mirror of
https://github.com/RPCS3/llvm-mirror.git
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c7f8ab2cc1
Summary: Made it convert from register to stack based instructions, and removed the registers. Fixes to related code that was expecting register based instructions. Added the correct testing flag to all tests, depending on what the format they were expecting so far. Translated one test to stack format as example: reg-stackify-stack.ll tested: llvm-lit -v `find test -name WebAssembly` unittests/MC/* Reviewers: dschuff, sunfish Subscribers: sbc100, jgravelle-google, eraman, aheejin, llvm-commits, jfb Differential Revision: https://reviews.llvm.org/D51241 llvm-svn: 340750
670 lines
20 KiB
LLVM
670 lines
20 KiB
LLVM
; RUN: llc < %s -asm-verbose=false -wasm-disable-explicit-locals -wasm-keep-registers -disable-wasm-fallthrough-return-opt | FileCheck %s
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; Test constant load and store address offsets.
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target datalayout = "e-m:e-p:32:32-i64:64-n32:64-S128"
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target triple = "wasm32-unknown-unknown"
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;===----------------------------------------------------------------------------
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; Loads: 32-bit
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;===----------------------------------------------------------------------------
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; Basic load.
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; CHECK-LABEL: load_i32_no_offset:
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; CHECK: i32.load $push0=, 0($0){{$}}
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; CHECK-NEXT: return $pop0{{$}}
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define i32 @load_i32_no_offset(i32 *%p) {
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%v = load i32, i32* %p
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ret i32 %v
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}
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; With an nuw add, we can fold an offset.
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; CHECK-LABEL: load_i32_with_folded_offset:
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; CHECK: i32.load $push0=, 24($0){{$}}
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define i32 @load_i32_with_folded_offset(i32* %p) {
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%q = ptrtoint i32* %p to i32
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%r = add nuw i32 %q, 24
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%s = inttoptr i32 %r to i32*
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%t = load i32, i32* %s
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ret i32 %t
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}
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; With an inbounds gep, we can fold an offset.
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; CHECK-LABEL: load_i32_with_folded_gep_offset:
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; CHECK: i32.load $push0=, 24($0){{$}}
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define i32 @load_i32_with_folded_gep_offset(i32* %p) {
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%s = getelementptr inbounds i32, i32* %p, i32 6
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%t = load i32, i32* %s
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ret i32 %t
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}
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; We can't fold a negative offset though, even with an inbounds gep.
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; CHECK-LABEL: load_i32_with_unfolded_gep_negative_offset:
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; CHECK: i32.const $push0=, -24{{$}}
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; CHECK: i32.add $push1=, $0, $pop0{{$}}
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; CHECK: i32.load $push2=, 0($pop1){{$}}
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define i32 @load_i32_with_unfolded_gep_negative_offset(i32* %p) {
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%s = getelementptr inbounds i32, i32* %p, i32 -6
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%t = load i32, i32* %s
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ret i32 %t
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}
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; Without nuw, and even with nsw, we can't fold an offset.
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; CHECK-LABEL: load_i32_with_unfolded_offset:
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; CHECK: i32.const $push0=, 24{{$}}
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; CHECK: i32.add $push1=, $0, $pop0{{$}}
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; CHECK: i32.load $push2=, 0($pop1){{$}}
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define i32 @load_i32_with_unfolded_offset(i32* %p) {
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%q = ptrtoint i32* %p to i32
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%r = add nsw i32 %q, 24
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%s = inttoptr i32 %r to i32*
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%t = load i32, i32* %s
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ret i32 %t
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}
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; Without inbounds, we can't fold a gep offset.
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; CHECK-LABEL: load_i32_with_unfolded_gep_offset:
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; CHECK: i32.const $push0=, 24{{$}}
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; CHECK: i32.add $push1=, $0, $pop0{{$}}
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; CHECK: i32.load $push2=, 0($pop1){{$}}
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define i32 @load_i32_with_unfolded_gep_offset(i32* %p) {
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%s = getelementptr i32, i32* %p, i32 6
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%t = load i32, i32* %s
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ret i32 %t
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}
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; When loading from a fixed address, materialize a zero.
