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aarch64: Add more lowerings for the CLIF fma (#6150)

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This commit adds new lowerings to the AArch64 backend of the
element-based `fmla` and `fmls` instructions. These instructions have
one of the multiplicands as an implicit broadcast of a single lane of
another register and can help remove `shuffle` or `dup` instructions
that would otherwise be used to implement them.
This commit is contained in:
Alex Crichton
2023-04-05 12:22:55 -05:00
committed by GitHub
parent bf741955f0
commit 967543eb43
8 changed files with 321 additions and 15 deletions
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20
cranelift/codegen/src/isa/aarch64/inst.isle
View File

@@ -651,6 +651,16 @@
(rm Reg)
(size VectorSize))
;; A vector ALU op modifying a source register.
(VecFmlaElem
(alu_op VecALUModOp)
(rd WritableReg)
(ri Reg)
(rn Reg)
(rm Reg)
(size VectorSize)
(idx u8))
;; Vector two register miscellaneous instruction.
(VecMisc
(op VecMisc2)
@@ -1850,7 +1860,7 @@
(_ Unit (emit (MInst.FpuRR op size dst src))))
dst))
;; Helper for emitting `MInst.VecRRR` instructions which use three registers,
;; Helper for emitting `MInst.VecRRRMod` instructions which use three registers,
;; one of which is both source and output.
(decl vec_rrr_mod (VecALUModOp Reg Reg Reg VectorSize) Reg)
(rule (vec_rrr_mod op src1 src2 src3 size)
@@ -1858,6 +1868,14 @@
(_1 Unit (emit (MInst.VecRRRMod op dst src1 src2 src3 size))))
dst))
;; Helper for emitting `MInst.VecFmlaElem` instructions which use three registers,
;; one of which is both source and output.
(decl vec_fmla_elem (VecALUModOp Reg Reg Reg VectorSize u8) Reg)
(rule (vec_fmla_elem op src1 src2 src3 size idx)
(let ((dst WritableReg (temp_writable_reg $I8X16))
(_1 Unit (emit (MInst.VecFmlaElem op dst src1 src2 src3 size idx))))
dst))
(decl fpu_rri (FPUOpRI Reg) Reg)
(rule (fpu_rri op src)
(let ((dst WritableReg (temp_writable_reg $F64))

39
cranelift/codegen/src/isa/aarch64/inst/emit.rs
View File

@@ -2914,6 +2914,45 @@ impl MachInstEmit for Inst {
};
sink.put4(enc_vec_rrr(top11 | q << 9, rm, bit15_10, rn, rd));
}
&Inst::VecFmlaElem {
rd,
ri,
rn,
rm,
alu_op,
size,
idx,
} => {
let rd = allocs.next_writable(rd);
let ri = allocs.next(ri);
debug_assert_eq!(rd.to_reg(), ri);
let rn = allocs.next(rn);
let rm = allocs.next(rm);
let idx = u32::from(idx);
let (q, _size) = size.enc_size();
let o2 = match alu_op {
VecALUModOp::Fmla => 0b0,
VecALUModOp::Fmls => 0b1,
_ => unreachable!(),
};
let (h, l) = match size {
VectorSize::Size32x4 => {
assert!(idx < 4);
(idx >> 1, idx & 1)
}
VectorSize::Size64x2 => {
assert!(idx < 2);
(idx, 0)
}
_ => unreachable!(),
};
let top11 = 0b000_011111_00 | (q << 9) | (size.enc_float_size() << 1) | l;
let bit15_10 = 0b000100 | (o2 << 4) | (h << 1);
sink.put4(enc_vec_rrr(top11, rm, bit15_10, rn, rd));
}
&Inst::VecLoadReplicate {
rd,
rn,

22
cranelift/codegen/src/isa/aarch64/inst/mod.rs
View File

@@ -812,7 +812,7 @@ fn aarch64_get_operands<F: Fn(VReg) -> VReg>(inst: &Inst, collector: &mut Operan
collector.reg_use(rn);
collector.reg_use(rm);
}
&Inst::VecRRRMod { rd, ri, rn, rm, .. } => {
&Inst::VecRRRMod { rd, ri, rn, rm, .. } | &Inst::VecFmlaElem { rd, ri, rn, rm, .. } => {
collector.reg_reuse_def(rd, 1); // `rd` == `ri`.
collector.reg_use(ri);
collector.reg_use(rn);
@@ -2171,6 +2171,26 @@ impl Inst {
let rm = pretty_print_vreg_vector(rm, size, allocs);
format!("{} {}, {}, {}, {}", op, rd, ri, rn, rm)
}
&Inst::VecFmlaElem {
rd,
ri,
rn,
rm,
alu_op,
size,
idx,
} => {
let (op, size) = match alu_op {
VecALUModOp::Fmla => ("fmla", size),
VecALUModOp::Fmls => ("fmls", size),
_ => unreachable!(),
};
let rd = pretty_print_vreg_vector(rd.to_reg(), size, allocs);
let ri = pretty_print_vreg_vector(ri, size, allocs);
let rn = pretty_print_vreg_vector(rn, size, allocs);
let rm = pretty_print_vreg_element(rm, idx.into(), size.lane_size(), allocs);
format!("{} {}, {}, {}, {}", op, rd, ri, rn, rm)
}
&Inst::VecRRRLong {
rd,
rn,

