| blob | adc9381631a63ac1d640145bcbc7d21a34ad99fb |
1 ; NOTE: Assertions have been autogenerated by utils/update_test_checks.py
2 ; RUN: opt -S -instcombine < %s | FileCheck %s
4 ; (-0.0 - X) * C => X * -C
5 define float @neg_constant(float %x) {
6 ; CHECK-LABEL: @neg_constant(
7 ; CHECK-NEXT: [[MUL:%.*]] = fmul ninf float [[X:%.*]], -2.000000e+01
8 ; CHECK-NEXT: ret float [[MUL]]
9 ;
10 %sub = fsub float -0.0, %x
11 %mul = fmul ninf float %sub, 2.0e+1
12 ret float %mul
13 }
15 define float @unary_neg_constant(float %x) {
16 ; CHECK-LABEL: @unary_neg_constant(
17 ; CHECK-NEXT: [[MUL:%.*]] = fmul ninf float [[X:%.*]], -2.000000e+01
18 ; CHECK-NEXT: ret float [[MUL]]
19 ;
20 %sub = fneg float %x
21 %mul = fmul ninf float %sub, 2.0e+1
22 ret float %mul
23 }
25 define <2 x float> @neg_constant_vec(<2 x float> %x) {
26 ; CHECK-LABEL: @neg_constant_vec(
27 ; CHECK-NEXT: [[MUL:%.*]] = fmul ninf <2 x float> [[X:%.*]], <float -2.000000e+00, float -3.000000e+00>
28 ; CHECK-NEXT: ret <2 x float> [[MUL]]
29 ;
30 %sub = fsub <2 x float> <float -0.0, float -0.0>, %x
31 %mul = fmul ninf <2 x float> %sub, <float 2.0, float 3.0>
32 ret <2 x float> %mul
33 }
35 define <2 x float> @unary_neg_constant_vec(<2 x float> %x) {
36 ; CHECK-LABEL: @unary_neg_constant_vec(
37 ; CHECK-NEXT: [[MUL:%.*]] = fmul ninf <2 x float> [[X:%.*]], <float -2.000000e+00, float -3.000000e+00>
38 ; CHECK-NEXT: ret <2 x float> [[MUL]]
39 ;
40 %sub = fneg <2 x float> %x
41 %mul = fmul ninf <2 x float> %sub, <float 2.0, float 3.0>
42 ret <2 x float> %mul
43 }
45 define <2 x float> @neg_constant_vec_undef(<2 x float> %x) {
46 ; CHECK-LABEL: @neg_constant_vec_undef(
47 ; CHECK-NEXT: [[MUL:%.*]] = fmul ninf <2 x float> [[X:%.*]], <float -2.000000e+00, float -3.000000e+00>
48 ; CHECK-NEXT: ret <2 x float> [[MUL]]
49 ;
50 %sub = fsub <2 x float> <float undef, float -0.0>, %x
51 %mul = fmul ninf <2 x float> %sub, <float 2.0, float 3.0>
52 ret <2 x float> %mul
53 }
55 ; (0.0 - X) * C => X * -C
56 define float @neg_nsz_constant(float %x) {
57 ; CHECK-LABEL: @neg_nsz_constant(
58 ; CHECK-NEXT: [[MUL:%.*]] = fmul nnan float [[X:%.*]], -2.000000e+01
59 ; CHECK-NEXT: ret float [[MUL]]
60 ;
61 %sub = fsub nsz float 0.0, %x
62 %mul = fmul nnan float %sub, 2.0e+1
63 ret float %mul
64 }
66 define float @unary_neg_nsz_constant(float %x) {
67 ; CHECK-LABEL: @unary_neg_nsz_constant(
68 ; CHECK-NEXT: [[MUL:%.*]] = fmul nnan float [[X:%.*]], -2.000000e+01
69 ; CHECK-NEXT: ret float [[MUL]]
70 ;
71 %sub = fneg nsz float %x
72 %mul = fmul nnan float %sub, 2.0e+1
73 ret float %mul
74 }
76 ; (-0.0 - X) * (-0.0 - Y) => X * Y
77 define float @neg_neg(float %x, float %y) {
78 ; CHECK-LABEL: @neg_neg(
79 ; CHECK-NEXT: [[MUL:%.*]] = fmul arcp float [[X:%.*]], [[Y:%.*]]
80 ; CHECK-NEXT: ret float [[MUL]]
81 ;
82 %sub1 = fsub float -0.0, %x
83 %sub2 = fsub float -0.0, %y
84 %mul = fmul arcp float %sub1, %sub2
85 ret float %mul
86 }
88 define float @unary_neg_unary_neg(float %x, float %y) {
89 ; CHECK-LABEL: @unary_neg_unary_neg(
90 ; CHECK-NEXT: [[MUL:%.*]] = fmul arcp float [[X:%.*]], [[Y:%.*]]
91 ; CHECK-NEXT: ret float [[MUL]]
92 ;
93 %sub1 = fneg float %x
94 %sub2 = fneg float %y
95 %mul = fmul arcp float %sub1, %sub2
96 ret float %mul
97 }
99 define float @unary_neg_neg(float %x, float %y) {
100 ; CHECK-LABEL: @unary_neg_neg(
101 ; CHECK-NEXT: [[MUL:%.*]] = fmul arcp float [[X:%.*]], [[Y:%.*]]
102 ; CHECK-NEXT: ret float [[MUL]]
103 ;
104 %sub1 = fneg float %x
105 %sub2 = fsub float -0.0, %y
106 %mul = fmul arcp float %sub1, %sub2
107 ret float %mul
108 }
110 define float @neg_unary_neg(float %x, float %y) {
111 ; CHECK-LABEL: @neg_unary_neg(
112 ; CHECK-NEXT: [[MUL:%.*]] = fmul arcp float [[X:%.*]], [[Y:%.*]]
113 ; CHECK-NEXT: ret float [[MUL]]
114 ;
115 %sub1 = fsub float -0.0, %x
116 %sub2 = fneg float %y
117 %mul = fmul arcp float %sub1, %sub2
118 ret float %mul
119 }
121 define <2 x float> @neg_neg_vec(<2 x float> %x, <2 x float> %y) {
122 ; CHECK-LABEL: @neg_neg_vec(
123 ; CHECK-NEXT: [[MUL:%.*]] = fmul arcp <2 x float> [[X:%.*]], [[Y:%.*]]
124 ; CHECK-NEXT: ret <2 x float> [[MUL]]
125 ;
126 %sub1 = fsub <2 x float> <float -0.0, float -0.0>, %x
127 %sub2 = fsub <2 x float> <float -0.0, float -0.0>, %y
128 %mul = fmul arcp <2 x float> %sub1, %sub2
129 ret <2 x float> %mul
130 }
132 define <2 x float> @unary_neg_unary_neg_vec(<2 x float> %x, <2 x float> %y) {
133 ; CHECK-LABEL: @unary_neg_unary_neg_vec(
134 ; CHECK-NEXT: [[MUL:%.*]] = fmul arcp <2 x float> [[X:%.*]], [[Y:%.*]]
135 ; CHECK-NEXT: ret <2 x float> [[MUL]]
136 ;
137 %sub1 = fneg <2 x float> %x
138 %sub2 = fneg <2 x float> %y
139 %mul = fmul arcp <2 x float> %sub1, %sub2
140 ret <2 x float> %mul
141 }
143 define <2 x float> @unary_neg_neg_vec(<2 x float> %x, <2 x float> %y) {
144 ; CHECK-LABEL: @unary_neg_neg_vec(
145 ; CHECK-NEXT: [[MUL:%.*]] = fmul arcp <2 x float> [[X:%.*]], [[Y:%.*]]
146 ; CHECK-NEXT: ret <2 x float> [[MUL]]
147 ;
148 %sub1 = fneg <2 x float> %x
149 %sub2 = fsub <2 x float> <float -0.0, float -0.0>, %y
150 %mul = fmul arcp <2 x float> %sub1, %sub2
151 ret <2 x float> %mul
152 }
154 define <2 x float> @neg_unary_neg_vec(<2 x float> %x, <2 x float> %y) {
155 ; CHECK-LABEL: @neg_unary_neg_vec(
