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gerrit-public.fairphone.software / platform / external / llvm / 9de5d0dd42463f61c4ee2f9db5f3d08153c0dacf / . / test / CodeGen / CellSPU / shift_ops.ll
blob: 4256d91fdb3c2b26e1b48c544b84e56310995078 [file] [log] [blame]
Scott Michel0a92af42007-12-19 20:50:49 +0000[diff] [blame]1; RUN: llvm-as -o - %s | llc -march=cellspu > %t1.s
2; RUN: grep shlh %t1.s | count 84
3; RUN: grep shlhi %t1.s | count 51
4; RUN: grep shl %t1.s | count 168
5; RUN: grep shli %t1.s | count 51
6; RUN: grep xshw %t1.s | count 5
7; RUN: grep and %t1.s | count 5
Scott Michel9de5d0d2008-01-11 02:53:15 +0000[diff] [blame^]8target 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"
9target triple = "spu"
Scott Michel0a92af42007-12-19 20:50:49 +0000[diff] [blame]10
11; Vector shifts are not currently supported in gcc or llvm assembly. These are
12; not tested.
13
14; Shift left i16 via register, note that the second operand to shl is promoted
15; to a 32-bit type:
16
17define i16 @shlh_i16_1(i16 %arg1, i16 %arg2) {
18 %A = shl i16 %arg1, %arg2
19 ret i16 %A
20}
21
22define i16 @shlh_i16_2(i16 %arg1, i16 %arg2) {
23 %A = shl i16 %arg2, %arg1
24 ret i16 %A
25}
26
27define i16 @shlh_i16_3(i16 signext %arg1, i16 signext %arg2) signext {
28 %A = shl i16 %arg1, %arg2
29 ret i16 %A
30}
31
32define i16 @shlh_i16_4(i16 signext %arg1, i16 signext %arg2) signext {
33 %A = shl i16 %arg2, %arg1
34 ret i16 %A
35}
36
37define i16 @shlh_i16_5(i16 zeroext %arg1, i16 zeroext %arg2) zeroext {
38 %A = shl i16 %arg1, %arg2
39 ret i16 %A
40}
41
42define i16 @shlh_i16_6(i16 zeroext %arg1, i16 zeroext %arg2) zeroext {
43 %A = shl i16 %arg2, %arg1
44 ret i16 %A
45}
46
47; Shift left i16 with immediate:
48define i16 @shlhi_i16_1(i16 %arg1) {
49 %A = shl i16 %arg1, 12
50 ret i16 %A
51}
52
53; Should not generate anything other than the return, arg1 << 0 = arg1
54define i16 @shlhi_i16_2(i16 %arg1) {
55 %A = shl i16 %arg1, 0
56 ret i16 %A
57}
58
59define i16 @shlhi_i16_3(i16 %arg1) {
60 %A = shl i16 16383, %arg1
61 ret i16 %A
62}
63
64; Should generate 0, 0 << arg1 = 0
65define i16 @shlhi_i16_4(i16 %arg1) {
66 %A = shl i16 0, %arg1
67 ret i16 %A
68}
69
70define i16 @shlhi_i16_5(i16 signext %arg1) signext {
71 %A = shl i16 %arg1, 12
72 ret i16 %A
73}
74
75; Should not generate anything other than the return, arg1 << 0 = arg1
76define i16 @shlhi_i16_6(i16 signext %arg1) signext {
77 %A = shl i16 %arg1, 0
78 ret i16 %A
79}
80
81define i16 @shlhi_i16_7(i16 signext %arg1) signext {
82 %A = shl i16 16383, %arg1
83 ret i16 %A
84}
85
86; Should generate 0, 0 << arg1 = 0
87define i16 @shlhi_i16_8(i16 signext %arg1) signext {
88 %A = shl i16 0, %arg1
89 ret i16 %A
90}
91
92define i16 @shlhi_i16_9(i16 zeroext %arg1) zeroext {
93 %A = shl i16 %arg1, 12
94 ret i16 %A
95}
96
