//===- PolynomialApproximation.cpp - Approximate math operations ----------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// // // This file implements expansion of math operations to fast approximations // that do not rely on any of the library functions. // //===----------------------------------------------------------------------===// #include #include #include "mlir/Dialect/Arithmetic/IR/Arithmetic.h" #include "mlir/Dialect/Math/IR/Math.h" #include "mlir/Dialect/Math/Transforms/Approximation.h" #include "mlir/Dialect/Math/Transforms/Passes.h" #include "mlir/Dialect/Utils/IndexingUtils.h" #include "mlir/Dialect/Vector/IR/VectorOps.h" #include "mlir/Dialect/Vector/Utils/VectorUtils.h" #include "mlir/Dialect/X86Vector/X86VectorDialect.h" #include "mlir/IR/Builders.h" #include "mlir/IR/BuiltinTypes.h" #include "mlir/IR/ImplicitLocOpBuilder.h" #include "mlir/IR/OpDefinition.h" #include "mlir/IR/PatternMatch.h" #include "mlir/IR/TypeUtilities.h" #include "mlir/Transforms/DialectConversion.h" #include "mlir/Transforms/GreedyPatternRewriteDriver.h" #include "llvm/ADT/ArrayRef.h" #include "llvm/ADT/STLExtras.h" using namespace mlir; using namespace mlir::math; using namespace mlir::vector; // Returns vector shape if the type is a vector. Returns an empty shape if it is // not a vector. static ArrayRef vectorShape(Type type) { auto vectorType = type.dyn_cast(); return vectorType ? vectorType.getShape() : ArrayRef(); } static ArrayRef vectorShape(Value value) { return vectorShape(value.getType()); } //----------------------------------------------------------------------------// // Broadcast scalar types and values into vector types and values. //----------------------------------------------------------------------------// // Broadcasts scalar type into vector type (iff shape is non-scalar). static Type broadcast(Type type, ArrayRef shape) { assert(!type.isa() && "must be scalar type"); return !shape.empty() ? VectorType::get(shape, type) : type; } // Broadcasts scalar value into vector (iff shape is non-scalar). static Value broadcast(ImplicitLocOpBuilder &builder, Value value, ArrayRef shape) { assert(!value.getType().isa() && "must be scalar value"); auto type = broadcast(value.getType(), shape); return !shape.empty() ? builder.create(type, value) : value; } //----------------------------------------------------------------------------// // Helper function to handle n-D vectors with 1-D operations. //----------------------------------------------------------------------------// // Expands and unrolls n-D vector operands into multiple fixed size 1-D vectors // and calls the compute function with 1-D vector operands. Stitches back all // results into the original n-D vector result. // // Examples: vectorWidth = 8 // - vector<4x8xf32> unrolled 4 times // - vector<16xf32> expanded to vector<2x8xf32> and unrolled 2 times // - vector<4x16xf32> expanded to vector<4x2x8xf32> and unrolled 4*2 times // // Some math approximations rely on ISA-specific operations that only accept // fixed size 1-D vectors (e.g. AVX expects vectors of width 8). // // It is the caller's responsibility to verify that the inner dimension is // divisible by the vectorWidth, and that all operands have the same vector // shape. static Value handleMultidimensionalVectors(ImplicitLocOpBuilder &builder, ValueRange operands, int64_t vectorWidth, llvm::function_ref compute) { assert(!operands.empty() && "operands must be not empty"); assert(vectorWidth > 0 && "vector width must be larger than 0"); VectorType inputType = operands[0].getType().cast(); ArrayRef inputShape = inputType.getShape(); // If input shape matches target vector width, we can just call the // user-provided compute function with the operands. if (inputShape == llvm::makeArrayRef(vectorWidth)) return compute(operands); // Check if the inner dimension has to be expanded, or we can directly iterate // over the outer dimensions of the vector. int64_t innerDim = inputShape.back(); int64_t expansionDim = innerDim / vectorWidth; assert((innerDim % vectorWidth == 0) && "invalid inner dimension size"); // Maybe expand operands to the higher rank vector shape that we'll use to // iterate over and extract one dimensional vectors. SmallVector expandedShape(inputShape.begin(), inputShape.end()); SmallVector expandedOperands(operands); if (expansionDim > 1) { // Expand shape from [..., innerDim] to [..., expansionDim, vectorWidth]. expandedShape.insert(expandedShape.end() - 1, expansionDim); expandedShape.back() = vectorWidth; for (unsigned i = 0; i < operands.size(); ++i) { auto operand = operands[i]; auto eltType = operand.getType().cast().getElementType(); auto expandedType = VectorType::get(expandedShape, eltType); expandedOperands[i] = builder.create(expandedType, operand); } } // Iterate over all outer dimensions of the compute shape vector type. auto iterationDims = ArrayRef(expandedShape).drop_back(); int64_t maxLinearIndex = computeMaxLinearIndex(iterationDims); SmallVector ones(iterationDims.size(), 1); auto strides = computeStrides(iterationDims, ones); // Compute results for each one dimensional vector. SmallVector results(maxLinearIndex); for (int64_t i = 0; i < maxLinearIndex; ++i) { auto offsets = delinearize(strides, i); SmallVector extracted(expandedOperands.size()); for (const auto &tuple : llvm::enumerate(expandedOperands)) extracted[tuple.index()] = builder.create(tuple.value(), offsets); results[i] = compute(extracted); } // Stitch results together into one large vector. Type