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; CHECK-LABEL: load_i32_from_numeric_address
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; CHECK: i32.const $push0=, 0{{$}}
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; CHECK: i32.load $push1=, 42($pop0){{$}}
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define i32 @load_i32_from_numeric_address() {
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%s = inttoptr i32 42 to i32*
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%t = load i32, i32* %s
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ret i32 %t
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}
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; CHECK-LABEL: load_i32_from_global_address
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; CHECK: i32.const $push0=, 0{{$}}
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; CHECK: i32.load $push1=, gv($pop0){{$}}
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@gv = global i32 0
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define i32 @load_i32_from_global_address() {
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%t = load i32, i32* @gv
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ret i32 %t
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}
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;===----------------------------------------------------------------------------
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; Loads: 64-bit
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;===----------------------------------------------------------------------------
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; Basic load.
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; CHECK-LABEL: load_i64_no_offset:
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; CHECK: i64.load $push0=, 0($0){{$}}
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; CHECK-NEXT: return $pop0{{$}}
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define i64 @load_i64_no_offset(i64 *%p) {
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%v = load i64, i64* %p
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ret i64 %v
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}
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; With an nuw add, we can fold an offset.
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; CHECK-LABEL: load_i64_with_folded_offset:
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; CHECK: i64.load $push0=, 24($0){{$}}
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define i64 @load_i64_with_folded_offset(i64* %p) {
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%q = ptrtoint i64* %p to i32
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%r = add nuw i32 %q, 24
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%s = inttoptr i32 %r to i64*
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%t = load i64, i64* %s
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ret i64 %t
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}
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; With an inbounds gep, we can fold an offset.
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; CHECK-LABEL: load_i64_with_folded_gep_offset:
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; CHECK: i64.load $push0=, 24($0){{$}}
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define i64 @load_i64_with_folded_gep_offset(i64* %p) {
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%s = getelementptr inbounds i64, i64* %p, i32 3
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%t = load i64, i64* %s
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ret i64 %t
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}
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; We can't fold a negative offset though, even with an inbounds gep.
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; CHECK-LABEL: load_i64_with_unfolded_gep_negative_offset:
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; CHECK: i32.const $push0=, -24{{$}}
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; CHECK: i32.add $push1=, $0, $pop0{{$}}
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; CHECK: i64.load $push2=, 0($pop1){{$}}
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define i64 @load_i64_with_unfolded_gep_negative_offset(i64* %p) {
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%s = getelementptr inbounds i64, i64* %p, i32 -3
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%t = load i64, i64* %s
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ret i64 %t
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}
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; Without nuw, and even with nsw, we can't fold an offset.
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; CHECK-LABEL: load_i64_with_unfolded_offset:
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; CHECK: i32.const $push0=, 24{{$}}
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; CHECK: i32.add $push1=, $0, $pop0{{$}}
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; CHECK: i64.load $push2=, 0($pop1){{$}}
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define i64 @load_i64_with_unfolded_offset(i64* %p) {
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%q = ptrtoint i64* %p to i32
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%r = add nsw i32 %q, 24
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%s = inttoptr i32 %r to i64*
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%t = load i64, i64* %s
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ret i64 %t
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}
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; Without inbounds, we can't fold a gep offset.
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; CHECK-LABEL: load_i64_with_unfolded_gep_offset:
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; CHECK: i32.const $push0=, 24{{$}}
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; CHECK: i32.add $push1=, $0, $pop0{{$}}
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; CHECK: i64.load $push2=, 0($pop1){{$}}
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define i64 @load_i64_with_unfolded_gep_offset(i64* %p) {
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%s = getelementptr i64, i64* %p, i32 3
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%t = load i64, i64* %s
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ret i64 %t
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}
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;===----------------------------------------------------------------------------
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; Stores: 32-bit
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;===----------------------------------------------------------------------------
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; Basic store.
