MLIR  20.0.0git
AffineExpr.cpp
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1 //===- AffineExpr.cpp - MLIR Affine Expr Classes --------------------------===//
2 //
3 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4 // See https://llvm.org/LICENSE.txt for license information.
5 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6 //
7 //===----------------------------------------------------------------------===//
8 
9 #include <cmath>
10 #include <cstdint>
11 #include <limits>
12 #include <utility>
13 
14 #include "AffineExprDetail.h"
15 #include "mlir/IR/AffineExpr.h"
17 #include "mlir/IR/AffineMap.h"
18 #include "mlir/IR/IntegerSet.h"
19 #include "mlir/Support/TypeID.h"
20 #include "llvm/ADT/STLExtras.h"
21 #include "llvm/Support/MathExtras.h"
22 #include <numeric>
23 #include <optional>
24 
25 using namespace mlir;
26 using namespace mlir::detail;
27 
28 using llvm::divideCeilSigned;
29 using llvm::divideFloorSigned;
30 using llvm::divideSignedWouldOverflow;
31 using llvm::mod;
32 
33 MLIRContext *AffineExpr::getContext() const { return expr->context; }
34 
35 AffineExprKind AffineExpr::getKind() const { return expr->kind; }
36 
37 /// Walk all of the AffineExprs in `e` in postorder. This is a private factory
38 /// method to help handle lambda walk functions. Users should use the regular
39 /// (non-static) `walk` method.
40 template <typename WalkRetTy>
42  function_ref<WalkRetTy(AffineExpr)> callback) {
43  struct AffineExprWalker
44  : public AffineExprVisitor<AffineExprWalker, WalkRetTy> {
45  function_ref<WalkRetTy(AffineExpr)> callback;
46 
47  AffineExprWalker(function_ref<WalkRetTy(AffineExpr)> callback)
48  : callback(callback) {}
49 
50  WalkRetTy visitAffineBinaryOpExpr(AffineBinaryOpExpr expr) {
51  return callback(expr);
52  }
53  WalkRetTy visitConstantExpr(AffineConstantExpr expr) {
54  return callback(expr);
55  }
56  WalkRetTy visitDimExpr(AffineDimExpr expr) { return callback(expr); }
57  WalkRetTy visitSymbolExpr(AffineSymbolExpr expr) { return callback(expr); }
58  };
59 
60  return AffineExprWalker(callback).walkPostOrder(e);
61 }
62 // Explicitly instantiate for the two supported return types.
63 template void mlir::AffineExpr::walk(AffineExpr e,
64  function_ref<void(AffineExpr)> callback);
65 template WalkResult
68 
69 // Dispatch affine expression construction based on kind.
71  AffineExpr rhs) {
72  if (kind == AffineExprKind::Add)
73  return lhs + rhs;
74  if (kind == AffineExprKind::Mul)
75  return lhs * rhs;
76  if (kind == AffineExprKind::FloorDiv)
77  return lhs.floorDiv(rhs);
78  if (kind == AffineExprKind::CeilDiv)
79  return lhs.ceilDiv(rhs);
80  if (kind == AffineExprKind::Mod)
81  return lhs % rhs;
82 
83  llvm_unreachable("unknown binary operation on affine expressions");
84 }
85 
86 /// This method substitutes any uses of dimensions and symbols (e.g.
87 /// dim#0 with dimReplacements[0]) and returns the modified expression tree.
90  ArrayRef<AffineExpr> symReplacements) const {
91  switch (getKind()) {
93  return *this;
94  case AffineExprKind::DimId: {
95  unsigned dimId = llvm::cast<AffineDimExpr>(*this).getPosition();
96  if (dimId >= dimReplacements.size())
97  return *this;
98  return dimReplacements[dimId];
99  }
101  unsigned symId = llvm::cast<AffineSymbolExpr>(*this).getPosition();
102  if (symId >= symReplacements.size())
103  return *this;
104  return symReplacements[symId];
105  }
106  case AffineExprKind::Add:
107  case AffineExprKind::Mul:
110  case AffineExprKind::Mod:
111  auto binOp = llvm::cast<AffineBinaryOpExpr>(*this);
112  auto lhs = binOp.getLHS(), rhs = binOp.getRHS();
113  auto newLHS = lhs.replaceDimsAndSymbols(dimReplacements, symReplacements);
114  auto newRHS = rhs.replaceDimsAndSymbols(dimReplacements, symReplacements);
115  if (newLHS == lhs && newRHS == rhs)
116  return *this;
117  return getAffineBinaryOpExpr(getKind(), newLHS, newRHS);
118  }
119  llvm_unreachable("Unknown AffineExpr");
120 }
121 
123  return replaceDimsAndSymbols(dimReplacements, {});
124 }
125 
128  return replaceDimsAndSymbols({}, symReplacements);
129 }
130 
131 /// Replace dims[offset ... numDims)
132 /// by dims[offset + shift ... shift + numDims).
133 AffineExpr AffineExpr::shiftDims(unsigned numDims, unsigned shift,
134  unsigned offset) const {
136  for (unsigned idx = 0; idx < offset; ++idx)
137  dims.push_back(getAffineDimExpr(idx, getContext()));
138  for (unsigned idx = offset; idx < numDims; ++idx)
139  dims.push_back(getAffineDimExpr(idx + shift, getContext()));
140  return replaceDimsAndSymbols(dims, {});
141 }
142 
143 /// Replace symbols[offset ... numSymbols)
144 /// by symbols[offset + shift ... shift + numSymbols).
145 AffineExpr AffineExpr::shiftSymbols(unsigned numSymbols, unsigned shift,
146  unsigned offset) const {
148  for (unsigned idx = 0; idx < offset; ++idx)
149  symbols.push_back(getAffineSymbolExpr(idx, getContext()));
150  for (unsigned idx = offset; idx < numSymbols; ++idx)
151  symbols.push_back(getAffineSymbolExpr(idx + shift, getContext()));
152  return replaceDimsAndSymbols({}, symbols);
153 }
154 
155 /// Sparse replace method. Return the modified expression tree.
158  auto it = map.find(*this);
159  if (it != map.end())
160  return it->second;
161  switch (getKind()) {
162  default:
163  return *this;
164  case AffineExprKind::Add:
165  case AffineExprKind::Mul:
168  case AffineExprKind::Mod:
169  auto binOp = llvm::cast<AffineBinaryOpExpr>(*this);
170  auto lhs = binOp.getLHS(), rhs = binOp.getRHS();
171  auto newLHS = lhs.replace(map);
172  auto newRHS = rhs.replace(map);
173  if (newLHS == lhs && newRHS == rhs)
174  return *this;
175  return getAffineBinaryOpExpr(getKind(), newLHS, newRHS);
176  }
177  llvm_unreachable("Unknown AffineExpr");
178 }
179 
180 /// Sparse replace method. Return the modified expression tree.
183  map.insert(std::make_pair(expr, replacement));
184  return replace(map);
185 }
186 /// Returns true if this expression is made out of only symbols and
187 /// constants (no dimensional identifiers).