156 ; CHECK-NEXT: [[MUL:%.*]] = fmul arcp <2 x float> [[X:%.*]], [[Y:%.*]]
157 ; CHECK-NEXT: ret <2 x float> [[MUL]]
158 ;
159 %sub1 = fsub <2 x float> <float -0.0, float -0.0>, %x
160 %sub2 = fneg <2 x float> %y
161 %mul = fmul arcp <2 x float> %sub1, %sub2
162 ret <2 x float> %mul
163 }
165 define <2 x float> @neg_neg_vec_undef(<2 x float> %x, <2 x float> %y) {
166 ; CHECK-LABEL: @neg_neg_vec_undef(
167 ; CHECK-NEXT: [[MUL:%.*]] = fmul arcp <2 x float> [[X:%.*]], [[Y:%.*]]
168 ; CHECK-NEXT: ret <2 x float> [[MUL]]
169 ;
170 %sub1 = fsub <2 x float> <float -0.0, float undef>, %x
171 %sub2 = fsub <2 x float> <float undef, float -0.0>, %y
172 %mul = fmul arcp <2 x float> %sub1, %sub2
173 ret <2 x float> %mul
174 }
176 define <2 x float> @unary_neg_neg_vec_undef(<2 x float> %x, <2 x float> %y) {
177 ; CHECK-LABEL: @unary_neg_neg_vec_undef(
178 ; CHECK-NEXT: [[MUL:%.*]] = fmul arcp <2 x float> [[X:%.*]], [[Y:%.*]]
179 ; CHECK-NEXT: ret <2 x float> [[MUL]]
180 ;
181 %neg = fneg <2 x float> %x
182 %sub = fsub <2 x float> <float undef, float -0.0>, %y
183 %mul = fmul arcp <2 x float> %neg, %sub
184 ret <2 x float> %mul
185 }
187 define <2 x float> @neg_unary_neg_vec_undef(<2 x float> %x, <2 x float> %y) {
188 ; CHECK-LABEL: @neg_unary_neg_vec_undef(
189 ; CHECK-NEXT: [[MUL:%.*]] = fmul arcp <2 x float> [[X:%.*]], [[Y:%.*]]
190 ; CHECK-NEXT: ret <2 x float> [[MUL]]
191 ;
192 %sub = fsub <2 x float> <float -0.0, float undef>, %x
193 %neg = fneg <2 x float> %y
194 %mul = fmul arcp <2 x float> %sub, %neg
195 ret <2 x float> %mul
196 }
198 ; (0.0 - X) * (0.0 - Y) => X * Y
199 define float @neg_neg_nsz(float %x, float %y) {
200 ; CHECK-LABEL: @neg_neg_nsz(
201 ; CHECK-NEXT: [[MUL:%.*]] = fmul afn float [[X:%.*]], [[Y:%.*]]
202 ; CHECK-NEXT: ret float [[MUL]]
203 ;
204 %sub1 = fsub nsz float 0.0, %x
205 %sub2 = fsub nsz float 0.0, %y
206 %mul = fmul afn float %sub1, %sub2
207 ret float %mul
208 }
210 declare void @use_f32(float)
212 define float @neg_neg_multi_use(float %x, float %y) {
213 ; CHECK-LABEL: @neg_neg_multi_use(
214 ; CHECK-NEXT: [[NX:%.*]] = fsub float -0.000000e+00, [[X:%.*]]
215 ; CHECK-NEXT: [[NY:%.*]] = fsub float -0.000000e+00, [[Y:%.*]]
216 ; CHECK-NEXT: [[MUL:%.*]] = fmul afn float [[X]], [[Y]]
217 ; CHECK-NEXT: call void @use_f32(float [[NX]])
218 ; CHECK-NEXT: call void @use_f32(float [[NY]])
219 ; CHECK-NEXT: ret float [[MUL]]
220 ;
221 %nx = fsub float -0.0, %x
222 %ny = fsub float -0.0, %y
223 %mul = fmul afn float %nx, %ny
224 call void @use_f32(float %nx)
225 call void @use_f32(float %ny)
226 ret float %mul
227 }
229 define float @unary_neg_unary_neg_multi_use(float %x, float %y) {
230 ; CHECK-LABEL: @unary_neg_unary_neg_multi_use(
231 ; CHECK-NEXT: [[NX:%.*]] = fneg float [[X:%.*]]
232 ; CHECK-NEXT: [[NY:%.*]] = fneg float [[Y:%.*]]
233 ; CHECK-NEXT: [[MUL:%.*]] = fmul afn float [[X]], [[Y]]
234 ; CHECK-NEXT: call void @use_f32(float [[NX]])
235 ; CHECK-NEXT: call void @use_f32(float [[NY]])
236 ; CHECK-NEXT: ret float [[MUL]]
237 ;
238 %nx = fneg float %x
239 %ny = fneg float %y
240 %mul = fmul afn float %nx, %ny
241 call void @use_f32(float %nx)
242 call void @use_f32(float %ny)
243 ret float %mul
244 }
246 define float @unary_neg_neg_multi_use(float %x, float %y) {
247 ; CHECK-LABEL: @unary_neg_neg_multi_use(
248 ; CHECK-NEXT: [[NX:%.*]] = fneg float [[X:%.*]]
249 ; CHECK-NEXT: [[NY:%.*]] = fsub float -0.000000e+00, [[Y:%.*]]
250 ; CHECK-NEXT: [[MUL:%.*]] = fmul afn float [[X]], [[Y]]
251 ; CHECK-NEXT: call void @use_f32(float [[NX]])
252 ; CHECK-NEXT: call void @use_f32(float [[NY]])
253 ; CHECK-NEXT: ret float [[MUL]]
254 ;
255 %nx = fneg float %x
256 %ny = fsub float -0.0, %y
257 %mul = fmul afn float %nx, %ny
258 call void @use_f32(float %nx)
259 call void @use_f32(float %ny)
260 ret float %mul
261 }
263 define float @neg_unary_neg_multi_use(float %x, float %y) {
264 ; CHECK-LABEL: @neg_unary_neg_multi_use(
265 ; CHECK-NEXT: [[NX:%.*]] = fsub float -0.000000e+00, [[X:%.*]]
266 ; CHECK-NEXT: [[NY:%.*]] = fneg float [[Y:%.*]]
267 ; CHECK-NEXT: [[MUL:%.*]] = fmul afn float [[X]], [[Y]]
268 ; CHECK-NEXT: call void @use_f32(float [[NX]])
269 ; CHECK-NEXT: call void @use_f32(float [[NY]])
270 ; CHECK-NEXT: ret float [[MUL]]
271 ;
272 %nx = fsub float -0.0, %x
273 %ny = fneg float %y
274 %mul = fmul afn float %nx, %ny
275 call void @use_f32(float %nx)
276 call void @use_f32(float %ny)
277 ret float %mul
278 }
280 ; (-0.0 - X) * Y
281 define float @neg_mul(float %x, float %y) {
282 ; CHECK-LABEL: @neg_mul(
283 ; CHECK-NEXT: [[SUB:%.*]] = fsub float -0.000000e+00, [[X:%.*]]
284 ; CHECK-NEXT: [[MUL:%.*]] = fmul float [[SUB]], [[Y:%.*]]
285 ; CHECK-NEXT: ret float [[MUL]]
286 ;
287 %sub = fsub float -0.0, %x
288 %mul = fmul float %sub, %y
289 ret float %mul
290 }
292 define float @unary_neg_mul(float %x, float %y) {
293 ; CHECK-LABEL: @unary_neg_mul(
294 ; CHECK-NEXT: [[NEG:%.*]] = fneg float [[X:%.*]]
295 ; CHECK-NEXT: [[MUL:%.*]] = fmul float [[NEG]], [[Y:%.*]]
296 ; CHECK-NEXT: ret float [[MUL]]
297 ;
298 %neg = fneg float %x
299 %mul = fmul float %neg, %y
300 ret float %mul
301 }
303 define <2 x float> @neg_mul_vec(<2 x float> %x, <2 x float> %y) {
304 ; CHECK-LABEL: @neg_mul_vec(
