third_party/subzero/tests_lit/llvm2ice_tests/adv-switch-opt.ll - SwiftShader - Git at Google

 ; This tests the advanced lowering of switch statements. The advanced lowering
 ; uses jump tables, range tests and binary search.

 ; RUN: %p2i -i %s --target=x8632 --filetype=obj --disassemble --args -O2 \
 ; RUN:   | FileCheck %s --check-prefix=CHECK --check-prefix=X8632
 ; RUN: %p2i -i %s --target=x8664 --filetype=obj --disassemble --args -O2 \
 ; RUN:   | FileCheck %s --check-prefix=CHECK --check-prefix=X8664

 ; RUN: %if --need=target_MIPS32 --need=allow_dump \
 ; RUN:   --command %p2i --filetype=asm --assemble --disassemble --target \
 ; RUN:   mips32 -i %s --args -O2 -allow-externally-defined-symbols \
 ; RUN:   | %if --need=target_MIPS32 --need=allow_dump \
 ; RUN:   --command FileCheck --check-prefix MIPS32 %s

 ; Dense but non-continuous ranges should be converted into a jump table.
 define internal i32 @testJumpTable(i32 %a) {
 entry:
   switch i32 %a, label %sw.default [
     i32 91, label %sw.default
     i32 92, label %sw.bb1
     i32 93, label %sw.default
     i32 99, label %sw.bb1
     i32 98, label %sw.default
     i32 96, label %sw.bb1
     i32 97, label %sw.epilog
   ]

 sw.default:
   %add = add i32 %a, 27
   br label %sw.epilog

 sw.bb1:
   %tmp = add i32 %a, 16
   br label %sw.epilog

 sw.epilog:
   %result.1 = phi i32 [ %add, %sw.default ], [ %tmp, %sw.bb1 ], [ 17, %entry ]
   ret i32 %result.1
 }
 ; CHECK-LABEL: testJumpTable
 ; CHECK: sub [[IND:[^,]+]],0x5b
 ; CHECK-NEXT: cmp [[IND]],0x8
 ; CHECK-NEXT: ja
 ; X8632-NEXT: mov [[TARGET:.*]],DWORD PTR {{\[}}[[IND]]*4+0x0] {{[0-9a-f]+}}: R_386_32 .{{.*}}testJumpTable$jumptable
 ; X8632-NEXT: jmp [[TARGET]]
 ; X8664-NEXT: mov {{.}}[[TARGET:.*]],DWORD PTR {{\[}}[[IND]]*4+0x0] {{[0-9a-f]+}}: R_X86_64_32S .{{.*}}testJumpTable$jumptable
 ; X8664-NEXT: jmp {{.}}[[TARGET]]
 ; Note: x86-32 may do "mov eax, [...]; jmp eax", whereas x86-64 may do
 ; "mov eax, [...]; jmp rax", so we assume the all characters except the first
 ; one in the register name will match.

 ; MIPS32-LABEL: testJumpTable
 ; MIPS32: 	move	[[REG1:.*]],{{.*}}
 ; MIPS32: 	li	[[REG2:.*]],91
 ; MIPS32: 	beq	[[REG1]],[[REG2]],6c <.LtestJumpTable$sw.default>
 ; MIPS32: 	nop
 ; MIPS32: 	li	[[REG2:.*]],92
 ; MIPS32: 	beq	[[REG1]],[[REG2]],78 <.LtestJumpTable$sw.bb1>
 ; MIPS32: 	nop
 ; MIPS32: 	li	[[REG2:.*]],93
 ; MIPS32: 	beq	[[REG1]],[[REG2]],6c <.LtestJumpTable$sw.default>
 ; MIPS32: 	nop
 ; MIPS32: 	li	[[REG2:.*]],99
 ; MIPS32: 	beq	[[REG1]],[[REG2]],78 <.LtestJumpTable$sw.bb1>
 ; MIPS32: 	nop
 ; MIPS32: 	li	[[REG2:.*]],98
 ; MIPS32: 	beq	[[REG1]],[[REG2]],6c <.LtestJumpTable$sw.default>
 ; MIPS32: 	nop
 ; MIPS32: 	li	[[REG2:.*]],96
 ; MIPS32: 	beq	[[REG1]],[[REG2]],78 <.LtestJumpTable$sw.bb1>
 ; MIPS32: 	nop
 ; MIPS32: 	li	[[REG2:.*]],97
 ; MIPS32: 	beq	[[REG1]],[[REG2]],60 <.LtestJumpTable$split_entry_sw.epilog_0>
 ; MIPS32: 	nop
 ; MIPS32: 	b	6c <.LtestJumpTable$sw.default>
 ; MIPS32: 	nop