189  switch (getKind()) {
191  return true;
193  return false;
195  return true;
196 
197  case AffineExprKind::Add:
198  case AffineExprKind::Mul:
201  case AffineExprKind::Mod: {
202  auto expr = llvm::cast<AffineBinaryOpExpr>(*this);
203  return expr.getLHS().isSymbolicOrConstant() &&
204  expr.getRHS().isSymbolicOrConstant();
205  }
206  }
207  llvm_unreachable("Unknown AffineExpr");
208 }
209 
210 /// Returns true if this is a pure affine expression, i.e., multiplication,
211 /// floordiv, ceildiv, and mod is only allowed w.r.t constants.
213  switch (getKind()) {
217  return true;
218  case AffineExprKind::Add: {
219  auto op = llvm::cast<AffineBinaryOpExpr>(*this);
220  return op.getLHS().isPureAffine() && op.getRHS().isPureAffine();
221  }
222 
223  case AffineExprKind::Mul: {
224  // TODO: Canonicalize the constants in binary operators to the RHS when
225  // possible, allowing this to merge into the next case.
226  auto op = llvm::cast<AffineBinaryOpExpr>(*this);
227  return op.getLHS().isPureAffine() && op.getRHS().isPureAffine() &&
228  (llvm::isa<AffineConstantExpr>(op.getLHS()) ||
229  llvm::isa<AffineConstantExpr>(op.getRHS()));
230  }
233  case AffineExprKind::Mod: {
234  auto op = llvm::cast<AffineBinaryOpExpr>(*this);
235  return op.getLHS().isPureAffine() &&
236  llvm::isa<AffineConstantExpr>(op.getRHS());
237  }
238  }
239  llvm_unreachable("Unknown AffineExpr");
240 }
241 
242 // Returns the greatest known integral divisor of this affine expression.
244  AffineBinaryOpExpr binExpr(nullptr);
245  switch (getKind()) {
247  [[fallthrough]];
249  return 1;
251  [[fallthrough]];
253  // If the RHS is a constant and divides the known divisor on the LHS, the
254  // quotient is a known divisor of the expression.
255  binExpr = llvm::cast<AffineBinaryOpExpr>(*this);
256  auto rhs = llvm::dyn_cast<AffineConstantExpr>(binExpr.getRHS());
257  // Leave alone undefined expressions.
258  if (rhs && rhs.getValue() != 0) {
259  int64_t lhsDiv = binExpr.getLHS().getLargestKnownDivisor();
260  if (lhsDiv % rhs.getValue() == 0)
261  return std::abs(lhsDiv / rhs.getValue());
262  }
263  return 1;
264  }
266  return std::abs(llvm::cast<AffineConstantExpr>(*this).getValue());
267  case AffineExprKind::Mul: {
268  binExpr = llvm::cast<AffineBinaryOpExpr>(*this);
269  return binExpr.getLHS().getLargestKnownDivisor() *
270  binExpr.getRHS().getLargestKnownDivisor();
271  }
272  case AffineExprKind::Add:
273  [[fallthrough]];
274  case AffineExprKind::Mod: {
275  binExpr = llvm::cast<AffineBinaryOpExpr>(*this);
276  return std::gcd((uint64_t)binExpr.getLHS().getLargestKnownDivisor(),
277  (uint64_t)binExpr.getRHS().getLargestKnownDivisor());
278  }
279  }
280  llvm_unreachable("Unknown AffineExpr");
281 }
282 
283 bool AffineExpr::isMultipleOf(int64_t factor) const {
284  AffineBinaryOpExpr binExpr(nullptr);
285  uint64_t l, u;
286  switch (getKind()) {
288  [[fallthrough]];
290  return factor * factor == 1;
292  return llvm::cast<AffineConstantExpr>(*this).getValue() % factor == 0;
293  case AffineExprKind::Mul: {
294  binExpr = llvm::cast<AffineBinaryOpExpr>(*this);
295  // It's probably not worth optimizing this further (to not traverse the
296  // whole sub-tree under - it that would require a version of isMultipleOf
297  // that on a 'false' return also returns the largest known divisor).
298  return (l = binExpr.getLHS().getLargestKnownDivisor()) % factor == 0 ||
299  (u = binExpr.getRHS().getLargestKnownDivisor()) % factor == 0 ||
300  (l * u) % factor == 0;
301  }
302  case AffineExprKind::Add:
305  case AffineExprKind::Mod: {
306  binExpr = llvm::cast<AffineBinaryOpExpr>(*this);
307  return std::gcd((uint64_t)binExpr.getLHS().getLargestKnownDivisor(),
308  (uint64_t)binExpr.getRHS().getLargestKnownDivisor()) %
309  factor ==
310  0;
311  }
312  }
313  llvm_unreachable("Unknown AffineExpr");
314 }
315 
316 bool AffineExpr::isFunctionOfDim(unsigned position) const {
317  if (getKind() == AffineExprKind::DimId) {
318  return *this == mlir::getAffineDimExpr(position, getContext());
319  }
320  if (auto expr = llvm::dyn_cast<AffineBinaryOpExpr>(*this)) {
321  return expr.getLHS().isFunctionOfDim(position) ||
322  expr.getRHS().isFunctionOfDim(position);
323  }
324  return false;
325 }
326 
327 bool AffineExpr::isFunctionOfSymbol(unsigned position) const {
328  if (getKind() == AffineExprKind::SymbolId) {
329  return *this == mlir::getAffineSymbolExpr(position, getContext());
330  }
331  if (auto expr = llvm::dyn_cast<AffineBinaryOpExpr>(*this)) {
332  return expr.getLHS().isFunctionOfSymbol(position) ||
333  expr.getRHS().isFunctionOfSymbol(position);
334  }
335  return false;
336 }
337 
339  : AffineExpr(ptr) {}
341  return static_cast<ImplType *>(expr)->lhs;
342 }
344  return static_cast<ImplType *>(expr)->rhs;
345 }
346 
348 unsigned AffineDimExpr::getPosition() const {
349  return static_cast<ImplType *>(expr)->position;
350 }
351 
352 /// Returns true if the expression is divisible by the given symbol with
353 /// position `symbolPos`. The argument `opKind` specifies here what kind of
354 /// division or mod operation called this division. It helps in implementing the
355 /// commutative property of the floordiv and ceildiv operations. If the argument
356 ///`exprKind` is floordiv and `expr` is also a binary expression of a floordiv
357 /// operation, then the commutative property can be used otherwise, the floordiv
358 /// operation is not divisible. The same argument holds for ceildiv operation.
359 static bool canSimplifyDivisionBySymbol(AffineExpr expr, unsigned symbolPos,
360  AffineExprKind opKind,
361  bool fromMul = false) {
362  // The argument `opKind` can either be Modulo, Floordiv or Ceildiv only.
363  assert((opKind == AffineExprKind::Mod || opKind == AffineExprKind::FloorDiv ||
364  opKind == AffineExprKind::CeilDiv) &&
365  "unexpected opKind");
366  switch (expr.getKind()) {
368  return cast<AffineConstantExpr>(expr).getValue() == 0;
370  return false;
372  return (cast<AffineSymbolExpr>(expr).getPosition() == symbolPos);
373  // Checks divisibility by the given symbol for both operands.
