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//===-- comparesf2.S - Implement single-precision soft-float comparisons --===// 
// 
//                     The LLVM Compiler Infrastructure 
// 
// This file is dual licensed under the MIT and the University of Illinois Open 
// Source Licenses. See LICENSE.TXT for details. 
// 
//===----------------------------------------------------------------------===// 
// 
// This file implements the following soft-fp_t comparison routines: 
// 
//   __eqsf2   __gesf2   __unordsf2 
//   __lesf2   __gtsf2 
//   __ltsf2 
//   __nesf2 
// 
// The semantics of the routines grouped in each column are identical, so there 
// is a single implementation for each, with multiple names. 
// 
// The routines behave as follows: 
// 
//   __lesf2(a,b) returns -1 if a < b 
//                         0 if a == b 
//                         1 if a > b 
//                         1 if either a or b is NaN 
// 
//   __gesf2(a,b) returns -1 if a < b 
//                         0 if a == b 
//                         1 if a > b 
//                        -1 if either a or b is NaN 
// 
//   __unordsf2(a,b) returns 0 if both a and b are numbers 
//                           1 if either a or b is NaN 
// 
// Note that __lesf2( ) and __gesf2( ) are identical except in their handling of 
// NaN values. 
// 
//===----------------------------------------------------------------------===// 
 
#include "../assembly.h" 
.syntax unified 
 
.p2align 2 
DEFINE_COMPILERRT_FUNCTION(__eqsf2) 
    // Make copies of a and b with the sign bit shifted off the top.  These will 
    // be used to detect zeros and NaNs. 
    mov     r2,         r0, lsl #1 
    mov     r3,         r1, lsl #1 
 
    // We do the comparison in three stages (ignoring NaN values for the time 
    // being).  First, we orr the absolute values of a and b; this sets the Z 
    // flag if both a and b are zero (of either sign).  The shift of r3 doesn't 
    // effect this at all, but it *does* make sure that the C flag is clear for 
    // the subsequent operations. 
    orrs    r12,    r2, r3, lsr #1 
 
    // Next, we check if a and b have the same or different signs.  If they have 
    // opposite signs, this eor will set the N flag. 
    it ne 
    eorsne  r12,    r0, r1 
 
    // If a and b are equal (either both zeros or bit identical; again, we're 
    // ignoring NaNs for now), this subtract will zero out r0.  If they have the 
    // same sign, the flags are updated as they would be for a comparison of the 
    // absolute values of a and b. 
    it pl 
    subspl  r0,     r2, r3 
 
    // If a is smaller in magnitude than b and both have the same sign, place 
    // the negation of the sign of b in r0.  Thus, if both are negative and 
    // a > b, this sets r0 to 0; if both are positive and a < b, this sets 
    // r0 to -1. 
    // 
    // This is also done if a and b have opposite signs and are not both zero, 
    // because in that case the subtract was not performed and the C flag is 
    // still clear from the shift argument in orrs; if a is positive and b 
    // negative, this places 0 in r0; if a is negative and b positive, -1 is 
    // placed in r0. 
    it lo 
    mvnlo   r0,         r1, asr #31 
 
    // If a is greater in magnitude than b and both have the same sign, place 
    // the sign of b in r0.  Thus, if both are negative and a < b, -1 is placed 
    // in r0, which is the desired result.  Conversely, if both are positive 
    // and a > b, zero is placed in r0. 
    it hi 
    movhi   r0,         r1, asr #31 
 
    // If you've been keeping track, at this point r0 contains -1 if a < b and 
    // 0 if a >= b.  All that remains to be done is to set it to 1 if a > b. 
    // If a == b, then the Z flag is set, so we can get the correct final value 
    // into r0 by simply or'ing with 1 if Z is clear. 
    it ne 
    orrne   r0,     r0, #1 
 
    // Finally, we need to deal with NaNs.  If either argument is NaN, replace 
    // the value in r0 with 1. 
    cmp     r2,         #0xff000000 
    ite ls 
    cmpls   r3,         #0xff000000 
    movhi   r0,         #1 
    JMP(lr) 
END_COMPILERRT_FUNCTION(__eqsf2) 
DEFINE_COMPILERRT_FUNCTION_ALIAS(__lesf2, __eqsf2) 
DEFINE_COMPILERRT_FUNCTION_ALIAS(__ltsf2, __eqsf2) 
DEFINE_COMPILERRT_FUNCTION_ALIAS(__nesf2, __eqsf2) 
 
.p2align 2 
DEFINE_COMPILERRT_FUNCTION(__gtsf2) 
    // Identical to the preceding except in that we return -1 for NaN values. 
    // Given that the two paths share so much code, one might be tempted to  
    // unify them; however, the extra code needed to do so makes the code size 
    // to performance tradeoff very hard to justify for such small functions. 
    mov     r2,         r0, lsl #1 
    mov     r3,         r1, lsl #1 
    orrs    r12,    r2, r3, lsr #1 
    it ne 
    eorsne  r12,    r0, r1 
    it pl 
    subspl  r0,     r2, r3 
    it lo 
    mvnlo   r0,         r1, asr #31 
    it hi 
    movhi   r0,         r1, asr #31 
    it ne 
    orrne   r0,     r0, #1 
    cmp     r2,         #0xff000000 
    ite ls 
    cmpls   r3,         #0xff000000 
    movhi   r0,         #-1 
    JMP(lr) 
END_COMPILERRT_FUNCTION(__gtsf2) 
DEFINE_COMPILERRT_FUNCTION_ALIAS(__gesf2, __gtsf2) 
 
.p2align 2 
DEFINE_COMPILERRT_FUNCTION(__unordsf2) 
    // Return 1 for NaN values, 0 otherwise. 
    mov     r2,         r0, lsl #1 
    mov     r3,         r1, lsl #1 
    mov     r0,         #0 
    cmp     r2,         #0xff000000 
    ite ls 
    cmpls   r3,         #0xff000000 
    movhi   r0,         #1 
    JMP(lr) 
END_COMPILERRT_FUNCTION(__unordsf2) 
 
DEFINE_AEABI_FUNCTION_ALIAS(__aeabi_fcmpun, __unordsf2)