forked from OSchip/llvm-project
162 lines
6.6 KiB
C++
162 lines
6.6 KiB
C++
// Purpose:
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// Verifies that the debugging experience of loops marked optnone is as expected.
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// REQUIRES: lldb
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// UNSUPPORTED: system-windows
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// UNSUPPORTED: system-darwin
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// RUN: %dexter --fail-lt 1.0 -w \
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// RUN: --builder 'clang' --debugger 'lldb' \
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// RUN: --cflags "-O2 -g" -- %s
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// A simple loop of assignments.
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// With optimization level > 0 the compiler reorders basic blocks
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// based on the basic block frequency analysis information.
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// This also happens with optnone and it shouldn't.
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// This is not affecting debug info so it is a minor limitation.
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// Basic block placement based on the block frequency analysis
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// is normally done to improve i-Cache performances.
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__attribute__((optnone)) void simple_memcpy_loop(int *dest, const int *src,
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unsigned nelems) {
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for (unsigned i = 0; i != nelems; ++i)
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dest[i] = src[i]; // DexLabel('target_simple_memcpy_loop')
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}
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// DexLimitSteps('i', 0, 4, 8, on_line='target_simple_memcpy_loop')
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// DexExpectWatchValue('nelems', '16', on_line='target_simple_memcpy_loop')
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// DexExpectWatchValue('src[i]', '3', '7', '1', on_line='target_simple_memcpy_loop')
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// A trivial loop that could be optimized into a builtin memcpy
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// which is either expanded into a optimal sequence of mov
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// instructions or directly into a call to memset@plt
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__attribute__((optnone)) void trivial_memcpy_loop(int *dest, const int *src) {
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for (unsigned i = 0; i != 16; ++i)
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dest[i] = src[i]; // DexLabel('target_trivial_memcpy_loop')
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}
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// DexLimitSteps('i', 3, 7, 9, 14, 15, on_line='target_trivial_memcpy_loop')
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// DexExpectWatchValue('i', 3, 7, 9, 14, 15, on_line='target_trivial_memcpy_loop')
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// DexExpectWatchValue('dest[i-1] == src[i-1]', 'true', on_line='target_trivial_memcpy_loop')
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__attribute__((always_inline)) int foo(int a) { return a + 5; }
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// A trivial loop of calls to a 'always_inline' function.
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__attribute__((optnone)) void nonleaf_function_with_loop(int *dest,
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const int *src) {
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for (unsigned i = 0; i != 16; ++i)
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dest[i] = foo(src[i]); // DexLabel('target_nonleaf_function_with_loop')
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}
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// DexLimitSteps('i', 1, on_line='target_nonleaf_function_with_loop')
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// DexExpectWatchValue('dest[0]', '8', on_line='target_nonleaf_function_with_loop')
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// DexExpectWatchValue('dest[1]', '4', on_line='target_nonleaf_function_with_loop')
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// DexExpectWatchValue('dest[2]', '5', on_line='target_nonleaf_function_with_loop')
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// DexExpectWatchValue('src[0]', '8', on_line='target_nonleaf_function_with_loop')
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// DexExpectWatchValue('src[1]', '4', on_line='target_nonleaf_function_with_loop')
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// DexExpectWatchValue('src[2]', '5', on_line='target_nonleaf_function_with_loop')
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// DexExpectWatchValue('src[1] == dest[1]', 'true', on_line='target_nonleaf_function_with_loop')
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// DexExpectWatchValue('src[2] == dest[2]', 'true', on_line='target_nonleaf_function_with_loop')
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// This entire function could be optimized into a
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// simple movl %esi, %eax.
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// That is because we can compute the loop trip count
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// knowing that ind-var 'i' can never be negative.
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__attribute__((optnone)) int counting_loop(unsigned values) {
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unsigned i = 0;
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while (values--) // DexLabel('target_counting_loop')
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i++;
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return i;
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}
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// DexLimitSteps('i', 8, 16, on_line='target_counting_loop')
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// DexExpectWatchValue('i', 8, 16, on_line='target_counting_loop')
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// This loop could be rotated.