305 ; CHECK-NEXT: [[SUB:%.*]] = fsub <2 x float> <float -0.000000e+00, float -0.000000e+00>, [[X:%.*]]
306 ; CHECK-NEXT: [[MUL:%.*]] = fmul <2 x float> [[SUB]], [[Y:%.*]]
307 ; CHECK-NEXT: ret <2 x float> [[MUL]]
308 ;
309 %sub = fsub <2 x float> <float -0.0, float -0.0>, %x
310 %mul = fmul <2 x float> %sub, %y
311 ret <2 x float> %mul
312 }
314 define <2 x float> @unary_neg_mul_vec(<2 x float> %x, <2 x float> %y) {
315 ; CHECK-LABEL: @unary_neg_mul_vec(
316 ; CHECK-NEXT: [[SUB:%.*]] = fneg <2 x float> [[X:%.*]]
317 ; CHECK-NEXT: [[MUL:%.*]] = fmul <2 x float> [[SUB]], [[Y:%.*]]
318 ; CHECK-NEXT: ret <2 x float> [[MUL]]
319 ;
320 %sub = fneg <2 x float> %x
321 %mul = fmul <2 x float> %sub, %y
322 ret <2 x float> %mul
323 }
325 define <2 x float> @neg_mul_vec_undef(<2 x float> %x, <2 x float> %y) {
326 ; CHECK-LABEL: @neg_mul_vec_undef(
327 ; CHECK-NEXT: [[SUB:%.*]] = fsub <2 x float> <float undef, float -0.000000e+00>, [[X:%.*]]
328 ; CHECK-NEXT: [[MUL:%.*]] = fmul <2 x float> [[SUB]], [[Y:%.*]]
329 ; CHECK-NEXT: ret <2 x float> [[MUL]]
330 ;
331 %sub = fsub <2 x float> <float undef, float -0.0>, %x
332 %mul = fmul <2 x float> %sub, %y
333 ret <2 x float> %mul
334 }
336 ; (0.0 - X) * Y
337 define float @neg_sink_nsz(float %x, float %y) {
338 ; CHECK-LABEL: @neg_sink_nsz(
339 ; CHECK-NEXT: [[SUB1:%.*]] = fsub nsz float -0.000000e+00, [[X:%.*]]
340 ; CHECK-NEXT: [[MUL:%.*]] = fmul float [[SUB1]], [[Y:%.*]]
341 ; CHECK-NEXT: ret float [[MUL]]
342 ;
343 %sub1 = fsub nsz float 0.0, %x
344 %mul = fmul float %sub1, %y
345 ret float %mul
346 }
348 define float @neg_sink_multi_use(float %x, float %y) {
349 ; CHECK-LABEL: @neg_sink_multi_use(
350 ; CHECK-NEXT: [[SUB1:%.*]] = fsub float -0.000000e+00, [[X:%.*]]
351 ; CHECK-NEXT: [[MUL:%.*]] = fmul float [[SUB1]], [[Y:%.*]]
352 ; CHECK-NEXT: [[MUL2:%.*]] = fmul float [[MUL]], [[SUB1]]
353 ; CHECK-NEXT: ret float [[MUL2]]
354 ;
355 %sub1 = fsub float -0.0, %x
356 %mul = fmul float %sub1, %y
357 %mul2 = fmul float %mul, %sub1
358 ret float %mul2
359 }
361 define float @unary_neg_mul_multi_use(float %x, float %y) {
362 ; CHECK-LABEL: @unary_neg_mul_multi_use(
363 ; CHECK-NEXT: [[SUB1:%.*]] = fneg float [[X:%.*]]
364 ; CHECK-NEXT: [[MUL:%.*]] = fmul float [[SUB1]], [[Y:%.*]]
365 ; CHECK-NEXT: [[MUL2:%.*]] = fmul float [[MUL]], [[SUB1]]
366 ; CHECK-NEXT: ret float [[MUL2]]
367 ;
368 %sub1 = fneg float %x
369 %mul = fmul float %sub1, %y
370 %mul2 = fmul float %mul, %sub1
371 ret float %mul2
372 }
374 ; Don't crash when attempting to cast a constant FMul to an instruction.
375 define void @test8(i32* %inout) {
376 ; CHECK-LABEL: @test8(
377 ; CHECK-NEXT: entry:
378 ; CHECK-NEXT: br label [[FOR_COND:%.*]]
379 ; CHECK: for.cond:
380 ; CHECK-NEXT: [[LOCAL_VAR_7_0:%.*]] = phi <4 x float> [ <float -0.000000e+00, float -0.000000e+00, float -0.000000e+00, float -0.000000e+00>, [[ENTRY:%.*]] ], [ [[TMP0:%.*]], [[FOR_BODY:%.*]] ]
381 ; CHECK-NEXT: br i1 undef, label [[FOR_BODY]], label [[FOR_END:%.*]]
382 ; CHECK: for.body:
383 ; CHECK-NEXT: [[TMP0]] = insertelement <4 x float> [[LOCAL_VAR_7_0]], float 0.000000e+00, i32 2
384 ; CHECK-NEXT: br label [[FOR_COND]]
385 ; CHECK: for.end:
386 ; CHECK-NEXT: ret void
387 ;
388 entry:
389 %0 = load i32, i32* %inout, align 4
390 %conv = uitofp i32 %0 to float
391 %vecinit = insertelement <4 x float> <float 0.000000e+00, float 0.000000e+00, float 0.000000e+00, float undef>, float %conv, i32 3
392 %sub = fsub <4 x float> <float -0.000000e+00, float -0.000000e+00, float -0.000000e+00, float -0.000000e+00>, %vecinit
393 %1 = shufflevector <4 x float> %sub, <4 x float> undef, <4 x i32> <i32 1, i32 1, i32 1, i32 1>
394 %mul = fmul <4 x float> zeroinitializer, %1
395 br label %for.cond
397 for.cond: ; preds = %for.body, %entry
398 %local_var_7.0 = phi <4 x float> [ %mul, %entry ], [ %2, %for.body ]
399 br i1 undef, label %for.body, label %for.end
401 for.body: ; preds = %for.cond
402 %2 = insertelement <4 x float> %local_var_7.0, float 0.000000e+00, i32 2
403 br label %for.cond
405 for.end: ; preds = %for.cond
406 ret void
407 }
409 ; X * -1.0 => -0.0 - X
410 define float @test9(float %x) {
411 ; CHECK-LABEL: @test9(
412 ; CHECK-NEXT: [[MUL:%.*]] = fsub float -0.000000e+00, [[X:%.*]]
413 ; CHECK-NEXT: ret float [[MUL]]
414 ;
415 %mul = fmul float %x, -1.0
416 ret float %mul
417 }
419 ; PR18532
420 define <4 x float> @test10(<4 x float> %x) {
421 ; CHECK-LABEL: @test10(
422 ; CHECK-NEXT: [[MUL:%.*]] = fsub arcp afn <4 x float> <float -0.000000e+00, float -0.000000e+00, float -0.000000e+00, float -0.000000e+00>, [[X:%.*]]
423 ; CHECK-NEXT: ret <4 x float> [[MUL]]
424 ;
425 %mul = fmul arcp afn <4 x float> %x, <float -1.0, float -1.0, float -1.0, float -1.0>
426 ret <4 x float> %mul
427 }
429 define float @test11(float %x, float %y) {
430 ; CHECK-LABEL: @test11(
431 ; CHECK-NEXT: [[B:%.*]] = fadd fast float [[X:%.*]], [[Y:%.*]]
432 ; CHECK-NEXT: [[C:%.*]] = fadd fast float [[B]], 3.000000e+00
433 ; CHECK-NEXT: ret float [[C]]
434 ;
435 %a = fadd fast float %x, 1.0
436 %b = fadd fast float %y, 2.0
437 %c = fadd fast float %a, %b
438 ret float %c
439 }
441 declare double @llvm.sqrt.f64(double)
443 ; With unsafe/fast math, sqrt(X) * sqrt(X) is just X,
444 ; but make sure another use of the sqrt is intact.