resultEltType = results[0].getType().cast().getElementType(); Type resultExpandedType = VectorType::get(expandedShape, resultEltType); Value result = builder.create( resultExpandedType, builder.getZeroAttr(resultExpandedType)); for (int64_t i = 0; i < maxLinearIndex; ++i) result = builder.create(results[i], result, delinearize(strides, i)); // Reshape back to the original vector shape. return builder.create( VectorType::get(inputShape, resultEltType), result); } //----------------------------------------------------------------------------// // Helper functions to create constants. //----------------------------------------------------------------------------// static Value f32Cst(ImplicitLocOpBuilder &builder, float value) { return builder.create(builder.getF32FloatAttr(value)); } static Value i32Cst(ImplicitLocOpBuilder &builder, int32_t value) { return builder.create(builder.getI32IntegerAttr(value)); } static Value f32FromBits(ImplicitLocOpBuilder &builder, uint32_t bits) { Value i32Value = i32Cst(builder, static_cast(bits)); return builder.create(builder.getF32Type(), i32Value); } //----------------------------------------------------------------------------// // Helper functions to build math functions approximations. //----------------------------------------------------------------------------// // Return the minimum of the two values or NaN if value is NaN static Value min(ImplicitLocOpBuilder &builder, Value value, Value bound) { return builder.create( builder.create(arith::CmpFPredicate::ULT, value, bound), value, bound); } // Return the maximum of the two values or NaN if value is NaN static Value max(ImplicitLocOpBuilder &builder, Value value, Value bound) { return builder.create( builder.create(arith::CmpFPredicate::UGT, value, bound), value, bound); } // Return the clamped value or NaN if value is NaN static Value clamp(ImplicitLocOpBuilder &builder, Value value, Value lowerBound, Value upperBound) { return max(builder, min(builder, value, upperBound), lowerBound); } // Decomposes given floating point value `arg` into a normalized fraction and // an integral power of two (see std::frexp). Returned values have float type. static std::pair frexp(ImplicitLocOpBuilder &builder, Value arg, bool isPositive = false) { assert(getElementTypeOrSelf(arg).isF32() && "arg must be f32 type"); ArrayRef shape = vectorShape(arg); auto bcast = [&](Value value) -> Value { return broadcast(builder, value, shape); }; auto i32 = builder.getIntegerType(32); auto i32Vec = broadcast(i32, shape); auto f32Vec = broadcast(builder.getF32Type(), shape); Value cst126f = f32Cst(builder, 126.0f); Value cstHalf = f32Cst(builder, 0.5f); Value cstInvMantMask = f32FromBits(builder, ~0x7f800000u); // Bitcast to i32 for bitwise operations. Value i32Half = builder.create(i32, cstHalf); Value i32InvMantMask = builder.create(i32, cstInvMantMask); Value i32Arg = builder.create(i32Vec, arg); // Compute normalized fraction. Value tmp0 = builder.create(i32Arg, bcast(i32InvMantMask)); Value tmp1 = builder.create(tmp0, bcast(i32Half)); Value normalizedFraction = builder.create(f32Vec, tmp1); // Compute exponent. Value arg0 = isPositive ? arg : builder.create(arg); Value biasedExponentBits = builder.create( builder.create(i32Vec, arg0), bcast(i32Cst(builder, 23))); Value biasedExponent = builder.create(f32Vec, biasedExponentBits); Value exponent = builder.create(biasedExponent, bcast(cst126f)); return {normalizedFraction, exponent}; } // Computes exp2 for an i32 argument. static Value exp2I32(ImplicitLocOpBuilder &builder, Value arg) { assert(getElementTypeOrSelf(arg).isInteger(32) && "arg must be i32 type"); ArrayRef shape = vectorShape(arg); auto bcast = [&](Value value) -> Value { return broadcast(builder, value, shape); }; auto f32Vec = broadcast(builder.getF32Type(), shape); // The exponent of f32 located at 23-bit. auto exponetBitLocation = bcast(i32Cst(builder, 23)); // Set the exponent bias to zero. auto bias = bcast(i32Cst(builder, 127)); Value biasedArg = builder.create(arg, bias); Value exp2ValueInt = builder.create(biasedArg, exponetBitLocation); Value exp2ValueF32 = builder.create(f32Vec, exp2ValueInt); return exp2ValueF32; } namespace { Value makePolynomialCalculation(ImplicitLocOpBuilder &builder, llvm::ArrayRef coeffs, Value x) { assert(getElementTypeOrSelf(x).isF32() && "x must be f32 type"); ArrayRef shape = vectorShape(x); if (coeffs.empty()) return broadcast(builder, f32Cst(builder, 0.0f), shape); if (coeffs.size() == 1) return coeffs[0]; Value res = builder.create(x, coeffs[coeffs.size() - 1], coeffs[coeffs.size() - 2]); for (auto i = ptrdiff_t(coeffs.size()) - 3; i >= 0; --i) { res = builder.create(x, res, coeffs[i]); } return res; } } // namespace //----------------------------------------------------------------------------// // Helper function/pattern to insert casts for reusing F32 bit expansion. //----------------------------------------------------------------------------// template LogicalResult insertCasts(Operation *op, PatternRewriter &rewriter) { // Conservatively only allow where the operand and result types are exactly 1. Type origType = op->getResultTypes().front(); for (Type t : llvm::drop_begin(op->getResultTypes())) if (origType != t) return rewriter.notifyMatchFailure(op, "required all types to match"); for (Type t : op->getOperandTypes()) if (origType != t) return rewriter.notifyMatchFailure(op, "required all types to match"); // Skip if already F32 or larger than 32 bits. if (getElementTypeOrSelf(origType).isF32() || getElementTypeOrSelf(origType).getIntOrFloatBitWidth() > 32) return failure(); // Create F32 equivalent type. Type newType; if (auto shaped = origType.dyn_cast()) { newType = shaped.clone(rewriter.getF32Type()); } else if (origType.isa()) { newType = rewriter.getF32Type(); } else { return rewriter.notifyMatchFailure(op, "unable to find F32 equivalent type"); } Location loc = op->getLoc(); SmallVector operands; for (auto operand : op->getOperands()) operands.push_back(rewriter.create(loc, newType, operand)); auto result = rewriter.create(loc, newType, operands); rewriter.replaceOpWithNewOp(op, origType, result); return success(); } namespace { // Pattern to cast to F32 to reuse F32 expansion as fallback for single-result // op. // TODO: Consider revising to avoid adding multiple casts for a subgraph that is // all in lower precision. Currently this is only fallback support and performs // simplistic casting. template struct ReuseF32Expansion : public OpRewritePattern { public: using OpRewritePattern::OpRewritePattern; LogicalResult matchAndRewrite(T op, PatternRewriter &rewriter) const final { static_assert( T::template hasTrait(), "requires same operands and result types"); return insertCasts(op, rewriter); } }; } // namespace //----------------------------------------------------------------------------// // AtanOp approximation. //----------------------------------------------------------------------------// namespace { struct AtanApproximation : public OpRewritePattern { public: using OpRewritePattern::OpRewritePattern; LogicalResult matchAndRewrite(math::AtanOp op, PatternRewriter &rewriter) const final; }; } // namespace LogicalResult AtanApproximation::matchAndRewrite(math::AtanOp op, PatternRewriter &rewriter) const { auto operand = op.getOperand(); if (!getElementTypeOrSelf(operand).isF32()) return rewriter.notifyMatchFailure(op, "unsupported operand type"); ArrayRef shape = vectorShape(op.getOperand()); ImplicitLocOpBuilder builder(op->getLoc(), rewriter); auto one = broadcast(builder, f32Cst(builder, 1.0f), shape); // Remap the problem over [0.0, 1.0] by looking at the absolute value and the // handling symmetry. Value abs = builder.create(operand); Value reciprocal = builder.create(one, abs); Value compare = builder.create(arith::CmpFPredicate::OLT, abs, reciprocal); Value x = builder.create(compare, abs, reciprocal); // Perform the Taylor series approximation for atan over the range // [-1.0, 1.0]. auto n1 = broadcast(builder, f32Cst(builder, 0.14418283f), shape); auto n2 = broadcast(builder, f32Cst(builder, -0.34999234f), shape); auto n3 = broadcast(builder, f32Cst(builder, -0.01067831f), shape); auto n4 = broadcast(builder, f32Cst(builder, 1.00209986f), shape); Value p = builder.create(x, n1, n2); p = builder.create(x, p, n3); p = builder.create(x, p, n4); p = builder.create(x, p); // Remap the solution for over [0.0, 1.0] to [0.0, inf] auto halfPi = broadcast(builder, f32Cst(builder, 1.57079632679f), shape); Value sub = builder.create(halfPi, p); Value select = builder.create(compare, p, sub); // Correct for signing of the input. rewriter.replaceOpWithNewOp(op, select, operand); return success(); } //----------------------------------------------------------------------------// // AtanOp approximation. //----------------------------------------------------------------------------// namespace { struct Atan2Approximation : public OpRewritePattern { public: using OpRewritePattern::OpRewritePattern; LogicalResult matchAndRewrite(math::Atan2Op op, PatternRewriter &rewriter) const final; }; } // namespace LogicalResult Atan2Approximation::matchAndRewrite(math::Atan2Op op, PatternRewriter &rewriter) const { auto y = op.getOperand(0); auto x = op.getOperand(1); if (!getElementTypeOrSelf(x).isF32()) return rewriter.notifyMatchFailure(op, "unsupported operand type"); ImplicitLocOpBuilder builder(op->getLoc(), rewriter); ArrayRef shape = vectorShape(op.getResult()); // Compute atan in the valid range. auto div = builder.create(y, x); auto atan = builder.create(div); // Determine what the atan would be for a 180 degree rotation. auto zero = broadcast(builder, f32Cst(builder, 0.0f), shape); auto pi = broadcast(builder, f32Cst(builder, 3.14159265359f), shape); auto addPi = builder.create(atan, pi); auto subPi = builder.create(atan, pi); auto atanGt = builder.create(arith::CmpFPredicate::OGT, atan, zero); auto flippedAtan = builder.create(atanGt, subPi, addPi); // Determine whether to directly use atan or use the 180 degree flip auto xGt = builder.create(arith::CmpFPredicate::OGT, x, zero); Value result = builder.create(xGt, atan, flippedAtan); // Handle x = 0, y > 0 Value xZero = builder.create(arith::CmpFPredicate::OEQ, x, zero); Value yGt = builder.create(arith::CmpFPredicate::OGT, y, zero); Value isHalfPi = builder.create(xZero, yGt); auto halfPi = broadcast(builder, f32Cst(builder, 1.57079632679f), shape); result = builder.create(isHalfPi, halfPi, result); // Handle x = 0, y < 0 Value yLt = builder.create(arith::CmpFPredicate::OLT, y, zero); Value isNegativeHalfPiPi = builder.create(xZero, yLt); auto negativeHalfPiPi = broadcast(builder, f32Cst(builder, -1.57079632679f), shape); result = builder.create(isNegativeHalfPiPi, negativeHalfPiPi, result); // Handle x = 0, y = 0; Value yZero = builder.create(arith::CmpFPredicate::OEQ, y, zero); Value isNan = builder.create(xZero, yZero); Value cstNan = broadcast(builder, f32FromBits(builder, 0x7fc00000), shape); result = builder.create(isNan, cstNan, result); rewriter.replaceOp(op, result); return