65
cranelift/codegen/src/isa/aarch64/lower.isle
View File

@@ -513,18 +513,63 @@
;;;; Rules for `fma` ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
(rule (lower (has_type ty @ (multi_lane _ _) (fma x y z)))
(vec_rrr_mod (VecALUModOp.Fmla) z x y (vector_size ty)))
(rule 1 (lower (has_type ty @ (multi_lane _ _) (fma (fneg x) y z)))
(vec_rrr_mod (VecALUModOp.Fmls) z x y (vector_size ty)))
(rule 2 (lower (has_type ty @ (multi_lane _ _) (fma x (fneg y) z)))
(vec_rrr_mod (VecALUModOp.Fmls) z x y (vector_size ty)))
(rule 3 (lower (has_type (ty_scalar_float ty) (fma x y z)))
(rule (lower (has_type (ty_scalar_float ty) (fma x y z)))
(fpu_rrrr (FPUOp3.MAdd) (scalar_size ty) x y z))
;; Delegate vector-based lowerings to helpers below
(rule 1 (lower (has_type ty @ (multi_lane _ _) (fma x y z)))
(lower_fmla (VecALUModOp.Fmla) x y z (vector_size ty)))
;; Lowers a fused-multiply-add operation handling various forms of the
;; instruction to get maximal coverage of what's available on AArch64.
(decl lower_fmla (VecALUModOp Value Value Value VectorSize) Reg)
;; Base case, emit the op requested.
(rule (lower_fmla op x y z size)
(vec_rrr_mod op z x y size))
;; Special case: if one of the multiplicands are a splat then the element-based
;; fma can be used instead with 0 as the element index.
(rule 1 (lower_fmla op (splat x) y z size)
(vec_fmla_elem op z y x size 0))
(rule 2 (lower_fmla op x (splat y) z size)
(vec_fmla_elem op z x y size 0))
;; Special case: if one of the multiplicands is a shuffle to broadcast a
;; single element of a vector then the element-based fma can be used like splat
;; above.
;;
;; Note that in Cranelift shuffle always has i8x16 inputs and outputs so
;; a `bitcast` is matched here explicitly since that's the main way a shuffle
;; output will be fed into this instruction.
(rule 3 (lower_fmla op (bitcast _ (shuffle x x (shuffle32_from_imm n n n n))) y z size @ (VectorSize.Size32x4))
(if-let $true (u64_lt n 4))
(vec_fmla_elem op z y x size n))
(rule 4 (lower_fmla op x (bitcast _ (shuffle y y (shuffle32_from_imm n n n n))) z size @ (VectorSize.Size32x4))
(if-let $true (u64_lt n 4))
(vec_fmla_elem op z x y size n))
(rule 3 (lower_fmla op (bitcast _ (shuffle x x (shuffle64_from_imm n n))) y z size @ (VectorSize.Size64x2))
(if-let $true (u64_lt n 2))
(vec_fmla_elem op z y x size n))
(rule 4 (lower_fmla op x (bitcast _ (shuffle y y (shuffle64_from_imm n n))) z size @ (VectorSize.Size64x2))
(if-let $true (u64_lt n 2))
(vec_fmla_elem op z x y size n))
;; Special case: if one of the multiplicands is `fneg` then peel that away,
;; reverse the operation being performed, and then recurse on `lower_fmla`
;; again to generate the actual instruction.
;;
;; Note that these are the highest priority cases for `lower_fmla` to peel
;; away as many `fneg` operations as possible.
(rule 5 (lower_fmla op (fneg x) y z size)
(lower_fmla (neg_fmla op) x y z size))
(rule 6 (lower_fmla op x (fneg y) z size)
(lower_fmla (neg_fmla op) x y z size))
(decl neg_fmla (VecALUModOp) VecALUModOp)
(rule (neg_fmla (VecALUModOp.Fmla)) (VecALUModOp.Fmls))
(rule (neg_fmla (VecALUModOp.Fmls)) (VecALUModOp.Fmla))
;;;; Rules for `fcopysign` ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
(rule (lower (has_type ty (fcopysign x y)))