445 ; Note that the remaining fmul is altered but is not 'fast'
446 ; itself because it was not marked 'fast' originally.
447 ; Thus, we have an overall fast result, but no more indication of
448 ; 'fast'ness in the code.
449 define double @sqrt_squared2(double %f) {
450 ; CHECK-LABEL: @sqrt_squared2(
451 ; CHECK-NEXT: [[SQRT:%.*]] = call double @llvm.sqrt.f64(double [[F:%.*]])
452 ; CHECK-NEXT: [[MUL2:%.*]] = fmul double [[SQRT]], [[F]]
453 ; CHECK-NEXT: ret double [[MUL2]]
454 ;
455 %sqrt = call double @llvm.sqrt.f64(double %f)
456 %mul1 = fmul fast double %sqrt, %sqrt
457 %mul2 = fmul double %mul1, %sqrt
458 ret double %mul2
459 }
461 declare float @llvm.fabs.f32(float) nounwind readnone
463 define float @fabs_squared(float %x) {
464 ; CHECK-LABEL: @fabs_squared(
465 ; CHECK-NEXT: [[MUL:%.*]] = fmul float [[X:%.*]], [[X]]
466 ; CHECK-NEXT: ret float [[MUL]]
467 ;
468 %x.fabs = call float @llvm.fabs.f32(float %x)
469 %mul = fmul float %x.fabs, %x.fabs
470 ret float %mul
471 }
473 define float @fabs_squared_fast(float %x) {
474 ; CHECK-LABEL: @fabs_squared_fast(
475 ; CHECK-NEXT: [[MUL:%.*]] = fmul fast float [[X:%.*]], [[X]]
476 ; CHECK-NEXT: ret float [[MUL]]
477 ;
478 %x.fabs = call float @llvm.fabs.f32(float %x)
479 %mul = fmul fast float %x.fabs, %x.fabs
480 ret float %mul
481 }
483 define float @fabs_x_fabs(float %x, float %y) {
484 ; CHECK-LABEL: @fabs_x_fabs(
485 ; CHECK-NEXT: [[X_FABS:%.*]] = call float @llvm.fabs.f32(float [[X:%.*]])
486 ; CHECK-NEXT: [[Y_FABS:%.*]] = call float @llvm.fabs.f32(float [[Y:%.*]])
487 ; CHECK-NEXT: [[MUL:%.*]] = fmul float [[X_FABS]], [[Y_FABS]]
488 ; CHECK-NEXT: ret float [[MUL]]
489 ;
490 %x.fabs = call float @llvm.fabs.f32(float %x)
491 %y.fabs = call float @llvm.fabs.f32(float %y)
492 %mul = fmul float %x.fabs, %y.fabs
493 ret float %mul
494 }
496 ; (X*Y) * X => (X*X) * Y
497 ; The transform only requires 'reassoc', but test other FMF in
498 ; the commuted variants to make sure FMF propagates as expected.
500 define float @reassoc_common_operand1(float %x, float %y) {
501 ; CHECK-LABEL: @reassoc_common_operand1(
502 ; CHECK-NEXT: [[TMP1:%.*]] = fmul reassoc float [[X:%.*]], [[X]]
503 ; CHECK-NEXT: [[MUL2:%.*]] = fmul reassoc float [[TMP1]], [[Y:%.*]]
504 ; CHECK-NEXT: ret float [[MUL2]]
505 ;
506 %mul1 = fmul float %x, %y
507 %mul2 = fmul reassoc float %mul1, %x
508 ret float %mul2
509 }
511 ; (Y*X) * X => (X*X) * Y
513 define float @reassoc_common_operand2(float %x, float %y) {
514 ; CHECK-LABEL: @reassoc_common_operand2(
515 ; CHECK-NEXT: [[TMP1:%.*]] = fmul fast float [[X:%.*]], [[X]]
516 ; CHECK-NEXT: [[MUL2:%.*]] = fmul fast float [[TMP1]], [[Y:%.*]]
517 ; CHECK-NEXT: ret float [[MUL2]]
518 ;
519 %mul1 = fmul float %y, %x
520 %mul2 = fmul fast float %mul1, %x
521 ret float %mul2
522 }
524 ; X * (X*Y) => (X*X) * Y
526 define float @reassoc_common_operand3(float %x1, float %y) {
527 ; CHECK-LABEL: @reassoc_common_operand3(
528 ; CHECK-NEXT: [[X:%.*]] = fdiv float [[X1:%.*]], 3.000000e+00
529 ; CHECK-NEXT: [[TMP1:%.*]] = fmul reassoc nnan float [[X]], [[X]]
530 ; CHECK-NEXT: [[MUL2:%.*]] = fmul reassoc nnan float [[TMP1]], [[Y:%.*]]
531 ; CHECK-NEXT: ret float [[MUL2]]
532 ;
533 %x = fdiv float %x1, 3.0 ; thwart complexity-based canonicalization
534 %mul1 = fmul float %x, %y
535 %mul2 = fmul reassoc nnan float %x, %mul1
536 ret float %mul2
537 }
539 ; X * (Y*X) => (X*X) * Y
541 define float @reassoc_common_operand4(float %x1, float %y) {
542 ; CHECK-LABEL: @reassoc_common_operand4(
543 ; CHECK-NEXT: [[X:%.*]] = fdiv float [[X1:%.*]], 3.000000e+00
544 ; CHECK-NEXT: [[TMP1:%.*]] = fmul reassoc ninf float [[X]], [[X]]
545 ; CHECK-NEXT: [[MUL2:%.*]] = fmul reassoc ninf float [[TMP1]], [[Y:%.*]]
546 ; CHECK-NEXT: ret float [[MUL2]]
547 ;
548 %x = fdiv float %x1, 3.0 ; thwart complexity-based canonicalization
549 %mul1 = fmul float %y, %x
550 %mul2 = fmul reassoc ninf float %x, %mul1
551 ret float %mul2
552 }
554 ; No change if the first fmul has another use.