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; CHECK-LABEL: store_i32_no_offset:
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; CHECK-NEXT: .param i32, i32{{$}}
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; CHECK-NEXT: i32.store 0($0), $1{{$}}
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; CHECK-NEXT: return{{$}}
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define void @store_i32_no_offset(i32 *%p, i32 %v) {
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store i32 %v, i32* %p
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ret void
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}
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; With an nuw add, we can fold an offset.
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; CHECK-LABEL: store_i32_with_folded_offset:
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; CHECK: i32.store 24($0), $pop0{{$}}
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define void @store_i32_with_folded_offset(i32* %p) {
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%q = ptrtoint i32* %p to i32
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%r = add nuw i32 %q, 24
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%s = inttoptr i32 %r to i32*
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store i32 0, i32* %s
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ret void
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}
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; With an inbounds gep, we can fold an offset.
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; CHECK-LABEL: store_i32_with_folded_gep_offset:
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; CHECK: i32.store 24($0), $pop0{{$}}
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define void @store_i32_with_folded_gep_offset(i32* %p) {
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%s = getelementptr inbounds i32, i32* %p, i32 6
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store i32 0, i32* %s
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ret void
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}
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; We can't fold a negative offset though, even with an inbounds gep.
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; CHECK-LABEL: store_i32_with_unfolded_gep_negative_offset:
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; CHECK: i32.const $push0=, -24{{$}}
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; CHECK: i32.add $push1=, $0, $pop0{{$}}
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; CHECK: i32.store 0($pop1), $pop2{{$}}
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define void @store_i32_with_unfolded_gep_negative_offset(i32* %p) {
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%s = getelementptr inbounds i32, i32* %p, i32 -6
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store i32 0, i32* %s
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ret void
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}
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; Without nuw, and even with nsw, we can't fold an offset.
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; CHECK-LABEL: store_i32_with_unfolded_offset:
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; CHECK: i32.const $push0=, 24{{$}}
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; CHECK: i32.add $push1=, $0, $pop0{{$}}
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; CHECK: i32.store 0($pop1), $pop2{{$}}
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define void @store_i32_with_unfolded_offset(i32* %p) {
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%q = ptrtoint i32* %p to i32
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%r = add nsw i32 %q, 24
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%s = inttoptr i32 %r to i32*
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store i32 0, i32* %s
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ret void
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}
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; Without inbounds, we can't fold a gep offset.
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; CHECK-LABEL: store_i32_with_unfolded_gep_offset:
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; CHECK: i32.const $push0=, 24{{$}}
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; CHECK: i32.add $push1=, $0, $pop0{{$}}
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; CHECK: i32.store 0($pop1), $pop2{{$}}
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define void @store_i32_with_unfolded_gep_offset(i32* %p) {
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%s = getelementptr i32, i32* %p, i32 6
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store i32 0, i32* %s
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ret void
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}
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; When storing from a fixed address, materialize a zero.
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; CHECK-LABEL: store_i32_to_numeric_address:
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; CHECK-NEXT: i32.const $push0=, 0{{$}}
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; CHECK-NEXT: i32.const $push1=, 0{{$}}
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; CHECK-NEXT: i32.store 42($pop0), $pop1{{$}}
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define void @store_i32_to_numeric_address() {
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%s = inttoptr i32 42 to i32*
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store i32 0, i32* %s
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ret void
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}
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; CHECK-LABEL: store_i32_to_global_address:
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; CHECK: i32.const $push0=, 0{{$}}
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; CHECK: i32.const $push1=, 0{{$}}
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; CHECK: i32.store gv($pop0), $pop1{{$}}
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define void @store_i32_to_global_address() {
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store i32 0, i32* @gv
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ret void
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}
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;===----------------------------------------------------------------------------
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; Stores: 64-bit
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;===----------------------------------------------------------------------------
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; Basic store.