 ; Continuous ranges which map to the same target should be grouped and
 ; efficiently tested.
 define internal i32 @testRangeTest() {
 entry:
   switch i32 10, label %sw.default [
     i32 0, label %sw.epilog
     i32 1, label %sw.epilog
     i32 2, label %sw.epilog
     i32 3, label %sw.epilog
     i32 10, label %sw.bb1
     i32 11, label %sw.bb1
     i32 12, label %sw.bb1
     i32 13, label %sw.bb1
   ]

 sw.default:
   br label %sw.epilog

 sw.bb1:
   br label %sw.epilog

 sw.epilog:
   %result.1 = phi i32 [ 23, %sw.default ], [ 42, %sw.bb1 ], [ 17, %entry ], [ 17, %entry ], [ 17, %entry ], [ 17, %entry ]
   ret i32 %result.1
 }
 ; CHECK-LABEL: testRangeTest
 ; CHECK: cmp {{.*}},0x3
 ; CHECK-NEXT: jbe
 ; CHECK: sub [[REG:[^,]*]],0xa
 ; CHECK-NEXT: cmp [[REG]],0x3
 ; CHECK-NEXT: jbe
 ; CHECK-NEXT: jmp

 ; MIPS32-LABEL: testRangeTest
 ; MIPS32: 	li	[[REG1:.*]],10
 ; MIPS32: 	li	[[REG2:.*]],0
 ; MIPS32: 	beq	[[REG1]],[[REG2]],114 <.LtestRangeTest$split_entry_sw.epilog_0>
 ; MIPS32: 	nop
 ; MIPS32: 	li	[[REG2:.*]],1
 ; MIPS32: 	beq	[[REG1]],[[REG2]],114 <.LtestRangeTest$split_entry_sw.epilog_0>
 ; MIPS32: 	nop
 ; MIPS32: 	li	[[REG2:.*]],2
 ; MIPS32: 	beq	[[REG1]],[[REG2]],114 <.LtestRangeTest$split_entry_sw.epilog_0>
 ; MIPS32: 	nop
 ; MIPS32: 	li	[[REG2:.*]],3
 ; MIPS32: 	beq	[[REG1]],[[REG2]],114 <.LtestRangeTest$split_entry_sw.epilog_0>
 ; MIPS32: 	nop
 ; MIPS32: 	li	[[REG2:.*]],10
 ; MIPS32: 	beq	[[REG1]],[[REG2]],fc <.LtestRangeTest$split_sw.bb1_sw.epilog_2>
 ; MIPS32: 	nop
 ; MIPS32: 	li	[[REG2:.*]],11
 ; MIPS32: 	beq	[[REG1]],[[REG2]],fc <.LtestRangeTest$split_sw.bb1_sw.epilog_2>
 ; MIPS32: 	nop
 ; MIPS32: 	li	[[REG2:.*]],12
 ; MIPS32: 	beq	[[REG1]],[[REG2]],fc <.LtestRangeTest$split_sw.bb1_sw.epilog_2>
 ; MIPS32: 	nop
 ; MIPS32: 	li	[[REG2:.*]],13
 ; MIPS32: 	beq	[[REG1]],[[REG2]],fc <.LtestRangeTest$split_sw.bb1_sw.epilog_2>
 ; MIPS32: 	nop
 ; MIPS32: 	b	108 <.LtestRangeTest$split_sw.default_sw.epilog_1>
 ; MIPS32: 	nop

