m68k/fpe/fpu_fscale.c

1.7        is /*	$NetBSD: fpu_fscale.c,v 1.7 1997/10/09 19:19:01 is Exp $	*/
1.1    briggs
1.1    briggs /*
1.1    briggs  * Copyright (c) 1995 Ken Nakata
1.1    briggs  * All rights reserved.
1.1    briggs  *
1.1    briggs  * Redistribution and use in source and binary forms, with or without
1.1    briggs  * modification, are permitted provided that the following conditions
1.1    briggs  * are met:
1.1    briggs  * 1. Redistributions of source code must retain the above copyright
1.1    briggs  *    notice, this list of conditions and the following disclaimer.
1.1    briggs  * 2. Redistributions in binary form must reproduce the above copyright
1.1    briggs  *    notice, this list of conditions and the following disclaimer in the
1.1    briggs  *    documentation and/or other materials provided with the distribution.
1.1    briggs  * 3. The name of the author may not be used to endorse or promote products
1.1    briggs  *    derived from this software without specific prior written permission.
1.1    briggs  * 4. All advertising materials mentioning features or use of this software
1.1    briggs  *    must display the following acknowledgement:
1.1    briggs  *      This product includes software developed by Gordon Ross
1.1    briggs  *
1.1    briggs  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
1.1    briggs  * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
1.1    briggs  * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
1.1    briggs  * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
1.1    briggs  * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
1.1    briggs  * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
1.1    briggs  * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
1.1    briggs  * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
1.1    briggs  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
1.1    briggs  * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
1.1    briggs  */
1.1    briggs
1.1    briggs /*
1.1    briggs  * FSCALE - separated from the other type0 arithmetic instructions
1.1    briggs  * for performance reason; maybe unnecessary, but FSCALE assumes
1.1    briggs  * the source operand be an integer.  It performs type conversion
1.1    briggs  * only if the source operand is *not* an integer.
1.1    briggs  */
1.1    briggs
1.1    briggs #include <sys/types.h>
1.1    briggs #include <sys/signal.h>
1.3    briggs #include <sys/systm.h>
1.1    briggs #include <machine/frame.h>
1.1    briggs
1.1    briggs #include "fpu_emulate.h"
1.1    briggs
1.1    briggs int
1.1    briggs fpu_emul_fscale(fe, insn)
1.1    briggs      struct fpemu *fe;
1.1    briggs      struct instruction *insn;
1.1    briggs {
1.1    briggs     struct frame *frame;
1.1    briggs     u_int *fpregs;
1.1    briggs     int word1, sig;
1.1    briggs     int regnum, format;
1.1    briggs     int scale, sign, exp;
1.1    briggs     u_int m0, m1;
1.1    briggs     u_int buf[3], fpsr;
1.1    briggs     int flags;
1.1    briggs     char regname;
1.1    briggs
1.4       leo     scale = sig = 0;
1.1    briggs     frame = fe->fe_frame;
1.1    briggs     fpregs = &(fe->fe_fpframe->fpf_regs[0]);
1.1    briggs     /* clear all exceptions and conditions */
1.1    briggs     fpsr = fe->fe_fpsr & ~FPSR_EXCP & ~FPSR_CCB;
1.2    briggs     if (fpu_debug_level & DL_FSCALE) {
1.6  christos 	printf("  fpu_emul_fscale: FPSR = %08x, FPCR = %08x\n", fpsr, fe->fe_fpcr);
1.1    briggs     }
1.1    briggs