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; CHECK-LABEL: store_i64_with_folded_offset:
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; CHECK: i64.store 24($0), $pop0{{$}}
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define void @store_i64_with_folded_offset(i64* %p) {
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%q = ptrtoint i64* %p to i32
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%r = add nuw i32 %q, 24
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%s = inttoptr i32 %r to i64*
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store i64 0, i64* %s
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ret void
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}
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; With an nuw add, we can fold an offset.
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; CHECK-LABEL: store_i64_with_folded_gep_offset:
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; CHECK: i64.store 24($0), $pop0{{$}}
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define void @store_i64_with_folded_gep_offset(i64* %p) {
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%s = getelementptr inbounds i64, i64* %p, i32 3
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store i64 0, i64* %s
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ret void
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}
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; With an inbounds gep, we can fold an offset.
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; CHECK-LABEL: store_i64_with_unfolded_gep_negative_offset:
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; CHECK: i32.const $push0=, -24{{$}}
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; CHECK: i32.add $push1=, $0, $pop0{{$}}
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; CHECK: i64.store 0($pop1), $pop2{{$}}
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define void @store_i64_with_unfolded_gep_negative_offset(i64* %p) {
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%s = getelementptr inbounds i64, i64* %p, i32 -3
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store i64 0, i64* %s
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ret void
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}
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; We can't fold a negative offset though, even with an inbounds gep.
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; CHECK-LABEL: store_i64_with_unfolded_offset:
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; CHECK: i32.const $push0=, 24{{$}}
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; CHECK: i32.add $push1=, $0, $pop0{{$}}
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; CHECK: i64.store 0($pop1), $pop2{{$}}
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define void @store_i64_with_unfolded_offset(i64* %p) {
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%q = ptrtoint i64* %p to i32
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%r = add nsw i32 %q, 24
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%s = inttoptr i32 %r to i64*
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store i64 0, i64* %s
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ret void
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}
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; Without nuw, and even with nsw, we can't fold an offset.
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; CHECK-LABEL: store_i64_with_unfolded_gep_offset:
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; CHECK: i32.const $push0=, 24{{$}}
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; CHECK: i32.add $push1=, $0, $pop0{{$}}
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; CHECK: i64.store 0($pop1), $pop2{{$}}
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define void @store_i64_with_unfolded_gep_offset(i64* %p) {
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%s = getelementptr i64, i64* %p, i32 3
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store i64 0, i64* %s
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ret void
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}
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; Without inbounds, we can't fold a gep offset.
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; CHECK-LABEL: store_i32_with_folded_or_offset:
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; CHECK: i32.store8 2($pop{{[0-9]+}}), $pop{{[0-9]+}}{{$}}
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define void @store_i32_with_folded_or_offset(i32 %x) {
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%and = and i32 %x, -4
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%t0 = inttoptr i32 %and to i8*
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%arrayidx = getelementptr inbounds i8, i8* %t0, i32 2
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store i8 0, i8* %arrayidx, align 1
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ret void
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}
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;===----------------------------------------------------------------------------
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; Sign-extending loads
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;===----------------------------------------------------------------------------
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; Fold an offset into a sign-extending load.
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; CHECK-LABEL: load_i8_i32_s_with_folded_offset:
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; CHECK: i32.load8_s $push0=, 24($0){{$}}
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define i32 @load_i8_i32_s_with_folded_offset(i8* %p) {
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%q = ptrtoint i8* %p to i32
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%r = add nuw i32 %q, 24
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%s = inttoptr i32 %r to i8*
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%t = load i8, i8* %s
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%u = sext i8 %t to i32
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ret i32 %u
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}
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; CHECK-LABEL: load_i32_i64_s_with_folded_offset:
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; CHECK: i64.load32_s $push0=, 24($0){{$}}
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define i64 @load_i32_i64_s_with_folded_offset(i32* %p) {
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%q = ptrtoint i32* %p to i32
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%r = add nuw i32 %q, 24
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%s = inttoptr i32 %r to i32*
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%t = load i32, i32* %s
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%u = sext i32 %t to i64
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ret i64 %u
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}
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; Fold a gep offset into a sign-extending load.