 ; Sparse cases should be searched with a binary search.
 define internal i32 @testBinarySearch() {
 entry:
   switch i32 10, label %sw.default [
     i32 0, label %sw.epilog
     i32 10, label %sw.epilog
     i32 20, label %sw.bb1
     i32 30, label %sw.bb1
   ]

 sw.default:
   br label %sw.epilog

 sw.bb1:
   br label %sw.epilog

 sw.epilog:
   %result.1 = phi i32 [ 23, %sw.default ], [ 42, %sw.bb1 ], [ 17, %entry ], [ 17, %entry ]
   ret i32 %result.1
 }
 ; CHECK-LABEL: testBinarySearch
 ; CHECK: cmp {{.*}},0x14
 ; CHECK-NEXT: jb
 ; CHECK-NEXT: je
 ; CHECK-NEXT: cmp {{.*}},0x1e
 ; CHECK-NEXT: je
 ; CHECK-NEXT: jmp
 ; CHECK-NEXT: cmp {{.*}},0x0
 ; CHECK-NEXT: je
 ; CHECK-NEXT: cmp {{.*}},0xa
 ; CHECK-NEXT: je
 ; CHECK-NEXT: jmp

 ; MIPS32-LABEL: testBinarySearch
 ; MIPS32: 	li	[[REG1:.*]],10
 ; MIPS32: 	li	[[REG2:.*]],0
 ; MIPS32: 	beq	[[REG1]],[[REG2]],174 <.LtestBinarySearch$split_entry_sw.epilog_0>
 ; MIPS32: 	nop
 ; MIPS32: 	li	[[REG2:.*]],10
 ; MIPS32: 	beq	[[REG1]],[[REG2]],174 <.LtestBinarySearch$split_entry_sw.epilog_0>
 ; MIPS32: 	nop
 ; MIPS32: 	li	[[REG2:.*]],20
 ; MIPS32: 	beq	[[REG1]],[[REG2]],15c <.LtestBinarySearch$split_sw.bb1_sw.epilog_2>
 ; MIPS32: 	nop
 ; MIPS32: 	li	[[REG2:.*]],30
 ; MIPS32: 	beq	[[REG1]],[[REG2]],15c <.LtestBinarySearch$split_sw.bb1_sw.epilog_2>
 ; MIPS32: 	nop
 ; MIPS32: 	b	168 <.LtestBinarySearch$split_sw.default_sw.epilog_1>
 ; MIPS32: 	nop

 ; 64-bit switches where the cases are all 32-bit values should be reduced to a
 ; 32-bit switch after checking the top byte is 0.
 define internal i32 @testSwitchSmall64(i64 %a) {
 entry:
   switch i64 %a, label %sw.default [
     i64 123, label %return
     i64 234, label %sw.bb1
     i64 345, label %sw.bb2
     i64 456, label %sw.bb3
   ]

 sw.bb1:
   br label %return

 sw.bb2:
   br label %return

 sw.bb3:
   br label %return

 sw.default:
   br label %return

 return:
   %retval.0 = phi i32 [ 5, %sw.default ], [ 4, %sw.bb3 ], [ 3, %sw.bb2 ], [ 2, %sw.bb1 ], [ 1, %entry ]
   ret i32 %retval.0
 }
 ; CHECK-LABEL: testSwitchSmall64
 ; X8632: cmp {{.*}},0x0
 ; X8632-NEXT: jne
 ; X8632-NEXT: cmp {{.*}},0x159
 ; X8632-NEXT: jb
 ; X8632-NEXT: je
 ; X8632-NEXT: cmp {{.*}},0x1c8
 ; X8632-NEXT: je
 ; X8632-NEXT: jmp
 ; X8632-NEXT: cmp {{.*}},0x7b
 ; X8632-NEXT: je
 ; X8632-NEXT: cmp {{.*}},0xea
 ; X8632-NEXT: je

 ; MIPS32-LABEL: testSwitchSmall64
 ; MIPS32: 	li	[[REG:.*]],0
 ; MIPS32: 	bne	{{.*}},[[REG]],198 <.LtestSwitchSmall64$local$__0>
 ; MIPS32: 	nop
 ; MIPS32: 	li	[[REG:.*]],123
 ; MIPS32: 	beq	{{.*}},[[REG]],210 <.LtestSwitchSmall64$split_entry_return_0>
 ; MIPS32: 	nop