1.1    briggs     word1 = insn->is_word1;
1.1    briggs     format = (word1 >> 10) & 7;
1.1    briggs     regnum = (word1 >> 7) & 7;
1.1    briggs
1.1    briggs     fe->fe_fpcr &= FPCR_ROUND;
1.1    briggs     fe->fe_fpcr |= FPCR_ZERO;
1.1    briggs
1.1    briggs     /* get the source operand */
1.1    briggs     if ((word1 & 0x4000) == 0) {
1.2    briggs 	if (fpu_debug_level & DL_FSCALE) {
1.6  christos 	    printf("  fpu_emul_fscale: FP%d op FP%d => FP%d\n",
1.1    briggs 		   format, regnum, regnum);
1.1    briggs 	}
1.1    briggs 	/* the operand is an FP reg */
1.2    briggs 	if (fpu_debug_level & DL_FSCALE) {
1.6  christos 	    printf("  fpu_emul_scale: src opr FP%d=%08x%08x%08x\n",
1.1    briggs 		   format, fpregs[format*3], fpregs[format*3+1],
1.1    briggs 		   fpregs[format*3+2]);
1.1    briggs 	}
1.1    briggs 	fpu_explode(fe, &fe->fe_f2, FTYPE_EXT, &fpregs[format * 3]);
1.1    briggs 	fpu_implode(fe, &fe->fe_f2, FTYPE_LNG, buf);
1.7        is       scale = buf[0];
1.1    briggs     } else {
1.1    briggs 	/* the operand is in memory */
1.1    briggs 	if (format == FTYPE_DBL) {
1.1    briggs 	    insn->is_datasize = 8;
1.1    briggs 	} else if (format == FTYPE_SNG || format == FTYPE_LNG) {
1.1    briggs 	    insn->is_datasize = 4;
1.1    briggs 	} else if (format == FTYPE_WRD) {
1.1    briggs 	    insn->is_datasize = 2;
1.1    briggs 	} else if (format == FTYPE_BYT) {
1.1    briggs 	    insn->is_datasize = 1;
1.1    briggs 	} else if (format == FTYPE_EXT) {
1.1    briggs 	    insn->is_datasize = 12;
1.1    briggs 	} else {
1.1    briggs 	    /* invalid or unsupported operand format */
1.1    briggs 	    sig = SIGFPE;
1.1    briggs 	    return sig;
1.1    briggs 	}
1.1    briggs
1.1    briggs 	/* Get effective address. (modreg=opcode&077) */
1.1    briggs 	sig = fpu_decode_ea(frame, insn, &insn->is_ea0, insn->is_opcode);
1.1    briggs 	if (sig) {
1.2    briggs 	    if (fpu_debug_level & DL_FSCALE) {
1.6  christos 		printf("  fpu_emul_fscale: error in decode_ea\n");
1.1    briggs 	    }
1.1    briggs 	    return sig;
1.1    briggs 	}
1.1    briggs
1.2    briggs 	if (fpu_debug_level & DL_FSCALE) {
1.6  christos 	    printf("  fpu_emul_fscale: addr mode = ");
1.1    briggs 	    flags = insn->is_ea0.ea_flags;
1.1    briggs 	    regname = (insn->is_ea0.ea_regnum & 8) ? 'a' : 'd';
1.1    briggs
1.1    briggs 	    if (flags & EA_DIRECT) {
1.6  christos 		printf("%c%d\n", regname, insn->is_ea0.ea_regnum & 7);
1.1    briggs 	    } else if (insn->is_ea0.ea_flags & EA_PREDECR) {
1.6  christos 		printf("%c%d@-\n", regname, insn->is_ea0.ea_regnum & 7);
1.1    briggs 	    } else if (insn->is_ea0.ea_flags & EA_POSTINCR) {
1.6  christos 		printf("%c%d@+\n", regname, insn->is_ea0.ea_regnum & 7);
1.1    briggs 	    } else if (insn->is_ea0.ea_flags & EA_OFFSET) {
1.6  christos 		printf("%c%d@(%d)\n", regname, insn->is_ea0.ea_regnum & 7,
1.1    briggs 		       insn->is_ea0.ea_offset);
1.1    briggs 	    } else if (insn->is_ea0.ea_flags & EA_INDEXED) {
1.6  christos 		printf("%c%d@(...)\n", regname, insn->is_ea0.ea_regnum & 7);
1.1    briggs 	    } else if (insn->is_ea0.ea_flags & EA_ABS) {
1.6  christos 		printf("0x%08x\n", insn->is_ea0.ea_absaddr);
1.1    briggs 	    } else if (insn->is_ea0.ea_flags & EA_PC_REL) {
1.6  christos 		printf("pc@(%d)\n", insn->is_ea0.ea_offset);
1.1    briggs 	    } else if (flags & EA_IMMED) {
1.6  christos 		printf("#0x%08x%08x%08x\n",
1.1    briggs 		       insn->is_ea0.ea_immed[0], insn->is_ea0.ea_immed[1],
1.1    briggs 		       insn->is_ea0.ea_immed[2]);