374  case AffineExprKind::Add: {
375  AffineBinaryOpExpr binaryExpr = cast<AffineBinaryOpExpr>(expr);
376  return canSimplifyDivisionBySymbol(binaryExpr.getLHS(), symbolPos,
377  opKind) &&
378  canSimplifyDivisionBySymbol(binaryExpr.getRHS(), symbolPos, opKind);
379  }
380  // Checks divisibility by the given symbol for both operands. Consider the
381  // expression `(((s1*s0) floordiv w) mod ((s1 * s2) floordiv p)) floordiv s1`,
382  // this is a division by s1 and both the operands of modulo are divisible by
383  // s1 but it is not divisible by s1 always. The third argument is
384  // `AffineExprKind::Mod` for this reason.
385  case AffineExprKind::Mod: {
386  AffineBinaryOpExpr binaryExpr = cast<AffineBinaryOpExpr>(expr);
387  return canSimplifyDivisionBySymbol(binaryExpr.getLHS(), symbolPos,
389  canSimplifyDivisionBySymbol(binaryExpr.getRHS(), symbolPos,
391  }
392  // Checks if any of the operand divisible by the given symbol.
393  case AffineExprKind::Mul: {
394  AffineBinaryOpExpr binaryExpr = cast<AffineBinaryOpExpr>(expr);
395  return canSimplifyDivisionBySymbol(binaryExpr.getLHS(), symbolPos, opKind,
396  true) ||
397  canSimplifyDivisionBySymbol(binaryExpr.getRHS(), symbolPos, opKind,
398  true);
399  }
400  // Floordiv and ceildiv are divisible by the given symbol when the first
401  // operand is divisible, and the affine expression kind of the argument expr
402  // is same as the argument `opKind`. This can be inferred from commutative
403  // property of floordiv and ceildiv operations and are as follow:
404  // (exp1 floordiv exp2) floordiv exp3 = (exp1 floordiv exp3) floordiv exp2
405  // (exp1 ceildiv exp2) ceildiv exp3 = (exp1 ceildiv exp3) ceildiv expr2
406  // It will fail 1.if operations are not same. For example:
407  // (exps1 ceildiv exp2) floordiv exp3 can not be simplified. 2.if there is a
408  // multiplication operation in the expression. For example:
409  // (exps1 ceildiv exp2) mul exp3 ceildiv exp4 can not be simplified.
412  AffineBinaryOpExpr binaryExpr = cast<AffineBinaryOpExpr>(expr);
413  if (opKind != expr.getKind())
414  return false;
415  if (fromMul)
416  return false;
417  return canSimplifyDivisionBySymbol(binaryExpr.getLHS(), symbolPos,
418  expr.getKind());
419  }
420  }
421  llvm_unreachable("Unknown AffineExpr");
422 }
423 
424 /// Divides the given expression by the given symbol at position `symbolPos`. It
425 /// considers the divisibility condition is checked before calling itself. A
426 /// null expression is returned whenever the divisibility condition fails.
427 static AffineExpr symbolicDivide(AffineExpr expr, unsigned symbolPos,
428  AffineExprKind opKind) {
429  // THe argument `opKind` can either be Modulo, Floordiv or Ceildiv only.
430  assert((opKind == AffineExprKind::Mod || opKind == AffineExprKind::FloorDiv ||
431  opKind == AffineExprKind::CeilDiv) &&
432  "unexpected opKind");
433  switch (expr.getKind()) {
435  if (cast<AffineConstantExpr>(expr).getValue() != 0)
436  return nullptr;
437  return getAffineConstantExpr(0, expr.getContext());
439  return nullptr;
441  return getAffineConstantExpr(1, expr.getContext());
442  // Dividing both operands by the given symbol.
443  case AffineExprKind::Add: {
444  AffineBinaryOpExpr binaryExpr = cast<AffineBinaryOpExpr>(expr);
445  return getAffineBinaryOpExpr(
446  expr.getKind(), symbolicDivide(binaryExpr.getLHS(), symbolPos, opKind),
447  symbolicDivide(binaryExpr.getRHS(), symbolPos, opKind));
448  }
449  // Dividing both operands by the given symbol.
450  case AffineExprKind::Mod: {
451  AffineBinaryOpExpr binaryExpr = cast<AffineBinaryOpExpr>(expr);
452  return getAffineBinaryOpExpr(
453  expr.getKind(),
454  symbolicDivide(binaryExpr.getLHS(), symbolPos, expr.getKind()),
455  symbolicDivide(binaryExpr.getRHS(), symbolPos, expr.getKind()));
456  }
457  // Dividing any of the operand by the given symbol.
458  case AffineExprKind::Mul: {
459  AffineBinaryOpExpr binaryExpr = cast<AffineBinaryOpExpr>(expr);
460  if (!canSimplifyDivisionBySymbol(binaryExpr.getLHS(), symbolPos, opKind))
461  return binaryExpr.getLHS() *
462  symbolicDivide(binaryExpr.getRHS(), symbolPos, opKind);
463  return symbolicDivide(binaryExpr.getLHS(), symbolPos, opKind) *
464  binaryExpr.getRHS();
465  }
466  // Dividing first operand only by the given symbol.
469  AffineBinaryOpExpr binaryExpr = cast<AffineBinaryOpExpr>(expr);
470  return getAffineBinaryOpExpr(
471  expr.getKind(),
472  symbolicDivide(binaryExpr.getLHS(), symbolPos, expr.getKind()),
473  binaryExpr.getRHS());
474  }
475  }
476  llvm_unreachable("Unknown AffineExpr");
477 }
478 
479 /// Populate `result` with all summand operands of given (potentially nested)
480 /// addition. If the given expression is not an addition, just populate the
481 /// expression itself.
482 /// Example: Add(Add(7, 8), Mul(9, 10)) will return [7, 8, Mul(9, 10)].
484  auto addExpr = dyn_cast<AffineBinaryOpExpr>(expr);
485  if (!addExpr || addExpr.getKind() != AffineExprKind::Add) {
486  result.push_back(expr);
487  return;
488  }
489  getSummandExprs(addExpr.getLHS(), result);
490  getSummandExprs(addExpr.getRHS(), result);
491 }
492 
493 /// Return "true" if `candidate` is a negated expression, i.e., Mul(-1, expr).
494 /// If so, also return the non-negated expression via `expr`.
495 static bool isNegatedAffineExpr(AffineExpr candidate, AffineExpr &expr) {
496  auto mulExpr = dyn_cast<AffineBinaryOpExpr>(candidate);
497  if (!mulExpr || mulExpr.getKind() != AffineExprKind::Mul)
498  return false;
499  if (auto lhs = dyn_cast<AffineConstantExpr>(mulExpr.getLHS())) {
500  if (lhs.getValue() == -1) {
501  expr = mulExpr.getRHS();
502  return true;
503  }
504  }
505  if (auto rhs = dyn_cast<AffineConstantExpr>(mulExpr.getRHS())) {
506  if (rhs.getValue() == -1) {
507  expr = mulExpr.getLHS();
508  return true;
509  }
510  }
511  return false;
512 }
513 
514 /// Return "true" if `lhs` % `rhs` is guaranteed to evaluate to zero based on
515 /// the fact that `lhs` contains another modulo expression that ensures that
516 /// `lhs` is divisible by `rhs`. This is a common pattern in the resulting IR
517 /// after loop peeling.