2
cranelift/codegen/src/isa/riscv64/inst.isle
View File

@@ -708,8 +708,6 @@
(decl u8_as_i32 (u8) i32)
(extern constructor u8_as_i32 u8_as_i32)
(convert u8 u64 u8_as_u64)
(decl convert_valueregs_reg (ValueRegs) Reg)
(rule (convert_valueregs_reg x)
(value_regs_get x 0))

1
cranelift/codegen/src/prelude.isle
View File

@@ -82,6 +82,7 @@
(decl pure u8_as_u64 (u8) u64)
(extern constructor u8_as_u64 u8_as_u64)
(convert u8 u64 u8_as_u64)
(decl pure u16_as_u64 (u16) u64)
(extern constructor u16_as_u64 u16_as_u64)

149
cranelift/filetests/filetests/isa/aarch64/fma.clif
View File

@@ -157,3 +157,152 @@ block0(v0: f64x2, v1: f64x2, v2: f64x2):
; fmls v0.2d, v5.2d, v1.2d
; ret
function %f32x4_splat0(f32, f32x4, f32x4) -> f32x4 {
block0(v0: f32, v1: f32x4, v2: f32x4):
v3 = splat.f32x4 v0
v4 = fma v3, v1, v2
return v4
}
; VCode:
; block0:
; mov v5.16b, v0.16b
; mov v0.16b, v2.16b
; fmla v0.4s, v0.4s, v1.4s, v5.s[0]
; ret
;
; Disassembled:
; block0: ; offset 0x0
; mov v5.16b, v0.16b
; mov v0.16b, v2.16b
; fmla v0.4s, v1.4s, v5.s[0]
; ret
function %f32x4_splat1(f32x4, f32, f32x4) -> f32x4 {
block0(v0: f32x4, v1: f32, v2: f32x4):
v3 = splat.f32x4 v1
v4 = fneg v0
v5 = fma v4, v3, v2
return v5
}
; VCode:
; block0:
; mov v5.16b, v0.16b
; mov v0.16b, v2.16b
; fmls v0.4s, v0.4s, v5.4s, v1.s[0]
; ret
;
; Disassembled:
; block0: ; offset 0x0
; mov v5.16b, v0.16b
; mov v0.16b, v2.16b
; fmls v0.4s, v5.4s, v1.s[0]
; ret
function %f32x4_splat2(f32x4, f32x4, f32x4) -> f32x4 {
block0(v0: f32x4, v1: f32x4, v2: f32x4):
v3 = bitcast.i8x16 little v0
v4 = shuffle v3, v3, 0x07060504_07060504_07060504_07060504
v5 = bitcast.f32x4 little v4
v6 = fma v5, v1, v2
return v6
}
; VCode:
; block0:
; mov v5.16b, v0.16b
; mov v0.16b, v2.16b
; fmla v0.4s, v0.4s, v1.4s, v5.s[1]
; ret
;
; Disassembled:
; block0: ; offset 0x0
; mov v5.16b, v0.16b
; mov v0.16b, v2.16b
; fmla v0.4s, v1.4s, v5.s[1]
; ret
function %f32x4_splat3(f32x4, f32x4, f32x4) -> f32x4 {
block0(v0: f32x4, v1: f32x4, v2: f32x4):
v3 = bitcast.i8x16 little v1
v4 = shuffle v3, v3, 0x0f0e0d0c_0f0e0d0c_0f0e0d0c_0f0e0d0c
v5 = bitcast.f32x4 little v4
v6 = fneg v5
v7 = fma v0, v6, v2
return v7
}
; VCode:
; block0:
; mov v5.16b, v0.16b
; mov v0.16b, v2.16b
; fmls v0.4s, v0.4s, v5.4s, v1.s[3]
; ret
;
; Disassembled:
; block0: ; offset 0x0
; mov v5.16b, v0.16b
; mov v0.16b, v2.16b
; fmls v0.4s, v5.4s, v1.s[3]
; ret
function %f32x4_splat4(f32x4, f32x4, f32x4) -> f32x4 {
block0(v0: f32x4, v1: f32x4, v2: f32x4):
v3 = bitcast.i8x16 little v1
v4 = shuffle v3, v3, 0x1f1e1d1c_1f1e1d1c_1f1e1d1c_1f1e1d1c
v5 = bitcast.f32x4 little v4
v6 = fma v0, v5, v2
return v6
}
; VCode:
; block0:
; mov v31.16b, v1.16b
; movz w6, #7452
; movk w6, w6, #7966, LSL #16
; dup v17.4s, w6
; mov v30.16b, v31.16b
; tbl v19.16b, { v30.16b, v31.16b }, v17.16b
; mov v23.16b, v0.16b
; mov v0.16b, v2.16b
; fmla v0.4s, v0.4s, v23.4s, v19.4s
; ret
;
; Disassembled:
; block0: ; offset 0x0
; mov v31.16b, v1.16b
; mov w6, #0x1d1c
; movk w6, #0x1f1e, lsl #16
; dup v17.4s, w6
; mov v30.16b, v31.16b
; tbl v19.16b, {v30.16b, v31.16b}, v17.16b
; mov v23.16b, v0.16b
; mov v0.16b, v2.16b
; fmla v0.4s, v23.4s, v19.4s
; ret
function %f64x2_splat0(f64x2, f64x2, f64x2) -> f64x2 {
block0(v0: f64x2, v1: f64x2, v2: f64x2):
v3 = bitcast.i8x16 little v1
v4 = shuffle v3, v3, 0x0f0e0d0c0b0a0908_0f0e0d0c0b0a0908
v5 = bitcast.f64x2 little v4
v6 = fneg v5
v7 = fma v0, v6, v2
return v7
}
; VCode:
; block0:
; mov v5.16b, v0.16b
; mov v0.16b, v2.16b
; fmls v0.2d, v0.2d, v5.2d, v1.d[1]
; ret
;
; Disassembled:
; block0: ; offset 0x0
; mov v5.16b, v0.16b
; mov v0.16b, v2.16b
; fmls v0.2d, v5.2d, v1.d[1]
; ret

