/* $NetBSD: n_argred.S,v 1.9 2007/04/19 00:37:20 matt Exp $ */ /* * Copyright (c) 1985, 1993 * The Regents of the University of California. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. Neither the name of the University nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * @(#)argred.s 8.1 (Berkeley) 6/4/93 */ #include /* * libm$argred implements Bob Corbett's argument reduction and * libm$sincos implements Peter Tang's double precision sin/cos. * * Note: The two entry points libm$argred and libm$sincos are meant * to be used only by _sin, _cos and _tan. * * method: true range reduction to [-pi/4,pi/4], P. Tang & B. Corbett * S. McDonald, April 4, 1985 */ .hidden __libm_argred ENTRY(__libm_argred, 0) /* * Compare the argument with the largest possible that can * be reduced by table lookup. %r3 := |x| will be used in table_lookup . */ movd %r0,%r3 bgeq abs1 mnegd %r3,%r3 abs1: cmpd %r3,$0d+4.55530934770520019583e+01 blss small_arg jsb trigred rsb small_arg: jsb table_lookup rsb /* * At this point, * %r0 contains the quadrant number, 0, 1, 2, or 3; * %r2/%r1 contains the reduced argument as a D-format number; * %r3 contains a F-format extension to the reduced argument; * %r4 contains a 0 or 1 corresponding to a sin or cos entry. */ .hidden __libm_sincos ENTRY(__libm_sincos, 0) /* * Compensate for a cosine entry by adding one to the quadrant number. */ addl2 %r4,%r0 /* * Polyd clobbers %r5-%r0 ; save X in %r7/%r6 . * This can be avoided by rewriting trigred . */ movd %r1,%r6 /* * Likewise, save alpha in %r8 . * This can be avoided by rewriting trigred . */ movf %r3,%r8 /* * Odd or even quadrant? cosine if odd, sine otherwise. * Save floor(quadrant/2) in %r9 ; it determines the final sign. */ rotl $-1,%r0,%r9 blss cosine sine: muld2 %r1,%r1 # Xsq = X * X cmpw $0x2480,%r1 # [zl] Xsq > 2^-56? blss 1f # [zl] yes, go ahead and do polyd clrq %r1 # [zl] work around 11/780 FPA polyd bug 1: polyd %r1,$7,sin_coef # Q = P(Xsq) , of deg 7 mulf3 $0f3.0,%r8,%r4 # beta = 3 * alpha mulf2 %r0,%r4 # beta = Q * beta addf2 %r8,%r4 # beta = alpha + beta muld2 %r6,%r0 # S(X) = X * Q /* cvtfd %r4,%r4 ... %r5 = 0 after a polyd. */ addd2 %r4,%r0 # S(X) = beta + S(X) addd2 %r6,%r0 # S(X) = X + S(X) jbr done cosine: muld2 %r6,%r6 # Xsq = X * X beql zero_arg mulf2 %r1,%r8 # beta = X * alpha polyd %r6,$7,cos_coef /* Q = P'(Xsq) , of deg 7 */ subd3 %r0,%r8,%r0 # beta = beta - Q subw2 $0x80,%r6 # Xsq = Xsq / 2 addd2 %r0,%r6 # Xsq = Xsq + beta zero_arg: subd3 %r6,$0d1.0,%r0 # C(X) = 1 - Xsq done: blbc %r9,even mnegd %r0,%r0 even: rsb #ifdef __ELF__ .section .rodata #else .text #endif _ALIGN_TEXT sin_coef: .double 0d-7.53080332264191085773e-13 # s7 = 2^-29 -1.a7f2504ffc49f8.. .double 0d+1.60573519267703489121e-10 # s6 = 2^-21 1.611adaede473c8.. .double 0d-2.50520965150706067211e-08 # s5 = 2^-1a -1.ae644921ed8382.. .double 0d+2.75573191800593885716e-06 # s4 = 2^-13 1.71de3a4b884278.. .double 0d-1.98412698411850507950e-04 # s3 = 2^-0d -1.a01a01a0125e7d.. .double 0d+8.33333333333325688985e-03 # s2 = 2^-07 1.11111111110e50 .double 0d-1.66666666666666664354e-01 # s1 = 2^-03 -1.55555555555554 .double 0d+0.00000000000000000000e+00 # s0 = 0 cos_coef: .double 0d-1.13006966202629430300e-11 # s7 = 2^-25 -1.8D9BA04D1374BE.. .double 0d+2.08746646574796004700e-09 # s6 = 2^-1D 1.1EE632650350BA.. .double 0d-2.75573073031284417300e-07 # s5 = 2^-16 -1.27E4F31411719E.. .double 0d+2.48015872682668025200e-05 # s4 = 2^-10 1.A01A0196B902E8.. .double 0d-1.38888888888464709200e-03 # s3 = 2^-0A -1.6C16C16C11FACE.. .double 0d+4.16666666666664761400e-02 # s2 = 2^-05 1.5555555555539E .double 0d+0.00000000000000000000e+00 # s1 = 0 .double 0d+0.00000000000000000000e+00 # s0 = 0 /* * Multiples of pi/2 expressed as the sum of three doubles, * * trailing: n * pi/2 , n = 0, 1, 2, ..., 29 * trailing[n] , * * middle: n * pi/2 , n = 0, 1, 2, ..., 29 * middle[n] , * * leading: n * pi/2 , n = 0, 1, 2, ..., 29 * leading[n] , * * where * leading[n] := (n * pi/2) rounded, * middle[n] := (n * pi/2 - leading[n]) rounded, * trailing[n] := (( n * pi/2 - leading[n]) - middle[n]) rounded . */ trailing: .double 0d+0.00000000000000000000e+00 # 0 * pi/2 trailing .double 0d+4.33590506506189049611e-35 # 1 * pi/2 trailing .double 0d+8.67181013012378099223e-35 # 2 * pi/2 trailing .double 0d+1.30077151951856714215e-34 # 3 * pi/2 trailing .double 0d+1.73436202602475619845e-34 # 4 * pi/2 trailing .double 0d-1.68390735624352669192e-34 # 5 * pi/2 trailing .double 0d+2.60154303903713428430e-34 # 6 * pi/2 trailing .double 0d-8.16726343231148352150e-35 # 7 * pi/2 trailing .double 0d+3.46872405204951239689e-34 # 8 * pi/2 trailing .double 0d+3.90231455855570147991e-34 # 9 * pi/2 trailing .double 0d-3.36781471248705338384e-34 # 10 * pi/2 trailing .double 0d-1.06379439835298071785e-33 # 11 * pi/2 trailing .double 0d+5.20308607807426856861e-34 # 12 * pi/2 trailing .double 0d+5.63667658458045770509e-34 # 13 * pi/2 trailing .double 0d-1.63345268646229670430e-34 # 14 * pi/2 trailing .double 0d-1.19986217995610764801e-34 # 15 * pi/2 trailing .double 0d+6.93744810409902479378e-34 # 16 * pi/2 trailing .double 0d-8.03640094449267300110e-34 # 17 * pi/2 trailing .double 0d+7.80462911711140295982e-34 # 18 * pi/2 trailing .double 0d-7.16921993148029483506e-34 # 19 * pi/2 trailing .double 0d-6.73562942497410676769e-34 # 20 * pi/2 trailing .double 0d-6.30203891846791677593e-34 # 21 * pi/2 trailing .double 0d-2.12758879670596143570e-33 # 22 * pi/2 trailing .double 0d+2.53800212047402350390e-33 # 23 * pi/2 trailing .double 0d+1.04061721561485371372e-33 # 24 * pi/2 trailing .double 0d+6.11729905311472319056e-32 # 25 * pi/2 trailing .double 0d+1.12733531691609154102e-33 # 26 * pi/2 trailing .double 0d-3.70049587943078297272e-34 # 27 * pi/2 trailing .double 0d-3.26690537292459340860e-34 # 28 * pi/2 trailing .double 0d-1.14812616507957271361e-34 # 29 * pi/2 trailing middle: .double 0d+0.00000000000000000000e+00 # 0 * pi/2 middle .double 0d+5.72118872610983179676e-18 # 1 * pi/2 middle .double 0d+1.14423774522196635935e-17 # 2 * pi/2 middle .double 0d-3.83475850529283316309e-17 # 3 * pi/2 middle .double 0d+2.28847549044393271871e-17 # 4 * pi/2 middle .double 0d-2.69052076007086676522e-17 # 5 * pi/2 middle .double 0d-7.66951701058566632618e-17 # 6 * pi/2 middle .double 0d-1.54628301484890040587e-17 # 7 * pi/2 middle .double 0d+4.57695098088786543741e-17 # 8 * pi/2 middle .double 0d+1.07001849766246313192e-16 # 9 * pi/2 middle .double 0d-5.38104152014173353044e-17 # 10 * pi/2 middle .double 0d-2.14622680169080983801e-16 # 11 * pi/2 middle .double 0d-1.53390340211713326524e-16 # 12 * pi/2 middle .double 0d-9.21580002543456677056e-17 # 13 * pi/2 middle .double 0d-3.09256602969780081173e-17 # 14 * pi/2 middle .double 0d+3.03066796603896507006e-17 # 15 * pi/2 middle .double 0d+9.15390196177573087482e-17 # 16 * pi/2 middle .double 0d+1.52771359575124969107e-16 # 17 * pi/2 middle .double 0d+2.14003699532492626384e-16 # 18 * pi/2 middle .double 0d-1.68853170360202329427e-16 # 19 * pi/2 middle .double 0d-1.07620830402834670609e-16 # 20 * pi/2 middle .double 0d+3.97700719404595604379e-16 # 21 * pi/2 middle .double 0d-4.29245360338161967602e-16 # 22 * pi/2 middle .double 0d-3.68013020380794313406e-16 # 23 * pi/2 middle .double 0d-3.06780680423426653047e-16 # 24 * pi/2 middle .double 0d-2.45548340466059054318e-16 # 25 * pi/2 middle .double 0d-1.84316000508691335411e-16 # 26 * pi/2 middle .double 0d-1.23083660551323675053e-16 # 27 * pi/2 middle .double 0d-6.18513205939560162346e-17 # 28 * pi/2 middle .double 0d-6.18980636588357585202e-19 # 29 * pi/2 middle leading: .double 0d+0.00000000000000000000e+00 # 0 * pi/2 leading .double 0d+1.57079632679489661351e+00 # 1 * pi/2 leading .double 0d+3.14159265358979322702e+00 # 2 * pi/2 leading .double 0d+4.71238898038468989604e+00 # 3 * pi/2 leading .double 0d+6.28318530717958645404e+00 # 4 * pi/2 leading .double 0d+7.85398163397448312306e+00 # 5 * pi/2 leading .double 0d+9.42477796076937979208e+00 # 6 * pi/2 leading .double 0d+1.09955742875642763501e+01 # 7 * pi/2 leading .double 0d+1.25663706143591729081e+01 # 8 * pi/2 leading .double 0d+1.41371669411540694661e+01 # 9 * pi/2 leading .double 0d+1.57079632679489662461e+01 # 10 * pi/2 leading .double 0d+1.72787595947438630262e+01 # 11 * pi/2 leading .double 0d+1.88495559215387595842e+01 # 12 * pi/2 leading .double 0d+2.04203522483336561422e+01 # 13 * pi/2 leading .double 0d+2.19911485751285527002e+01 # 14 * pi/2 leading .double 0d+2.35619449019234492582e+01 # 15 * pi/2 leading .double 0d+2.51327412287183458162e+01 # 16 * pi/2 leading .double 0d+2.67035375555132423742e+01 # 17 * pi/2 leading .double 0d+2.82743338823081389322e+01 # 18 * pi/2 leading .double 0d+2.98451302091030359342e+01 # 19 * pi/2 leading .double 0d+3.14159265358979324922e+01 # 20 * pi/2 leading .double 0d+3.29867228626928286062e+01 # 21 * pi/2 leading .double 0d+3.45575191894877260523e+01 # 22 * pi/2 leading .double 0d+3.61283155162826226103e+01 # 23 * pi/2 leading .double 0d+3.76991118430775191683e+01 # 24 * pi/2 leading .double 0d+3.92699081698724157263e+01 # 25 * pi/2 leading .double 0d+4.08407044966673122843e+01 # 26 * pi/2 leading .double 0d+4.24115008234622088423e+01 # 27 * pi/2 leading .double 0d+4.39822971502571054003e+01 # 28 * pi/2 leading .double 0d+4.55530934770520019583e+01 # 29 * pi/2 leading twoOverPi: .double 0d+6.36619772367581343076e-01 .text _ALIGN_TEXT table_lookup: muld3 %r3,twoOverPi,%r0 cvtrdl %r0,%r0 # n = nearest int to ((2/pi)*|x|) rnded subd2 leading[%r0],%r3 # p = (|x| - leading n*pi/2) exactly subd3 middle[%r0],%r3,%r1 # q = (p - middle n*pi/2) rounded subd2 %r1,%r3 # r = (p - q) subd2 middle[%r0],%r3 # r = r - middle n*pi/2 subd2 trailing[%r0],%r3 # r = r - trailing n*pi/2 rounded /* * If the original argument was negative, * negate the reduce argument and * adjust the octant/quadrant number. */ tstw 4(%ap) bgeq abs2 mnegf %r1,%r1 mnegf %r3,%r3 /* subb3 %r0,$8,%r0 ...used for pi/4 reduction -S.McD */ subb3 %r0,$4,%r0 abs2: /* * Clear all unneeded octant/quadrant bits. */ /* bicb2 $0xf8,%r0 ...used for pi/4 reduction -S.McD */ bicb2 $0xfc,%r0 rsb /* * p.0 */ #ifdef __ELF__ .section .rodata #else .text #endif _ALIGN_TEXT /* * Only 256 (actually 225) bits of 2/pi are needed for VAX double * precision; this was determined by enumerating all the nearest * machine integer multiples of pi/2 using continued fractions. * (8a8d3673775b7ff7 required the most bits.) -S.McD */ .long 0 .long 0 .long 0xaef1586d .long 0x9458eaf7 .long 0x10e4107f .long 0xd8a5664f .long 0x4d377036 .long 0x09d5f47d .long 0x91054a7f .long 0xbe60db93 bits2opi: .long 0x00000028 .long 0 /* * Note: wherever you see the word `octant', read `quadrant'. * Currently this code is set up for pi/2 argument reduction. * By uncommenting/commenting the appropriate lines, it will * also serve as a pi/4 argument reduction code. */ .text /* p.1 * Trigred preforms argument reduction * for the trigonometric functions. It * takes one input argument, a D-format * number in %r1/%r0 . The magnitude of * the input argument must be greater * than or equal to 1/2 . Trigred produces * three results: the number of the octant * occupied by the argument, the reduced * argument, and an extension of the * reduced argument. The octant number is * returned in %r0 . The reduced argument * is returned as a D-format number in * %r2/%r1 . An 8 bit extension of the * reduced argument is returned as an * F-format number in %r3. * p.2 */ trigred: /* * Save the sign of the input argument. */ movw %r0,-(%sp) /* * Extract the exponent field. */ extzv $7,$7,%r0,%r2 /* * Convert the fraction part of the input * argument into a quadword integer. */ bicw2 $0xff80,%r0 bisb2 $0x80,%r0 # -S.McD rotl $16,%r0,%r0 rotl $16,%r1,%r1 /* * If %r1 is negative, add 1 to %r0 . This * adjustment is made so that the two's * complement multiplications done later * will produce unsigned results. */ bgeq posmid incl %r0 posmid: /* p.3 * * Set %r3 to the address of the first quadword * used to obtain the needed portion of 2/pi . * The address is longword aligned to ensure * efficient access. */ ashl $-3,%r2,%r3 bicb2 $3,%r3 mnegl %r3,%r3 movab bits2opi[%r3],%r3 /* * Set %r2 to the size of the shift needed to * obtain the correct portion of 2/pi . */ bicb2 $0xe0,%r2 /* p.4 * * Move the needed 128 bits of 2/pi into * %r11 - %r8 . Adjust the numbers to allow * for unsigned multiplication. */ ashq %r2,(%r3),%r10 subl2 $4,%r3 ashq %r2,(%r3),%r9 bgeq signoff1 incl %r11 signoff1: subl2 $4,%r3 ashq %r2,(%r3),%r8 bgeq signoff2 incl %r10 signoff2: subl2 $4,%r3 ashq %r2,(%r3),%r7 bgeq signoff3 incl %r9 signoff3: /* p.5 * * Multiply the contents of %r0/%r1 by the * slice of 2/pi in %r11 - %r8 . */ emul %r0,%r8,$0,%r4 emul %r0,%r9,%r5,%r5 emul %r0,%r10,%r6,%r6 emul %r1,%r8,$0,%r7 emul %r1,%r9,%r8,%r8 emul %r1,%r10,%r9,%r9 emul %r1,%r11,%r10,%r10 addl2 %r4,%r8 adwc %r5,%r9 adwc %r6,%r10 /* p.6 * * If there are more than five leading