518 ///
519 /// Example: lhs = ub - ub % step
520 /// rhs = step
521 /// => (ub - ub % step) % step is guaranteed to evaluate to 0.
523  unsigned numDims, unsigned numSymbols) {
524  // TODO: Try to unify this function with `getBoundForAffineExpr`.
525  // Collect all summands in lhs.
526  SmallVector<AffineExpr> summands;
527  getSummandExprs(lhs, summands);
528  // Look for Mul(-1, Mod(x, rhs)) among the summands. If x matches the
529  // remaining summands, then lhs % rhs is guaranteed to evaluate to 0.
530  for (int64_t i = 0, e = summands.size(); i < e; ++i) {
531  AffineExpr current = summands[i];
532  AffineExpr beforeNegation;
533  if (!isNegatedAffineExpr(current, beforeNegation))
534  continue;
535  AffineBinaryOpExpr innerMod = dyn_cast<AffineBinaryOpExpr>(beforeNegation);
536  if (!innerMod || innerMod.getKind() != AffineExprKind::Mod)
537  continue;
538  if (innerMod.getRHS() != rhs)
539  continue;
540  // Sum all remaining summands and subtract x. If that expression can be
541  // simplified to zero, then the remaining summands and x are equal.
543  for (int64_t j = 0; j < e; ++j)
544  if (i != j)
545  diff = diff + summands[j];
546  diff = diff - innerMod.getLHS();
547  diff = simplifyAffineExpr(diff, numDims, numSymbols);
548  auto constExpr = dyn_cast<AffineConstantExpr>(diff);
549  if (constExpr && constExpr.getValue() == 0)
550  return true;
551  }
552  return false;
553 }
554 
555 /// Simplify a semi-affine expression by handling modulo, floordiv, or ceildiv
556 /// operations when the second operand simplifies to a symbol and the first
557 /// operand is divisible by that symbol. It can be applied to any semi-affine
558 /// expression. Returned expression can either be a semi-affine or pure affine
559 /// expression.
560 static AffineExpr simplifySemiAffine(AffineExpr expr, unsigned numDims,
561  unsigned numSymbols) {
562  switch (expr.getKind()) {
566  return expr;
567  case AffineExprKind::Add:
568  case AffineExprKind::Mul: {
569  AffineBinaryOpExpr binaryExpr = cast<AffineBinaryOpExpr>(expr);
570  return getAffineBinaryOpExpr(
571  expr.getKind(),
572  simplifySemiAffine(binaryExpr.getLHS(), numDims, numSymbols),
573  simplifySemiAffine(binaryExpr.getRHS(), numDims, numSymbols));
574  }
575  // Check if the simplification of the second operand is a symbol, and the
576  // first operand is divisible by it. If the operation is a modulo, a constant
577  // zero expression is returned. In the case of floordiv and ceildiv, the
578  // symbol from the simplification of the second operand divides the first
579  // operand. Otherwise, simplification is not possible.
582  case AffineExprKind::Mod: {
583  AffineBinaryOpExpr binaryExpr = cast<AffineBinaryOpExpr>(expr);
584  AffineExpr sLHS =
585  simplifySemiAffine(binaryExpr.getLHS(), numDims, numSymbols);
586  AffineExpr sRHS =
587  simplifySemiAffine(binaryExpr.getRHS(), numDims, numSymbols);
588  if (isModOfModSubtraction(sLHS, sRHS, numDims, numSymbols))
589  return getAffineConstantExpr(0, expr.getContext());
590  AffineSymbolExpr symbolExpr = dyn_cast<AffineSymbolExpr>(
591  simplifySemiAffine(binaryExpr.getRHS(), numDims, numSymbols));
592  if (!symbolExpr)
593  return getAffineBinaryOpExpr(expr.getKind(), sLHS, sRHS);
594  unsigned symbolPos = symbolExpr.getPosition();
595  if (!canSimplifyDivisionBySymbol(binaryExpr.getLHS(), symbolPos,
596  expr.getKind()))
597  return getAffineBinaryOpExpr(expr.getKind(), sLHS, sRHS);
598  if (expr.getKind() == AffineExprKind::Mod)
599  return getAffineConstantExpr(0, expr.getContext());
600  return symbolicDivide(sLHS, symbolPos, expr.getKind());
601  }
602  }
603  llvm_unreachable("Unknown AffineExpr");
604 }
605 
606 static AffineExpr getAffineDimOrSymbol(AffineExprKind kind, unsigned position,
607  MLIRContext *context) {
608  auto assignCtx = [context](AffineDimExprStorage *storage) {
609  storage->context = context;
610  };
611 
612  StorageUniquer &uniquer = context->getAffineUniquer();
613  return uniquer.get<AffineDimExprStorage>(
614  assignCtx, static_cast<unsigned>(kind), position);
615 }
616 
617 AffineExpr mlir::getAffineDimExpr(unsigned position, MLIRContext *context) {
618  return getAffineDimOrSymbol(AffineExprKind::DimId, position, context);
619 }
620 
622  : AffineExpr(ptr) {}
624  return static_cast<ImplType *>(expr)->position;
625 }
626 
627 AffineExpr mlir::getAffineSymbolExpr(unsigned position, MLIRContext *context) {
628  return getAffineDimOrSymbol(AffineExprKind::SymbolId, position, context);
629 }
630 
632  : AffineExpr(ptr) {}
634  return static_cast<ImplType *>(expr)->constant;
635 }
636 
637 bool AffineExpr::operator==(int64_t v) const {
638  return *this == getAffineConstantExpr(v, getContext());
639 }
640 
642  auto assignCtx = [context](AffineConstantExprStorage *storage) {
643  storage->context = context;
644  };
645 
646  StorageUniquer &uniquer = context->getAffineUniquer();
647  return uniquer.get<AffineConstantExprStorage>(assignCtx, constant);
648 }
649 
652  MLIRContext *context) {
653  return llvm::to_vector(llvm::map_range(constants, [&](int64_t constant) {
654  return getAffineConstantExpr(constant, context);
655  }));
656 }
657 
658 /// Simplify add expression. Return nullptr if it can't be simplified.
660  auto lhsConst = dyn_cast<AffineConstantExpr>(lhs);
661  auto rhsConst = dyn_cast<AffineConstantExpr>(rhs);
662  // Fold if both LHS, RHS are a constant and the sum does not overflow.
663  if (lhsConst && rhsConst) {
664  int64_t sum;
665  if (llvm::AddOverflow(lhsConst.getValue(), rhsConst.getValue(), sum)) {
666  return nullptr;
667  }
668  return getAffineConstantExpr(sum, lhs.getContext());
669  }
670 
671  // Canonicalize so that only the RHS is a constant. (4 + d0 becomes d0 + 4).