556 define float @reassoc_common_operand_multi_use(float %x, float %y) {
557 ; CHECK-LABEL: @reassoc_common_operand_multi_use(
558 ; CHECK-NEXT: [[MUL1:%.*]] = fmul float [[X:%.*]], [[Y:%.*]]
559 ; CHECK-NEXT: [[MUL2:%.*]] = fmul fast float [[MUL1]], [[X]]
560 ; CHECK-NEXT: call void @use_f32(float [[MUL1]])
561 ; CHECK-NEXT: ret float [[MUL2]]
562 ;
563 %mul1 = fmul float %x, %y
564 %mul2 = fmul fast float %mul1, %x
565 call void @use_f32(float %mul1)
566 ret float %mul2
567 }
569 declare float @llvm.log2.f32(float)
571 ; log2(Y * 0.5) * X = log2(Y) * X - X
573 define float @log2half(float %x, float %y) {
574 ; CHECK-LABEL: @log2half(
575 ; CHECK-NEXT: [[LOG2:%.*]] = call fast float @llvm.log2.f32(float [[Y:%.*]])
576 ; CHECK-NEXT: [[TMP1:%.*]] = fmul fast float [[LOG2]], [[X:%.*]]
577 ; CHECK-NEXT: [[MUL:%.*]] = fsub fast float [[TMP1]], [[X]]
578 ; CHECK-NEXT: ret float [[MUL]]
579 ;
580 %halfy = fmul float %y, 0.5
581 %log2 = call float @llvm.log2.f32(float %halfy)
582 %mul = fmul fast float %log2, %x
583 ret float %mul
584 }
586 define float @log2half_commute(float %x1, float %y) {
587 ; CHECK-LABEL: @log2half_commute(
588 ; CHECK-NEXT: [[LOG2:%.*]] = call fast float @llvm.log2.f32(float [[Y:%.*]])
589 ; CHECK-NEXT: [[TMP1:%.*]] = fmul fast float [[LOG2]], [[X1:%.*]]
590 ; CHECK-NEXT: [[TMP2:%.*]] = fsub fast float [[TMP1]], [[X1]]
591 ; CHECK-NEXT: [[MUL:%.*]] = fmul fast float [[TMP2]], 0x3FC24924A0000000
592 ; CHECK-NEXT: ret float [[MUL]]
593 ;
594 %x = fdiv float %x1, 7.0 ; thwart complexity-based canonicalization
595 %halfy = fmul float %y, 0.5
596 %log2 = call float @llvm.log2.f32(float %halfy)
597 %mul = fmul fast float %x, %log2
598 ret float %mul
599 }
601 ; C1/X * C2 => (C1*C2) / X
603 define float @fdiv_constant_numerator_fmul(float %x) {
604 ; CHECK-LABEL: @fdiv_constant_numerator_fmul(
605 ; CHECK-NEXT: [[T3:%.*]] = fdiv reassoc float 1.200000e+07, [[X:%.*]]
606 ; CHECK-NEXT: ret float [[T3]]
607 ;
608 %t1 = fdiv float 2.0e+3, %x
609 %t3 = fmul reassoc float %t1, 6.0e+3
610 ret float %t3
611 }
613 ; C1/X * C2 => (C1*C2) / X is disabled if C1/X has multiple uses
615 @fmul2_external = external global float
617 define float @fdiv_constant_numerator_fmul_extra_use(float %x) {
618 ; CHECK-LABEL: @fdiv_constant_numerator_fmul_extra_use(
619 ; CHECK-NEXT: [[DIV:%.*]] = fdiv fast float 1.000000e+00, [[X:%.*]]
620 ; CHECK-NEXT: store float [[DIV]], float* @fmul2_external, align 4
621 ; CHECK-NEXT: [[MUL:%.*]] = fmul fast float [[DIV]], 2.000000e+00
622 ; CHECK-NEXT: ret float [[MUL]]
623 ;
624 %div = fdiv fast float 1.0, %x
625 store float %div, float* @fmul2_external
626 %mul = fmul fast float %div, 2.0
627 ret float %mul
628 }
630 ; X/C1 * C2 => X * (C2/C1) (if C2/C1 is normal FP)
632 define float @fdiv_constant_denominator_fmul(float %x) {
633 ; CHECK-LABEL: @fdiv_constant_denominator_fmul(
634 ; CHECK-NEXT: [[T3:%.*]] = fmul reassoc float [[X:%.*]], 3.000000e+00
635 ; CHECK-NEXT: ret float [[T3]]
636 ;
637 %t1 = fdiv float %x, 2.0e+3
638 %t3 = fmul reassoc float %t1, 6.0e+3
639 ret float %t3
640 }
642 define <4 x float> @fdiv_constant_denominator_fmul_vec(<4 x float> %x) {
643 ; CHECK-LABEL: @fdiv_constant_denominator_fmul_vec(
644 ; CHECK-NEXT: [[T3:%.*]] = fmul reassoc <4 x float> [[X:%.*]], <float 3.000000e+00, float 2.000000e+00, float 1.000000e+00, float 1.000000e+00>
645 ; CHECK-NEXT: ret <4 x float> [[T3]]
646 ;
647 %t1 = fdiv <4 x float> %x, <float 2.0e+3, float 3.0e+3, float 2.0e+3, float 1.0e+3>
648 %t3 = fmul reassoc <4 x float> %t1, <float 6.0e+3, float 6.0e+3, float 2.0e+3, float 1.0e+3>
649 ret <4 x float> %t3
650 }
652 ; Make sure fmul with constant expression doesn't assert.
654 define <4 x float> @fdiv_constant_denominator_fmul_vec_constexpr(<4 x float> %x) {
655 ; CHECK-LABEL: @fdiv_constant_denominator_fmul_vec_constexpr(
656 ; CHECK-NEXT: [[T3:%.*]] = fmul reassoc <4 x float> [[X:%.*]], <float 3.000000e+00, float 2.000000e+00, float 1.000000e+00, float 1.000000e+00>
657 ; CHECK-NEXT: ret <4 x float> [[T3]]
658 ;
659 %constExprMul = bitcast i128 trunc (i160 bitcast (<5 x float> <float 6.0e+3, float 6.0e+3, float 2.0e+3, float 1.0e+3, float undef> to i160) to i128) to <4 x float>
660 %t1 = fdiv <4 x float> %x, <float 2.0e+3, float 3.0e+3, float 2.0e+3, float 1.0e+3>
661 %t3 = fmul reassoc <4 x float> %t1, %constExprMul
662 ret <4 x float> %t3
663 }
665 ; This shows that at least part of instcombine does not check constant
666 ; values to see if it is creating denorms (0x3800000000000000 is a denorm
667 ; for 32-bit float), so protecting against denorms in other parts is
668 ; probably not doing the intended job.
670 define float @fmul_constant_reassociation(float %x) {
671 ; CHECK-LABEL: @fmul_constant_reassociation(
672 ; CHECK-NEXT: [[R:%.*]] = fmul reassoc nsz float [[X:%.*]], 0x3800000000000000
673 ; CHECK-NEXT: ret float [[R]]
674 ;
675 %mul_flt_min = fmul reassoc nsz float %x, 0x3810000000000000
676 %r = fmul reassoc nsz float %mul_flt_min, 0.5
677 ret float %r
678 }
680 ; Canonicalization "X/C1 * C2 => X * (C2/C1)" still applies if C2/C1 is denormal
681 ; (otherwise, we should not have allowed the reassociation in the previous test).
682 ; 0x3810000000000000 == FLT_MIN
684 define float @fdiv_constant_denominator_fmul_denorm(float %x) {
685 ; CHECK-LABEL: @fdiv_constant_denominator_fmul_denorm(
686 ; CHECK-NEXT: [[T3:%.*]] = fmul fast float [[X:%.*]], 0x3760620000000000
687 ; CHECK-NEXT: ret float [[T3]]
688 ;
689 %t1 = fdiv float %x, 2.0e+3
690 %t3 = fmul fast float %t1, 0x3810000000000000
691 ret float %t3
692 }
694 ; X / C1 * C2 => X / (C2/C1) if C1/C2 is abnormal, but C2/C1 is a normal value.
695 ; TODO: We don't convert the fast fdiv to fmul because that would be multiplication
696 ; by a denormal, but we could do better when we know that denormals are not a problem.
698 define float @fdiv_constant_denominator_fmul_denorm_try_harder(float %x) {
699 ; CHECK-LABEL: @fdiv_constant_denominator_fmul_denorm_try_harder(
700 ; CHECK-NEXT: [[T3:%.*]] = fdiv reassoc float [[X:%.*]], 0x47E8000000000000
701 ; CHECK-NEXT: ret float [[T3]]
702 ;
703 %t1 = fdiv float %x, 3.0
704 %t3 = fmul reassoc float %t1, 0x3810000000000000
705 ret float %t3
706 }
708 ; Negative test: we should not have 2 divisions instead of the 1 we started with.