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// while(cond){
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// ..
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// cond--;
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// }
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//
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// -->
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// if(cond) {
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// do {
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// ...
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// cond--;
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// } while(cond);
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// }
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//
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// the compiler will not try to optimize this function.
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// However the Machine BB Placement Pass will try
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// to reorder the basic block that computes the
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// expression 'count' in order to simplify the control
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// flow.
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__attribute__((optnone)) int loop_rotate_test(int *src, unsigned count) {
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int result = 0;
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while (count) {
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result += src[count - 1]; // DexLabel('target_loop_rotate_test')
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count--;
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}
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return result; // DexLabel('target_loop_rotate_test_ret')
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}
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// DexLimitSteps('result', 13, on_line='target_loop_rotate_test')
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// DexExpectWatchValue('src[count]', 13, on_line='target_loop_rotate_test')
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// DexLimitSteps('result', 158, on_line='target_loop_rotate_test_ret')
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// DexExpectWatchValue('result', 158, on_line='target_loop_rotate_test_ret')
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typedef int *intptr __attribute__((aligned(16)));
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// This loop can be vectorized if we enable
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// the loop vectorizer.
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__attribute__((optnone)) void loop_vectorize_test(intptr dest, intptr src) {
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unsigned count = 0;
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int tempArray[16];
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while(count != 16) { // DexLabel('target_loop_vectorize_test')
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tempArray[count] = src[count];
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tempArray[count+1] = src[count+1]; // DexLabel('target_loop_vectorize_test_2')
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tempArray[count+2] = src[count+2]; // DexLabel('target_loop_vectorize_test_3')
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tempArray[count+3] = src[count+3]; // DexLabel('target_loop_vectorize_test_4')
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dest[count] = tempArray[count]; // DexLabel('target_loop_vectorize_test_5')
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dest[count+1] = tempArray[count+1]; // DexLabel('target_loop_vectorize_test_6')
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dest[count+2] = tempArray[count+2]; // DexLabel('target_loop_vectorize_test_7')
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dest[count+3] = tempArray[count+3]; // DexLabel('target_loop_vectorize_test_8')
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count += 4; // DexLabel('target_loop_vectorize_test_9')
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}
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}
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// DexLimitSteps('count', 4, 8, 12, 16, from_line='target_loop_vectorize_test', to_line='target_loop_vectorize_test_9')
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// DexExpectWatchValue('tempArray[count] == src[count]', 'true', on_line='target_loop_vectorize_test_2')
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// DexExpectWatchValue('tempArray[count+1] == src[count+1]', 'true', on_line='target_loop_vectorize_test_3')
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// DexExpectWatchValue('tempArray[count+2] == src[count+2]', 'true', on_line='target_loop_vectorize_test_4')
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// DexExpectWatchValue('tempArray[count+3] == src[count+3]', 'true', on_line='target_loop_vectorize_test_5')
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// DexExpectWatchValue('dest[count] == tempArray[count]', 'true', on_line='target_loop_vectorize_test_6')
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// DexExpectWatchValue('dest[count+1] == tempArray[count+1]', 'true', on_line='target_loop_vectorize_test_7')
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// DexExpectWatchValue('dest[count+2] == tempArray[count+2]', 'true', on_line='target_loop_vectorize_test_8')
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// DexExpectWatchValue('dest[count+3] == tempArray[count+3]', 'true', on_line='target_loop_vectorize_test_9')
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int main() {
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int A[] = {3, 4, 5, 6, 7, 8, 9, 0, 1, 2, 3, 4, 5, 6, 7, 8, 9};
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int B[] = {13, 14, 15, 16, 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12};
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int C[16] = {0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0};
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simple_memcpy_loop(C, A, 16);
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trivial_memcpy_loop(B, C);
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nonleaf_function_with_loop(B, B);
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int count = counting_loop(16);
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count += loop_rotate_test(B, 16);
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loop_vectorize_test(A, B);
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return A[0] + count;
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}
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