672  // If only one of them is a symbolic expressions, make it the RHS.
673  if (isa<AffineConstantExpr>(lhs) ||
674  (lhs.isSymbolicOrConstant() && !rhs.isSymbolicOrConstant())) {
675  return rhs + lhs;
676  }
677 
678  // At this point, if there was a constant, it would be on the right.
679 
680  // Addition with a zero is a noop, return the other input.
681  if (rhsConst) {
682  if (rhsConst.getValue() == 0)
683  return lhs;
684  }
685  // Fold successive additions like (d0 + 2) + 3 into d0 + 5.
686  auto lBin = dyn_cast<AffineBinaryOpExpr>(lhs);
687  if (lBin && rhsConst && lBin.getKind() == AffineExprKind::Add) {
688  if (auto lrhs = dyn_cast<AffineConstantExpr>(lBin.getRHS()))
689  return lBin.getLHS() + (lrhs.getValue() + rhsConst.getValue());
690  }
691 
692  // Detect "c1 * expr + c_2 * expr" as "(c1 + c2) * expr".
693  // c1 is rRhsConst, c2 is rLhsConst; firstExpr, secondExpr are their
694  // respective multiplicands.
695  std::optional<int64_t> rLhsConst, rRhsConst;
696  AffineExpr firstExpr, secondExpr;
697  AffineConstantExpr rLhsConstExpr;
698  auto lBinOpExpr = dyn_cast<AffineBinaryOpExpr>(lhs);
699  if (lBinOpExpr && lBinOpExpr.getKind() == AffineExprKind::Mul &&
700  (rLhsConstExpr = dyn_cast<AffineConstantExpr>(lBinOpExpr.getRHS()))) {
701  rLhsConst = rLhsConstExpr.getValue();
702  firstExpr = lBinOpExpr.getLHS();
703  } else {
704  rLhsConst = 1;
705  firstExpr = lhs;
706  }
707 
708  auto rBinOpExpr = dyn_cast<AffineBinaryOpExpr>(rhs);
709  AffineConstantExpr rRhsConstExpr;
710  if (rBinOpExpr && rBinOpExpr.getKind() == AffineExprKind::Mul &&
711  (rRhsConstExpr = dyn_cast<AffineConstantExpr>(rBinOpExpr.getRHS()))) {
712  rRhsConst = rRhsConstExpr.getValue();
713  secondExpr = rBinOpExpr.getLHS();
714  } else {
715  rRhsConst = 1;
716  secondExpr = rhs;
717  }
718 
719  if (rLhsConst && rRhsConst && firstExpr == secondExpr)
720  return getAffineBinaryOpExpr(
721  AffineExprKind::Mul, firstExpr,
722  getAffineConstantExpr(*rLhsConst + *rRhsConst, lhs.getContext()));
723 
724  // When doing successive additions, bring constant to the right: turn (d0 + 2)
725  // + d1 into (d0 + d1) + 2.
726  if (lBin && lBin.getKind() == AffineExprKind::Add) {
727  if (auto lrhs = dyn_cast<AffineConstantExpr>(lBin.getRHS())) {
728  return lBin.getLHS() + rhs + lrhs;
729  }
730  }
731 
732  // Detect and transform "expr - q * (expr floordiv q)" to "expr mod q", where
733  // q may be a constant or symbolic expression. This leads to a much more
734  // efficient form when 'c' is a power of two, and in general a more compact
735  // and readable form.
736 
737  // Process '(expr floordiv c) * (-c)'.
738  if (!rBinOpExpr)
739  return nullptr;
740 
741  auto lrhs = rBinOpExpr.getLHS();
742  auto rrhs = rBinOpExpr.getRHS();
743 
744  AffineExpr llrhs, rlrhs;
745 
746  // Check if lrhsBinOpExpr is of the form (expr floordiv q) * q, where q is a
747  // symbolic expression.
748  auto lrhsBinOpExpr = dyn_cast<AffineBinaryOpExpr>(lrhs);
749  // Check rrhsConstOpExpr = -1.
750  auto rrhsConstOpExpr = dyn_cast<AffineConstantExpr>(rrhs);
751  if (rrhsConstOpExpr && rrhsConstOpExpr.getValue() == -1 && lrhsBinOpExpr &&
752  lrhsBinOpExpr.getKind() == AffineExprKind::Mul) {
753  // Check llrhs = expr floordiv q.
754  llrhs = lrhsBinOpExpr.getLHS();
755  // Check rlrhs = q.
756  rlrhs = lrhsBinOpExpr.getRHS();
757  auto llrhsBinOpExpr = dyn_cast<AffineBinaryOpExpr>(llrhs);
758  if (!llrhsBinOpExpr || llrhsBinOpExpr.getKind() != AffineExprKind::FloorDiv)
759  return nullptr;
760  if (llrhsBinOpExpr.getRHS() == rlrhs && lhs == llrhsBinOpExpr.getLHS())
761  return lhs % rlrhs;
762  }
763 
764  // Process lrhs, which is 'expr floordiv c'.
765  // expr + (expr // c * -c) = expr % c
766  AffineBinaryOpExpr lrBinOpExpr = dyn_cast<AffineBinaryOpExpr>(lrhs);
767  if (!lrBinOpExpr || rhs.getKind() != AffineExprKind::Mul ||
768  lrBinOpExpr.getKind() != AffineExprKind::FloorDiv)
769  return nullptr;
770 
771  llrhs = lrBinOpExpr.getLHS();
772  rlrhs = lrBinOpExpr.getRHS();
773  auto rlrhsConstOpExpr = dyn_cast<AffineConstantExpr>(rlrhs);
774  // We don't support modulo with a negative RHS.
775  bool isPositiveRhs = rlrhsConstOpExpr && rlrhsConstOpExpr.getValue() > 0;
776 
777  if (isPositiveRhs && lhs == llrhs && rlrhs == -rrhs) {
778  return lhs % rlrhs;
779  }
780  return nullptr;
781 }
782 
784  return *this + getAffineConstantExpr(v, getContext());
785 }
787  if (auto simplified = simplifyAdd(*this, other))
788  return simplified;
789 
791  return uniquer.get<AffineBinaryOpExprStorage>(
792  /*initFn=*/{}, static_cast<unsigned>(AffineExprKind::Add), *this, other);
793 }
794 
795 /// Simplify a multiply expression. Return nullptr if it can't be simplified.
797  auto lhsConst = dyn_cast<AffineConstantExpr>(lhs);
798  auto rhsConst = dyn_cast<AffineConstantExpr>(rhs);
799 
800  if (lhsConst && rhsConst) {
801  int64_t product;
802  if (llvm::MulOverflow(lhsConst.getValue(), rhsConst.getValue(), product)) {
803  return nullptr;
804  }
806  }
807 
808  if (!lhs.isSymbolicOrConstant() && !rhs.isSymbolicOrConstant())
809  return nullptr;
810 
811  // Canonicalize the mul expression so that the constant/symbolic term is the
812  // RHS. If both the lhs and rhs are symbolic, swap them if the lhs is a
813  // constant. (Note that a constant is trivially symbolic).