710 define float @fdiv_constant_denominator_fmul_denorm_try_harder_extra_use(float %x) {
711 ; CHECK-LABEL: @fdiv_constant_denominator_fmul_denorm_try_harder_extra_use(
712 ; CHECK-NEXT: [[T1:%.*]] = fdiv float [[X:%.*]], 3.000000e+00
713 ; CHECK-NEXT: [[T3:%.*]] = fmul fast float [[T1]], 0x3810000000000000
714 ; CHECK-NEXT: [[R:%.*]] = fadd float [[T1]], [[T3]]
715 ; CHECK-NEXT: ret float [[R]]
716 ;
717 %t1 = fdiv float %x, 3.0e+0
718 %t3 = fmul fast float %t1, 0x3810000000000000
719 %r = fadd float %t1, %t3
720 ret float %r
721 }
723 ; (X + C1) * C2 --> (X * C2) + C1*C2
725 define float @fmul_fadd_distribute(float %x) {
726 ; CHECK-LABEL: @fmul_fadd_distribute(
727 ; CHECK-NEXT: [[TMP1:%.*]] = fmul reassoc float [[X:%.*]], 3.000000e+00
728 ; CHECK-NEXT: [[T3:%.*]] = fadd reassoc float [[TMP1]], 6.000000e+00
729 ; CHECK-NEXT: ret float [[T3]]
730 ;
731 %t2 = fadd float %x, 2.0
732 %t3 = fmul reassoc float %t2, 3.0
733 ret float %t3
734 }
736 ; (X - C1) * C2 --> (X * C2) - C1*C2
738 define float @fmul_fsub_distribute1(float %x) {
739 ; CHECK-LABEL: @fmul_fsub_distribute1(
740 ; CHECK-NEXT: [[TMP1:%.*]] = fmul reassoc float [[X:%.*]], 3.000000e+00
741 ; CHECK-NEXT: [[T3:%.*]] = fadd reassoc float [[TMP1]], -6.000000e+00
742 ; CHECK-NEXT: ret float [[T3]]
743 ;
744 %t2 = fsub float %x, 2.0
745 %t3 = fmul reassoc float %t2, 3.0
746 ret float %t3
747 }
749 ; (C1 - X) * C2 --> C1*C2 - (X * C2)
751 define float @fmul_fsub_distribute2(float %x) {
752 ; CHECK-LABEL: @fmul_fsub_distribute2(
753 ; CHECK-NEXT: [[TMP1:%.*]] = fmul reassoc float [[X:%.*]], 3.000000e+00
754 ; CHECK-NEXT: [[T3:%.*]] = fsub reassoc float 6.000000e+00, [[TMP1]]
755 ; CHECK-NEXT: ret float [[T3]]
756 ;
757 %t2 = fsub float 2.0, %x
758 %t3 = fmul reassoc float %t2, 3.0
759 ret float %t3
760 }
762 ; FIXME: This should only need 'reassoc'.
763 ; ((X*C1) + C2) * C3 => (X * (C1*C3)) + (C2*C3)
765 define float @fmul_fadd_fmul_distribute(float %x) {
766 ; CHECK-LABEL: @fmul_fadd_fmul_distribute(
767 ; CHECK-NEXT: [[TMP1:%.*]] = fmul fast float [[X:%.*]], 3.000000e+01
768 ; CHECK-NEXT: [[T3:%.*]] = fadd fast float [[TMP1]], 1.000000e+01
769 ; CHECK-NEXT: ret float [[T3]]
770 ;
771 %t1 = fmul float %x, 6.0
772 %t2 = fadd float %t1, 2.0
773 %t3 = fmul fast float %t2, 5.0
774 ret float %t3
775 }
777 define float @fmul_fadd_distribute_extra_use(float %x) {
778 ; CHECK-LABEL: @fmul_fadd_distribute_extra_use(
779 ; CHECK-NEXT: [[T1:%.*]] = fmul float [[X:%.*]], 6.000000e+00
780 ; CHECK-NEXT: [[T2:%.*]] = fadd float [[T1]], 2.000000e+00
781 ; CHECK-NEXT: [[T3:%.*]] = fmul fast float [[T2]], 5.000000e+00
782 ; CHECK-NEXT: call void @use_f32(float [[T2]])
783 ; CHECK-NEXT: ret float [[T3]]
784 ;
785 %t1 = fmul float %x, 6.0
786 %t2 = fadd float %t1, 2.0
787 %t3 = fmul fast float %t2, 5.0
788 call void @use_f32(float %t2)
789 ret float %t3
790 }
792 ; (X/C1 + C2) * C3 => X/(C1/C3) + C2*C3
793 ; 0x10000000000000 = DBL_MIN
794 ; TODO: We don't convert the fast fdiv to fmul because that would be multiplication
795 ; by a denormal, but we could do better when we know that denormals are not a problem.
797 define double @fmul_fadd_fdiv_distribute2(double %x) {
798 ; CHECK-LABEL: @fmul_fadd_fdiv_distribute2(
799 ; CHECK-NEXT: [[TMP1:%.*]] = fdiv reassoc double [[X:%.*]], 0x7FE8000000000000
800 ; CHECK-NEXT: [[T3:%.*]] = fadd reassoc double [[TMP1]], 0x34000000000000
801 ; CHECK-NEXT: ret double [[T3]]
802 ;
803 %t1 = fdiv double %x, 3.0
804 %t2 = fadd double %t1, 5.0
805 %t3 = fmul reassoc double %t2, 0x10000000000000
806 ret double %t3
807 }
809 ; 5.0e-1 * DBL_MIN yields denormal, so "(f1*3.0 + 5.0e-1) * DBL_MIN" cannot
810 ; be simplified into f1 * (3.0*DBL_MIN) + (5.0e-1*DBL_MIN)
812 define double @fmul_fadd_fdiv_distribute3(double %x) {
813 ; CHECK-LABEL: @fmul_fadd_fdiv_distribute3(
814 ; CHECK-NEXT: [[TMP1:%.*]] = fdiv reassoc double [[X:%.*]], 0x7FE8000000000000
815 ; CHECK-NEXT: [[T3:%.*]] = fadd reassoc double [[TMP1]], 0x34000000000000
816 ; CHECK-NEXT: ret double [[T3]]
817 ;
818 %t1 = fdiv double %x, 3.0
819 %t2 = fadd double %t1, 5.0
820 %t3 = fmul reassoc double %t2, 0x10000000000000
821 ret double %t3
822 }
824 ; FIXME: This should only need 'reassoc'.
825 ; (C2 - (X*C1)) * C3 => (C2*C3) - (X * (C1*C3))
827 define float @fmul_fsub_fmul_distribute(float %x) {
828 ; CHECK-LABEL: @fmul_fsub_fmul_distribute(
829 ; CHECK-NEXT: [[TMP1:%.*]] = fmul fast float [[X:%.*]], 3.000000e+01
830 ; CHECK-NEXT: [[T3:%.*]] = fsub fast float 1.000000e+01, [[TMP1]]
831 ; CHECK-NEXT: ret float [[T3]]
832 ;
833 %t1 = fmul float %x, 6.0
834 %t2 = fsub float 2.0, %t1
835 %t3 = fmul fast float %t2, 5.0
836 ret float %t3
837 }
839 define float @fmul_fsub_fmul_distribute_extra_use(float %x) {
840 ; CHECK-LABEL: @fmul_fsub_fmul_distribute_extra_use(
841 ; CHECK-NEXT: [[T1:%.*]] = fmul float [[X:%.*]], 6.000000e+00
842 ; CHECK-NEXT: [[T2:%.*]] = fsub float 2.000000e+00, [[T1]]
843 ; CHECK-NEXT: [[T3:%.*]] = fmul fast float [[T2]], 5.000000e+00
844 ; CHECK-NEXT: call void @use_f32(float [[T2]])
845 ; CHECK-NEXT: ret float [[T3]]
846 ;
847 %t1 = fmul float %x, 6.0
848 %t2 = fsub float 2.0, %t1
849 %t3 = fmul fast float %t2, 5.0
850 call void @use_f32(float %t2)
851 ret float %t3
852 }
854 ; FIXME: This should only need 'reassoc'.
