Hi, %1 = tail call i32 (i8*, ...) @printf(i8* getelementptr inbounds ([30 x i8], [30 x i8]* @.str, i64 0, i64 0), i32 10) %2 = tail call i32 (i8*, ...) @printf(i8* getelementptr inbounds ([30 x i8], [30 x i8]* @.str.1, i64 0, i64 0), i32 10) When I use -O2 to compile the following C code, I will get the above IR code. I don't understand the explanation of tail-call-optimization in the langref. Could anybody help me understand what tail call means? Thanks. https://llvm.org/docs/CodeGenerator.html#tail-call-optimization #include <stdio.h> int main(void) { const int local = 10; int *ptr = (int*) &local; printf("Initial value of local : %d \n", local); *ptr = 100; printf("Modified value of local: %d \n", local); return 0; } -- Regards, Peng
Tim Northover via llvm-dev
2019-Feb-06 18:35 UTC
[llvm-dev] How to understand "tail" call?
On Wed, 6 Feb 2019 at 18:04, Peng Yu via llvm-dev <llvm-dev at lists.llvm.org> wrote:> in the langref. Could anybody help me understand what tail call means?In its simplest form, when the last thing a function does is call something else then the compiler can deallocate the caller's stack frame early and just jump to the callee rather than actually calling it. For example: void foo() { [...] bar(); } Without the tail-call optimization this might produce: foo: sub $16, %rsp ; Allocate stack space for local variables [...] callq bar add $16, %rsp ; Free up local stack space retq With tail call optimization it would become: foo: sub $16, %rsp ; Allocate stack space for local variables [...] add $16, %rsp ; Free up local stack space jmpq bar Then when bar returns, it actually grabs the return address intended for foo and returns to the correct place. The main benefit is that while bar (and its nested functions) are running, foo isn't consuming any stack space. There are certain embellishments that basically allow "return bar();" as well if the arguments are compatible, but that's the basic idea. Many functional languages that handle loop-like constructs via recursion idioms instead demand their compilers guarantee this optimization will occur, otherwise they'd blow their stack for fairly small iteration counts on loops. In the example you gave, no tail call optimization can occur despite the calls being marked as candidates because main has to materialize the "return 0" code after both calls to printf have happened. If you returned the result of the last printf instead it would probably trigger. Cheers. Tim.
> In the example you gave, no tail call optimization can occur despite > the calls being marked as candidates because main has to materialize > the "return 0" code after both calls to printf have happened.Since the tail call optimization can not be trigger any way, why the generated IR still has the keyword "tail"? Isn't that unnecessary? -- Regards, Peng
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