1.1    briggs 	    } else {
1.6  christos 		printf("%c%d@\n", regname, insn->is_ea0.ea_regnum & 7);
1.1    briggs 	    }
1.1    briggs 	}
1.1    briggs 	fpu_load_ea(frame, insn, &insn->is_ea0, (char*)buf);
1.1    briggs
1.2    briggs 	if (fpu_debug_level & DL_FSCALE) {
1.6  christos 	    printf(" fpu_emul_fscale: src = %08x%08x%08x, siz = %d\n",
1.1    briggs 		   buf[0], buf[1], buf[2], insn->is_datasize);
1.1    briggs 	}
1.1    briggs 	if (format == FTYPE_LNG) {
1.1    briggs 	    /* nothing */
1.7        is           scale = buf[0];
1.1    briggs 	} else if (format == FTYPE_WRD) {
1.1    briggs 	    /* sign-extend */
1.1    briggs 	    scale = buf[0] & 0xffff;
1.1    briggs 	    if (scale & 0x8000) {
1.1    briggs 		scale |= 0xffff0000;
1.1    briggs 	    }
1.1    briggs 	} else if (format == FTYPE_BYT) {
1.1    briggs 	    /* sign-extend */
1.1    briggs 	    scale = buf[0] & 0xff;
1.1    briggs 	    if (scale & 0x80) {
1.1    briggs 		scale |= 0xffffff00;
1.1    briggs 	    }
1.1    briggs 	} else if (format == FTYPE_DBL || format == FTYPE_SNG ||
1.1    briggs 		   format == FTYPE_EXT) {
1.1    briggs 	    fpu_explode(fe, &fe->fe_f2, format, buf);
1.1    briggs 	    fpu_implode(fe, &fe->fe_f2, FTYPE_LNG, buf);
1.7        is           scale = buf[0];
1.1    briggs 	}
1.1    briggs 	/* make it look like we've got an FP oprand */
1.1    briggs 	fe->fe_f2.fp_class = (buf[0] == 0) ? FPC_ZERO : FPC_NUM;
1.1    briggs     }
1.1    briggs
1.1    briggs     /* assume there's no exception */
1.1    briggs     sig = 0;
1.1    briggs
1.1    briggs     /* it's barbaric but we're going to operate directly on
1.1    briggs      * the dst operand's bit pattern */
1.1    briggs     sign = fpregs[regnum * 3] & 0x80000000;
1.1    briggs     exp = (fpregs[regnum * 3] & 0x7fff0000) >> 16;
1.1    briggs     m0 = fpregs[regnum * 3 + 1];
1.1    briggs     m1 = fpregs[regnum * 3 + 2];
1.1    briggs
1.1    briggs     switch (fe->fe_f2.fp_class) {
1.1    briggs     case FPC_SNAN:
1.1    briggs 	fpsr |= FPSR_SNAN;
1.1    briggs     case FPC_QNAN:
1.1    briggs 	/* dst = NaN */
1.1    briggs 	exp = 0x7fff;
1.1    briggs 	m0 = m1 = 0xffffffff;
1.1    briggs 	break;
1.1    briggs     case FPC_ZERO:
1.1    briggs     case FPC_NUM:
1.1    briggs 	if ((0 < exp && exp < 0x7fff) ||
1.1    briggs 	    (exp == 0 && (m0 | m1) != 0)) {
1.1    briggs 	    /* normal or denormal */
1.1    briggs 	    exp += scale;
1.1    briggs 	    if (exp < 0) {
1.1    briggs 		/* underflow */
1.1    briggs 		u_int grs;	/* guard, round and sticky */
1.1    briggs
1.1    briggs 		exp = 0;
1.1    briggs 		grs = m1 << (32 + exp);
1.1    briggs 		m1 = m0 << (32 + exp) | m1 >> -exp;
1.1    briggs 		m0 >>= -exp;
1.1    briggs 		if (grs != 0) {
1.1    briggs 		    fpsr |= FPSR_INEX2;
1.1    briggs
1.1    briggs 		    switch (fe->fe_fpcr & 0x30) {
1.1    briggs 		    case FPCR_MINF:
1.1    briggs 			if (sign != 0) {
1.1    briggs 			    if (++m1 == 0 &&
1.1    briggs 				++m0 == 0) {
1.1    briggs 				m0 = 0x80000000;
1.1    briggs 				exp++;
1.1    briggs 			    }
1.1    briggs 			}
1.1    briggs 			break;
1.1    briggs 		    case FPCR_NEAR:
1.1    briggs 			if (grs == 0x80000000) {
1.1    briggs 			    /* tie */
1.1    briggs 			    if ((m1 & 1) &&
1.1    briggs 				++m1 == 0 &&
1.1    briggs 				++m0 == 0) {
1.1    briggs 				m0 = 0x80000000;
1.1    briggs 				exp++;
1.1    briggs 			    }
1.1    briggs 			} else if (grs & 0x80000000) {
1.1    briggs 			    if (++m1 == 0 &&
1.1    briggs 				++m0 == 0) {
