test/CodeGen/X86/late-remat-update-2.mir - llvm - Git at Google

 # RUN: llc -mtriple=x86_64-- -run-pass=simple-register-coalescing -run-pass=regallocbasic -run-pass=virtregrewriter -late-remat-update-threshold=0 %s -o - | FileCheck %s
 #
 # PR40061: %t2 = %t1 is rematerialized and %t1 is added into toBeUpdated set
 # to postpone its live interval update. After the rematerialization, the live
 # interval of %t1 is larger than necessary. Then %t1 is merged into %t3 and %t1
 # gets removed. After the merge, %t3 contains live interval larger than
 # necessary. Because %t3 is not in toBeUpdated set so its live interval is not
 # updated after register coalescing, and it will break some assumption in
 # regalloc. This test wants to check the live interval is up-to-date after
 # register coalescing.
 #
 # To prevent the test from taking effect only in assert enabled mode, we want
 # to achieve the test goal without dumping regalloc trace. We add strong hint
 # to allocate both %t1 and %t2 to $rax register. If the %t1's live interval is
 # not shrinked properly after register coalescing, %t1 and %t2 will not be
 # both allocated to $rax because of inference, and we utilize the fact to
 # achieve the test goal. But note that the assumption only holds when we use
 # regallocbasic instead of greedy because greedy can update the live interval
 # in the process of splitting.
 #
 # CHECK-LABEL: name: foo
 # CHECK: bb.0.entry:
 # CHECK: $rax = MOV64ri32 -11
 # CHECK: bb.1:
 # CHECK: $rax = MOV64ri32 -11
 # CHECK: $rax = ADD64ri8 killed renamable $rax, 5
 # CHECK: CMP64ri8 renamable $rax
 # CHECK: RET 0, $rax
 # CHECK: bb.2:
 # CHECK: $rax = ADD64ri8 killed renamable $rax, 10
 # CHECK: bb.3:
 # CHECK: RET 0, $rax
 ---
 name:            foo
 body:             |
   bb.0.entry:
     successors: %bb.1(0x15555555), %bb.2(0x6aaaaaab)

     %t1:gr64 = MOV64ri32 -11
     CMP64ri8 %t1, 1, implicit-def $eflags
     JCC_1 %bb.2, 4, implicit killed $eflags
     JMP_1 %bb.1

   bb.1:
     successors: %bb.1(0x80000000)

     %t2:gr64 = COPY %t1
     %t2:gr64 = ADD64ri8 %t2, 5, implicit-def $eflags
     $rax = COPY %t2
     CMP64ri8 %t2, 1, implicit-def $eflags
     JCC_1 %bb.1, 4, implicit killed $eflags
     RET 0, $rax

   bb.2:
     successors: %bb.3(0x80000000)
     %t3:gr64 = COPY %t1
     %t3:gr64 = ADD64ri8 %t3, 10, implicit-def $eflags

   bb.3:
     $rax = COPY %t3
     RET 0, $rax

 ...
	# RUN: llc -mtriple=x86_64-- -run-pass=simple-register-coalescing -run-pass=regallocbasic -run-pass=virtregrewriter -late-remat-update-threshold=0 %s -o - \| FileCheck %s
	#
	# PR40061: %t2 = %t1 is rematerialized and %t1 is added into toBeUpdated set
	# to postpone its live interval update. After the rematerialization, the live
	# interval of %t1 is larger than necessary. Then %t1 is merged into %t3 and %t1
	# gets removed. After the merge, %t3 contains live interval larger than
	# necessary. Because %t3 is not in toBeUpdated set so its live interval is not
	# updated after register coalescing, and it will break some assumption in
	# regalloc. This test wants to check the live interval is up-to-date after
	# register coalescing.
	#
	# To prevent the test from taking effect only in assert enabled mode, we want
	# to achieve the test goal without dumping regalloc trace. We add strong hint
	# to allocate both %t1 and %t2 to $rax register. If the %t1's live interval is
	# not shrinked properly after register coalescing, %t1 and %t2 will not be
	# both allocated to $rax because of inference, and we utilize the fact to
	# achieve the test goal. But note that the assumption only holds when we use
	# regallocbasic instead of greedy because greedy can update the live interval
	# in the process of splitting.
	#
	# CHECK-LABEL: name: foo
	# CHECK: bb.0.entry:
	# CHECK: $rax = MOV64ri32 -11
	# CHECK: bb.1:
	# CHECK: $rax = MOV64ri32 -11
	# CHECK: $rax = ADD64ri8 killed renamable $rax, 5
	# CHECK: CMP64ri8 renamable $rax
	# CHECK: RET 0, $rax
	# CHECK: bb.2:
	# CHECK: $rax = ADD64ri8 killed renamable $rax, 10
	# CHECK: bb.3:
	# CHECK: RET 0, $rax
	---
	name: foo
	body: \|
	bb.0.entry:
	successors: %bb.1(0x15555555), %bb.2(0x6aaaaaab)

	%t1:gr64 = MOV64ri32 -11
	CMP64ri8 %t1, 1, implicit-def $eflags
	JCC_1 %bb.2, 4, implicit killed $eflags
	JMP_1 %bb.1

	bb.1:
	successors: %bb.1(0x80000000)

	%t2:gr64 = COPY %t1
	%t2:gr64 = ADD64ri8 %t2, 5, implicit-def $eflags
	$rax = COPY %t2
	CMP64ri8 %t2, 1, implicit-def $eflags
	JCC_1 %bb.1, 4, implicit killed $eflags
	RET 0, $rax

	bb.2:
	successors: %bb.3(0x80000000)
	%t3:gr64 = COPY %t1
	%t3:gr64 = ADD64ri8 %t3, 10, implicit-def $eflags

	bb.3:
	$rax = COPY %t3
	RET 0, $rax

	...