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f2286b0152
on a per-callsite walk of the called function's instructions, in breadth-first order over the potentially reachable set of basic blocks. This is a major shift in how inline cost analysis works to improve the accuracy and rationality of inlining decisions. A brief outline of the algorithm this moves to: - Build a simplification mapping based on the callsite arguments to the function arguments. - Push the entry block onto a worklist of potentially-live basic blocks. - Pop the first block off of the *front* of the worklist (for breadth-first ordering) and walk its instructions using a custom InstVisitor. - For each instruction's operands, re-map them based on the simplification mappings available for the given callsite. - Compute any simplification possible of the instruction after re-mapping, and store that back int othe simplification mapping. - Compute any bonuses, costs, or other impacts of the instruction on the cost metric. - When the terminator is reached, replace any conditional value in the terminator with any simplifications from the mapping we have, and add any successors which are not proven to be dead from these simplifications to the worklist. - Pop the next block off of the front of the worklist, and repeat. - As soon as the cost of inlining exceeds the threshold for the callsite, stop analyzing the function in order to bound cost. The primary goal of this algorithm is to perfectly handle dead code paths. We do not want any code in trivially dead code paths to impact inlining decisions. The previous metric was *extremely* flawed here, and would always subtract the average cost of two successors of a conditional branch when it was proven to become an unconditional branch at the callsite. There was no handling of wildly different costs between the two successors, which would cause inlining when the path actually taken was too large, and no inlining when the path actually taken was trivially simple. There was also no handling of the code *path*, only the immediate successors. These problems vanish completely now. See the added regression tests for the shiny new features -- we skip recursive function calls, SROA-killing instructions, and high cost complex CFG structures when dead at the callsite being analyzed. Switching to this algorithm required refactoring the inline cost interface to accept the actual threshold rather than simply returning a single cost. The resulting interface is pretty bad, and I'm planning to do lots of interface cleanup after this patch. Several other refactorings fell out of this, but I've tried to minimize them for this patch. =/ There is still more cleanup that can be done here. Please point out anything that you see in review. I've worked really hard to try to mirror at least the spirit of all of the previous heuristics in the new model. It's not clear that they are all correct any more, but I wanted to minimize the change in this single patch, it's already a bit ridiculous. One heuristic that is *not* yet mirrored is to allow inlining of functions with a dynamic alloca *if* the caller has a dynamic alloca. I will add this back, but I think the most reasonable way requires changes to the inliner itself rather than just the cost metric, and so I've deferred this for a subsequent patch. The test case is XFAIL-ed until then. As mentioned in the review mail, this seems to make Clang run about 1% to 2% faster in -O0, but makes its binary size grow by just under 4%. I've looked into the 4% growth, and it can be fixed, but requires changes to other parts of the inliner. git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@153812 91177308-0d34-0410-b5e6-96231b3b80d8
156 lines
3.7 KiB
LLVM
156 lines
3.7 KiB
LLVM
; RUN: opt -inline < %s -S -o - -inline-threshold=8 | FileCheck %s
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target datalayout = "p:32:32"
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declare void @llvm.lifetime.start(i64 %size, i8* nocapture %ptr)
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@glbl = external global i32
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define void @outer1() {
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; CHECK: @outer1
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; CHECK-NOT: call void @inner1
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%ptr = alloca i32
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call void @inner1(i32* %ptr)
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ret void
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}
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define void @inner1(i32 *%ptr) {
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%A = load i32* %ptr
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store i32 0, i32* %ptr
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%C = getelementptr inbounds i32* %ptr, i32 0
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%D = getelementptr inbounds i32* %ptr, i32 1
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%E = bitcast i32* %ptr to i8*
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%F = select i1 false, i32* %ptr, i32* @glbl
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call void @llvm.lifetime.start(i64 0, i8* %E)
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ret void
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}
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define void @outer2() {
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; CHECK: @outer2
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; CHECK: call void @inner2
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%ptr = alloca i32
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call void @inner2(i32* %ptr)
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ret void
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}
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; %D poisons this call, scalar-repl can't handle that instruction.