36
cranelift/filetests/filetests/runtests/simd-fma.clif
View File

@@ -87,3 +87,39 @@ block0(v0: f64x2, v1: f64x2, v2: f64x2):
; run: %fma_is_nan_f64x2([0x0.0 0x0.0], [+NaN 0x0.0], [0x0.0 +NaN]) == 1
; run: %fma_is_nan_f64x2([-NaN 0x0.0], [0x0.0 -NaN], [0x0.0 0x0.0]) == 1
; run: %fma_is_nan_f64x2([0x0.0 NaN], [0x0.0 NaN], [-NaN NaN]) == 1
function %fma_f32x4_splat1(f32x4, f32, f32x4) -> f32x4 {
block0(v0: f32x4, v1: f32, v2: f32x4):
v3 = splat.f32x4 v1
v4 = fma v0, v3, v2
return v4
}
; run: %fma_f32x4_splat1([0x9.0 0x9.0 0x9.0 0x9.0], 0x9.0, [0x9.0 0x9.0 0x9.0 0x9.0]) == [0x1.680000p6 0x1.680000p6 0x1.680000p6 0x1.680000p6]
; run: %fma_f32x4_splat1([0x1.0 0x2.0 0x3.0 0x4.0], 0x0.0, [0x5.0 0x6.0 0x7.0 0x8.0]) == [0x5.0 0x6.0 0x7.0 0x8.0]
function %fma_f32x4_splat2(f32, f32x4, f32x4) -> f32x4 {
block0(v0: f32, v1: f32x4, v2: f32x4):
v3 = splat.f32x4 v0
v4 = fma v3, v1, v2
return v4
}
; run: %fma_f32x4_splat2(0x9.0, [0x9.0 0x9.0 0x9.0 0x9.0], [0x9.0 0x9.0 0x9.0 0x9.0]) == [0x1.680000p6 0x1.680000p6 0x1.680000p6 0x1.680000p6]
; run: %fma_f32x4_splat2(0x0.0, [0x1.0 0x2.0 0x3.0 0x4.0], [0x5.0 0x6.0 0x7.0 0x8.0]) == [0x5.0 0x6.0 0x7.0 0x8.0]
function %fma_f64x2_splat1(f64x2, f64, f64x2) -> f64x2 {
block0(v0: f64x2, v1: f64, v2: f64x2):
v3 = splat.f64x2 v1
v4 = fma v0, v3, v2
return v4
}
; run: %fma_f64x2_splat1([0x9.0 0x9.0], 0x9.0, [0x9.0 0x9.0]) == [0x1.680000p6 0x1.680000p6]
; run: %fma_f64x2_splat1([0x1.0 0x2.0], 0x0.0, [0x5.0 0x6.0]) == [0x5.0 0x6.0]
function %fma_f64x2_splat2(f64, f64x2, f64x2) -> f64x2 {
block0(v0: f64, v1: f64x2, v2: f64x2):
v3 = splat.f64x2 v0
v4 = fma v3, v1, v2
return v4
}
; run: %fma_f64x2_splat2(0x9.0, [0x9.0 0x9.0], [0x9.0 0x9.0]) == [0x1.680000p6 0x1.680000p6]
; run: %fma_f64x2_splat2(0x0.0, [0x1.0 0x2.0], [0x5.0 0x6.0]) == [0x5.0 0x6.0]