success(); } //----------------------------------------------------------------------------// // TanhOp approximation. //----------------------------------------------------------------------------// namespace { struct TanhApproximation : public OpRewritePattern { public: using OpRewritePattern::OpRewritePattern; LogicalResult matchAndRewrite(math::TanhOp op, PatternRewriter &rewriter) const final; }; } // namespace LogicalResult TanhApproximation::matchAndRewrite(math::TanhOp op, PatternRewriter &rewriter) const { if (!getElementTypeOrSelf(op.getOperand()).isF32()) return rewriter.notifyMatchFailure(op, "unsupported operand type"); ArrayRef shape = vectorShape(op.getOperand()); ImplicitLocOpBuilder builder(op->getLoc(), rewriter); auto bcast = [&](Value value) -> Value { return broadcast(builder, value, shape); }; // Clamp operand into [plusClamp, minusClamp] range. Value minusClamp = bcast(f32Cst(builder, -7.99881172180175781f)); Value plusClamp = bcast(f32Cst(builder, 7.99881172180175781f)); Value x = clamp(builder, op.getOperand(), minusClamp, plusClamp); // Mask for tiny values that are approximated with `operand`. Value tiny = bcast(f32Cst(builder, 0.0004f)); Value tinyMask = builder.create( arith::CmpFPredicate::OLT, builder.create(op.getOperand()), tiny); // The monomial coefficients of the numerator polynomial (odd). Value alpha1 = bcast(f32Cst(builder, 4.89352455891786e-03f)); Value alpha3 = bcast(f32Cst(builder, 6.37261928875436e-04f)); Value alpha5 = bcast(f32Cst(builder, 1.48572235717979e-05f)); Value alpha7 = bcast(f32Cst(builder, 5.12229709037114e-08f)); Value alpha9 = bcast(f32Cst(builder, -8.60467152213735e-11f)); Value alpha11 = bcast(f32Cst(builder, 2.00018790482477e-13f)); Value alpha13 = bcast(f32Cst(builder, -2.76076847742355e-16f)); // The monomial coefficients of the denominator polynomial (even). Value beta0 = bcast(f32Cst(builder, 4.89352518554385e-03f)); Value beta2 = bcast(f32Cst(builder, 2.26843463243900e-03f)); Value beta4 = bcast(f32Cst(builder, 1.18534705686654e-04f)); Value beta6 = bcast(f32Cst(builder, 1.19825839466702e-06f)); // Since the polynomials are odd/even, we need x^2. Value x2 = builder.create(x, x); // Evaluate the numerator polynomial p. Value p = builder.create(x2, alpha13, alpha11); p = builder.create(x2, p, alpha9); p = builder.create(x2, p, alpha7); p = builder.create(x2, p, alpha5); p = builder.create(x2, p, alpha3); p = builder.create(x2, p, alpha1); p = builder.create(x, p); // Evaluate the denominator polynomial q. Value q = builder.create(x2, beta6, beta4); q = builder.create(x2, q, beta2); q = builder.create(x2, q, beta0); // Divide the numerator by the denominator. Value res = builder.create( tinyMask, x, builder.create(p, q)); rewriter.replaceOp(op, res); return success(); } #define LN2_VALUE \ 0.693147180559945309417232121458176568075500134360255254120680009493393621L #define LOG2E_VALUE \ 1.442695040888963407359924681001892137426645954152985934135449406931109219L //----------------------------------------------------------------------------// // LogOp and Log2Op approximation. //----------------------------------------------------------------------------// namespace { template struct LogApproximationBase : public OpRewritePattern { using OpRewritePattern::OpRewritePattern; /// Base 2 if 'base2' is set; natural logarithm (base e) otherwise. LogicalResult logMatchAndRewrite(Op op, PatternRewriter &rewriter, bool base2) const; }; } // namespace // This approximation comes from Julien Pommier's SSE math library. // Link: http://gruntthepeon.free.fr/ssemath template LogicalResult LogApproximationBase::logMatchAndRewrite(Op op, PatternRewriter &rewriter, bool base2) const { if (!getElementTypeOrSelf(op.getOperand()).isF32()) return rewriter.notifyMatchFailure(op, "unsupported operand type"); ArrayRef shape = vectorShape(op.getOperand()); ImplicitLocOpBuilder builder(op->getLoc(), rewriter); auto bcast = [&](Value value) -> Value { return broadcast(builder, value, shape); }; Value cstZero = bcast(f32Cst(builder, 0.0f)); Value cstOne = bcast(f32Cst(builder, 1.0f)); Value cstNegHalf = bcast(f32Cst(builder, -0.5f)); // The smallest non denormalized float number. Value cstMinNormPos = bcast(f32FromBits(builder, 0x00800000u)); Value cstMinusInf = bcast(f32FromBits(builder, 0xff800000u)); Value cstPosInf = bcast(f32FromBits(builder, 0x7f800000u)); Value cstNan = bcast(f32FromBits(builder, 0x7fc00000)); // Polynomial coefficients. Value cstCephesSQRTHF = bcast(f32Cst(builder, 0.707106781186547524f)); Value cstCephesLogP0 = bcast(f32Cst(builder, 7.0376836292E-2f)); Value cstCephesLogP1 = bcast(f32Cst(builder, -1.1514610310E-1f)); Value cstCephesLogP2 = bcast(f32Cst(builder, 1.1676998740E-1f)); Value cstCephesLogP3 = bcast(f32Cst(builder, -1.2420140846E-1f)); Value cstCephesLogP4 = bcast(f32Cst(builder, +1.4249322787E-1f)); Value cstCephesLogP5 = bcast(f32Cst(builder, -1.6668057665E-1f)); Value cstCephesLogP6 = bcast(f32Cst(builder, +2.0000714765E-1f)); Value cstCephesLogP7 = bcast(f32Cst(builder, -2.4999993993E-1f)); Value cstCephesLogP8 = bcast(f32Cst(builder, +3.3333331174E-1f)); Value x = op.getOperand(); // Truncate input values to the minimum positive normal. x = max(builder, x, cstMinNormPos); // Extract significant in the range [0.5,1) and exponent. std::pair pair = frexp(builder, x, /*isPositive=*/true); x = pair.first; Value e = pair.second; // Shift the inputs from the range [0.5,1) to [sqrt(1/2), sqrt(2)) and shift // by -1.0. The