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path: root/contrib/libs/llvm12/lib/Analysis/ConstraintSystem.cpp
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//===- ConstraintSytem.cpp - A system of linear constraints. ----*- C++ -*-===// 
// 
// 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 
// 
//===----------------------------------------------------------------------===// 
 
#include "llvm/Analysis/ConstraintSystem.h" 
#include "llvm/ADT/SmallVector.h" 
#include "llvm/Support/MathExtras.h" 
#include "llvm/ADT/StringExtras.h" 
#include "llvm/Support/Debug.h" 
 
#include <algorithm> 
#include <string> 
 
using namespace llvm; 
 
#define DEBUG_TYPE "constraint-system" 
 
bool ConstraintSystem::eliminateUsingFM() { 
  // Implementation of Fourier–Motzkin elimination, with some tricks from the 
  // paper Pugh, William. "The Omega test: a fast and practical integer 
  // programming algorithm for dependence 
  //  analysis." 
  // Supercomputing'91: Proceedings of the 1991 ACM/ 
  // IEEE conference on Supercomputing. IEEE, 1991. 
  assert(!Constraints.empty() && 
         "should only be called for non-empty constraint systems"); 
  unsigned NumVariables = Constraints[0].size(); 
  SmallVector<SmallVector<int64_t, 8>, 4> NewSystem; 
 
  unsigned NumConstraints = Constraints.size(); 
  uint32_t NewGCD = 1; 
  // FIXME do not use copy 
  for (unsigned R1 = 0; R1 < NumConstraints; R1++) { 
    if (Constraints[R1][1] == 0) { 
      SmallVector<int64_t, 8> NR; 
      NR.push_back(Constraints[R1][0]); 
      for (unsigned i = 2; i < NumVariables; i++) { 
        NR.push_back(Constraints[R1][i]); 
      } 
      NewSystem.push_back(std::move(NR)); 
      continue; 
    } 
 
    // FIXME do not use copy 
    for (unsigned R2 = R1 + 1; R2 < NumConstraints; R2++) { 
      if (R1 == R2) 
        continue; 
 
      // FIXME: can we do better than just dropping things here? 
      if (Constraints[R2][1] == 0) 
        continue; 
 
      if ((Constraints[R1][1] < 0 && Constraints[R2][1] < 0) || 
          (Constraints[R1][1] > 0 && Constraints[R2][1] > 0)) 
        continue; 
 
      unsigned LowerR = R1; 
      unsigned UpperR = R2; 
      if (Constraints[UpperR][1] < 0) 
        std::swap(LowerR, UpperR); 
 
      SmallVector<int64_t, 8> NR; 
      for (unsigned I = 0; I < NumVariables; I++) { 
        if (I == 1) 
          continue; 
 
        int64_t M1, M2, N; 
        if (MulOverflow(Constraints[UpperR][I], 
                                   ((-1) * Constraints[LowerR][1] / GCD), M1)) 
          return false; 
        if (MulOverflow(Constraints[LowerR][I], 
                                   (Constraints[UpperR][1] / GCD), M2)) 
          return false; 
        if (AddOverflow(M1, M2, N)) 
          return false; 
        NR.push_back(N); 
 
        NewGCD = APIntOps::GreatestCommonDivisor({32, (uint32_t)NR.back()}, 
                                                 {32, NewGCD}) 
                     .getZExtValue(); 
      } 
      NewSystem.push_back(std::move(NR)); 
      // Give up if the new system gets too big. 
      if (NewSystem.size() > 500) 
        return false; 
    } 
  } 
  Constraints = std::move(NewSystem); 
  GCD = NewGCD; 
 
  return true; 
} 
 
bool ConstraintSystem::mayHaveSolutionImpl() { 
  while (!Constraints.empty() && Constraints[0].size() > 1) { 
    if (!eliminateUsingFM()) 
      return true; 
  } 
 
  if (Constraints.empty() || Constraints[0].size() > 1) 
    return true; 
 
  return all_of(Constraints, [](auto &R) { return R[0] >= 0; }); 
} 
 
void ConstraintSystem::dump(ArrayRef<std::string> Names) const { 
  if (Constraints.empty()) 
    return; 
 
  for (auto &Row : Constraints) { 
    SmallVector<std::string, 16> Parts; 
    for (unsigned I = 1, S = Row.size(); I < S; ++I) { 
      if (Row[I] == 0) 
        continue; 
      std::string Coefficient; 
      if (Row[I] != 1) 
        Coefficient = std::to_string(Row[I]) + " * "; 
      Parts.push_back(Coefficient + Names[I - 1]); 
    } 
    assert(!Parts.empty() && "need to have at least some parts"); 
    LLVM_DEBUG(dbgs() << join(Parts, std::string(" + ")) 
                      << " <= " << std::to_string(Row[0]) << "\n"); 
  } 
} 
 
void ConstraintSystem::dump() const { 
  SmallVector<std::string, 16> Names; 
  for (unsigned i = 1; i < Constraints.back().size(); ++i) 
    Names.push_back("x" + std::to_string(i)); 
  LLVM_DEBUG(dbgs() << "---\n"); 
  dump(Names); 
} 
 
bool ConstraintSystem::mayHaveSolution() { 
  LLVM_DEBUG(dump()); 
  bool HasSolution = mayHaveSolutionImpl(); 
  LLVM_DEBUG(dbgs() << (HasSolution ? "sat" : "unsat") << "\n"); 
  return HasSolution; 
} 
 
bool ConstraintSystem::isConditionImplied(SmallVector<int64_t, 8> R) { 
  // If all variable coefficients are 0, we have 'C >= 0'. If the constant is >= 
  // 0, R is always true, regardless of the system. 
  if (all_of(makeArrayRef(R).drop_front(1), [](int64_t C) { return C == 0; })) 
    return R[0] >= 0; 
 
  // If there is no solution with the negation of R added to the system, the 
  // condition must hold based on the existing constraints. 
  R = ConstraintSystem::negate(R); 
 
  auto NewSystem = *this; 
  NewSystem.addVariableRow(R); 
  return !NewSystem.mayHaveSolution(); 
}