814  if (!rhs.isSymbolicOrConstant() || isa<AffineConstantExpr>(lhs)) {
815  // At least one of them has to be symbolic.
816  return rhs * lhs;
817  }
818 
819  // At this point, if there was a constant, it would be on the right.
820 
821  // Multiplication with a one is a noop, return the other input.
822  if (rhsConst) {
823  if (rhsConst.getValue() == 1)
824  return lhs;
825  // Multiplication with zero.
826  if (rhsConst.getValue() == 0)
827  return rhsConst;
828  }
829 
830  // Fold successive multiplications: eg: (d0 * 2) * 3 into d0 * 6.
831  auto lBin = dyn_cast<AffineBinaryOpExpr>(lhs);
832  if (lBin && rhsConst && lBin.getKind() == AffineExprKind::Mul) {
833  if (auto lrhs = dyn_cast<AffineConstantExpr>(lBin.getRHS()))
834  return lBin.getLHS() * (lrhs.getValue() * rhsConst.getValue());
835  }
836 
837  // When doing successive multiplication, bring constant to the right: turn (d0
838  // * 2) * d1 into (d0 * d1) * 2.
839  if (lBin && lBin.getKind() == AffineExprKind::Mul) {
840  if (auto lrhs = dyn_cast<AffineConstantExpr>(lBin.getRHS())) {
841  return (lBin.getLHS() * rhs) * lrhs;
842  }
843  }
844 
845  return nullptr;
846 }
847 
849  return *this * getAffineConstantExpr(v, getContext());
850 }
852  if (auto simplified = simplifyMul(*this, other))
853  return simplified;
854 
856  return uniquer.get<AffineBinaryOpExprStorage>(
857  /*initFn=*/{}, static_cast<unsigned>(AffineExprKind::Mul), *this, other);
858 }
859 
860 // Unary minus, delegate to operator*.
862  return *this * getAffineConstantExpr(-1, getContext());
863 }
864 
865 // Delegate to operator+.
866 AffineExpr AffineExpr::operator-(int64_t v) const { return *this + (-v); }
868  return *this + (-other);
869 }
870 
872  auto lhsConst = dyn_cast<AffineConstantExpr>(lhs);
873  auto rhsConst = dyn_cast<AffineConstantExpr>(rhs);
874 
875  if (!rhsConst || rhsConst.getValue() == 0)
876  return nullptr;
877 
878  if (lhsConst) {
879  if (divideSignedWouldOverflow(lhsConst.getValue(), rhsConst.getValue()))
880  return nullptr;
881  return getAffineConstantExpr(
882  divideFloorSigned(lhsConst.getValue(), rhsConst.getValue()),
883  lhs.getContext());
884  }
885 
886  // Fold floordiv of a multiply with a constant that is a multiple of the
887  // divisor. Eg: (i * 128) floordiv 64 = i * 2.
888  if (rhsConst == 1)
889  return lhs;
890 
891  // Simplify `(expr * lrhs) floordiv rhsConst` when `lrhs` is known to be a
892  // multiple of `rhsConst`.
893  auto lBin = dyn_cast<AffineBinaryOpExpr>(lhs);
894  if (lBin && lBin.getKind() == AffineExprKind::Mul) {
895  if (auto lrhs = dyn_cast<AffineConstantExpr>(lBin.getRHS())) {
896  // `rhsConst` is known to be a nonzero constant.
897  if (lrhs.getValue() % rhsConst.getValue() == 0)
898  return lBin.getLHS() * (lrhs.getValue() / rhsConst.getValue());
899  }
900  }
901 
902  // Simplify (expr1 + expr2) floordiv divConst when either expr1 or expr2 is
903  // known to be a multiple of divConst.
904  if (lBin && lBin.getKind() == AffineExprKind::Add) {
905  int64_t llhsDiv = lBin.getLHS().getLargestKnownDivisor();
906  int64_t lrhsDiv = lBin.getRHS().getLargestKnownDivisor();
907  // rhsConst is known to be a nonzero constant.
908  if (llhsDiv % rhsConst.getValue() == 0 ||
909  lrhsDiv % rhsConst.getValue() == 0)
910  return lBin.getLHS().floorDiv(rhsConst.getValue()) +
911  lBin.getRHS().floorDiv(rhsConst.getValue());
912  }
913 
914  return nullptr;
915 }
916 
917 AffineExpr AffineExpr::floorDiv(uint64_t v) const {
919 }
921  if (auto simplified = simplifyFloorDiv(*this, other))
922  return simplified;
923 
925  return uniquer.get<AffineBinaryOpExprStorage>(
926  /*initFn=*/{}, static_cast<unsigned>(AffineExprKind::FloorDiv), *this,
927  other);
928 }
929 
931  auto lhsConst = dyn_cast<AffineConstantExpr>(lhs);
932  auto rhsConst = dyn_cast<AffineConstantExpr>(rhs);
933 
934  if (!rhsConst || rhsConst.getValue() == 0)
935  return nullptr;
936 
937  if (lhsConst) {
938  if (divideSignedWouldOverflow(lhsConst.getValue(), rhsConst.getValue()))
939  return nullptr;
940  return getAffineConstantExpr(
941  divideCeilSigned(lhsConst.getValue(), rhsConst.getValue()),
942  lhs.getContext());
943  }
944 
945  // Fold ceildiv of a multiply with a constant that is a multiple of the
946  // divisor. Eg: (i * 128) ceildiv 64 = i * 2.
947  if (rhsConst.getValue() == 1)
948  return lhs;
949 
950  // Simplify `(expr * lrhs) ceildiv rhsConst` when `lrhs` is known to be a
951  // multiple of `rhsConst`.
952  auto lBin = dyn_cast<AffineBinaryOpExpr>(lhs);
953  if (lBin && lBin.getKind() == AffineExprKind::Mul) {
954  if (auto lrhs = dyn_cast<AffineConstantExpr>(lBin.getRHS())) {
955  // `rhsConst` is known to be a nonzero constant.
956  if (lrhs.getValue() % rhsConst.getValue() == 0)
957  return lBin.getLHS() * (lrhs.getValue() / rhsConst.getValue());
958  }
959  }
960 
961  return nullptr;
962 }
963 
964 AffineExpr AffineExpr::ceilDiv(uint64_t v) const {
966 }
968  if (auto simplified = simplifyCeilDiv(*this, other))
969  return simplified;
970 
972  return uniquer.get<AffineBinaryOpExprStorage>(
973  /*initFn=*/{}, static_cast<unsigned>(AffineExprKind::CeilDiv), *this,
974  other);
975 }
976 
978  auto lhsConst = dyn_cast<AffineConstantExpr>(lhs);
979  auto rhsConst = dyn_cast<AffineConstantExpr>(rhs);
980 
981  // mod w.r.t zero or negative numbers is undefined and preserved as is.
982  if (!rhsConst || rhsConst.getValue() < 1)
983  return nullptr;
984 
985  if (lhsConst) {
986  // mod never overflows.