855 ; ((X*C1) - C2) * C3 => (X * (C1*C3)) - C2*C3
857 define float @fmul_fsub_fmul_distribute2(float %x) {
858 ; CHECK-LABEL: @fmul_fsub_fmul_distribute2(
859 ; CHECK-NEXT: [[TMP1:%.*]] = fmul fast float [[X:%.*]], 3.000000e+01
860 ; CHECK-NEXT: [[T3:%.*]] = fadd fast float [[TMP1]], -1.000000e+01
861 ; CHECK-NEXT: ret float [[T3]]
862 ;
863 %t1 = fmul float %x, 6.0
864 %t2 = fsub float %t1, 2.0
865 %t3 = fmul fast float %t2, 5.0
866 ret float %t3
867 }
869 define float @fmul_fsub_fmul_distribute2_extra_use(float %x) {
870 ; CHECK-LABEL: @fmul_fsub_fmul_distribute2_extra_use(
871 ; CHECK-NEXT: [[T1:%.*]] = fmul float [[X:%.*]], 6.000000e+00
872 ; CHECK-NEXT: [[T2:%.*]] = fsub float 2.000000e+00, [[T1]]
873 ; CHECK-NEXT: [[T3:%.*]] = fmul fast float [[T2]], 5.000000e+00
874 ; CHECK-NEXT: call void @use_f32(float [[T2]])
875 ; CHECK-NEXT: ret float [[T3]]
876 ;
877 %t1 = fmul float %x, 6.0
878 %t2 = fsub float 2.0, %t1
879 %t3 = fmul fast float %t2, 5.0
880 call void @use_f32(float %t2)
881 ret float %t3
882 }
884 ; "(X*Y) * X => (X*X) * Y" is disabled if "X*Y" has multiple uses
886 define float @common_factor(float %x, float %y) {
887 ; CHECK-LABEL: @common_factor(
888 ; CHECK-NEXT: [[MUL:%.*]] = fmul float [[X:%.*]], [[Y:%.*]]
889 ; CHECK-NEXT: [[MUL1:%.*]] = fmul fast float [[MUL]], [[X]]
890 ; CHECK-NEXT: [[ADD:%.*]] = fadd float [[MUL1]], [[MUL]]
891 ; CHECK-NEXT: ret float [[ADD]]
892 ;
893 %mul = fmul float %x, %y
894 %mul1 = fmul fast float %mul, %x
895 %add = fadd float %mul1, %mul
896 ret float %add
897 }
899 define double @fmul_fdiv_factor_squared(double %x, double %y) {
900 ; CHECK-LABEL: @fmul_fdiv_factor_squared(
901 ; CHECK-NEXT: [[DIV:%.*]] = fdiv fast double [[X:%.*]], [[Y:%.*]]
902 ; CHECK-NEXT: [[SQUARED:%.*]] = fmul fast double [[DIV]], [[DIV]]
903 ; CHECK-NEXT: ret double [[SQUARED]]
904 ;
905 %div = fdiv fast double %x, %y
906 %squared = fmul fast double %div, %div
907 ret double %squared
908 }
910 define double @fmul_fdivs_factor_common_denominator(double %x, double %y, double %z) {
911 ; CHECK-LABEL: @fmul_fdivs_factor_common_denominator(
912 ; CHECK-NEXT: [[TMP1:%.*]] = fmul fast double [[Y:%.*]], [[X:%.*]]
913 ; CHECK-NEXT: [[TMP2:%.*]] = fmul fast double [[Z:%.*]], [[Z]]
914 ; CHECK-NEXT: [[MUL:%.*]] = fdiv fast double [[TMP1]], [[TMP2]]
915 ; CHECK-NEXT: ret double [[MUL]]
916 ;
917 %div1 = fdiv double %x, %z
918 %div2 = fdiv double %y, %z
919 %mul = fmul fast double %div1, %div2
920 ret double %mul
921 }
923 define double @fmul_fdivs_factor(double %x, double %y, double %z, double %w) {
924 ; CHECK-LABEL: @fmul_fdivs_factor(
925 ; CHECK-NEXT: [[TMP1:%.*]] = fmul reassoc double [[Z:%.*]], [[X:%.*]]
926 ; CHECK-NEXT: [[TMP2:%.*]] = fdiv reassoc double [[TMP1]], [[W:%.*]]
927 ; CHECK-NEXT: [[MUL:%.*]] = fdiv reassoc double [[TMP2]], [[Y:%.*]]
928 ; CHECK-NEXT: ret double [[MUL]]
929 ;
930 %div1 = fdiv double %x, %y
931 %div2 = fdiv double %z, %w
932 %mul = fmul reassoc double %div1, %div2
933 ret double %mul
934 }
936 define double @fmul_fdiv_factor(double %x, double %y, double %z) {
937 ; CHECK-LABEL: @fmul_fdiv_factor(
938 ; CHECK-NEXT: [[TMP1:%.*]] = fmul reassoc double [[X:%.*]], [[Z:%.*]]
939 ; CHECK-NEXT: [[MUL:%.*]] = fdiv reassoc double [[TMP1]], [[Y:%.*]]
940 ; CHECK-NEXT: ret double [[MUL]]
941 ;
942 %div = fdiv double %x, %y
943 %mul = fmul reassoc double %div, %z
944 ret double %mul
945 }
947 define double @fmul_fdiv_factor_constant1(double %x, double %y) {
948 ; CHECK-LABEL: @fmul_fdiv_factor_constant1(
949 ; CHECK-NEXT: [[TMP1:%.*]] = fmul reassoc double [[X:%.*]], 4.200000e+01
950 ; CHECK-NEXT: [[MUL:%.*]] = fdiv reassoc double [[TMP1]], [[Y:%.*]]
951 ; CHECK-NEXT: ret double [[MUL]]
952 ;
953 %div = fdiv double %x, %y
954 %mul = fmul reassoc double %div, 42.0
955 ret double %mul
956 }
958 define <2 x float> @fmul_fdiv_factor_constant2(<2 x float> %x, <2 x float> %y) {
959 ; CHECK-LABEL: @fmul_fdiv_factor_constant2(
960 ; CHECK-NEXT: [[TMP1:%.*]] = fmul reassoc <2 x float> [[X:%.*]], [[Y:%.*]]
961 ; CHECK-NEXT: [[MUL:%.*]] = fdiv reassoc <2 x float> [[TMP1]], <float 4.200000e+01, float 1.200000e+01>
962 ; CHECK-NEXT: ret <2 x float> [[MUL]]
963 ;
964 %div = fdiv <2 x float> %x, <float 42.0, float 12.0>
965 %mul = fmul reassoc <2 x float> %div, %y
966 ret <2 x float> %mul
967 }
969 define float @fmul_fdiv_factor_extra_use(float %x, float %y) {
970 ; CHECK-LABEL: @fmul_fdiv_factor_extra_use(
971 ; CHECK-NEXT: [[DIV:%.*]] = fdiv float [[X:%.*]], 4.200000e+01
972 ; CHECK-NEXT: call void @use_f32(float [[DIV]])
973 ; CHECK-NEXT: [[MUL:%.*]] = fmul reassoc float [[DIV]], [[Y:%.*]]
974 ; CHECK-NEXT: ret float [[MUL]]
975 ;
976 %div = fdiv float %x, 42.0
977 call void @use_f32(float %div)
978 %mul = fmul reassoc float %div, %y
979 ret float %mul
980 }
982 ; Avoid infinite looping by moving negation out of a constant expression.
