wasmtime/cranelift/filetests/parser/tiny.clif

test cat

; The smallest possible function.
function %minimal() {
ebb0:
    trap user0
}
; sameln: function %minimal() fast {
; nextln: ebb0:
; nextln:     trap user0
; nextln: }

; Create and use values.
; Polymorphic instructions with type suffix.
function %ivalues() {
ebb0:
    v0 = iconst.i32 2
    v1 = iconst.i8 6
    v2 = ishl v0, v1
}
; sameln: function %ivalues() fast {
; nextln: ebb0:
; nextln:     v0 = iconst.i32 2
; nextln:     v1 = iconst.i8 6
; nextln:     v2 = ishl v0, v1
; nextln: }

; Create and use values.
; Polymorphic instructions with type suffix.
function %bvalues() {
ebb0:
    v0 = bconst.b32 true
    v1 = bconst.b8 false
    v2 = bextend.b32 v1
    v3 = bxor v0, v2
}
; sameln: function %bvalues() fast {
; nextln: ebb0:
; nextln:     v0 = bconst.b32 true
; nextln:     v1 = bconst.b8 false
; nextln:     v2 = bextend.b32 v1
; nextln:     v3 = bxor v0, v2
; nextln: }

; Polymorphic instruction controlled by second operand.
function %select() {
ebb0(v90: i32, v91: i32, v92: b1):
    v0 = select v92, v90, v91
}
; sameln: function %select() fast {
; nextln: ebb0(v90: i32, v91: i32, v92: b1):
; nextln:     v0 = select v92, v90, v91
; nextln: }

; Polymorphic instruction controlled by third operand.
function %selectif() system_v {
ebb0(v95: i32, v96: i32, v97: b1):
    v98 = selectif.i32 eq v97, v95, v96
}
; sameln: function %selectif() system_v {
; nextln: ebb0(v95: i32, v96: i32, v97: b1):
; nextln: v98 = selectif.i32 eq v97, v95, v96
; nextln: }

; Lane indexes.
function %lanes() {
ebb0:
    v0 = iconst.i32x4 2
    v1 = extractlane v0, 3
    v2 = insertlane v0, 1, v1
}
; sameln: function %lanes() fast {
; nextln: ebb0:
; nextln:     v0 = iconst.i32x4 2
; nextln:     v1 = extractlane v0, 3
; nextln:     v2 = insertlane v0, 1, v1
; nextln: }

; Integer condition codes.
function %icmp(i32, i32) {
ebb0(v90: i32, v91: i32):
    v0 = icmp eq v90, v91
    v1 = icmp ult v90, v91
    v2 = icmp_imm sge v90, -12
    v3 = irsub_imm v91, 45
    br_icmp eq v90, v91, ebb0(v91, v90)
}
; sameln: function %icmp(i32, i32) fast {
; nextln: ebb0(v90: i32, v91: i32):
; nextln:     v0 = icmp eq v90, v91
; nextln:     v1 = icmp ult v90, v91
; nextln:     v2 = icmp_imm sge v90, -12
; nextln:     v3 = irsub_imm v91, 45
; nextln:     br_icmp eq v90, v91, ebb0(v91, v90)
; nextln: }

; Floating condition codes.
function %fcmp(f32, f32) {
ebb0(v90: f32, v91: f32):
    v0 = fcmp eq v90, v91
    v1 = fcmp uno v90, v91
    v2 = fcmp lt v90, v91
}
; sameln: function %fcmp(f32, f32) fast {
; nextln: ebb0(v90: f32, v91: f32):
; nextln:     v0 = fcmp eq v90, v91
; nextln:     v1 = fcmp uno v90, v91
; nextln:     v2 = fcmp lt v90, v91
; nextln: }

; The bitcast instruction has two type variables: The controlling type variable
; controls the outout type, and the input type is a free variable.
function %bitcast(i32, f32) {
ebb0(v90: i32, v91: f32):
    v0 = bitcast.i8x4 v90
    v1 = bitcast.i32 v91
}
; sameln: function %bitcast(i32, f32) fast {
; nextln: ebb0(v90: i32, v91: f32):
; nextln:     v0 = bitcast.i8x4 v90
; nextln:     v1 = bitcast.i32 v91
; nextln: }