987  return getAffineConstantExpr(mod(lhsConst.getValue(), rhsConst.getValue()),
988  lhs.getContext());
989  }
990 
991  // Fold modulo of an expression that is known to be a multiple of a constant
992  // to zero if that constant is a multiple of the modulo factor. Eg: (i * 128)
993  // mod 64 is folded to 0, and less trivially, (i*(j*4*(k*32))) mod 128 = 0.
994  if (lhs.getLargestKnownDivisor() % rhsConst.getValue() == 0)
995  return getAffineConstantExpr(0, lhs.getContext());
996 
997  // Simplify (expr1 + expr2) mod divConst when either expr1 or expr2 is
998  // known to be a multiple of divConst.
999  auto lBin = dyn_cast<AffineBinaryOpExpr>(lhs);
1000  if (lBin && lBin.getKind() == AffineExprKind::Add) {
1001  int64_t llhsDiv = lBin.getLHS().getLargestKnownDivisor();
1002  int64_t lrhsDiv = lBin.getRHS().getLargestKnownDivisor();
1003  // rhsConst is known to be a positive constant.
1004  if (llhsDiv % rhsConst.getValue() == 0)
1005  return lBin.getRHS() % rhsConst.getValue();
1006  if (lrhsDiv % rhsConst.getValue() == 0)
1007  return lBin.getLHS() % rhsConst.getValue();
1008  }
1009 
1010  // Simplify (e % a) % b to e % b when b evenly divides a
1011  if (lBin && lBin.getKind() == AffineExprKind::Mod) {
1012  auto intermediate = dyn_cast<AffineConstantExpr>(lBin.getRHS());
1013  if (intermediate && intermediate.getValue() >= 1 &&
1014  mod(intermediate.getValue(), rhsConst.getValue()) == 0) {
1015  return lBin.getLHS() % rhsConst.getValue();
1016  }
1017  }
1018 
1019  return nullptr;
1020 }
1021 
1023  return *this % getAffineConstantExpr(v, getContext());
1024 }
1026  if (auto simplified = simplifyMod(*this, other))
1027  return simplified;
1028 
1029  StorageUniquer &uniquer = getContext()->getAffineUniquer();
1030  return uniquer.get<AffineBinaryOpExprStorage>(
1031  /*initFn=*/{}, static_cast<unsigned>(AffineExprKind::Mod), *this, other);
1032 }
1033 
1035  SmallVector<AffineExpr, 8> dimReplacements(map.getResults());
1036  return replaceDimsAndSymbols(dimReplacements, {});
1037 }
1038 raw_ostream &mlir::operator<<(raw_ostream &os, AffineExpr expr) {
1039  expr.print(os);
1040  return os;
1041 }
1042 
1043 /// Constructs an affine expression from a flat ArrayRef. If there are local
1044 /// identifiers (neither dimensional nor symbolic) that appear in the sum of
1045 /// products expression, `localExprs` is expected to have the AffineExpr
1046 /// for it, and is substituted into. The ArrayRef `flatExprs` is expected to be
1047 /// in the format [dims, symbols, locals, constant term].
1049  unsigned numDims,
1050  unsigned numSymbols,
1051  ArrayRef<AffineExpr> localExprs,
1052  MLIRContext *context) {
1053  // Assert expected numLocals = flatExprs.size() - numDims - numSymbols - 1.
1054  assert(flatExprs.size() - numDims - numSymbols - 1 == localExprs.size() &&
1055  "unexpected number of local expressions");
1056 
1057  auto expr = getAffineConstantExpr(0, context);
1058  // Dimensions and symbols.
1059  for (unsigned j = 0; j < numDims + numSymbols; j++) {
1060  if (flatExprs[j] == 0)
1061  continue;
1062  auto id = j < numDims ? getAffineDimExpr(j, context)
1063  : getAffineSymbolExpr(j - numDims, context);
1064  expr = expr + id * flatExprs[j];
1065  }
1066 
1067  // Local identifiers.
1068  for (unsigned j = numDims + numSymbols, e = flatExprs.size() - 1; j < e;
1069  j++) {
1070  if (flatExprs[j] == 0)
1071  continue;
1072  auto term = localExprs[j - numDims - numSymbols] * flatExprs[j];
1073  expr = expr + term;
1074  }
1075 
1076  // Constant term.
1077  int64_t constTerm = flatExprs[flatExprs.size() - 1];
1078  if (constTerm != 0)
1079  expr = expr + constTerm;
1080  return expr;
1081 }
1082 
1083 /// Constructs a semi-affine expression from a flat ArrayRef. If there are
1084 /// local identifiers (neither dimensional nor symbolic) that appear in the sum
1085 /// of products expression, `localExprs` is expected to have the AffineExprs for
1086 /// it, and is substituted into. The ArrayRef `flatExprs` is expected to be in
1087 /// the format [dims, symbols, locals, constant term]. The semi-affine
1088 /// expression is constructed in the sorted order of dimension and symbol
1089 /// position numbers. Note: local expressions/ids are used for mod, div as well
1090 /// as symbolic RHS terms for terms that are not pure affine.
1092  unsigned numDims,
1093  unsigned numSymbols,
1094  ArrayRef<AffineExpr> localExprs,
1095  MLIRContext *context) {
1096  assert(!flatExprs.empty() && "flatExprs cannot be empty");
1097 
1098  // Assert expected numLocals = flatExprs.size() - numDims - numSymbols - 1.
1099  assert(flatExprs.size() - numDims - numSymbols - 1 == localExprs.size() &&
1100  "unexpected number of local expressions");
1101 
1102  AffineExpr expr = getAffineConstantExpr(0, context);
1103 
1104  // We design indices as a pair which help us present the semi-affine map as
1105  // sum of product where terms are sorted based on dimension or symbol
1106  // position: <keyA, keyB> for expressions of the form dimension * symbol,
1107  // where keyA is the position number of the dimension and keyB is the
1108  // position number of the symbol. For dimensional expressions we set the index
1109  // as (position number of the dimension, -1), as we want dimensional
1110  // expressions to appear before symbolic and product of dimensional and
1111  // symbolic expressions having the dimension with the same position number.
1112  // For symbolic expression set the index as (position number of the symbol,
1113  // maximum of last dimension and symbol position) number. For example, we want
1114  // the expression we are constructing to look something like: d0 + d0 * s0 +
1115  // s0 + d1*s1 + s1.
1116 
1117  // Stores the affine expression corresponding to a given index.
1119  // Stores the constant coefficient value corresponding to a given
1120  // dimension, symbol or a non-pure affine expression stored in `localExprs`.
1121  DenseMap<std::pair<unsigned, signed>, int64_t> coefficients;
1122  // Stores the indices as defined above, and later sorted to produce
1123  // the semi-affine expression in the desired form.
1125 
1126  // Example: expression = d0 + d0 * s0 + 2 * s0.
