERO -127 #define EXP_INF 128 #define MANT_BIAS 0x00080000UL typedef struct { int exp; unsigned int mant; /* 24 bits */ char type; char sign; fp_t orig_value; } FP_Parts; static void fp_explode (fp_t f, FP_Parts *p) { int exp, mant, sign; exp = ((f & 0x7f800000UL) >> 23); mant = f & 0x007fffffUL; sign = f & 0x80000000UL; /*printf("explode: %08x %x %2x %6x\n", f, sign, exp, mant);*/ p->sign = sign ? -1 : 1; p->exp = exp - EXP_BIAS; p->orig_value = f; p->mant = mant | 0x00800000UL; if (p->exp == EXP_ZERO) { if (regs.r_fpsw & FPSWBITS_DN) mant = 0; if (mant) p->type = FP_DENORMAL; else { p->mant = 0; p->type = sign ? FP_NZERO : FP_PZERO; } } else if (p->exp == EXP_INF) { if (mant == 0) p->type = sign ? FP_NINFINITY : FP_PINFINITY; else if (mant & 0x00400000UL) p->type = FP_QNAN; else p->type = FP_SNAN; } else p->type = FP_NORMAL; } static fp_t fp_implode (FP_Parts *p) { int exp, mant; exp = p->exp + EXP_BIAS; mant = p->mant; /*printf("implode: exp %d mant 0x%x\n", exp, mant);*/ if (p->type == FP_NORMAL) { while (mant && exp > 0 && mant < 0x00800000UL) { mant <<= 1; exp --; } while (mant > 0x00ffffffUL) { mant >>= 1; exp ++; } if (exp < 0) { /* underflow */ exp = 0; mant = 0; FP_RAISE (E); } if (exp >= 255) { /* overflow */ exp = 255; mant = 0; FP_RAISE (O); } } mant &= 0x007fffffUL; exp &= 0xff; mant |= exp << 23; if (p->sign < 0) mant |= 0x80000000UL; return mant; } typedef union { unsigned long long ll; double d; } U_d_ll; static int checked_format = 0; /* We assume a double format like this: S[1] E[11] M[52] */ static double fp_to_double (FP_Parts *p) { U_d_ll u; if (!checked_format) { u.d = 1.5; if (u.ll != 0x3ff8000000000000ULL) abort (); u.d = -225; if (u.ll != 0xc06c200000000000ULL) abort (); u.d = 10.1; if (u.ll != 0x4024333333333333ULL) abort (); checked_format = 1; } u.ll = 0; if (p->sign < 0) u.ll |= (1ULL << 63); /* Make sure a zero encoding stays a zero. */ if (p->exp != -EXP_BIAS) u.ll |= ((unsigned long long)p->exp + 1023ULL) << 52; u.ll |= (unsigned long long) (p->mant & 0x007fffffUL) << (52 - 23); return u.d; } static void double_to_fp (double d, FP_Parts *p) { int exp; U_d_ll u; int sign; u.d = d; sign = (u.ll & 0x8000000000000000ULL) ? 1 : 0; exp = u.ll >> 52; exp = (exp & 0x7ff); if (exp == 0) { /* A generated denormal should show up as an underflow, not here. */ if (sign) fp_explode (MINUS_ZERO, p); else fp_explode (PLUS_ZERO, p); return; } exp = exp - 1023; if ((exp + EXP_BIAS) > 254) { FP_RAISE (O); switch (regs.r_fpsw & FPSWBITS_RM) { case FPRM_NEAREST: if (sign) fp_explode (MINUS_INF, p); else fp_explode (PLUS_INF, p); break; case FPRM_ZERO: if (sign) fp_explode (MINUS_MAX, p); else fp_explode (PLUS_MAX, p); break; case FPRM_PINF: if (sign) fp_explode (MINUS_MAX, p); else fp_explode (PLUS_INF, p); break; case FPRM_NINF: if (sign) fp_explode (MINUS_INF, p); else fp_explode (PLUS_MAX, p); break; } return; } if ((exp + EXP_BIAS) < 1) { if (sign) fp_explode (MINUS_ZERO, p); else fp_explode (PLUS_ZERO, p); FP_RAISE (U); } p->sign = sign ? -1 : 1; p->exp = exp; p->mant = u.ll >> (52-23) & 0x007fffffUL; p->mant |= 0x00800000UL; p->type = FP_NORMAL; if (u.ll & 0x1fffffffULL) { switch (regs.r_fpsw & FPSWBITS_RM) { case FPRM_NEAREST: if (u.ll & 0x10000000ULL) p->mant ++; break; case FPRM_ZERO: break; case FPRM_PINF: if (sign == 1) p->mant ++; break; case FPRM_NINF: if (sign == -1) p->mant ++; break; } FP_RAISE (X); } } typedef enum { eNR, /* Use the normal result. */ ePZ, eNZ, /* +- zero */ eSZ, /* signed zero - XOR signs of ops together. */ eRZ, /* +- zero depending on rounding mode. */ ePI, eNI, /* +- Infinity */ eSI, /* signed infinity - XOR signs of ops together. */ eQN, eSN, /* Quiet/Signalling NANs */ eIn, /* Invalid. */ eUn, /* Unimplemented. */ eDZ, /* Divide-by-zero. */ eLT, /* less than */ eGT, /* greater than */ eEQ, /* equal to */ } FP_ExceptionCases; #if defined DEBUG0 static const char *ex_names[] = { "NR", "PZ", "NZ", "SZ", "RZ", "PI", "NI", "SI", "QN", "SN", "IN", "Un", "DZ", "LT", "GT", "EQ" }; #endif /* This checks for all exceptional cases (not all FP exceptions) and returns TRUE if it is providing the result in *c. If it returns FALSE, the caller should do the "normal" operation. */ int check_exceptions (FP_Parts *a, FP_Parts *b, fp_t *c, FP_ExceptionCases ex_tab[5][5], FP_ExceptionCases *case_ret) { FP_ExceptionCases fpec; if (a->type == FP_SNAN || b->type == FP_SNAN) fpec = eIn; else if (a->type == FP_QNAN || b->type == FP_QNAN) fpec = eQN; else if (a->type == FP_DENORMAL || b->type == FP_DENORMAL) fpec = eUn; else fpec = ex_tab[(int)(a->type)][(int)(b->type)]; /*printf("%s %s -> %s\n", fpt_names[(int)(a->type)], fpt_names[(int)(b->type)], ex_names[(int)(fpec)]);*/ if (case_ret) *case_ret = fpec; switch (fpec) { case eNR: /* Use the normal result. */ return 0; case ePZ: /* + zero */ *c = 0x00000000; return 1; case eNZ: /* - zero */ *c = 0x80000000; return 1; case eSZ: /* signed zero */ *c = (a->sign == b->sign) ? PLUS_ZERO : MINUS_ZERO; return 1; case eRZ: /* +- zero depending on rounding mode. */ if ((regs.r_fpsw & FPSWBITS_RM) == FPRM_NINF) *c = 0x80000000; else *c = 0x00000000; return 1; case ePI: /* + Infinity */ *c = 0x7F800000; return 1; case eNI: /* - Infinity */ *c = 0xFF800000; return 1; case eSI: /* sign Infinity */ *c = (a->sign == b->sign) ? PLUS_INF : MINUS_INF; return 1; case eQN: /* Quiet NANs */ if (a->type == FP_QNAN) *c = a->orig_value; else *c = b->orig_value; return 1; case eSN: /* Signalling NANs */ if (a->type == FP_SNAN) *c = a->orig_value; else *c = b->orig_value; FP_RAISE (V); return 1; case eIn: /* Invalid. */ FP_RAISE (V); if (a->type == FP_SNAN) *c = a->orig_value | 0x00400000; else if (a->type == FP_SNAN) *c = b->orig_value | 0x00400000; else *c = 0x7fc00000; return 1; case eUn: /* Unimplemented. */ FP_RAISE (E); return 1; case eDZ: /* Division-by-zero. */ *c = (a->sign == b->sign) ? PLUS_INF : MINUS_INF; FP_RAISE (Z); return 1; default: return 0; } } #define CHECK_EXCEPTIONS(FPPa, FPPb, fpc, ex_tab) \ if (check_exceptions (&FPPa, &FPPb, &fpc, ex_tab, 0)) \ return fpc; /* For each operation, we have two tables of how nonnormal cases are handled. The DN=0 case is first, followed by the DN=1 case, with each table using the following layout: */ static FP_ExceptionCases ex_add_tab[5][5] = { /* N +0 -0 +In -In */ { eNR, eNR, eNR, ePI, eNI }, /* Normal */ { eNR, ePZ, eRZ, ePI, eNI }, /* +0 */ { eNR, eRZ, eNZ, ePI, eNI }, /* -0 */ { ePI, ePI, ePI, ePI, eIn }, /* +Inf */ { eNI, eNI, eNI, eIn, eNI }, /* -Inf */ }; fp_t rxfp_add (fp_t fa, fp_t fb) { FP_Parts a, b, c; fp_t rv; double da, db; fp_explode (fa, &a); fp_explode (fb, &b); CHECK_EXCEPTIONS (a, b, rv, ex_add_tab); da = fp_to_double (&a); db = fp_to_double (&b); tprintf("%g + %g = %g\n", da, db, da+db); double_to_fp (da+db, &c); rv = fp_implode (&c); return rv; } static FP_ExceptionCases ex_sub_tab[5][5] = { /* N +0 -0 +In -In */ { eNR, eNR, eNR, eNI, ePI }, /* Normal */ { eNR, eRZ, ePZ, eNI, ePI }, /* +0 */ { eNR, eNZ, eRZ, eNI, ePI }, /* -0 */ { ePI, ePI, ePI, eIn, ePI }, /* +Inf */ { eNI, eNI, eNI, eNI, eIn }, /* -Inf */ }; fp_t rxfp_sub (fp_t fa, fp_t fb) { FP_Parts a, b, c; fp_t rv; double da, db; fp_explode (fa, &a); fp_explode (fb, &b); CHECK_EXCEPTIONS (a, b, rv, ex_sub_tab); da = fp_to_double (&a); db = fp_to_double (&b); tprintf("%g - %g = %g\n", da, db, da-db); double_to_fp (da-db, &c); rv = fp_implode (&c); return rv; } static FP_ExceptionCases ex_mul_tab[5][5] = { /* N +0 -0 +In -In */ { eNR, eNR, eNR, eSI, eSI }, /* Normal */ { eNR, ePZ, eNZ, eIn, eIn }, /* +0 */ { eNR, eNZ, ePZ, eIn, eIn }, /* -0 */ { eSI, eIn, eIn, ePI, eNI }, /* +Inf */ { eSI, eIn, eIn, eNI, ePI }, /* -Inf */ }; fp_t rxfp_mul (fp_t fa, fp_t fb) { FP_Parts a, b, c; fp_t rv; double da, db; fp_explode (fa, &a); fp_explode (fb, &b); CHECK_EXCEPTIONS (a, b, rv, ex_mul_tab); da = fp_to_double (&a); db = fp_to_double (&b); tprintf("%g x %g = %g\n", da, db, da*db); double_to_fp (da*db, &c); rv = fp_implode (&c); return rv; } static FP_ExceptionCases ex_div_tab[5][5] = { /* N +0 -0 +In -In */ { eNR, eDZ, eDZ, eSZ, eSZ }, /* Normal */ { eSZ, eIn, eIn, ePZ, eNZ }, /* +0 */ { eSZ, eIn, eIn, eNZ, ePZ }, /* -0 */ { eSI, ePI, eNI, eIn, eIn }, /* +Inf */ { eSI, eNI, ePI, eIn, eIn }, /* -Inf */ }; fp_t rxfp_div (fp_t fa, fp_t fb) { FP_Parts a, b, c; fp_t rv; double da, db; fp_explode (fa, &a); fp_explode (fb, &b); CHECK_EXCEPTIONS (a, b, rv, ex_div_tab); da = fp_to_double (&a); db = fp_to_double (&b); tprintf("%g / %g = %g\n", da, db, da/db); double_to_fp (da/db, &c); rv = fp_implode (&c); return rv; } static FP_ExceptionCases