 ; Test for correct 64-bit lowering.
 ; TODO(ascull): this should generate better code like the 32-bit version
 define internal i32 @testSwitch64(i64 %a) {
 entry:
   switch i64 %a, label %sw.default [
     i64 123, label %return
     i64 234, label %sw.bb1
     i64 345, label %sw.bb2
     i64 78187493520, label %sw.bb3
   ]

 sw.bb1:
   br label %return

 sw.bb2:
   br label %return

 sw.bb3:
   br label %return

 sw.default:
   br label %return

 return:
   %retval.0 = phi i32 [ 5, %sw.default ], [ 4, %sw.bb3 ], [ 3, %sw.bb2 ], [ 2, %sw.bb1 ], [ 1, %entry ]
   ret i32 %retval.0
 }
 ; CHECK-LABEL: testSwitch64
 ; X8632: cmp {{.*}},0x7b
 ; X8632-NEXT: jne
 ; X8632-NEXT: cmp {{.*}},0x0
 ; X8632-NEXT: je
 ; X8632: cmp {{.*}},0xea
 ; X8632-NEXT: jne
 ; X8632-NEXT: cmp {{.*}},0x0
 ; X8632-NEXT: je
 ; X8632: cmp {{.*}},0x159
 ; X8632-NEXT: jne
 ; X8632-NEXT: cmp {{.*}},0x0
 ; X8632-NEXT: je
 ; X8632: cmp {{.*}},0x34567890
 ; X8632-NEXT: jne
 ; X8632-NEXT: cmp {{.*}},0x12
 ; X8632-NEXT: je

 ; MIPS32-LABEL: testSwitch64
 ; MIPS32: 	li	[[REG:.*]],0
 ; MIPS32: 	bne	{{.*}},[[REG]],238 <.LtestSwitch64$local$__0>
 ; MIPS32: 	nop
 ; MIPS32: 	li	[[REG:.*]],123
 ; MIPS32: 	beq	{{.*}},[[REG]],2b4 <.LtestSwitch64$split_entry_return_0>
 ; MIPS32: 	nop

 ; Test for correct 64-bit jump table with UINT64_MAX as one of the values.
 define internal i32 @testJumpTable64(i64 %a) {
 entry:
   switch i64 %a, label %sw.default [
     i64 -6, label %return
     i64 -4, label %sw.bb1
     i64 -3, label %sw.bb2
     i64 -1, label %sw.bb3
   ]

 sw.bb1:
   br label %return

 sw.bb2:
   br label %return

 sw.bb3:
   br label %return

 sw.default:
   br label %return

 return:
   %retval.0 = phi i32 [ 5, %sw.default ], [ 4, %sw.bb3 ], [ 3, %sw.bb2 ], [ 2, %sw.bb1 ], [ 1, %entry ]
   ret i32 %retval.0
 }

 ; TODO(ascull): this should generate a jump table. For now, just make sure it
 ; doesn't crash the compiler.
 ; CHECK-LABEL: testJumpTable64
	; This tests the advanced lowering of switch statements. The advanced lowering
	; uses jump tables, range tests and binary search.

	; RUN: %p2i -i %s --target=x8632 --filetype=obj --disassemble --args -O2 \
	; RUN: \| FileCheck %s --check-prefix=CHECK --check-prefix=X8632
	; RUN: %p2i -i %s --target=x8664 --filetype=obj --disassemble --args -O2 \
	; RUN: \| FileCheck %s --check-prefix=CHECK --check-prefix=X8664

	; RUN: %if --need=target_MIPS32 --need=allow_dump \
	; RUN: --command %p2i --filetype=asm --assemble --disassemble --target \
	; RUN: mips32 -i %s --args -O2 -allow-externally-defined-symbols \
	; RUN: \| %if --need=target_MIPS32 --need=allow_dump \
	; RUN: --command FileCheck --check-prefix MIPS32 %s

	; Dense but non-continuous ranges should be converted into a jump table.
	define internal i32 @testJumpTable(i32 %a) {
	entry:
	switch i32 %a, label %sw.default [
	i32 91, label %sw.default
	i32 92, label %sw.bb1
	i32 93, label %sw.default
	i32 99, label %sw.bb1
	i32 98, label %sw.default
	i32 96, label %sw.bb1
	i32 97, label %sw.epilog
	]