97; Should not generate anything other than the return, arg1 << 0 = arg1
98define i16 @shlhi_i16_10(i16 zeroext %arg1) zeroext {
99 %A = shl i16 %arg1, 0
100 ret i16 %A
101}
102
103define i16 @shlhi_i16_11(i16 zeroext %arg1) zeroext {
104 %A = shl i16 16383, %arg1
105 ret i16 %A
106}
107
108; Should generate 0, 0 << arg1 = 0
109define i16 @shlhi_i16_12(i16 zeroext %arg1) zeroext {
110 %A = shl i16 0, %arg1
111 ret i16 %A
112}
113
114; Shift left i32 via register, note that the second operand to shl is promoted
115; to a 32-bit type:
116
117define i32 @shl_i32_1(i32 %arg1, i32 %arg2) {
118 %A = shl i32 %arg1, %arg2
119 ret i32 %A
120}
121
122define i32 @shl_i32_2(i32 %arg1, i32 %arg2) {
123 %A = shl i32 %arg2, %arg1
124 ret i32 %A
125}
126
127define i32 @shl_i32_3(i32 signext %arg1, i32 signext %arg2) signext {
128 %A = shl i32 %arg1, %arg2
129 ret i32 %A
130}
131
132define i32 @shl_i32_4(i32 signext %arg1, i32 signext %arg2) signext {
133 %A = shl i32 %arg2, %arg1
134 ret i32 %A
135}
136
137define i32 @shl_i32_5(i32 zeroext %arg1, i32 zeroext %arg2) zeroext {
138 %A = shl i32 %arg1, %arg2
139 ret i32 %A
140}
141
142define i32 @shl_i32_6(i32 zeroext %arg1, i32 zeroext %arg2) zeroext {
143 %A = shl i32 %arg2, %arg1
144 ret i32 %A
145}
146
147; Shift left i32 with immediate:
148define i32 @shli_i32_1(i32 %arg1) {
149 %A = shl i32 %arg1, 12
150 ret i32 %A
151}
152
153; Should not generate anything other than the return, arg1 << 0 = arg1
154define i32 @shli_i32_2(i32 %arg1) {
155 %A = shl i32 %arg1, 0
156 ret i32 %A
157}
158
159define i32 @shli_i32_3(i32 %arg1) {
160 %A = shl i32 16383, %arg1
161 ret i32 %A
162}
163
164; Should generate 0, 0 << arg1 = 0
165define i32 @shli_i32_4(i32 %arg1) {
166 %A = shl i32 0, %arg1
167 ret i32 %A
168}
169
170define i32 @shli_i32_5(i32 signext %arg1) signext {
171 %A = shl i32 %arg1, 12
172 ret i32 %A
173}
174
175; Should not generate anything other than the return, arg1 << 0 = arg1
176define i32 @shli_i32_6(i32 signext %arg1) signext {
177 %A = shl i32 %arg1, 0
178 ret i32 %A
179}
180
181define i32 @shli_i32_7(i32 signext %arg1) signext {
182 %A = shl i32 16383, %arg1
183 ret i32 %A
184}
185
186; Should generate 0, 0 << arg1 = 0
187define i32 @shli_i32_8(i32 signext %arg1) signext {
188 %A = shl i32 0, %arg1
189 ret i32 %A
190}
191
192define i32 @shli_i32_9(i32 zeroext %arg1) zeroext {
193 %A = shl i32 %arg1, 12
194 ret i32 %A
195}
196
197; Should not generate anything other than the return, arg1 << 0 = arg1
198define i32 @shli_i32_10(i32 zeroext %arg1) zeroext {
199 %A = shl i32 %arg1, 0
200 ret i32 %A
201}
202
203define i32 @shli_i32_11(i32 zeroext %arg1) zeroext {
204 %A = shl i32 16383, %arg1
205 ret i32 %A
206}
207
208; Should generate 0, 0 << arg1 = 0
209define i32 @shli_i32_12(i32 zeroext %arg1) zeroext {
210 %A = shl i32 0, %arg1
211 ret i32 %A
212}