values are then centered around 0, which improves the // stability of the polynomial evaluation: // // if( x < SQRTHF ) { // e -= 1; // x = x + x - 1.0; // } else { x = x - 1.0; } Value mask = builder.create(arith::CmpFPredicate::OLT, x, cstCephesSQRTHF); Value tmp = builder.create(mask, x, cstZero); x = builder.create(x, cstOne); e = builder.create( e, builder.create(mask, cstOne, cstZero)); x = builder.create(x, tmp); Value x2 = builder.create(x, x); Value x3 = builder.create(x2, x); // Evaluate the polynomial approximant of degree 8 in three parts. Value y0, y1, y2; y0 = builder.create(cstCephesLogP0, x, cstCephesLogP1); y1 = builder.create(cstCephesLogP3, x, cstCephesLogP4); y2 = builder.create(cstCephesLogP6, x, cstCephesLogP7); y0 = builder.create(y0, x, cstCephesLogP2); y1 = builder.create(y1, x, cstCephesLogP5); y2 = builder.create(y2, x, cstCephesLogP8); y0 = builder.create(y0, x3, y1); y0 = builder.create(y0, x3, y2); y0 = builder.create(y0, x3); y0 = builder.create(cstNegHalf, x2, y0); x = builder.create(x, y0); if (base2) { Value cstLog2e = bcast(f32Cst(builder, static_cast(LOG2E_VALUE))); x = builder.create(x, cstLog2e, e); } else { Value cstLn2 = bcast(f32Cst(builder, static_cast(LN2_VALUE))); x = builder.create(e, cstLn2, x); } Value invalidMask = builder.create(arith::CmpFPredicate::ULT, op.getOperand(), cstZero); Value zeroMask = builder.create(arith::CmpFPredicate::OEQ, op.getOperand(), cstZero); Value posInfMask = builder.create(arith::CmpFPredicate::OEQ, op.getOperand(), cstPosInf); // Filter out invalid values: // • x == 0 -> -INF // • x < 0 -> NAN // • x == +INF -> +INF Value aproximation = builder.create( zeroMask, cstMinusInf, builder.create( invalidMask, cstNan, builder.create(posInfMask, cstPosInf, x))); rewriter.replaceOp(op, aproximation); return success(); } namespace { struct LogApproximation : public LogApproximationBase { using LogApproximationBase::LogApproximationBase; LogicalResult matchAndRewrite(math::LogOp op, PatternRewriter &rewriter) const final { return logMatchAndRewrite(op, rewriter, /*base2=*/false); } }; } // namespace namespace { struct Log2Approximation : public LogApproximationBase { using LogApproximationBase::LogApproximationBase; LogicalResult matchAndRewrite(math::Log2Op op, PatternRewriter &rewriter) const final { return logMatchAndRewrite(op, rewriter, /*base2=*/true); } }; } // namespace //----------------------------------------------------------------------------// // Log1p approximation. //----------------------------------------------------------------------------// namespace { struct Log1pApproximation : public OpRewritePattern { public: using OpRewritePattern::OpRewritePattern; LogicalResult matchAndRewrite(math::Log1pOp op, PatternRewriter &rewriter) const final; }; } // namespace // Approximate log(1+x). LogicalResult Log1pApproximation::matchAndRewrite(math::Log1pOp op, PatternRewriter &rewriter) const { if (!getElementTypeOrSelf(op.getOperand()).isF32()) return rewriter.notifyMatchFailure(op, "unsupported operand type"); ArrayRef shape = vectorShape(op.getOperand()); ImplicitLocOpBuilder builder(op->getLoc(), rewriter); auto bcast = [&](Value value) -> Value { return broadcast(builder, value, shape); }; // Approximate log(1+x) using the following, due to W. Kahan: // u = x + 1.0; // if (u == 1.0 || u == inf) return x; // return x * log(u) / (u - 1.0); // ^^^^^^^^^^^^^^^^^^^^^^ // "logLarge" below. Value cstOne = bcast(f32Cst(builder, 1.0f)); Value x = op.getOperand(); Value u = builder.create(x, cstOne); Value uSmall = builder.create(arith::CmpFPredicate::OEQ, u, cstOne); Value logU = builder.create(u); Value uInf = builder.create(arith::CmpFPredicate::OEQ, u, logU); Value logLarge = builder.create( x, builder.create( logU, builder.create(u, cstOne))); Value approximation = builder.create( builder.create(uSmall, uInf), x, logLarge); rewriter.replaceOp(op, approximation); return success(); } //----------------------------------------------------------------------------// // Erf approximation. //----------------------------------------------------------------------------// // Approximates erf(x) with // a - P(x)/Q(x) // where P and Q are polynomials of degree 4. // Different coefficients are chosen based on the value of x. // The approximation error is ~2.5e-07. // Boost's minimax tool that utilizes the Remez method was used to find the // coefficients. LogicalResult ErfPolynomialApproximation::matchAndRewrite(math::ErfOp op, PatternRewriter &rewriter) const { if (!getElementTypeOrSelf(op.getOperand()).isF32()) return rewriter.notifyMatchFailure(op, "unsupported operand type"); ArrayRef shape = vectorShape(op.getOperand()); ImplicitLocOpBuilder builder(op->getLoc(), rewriter); auto bcast = [&](Value value) -> Value { return broadcast(builder, value, shape); }; const int intervalsCount = 3; const int polyDegree = 4; Value zero = bcast(f32Cst(builder, 0)); Value one = bcast(f32Cst(builder, 1)); Value pp[intervalsCount][polyDegree + 1]; pp[0][0] = bcast(f32Cst(builder, +0.00000000000000000e+00f)); pp[0][1] = bcast(f32Cst(builder, +1.12837916222975858e+00f)); pp[0][2] = bcast(f32Cst(builder, -5.23018562988006470e-01f)); pp[0][3] = bcast(f32Cst(builder, +2.09741709609267072e-01f)); pp[0][4] = bcast(f32Cst(builder, +2.58146801602987875e-02f)); pp[1][0] = bcast(f32Cst(builder, +0.00000000000000000e+00f)); pp[1][1] = bcast(f32Cst(builder, +1.12750687816789140e+00f)); pp[1][2] = bcast(f32Cst(builder, -3.64721408487825775e-01f)); pp[1][3] = bcast(f32Cst(builder, +1.18407396425136952e-01f)); pp[1][4] = bcast(f32Cst(builder, +3.70645533056476558e-02f)); pp[2][0] = bcast(f32Cst(builder, -3.30093071049483172e-03f)); pp[2][1] = bcast(f32Cst(builder, +3.51961938357697011e-03f)); pp[2][2] = bcast(f32Cst(builder, -1.41373622814988039e-03f)); pp[2][3] = bcast(f32Cst(builder, +2.53447094961941348e-04f)); pp[2][4] = bcast(f32Cst(builder, -1.71048029455037401e-05f)); Value