reactos/lib/sdk/crt/math/i386/aullrem_asm.s

   1 /*
   2  * COPYRIGHT:         See COPYING in the top level directory
   3  * PROJECT:           ReactOS kernel
   4  * PURPOSE:           Run-Time Library
   5  * FILE:              lib/rtl/i386/aullrem.S
   6  * PROGRAMER:         Alex Ionescu (alex@relsoft.net)
   7  *
   8  * Copyright (C) 2002 Michael Ringgaard.
   9  * All rights reserved.
  10  *
  11  * Redistribution and use in source and binary forms, with or without
  12  * modification, are permitted provided that the following conditions
  13  * are met:
  14  *
  15  * 1. Redistributions of source code must retain the above copyright
  16  *    notice, this list of conditions and the following disclaimer.
  17  * 2. Redistributions in binary form must reproduce the above copyright
  18  *    notice, this list of conditions and the following disclaimer in the
  19  *    documentation and/or other materials provided with the distribution.
  20  * 3. Neither the name of the project nor the names of its contributors
  21  *    may be used to endorse or promote products derived from this software
  22  *    without specific prior written permission.
  23
  24  * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
  25  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
  26  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
  27  * ARE DISCLAIMED.  IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE
  28  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
  29  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
  30  * OR SERVICES// LOSS OF USE, DATA, OR PROFITS// OR BUSINESS INTERRUPTION)
  31  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
  32  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
  33  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
  34  * SUCH DAMAGE.
  35  */
  36
  37 #include <asm.inc>
  38
  39 PUBLIC __aullrem
  40
  41 /* FUNCTIONS ***************************************************************/
  42 .code
  43
  44 //
  45 // ullrem - unsigned long remainder
  46 //
  47 // Purpose:
  48 //       Does a unsigned long remainder of the arguments.  Arguments are
  49 //       not changed.
  50 //
  51 // Entry:
  52 //       Arguments are passed on the stack:
  53 //               1st pushed: divisor (QWORD)
  54 //               2nd pushed: dividend (QWORD)
  55 //
  56 // Exit:
  57 //       EDX:EAX contains the remainder (dividend%divisor)
  58 //       NOTE: this routine removes the parameters from the stack.
  59 //
  60 // Uses:
  61 //       ECX
  62 //
  63
  64 __aullrem:
  65
  66         push    ebx
  67
  68 // Set up the local stack and save the index registers.  When this is done
  69 // the stack frame will look as follows (assuming that the expression a%b will
  70 // generate a call to ullrem(a, b)):
  71 //
  72 //               -----------------
  73 //               |               |
  74 //               |---------------|
  75 //               |               |
  76 //               |--divisor (b)--|
  77 //               |               |
  78 //               |---------------|
  79 //               |               |
  80 //               |--dividend (a)-|
  81 //               |               |
  82 //               |---------------|
  83 //               | return addr** |
  84 //               |---------------|
  85 //       ESP---->|      EBX      |
  86 //               -----------------
  87 //
  88
  89 #undef DVNDLO
  90 #undef DVNDHI
  91 #undef DVSRLO
  92 #undef DVSRHI
  93 #define DVNDLO  [esp + 8]       // stack address of dividend (a)
  94 #define DVNDHI  [esp + 12]      // stack address of dividend (a)
  95 #define DVSRLO  [esp + 16]      // stack address of divisor (b)
  96 #define DVSRHI  [esp + 20]      // stack address of divisor (b)
  97
  98 // Now do the divide.  First look to see if the divisor is less than 4194304K.
  99 // If so, then we can use a simple algorithm with word divides, otherwise
 100 // things get a little more complex.
 101 //
 102
 103         mov     eax,DVSRHI // check to see if divisor < 4194304K
 104         or      eax,eax
 105         jnz     short .L1        // nope, gotta do this the hard way
 106         mov     ecx,DVSRLO // load divisor
 107         mov     eax,DVNDHI // load high word of dividend
 108         xor     edx,edx
 109         div     ecx             // edx <- remainder, eax <- quotient
 110         mov     eax,DVNDLO // edx:eax <- remainder:lo word of dividend
 111         div     ecx             // edx <- final remainder
 112         mov     eax,edx         // edx:eax <- remainder
 113         xor     edx,edx
 114         jmp     short .L2        // restore stack and return
 115
 116 //
 117 // Here we do it the hard way.  Remember, eax contains DVSRHI
 118 //
 119
 120 .L1:
 121         mov     ecx,eax         // ecx:ebx <- divisor
 122         mov     ebx,DVSRLO
 123         mov     edx,DVNDHI // edx:eax <- dividend
 124         mov     eax,DVNDLO
 125 .L3:
 126         shr     ecx,1           // shift divisor right one bit// hi bit <- 0
 127         rcr     ebx,1
 128         shr     edx,1           // shift dividend right one bit// hi bit <- 0
 129         rcr     eax,1
 130         or      ecx,ecx
 131         jnz     short .L3        // loop until divisor < 4194304K
 132         div     ebx             // now divide, ignore remainder
 133
 134 //
 135 // We may be off by one, so to check, we will multiply the quotient
 136 // by the divisor and check the result against the orignal dividend
 137 // Note that we must also check for overflow, which can occur if the
 138 // dividend is close to 2**64 and the quotient is off by 1.
 139 //
 140
 141         mov     ecx,eax         // save a copy of quotient in ECX
 142         mul     dword ptr DVSRHI
 143         xchg    ecx,eax         // put partial product in ECX, get quotient in EAX
 144         mul     dword ptr DVSRLO
 145         add     edx,ecx         // EDX:EAX = QUOT * DVSR
 146         jc      short .L4        // carry means Quotient is off by 1
 147
 148 //
 149 // do long compare here between original dividend and the result of the
 150 // multiply in edx:eax.  If original is larger or equal, we're ok, otherwise
 151 // subtract the original divisor from the result.
 152 //
 153
 154         cmp     edx,DVNDHI // compare hi words of result and original
 155         ja      short .L4        // if result > original, do subtract
 156         jb      short .L5        // if result < original, we're ok
 157         cmp     eax,DVNDLO // hi words are equal, compare lo words
 158         jbe     short .L5        // if less or equal we're ok, else subtract
 159 .L4:
 160         sub     eax,DVSRLO // subtract divisor from result
 161         sbb     edx,DVSRHI
 162 .L5:
 163
 164 //
 165 // Calculate remainder by subtracting the result from the original dividend.
 166 // Since the result is already in a register, we will perform the subtract in
 167 // the opposite direction and negate the result to make it positive.
 168 //
 169
 170         sub     eax,DVNDLO // subtract original dividend from result
 171         sbb     edx,DVNDHI
 172         neg     edx             // and negate it
 173         neg     eax
 174         sbb     edx,0
 175
 176 //
 177 // Just the cleanup left to do.  dx:ax contains the remainder.
 178 // Restore the saved registers and return.
 179 //
 180
 181 .L2:
 182
 183         pop     ebx
 184
 185         ret     16
 186
 187 END