	sw.default:
	%add = add i32 %a, 27
	br label %sw.epilog

	sw.bb1:
	%tmp = add i32 %a, 16
	br label %sw.epilog

	sw.epilog:
	%result.1 = phi i32 [ %add, %sw.default ], [ %tmp, %sw.bb1 ], [ 17, %entry ]
	ret i32 %result.1
	}
	; CHECK-LABEL: testJumpTable
	; CHECK: sub [[IND:[^,]+]],0x5b
	; CHECK-NEXT: cmp [[IND]],0x8
	; CHECK-NEXT: ja
	; X8632-NEXT: mov [[TARGET:.]],DWORD PTR {{\[}}[[IND]]4+0x0] {{[0-9a-f]+}}: R_386_32 .{{.*}}testJumpTable$jumptable
	; X8632-NEXT: jmp [[TARGET]]
	; X8664-NEXT: mov {{.}}[[TARGET:.]],DWORD PTR {{\[}}[[IND]]4+0x0] {{[0-9a-f]+}}: R_X86_64_32S .{{.*}}testJumpTable$jumptable
	; X8664-NEXT: jmp {{.}}[[TARGET]]
	; Note: x86-32 may do "mov eax, [...]; jmp eax", whereas x86-64 may do
	; "mov eax, [...]; jmp rax", so we assume the all characters except the first
	; one in the register name will match.

	; MIPS32-LABEL: testJumpTable
	; MIPS32: move [[REG1:.]],{{.}}
	; MIPS32: li [[REG2:.*]],91
	; MIPS32: beq [[REG1]],[[REG2]],6c <.LtestJumpTable$sw.default>
	; MIPS32: nop
	; MIPS32: li [[REG2:.*]],92
	; MIPS32: beq [[REG1]],[[REG2]],78 <.LtestJumpTable$sw.bb1>
	; MIPS32: nop
	; MIPS32: li [[REG2:.*]],93
	; MIPS32: beq [[REG1]],[[REG2]],6c <.LtestJumpTable$sw.default>
	; MIPS32: nop
	; MIPS32: li [[REG2:.*]],99
	; MIPS32: beq [[REG1]],[[REG2]],78 <.LtestJumpTable$sw.bb1>
	; MIPS32: nop
	; MIPS32: li [[REG2:.*]],98
	; MIPS32: beq [[REG1]],[[REG2]],6c <.LtestJumpTable$sw.default>
	; MIPS32: nop
	; MIPS32: li [[REG2:.*]],96
	; MIPS32: beq [[REG1]],[[REG2]],78 <.LtestJumpTable$sw.bb1>
	; MIPS32: nop
	; MIPS32: li [[REG2:.*]],97
	; MIPS32: beq [[REG1]],[[REG2]],60 <.LtestJumpTable$split_entry_sw.epilog_0>
	; MIPS32: nop
	; MIPS32: b 6c <.LtestJumpTable$sw.default>
	; MIPS32: nop

	; Continuous ranges which map to the same target should be grouped and
	; efficiently tested.
	define internal i32 @testRangeTest() {
	entry:
	switch i32 10, label %sw.default [
	i32 0, label %sw.epilog
	i32 1, label %sw.epilog
	i32 2, label %sw.epilog
	i32 3, label %sw.epilog
	i32 10, label %sw.bb1
	i32 11, label %sw.bb1
	i32 12, label %sw.bb1
	i32 13, label %sw.bb1
	]

	sw.default:
	br label %sw.epilog

	sw.bb1:
	br label %sw.epilog

	sw.epilog:
	%result.1 = phi i32 [ 23, %sw.default ], [ 42, %sw.bb1 ], [ 17, %entry ], [ 17, %entry ], [ 17, %entry ], [ 17, %entry ]
	ret i32 %result.1
	}
	; CHECK-LABEL: testRangeTest
	; CHECK: cmp {{.*}},0x3
	; CHECK-NEXT: jbe
	; CHECK: sub [[REG:[^,]*]],0xa
	; CHECK-NEXT: cmp [[REG]],0x3
	; CHECK-NEXT: jbe
	; CHECK-NEXT: jmp