qq[intervalsCount][polyDegree + 1]; qq[0][0] = bcast(f32Cst(builder, +1.000000000000000000e+00f)); qq[0][1] = bcast(f32Cst(builder, -4.635138185962547255e-01f)); qq[0][2] = bcast(f32Cst(builder, +5.192301327279782447e-01f)); qq[0][3] = bcast(f32Cst(builder, -1.318089722204810087e-01f)); qq[0][4] = bcast(f32Cst(builder, +7.397964654672315005e-02f)); qq[1][0] = bcast(f32Cst(builder, +1.00000000000000000e+00f)); qq[1][1] = bcast(f32Cst(builder, -3.27607011824493086e-01f)); qq[1][2] = bcast(f32Cst(builder, +4.48369090658821977e-01f)); qq[1][3] = bcast(f32Cst(builder, -8.83462621207857930e-02f)); qq[1][4] = bcast(f32Cst(builder, +5.72442770283176093e-02f)); qq[2][0] = bcast(f32Cst(builder, +1.00000000000000000e+00f)); qq[2][1] = bcast(f32Cst(builder, -2.06069165953913769e+00f)); qq[2][2] = bcast(f32Cst(builder, +1.62705939945477759e+00f)); qq[2][3] = bcast(f32Cst(builder, -5.83389859211130017e-01f)); qq[2][4] = bcast(f32Cst(builder, +8.21908939856640930e-02f)); Value offsets[intervalsCount]; offsets[0] = bcast(f32Cst(builder, 0.0f)); offsets[1] = bcast(f32Cst(builder, 0.0f)); offsets[2] = bcast(f32Cst(builder, 1.0f)); Value bounds[intervalsCount]; bounds[0] = bcast(f32Cst(builder, 0.8f)); bounds[1] = bcast(f32Cst(builder, 2.0f)); bounds[2] = bcast(f32Cst(builder, 3.75f)); Value isNegativeArg = builder.create(arith::CmpFPredicate::OLT, op.getOperand(), zero); Value negArg = builder.create(op.getOperand()); Value x = builder.create(isNegativeArg, negArg, op.getOperand()); Value offset = offsets[0]; Value p[polyDegree + 1]; Value q[polyDegree + 1]; for (int i = 0; i <= polyDegree; ++i) { p[i] = pp[0][i]; q[i] = qq[0][i]; } // TODO: maybe use vector stacking to reduce the number of selects. Value isLessThanBound[intervalsCount]; for (int j = 0; j < intervalsCount - 1; ++j) { isLessThanBound[j] = builder.create(arith::CmpFPredicate::OLT, x, bounds[j]); for (int i = 0; i <= polyDegree; ++i) { p[i] = builder.create(isLessThanBound[j], p[i], pp[j + 1][i]); q[i] = builder.create(isLessThanBound[j], q[i], qq[j + 1][i]); } offset = builder.create(isLessThanBound[j], offset, offsets[j + 1]); } isLessThanBound[intervalsCount - 1] = builder.create( arith::CmpFPredicate::ULT, x, bounds[intervalsCount - 1]); Value pPoly = makePolynomialCalculation(builder, p, x); Value qPoly = makePolynomialCalculation(builder, q, x); Value rationalPoly = builder.create(pPoly, qPoly); Value formula = builder.create(offset, rationalPoly); formula = builder.create(isLessThanBound[intervalsCount - 1], formula, one); // erf is odd function: erf(x) = -erf(-x). Value negFormula = builder.create(formula); Value res = builder.create(isNegativeArg, negFormula, formula); rewriter.replaceOp(op, res); return success(); } //----------------------------------------------------------------------------// // Exp approximation. //----------------------------------------------------------------------------// namespace { struct ExpApproximation : public OpRewritePattern { public: using OpRewritePattern::OpRewritePattern; LogicalResult matchAndRewrite(math::ExpOp op, PatternRewriter &rewriter) const final; }; } // namespace // Approximate exp(x) using its reduced range exp(y) where y is in the range // [0, ln(2)], let y = x - floor(x / ln(2)) * ln(2) = x - k * ln(2), exp(x) // = exp(y) * 2^k. exp(y). LogicalResult ExpApproximation::matchAndRewrite(math::ExpOp op, PatternRewriter &rewriter) const { if (!getElementTypeOrSelf(op.getOperand()).isF32()) return rewriter.notifyMatchFailure(op, "unsupported operand type"); ArrayRef shape = vectorShape(op.getOperand()); ImplicitLocOpBuilder builder(op->getLoc(), rewriter); // TODO: Consider a common pattern rewriter with all methods below to // write the approximations. auto bcast = [&](Value value) -> Value { return broadcast(builder, value, shape); }; auto fmla = [&](Value a, Value b, Value c) { return builder.create(a, b, c); }; auto mul = [&](Value a, Value b) -> Value { return builder.create(a, b); }; auto sub = [&](Value a, Value b) -> Value { return builder.create(a, b); }; auto floor = [&](Value a) { return builder.create(a); }; Value cstLn2 = bcast(f32Cst(builder, static_cast(LN2_VALUE))); Value cstLog2E = bcast(f32Cst(builder, static_cast(LOG2E_VALUE))); // Polynomial coefficients. Value cstCephesExpP0 = bcast(f32Cst(builder, 1.0)); Value cstCephesExpP1 = bcast(f32Cst(builder, 1.0)); Value cstCephesExpP2 = bcast(f32Cst(builder, 0.49970514590562437052f)); Value cstCephesExpP3 = bcast(f32Cst(builder, 0.16873890085469545053f)); Value cstCephesExpP4 = bcast(f32Cst(builder, 0.03668965196652099192f)); Value cstCephesExpP5 = bcast(f32Cst(builder, 0.01314350012789660196f)); Value x = op.getOperand(); Value isNan = builder.create(arith::CmpFPredicate::UNO, x, x); // Reduced y = x - floor(x / ln(2)) * ln(2) = x - k * ln(2) Value xL2Inv = mul(x, cstLog2E); Value kF32 = floor(xL2Inv); Value kLn2 = mul(kF32, cstLn2); Value y = sub(x, kLn2); // Use Estrin's evaluation scheme with 3 independent parts: // P(y)^y : (c0 + c1 y) + (c2 + c3 y) y^2 + (c4 + c5 y) y^4 Value y2 = mul(y, y); Value y4 = mul(y2, y2); Value q0 = fmla(cstCephesExpP1, y, cstCephesExpP0); Value