/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License, Version 1.0 only * (the "License"). You may not use this file except in compliance * with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2005 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ .ident "%Z%%M% %I% %E% SMI" .file "%M%" #include "SYS.h" /* * C support for 64-bit modulo and division. * Hand-customized compiler output - see comments for details. */ /* * int32_t/int64_t division/manipulation * * Hand-customized compiler output: the non-GCC entry points depart from * the SYS V ABI by requiring their arguments to be popped, and in the * [u]divrem64 cases returning the remainder in %ecx:%esi. Note the * compiler-generated use of %edx:%eax for the first argument of * internal entry points. * * Inlines for speed: * - counting the number of leading zeros in a word * - multiplying two 32-bit numbers giving a 64-bit result * - dividing a 64-bit number by a 32-bit number, giving both quotient * and remainder * - subtracting two 64-bit results */ / #define LO(X) ((uint32_t)(X) & 0xffffffff) / #define HI(X) ((uint32_t)((X) >> 32) & 0xffffffff) / #define HILO(H, L) (((uint64_t)(H) << 32) + (L)) / / /* give index of highest bit */ / #define HIBIT(a, r) \ / asm("bsrl %1,%0": "=r"((uint32_t)(r)) : "g" (a)) / / /* multiply two uint32_ts resulting in a uint64_t */ / #define A_MUL32(a, b, lo, hi) \ / asm("mull %2" \ / : "=a"((uint32_t)(lo)), "=d"((uint32_t)(hi)) : "g" (b), "0"(a)) / / /* divide a uint64_t by a uint32_t */ / #define A_DIV32(lo, hi, b, q, r) \ / asm("divl %2" \ / : "=a"((uint32_t)(q)), "=d"((uint32_t)(r)) \ / : "g" (b), "0"((uint32_t)(lo)), "1"((uint32_t)hi)) / / /* subtract two uint64_ts (with borrow) */ / #define A_SUB2(bl, bh, al, ah) \ / asm("subl %4,%0\n\tsbbl %5,%1" \ / : "=&r"((uint32_t)(al)), "=r"((uint32_t)(ah)) \ / : "0"((uint32_t)(al)), "1"((uint32_t)(ah)), "g"((uint32_t)(bl)), \ / "g"((uint32_t)(bh))) / / /* / * Unsigned division with remainder. / * Divide two uint64_ts, and calculate remainder. / */ / uint64_t / UDivRem(uint64_t x, uint64_t y, uint64_t * pmod) / { / /* simple cases: y is a single uint32_t */ / if (HI(y) == 0) { / uint32_t div_hi, div_rem; / uint32_t q0, q1; / / /* calculate q1 */ / if (HI(x) < LO(y)) { / /* result is a single uint32_t, use one division */ / q1 = 0; / div_hi = HI(x); / } else { / /* result is a double uint32_t, use two divisions */ / A_DIV32(HI(x), 0, LO(y), q1, div_hi); / } / / /* calculate q0 and remainder */ / A_DIV32(LO(x), div_hi, LO(y), q0, div_rem); / / /* return remainder */ / *pmod = div_rem; / / /* return result */ / return (HILO(q1, q0)); / / } else if (HI(x) < HI(y)) { / /* HI(x) < HI(y) => x < y => result is 0 */ / / /* return remainder */ / *pmod = x; / / /* return result */ / return (0); / / } else { / /* / * uint64_t by uint64_t division, resulting in a one-uint32_t / * result / */ / uint32_t y0, y1; / uint32_t x1, x0; / uint32_t q0; / uint32_t normshift; / / /* normalize by shifting x and y so MSB(y) == 1 */ / HIBIT(HI(y), normshift); /* index of highest 1 bit */ / normshift = 31 - normshift; / / if (normshift == 0) { / /* no shifting needed, and x < 2*y so q <= 1 */ / y1 = HI(y); / y0 = LO(y); / x1 = HI(x); / x0 = LO(x); / / /* if x >= y then q = 1 (note x1 >= y1) */ / if (x1 > y1 || x0 >= y0) { / q0 = 1; / /* subtract y from x to get remainder */ / A_SUB2(y0, y1, x0, x1); / } else { / q0 = 0; / } / / /* return remainder */ / *pmod = HILO(x1, x0); / / /* return result */ / return (q0); / / } else { / /* / * the last case: result is one uint32_t, but we need to / * normalize / */ / uint64_t dt; / uint32_t t0, t1, x2; / / /* normalize y */ / dt = (y << normshift); / y1 = HI(dt); / y0 = LO(dt); / / /* normalize x (we need 3 uint32_ts!!!) */ / x2 = (HI(x) >> (32 - normshift)); / dt = (x << normshift); / x1 = HI(dt); / x0 = LO(dt); / / /* estimate q0, and reduce x to a two uint32_t value */ / A_DIV32(x1, x2, y1, q0, x1); / / /* adjust q0 down if too high */ / /* / * because of the limited range of x2 we can only be / * one off / */ / A_MUL32(y0, q0, t0, t1); / if (t1 > x1 || (t1 == x1 && t0 > x0)) { / q0--; / A_SUB2(y0, y1, t0, t1); / } / /* return remainder */ / /* subtract product from x to get remainder */ / A_SUB2(t0, t1, x0, x1); / *pmod = (HILO(x1, x0) >> normshift); / / /* return result */ / return (q0); / } / } / } ENTRY(UDivRem) pushl %ebp pushl %edi pushl %esi subl $48, %esp movl 68(%esp), %edi / y, testl %edi, %edi / tmp63 movl %eax, 40(%esp) / x, x movl %edx, 44(%esp) / x, x movl %edi, %esi /, tmp62 movl %edi, %ecx / tmp62, tmp63 jne .LL2 movl %edx, %eax /, tmp68 cmpl 64(%esp), %eax / y, tmp68 jae .LL21 .LL4: movl 72(%esp), %ebp / pmod, xorl %esi, %esi / movl 40(%esp), %eax / x, q0 movl %ecx, %edi / , divl 64(%esp) / y movl %edx, (%ebp) / div_rem, xorl %edx, %edx / q0 addl %eax, %esi / q0, movl $0, 4(%ebp) adcl %edx, %edi / q0, addl $48, %esp movl %esi, %eax / , popl %esi movl %edi, %edx / , popl %edi popl %ebp ret .align 16 .LL2: movl 44(%esp), %eax / x, xorl %edx, %edx cmpl %esi, %eax / tmp62, tmp5 movl %eax, 32(%esp) / tmp5, movl %edx, 36(%esp) jae .LL6 movl 72(%esp), %esi / pmod, movl 40(%esp), %ebp / x, movl 44(%esp), %ecx / x, movl %ebp, (%esi) movl %ecx, 4(%esi) xorl %edi, %edi / xorl %esi, %esi / .LL22: addl $48, %esp movl %esi, %eax / , popl %esi movl %edi, %edx / , popl %edi popl %ebp ret .align 16 .LL21: movl %edi, %edx / tmp63, div_hi divl 64(%esp) / y movl %eax, %ecx /, q1 jmp .LL4 .align 16 .LL6: movl $31, %edi /, tmp87 bsrl %esi,%edx / tmp62, normshift subl %edx, %edi / normshift, tmp87 movl %edi, 28(%esp) / tmp87, jne .LL8 movl 32(%esp), %edx /, x1 cmpl %ecx, %edx / y1, x1 movl 64(%esp), %edi / y, y0 movl 40(%esp), %esi / x, x0 ja .LL10 xorl %ebp, %ebp / q0 cmpl %edi, %esi / y0, x0 jb .LL11 .LL10: movl $1, %ebp /, q0 subl %edi,%esi / y0, x0 sbbl %ecx,%edx / tmp63, x1 .LL11: movl %edx, %ecx / x1, x1 xorl %edx, %edx / x1 xorl %edi, %edi / x0 addl %esi, %edx / x0, x1 adcl %edi, %ecx / x0, x1 movl 72(%esp), %esi / pmod, movl %edx, (%esi) / x1, movl %ecx, 4(%esi) / x1, xorl %edi, %edi / movl %ebp, %esi / q0, jmp .LL22 .align 16 .LL8: movb 28(%esp), %cl