	; MIPS32-LABEL: testRangeTest
	; MIPS32: li [[REG1:.*]],10
	; MIPS32: li [[REG2:.*]],0
	; MIPS32: beq [[REG1]],[[REG2]],114 <.LtestRangeTest$split_entry_sw.epilog_0>
	; MIPS32: nop
	; MIPS32: li [[REG2:.*]],1
	; MIPS32: beq [[REG1]],[[REG2]],114 <.LtestRangeTest$split_entry_sw.epilog_0>
	; MIPS32: nop
	; MIPS32: li [[REG2:.*]],2
	; MIPS32: beq [[REG1]],[[REG2]],114 <.LtestRangeTest$split_entry_sw.epilog_0>
	; MIPS32: nop
	; MIPS32: li [[REG2:.*]],3
	; MIPS32: beq [[REG1]],[[REG2]],114 <.LtestRangeTest$split_entry_sw.epilog_0>
	; MIPS32: nop
	; MIPS32: li [[REG2:.*]],10
	; MIPS32: beq [[REG1]],[[REG2]],fc <.LtestRangeTest$split_sw.bb1_sw.epilog_2>
	; MIPS32: nop
	; MIPS32: li [[REG2:.*]],11
	; MIPS32: beq [[REG1]],[[REG2]],fc <.LtestRangeTest$split_sw.bb1_sw.epilog_2>
	; MIPS32: nop
	; MIPS32: li [[REG2:.*]],12
	; MIPS32: beq [[REG1]],[[REG2]],fc <.LtestRangeTest$split_sw.bb1_sw.epilog_2>
	; MIPS32: nop
	; MIPS32: li [[REG2:.*]],13
	; MIPS32: beq [[REG1]],[[REG2]],fc <.LtestRangeTest$split_sw.bb1_sw.epilog_2>
	; MIPS32: nop
	; MIPS32: b 108 <.LtestRangeTest$split_sw.default_sw.epilog_1>
	; MIPS32: nop

	; Sparse cases should be searched with a binary search.
	define internal i32 @testBinarySearch() {
	entry:
	switch i32 10, label %sw.default [
	i32 0, label %sw.epilog
	i32 10, label %sw.epilog
	i32 20, label %sw.bb1
	i32 30, label %sw.bb1
	]

	sw.default:
	br label %sw.epilog

	sw.bb1:
	br label %sw.epilog

	sw.epilog:
	%result.1 = phi i32 [ 23, %sw.default ], [ 42, %sw.bb1 ], [ 17, %entry ], [ 17, %entry ]
	ret i32 %result.1
	}
	; CHECK-LABEL: testBinarySearch
	; CHECK: cmp {{.*}},0x14
	; CHECK-NEXT: jb
	; CHECK-NEXT: je
	; CHECK-NEXT: cmp {{.*}},0x1e
	; CHECK-NEXT: je
	; CHECK-NEXT: jmp
	; CHECK-NEXT: cmp {{.*}},0x0
	; CHECK-NEXT: je
	; CHECK-NEXT: cmp {{.*}},0xa
	; CHECK-NEXT: je
	; CHECK-NEXT: jmp

	; MIPS32-LABEL: testBinarySearch
	; MIPS32: li [[REG1:.*]],10
	; MIPS32: li [[REG2:.*]],0
	; MIPS32: beq [[REG1]],[[REG2]],174 <.LtestBinarySearch$split_entry_sw.epilog_0>
	; MIPS32: nop
	; MIPS32: li [[REG2:.*]],10
	; MIPS32: beq [[REG1]],[[REG2]],174 <.LtestBinarySearch$split_entry_sw.epilog_0>
	; MIPS32: nop
	; MIPS32: li [[REG2:.*]],20
	; MIPS32: beq [[REG1]],[[REG2]],15c <.LtestBinarySearch$split_sw.bb1_sw.epilog_2>
	; MIPS32: nop
	; MIPS32: li [[REG2:.*]],30
	; MIPS32: beq [[REG1]],[[REG2]],15c <.LtestBinarySearch$split_sw.bb1_sw.epilog_2>
	; MIPS32: nop
	; MIPS32: b 168 <.LtestBinarySearch$split_sw.default_sw.epilog_1>
	; MIPS32: nop