984 @g = external global {[2 x i8*]}, align 1
986 define double @fmul_negated_constant_expression(double %x) {
987 ; CHECK-LABEL: @fmul_negated_constant_expression(
988 ; CHECK-NEXT: [[R:%.*]] = fmul double [[X:%.*]], fsub (double -0.000000e+00, double bitcast (i64 ptrtoint (i8** getelementptr inbounds ({ [2 x i8*] }, { [2 x i8*] }* @g, i64 0, inrange i32 0, i64 2) to i64) to double))
989 ; CHECK-NEXT: ret double [[R]]
990 ;
991 %r = fmul double %x, fsub (double -0.000000e+00, double bitcast (i64 ptrtoint (i8** getelementptr inbounds ({ [2 x i8*] }, { [2 x i8*] }* @g, i64 0, inrange i32 0, i64 2) to i64) to double))
992 ret double %r
993 }
995 define float @negate_if_true(float %x, i1 %cond) {
996 ; CHECK-LABEL: @negate_if_true(
997 ; CHECK-NEXT: [[TMP1:%.*]] = fneg float [[X:%.*]]
998 ; CHECK-NEXT: [[TMP2:%.*]] = select i1 [[COND:%.*]], float [[TMP1]], float [[X]]
999 ; CHECK-NEXT: ret float [[TMP2]]
1000 ;
1001 %sel = select i1 %cond, float -1.0, float 1.0
1002 %r = fmul float %sel, %x
1003 ret float %r
1004 }
1006 define float @negate_if_false(float %x, i1 %cond) {
1007 ; CHECK-LABEL: @negate_if_false(
1008 ; CHECK-NEXT: [[TMP1:%.*]] = fneg arcp float [[X:%.*]]
1009 ; CHECK-NEXT: [[TMP2:%.*]] = select arcp i1 [[COND:%.*]], float [[X]], float [[TMP1]]
1010 ; CHECK-NEXT: ret float [[TMP2]]
1011 ;
1012 %sel = select i1 %cond, float 1.0, float -1.0
1013 %r = fmul arcp float %sel, %x
1014 ret float %r
1015 }
1017 define <2 x double> @negate_if_true_commute(<2 x double> %px, i1 %cond) {
1018 ; CHECK-LABEL: @negate_if_true_commute(
1019 ; CHECK-NEXT: [[X:%.*]] = fdiv <2 x double> <double 4.200000e+01, double 4.200000e+01>, [[PX:%.*]]
1020 ; CHECK-NEXT: [[TMP1:%.*]] = fneg ninf <2 x double> [[X]]
1021 ; CHECK-NEXT: [[TMP2:%.*]] = select ninf i1 [[COND:%.*]], <2 x double> [[TMP1]], <2 x double> [[X]]
1022 ; CHECK-NEXT: ret <2 x double> [[TMP2]]
1023 ;
1024 %x = fdiv <2 x double> <double 42.0, double 42.0>, %px ; thwart complexity-based canonicalization
1025 %sel = select i1 %cond, <2 x double> <double -1.0, double -1.0>, <2 x double> <double 1.0, double 1.0>
1026 %r = fmul ninf <2 x double> %x, %sel
1027 ret <2 x double> %r
1028 }
1030 define <2 x double> @negate_if_false_commute(<2 x double> %px, <2 x i1> %cond) {
1031 ; CHECK-LABEL: @negate_if_false_commute(
1032 ; CHECK-NEXT: [[X:%.*]] = fdiv <2 x double> <double 4.200000e+01, double 5.100000e+00>, [[PX:%.*]]
1033 ; CHECK-NEXT: [[TMP1:%.*]] = fneg <2 x double> [[X]]
1034 ; CHECK-NEXT: [[TMP2:%.*]] = select <2 x i1> [[COND:%.*]], <2 x double> [[X]], <2 x double> [[TMP1]]
1035 ; CHECK-NEXT: ret <2 x double> [[TMP2]]
1036 ;
1037 %x = fdiv <2 x double> <double 42.0, double 5.1>, %px ; thwart complexity-based canonicalization
1038 %sel = select <2 x i1> %cond, <2 x double> <double 1.0, double 1.0>, <2 x double> <double -1.0, double -1.0>
1039 %r = fmul <2 x double> %x, %sel
1040 ret <2 x double> %r
1041 }
1043 ; Negative test
1045 define float @negate_if_true_extra_use(float %x, i1 %cond) {
1046 ; CHECK-LABEL: @negate_if_true_extra_use(
1047 ; CHECK-NEXT: [[SEL:%.*]] = select i1 [[COND:%.*]], float -1.000000e+00, float 1.000000e+00
1048 ; CHECK-NEXT: call void @use_f32(float [[SEL]])
1049 ; CHECK-NEXT: [[R:%.*]] = fmul float [[SEL]], [[X:%.*]]
1050 ; CHECK-NEXT: ret float [[R]]
1051 ;
1052 %sel = select i1 %cond, float -1.0, float 1.0
1053 call void @use_f32(float %sel)
1054 %r = fmul float %sel, %x
1055 ret float %r
1056 }
1058 ; Negative test
1060 define <2 x double> @negate_if_true_wrong_constant(<2 x double> %px, i1 %cond) {
1061 ; CHECK-LABEL: @negate_if_true_wrong_constant(
1062 ; CHECK-NEXT: [[X:%.*]] = fdiv <2 x double> <double 4.200000e+01, double 4.200000e+01>, [[PX:%.*]]
1063 ; CHECK-NEXT: [[SEL:%.*]] = select i1 [[COND:%.*]], <2 x double> <double -1.000000e+00, double 0.000000e+00>, <2 x double> <double 1.000000e+00, double 1.000000e+00>
1064 ; CHECK-NEXT: [[R:%.*]] = fmul <2 x double> [[X]], [[SEL]]
1065 ; CHECK-NEXT: ret <2 x double> [[R]]
1066 ;
1067 %x = fdiv <2 x double> <double 42.0, double 42.0>, %px ; thwart complexity-based canonicalization
1068 %sel = select i1 %cond, <2 x double> <double -1.0, double 0.0>, <2 x double> <double 1.0, double 1.0>
1069 %r = fmul <2 x double> %x, %sel
1070 ret <2 x double> %r
1071 }
1073 ; X *fast (C ? 1.0 : 0.0) -> C ? X : 0.0
1074 define float @fmul_select(float %x, i1 %c) {
1075 ; CHECK-LABEL: @fmul_select(
1076 ; CHECK-NEXT: [[SEL:%.*]] = select i1 [[C:%.*]], float 1.000000e+00, float 0.000000e+00
1077 ; CHECK-NEXT: [[MUL:%.*]] = fmul fast float [[SEL]], [[X:%.*]]
1078 ; CHECK-NEXT: ret float [[MUL]]
1079 ;
1080 %sel = select i1 %c, float 1.0, float 0.0
1081 %mul = fmul fast float %sel, %x
1082 ret float %mul
1083 }
1085 ; X *fast (C ? 1.0 : 0.0) -> C ? X : 0.0
1086 define <2 x float> @fmul_select_vec(<2 x float> %x, i1 %c) {
1087 ; CHECK-LABEL: @fmul_select_vec(
1088 ; CHECK-NEXT: [[SEL:%.*]] = select i1 [[C:%.*]], <2 x float> <float 1.000000e+00, float 1.000000e+00>, <2 x float> zeroinitializer
1089 ; CHECK-NEXT: [[MUL:%.*]] = fmul fast <2 x float> [[SEL]], [[X:%.*]]
1090 ; CHECK-NEXT: ret <2 x float> [[MUL]]
1091 ;
1092 %sel = select i1 %c, <2 x float> <float 1.0, float 1.0>, <2 x float> zeroinitializer
1093 %mul = fmul fast <2 x float> %sel, %x
1094 ret <2 x float> %mul
1095 }
1097 ; Without fast math flags we can't optimize X * (C ? 1.0 : 0.0) -> C ? X : 0.0
1098 define float @fmul_select_strict(float %x, i1 %c) {
1099 ; CHECK-LABEL: @fmul_select_strict(
1100 ; CHECK-NEXT: [[SEL:%.*]] = select i1 [[C:%.*]], float 1.000000e+00, float 0.000000e+00
1101 ; CHECK-NEXT: [[MUL:%.*]] = fmul float [[SEL]], [[X:%.*]]
1102 ; CHECK-NEXT: ret float [[MUL]]
1103 ;
1104 %sel = select i1 %c, float 1.0, float 0.0
1105 %mul = fmul float %sel, %x
1106 ret float %mul
1107 }
1109 ; sqrt(X) *fast (C ? sqrt(X) : 1.0) -> C ? X : sqrt(X)
1110 define double @fmul_sqrt_select(double %x, i1 %c) {
1111 ; CHECK-LABEL: @fmul_sqrt_select(
1112 ; CHECK-NEXT: [[SQR:%.*]] = call double @llvm.sqrt.f64(double [[X:%.*]])
1113 ; CHECK-NEXT: [[SEL:%.*]] = select i1 [[C:%.*]], double [[SQR]], double 1.000000e+00
1114 ; CHECK-NEXT: [[MUL:%.*]] = fmul fast double [[SQR]], [[SEL]]
1115 ; CHECK-NEXT: ret double [[MUL]]
1116 ;
1117 %sqr = call double @llvm.sqrt.f64(double %x)
1118 %sel = select i1 %c, double %sqr, double 1.0
1119 %mul = fmul fast double %sqr, %sel
1120 ret double %mul
1121 }