movl 64(%esp), %esi / y, dt movl 68(%esp), %edi / y, dt shldl %esi, %edi /, dt, dt sall %cl, %esi /, dt andl $32, %ecx jne .LL23 .LL17: movl $32, %ecx /, tmp102 subl 28(%esp), %ecx /, tmp102 movl %esi, %ebp / dt, y0 movl 32(%esp), %esi shrl %cl, %esi / tmp102, movl %edi, 24(%esp) / tmp99, movb 28(%esp), %cl movl %esi, 12(%esp) /, x2 movl 44(%esp), %edi / x, dt movl 40(%esp), %esi / x, dt shldl %esi, %edi /, dt, dt sall %cl, %esi /, dt andl $32, %ecx je .LL18 movl %esi, %edi / dt, dt xorl %esi, %esi / dt .LL18: movl %edi, %ecx / dt, movl %edi, %eax / tmp2, movl %ecx, (%esp) movl 12(%esp), %edx / x2, divl 24(%esp) movl %edx, %ecx /, x1 xorl %edi, %edi movl %eax, 20(%esp) movl %ebp, %eax / y0, t0 mull 20(%esp) cmpl %ecx, %edx / x1, t1 movl %edi, 4(%esp) ja .LL14 je .LL24 .LL15: movl %ecx, %edi / x1, subl %eax,%esi / t0, x0 sbbl %edx,%edi / t1, movl %edi, %eax /, x1 movl %eax, %edx / x1, x1 xorl %eax, %eax / x1 xorl %ebp, %ebp / x0 addl %esi, %eax / x0, x1 adcl %ebp, %edx / x0, x1 movb 28(%esp), %cl shrdl %edx, %eax /, x1, x1 shrl %cl, %edx /, x1 andl $32, %ecx je .LL16 movl %edx, %eax / x1, x1 xorl %edx, %edx / x1 .LL16: movl 72(%esp), %ecx / pmod, movl 20(%esp), %esi /, xorl %edi, %edi / movl %eax, (%ecx) / x1, movl %edx, 4(%ecx) / x1, jmp .LL22 .align 16 .LL24: cmpl %esi, %eax / x0, t0 jbe .LL15 .LL14: decl 20(%esp) subl %ebp,%eax / y0, t0 sbbl 24(%esp),%edx /, t1 jmp .LL15 .LL23: movl %esi, %edi / dt, dt xorl %esi, %esi / dt jmp .LL17 SET_SIZE(UDivRem) /* * Unsigned division without remainder. */ / uint64_t / UDiv(uint64_t x, uint64_t y) / { / if (HI(y) == 0) { / /* simple cases: y is a single uint32_t */ / uint32_t div_hi, div_rem; / uint32_t q0, q1; / / /* calculate q1 */ / if (HI(x) < LO(y)) { / /* result is a single uint32_t, use one division */ / q1 = 0; / div_hi = HI(x); / } else { / /* result is a double uint32_t, use two divisions */ / A_DIV32(HI(x), 0, LO(y), q1, div_hi); / } / / /* calculate q0 and remainder */ / A_DIV32(LO(x), div_hi, LO(y), q0, div_rem); / / /* return result */ / return (HILO(q1, q0)); / / } else if (HI(x) < HI(y)) { / /* HI(x) < HI(y) => x < y => result is 0 */ / / /* return result */ / return (0); / / } else { / /* / * uint64_t by uint64_t division, resulting in a one-uint32_t / * result / */ / uint32_t y0, y1; / uint32_t x1, x0; / uint32_t q0; / unsigned normshift; / / /* normalize by shifting x and y so MSB(y) == 1 */ / HIBIT(HI(y), normshift); /* index of highest 1 bit */ / normshift = 31 - normshift; / / if (normshift == 0) { / /* no shifting needed, and x < 2*y so q <= 1 */ / y1 = HI(y); / y0 = LO(y); / x1 = HI(x); / x0 = LO(x); / / /* if x >= y then q = 1 (note x1 >= y1) */ / if (x1 > y1 || x0 >= y0) { / q0 = 1; / /* subtract y from x to get remainder */ / /* A_SUB2(y0, y1, x0, x1); */ / } else { / q0 = 0; / } / / /* return result */ / return (q0); / / } else { / /* / * the last case: result is one uint32_t, but we need to / * normalize / */ / uint64_t dt; / uint32_t t0, t1, x2; / / /* normalize y */ / dt = (y << normshift); / y1 = HI(dt); / y0 = LO(dt); / / /* normalize