lib/Target/Hexagon/HexagonVectorLoopCarriedReuse.h - llvm-project/llvm - Git at Google

 //===- HexagonVectorLoopCarriedReuse.h ------------------------------------===//
 //
 // 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 pass removes the computation of provably redundant expressions that have
 // been computed earlier in a previous iteration. It relies on the use of PHIs
 // to identify loop carried dependences. This is scalar replacement for vector
 // types.
 //
 //-----------------------------------------------------------------------------
 // Motivation: Consider the case where we have the following loop structure.
 //
 // Loop:
 //  t0 = a[i];
 //  t1 = f(t0);
 //  t2 = g(t1);
 //  ...
 //  t3 = a[i+1];
 //  t4 = f(t3);
 //  t5 = g(t4);
 //  t6 = op(t2, t5)
 //  cond_branch <Loop>
 //
 // This can be converted to
 //  t00 = a[0];
 //  t10 = f(t00);
 //  t20 = g(t10);
 // Loop:
 //  t2 = t20;
 //  t3 = a[i+1];
 //  t4 = f(t3);
 //  t5 = g(t4);
 //  t6 = op(t2, t5)
 //  t20 = t5
 //  cond_branch <Loop>
 //
 // SROA does a good job of reusing a[i+1] as a[i] in the next iteration.
 // Such a loop comes to this pass in the following form.
 //
 // LoopPreheader:
 //  X0 = a[0];
 // Loop:
 //  X2 = PHI<(X0, LoopPreheader), (X1, Loop)>
 //  t1 = f(X2)   <-- I1
 //  t2 = g(t1)
 //  ...
 //  X1 = a[i+1]
 //  t4 = f(X1)   <-- I2
 //  t5 = g(t4)
 //  t6 = op(t2, t5)
 //  cond_branch <Loop>
 //
 // In this pass, we look for PHIs such as X2 whose incoming values come only
 // from the Loop Preheader and over the backedge and additionaly, both these
 // values are the results of the same operation in terms of opcode. We call such
 // a PHI node a dependence chain or DepChain. In this case, the dependence of X2
 // over X1 is carried over only one iteration and so the DepChain is only one
 // PHI node long.
 //
 // Then, we traverse the uses of the PHI (X2) and the uses of the value of the
 // PHI coming  over the backedge (X1). We stop at the first pair of such users
 // I1 (of X2) and I2 (of X1) that meet the following conditions.
 // 1. I1 and I2 are the same operation, but with different operands.
 // 2. X2 and X1 are used at the same operand number in the two instructions.
 // 3. All other operands Op1 of I1 and Op2 of I2 are also such that there is a
 //    a DepChain from Op1 to Op2 of the same length as that between X2 and X1.
 //
 // We then make the following transformation
 // LoopPreheader:
 //  X0 = a[0];
 //  Y0 = f(X0);
 // Loop:
 //  X2 = PHI<(X0, LoopPreheader), (X1, Loop)>
 //  Y2 = PHI<(Y0, LoopPreheader), (t4, Loop)>
 //  t1 = f(X2)   <-- Will be removed by DCE.
 //  t2 = g(Y2)
 //  ...
 //  X1 = a[i+1]
 //  t4 = f(X1)
 //  t5 = g(t4)
 //  t6 = op(t2, t5)
 //  cond_branch <Loop>
 //
 // We proceed until we cannot find any more such instructions I1 and I2.
 //
 // --- DepChains & Loop carried dependences ---
 // Consider a single basic block loop such as
 //
 // LoopPreheader:
 //  X0 = ...
 //  Y0 = ...
 // Loop:
 //  X2 = PHI<(X0, LoopPreheader), (X1, Loop)>
 //  Y2 = PHI<(Y0, LoopPreheader), (X2, Loop)>
 //  ...
 //  X1 = ...
 //  ...
 //  cond_branch <Loop>
 //
 // Then there is a dependence between X2 and X1 that goes back one iteration,
 // i.e. X1 is used as X2 in the very next iteration. We represent this as a
 // DepChain from X2 to X1 (X2->X1).
 // Similarly, there is a dependence between Y2 and X1 that goes back two
 // iterations. X1 is used as Y2 two iterations after it is computed. This is
 // represented by a DepChain as (Y2->X2->X1).
 //
 // A DepChain has the following properties.
 // 1. Num of edges in DepChain = Number of Instructions in DepChain = Number of
 //    iterations of carried dependence + 1.
 // 2. All instructions in the DepChain except the last are PHIs.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_LIB_TARGET_HEXAGON_HEXAGONVLCR_H
 #define LLVM_LIB_TARGET_HEXAGON_HEXAGONVLCR_H

 #include "llvm/Transforms/Scalar/LoopPassManager.h"

 namespace llvm {

 class Loop;

 /// Hexagon Vector Loop Carried Reuse Pass
 struct HexagonVectorLoopCarriedReusePass
     : public PassInfoMixin<HexagonVectorLoopCarriedReusePass> {
   HexagonVectorLoopCarriedReusePass() {}

   /// Run pass over the Loop.
   PreservedAnalyses run(Loop &L, LoopAnalysisManager &LAM,
                         LoopStandardAnalysisResults &AR, LPMUpdater &U);
 };

