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llvm-mirror/test/ExecutionEngine/MCJIT/pr13727.ll
Peter Collingbourne 5f190b5e4e Introduce llvm::sys::getProcessTriple() function.
In r143502, we renamed getHostTriple() to getDefaultTargetTriple()
as part of work to allow the user to supply a different default
target triple at configure time.  This change also affected the JIT.
However, it is inappropriate to use the default target triple in the
JIT in most circumstances because this will not necessarily match
the current architecture used by the process, leading to illegal
instruction and other such errors at run time.

Introduce the getProcessTriple() function for use in the JIT and
its clients, and cause the JIT to use it.  On architectures with a
single bitness, the host and process triples are identical.  On other
architectures, the host triple represents the architecture of the
host CPU, while the process triple represents the architecture used
by the host CPU to interpret machine code within the current process.
For example, when executing 32-bit code on a 64-bit Linux machine,
the host triple may be 'x86_64-unknown-linux-gnu', while the process
triple may be 'i386-unknown-linux-gnu'.

This fixes JIT for the 32-on-64-bit (and vice versa) build on non-Apple
platforms.

Differential Revision: http://llvm-reviews.chandlerc.com/D254

llvm-svn: 172627
2013-01-16 17:27:22 +00:00

89 lines
2.9 KiB
LLVM

; RUN: %lli_mcjit -O0 -disable-lazy-compilation=false %s
; The intention of this test is to verify that symbols mapped to COMMON in ELF
; work as expected.
;
; Compiled from this C code:
;
; int zero_int;
; double zero_double;
; int zero_arr[10];
;
; int main()
; {
; zero_arr[zero_int + 5] = 40;
;
; if (zero_double < 1.1)
; zero_arr[zero_int + 2] = 70;
;
; for (int i = 1; i < 10; ++i) {
; zero_arr[i] = zero_arr[i - 1] + zero_arr[i];
; }
; return zero_arr[9] == 110 ? 0 : -1;
; }
@zero_int = common global i32 0, align 4
@zero_arr = common global [10 x i32] zeroinitializer, align 16
@zero_double = common global double 0.000000e+00, align 8
define i32 @main() nounwind {
entry:
%retval = alloca i32, align 4
%i = alloca i32, align 4
store i32 0, i32* %retval
%0 = load i32* @zero_int, align 4
%add = add nsw i32 %0, 5
%idxprom = sext i32 %add to i64
%arrayidx = getelementptr inbounds [10 x i32]* @zero_arr, i32 0, i64 %idxprom
store i32 40, i32* %arrayidx, align 4
%1 = load double* @zero_double, align 8
%cmp = fcmp olt double %1, 1.100000e+00
br i1 %cmp, label %if.then, label %if.end
if.then: ; preds = %entry
%2 = load i32* @zero_int, align 4
%add1 = add nsw i32 %2, 2
%idxprom2 = sext i32 %add1 to i64
%arrayidx3 = getelementptr inbounds [10 x i32]* @zero_arr, i32 0, i64 %idxprom2
store i32 70, i32* %arrayidx3, align 4
br label %if.end
if.end: ; preds = %if.then, %entry
store i32 1, i32* %i, align 4
br label %for.cond
for.cond: ; preds = %for.inc, %if.end
%3 = load i32* %i, align 4
%cmp4 = icmp slt i32 %3, 10
br i1 %cmp4, label %for.body, label %for.end
for.body: ; preds = %for.cond
%4 = load i32* %i, align 4
%sub = sub nsw i32 %4, 1
%idxprom5 = sext i32 %sub to i64
%arrayidx6 = getelementptr inbounds [10 x i32]* @zero_arr, i32 0, i64 %idxprom5
%5 = load i32* %arrayidx6, align 4
%6 = load i32* %i, align 4
%idxprom7 = sext i32 %6 to i64
%arrayidx8 = getelementptr inbounds [10 x i32]* @zero_arr, i32 0, i64 %idxprom7
%7 = load i32* %arrayidx8, align 4
%add9 = add nsw i32 %5, %7
%8 = load i32* %i, align 4
%idxprom10 = sext i32 %8 to i64
%arrayidx11 = getelementptr inbounds [10 x i32]* @zero_arr, i32 0, i64 %idxprom10
store i32 %add9, i32* %arrayidx11, align 4
br label %for.inc
for.inc: ; preds = %for.body
%9 = load i32* %i, align 4
%inc = add nsw i32 %9, 1
store i32 %inc, i32* %i, align 4
br label %for.cond
for.end: ; preds = %for.cond
%10 = load i32* getelementptr inbounds ([10 x i32]* @zero_arr, i32 0, i64 9), align 4
%cmp12 = icmp eq i32 %10, 110
%cond = select i1 %cmp12, i32 0, i32 -1
ret i32 %cond
}