zeros * after the first two quotient bits or if there * are more than five leading ones after the first * two quotient bits, generate more fraction bits. * Otherwise, branch to code to produce the result. */ bicl3 $0xc1ffffff,%r10,%r4 beql more1 cmpl $0x3e000000,%r4 bneq result more1: /* p.7 * * generate another 32 result bits. */ subl2 $4,%r3 ashq %r2,(%r3),%r5 bgeq signoff4 emul %r1,%r6,$0,%r4 addl2 %r1,%r5 emul %r0,%r6,%r5,%r5 addl2 %r0,%r6 jbr addbits1 signoff4: emul %r1,%r6,$0,%r4 emul %r0,%r6,%r5,%r5 addbits1: addl2 %r5,%r7 adwc %r6,%r8 adwc $0,%r9 adwc $0,%r10 /* p.8 * * Check for massive cancellation. */ bicl3 $0xc0000000,%r10,%r6 /* bneq more2 -S.McD Test was backwards */ beql more2 cmpl $0x3fffffff,%r6 bneq result more2: /* p.9 * * If massive cancellation has occurred, * generate another 24 result bits. * Testing has shown there will always be * enough bits after this point. */ subl2 $4,%r3 ashq %r2,(%r3),%r5 bgeq signoff5 emul %r0,%r6,%r4,%r5 addl2 %r0,%r6 jbr addbits2 signoff5: emul %r0,%r6,%r4,%r5 addbits2: addl2 %r6,%r7 adwc $0,%r8 adwc $0,%r9 adwc $0,%r10 /* p.10 * * The following code produces the reduced * argument from the product bits contained * in %r10 - %r7 . */ result: /* * Extract the octant number from %r10 . */ /* extzv $29,$3,%r10,%r0 ...used for pi/4 reduction -S.McD */ extzv $30,$2,%r10,%r0 /* * Clear the octant bits in %r10 . */ /* bicl2 $0xe0000000,%r10 ...used for pi/4 reduction -S.McD */ bicl2 $0xc0000000,%r10 /* * Zero the sign flag. */ clrl %r5 /* p.11 * * Check to see if the fraction is greater than * or equal to one-half. If it is, add one * to the octant number, set the sign flag * on, and replace the fraction with 1 minus * the fraction. */ /* bitl $0x10000000,%r10 ...used for pi/4 reduction -S.McD */ bitl $0x20000000,%r10 beql small incl %r0 incl %r5 /* subl3 %r10,$0x1fffffff,%r10 ...used for pi/4 reduction -S.McD */ subl3 %r10,$0x3fffffff,%r10 mcoml %r9,%r9 mcoml %r8,%r8 mcoml %r7,%r7 small: /* p.12 * * Test whether the first 29 bits of the ...used for pi/4 reduction -S.McD * Test whether the first 30 bits of the * fraction are zero. */ tstl %r10 beql tiny /* * Find the position of the first one bit in %r10 . */ cvtld %r10,%r1 extzv $7,$7,%r1,%r1 /* * Compute the size of the shift needed. */ subl3 %r1,$32,%r6 /* * Shift up the high order 64 bits of the * product. */ ashq %r6,%r9,%r10 ashq %r6,%r8,%r9 jbr mult /* p.13 * * Test to see if the sign bit of %r9 is on. */ tiny: tstl %r9 bgeq tinier /* * If it is, shift the product bits up 32 bits. */ movl $32,%r6 movq %r8,%r10 tstl %r10 jbr mult /* p.14 * * Test whether %r9 is zero. It is probably * impossible for both %r10 and %r9 to be * zero, but until proven to be so, the test * must be made. */ tinier: beql zero /* * Find the position of the first one bit in %r9 . */ cvtld %r9,%r1 extzv $7,$7,%r1,%r1 /* * Compute the size of the shift needed. */ subl3 %r1,$32,%r1 addl3 $32,%r1,%r6 /* * Shift up the high order 64 bits of the * product. */ ashq %r1,%r8,%r10 ashq %r1,%r7,%r9 jbr mult /* p.15 * * The following code sets the reduced * argument to zero. */ zero: clrl %r1 clrl %r2 clrl %r3 jbr return /* p.16 * * At this point, %r0 contains the octant number, * %r6 indicates the number of bits