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// |jit-test| skip-if: true
// Common code to test simple binary operators. See runSimpleBinopTest below.
function expandConstantBinopInputs(op, memtype, inputs) {
let s = '';
let ident = 0;
for ( let [a, b] of inputs ) {
let constlhs = `${memtype.layoutName} ${a.map(jsValueToWasmName).join(' ')}`;
let constrhs = `${memtype.layoutName} ${b.map(jsValueToWasmName).join(' ')}`;
s += `
;; lhs is constant, rhs is variable
(func (export "run_constlhs${ident}")
(v128.store (i32.const 0)
(call $doit_constlhs${ident} (v128.const ${constrhs}))))
(func $doit_constlhs${ident} (param $b v128) (result v128)
(${op} (v128.const ${constlhs}) (local.get $b)))
;; rhs is constant, lhs is variable
(func (export "run_constrhs${ident}")
(v128.store (i32.const 0)
(call $doit_constrhs${ident} (v128.const ${constlhs}))))
(func $doit_constrhs${ident} (param $a v128) (result v128)
(${op} (local.get $a) (v128.const ${constrhs})))
;; both operands are constant
(func (export "run_constboth${ident}")
(v128.store (i32.const 0)
(call $doit_constboth${ident})))
(func $doit_constboth${ident} (result v128)
(${op} (v128.const ${constlhs}) (v128.const ${constrhs})))`
ident++;
}
return s;
}
function insAndMemBinop(op, memtype, resultmemtype, inputs) {
var ins = wasmEvalText(`
(module
(memory (export "mem") 1 1)
;; both arguments are variable
(func (export "run")
(v128.store (i32.const 0)
(call $doit (v128.load (i32.const 16)) (v128.load (i32.const 32)))))
(func $doit (param $a v128) (param $b v128) (result v128)
(${op} (local.get $a) (local.get $b)))
${expandConstantBinopInputs(op, memtype, inputs)})`);
var mem = new memtype(ins.exports.mem.buffer);
var resultmem = !resultmemtype || memtype == resultmemtype ? mem : new resultmemtype(ins.exports.mem.buffer);
return [ins, mem, resultmem];
}
function add(bits) { return (x, y) => sign_extend(x+y, bits) }
function add64(x, y) { return sign_extend(BigInt(x)+BigInt(y), 64) }
function sub(bits) { return (x, y) => sign_extend(x-y, bits) }
function sub64(x, y) { return sign_extend(BigInt(x)-BigInt(y), 64) }
// Even 32-bit multiply can overflow a Number, so always use BigInt
function mul(bits) { return (x, y) => sign_extend(BigInt(x)*BigInt(y), bits) }
function div(x, y) { return x/y }
function min(x, y) { return x < y ? x : y }
function max(x, y) { return x > y ? x : y }
function and(x, y) { return zero_extend(x&y, 8) }
function or(x, y) { return zero_extend(x|y, 8) }
function xor(x, y) { return zero_extend(x^y, 8) }
function andnot(x, y) { return zero_extend(x&~y, 8) }
function avgr(x, y) { return (x + y + 1) >> 1; }
function eq(truth) { return (x,y) => x==y ? truth : 0 }
function ne(truth) { return (x,y) => x!=y ? truth : 0 }
function lt(truth) { return (x, y) => x < y ? truth : 0 }
function gt(truth) { return (x, y) => x > y ? truth : 0 }
function le(truth) { return (x, y) => x <= y ? truth : 0 }
function ge(truth) { return (x, y) => x >= y ? truth : 0 }
function fadd(x, y) { return Math.fround(x+y) }
function fsub(x, y) { return Math.fround(x-y) }
function fmul(x, y) { return Math.fround(x*y) }
function fdiv(x, y) { return Math.fround(x/y) }
function fmin(x, y) {
if (x == y) return x;
if (x < y) return x;
if (y < x) return y;
if (isNaN(x)) return x;
return y;
}
function fmax(x, y) {
if (x == y) return x;
if (x > y) return x;
if (y > x) return y;
if (isNaN(x)) return x;
return y;
}
function dadd(x, y) { return x+y }
function dsub(x, y) { return x-y }
function dmul(x, y) { return x*y }
function ddiv(x, y) { return x/y }
var dmax = fmax;
var dmin = fmin;
function op_sat_s(bits, op) {
return (x, y) => {
return signed_saturate(op(sign_extend(x, bits),