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; CHECK-LABEL: load_i8_i32_s_with_folded_gep_offset:
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; CHECK: i32.load8_s $push0=, 24($0){{$}}
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define i32 @load_i8_i32_s_with_folded_gep_offset(i8* %p) {
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%s = getelementptr inbounds i8, i8* %p, i32 24
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%t = load i8, i8* %s
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%u = sext i8 %t to i32
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ret i32 %u
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}
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; CHECK-LABEL: load_i16_i32_s_with_folded_gep_offset:
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; CHECK: i32.load16_s $push0=, 48($0){{$}}
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define i32 @load_i16_i32_s_with_folded_gep_offset(i16* %p) {
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%s = getelementptr inbounds i16, i16* %p, i32 24
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%t = load i16, i16* %s
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%u = sext i16 %t to i32
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ret i32 %u
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}
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; CHECK-LABEL: load_i16_i64_s_with_folded_gep_offset:
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; CHECK: i64.load16_s $push0=, 48($0){{$}}
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define i64 @load_i16_i64_s_with_folded_gep_offset(i16* %p) {
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%s = getelementptr inbounds i16, i16* %p, i32 24
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%t = load i16, i16* %s
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%u = sext i16 %t to i64
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ret i64 %u
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}
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; 'add' in this code becomes 'or' after DAG optimization. Treat an 'or' node as
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; an 'add' if the or'ed bits are known to be zero.
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; CHECK-LABEL: load_i8_i32_s_with_folded_or_offset:
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; CHECK: i32.load8_s $push{{[0-9]+}}=, 2($pop{{[0-9]+}}){{$}}
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define i32 @load_i8_i32_s_with_folded_or_offset(i32 %x) {
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%and = and i32 %x, -4
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%t0 = inttoptr i32 %and to i8*
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%arrayidx = getelementptr inbounds i8, i8* %t0, i32 2
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%t1 = load i8, i8* %arrayidx
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%conv = sext i8 %t1 to i32
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ret i32 %conv
|
|
}
|
|
|
|
; CHECK-LABEL: load_i8_i64_s_with_folded_or_offset:
|
|
; CHECK: i64.load8_s $push{{[0-9]+}}=, 2($pop{{[0-9]+}}){{$}}
|
|
define i64 @load_i8_i64_s_with_folded_or_offset(i32 %x) {
|
|
%and = and i32 %x, -4
|
|
%t0 = inttoptr i32 %and to i8*
|
|
%arrayidx = getelementptr inbounds i8, i8* %t0, i32 2
|
|
%t1 = load i8, i8* %arrayidx
|
|
%conv = sext i8 %t1 to i64
|
|
ret i64 %conv
|
|
}
|
|
|
|
; When loading from a fixed address, materialize a zero.
|
|
|
|
; CHECK-LABEL: load_i16_i32_s_from_numeric_address
|
|
; CHECK: i32.const $push0=, 0{{$}}
|
|
; CHECK: i32.load16_s $push1=, 42($pop0){{$}}
|
|
define i32 @load_i16_i32_s_from_numeric_address() {
|
|
%s = inttoptr i32 42 to i16*
|
|
%t = load i16, i16* %s
|
|
%u = sext i16 %t to i32
|
|
ret i32 %u
|
|
}
|
|
|
|
; CHECK-LABEL: load_i8_i32_s_from_global_address
|
|
; CHECK: i32.const $push0=, 0{{$}}
|
|
; CHECK: i32.load8_s $push1=, gv8($pop0){{$}}
|
|
@gv8 = global i8 0
|
|
define i32 @load_i8_i32_s_from_global_address() {
|
|
%t = load i8, i8* @gv8
|
|
%u = sext i8 %t to i32
|
|
ret i32 %u
|
|
}
|
|
|
|
;===----------------------------------------------------------------------------
|
|
; Zero-extending loads
|
|
;===----------------------------------------------------------------------------
|
|
|
|
; Fold an offset into a zero-extending load.