the fraction * has been shifted, %r5 indicates the sign of * the fraction, %r11/%r10 contain the high order * 64 bits of the fraction, and the condition * codes indicate where the sign bit of %r10 * is on. The following code multiplies the * fraction by pi/2 . */ mult: /* * Save %r11/%r10 in %r4/%r1 . -S.McD */ movl %r11,%r4 movl %r10,%r1 /* * If the sign bit of %r10 is on, add 1 to %r11 . */ bgeq signoff6 incl %r11 signoff6: /* p.17 * * Move pi/2 into %r3/%r2 . */ movq $0xc90fdaa22168c235,%r2 /* * Multiply the fraction by the portion of pi/2 * in %r2 . */ emul %r2,%r10,$0,%r7 emul %r2,%r11,%r8,%r7 /* * Multiply the fraction by the portion of pi/2 * in %r3 . */ emul %r3,%r10,$0,%r9 emul %r3,%r11,%r10,%r10 /* * Add the product bits together. */ addl2 %r7,%r9 adwc %r8,%r10 adwc $0,%r11 /* * Compensate for not sign extending %r8 above.-S.McD */ tstl %r8 bgeq signoff6a decl %r11 signoff6a: /* * Compensate for %r11/%r10 being unsigned. -S.McD */ addl2 %r2,%r10 adwc %r3,%r11 /* * Compensate for %r3/%r2 being unsigned. -S.McD */ addl2 %r1,%r10 adwc %r4,%r11 /* p.18 * * If the sign bit of %r11 is zero, shift the * product bits up one bit and increment %r6 . */ blss signon incl %r6 ashq $1,%r10,%r10 tstl %r9 bgeq signoff7 incl %r10 signoff7: signon: /* p.19 * * Shift the 56 most significant product * bits into %r9/%r8 . The sign extension * will be handled later. */ ashq $-8,%r10,%r8 /* * Convert the low order 8 bits of %r10 * into an F-format number. */ cvtbf %r10,%r3 /* * If the result of the conversion was * negative, add 1 to %r9/%r8 . */ bgeq chop incl %r8 adwc $0,%r9 /* * If %r9 is now zero, branch to special * code to handle that possibility. */ beql carryout chop: /* p.20 * * Convert the number in %r9/%r8 into * D-format number in %r2/%r1 . */ rotl $16,%r8,%r2 rotl $16,%r9,%r1 /* * Set the exponent field to the appropriate * value. Note that the extra bits created by * sign extension are now eliminated. */ subw3 %r6,$131,%r6 insv %r6,$7,$9,%r1 /* * Set the exponent field of the F-format * number in %r3 to the appropriate value. */ tstf %r3 beql return /* extzv $7,$8,%r3,%r4 -S.McD */ extzv $7,$7,%r3,%r4 addw2 %r4,%r6 /* subw2 $217,%r6 -S.McD */ subw2 $64,%r6 insv %r6,$7,$8,%r3 jbr return /* p.21 * * The following code generates the appropriate * result for the unlikely possibility that * rounding the number in %r9/%r8 resulted in * a carry out. */ carryout: clrl %r1 clrl %r2 subw3 %r6,$132,%r6 insv %r6,$7,$9,%r1 tstf %r3 beql return extzv $7,$8,%r3,%r4 addw2 %r4,%r6 subw2 $218,%r6 insv %r6,$7,$8,%r3 /* p.22 * * The following code makes an needed * adjustments to the signs of the * results or to the octant number, and * then returns. */ return: /* * Test if the fraction was greater than or * equal to 1/2 . If so, negate the reduced * argument. */ blbc %r5,signoff8 mnegf %r1,%r1 mnegf %r3,%r3 signoff8: /* p.23 * * If the original argument was negative, * negate the reduce argument and * adjust the octant number. */ tstw (%sp)+ bgeq signoff9 mnegf %r1,%r1 mnegf %r3,%r3 /* subb3 %r0,$8,%r0 ...used for pi/4 reduction -S.McD */ subb3 %r0,$4,%r0 signoff9: /* * Clear all unneeded octant bits. * * bicb2 $0xf8,%r0 ...used for pi/4 reduction -S.McD */ bicb2 $0xfc,%r0 /* * Return. */ rsb