q1 = fmla(cstCephesExpP3, y, cstCephesExpP2); Value q2 = fmla(cstCephesExpP5, y, cstCephesExpP4); Value expY = fmla(q1, y2, q0); expY = fmla(q2, y4, expY); auto i32Vec = broadcast(builder.getI32Type(), shape); // exp2(k) Value k = builder.create(i32Vec, kF32); Value exp2KValue = exp2I32(builder, k); // exp(x) = exp(y) * exp2(k) expY = mul(expY, exp2KValue); // Handle overflow, inf and underflow of exp(x). exp(x) range is [0, inf], its // partitioned as the following: // exp(x) = 0, x <= -inf // exp(x) = underflow (min_float), x <= -88 // exp(x) = inf (min_float), x >= 88 // Note: |k| = 127 is the value where the 8-bits exponent saturates. Value zerof32Const = bcast(f32Cst(builder, 0)); auto constPosInfinity = bcast(f32Cst(builder, std::numeric_limits::infinity())); auto constNegIfinity = bcast(f32Cst(builder, -std::numeric_limits::infinity())); auto underflow = bcast(f32Cst(builder, std::numeric_limits::min())); Value kMaxConst = bcast(i32Cst(builder, 127)); Value kMaxNegConst = bcast(i32Cst(builder, -127)); Value rightBound = builder.create(arith::CmpIPredicate::sle, k, kMaxConst); Value leftBound = builder.create(arith::CmpIPredicate::sge, k, kMaxNegConst); Value isNegInfinityX = builder.create( arith::CmpFPredicate::OEQ, x, constNegIfinity); Value isPosInfinityX = builder.create( arith::CmpFPredicate::OEQ, x, constPosInfinity); Value isPostiveX = builder.create(arith::CmpFPredicate::OGT, x, zerof32Const); Value isComputable = builder.create(rightBound, leftBound); expY = builder.create( isNan, x, builder.create( isNegInfinityX, zerof32Const, builder.create( isPosInfinityX, constPosInfinity, builder.create( isComputable, expY, builder.create(isPostiveX, constPosInfinity, underflow))))); rewriter.replaceOp(op, expY); return success(); } //----------------------------------------------------------------------------// // ExpM1 approximation. //----------------------------------------------------------------------------// namespace { struct ExpM1Approximation : public OpRewritePattern { public: using OpRewritePattern::OpRewritePattern; LogicalResult matchAndRewrite(math::ExpM1Op op, PatternRewriter &rewriter) const final; }; } // namespace LogicalResult ExpM1Approximation::matchAndRewrite(math::ExpM1Op op, PatternRewriter &rewriter) const { if (!getElementTypeOrSelf(op.getOperand()).isF32()) return rewriter.notifyMatchFailure(op, "unsupported operand type"); ArrayRef shape = vectorShape(op.getOperand()); ImplicitLocOpBuilder builder(op->getLoc(), rewriter); auto bcast = [&](Value value) -> Value { return broadcast(builder, value, shape); }; // expm1(x) = exp(x) - 1 = u - 1. // We have to handle it carefully when x is near 0, i.e. u ~= 1, // and when the input is ~= -inf, i.e. u - 1 ~= -1. Value cstOne = bcast(f32Cst(builder, 1.0f)); Value cstNegOne = bcast(f32Cst(builder, -1.0f)); Value x = op.getOperand(); Value u = builder.create(x); Value uEqOneOrNaN = builder.create(arith::CmpFPredicate::UEQ, u, cstOne); Value uMinusOne = builder.create(u, cstOne); Value uMinusOneEqNegOne = builder.create( arith::CmpFPredicate::OEQ, uMinusOne, cstNegOne); // logU = log(u) ~= x Value logU = builder.create(u); // Detect exp(x) = +inf; written this way to avoid having to form +inf. Value isInf = builder.create(arith::CmpFPredicate::OEQ, logU, u); // (u - 1) * (x / ~x) Value expm1 = builder.create( uMinusOne, builder.create(x, logU)); expm1 = builder.create(isInf, u, expm1); Value approximation = builder.create( uEqOneOrNaN, x, builder.create(uMinusOneEqNegOne, cstNegOne, expm1)); rewriter.replaceOp(op, approximation); return success(); } //----------------------------------------------------------------------------// // Sin and Cos approximation. //----------------------------------------------------------------------------// namespace { template struct SinAndCosApproximation : public OpRewritePattern { public: using OpRewritePattern::OpRewritePattern; LogicalResult matchAndRewrite(OpTy op, PatternRewriter &rewriter) const final; }; } // namespace #define TWO_OVER_PI \ 0.6366197723675813430755350534900574481378385829618257949906693762L #define PI_OVER_2 \ 1.5707963267948966192313216916397514420985846996875529104874722961L // Approximates sin(x) or cos(x) by finding the best approximation polynomial in // the reduced range [0, pi/2] for both sin(x) and cos(x). Then given y in the // reduced range sin(x) will be computed as sin(y), -sin(y), cos(y) or -cos(y). template LogicalResult SinAndCosApproximation::matchAndRewrite( OpTy op, PatternRewriter &rewriter) const { static_assert( llvm::is_one_of::value, "SinAndCosApproximation pattern expects math::SinOp or math::CosOp"); if (!getElementTypeOrSelf(op.getOperand()).isF32()) return rewriter.notifyMatchFailure(op, "unsupported operand type"); ArrayRef shape = vectorShape(op.getOperand()); ImplicitLocOpBuilder builder(op->getLoc(), rewriter); auto bcast = [&](Value value) -> Value { return broadcast(builder, value, shape); }; auto mul = [&](Value a, Value b) -> Value { return builder.create(a, b); }; auto sub = [&](Value a, Value b) -> Value { return builder.create(a, b); }; auto floor = [&](Value a) { return builder.create(a); }; auto i32Vec = broadcast(builder.getI32Type(), shape); auto fPToSingedInteger = [&](Value a) -> Value { return builder.create(i32Vec, a); }; auto modulo4 = [&](Value a) -> Value { return builder.create(a, bcast(i32Cst(builder, 3))); }; auto isEqualTo = [&](Value a, Value b) -> Value { return builder.create(arith::CmpIPredicate::eq, a, b); }; auto