; Stack slot references
function %stack() {
    ss10 = spill_slot 8
    ss2 = explicit_slot 4
    ss3 = incoming_arg 4, offset 8
    ss4 = outgoing_arg 4
    ss5 = emergency_slot 4

ebb0:
    v1 = stack_load.i32 ss10
    v2 = stack_load.i32 ss10+4
    stack_store v1, ss10+2
    stack_store v2, ss2
}
; sameln: function %stack() fast {
; check:     ss2 = explicit_slot 4
; check:     ss3 = incoming_arg 4, offset 8
; check:     ss4 = outgoing_arg 4
; check:     ss5 = emergency_slot 4
; check:     ss10 = spill_slot 8

; check: ebb0:
; nextln: v1 = stack_load.i32 ss10
; nextln: v2 = stack_load.i32 ss10+4
; nextln: stack_store v1, ss10+2
; nextln: stack_store v2, ss2

; Memory access instructions.
function %memory(i32) {
ebb0(v1: i32):
    v2 = load.i64 v1
    v3 = load.i64 aligned v1
    v4 = load.i64 notrap v1
    v5 = load.i64 notrap aligned v1
    v6 = load.i64 aligned notrap v1
    v7 = load.i64 v1-12
    v8 = load.i64 notrap v1+0x1_0000
    v9 = load_complex.i64 v1+v2
    v10 = load_complex.i64 v1+v2+0x1
    store v2, v1
    store aligned v3, v1+12
    store notrap aligned v3, v1-12
    store_complex v3, v1+v2
    store_complex v3, v1+v2+0x1
}
; sameln: function %memory(i32) fast {
; nextln: ebb0(v1: i32):
; nextln:     v2 = load.i64 v1
; nextln:     v3 = load.i64 aligned v1
; nextln:     v4 = load.i64 notrap v1
; nextln:     v5 = load.i64 notrap aligned v1
; nextln:     v6 = load.i64 notrap aligned v1
; nextln:     v7 = load.i64 v1-12
; nextln:     v8 = load.i64 notrap v1+0x0001_0000
; nextln:     v9 = load_complex.i64 v1+v2
; nextln:     v10 = load_complex.i64 v1+v2+1
; nextln:     store v2, v1
; nextln:     store aligned v3, v1+12
; nextln:     store notrap aligned v3, v1-12
; nextln:     store_complex v3, v1+v2
; nextln:     store_complex v3, v1+v2+1

; Register diversions.
; This test file has no ISA, so we can unly use register unit numbers.
function %diversion(i32) {
    ss0 = spill_slot 4

ebb0(v1: i32):
    regmove v1, %10 -> %20
    regmove v1, %20 -> %10
    regspill v1, %10 -> ss0
    regfill v1, ss0 -> %10
    return
}
; sameln: function %diversion(i32) fast {
; nextln:     ss0 = spill_slot 4
; check: ebb0(v1: i32):
; nextln:     regmove v1, %10 -> %20
; nextln:     regmove v1, %20 -> %10
; nextln:     regspill v1, %10 -> ss0
; nextln:     regfill v1, ss0 -> %10
; nextln:     return
; nextln: }

; Register copies.
function %copy_special() {
ebb0:
    copy_special %10 -> %20
    copy_special %20 -> %10
    return
}
; sameln: function %copy_special() fast {
; nextln: ebb0:
; nextln:     copy_special %10 -> %20
; nextln:     copy_special %20 -> %10
; nextln:     return
; nextln: }

function %cond_traps(i32) {
ebb0(v0: i32):
    trapz v0, stk_ovf
    v1 = ifcmp_imm v0, 5
    trapif ugt v1, oob
    v2 = bitcast.f32 v1
    v3 = ffcmp v2, v2
    trapff uno v3, int_ovf
    return
}
; sameln: function %cond_traps(i32)
; nextln: ebb0(v0: i32):
; nextln:     trapz v0, stk_ovf
; nextln:     v1 = ifcmp_imm v0, 5
; nextln:     trapif ugt v1, oob
; nextln:     v2 = bitcast.f32 v1
; nextln:     v3 = ffcmp v2, v2
; nextln:     trapff uno v3, int_ovf
; nextln:     return
; nextln: }