x (we need 3 uint32_ts!!!) */ / x2 = (HI(x) >> (32 - normshift)); / dt = (x << normshift); / x1 = HI(dt); / x0 = LO(dt); / / /* estimate q0, and reduce x to a two uint32_t value */ / A_DIV32(x1, x2, y1, q0, x1); / / /* adjust q0 down if too high */ / /* / * because of the limited range of x2 we can only be / * one off / */ / A_MUL32(y0, q0, t0, t1); / if (t1 > x1 || (t1 == x1 && t0 > x0)) { / q0--; / } / /* return result */ / return (q0); / } / } / } ENTRY(UDiv) pushl %ebp pushl %edi pushl %esi subl $40, %esp movl %edx, 36(%esp) / x, x movl 60(%esp), %edx / y, testl %edx, %edx / tmp62 movl %eax, 32(%esp) / x, x movl %edx, %ecx / tmp61, tmp62 movl %edx, %eax /, tmp61 jne .LL26 movl 36(%esp), %esi / x, cmpl 56(%esp), %esi / y, tmp67 movl %esi, %eax /, tmp67 movl %esi, %edx / tmp67, div_hi jb .LL28 movl %ecx, %edx / tmp62, div_hi divl 56(%esp) / y movl %eax, %ecx /, q1 .LL28: xorl %esi, %esi / movl %ecx, %edi / , movl 32(%esp), %eax / x, q0 xorl %ecx, %ecx / q0 divl 56(%esp) / y addl %eax, %esi / q0, adcl %ecx, %edi / q0, .LL25: addl $40, %esp movl %esi, %eax / , popl %esi movl %edi, %edx / , popl %edi popl %ebp ret .align 16 .LL26: movl 36(%esp), %esi / x, xorl %edi, %edi movl %esi, 24(%esp) / tmp1, movl %edi, 28(%esp) xorl %esi, %esi / xorl %edi, %edi / cmpl %eax, 24(%esp) / tmp61, jb .LL25 bsrl %eax,%ebp / tmp61, normshift movl $31, %eax /, tmp85 subl %ebp, %eax / normshift, normshift jne .LL32 movl 24(%esp), %eax /, x1 cmpl %ecx, %eax / tmp62, x1 movl 56(%esp), %esi / y, y0 movl 32(%esp), %edx / x, x0 ja .LL34 xorl %eax, %eax / q0 cmpl %esi, %edx / y0, x0 jb .LL35 .LL34: movl $1, %eax /, q0 .LL35: movl %eax, %esi / q0, xorl %edi, %edi / .LL45: addl $40, %esp movl %esi, %eax / , popl %esi movl %edi, %edx / , popl %edi popl %ebp ret .align 16 .LL32: movb %al, %cl movl 56(%esp), %esi / y, movl 60(%esp), %edi / y, shldl %esi, %edi sall %cl, %esi andl $32, %ecx jne .LL43 .LL40: movl $32, %ecx /, tmp96 subl %eax, %ecx / normshift, tmp96 movl %edi, %edx movl %edi, 20(%esp) /, dt movl 24(%esp), %ebp /, x2 xorl %edi, %edi shrl %cl, %ebp / tmp96, x2 movl %esi, 16(%esp) /, dt movb %al, %cl movl 32(%esp), %esi / x, dt movl %edi, 12(%esp) movl 36(%esp), %edi / x, dt shldl %esi, %edi /, dt, dt sall %cl, %esi /, dt andl $32, %ecx movl %edx, 8(%esp) je .LL41 movl %esi, %edi / dt, dt xorl %esi, %esi / dt .LL41: xorl %ecx, %ecx movl %edi, %eax / tmp1, movl %ebp, %edx / x2, divl 8(%esp) movl %edx, %ebp /, x1 movl %ecx, 4(%esp) movl %eax, %ecx /, q0 movl 16(%esp), %eax / dt, mull %ecx / q0 cmpl %ebp, %edx / x1, t1 movl %edi, (%esp) movl %esi, %edi / dt, x0 ja .LL38 je .LL44 .LL39: movl %ecx, %esi / q0, .LL46: xorl %edi, %edi / jmp .LL45 .LL44: cmpl %edi, %eax / x0, t0 jbe .LL39 .LL38: decl %ecx / q0 movl %ecx, %esi / q0, jmp .LL46 .LL43: movl %esi, %edi xorl %esi, %esi jmp .LL40 SET_SIZE(UDiv) /* * __udiv64 * * Perform division of two unsigned 64-bit quantities, returning the * quotient in %edx:%eax. __udiv64 pops the arguments on return, */ ENTRY(__udiv64) movl 4(%esp), %eax / x, x movl 8(%esp), %edx / x, x pushl 16(%esp) / y