|
|
|
|
; CHECK-LABEL: load_i8_i32_z_with_folded_offset:
|
|
; CHECK: i32.load8_u $push0=, 24($0){{$}}
|
|
define i32 @load_i8_i32_z_with_folded_offset(i8* %p) {
|
|
%q = ptrtoint i8* %p to i32
|
|
%r = add nuw i32 %q, 24
|
|
%s = inttoptr i32 %r to i8*
|
|
%t = load i8, i8* %s
|
|
%u = zext i8 %t to i32
|
|
ret i32 %u
|
|
}
|
|
|
|
; CHECK-LABEL: load_i32_i64_z_with_folded_offset:
|
|
; CHECK: i64.load32_u $push0=, 24($0){{$}}
|
|
define i64 @load_i32_i64_z_with_folded_offset(i32* %p) {
|
|
%q = ptrtoint i32* %p to i32
|
|
%r = add nuw i32 %q, 24
|
|
%s = inttoptr i32 %r to i32*
|
|
%t = load i32, i32* %s
|
|
%u = zext i32 %t to i64
|
|
ret i64 %u
|
|
}
|
|
|
|
; Fold a gep offset into a zero-extending load.
|
|
|
|
; CHECK-LABEL: load_i8_i32_z_with_folded_gep_offset:
|
|
; CHECK: i32.load8_u $push0=, 24($0){{$}}
|
|
define i32 @load_i8_i32_z_with_folded_gep_offset(i8* %p) {
|
|
%s = getelementptr inbounds i8, i8* %p, i32 24
|
|
%t = load i8, i8* %s
|
|
%u = zext i8 %t to i32
|
|
ret i32 %u
|
|
}
|
|
|
|
; CHECK-LABEL: load_i16_i32_z_with_folded_gep_offset:
|
|
; CHECK: i32.load16_u $push0=, 48($0){{$}}
|
|
define i32 @load_i16_i32_z_with_folded_gep_offset(i16* %p) {
|
|
%s = getelementptr inbounds i16, i16* %p, i32 24
|
|
%t = load i16, i16* %s
|
|
%u = zext i16 %t to i32
|
|
ret i32 %u
|
|
}
|
|
|
|
; CHECK-LABEL: load_i16_i64_z_with_folded_gep_offset:
|
|
; CHECK: i64.load16_u $push0=, 48($0){{$}}
|
|
define i64 @load_i16_i64_z_with_folded_gep_offset(i16* %p) {
|
|
%s = getelementptr inbounds i16, i16* %p, i64 24
|
|
%t = load i16, i16* %s
|
|
%u = zext i16 %t to i64
|
|
ret i64 %u
|
|
}
|
|
|
|
; When loading from a fixed address, materialize a zero.
|
|
|
|
; CHECK-LABEL: load_i16_i32_z_from_numeric_address
|
|
; CHECK: i32.const $push0=, 0{{$}}
|
|
; CHECK: i32.load16_u $push1=, 42($pop0){{$}}
|
|
define i32 @load_i16_i32_z_from_numeric_address() {
|
|
%s = inttoptr i32 42 to i16*
|
|
%t = load i16, i16* %s
|
|
%u = zext i16 %t to i32
|
|
ret i32 %u
|
|
}
|
|
|
|
; CHECK-LABEL: load_i8_i32_z_from_global_address
|
|
; CHECK: i32.const $push0=, 0{{$}}
|
|
; CHECK: i32.load8_u $push1=, gv8($pop0){{$}}
|
|
define i32 @load_i8_i32_z_from_global_address() {
|
|
%t = load i8, i8* @gv8
|
|
%u = zext i8 %t to i32
|
|
ret i32 %u
|
|
}
|
|
|
|
; i8 return value should test anyext loads
|
|
; CHECK-LABEL: load_i8_i32_retvalue:
|
|
; CHECK: i32.load8_u $push[[NUM:[0-9]+]]=, 0($0){{$}}
|
|
; CHECK-NEXT: return $pop[[NUM]]{{$}}
|
|
define i8 @load_i8_i32_retvalue(i8 *%p) {
|
|
%v = load i8, i8* %p
|
|
ret i8 %v
|
|
}
|
|
|
|
;===----------------------------------------------------------------------------
|
|
; Truncating stores
|
|
;===----------------------------------------------------------------------------
|
|
|
|
; Fold an offset into a truncating store.