ex_cmp_tab[5][5] = { /* N +0 -0 +In -In */ { eNR, eNR, eNR, eLT, eGT }, /* Normal */ { eNR, eEQ, eEQ, eLT, eGT }, /* +0 */ { eNR, eEQ, eEQ, eLT, eGT }, /* -0 */ { eGT, eGT, eGT, eEQ, eGT }, /* +Inf */ { eLT, eLT, eLT, eLT, eEQ }, /* -Inf */ }; void rxfp_cmp (fp_t fa, fp_t fb) { FP_Parts a, b; fp_t c; FP_ExceptionCases reason; int flags = 0; double da, db; fp_explode (fa, &a); fp_explode (fb, &b); if (check_exceptions (&a, &b, &c, ex_cmp_tab, &reason)) { if (reason == eQN) { /* Special case - incomparable. */ set_flags (FLAGBIT_Z | FLAGBIT_S | FLAGBIT_O, FLAGBIT_O); return; } return; } switch (reason) { case eEQ: flags = FLAGBIT_Z; break; case eLT: flags = FLAGBIT_S; break; case eGT: flags = 0; break; case eNR: da = fp_to_double (&a); db = fp_to_double (&b); tprintf("fcmp: %g cmp %g\n", da, db); if (da < db) flags = FLAGBIT_S; else if (da == db) flags = FLAGBIT_Z; else flags = 0; break; default: abort(); } set_flags (FLAGBIT_Z | FLAGBIT_S | FLAGBIT_O, flags); } long rxfp_ftoi (fp_t fa, int round_mode) { FP_Parts a; fp_t rv; int sign; int whole_bits, frac_bits; fp_explode (fa, &a); sign = fa & 0x80000000UL; switch (a.type) { case FP_NORMAL: break; case FP_PZERO: case FP_NZERO: return 0; case FP_PINFINITY: FP_RAISE (V); return 0x7fffffffL; case FP_NINFINITY: FP_RAISE (V); return 0x80000000L; case FP_DENORMAL: FP_RAISE (E); return 0; case FP_QNAN: case FP_SNAN: FP_RAISE (V); return sign ? 0x80000000U : 0x7fffffff; } if (a.exp >= 31) { FP_RAISE (V); return sign ? 0x80000000U : 0x7fffffff; } a.exp -= 23; if (a.exp <= -25) { /* Less than 0.49999 */ frac_bits = a.mant; whole_bits = 0; } else if (a.exp < 0) { frac_bits = a.mant << (32 + a.exp); whole_bits = a.mant >> (-a.exp); } else { frac_bits = 0; whole_bits = a.mant << a.exp; } if (frac_bits) { switch (round_mode & 3) { case FPRM_NEAREST: if (frac_bits & 0x80000000UL) whole_bits ++; break; case FPRM_ZERO: break; case FPRM_PINF: if (!sign) whole_bits ++; break; case FPRM_NINF: if (sign) whole_bits ++; break; } } rv = sign ? -whole_bits : whole_bits; return rv; } fp_t rxfp_itof (long fa, int round_mode) { fp_t rv; int sign = 0; unsigned int frac_bits; volatile unsigned int whole_bits; FP_Parts a; if (fa == 0) return PLUS_ZERO; if (fa < 0) { fa = -fa; sign = 1; a.sign = -1; } else a.sign = 1; whole_bits = fa; a.exp = 31; while (! (whole_bits & 0x80000000UL)) { a.exp --; whole_bits <<= 1; } frac_bits = whole_bits & 0xff; whole_bits = whole_bits >> 8; if (frac_bits) { /* We must round */ switch (round_mode & 3) { case FPRM_NEAREST: if (frac_bits & 0x80) whole_bits ++; break; case FPRM_ZERO: break; case FPRM_PINF: if (!sign) whole_bits ++; break; case FPRM_NINF: if (sign) whole_bits ++; break; } } a.mant = whole_bits; if (whole_bits & 0xff000000UL) { a.mant >>= 1; a.exp ++; } rv = fp_implode (&a); return rv; }
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