pushl 16(%esp) call UDiv addl $8, %esp ret $16 SET_SIZE(__udiv64) /* * __urem64 * * Perform division of two unsigned 64-bit quantities, returning the * remainder in %edx:%eax. __urem64 pops the arguments on return */ ENTRY(__urem64) subl $12, %esp movl %esp, %ecx /, tmp65 movl 16(%esp), %eax / x, x movl 20(%esp), %edx / x, x pushl %ecx / tmp65 pushl 32(%esp) / y pushl 32(%esp) call UDivRem movl 12(%esp), %eax / rem, rem movl 16(%esp), %edx / rem, rem addl $24, %esp ret $16 SET_SIZE(__urem64) /* * __div64 * * Perform division of two signed 64-bit quantities, returning the * quotient in %edx:%eax. __div64 pops the arguments on return. */ / int64_t / __div64(int64_t x, int64_t y) / { / int negative; / uint64_t xt, yt, r; / / if (x < 0) { / xt = -(uint64_t) x; / negative = 1; / } else { / xt = x; / negative = 0; / } / if (y < 0) { / yt = -(uint64_t) y; / negative ^= 1; / } else { / yt = y; / } / r = UDiv(xt, yt); / return (negative ? (int64_t) - r : r); / } ENTRY(__div64) pushl %ebp pushl %edi pushl %esi subl $8, %esp movl 28(%esp), %edx / x, x testl %edx, %edx / x movl 24(%esp), %eax / x, x movl 32(%esp), %esi / y, y movl 36(%esp), %edi / y, y js .LL84 xorl %ebp, %ebp / negative testl %edi, %edi / y movl %eax, (%esp) / x, xt movl %edx, 4(%esp) / x, xt movl %esi, %eax / y, yt movl %edi, %edx / y, yt js .LL85 .LL82: pushl %edx / yt pushl %eax / yt movl 8(%esp), %eax / xt, xt movl 12(%esp), %edx / xt, xt call UDiv popl %ecx testl %ebp, %ebp / negative popl %esi je .LL83 negl %eax / r adcl $0, %edx /, r negl %edx / r .LL83: addl $8, %esp popl %esi popl %edi popl %ebp ret $16 .align 16 .LL84: negl %eax / x adcl $0, %edx /, x negl %edx / x testl %edi, %edi / y movl %eax, (%esp) / x, xt movl %edx, 4(%esp) / x, xt movl $1, %ebp /, negative movl %esi, %eax / y, yt movl %edi, %edx / y, yt jns .LL82 .align 16 .LL85: negl %eax / yt adcl $0, %edx /, yt negl %edx / yt xorl $1, %ebp /, negative jmp .LL82 SET_SIZE(__div64) /* * __rem64 * * Perform division of two signed 64-bit quantities, returning the * remainder in %edx:%eax. __rem64 pops the arguments on return. */ / int64_t / __rem64(int64_t x, int64_t y) / { / uint64_t xt, yt, rem; / / if (x < 0) { / xt = -(uint64_t) x; / } else { / xt = x; / } / if (y < 0) { / yt = -(uint64_t) y; / } else { / yt = y; / } / (void) UDivRem(xt, yt, &rem); / return (x < 0 ? (int64_t) - rem : rem); / } ENTRY(__rem64) pushl %edi pushl %esi subl $20, %esp movl 36(%esp), %ecx / x, movl 32(%esp), %esi / x, movl 36(%esp), %edi / x, testl %ecx, %ecx movl 40(%esp), %eax / y, y movl 44(%esp), %edx / y, y movl %esi, (%esp) /, xt movl %edi, 4(%esp) /, xt js .LL92 testl %edx, %edx / y movl %eax, %esi / y, yt movl %edx, %edi / y, yt js .LL93 .LL90: leal 8(%esp), %eax /, tmp66 pushl %eax / tmp66 pushl %edi / yt pushl %esi / yt movl 12(%esp), %eax / xt, xt movl 16(%esp), %edx / xt, xt call UDivRem addl $12, %esp movl 36(%esp), %edi / x, testl %edi, %edi movl 8(%esp), %eax / rem, rem movl 12(%esp), %edx / rem, rem js .LL94 addl $20, %esp popl %esi popl %edi ret $16 .align 16 .LL92: negl %esi adcl $0, %edi negl %edi testl %edx, %edx / y movl %esi, (%esp) /, xt movl %edi, 4(%esp) /, xt movl %eax, %esi / y, yt movl %edx, %edi / y, yt jns .LL90 .align 16 .LL93: negl %esi / yt adcl $0, %edi /, yt negl %edi / yt jmp .LL90 .align 16 .LL94: negl %eax / rem adcl $0, %edx /, rem addl $20, %esp popl %esi negl %edx / rem popl %edi ret $16 SET_SIZE(__rem64) /* * __udivrem64 * * Perform division of two unsigned 64-bit quantities, returning the * quotient in %edx:%eax, and the remainder in %ecx:%esi. __udivrem64 * pops the arguments on return. */ ENTRY(__udivrem64) subl $12, %esp movl %esp, %ecx /, tmp64 movl 16(%esp), %eax / x, x movl 20(%esp), %edx / x, x pushl %ecx / tmp64 pushl 32(%esp) / y pushl 32(%esp) call UDivRem movl 16(%esp), %ecx / rem, tmp63 movl 12(%esp), %esi / rem addl $24, %esp ret $16 SET_SIZE(__udivrem64) /* * Signed division with remainder. */ / int64_t / SDivRem(int64_t x, int64_t y, int64_t * pmod) / { / int negative; / uint64_t xt, yt, r, rem; / / if (x < 0) { / xt = -(uint64_t) x; / negative = 1; / } else { / xt = x; / negative = 0; / } / if (y < 0) { / yt = -(uint64_t) y; / negative ^= 1; / } else { / yt = y; / } / r = UDivRem(xt, yt, &rem); / *pmod = (x < 0 ? (int64_t) - rem : rem); / return (negative ? (int64_t) - r : r); / } ENTRY(SDivRem) pushl %ebp pushl %edi pushl %esi subl $24, %esp testl %edx, %edx / x movl %edx, %edi / x, x js .LL73 movl 44(%esp), %esi / y, xorl %ebp, %ebp / negative testl %esi, %esi movl %edx, 12(%esp) / x, xt movl %eax, 8(%esp) / x, xt movl 40(%esp), %edx / y, yt movl 44(%esp), %ecx / y, yt js .LL74 .LL70: leal 16(%esp), %eax /, tmp70 pushl %eax / tmp70 pushl %ecx / yt pushl %edx / yt movl 20(%esp), %eax / xt, xt movl 24(%esp), %edx / xt, xt call UDivRem movl %edx, 16(%esp) /, r movl %eax, 12(%esp) /, r addl $12, %esp testl %edi, %edi / x movl 16(%esp), %edx / rem, rem movl 20(%esp), %ecx / rem, rem js .LL75 .LL71: movl 48(%esp), %edi / pmod, pmod testl %ebp, %ebp / negative movl %edx, (%edi) / rem,* pmod movl %ecx, 4(%edi) / rem, movl (%esp), %eax / r, r movl 4(%esp), %edx / r, r je .LL72 negl %eax / r adcl $0, %edx /, r negl %edx / r .LL72: addl $24, %esp popl %esi popl %edi popl %ebp ret .align 16 .LL73: negl %eax adcl $0, %edx movl 44(%esp), %esi / y, negl %edx testl %esi, %esi movl %edx, 12(%esp) /, xt movl %eax, 8(%esp) /, xt movl $1, %ebp /, negative movl 40(%esp), %edx / y, yt movl 44(%esp), %ecx / y, yt jns .LL70 .align 16 .LL74: negl %edx / yt adcl $0, %ecx /, yt negl %ecx / yt xorl $1, %ebp /, negative jmp .LL70 .align 16 .LL75: negl %edx / rem adcl $0, %ecx /, rem negl %ecx / rem jmp .LL71 SET_SIZE(SDivRem) /* * __divrem64 * * Perform division of two signed 64-bit quantities, returning the * quotient in %edx:%eax, and the remainder in %ecx:%esi. __divrem64 * pops the arguments on return. */ ENTRY(__divrem64) subl $20, %esp movl %esp, %ecx /, tmp64 movl 24(%esp), %eax / x, x movl 28(%esp), %edx / x, x pushl %ecx / tmp64 pushl 40(%esp) / y pushl 40(%esp) call SDivRem movl 16(%esp), %ecx movl 12(%esp),%esi / rem addl $32, %esp ret $16 SET_SIZE(__divrem64)