|
|
|
|
; CHECK-LABEL: store_i8_i32_with_folded_offset:
|
|
; CHECK: i32.store8 24($0), $1{{$}}
|
|
define void @store_i8_i32_with_folded_offset(i8* %p, i32 %v) {
|
|
%q = ptrtoint i8* %p to i32
|
|
%r = add nuw i32 %q, 24
|
|
%s = inttoptr i32 %r to i8*
|
|
%t = trunc i32 %v to i8
|
|
store i8 %t, i8* %s
|
|
ret void
|
|
}
|
|
|
|
; CHECK-LABEL: store_i32_i64_with_folded_offset:
|
|
; CHECK: i64.store32 24($0), $1{{$}}
|
|
define void @store_i32_i64_with_folded_offset(i32* %p, i64 %v) {
|
|
%q = ptrtoint i32* %p to i32
|
|
%r = add nuw i32 %q, 24
|
|
%s = inttoptr i32 %r to i32*
|
|
%t = trunc i64 %v to i32
|
|
store i32 %t, i32* %s
|
|
ret void
|
|
}
|
|
|
|
; Fold a gep offset into a truncating store.
|
|
|
|
; CHECK-LABEL: store_i8_i32_with_folded_gep_offset:
|
|
; CHECK: i32.store8 24($0), $1{{$}}
|
|
define void @store_i8_i32_with_folded_gep_offset(i8* %p, i32 %v) {
|
|
%s = getelementptr inbounds i8, i8* %p, i32 24
|
|
%t = trunc i32 %v to i8
|
|
store i8 %t, i8* %s
|
|
ret void
|
|
}
|
|
|
|
; CHECK-LABEL: store_i16_i32_with_folded_gep_offset:
|
|
; CHECK: i32.store16 48($0), $1{{$}}
|
|
define void @store_i16_i32_with_folded_gep_offset(i16* %p, i32 %v) {
|
|
%s = getelementptr inbounds i16, i16* %p, i32 24
|
|
%t = trunc i32 %v to i16
|
|
store i16 %t, i16* %s
|
|
ret void
|
|
}
|
|
|
|
; CHECK-LABEL: store_i16_i64_with_folded_gep_offset:
|
|
; CHECK: i64.store16 48($0), $1{{$}}
|
|
define void @store_i16_i64_with_folded_gep_offset(i16* %p, i64 %v) {
|
|
%s = getelementptr inbounds i16, i16* %p, i64 24
|
|
%t = trunc i64 %v to i16
|
|
store i16 %t, i16* %s
|
|
ret void
|
|
}
|
|
|
|
; 'add' in this code becomes 'or' after DAG optimization. Treat an 'or' node as
|
|
; an 'add' if the or'ed bits are known to be zero.