 } // end namespace llvm

 #endif // LLVM_LIB_TARGET_HEXAGON_HEXAGONVLCR_H
	//===- HexagonVectorLoopCarriedReuse.h ------------------------------------===//
	//
	// 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 pass removes the computation of provably redundant expressions that have
	// been computed earlier in a previous iteration. It relies on the use of PHIs
	// to identify loop carried dependences. This is scalar replacement for vector
	// types.
	//
	//-----------------------------------------------------------------------------
	// Motivation: Consider the case where we have the following loop structure.
	//
	// Loop:
	// t0 = a[i];
	// t1 = f(t0);
	// t2 = g(t1);
	// ...
	// t3 = a[i+1];
	// t4 = f(t3);
	// t5 = g(t4);
	// t6 = op(t2, t5)
	// cond_branch <Loop>
	//
	// This can be converted to
	// t00 = a[0];
	// t10 = f(t00);
	// t20 = g(t10);
	// Loop:
	// t2 = t20;
	// t3 = a[i+1];
	// t4 = f(t3);
	// t5 = g(t4);
	// t6 = op(t2, t5)
	// t20 = t5
	// cond_branch <Loop>
	//
	// SROA does a good job of reusing a[i+1] as a[i] in the next iteration.
	// Such a loop comes to this pass in the following form.
	//
	// LoopPreheader:
	// X0 = a[0];
	// Loop:
	// X2 = PHI<(X0, LoopPreheader), (X1, Loop)>
	// t1 = f(X2) <-- I1
	// t2 = g(t1)
	// ...
	// X1 = a[i+1]
	// t4 = f(X1) <-- I2
	// t5 = g(t4)
	// t6 = op(t2, t5)
	// cond_branch <Loop>
	//
	// In this pass, we look for PHIs such as X2 whose incoming values come only
	// from the Loop Preheader and over the backedge and additionaly, both these
	// values are the results of the same operation in terms of opcode. We call such
	// a PHI node a dependence chain or DepChain. In this case, the dependence of X2
	// over X1 is carried over only one iteration and so the DepChain is only one
	// PHI node long.
	//
	// Then, we traverse the uses of the PHI (X2) and the uses of the value of the
	// PHI coming over the backedge (X1). We stop at the first pair of such users
	// I1 (of X2) and I2 (of X1) that meet the following conditions.
	// 1. I1 and I2 are the same operation, but with different operands.
	// 2. X2 and X1 are used at the same operand number in the two instructions.
	// 3. All other operands Op1 of I1 and Op2 of I2 are also such that there is a
	// a DepChain from Op1 to Op2 of the same length as that between X2 and X1.
	//
	// We then make the following transformation
	// LoopPreheader:
	// X0 = a[0];
	// Y0 = f(X0);
	// Loop:
	// X2 = PHI<(X0, LoopPreheader), (X1, Loop)>
	// Y2 = PHI<(Y0, LoopPreheader), (t4, Loop)>
	// t1 = f(X2) <-- Will be removed by DCE.
	// t2 = g(Y2)
	// ...
	// X1 = a[i+1]
	// t4 = f(X1)
	// t5 = g(t4)
	// t6 = op(t2, t5)
	// cond_branch <Loop>
	//
	// We proceed until we cannot find any more such instructions I1 and I2.
	//
	// --- DepChains & Loop carried dependences ---
	// Consider a single basic block loop such as
	//
	// LoopPreheader:
	// X0 = ...
	// Y0 = ...
	// Loop:
	// X2 = PHI<(X0, LoopPreheader), (X1, Loop)>
	// Y2 = PHI<(Y0, LoopPreheader), (X2, Loop)>
	// ...
	// X1 = ...
	// ...
	// cond_branch <Loop>
	//
	// Then there is a dependence between X2 and X1 that goes back one iteration,
	// i.e. X1 is used as X2 in the very next iteration. We represent this as a
	// DepChain from X2 to X1 (X2->X1).
	// Similarly, there is a dependence between Y2 and X1 that goes back two
	// iterations. X1 is used as Y2 two iterations after it is computed. This is
	// represented by a DepChain as (Y2->X2->X1).
	//
	// A DepChain has the following properties.
	// 1. Num of edges in DepChain = Number of Instructions in DepChain = Number of
	// iterations of carried dependence + 1.
	// 2. All instructions in the DepChain except the last are PHIs.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_LIB_TARGET_HEXAGON_HEXAGONVLCR_H
	#define LLVM_LIB_TARGET_HEXAGON_HEXAGONVLCR_H

	#include "llvm/Transforms/Scalar/LoopPassManager.h"

	namespace llvm {

	class Loop;

	/// Hexagon Vector Loop Carried Reuse Pass
	struct HexagonVectorLoopCarriedReusePass
	: public PassInfoMixin<HexagonVectorLoopCarriedReusePass> {
	HexagonVectorLoopCarriedReusePass() {}

	/// Run pass over the Loop.
	PreservedAnalyses run(Loop &L, LoopAnalysisManager &LAM,
	LoopStandardAnalysisResults &AR, LPMUpdater &U);
	};

	} // end namespace llvm

	#endif // LLVM_LIB_TARGET_HEXAGON_HEXAGONVLCR_H