	; 64-bit switches where the cases are all 32-bit values should be reduced to a
	; 32-bit switch after checking the top byte is 0.
	define internal i32 @testSwitchSmall64(i64 %a) {
	entry:
	switch i64 %a, label %sw.default [
	i64 123, label %return
	i64 234, label %sw.bb1
	i64 345, label %sw.bb2
	i64 456, label %sw.bb3
	]

	sw.bb1:
	br label %return

	sw.bb2:
	br label %return

	sw.bb3:
	br label %return

	sw.default:
	br label %return

	return:
	%retval.0 = phi i32 [ 5, %sw.default ], [ 4, %sw.bb3 ], [ 3, %sw.bb2 ], [ 2, %sw.bb1 ], [ 1, %entry ]
	ret i32 %retval.0
	}
	; CHECK-LABEL: testSwitchSmall64
	; X8632: cmp {{.*}},0x0
	; X8632-NEXT: jne
	; X8632-NEXT: cmp {{.*}},0x159
	; X8632-NEXT: jb
	; X8632-NEXT: je
	; X8632-NEXT: cmp {{.*}},0x1c8
	; X8632-NEXT: je
	; X8632-NEXT: jmp
	; X8632-NEXT: cmp {{.*}},0x7b
	; X8632-NEXT: je
	; X8632-NEXT: cmp {{.*}},0xea
	; X8632-NEXT: je

	; MIPS32-LABEL: testSwitchSmall64
	; MIPS32: li [[REG:.*]],0
	; MIPS32: bne {{.*}},[[REG]],198 <.LtestSwitchSmall64$local$__0>
	; MIPS32: nop
	; MIPS32: li [[REG:.*]],123
	; MIPS32: beq {{.*}},[[REG]],210 <.LtestSwitchSmall64$split_entry_return_0>
	; MIPS32: nop

	; Test for correct 64-bit lowering.
	; TODO(ascull): this should generate better code like the 32-bit version
	define internal i32 @testSwitch64(i64 %a) {
	entry:
	switch i64 %a, label %sw.default [
	i64 123, label %return
	i64 234, label %sw.bb1
	i64 345, label %sw.bb2
	i64 78187493520, label %sw.bb3
	]

	sw.bb1:
	br label %return

	sw.bb2:
	br label %return

	sw.bb3:
	br label %return

	sw.default:
	br label %return

	return:
	%retval.0 = phi i32 [ 5, %sw.default ], [ 4, %sw.bb3 ], [ 3, %sw.bb2 ], [ 2, %sw.bb1 ], [ 1, %entry ]
	ret i32 %retval.0
	}
	; CHECK-LABEL: testSwitch64
	; X8632: cmp {{.*}},0x7b
	; X8632-NEXT: jne
	; X8632-NEXT: cmp {{.*}},0x0
	; X8632-NEXT: je
	; X8632: cmp {{.*}},0xea
	; X8632-NEXT: jne
	; X8632-NEXT: cmp {{.*}},0x0
	; X8632-NEXT: je
	; X8632: cmp {{.*}},0x159
	; X8632-NEXT: jne
	; X8632-NEXT: cmp {{.*}},0x0
	; X8632-NEXT: je
	; X8632: cmp {{.*}},0x34567890
	; X8632-NEXT: jne
	; X8632-NEXT: cmp {{.*}},0x12
	; X8632-NEXT: je

	; MIPS32-LABEL: testSwitch64
	; MIPS32: li [[REG:.*]],0
	; MIPS32: bne {{.*}},[[REG]],238 <.LtestSwitch64$local$__0>
	; MIPS32: nop
	; MIPS32: li [[REG:.*]],123
	; MIPS32: beq {{.*}},[[REG]],2b4 <.LtestSwitch64$split_entry_return_0>
	; MIPS32: nop

	; Test for correct 64-bit jump table with UINT64_MAX as one of the values.
	define internal i32 @testJumpTable64(i64 %a) {
	entry:
	switch i64 %a, label %sw.default [
	i64 -6, label %return
	i64 -4, label %sw.bb1
	i64 -3, label %sw.bb2
	i64 -1, label %sw.bb3
	]

	sw.bb1:
	br label %return

	sw.bb2:
	br label %return

	sw.bb3:
	br label %return

	sw.default:
	br label %return

	return:
	%retval.0 = phi i32 [ 5, %sw.default ], [ 4, %sw.bb3 ], [ 3, %sw.bb2 ], [ 2, %sw.bb1 ], [ 1, %entry ]
	ret i32 %retval.0
	}

	; TODO(ascull): this should generate a jump table. For now, just make sure it
	; doesn't crash the compiler.
	; CHECK-LABEL: testJumpTable64