sign_extend(y, bits)),
bits);
}
}
function op_sat_u(bits, op) {
return (x, y) => {
return unsigned_saturate(op(zero_extend(x, bits),
zero_extend(y, bits)),
bits);
}
}
function add_sat_s(bits) {
return op_sat_s(bits, (x,y) => x+y);
}
function sub_sat_s(bits) {
return op_sat_s(bits, (x,y) => x-y);
}
function add_sat_u(bits) {
return op_sat_u(bits, (x,y) => x+y);
}
function sub_sat_u(bits) {
return op_sat_u(bits, (x,y) => x-y);
}
function max_s(bits) {
return (x, y) => {
return sign_extend(max(sign_extend(x, bits),
sign_extend(y, bits)),
bits);
}
}
function min_s(bits) {
return (x, y) => {
return sign_extend(min(sign_extend(x, bits),
sign_extend(y, bits)),
bits);
}
}
function max_u(bits) {
return (x, y) => {
return max(zero_extend(x, bits),
zero_extend(y, bits));
}
}
function min_u(bits) {
return (x, y) => {
return min(zero_extend(x, bits),
zero_extend(y, bits));
}
}
function pmin(x, y) { return y < x ? y : x }
function pmax(x, y) { return x < y ? y : x }
assertEq(max_s(8)(1, 2), 2);
assertEq(max_s(8)(1, 128), 1);
assertEq(min_s(8)(1, 2), 1);
assertEq(min_s(8)(1, 128), -128);
assertEq(max_u(8)(1, 2), 2);
assertEq(max_u(8)(1, 128), 128);
assertEq(min_u(8)(1, 2), 1);
assertEq(min_u(8)(1, 128), 1);
var binopTests =
[['i8x16.add', Int8Array, add(8)],
['i16x8.add', Int16Array, add(16)],
['i32x4.add', Int32Array, add(32)],
['i64x2.add', BigInt64Array, add64],
['i8x16.sub', Int8Array, sub(8)],
['i16x8.sub', Int16Array, sub(16)],
['i32x4.sub', Int32Array, sub(32)],
['i64x2.sub', BigInt64Array, sub64],
['i8x16.add_sat_s', Int8Array, add_sat_s(8)],
['i8x16.add_sat_u', Uint8Array, add_sat_u(8)],
['i16x8.add_sat_s', Int16Array, add_sat_s(16)],
['i16x8.add_sat_u', Uint16Array, add_sat_u(16)],
['i8x16.sub_sat_s', Int8Array, sub_sat_s(8)],
['i8x16.sub_sat_u', Uint8Array, sub_sat_u(8)],
['i16x8.sub_sat_s', Int16Array, sub_sat_s(16)],
['i16x8.sub_sat_u', Uint16Array, sub_sat_u(16)],
['i16x8.mul', Int16Array, mul(16)],
['i32x4.mul', Int32Array, mul(32)],
['i64x2.mul', BigInt64Array, mul(64)],
['i8x16.avgr_u', Uint8Array, avgr],
['i16x8.avgr_u', Uint16Array, avgr],
['i8x16.max_s', Int8Array, max_s(8)],
['i8x16.max_u', Uint8Array, max_u(8)],
['i8x16.min_s', Int8Array, min_s(8)],
['i8x16.min_u', Uint8Array, min_u(8)],
['i16x8.max_s', Int16Array, max_s(16)],
['i16x8.max_u', Uint16Array, max_u(16)],
['i16x8.min_s', Int16Array, min_s(16)],
['i16x8.min_u', Uint16Array, min_u(16)],
['i32x4.max_s', Int32Array, max_s(32)],
['i32x4.max_u', Uint32Array, max_u(32)],
['i32x4.min_s', Int32Array, min_s(32)],
['i32x4.min_u', Uint32Array, min_u(32)],
['v128.and', Uint8Array, and],
['v128.or', Uint8Array, or],
['v128.xor', Uint8Array, xor],
['v128.andnot', Uint8Array, andnot],
['f32x4.add', Float32Array, fadd],
['f32x4.sub', Float32Array, fsub],
['f32x4.mul', Float32Array, fmul],
['f32x4.div', Float32Array, fdiv],
['f32x4.min', Float32Array, fmin],
['f32x4.max', Float32Array, fmax],
['f64x2.add', Float64Array, dadd],
['f64x2.sub', Float64Array, dsub],
['f64x2.mul', Float64Array, dmul],
['f64x2.div', Float64Array, ddiv],
['f64x2.min', Float64Array, dmin],
['f64x2.max', Float64Array, dmax],
['i8x16.eq', Int8Array, eq(-1)],
['i8x16.ne', Int8Array, ne(-1)],
['i8x16.lt_s', Int8Array, lt(-1)],
['i8x16.gt_s', Int8Array, gt(-1)],
['i8x16.le_s', Int8Array, le(-1)],
['i8x16.ge_s', Int8Array, ge(-1)],
['i8x16.gt_u', Uint8Array, gt(0xFF)],
['i8x16.ge_u', Uint8Array, ge(0xFF)],
['i8x16.lt_u', Uint8Array, lt(0xFF)],
['i8x16.le_u', Uint8Array, le(0xFF)],
['i16x8.eq', Int16Array, eq(-1)],
['i16x8.ne', Int16Array, ne(-1)],
['i16x8.lt_s', Int16Array, lt(-1)],
['i16x8.gt_s', Int16Array, gt(-1)],
['i16x8.le_s', Int16Array, le(-1)],