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define void @inner2(i32 *%ptr) {
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%A = load i32* %ptr
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store i32 0, i32* %ptr
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%C = getelementptr inbounds i32* %ptr, i32 0
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%D = getelementptr inbounds i32* %ptr, i32 %A
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%E = bitcast i32* %ptr to i8*
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%F = select i1 false, i32* %ptr, i32* @glbl
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call void @llvm.lifetime.start(i64 0, i8* %E)
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ret void
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}
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define void @outer3() {
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; CHECK: @outer3
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; CHECK-NOT: call void @inner3
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%ptr = alloca i32
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call void @inner3(i32* %ptr, i1 undef)
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ret void
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}
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define void @inner3(i32 *%ptr, i1 %x) {
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%A = icmp eq i32* %ptr, null
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%B = and i1 %x, %A
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br i1 %A, label %bb.true, label %bb.false
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bb.true:
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; This block musn't be counted in the inline cost.
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%t1 = load i32* %ptr
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%t2 = add i32 %t1, 1
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%t3 = add i32 %t2, 1
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%t4 = add i32 %t3, 1
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%t5 = add i32 %t4, 1
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%t6 = add i32 %t5, 1
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%t7 = add i32 %t6, 1
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%t8 = add i32 %t7, 1
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%t9 = add i32 %t8, 1
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%t10 = add i32 %t9, 1
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%t11 = add i32 %t10, 1
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%t12 = add i32 %t11, 1
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%t13 = add i32 %t12, 1
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%t14 = add i32 %t13, 1
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%t15 = add i32 %t14, 1
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%t16 = add i32 %t15, 1
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%t17 = add i32 %t16, 1
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%t18 = add i32 %t17, 1
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%t19 = add i32 %t18, 1
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%t20 = add i32 %t19, 1
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ret void
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bb.false:
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ret void
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}
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define void @outer4(i32 %A) {
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; CHECK: @outer4
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; CHECK-NOT: call void @inner4
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%ptr = alloca i32
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call void @inner4(i32* %ptr, i32 %A)
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ret void
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}
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; %B poisons this call, scalar-repl can't handle that instruction. However, we
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; still want to detect that the icmp and branch *can* be handled.
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define void @inner4(i32 *%ptr, i32 %A) {
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%B = getelementptr inbounds i32* %ptr, i32 %A
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%C = icmp eq i32* %ptr, null
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br i1 %C, label %bb.true, label %bb.false
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bb.true:
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; This block musn't be counted in the inline cost.
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%t1 = load i32* %ptr
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%t2 = add i32 %t1, 1
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%t3 = add i32 %t2, 1
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%t4 = add i32 %t3, 1
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%t5 = add i32 %t4, 1
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%t6 = add i32 %t5, 1
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%t7 = add i32 %t6, 1
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%t8 = add i32 %t7, 1
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%t9 = add i32 %t8, 1
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%t10 = add i32 %t9, 1
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%t11 = add i32 %t10, 1
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%t12 = add i32 %t11, 1
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%t13 = add i32 %t12, 1
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%t14 = add i32 %t13, 1
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%t15 = add i32 %t14, 1
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%t16 = add i32 %t15, 1
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%t17 = add i32 %t16, 1
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%t18 = add i32 %t17, 1
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%t19 = add i32 %t18, 1
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%t20 = add i32 %t19, 1
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ret void
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bb.false:
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ret void
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}
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define void @outer5() {
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; CHECK: @outer5
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; CHECK-NOT: call void @inner5
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%ptr = alloca i32
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call void @inner5(i1 false, i32* %ptr)
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ret void
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}
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; %D poisons this call, scalar-repl can't handle that instruction. However, if
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; the flag is set appropriately, the poisoning instruction is inside of dead
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; code, and so shouldn't be counted.
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define void @inner5(i1 %flag, i32 *%ptr) {
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%A = load i32* %ptr
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store i32 0, i32* %ptr
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%C = getelementptr inbounds i32* %ptr, i32 0
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br i1 %flag, label %if.then, label %exit
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if.then:
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%D = getelementptr inbounds i32* %ptr, i32 %A
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%E = bitcast i32* %ptr to i8*
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%F = select i1 false, i32* %ptr, i32* @glbl
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call void @llvm.lifetime.start(i64 0, i8* %E)
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ret void
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exit:
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ret void
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}
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