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1.1 ! root 1: #ifdef LIBC_SCCS ! 2: .asciz "@(#)muld.s 1.1 (Berkeley/CCI) 7/2/86" ! 3: #endif LIBC_SCCS ! 4: ! 5: #include <tahoemath/fp.h> ! 6: #include "DEFS.h" ! 7: ! 8: #define HIDDEN 23 /* here we count from 0 not from 1 as in fp.h */ ! 9: ! 10: XENTRY(muld, R2|R3|R4|R5|R6|R7|R8|R9) ! 11: clrl r3 /* r3 - sign: 0 for positive,1 for negative. */ ! 12: movl 4(fp),r0 ! 13: jgeq 1f ! 14: movl $1,r3 ! 15: 1: movl 12(fp),r2 ! 16: jgeq 2f ! 17: bbc $0,r3,1f /* seconed operand is negative. */ ! 18: clrl r3 /* if first was negative, make result positive. */ ! 19: jmp 2f ! 20: 1: movl $1,r3 /* if first was positive, make result negative. */ ! 21: 2: andl2 $EXPMASK,r0 /* compute first 'pure'exponent. */ ! 22: jeql is_res1 ! 23: shrl $EXPSHIFT,r0,r0 ! 24: subl2 $BIASP1,r0 ! 25: andl2 $EXPMASK,r2 /* compute seconed 'pure'exponent. */ ! 26: jeql is_res2 ! 27: shrl $EXPSHIFT,r2,r2 ! 28: subl2 $BIASP1,r2 ! 29: addl2 r0,r2 /* add the exponents. */ ! 30: addl2 $(BIASP1+2),r2 ! 31: jleq underflow ! 32: cmpl r2,$258 /* normalization can make the exp. smaller. */ ! 33: jgeq overflow ! 34: /* ! 35: * We have the sign in r3,the exponent in r2,now is the time to ! 36: * perform the multiplication... ! 37: */ ! 38: /* fetch first fraction: (r0,r1) */ ! 39: andl3 $(0!(EXPMASK | SIGNBIT)),4(fp),r0 ! 40: orl2 $(0!CLEARHID),r0 ! 41: movl 8(fp),r1 ! 42: shlq $7,r0,r0 /* leave the sign bit cleared. */ ! 43: ! 44: /* fetch seconed fraction: (r4,r5) */ ! 45: andl3 $(0!(EXPMASK | SIGNBIT)),12(fp),r4 ! 46: orl2 $(0!CLEARHID),r4 ! 47: movl 16(fp),r5 ! 48: shlq $7,r4,r4 /* leave the sign bit cleared. */ ! 49: ! 50: /* in the following lp1 stands for least significant part of operand 1, ! 51: * lp2 for least significant part of operand 2, ! 52: * mp1 for most significant part of operand 1, ! 53: * mp2 for most significant part of operand 2. ! 54: */ ! 55: ! 56: clrl r6 ! 57: shrl $1,r1,r1 /* clear the sign bit of the lp1. */ ! 58: jeql 1f ! 59: emul r1,r4,$0,r6 /* r6,r7 <-- lp1*mp2 */ ! 60: shlq $1,r6,r6 /* to compensate for the shift we did to clear the sign bit. */ ! 61: 1: shrl $1,r5,r5 /* clear the sign bit of the lp2. */ ! 62: jeql 1f ! 63: emul r0,r5,$0,r8 /* r8,r9 <-- mp1*lp2 */ ! 64: shlq $1,r8,r8 ! 65: addl2 r9,r7 /* r6,r7 <-- the sum of the products. */ ! 66: adwc r8,r6 ! 67: 1: emul r0,r4,$0,r0 /* r0,r1 <-- mp1*mp2 */ ! 68: addl2 r6,r1 /* add the most sig. part of the sum. */ ! 69: adwc $0,r0 ! 70: movl r0,r4 /* to see how much we realy need to shift. */ ! 71: movl $6,r5 /* r5 - shift counter. */ ! 72: shrl $7,r4,r4 /* dummy shift. */ ! 73: 1: bbs $HIDDEN,r4,realshift ! 74: shll $1,r4,r4 ! 75: decl r2 /* update exponent. */ ! 76: jeql underflow ! 77: decl r5 /* update shift counter. */ ! 78: jmp 1b ! 79: realshift: ! 80: shrq r5,r0,r0 ! 81: bbc $0,r1,shiftmore ! 82: incl r1 /* rounding. */ ! 83: shiftmore: ! 84: shrq $1,r0,r0 ! 85: comb: ! 86: andl2 $CLEARHID,r0 ! 87: shll $EXPSHIFT,r2,r4 ! 88: orl2 r4,r0 ! 89: cmpl r2,$256 ! 90: jlss 1f ! 91: callf $4,fpover ! 92: sign: ! 93: 1: bbc $0,r3,done ! 94: orl2 $SIGNBIT,r0 ! 95: done: ret ! 96: ! 97: ! 98: ! 99: is_res1: ! 100: bbc $31,4(fp),retzero ! 101: callf $4,fpresop ! 102: ret ! 103: is_res2: ! 104: bbc $31,12(fp),retzero ! 105: callf $4,fpresop ! 106: ret ! 107: retzero: ! 108: clrl r0 ! 109: clrl r1 ! 110: ret ! 111: overflow: ! 112: callf $4,fpover ! 113: jmp sign ! 114: underflow: ! 115: callf $4,fpunder ! 116: ret
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