isGreaterThan = [&](Value a, Value b) -> Value { return builder.create(arith::CmpIPredicate::sgt, a, b); }; auto select = [&](Value cond, Value t, Value f) -> Value { return builder.create(cond, t, f); }; auto fmla = [&](Value a, Value b, Value c) { return builder.create(a, b, c); }; auto bitwiseOr = [&](Value a, Value b) { return builder.create(a, b); }; Value twoOverPi = bcast(f32Cst(builder, (float)TWO_OVER_PI)); Value piOverTwo = bcast(f32Cst(builder, (float)PI_OVER_2)); Value x = op.getOperand(); Value k = floor(mul(x, twoOverPi)); Value y = sub(x, mul(k, piOverTwo)); Value cstOne = bcast(f32Cst(builder, 1.0)); Value cstNegativeOne = bcast(f32Cst(builder, -1.0)); Value cstSC2 = bcast(f32Cst(builder, -0.16666667163372039794921875f)); Value cstSC4 = bcast(f32Cst(builder, 8.333347737789154052734375e-3f)); Value cstSC6 = bcast(f32Cst(builder, -1.9842604524455964565277099609375e-4f)); Value cstSC8 = bcast(f32Cst(builder, 2.760012648650445044040679931640625e-6f)); Value cstSC10 = bcast(f32Cst(builder, -2.50293279435709337121807038784027099609375e-8f)); Value cstCC2 = bcast(f32Cst(builder, -0.5f)); Value cstCC4 = bcast(f32Cst(builder, 4.166664183139801025390625e-2f)); Value cstCC6 = bcast(f32Cst(builder, -1.388833043165504932403564453125e-3f)); Value cstCC8 = bcast(f32Cst(builder, 2.47562347794882953166961669921875e-5f)); Value cstCC10 = bcast(f32Cst(builder, -2.59630184018533327616751194000244140625e-7f)); Value kMod4 = modulo4(fPToSingedInteger(k)); Value kR0 = isEqualTo(kMod4, bcast(i32Cst(builder, 0))); Value kR1 = isEqualTo(kMod4, bcast(i32Cst(builder, 1))); Value kR2 = isEqualTo(kMod4, bcast(i32Cst(builder, 2))); Value kR3 = isEqualTo(kMod4, bcast(i32Cst(builder, 3))); Value sinuseCos = isSine ? bitwiseOr(kR1, kR3) : bitwiseOr(kR0, kR2); Value negativeRange = isSine ? isGreaterThan(kMod4, bcast(i32Cst(builder, 1))) : bitwiseOr(kR1, kR2); Value y2 = mul(y, y); Value base = select(sinuseCos, cstOne, y); Value cstC2 = select(sinuseCos, cstCC2, cstSC2); Value cstC4 = select(sinuseCos, cstCC4, cstSC4); Value cstC6 = select(sinuseCos, cstCC6, cstSC6); Value cstC8 = select(sinuseCos, cstCC8, cstSC8); Value cstC10 = select(sinuseCos, cstCC10, cstSC10); Value v1 = fmla(y2, cstC10, cstC8); Value v2 = fmla(y2, v1, cstC6); Value v3 = fmla(y2, v2, cstC4); Value v4 = fmla(y2, v3, cstC2); Value v5 = fmla(y2, v4, cstOne); Value v6 = mul(base, v5); Value approximation = select(negativeRange, mul(cstNegativeOne, v6), v6); rewriter.replaceOp(op, approximation); return success(); } //----------------------------------------------------------------------------// // Rsqrt approximation. //----------------------------------------------------------------------------// namespace { struct RsqrtApproximation : public OpRewritePattern { using OpRewritePattern::OpRewritePattern; LogicalResult matchAndRewrite(math::RsqrtOp op, PatternRewriter &rewriter) const final; }; } // namespace LogicalResult RsqrtApproximation::matchAndRewrite(math::RsqrtOp op, PatternRewriter &rewriter) const { if (!getElementTypeOrSelf(op.getOperand()).isF32()) return rewriter.notifyMatchFailure(op, "unsupported operand type"); ArrayRef shape = vectorShape(op.getOperand()); // Only support already-vectorized rsqrt's. if (shape.empty() || shape.back() % 8 != 0) return rewriter.notifyMatchFailure(op, "unsupported operand type"); ImplicitLocOpBuilder builder(op->getLoc(), rewriter); auto bcast = [&](Value value) -> Value { return broadcast(builder, value, shape); }; Value cstPosInf = bcast(f32FromBits(builder, 0x7f800000u)); Value cstOnePointFive = bcast(f32Cst(builder, 1.5f)); Value cstNegHalf = bcast(f32Cst(builder, -0.5f)); Value cstMinNormPos = bcast(f32FromBits(builder, 0x00800000u)); Value negHalf = builder.create(op.getOperand(), cstNegHalf); // Select only the inverse sqrt of positive normals (denormals are // flushed to zero). Value ltMinMask = builder.create( arith::CmpFPredicate::OLT, op.getOperand(), cstMinNormPos); Value infMask = builder.create(arith::CmpFPredicate::OEQ, op.getOperand(), cstPosInf); Value notNormalFiniteMask = builder.create(ltMinMask, infMask); // Compute an approximate result. Value yApprox = handleMultidimensionalVectors( builder, op->getOperands(), 8, [&builder](ValueRange operands) -> Value { return builder.create(operands); }); // Do a single step of Newton-Raphson iteration to improve the approximation. // This uses the formula y_{n+1} = y_n * (1.5 - y_n * (0.5 * x) * y_n). // It is essential to evaluate the inner term like this because forming // y_n^2 may over- or underflow. Value inner = builder.create(negHalf, yApprox); Value fma = builder.create(yApprox, inner, cstOnePointFive); Value yNewton = builder.create(yApprox, fma); // Select the result of the Newton-Raphson step for positive normal arguments. // For other arguments, choose the output of the intrinsic. This will // return rsqrt(+inf) = 0, rsqrt(x) = NaN if x < 0, and rsqrt(x) = +inf if // x is zero or a positive denormalized float (equivalent to flushing positive // denormalized inputs to zero). Value res = builder.create(notNormalFiniteMask, yApprox, yNewton); rewriter.replaceOp(op, res); return success(); } //----------------------------------------------------------------------------// void mlir::populateMathPolynomialApproximationPatterns( RewritePatternSet &patterns, const MathPolynomialApproximationOptions &options) { patterns.add, SinAndCosApproximation, SinAndCosApproximation>( patterns.getContext()); if (options.enableAvx2) patterns.add(patterns.getContext()); }