|
|
|
|
; CHECK-LABEL: store_i8_i32_with_folded_or_offset:
|
|
; CHECK: i32.store8 2($pop{{[0-9]+}}), $1{{$}}
|
|
define void @store_i8_i32_with_folded_or_offset(i32 %x, i32 %v) {
|
|
%and = and i32 %x, -4
|
|
%p = inttoptr i32 %and to i8*
|
|
%arrayidx = getelementptr inbounds i8, i8* %p, i32 2
|
|
%t = trunc i32 %v to i8
|
|
store i8 %t, i8* %arrayidx
|
|
ret void
|
|
}
|
|
|
|
; CHECK-LABEL: store_i8_i64_with_folded_or_offset:
|
|
; CHECK: i64.store8 2($pop{{[0-9]+}}), $1{{$}}
|
|
define void @store_i8_i64_with_folded_or_offset(i32 %x, i64 %v) {
|
|
%and = and i32 %x, -4
|
|
%p = inttoptr i32 %and to i8*
|
|
%arrayidx = getelementptr inbounds i8, i8* %p, i32 2
|
|
%t = trunc i64 %v to i8
|
|
store i8 %t, i8* %arrayidx
|
|
ret void
|
|
}
|
|
|
|
;===----------------------------------------------------------------------------
|
|
; Aggregate values
|
|
;===----------------------------------------------------------------------------
|
|
|
|
; Fold the offsets when lowering aggregate loads and stores.
|
|
|
|
; CHECK-LABEL: aggregate_load_store:
|
|
; CHECK: i32.load $2=, 0($0){{$}}
|
|
; CHECK: i32.load $3=, 4($0){{$}}
|
|
; CHECK: i32.load $4=, 8($0){{$}}
|
|
; CHECK: i32.load $push0=, 12($0){{$}}
|
|
; CHECK: i32.store 12($1), $pop0{{$}}
|
|
; CHECK: i32.store 8($1), $4{{$}}
|
|
; CHECK: i32.store 4($1), $3{{$}}
|
|
; CHECK: i32.store 0($1), $2{{$}}
|
|
define void @aggregate_load_store({i32,i32,i32,i32}* %p, {i32,i32,i32,i32}* %q) {
|
|
; volatile so that things stay in order for the tests above
|
|
%t = load volatile {i32,i32,i32,i32}, {i32, i32,i32,i32}* %p
|
|
store volatile {i32,i32,i32,i32} %t, {i32, i32,i32,i32}* %q
|
|
ret void
|
|
}
|
|
|
|
; Fold the offsets when lowering aggregate return values. The stores get
|
|
; merged into i64 stores.
|
|
|
|
; CHECK-LABEL: aggregate_return:
|
|
; CHECK: i64.const $push[[L0:[0-9]+]]=, 0{{$}}
|
|
; CHECK: i64.store 8($0):p2align=2, $pop[[L0]]{{$}}
|
|
; CHECK: i64.const $push[[L1:[0-9]+]]=, 0{{$}}
|
|
; CHECK: i64.store 0($0):p2align=2, $pop[[L1]]{{$}}
|
|
define {i32,i32,i32,i32} @aggregate_return() {
|
|
ret {i32,i32,i32,i32} zeroinitializer
|
|
}
|
|
|
|
; Fold the offsets when lowering aggregate return values. The stores are not
|
|
; merged.
|
|
|
|
; CHECK-LABEL: aggregate_return_without_merge:
|
|
; CHECK: i32.const $push[[L0:[0-9]+]]=, 0{{$}}
|
|
; CHECK: i32.store8 14($0), $pop[[L0]]{{$}}
|
|
; CHECK: i32.const $push[[L1:[0-9]+]]=, 0{{$}}
|
|
; CHECK: i32.store16 12($0), $pop[[L1]]{{$}}
|
|
; CHECK: i32.const $push[[L2:[0-9]+]]=, 0{{$}}
|
|
; CHECK: i32.store 8($0), $pop[[L2]]{{$}}
|
|
; CHECK: i64.const $push[[L3:[0-9]+]]=, 0{{$}}
|
|
; CHECK: i64.store 0($0), $pop[[L3]]{{$}}
|
|
define {i64,i32,i16,i8} @aggregate_return_without_merge() {
|
|
ret {i64,i32,i16,i8} zeroinitializer
|
|
}
|