['i16x8.ge_s', Int16Array, ge(-1)],
['i16x8.gt_u', Uint16Array, gt(0xFFFF)],
['i16x8.ge_u', Uint16Array, ge(0xFFFF)],
['i16x8.lt_u', Uint16Array, lt(0xFFFF)],
['i16x8.le_u', Uint16Array, le(0xFFFF)],
['i32x4.eq', Int32Array, eq(-1)],
['i32x4.ne', Int32Array, ne(-1)],
['i32x4.lt_s', Int32Array, lt(-1)],
['i32x4.gt_s', Int32Array, gt(-1)],
['i32x4.le_s', Int32Array, le(-1)],
['i32x4.ge_s', Int32Array, ge(-1)],
['i32x4.gt_u', Uint32Array, gt(0xFFFFFFFF)],
['i32x4.ge_u', Uint32Array, ge(0xFFFFFFFF)],
['i32x4.lt_u', Uint32Array, lt(0xFFFFFFFF)],
['i32x4.le_u', Uint32Array, le(0xFFFFFFFF)],
['f32x4.eq', Float32Array, eq(-1), Int32Array],
['f32x4.ne', Float32Array, ne(-1), Int32Array],
['f32x4.lt', Float32Array, lt(-1), Int32Array],
['f32x4.gt', Float32Array, gt(-1), Int32Array],
['f32x4.le', Float32Array, le(-1), Int32Array],
['f32x4.ge', Float32Array, ge(-1), Int32Array],
['f64x2.eq', Float64Array, eq(-1), BigInt64Array],
['f64x2.ne', Float64Array, ne(-1), BigInt64Array],
['f64x2.lt', Float64Array, lt(-1), BigInt64Array],
['f64x2.gt', Float64Array, gt(-1), BigInt64Array],
['f64x2.le', Float64Array, le(-1), BigInt64Array],
['f64x2.ge', Float64Array, ge(-1), BigInt64Array],
['f32x4.pmin', Float32Array, pmin],
['f32x4.pmax', Float32Array, pmax],
['f64x2.pmin', Float64Array, pmin],
['f64x2.pmax', Float64Array, pmax]]
// Run v128 x v128 -> v128 tests. Inputs are taken from the common input sets,
// placed in memory, the test is run, and the result is extracted and checked.
//
// Runs tests with both operands as variables, either as constant, or both as
// constant. Also checks NaN behavior when appropriate.
//
// All runners that call this should use the same value for `ofParts` and should
// pass different values for `part`, up to `ofParts` - 1.
function runSimpleBinopTest(part, ofParts) {
let partSize = Math.ceil(binopTests.length / ofParts);
let start = part * partSize;
let end = Math.min((part + 1) * partSize, binopTests.length);
for ( let [op, memtype, rop, resultmemtype] of binopTests.slice(start, end) ) {
let inputs = cross(memtype.inputs);
let len = 16/memtype.BYTES_PER_ELEMENT;
let xs = iota(len);
let zero = xs.map(_ => 0);
let [ins, mem, resultmem] = insAndMemBinop(op, memtype, resultmemtype, inputs);
let bitsForF32 = memtype == Float32Array ? new Uint32Array(mem.buffer) : null;
let bitsForF64 = memtype == Float64Array ? new BigInt64Array(mem.buffer) : null;
function testIt(a,b,r) {
set(mem, len, a);
set(mem, len*2, b);
ins.exports.run();
assertSame(get(resultmem, 0, len), r);
// Test signalling NaN superficially by replacing QNaN inputs with SNaN
if (bitsForF32 != null && (a.some(isNaN) || b.some(isNaN))) {
a.forEach((x, i) => { if (isNaN(x)) { bitsForF32[len+i] = 0x7FA0_0000; } });
b.forEach((x, i) => { if (isNaN(x)) { bitsForF32[(len*2)+i] = 0x7FA0_0000; } });
ins.exports.run();
assertSame(get(resultmem, 0, len), r);
}
if (bitsForF64 != null && (a.some(isNaN) || b.some(isNaN))) {
a.forEach((x, i) => { if (isNaN(x)) { bitsForF64[len+i] = 0x7FF4_0000_0000_0000n; } });
b.forEach((x, i) => { if (isNaN(x)) { bitsForF64[(len*2)+i] = 0x7FF4_0000_0000_0000n; } });
ins.exports.run();
assertSame(get(resultmem, 0, len), r);
}
}
function testConstIt(i,r) {
set(resultmem, 0, zero);
ins.exports["run_constlhs" + i]();
assertSame(get(resultmem, 0, len), r);
set(resultmem, 0, zero);
ins.exports["run_constrhs" + i]();
assertSame(get(resultmem, 0, len), r);
set(resultmem, 0, zero);
ins.exports["run_constboth" + i]();
assertSame(get(resultmem, 0, len), r);
}
let i = 0;
for (let [a,b] of inputs) {
let r = xs.map((i) => rop(a[i], b[i]));
testIt(a,b,r);
testConstIt(i,r);
i++;
}
}
}
|
