llvm/test/CodeGen/CellSPU/dp_farith.ll
Dan Gohman ae3a0be92e Split the Add, Sub, and Mul instruction opcodes into separate
integer and floating-point opcodes, introducing
FAdd, FSub, and FMul.

For now, the AsmParser, BitcodeReader, and IRBuilder all preserve
backwards compatability, and the Core LLVM APIs preserve backwards
compatibility for IR producers. Most front-ends won't need to change
immediately.

This implements the first step of the plan outlined here:
http://nondot.org/sabre/LLVMNotes/IntegerOverflow.txt


git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@72897 91177308-0d34-0410-b5e6-96231b3b80d8
2009-06-04 22:49:04 +00:00

103 lines
3.3 KiB
LLVM

; RUN: llvm-as -o - %s | llc -march=cellspu > %t1.s
; RUN: grep dfa %t1.s | count 2
; RUN: grep dfs %t1.s | count 2
; RUN: grep dfm %t1.s | count 6
; RUN: grep dfma %t1.s | count 2
; RUN: grep dfms %t1.s | count 2
; RUN: grep dfnms %t1.s | count 4
;
; This file includes double precision floating point arithmetic instructions
target datalayout = "E-p:32:32:128-f64:64:128-f32:32:128-i64:32:128-i32:32:128-i16:16:128-i8:8:128-i1:8:128-a0:0:128-v128:128:128-s0:128:128"
target triple = "spu"
define double @fadd(double %arg1, double %arg2) {
%A = fadd double %arg1, %arg2
ret double %A
}
define <2 x double> @fadd_vec(<2 x double> %arg1, <2 x double> %arg2) {
%A = fadd <2 x double> %arg1, %arg2
ret <2 x double> %A
}
define double @fsub(double %arg1, double %arg2) {
%A = fsub double %arg1, %arg2
ret double %A
}
define <2 x double> @fsub_vec(<2 x double> %arg1, <2 x double> %arg2) {
%A = fsub <2 x double> %arg1, %arg2
ret <2 x double> %A
}
define double @fmul(double %arg1, double %arg2) {
%A = fmul double %arg1, %arg2
ret double %A
}
define <2 x double> @fmul_vec(<2 x double> %arg1, <2 x double> %arg2) {
%A = fmul <2 x double> %arg1, %arg2
ret <2 x double> %A
}
define double @fma(double %arg1, double %arg2, double %arg3) {
%A = fmul double %arg1, %arg2
%B = fadd double %A, %arg3
ret double %B
}
define <2 x double> @fma_vec(<2 x double> %arg1, <2 x double> %arg2, <2 x double> %arg3) {
%A = fmul <2 x double> %arg1, %arg2
%B = fadd <2 x double> %A, %arg3
ret <2 x double> %B
}
define double @fms(double %arg1, double %arg2, double %arg3) {
%A = fmul double %arg1, %arg2
%B = fsub double %A, %arg3
ret double %B
}
define <2 x double> @fms_vec(<2 x double> %arg1, <2 x double> %arg2, <2 x double> %arg3) {
%A = fmul <2 x double> %arg1, %arg2
%B = fsub <2 x double> %A, %arg3
ret <2 x double> %B
}
; - (a * b - c)
define double @d_fnms_1(double %arg1, double %arg2, double %arg3) {
%A = fmul double %arg1, %arg2
%B = fsub double %A, %arg3
%C = fsub double -0.000000e+00, %B ; <double> [#uses=1]
ret double %C
}
; Annother way of getting fnms
; - ( a * b ) + c => c - (a * b)
define double @d_fnms_2(double %arg1, double %arg2, double %arg3) {
%A = fmul double %arg1, %arg2
%B = fsub double %arg3, %A
ret double %B
}
; FNMS: - (a * b - c) => c - (a * b)
define <2 x double> @d_fnms_vec_1(<2 x double> %arg1, <2 x double> %arg2, <2 x double> %arg3) {
%A = fmul <2 x double> %arg1, %arg2
%B = fsub <2 x double> %arg3, %A ;
ret <2 x double> %B
}
; Another way to get fnms using a constant vector
; - ( a * b - c)
define <2 x double> @d_fnms_vec_2(<2 x double> %arg1, <2 x double> %arg2, <2 x double> %arg3) {
%A = fmul <2 x double> %arg1, %arg2 ; <<2 x double>> [#uses=1]
%B = fsub <2 x double> %A, %arg3 ; <<2 x double>> [#uses=1]
%C = fsub <2 x double> < double -0.00000e+00, double -0.00000e+00 >, %B
ret <2 x double> %C
}
;define double @fdiv_1(double %arg1, double %arg2) {
; %A = fdiv double %arg1, %arg2 ; <double> [#uses=1]
; ret double %A
;}