1.1    briggs 				m0 = 0x80000000;
1.1    briggs 				exp++;
1.1    briggs 			    }
1.1    briggs 			}
1.1    briggs 			break;
1.1    briggs 		    case FPCR_PINF:
1.1    briggs 			if (sign == 0) {
1.1    briggs 			    if (++m1 == 0 &&
1.1    briggs 				++m0 == 0) {
1.1    briggs 				m0 = 0x80000000;
1.1    briggs 				exp++;
1.1    briggs 			    }
1.1    briggs 			}
1.1    briggs 			break;
1.1    briggs 		    case FPCR_ZERO:
1.1    briggs 			break;
1.1    briggs 		    }
1.1    briggs 		}
1.1    briggs 		if (exp == 0 && (m0 & 0x80000000) == 0) {
1.1    briggs 		    fpsr |= FPSR_UNFL;
1.1    briggs 		    if ((m0 | m1) == 0) {
1.1    briggs 			fpsr |= FPSR_ZERO;
1.1    briggs 		    }
1.1    briggs 		}
1.1    briggs 	    } else if (exp >= 0x7fff) {
1.1    briggs 		/* overflow --> result = Inf */
1.1    briggs 		/* but first, try to normalize in case it's an unnormalized */
1.1    briggs 		while ((m0 & 0x80000000) == 0) {
1.1    briggs 		    exp--;
1.1    briggs 		    m0 = (m0 << 1) | (m1 >> 31);
1.1    briggs 		    m1 = m1 << 1;
1.1    briggs 		}
1.1    briggs 		/* if it's still too large, then return Inf */
1.1    briggs 		if (exp >= 0x7fff) {
1.1    briggs 		    exp = 0x7fff;
1.1    briggs 		    m0 = m1 = 0;
1.1    briggs 		    fpsr |= FPSR_OVFL | FPSR_INF;
1.1    briggs 		}
1.1    briggs 	    } else if ((m0 & 0x80000000) == 0) {
1.1    briggs 		/*
1.1    briggs 		 * it's a denormal; we try to normalize but
1.1    briggs 		 * result may and may not be a normal.
1.1    briggs 		 */
1.1    briggs 		while (exp > 0 && (m0 & 0x80000000) == 0) {
1.1    briggs 		    exp--;
1.1    briggs 		    m0 = (m0 << 1) | (m1 >> 31);
1.1    briggs 		    m1 = m1 << 1;
1.1    briggs 		}
1.1    briggs 		if ((m0 & 0x80000000) == 0) {
1.1    briggs 		    fpsr |= FPSR_UNFL;
1.1    briggs 		}
1.1    briggs 	    } /* exp in range and mantissa normalized */
1.1    briggs 	} else if (exp == 0 && m0 == 0 && m1 == 0) {
1.1    briggs 	    /* dst is Zero */
1.1    briggs 	    fpsr |= FPSR_ZERO;
1.1    briggs 	} /* else we know exp == 0x7fff */
1.1    briggs 	else if ((m0 | m1) == 0) {
1.1    briggs 	    fpsr |= FPSR_INF;
1.1    briggs 	} else if ((m0 & 0x40000000) == 0) {
1.1    briggs 	    /* a signaling NaN */
1.1    briggs 	    fpsr |= FPSR_NAN | FPSR_SNAN;
1.1    briggs 	} else {
1.1    briggs 	    /* a quiet NaN */
1.1    briggs 	    fpsr |= FPSR_NAN;
1.1    briggs 	}
1.1    briggs 	break;
1.1    briggs     case FPC_INF:
1.1    briggs 	/* dst = NaN */
1.1    briggs 	exp = 0x7fff;
1.1    briggs 	m0 = m1 = 0xffffffff;
1.1    briggs 	fpsr |= FPSR_OPERR | FPSR_NAN;
1.1    briggs 	break;
1.1    briggs     default:
1.1    briggs #ifdef DEBUG
1.1    briggs 	panic("  fpu_emul_fscale: invalid fp class");
1.1    briggs #endif
1.1    briggs 	break;
1.1    briggs     }
1.1    briggs
1.1    briggs     /* store the result */
1.1    briggs     fpregs[regnum * 3] = sign | (exp << 16);
1.1    briggs     fpregs[regnum * 3 + 1] = m0;
1.1    briggs     fpregs[regnum * 3 + 2] = m1;
1.1    briggs
1.1    briggs     if (sign) {
1.1    briggs 	fpsr |= FPSR_NEG;
1.1    briggs     }
1.1    briggs
1.1    briggs     /* update fpsr according to the result of operation */
1.1    briggs     fe->fe_fpframe->fpf_fpsr = fe->fe_fpsr = fpsr;
1.1    briggs
1.2    briggs     if (fpu_debug_level & DL_FSCALE) {
1.6  christos 	printf("  fpu_emul_fscale: FPSR = %08x, FPCR = %08x\n",
1.1    briggs 	       fe->fe_fpsr, fe->fe_fpcr);
1.1    briggs     }
1.1    briggs
1.1    briggs     return (fpsr & fe->fe_fpcr & FPSR_EXCP) ? SIGFPE : sig;
1.1    briggs }