1127  // indices = [{0,-1}, {0, 0}, {0, 1}]
1128  // coefficients = [{{0, -1}, 1}, {{0, 0}, 1}, {{0, 1}, 2}]
1129  // indexToExprMap = [{{0, -1}, d0}, {{0, 0}, d0 * s0}, {{0, 1}, s0}]
1130 
1131  // Adds entries to `indexToExprMap`, `coefficients` and `indices`.
1132  auto addEntry = [&](std::pair<unsigned, signed> index, int64_t coefficient,
1133  AffineExpr expr) {
1134  assert(!llvm::is_contained(indices, index) &&
1135  "Key is already present in indices vector and overwriting will "
1136  "happen in `indexToExprMap` and `coefficients`!");
1137 
1138  indices.push_back(index);
1139  coefficients.insert({index, coefficient});
1140  indexToExprMap.insert({index, expr});
1141  };
1142 
1143  // Design indices for dimensional or symbolic terms, and store the indices,
1144  // constant coefficient corresponding to the indices in `coefficients` map,
1145  // and affine expression corresponding to indices in `indexToExprMap` map.
1146 
1147  // Ensure we do not have duplicate keys in `indexToExpr` map.
1148  unsigned offsetSym = 0;
1149  signed offsetDim = -1;
1150  for (unsigned j = numDims; j < numDims + numSymbols; ++j) {
1151  if (flatExprs[j] == 0)
1152  continue;
1153  // For symbolic expression set the index as <position number
1154  // of the symbol, max(dimCount, symCount)> number,
1155  // as we want symbolic expressions with the same positional number to
1156  // appear after dimensional expressions having the same positional number.
1157  std::pair<unsigned, signed> indexEntry(
1158  j - numDims, std::max(numDims, numSymbols) + offsetSym++);
1159  addEntry(indexEntry, flatExprs[j],
1160  getAffineSymbolExpr(j - numDims, context));
1161  }
1162 
1163  // Denotes semi-affine product, modulo or division terms, which has been added
1164  // to the `indexToExpr` map.
1165  SmallVector<bool, 4> addedToMap(flatExprs.size() - numDims - numSymbols - 1,
1166  false);
1167  unsigned lhsPos, rhsPos;
1168  // Construct indices for product terms involving dimension, symbol or constant
1169  // as lhs/rhs, and store the indices, constant coefficient corresponding to
1170  // the indices in `coefficients` map, and affine expression corresponding to
1171  // in indices in `indexToExprMap` map.
1172  for (const auto &it : llvm::enumerate(localExprs)) {
1173  AffineExpr expr = it.value();
1174  if (flatExprs[numDims + numSymbols + it.index()] == 0)
1175  continue;
1176  AffineExpr lhs = cast<AffineBinaryOpExpr>(expr).getLHS();
1177  AffineExpr rhs = cast<AffineBinaryOpExpr>(expr).getRHS();
1178  if (!((isa<AffineDimExpr>(lhs) || isa<AffineSymbolExpr>(lhs)) &&
1179  (isa<AffineDimExpr>(rhs) || isa<AffineSymbolExpr>(rhs) ||
1180  isa<AffineConstantExpr>(rhs)))) {
1181  continue;
1182  }
1183  if (isa<AffineConstantExpr>(rhs)) {
1184  // For product/modulo/division expressions, when rhs of modulo/division
1185  // expression is constant, we put 0 in place of keyB, because we want
1186  // them to appear earlier in the semi-affine expression we are
1187  // constructing. When rhs is constant, we place 0 in place of keyB.
1188  if (isa<AffineDimExpr>(lhs)) {
1189  lhsPos = cast<AffineDimExpr>(lhs).getPosition();
1190  std::pair<unsigned, signed> indexEntry(lhsPos, offsetDim--);
1191  addEntry(indexEntry, flatExprs[numDims + numSymbols + it.index()],
1192  expr);
1193  } else {
1194  lhsPos = cast<AffineSymbolExpr>(lhs).getPosition();
1195  std::pair<unsigned, signed> indexEntry(
1196  lhsPos, std::max(numDims, numSymbols) + offsetSym++);
1197  addEntry(indexEntry, flatExprs[numDims + numSymbols + it.index()],
1198  expr);
1199  }
1200  } else if (isa<AffineDimExpr>(lhs)) {
1201  // For product/modulo/division expressions having lhs as dimension and rhs
1202  // as symbol, we order the terms in the semi-affine expression based on
1203  // the pair: <keyA, keyB> for expressions of the form dimension * symbol,
1204  // where keyA is the position number of the dimension and keyB is the
1205  // position number of the symbol.
1206  lhsPos = cast<AffineDimExpr>(lhs).getPosition();
1207  rhsPos = cast<AffineSymbolExpr>(rhs).getPosition();
1208  std::pair<unsigned, signed> indexEntry(lhsPos, rhsPos);
1209  addEntry(indexEntry, flatExprs[numDims + numSymbols + it.index()], expr);
1210  } else {
1211  // For product/modulo/division expressions having both lhs and rhs as
1212  // symbol, we design indices as a pair: <keyA, keyB> for expressions
1213  // of the form dimension * symbol, where keyA is the position number of
1214  // the dimension and keyB is the position number of the symbol.
1215  lhsPos = cast<AffineSymbolExpr>(lhs).getPosition();
1216  rhsPos = cast<AffineSymbolExpr>(rhs).getPosition();
1217  std::pair<unsigned, signed> indexEntry(
1218  lhsPos, std::max(numDims, numSymbols) + offsetSym++);
1219  addEntry(indexEntry, flatExprs[numDims + numSymbols + it.index()], expr);
1220  }
1221  addedToMap[it.index()] = true;
1222  }
1223 
1224  for (unsigned j = 0; j < numDims; ++j) {
1225  if (flatExprs[j] == 0)
1226  continue;
1227  // For dimensional expressions we set the index as <position number of the
1228  // dimension, 0>, as we want dimensional expressions to appear before
1229  // symbolic ones and products of dimensional and symbolic expressions
1230  // having the dimension with the same position number.
1231  std::pair<unsigned, signed> indexEntry(j, offsetDim--);
1232  addEntry(indexEntry, flatExprs[j], getAffineDimExpr(j, context));
1233  }
1234 
1235  // Constructing the simplified semi-affine sum of product/division/mod
1236  // expression from the flattened form in the desired sorted order of indices
1237  // of the various individual product/division/mod expressions.
1238  llvm::sort(indices);
1239  for (const std::pair<unsigned, unsigned> index : indices) {
1240  assert(indexToExprMap.lookup(index) &&
1241  "cannot find key in `indexToExprMap` map");
1242  expr = expr + indexToExprMap.lookup(index) * coefficients.lookup(index);
1243  }
1244 
1245  // Local identifiers.
1246  for (unsigned j = numDims + numSymbols, e = flatExprs.size() - 1; j < e;
1247  j++) {
1248  // If the coefficient of the local expression is 0, continue as we need not
1249  // add it in out final expression.
1250  if (flatExprs[j] == 0 || addedToMap[j - numDims - numSymbols])
1251  continue;
1252  auto term = localExprs[j - numDims - numSymbols] * flatExprs[j];
1253  expr = expr + term;
1254  }
1255 
1256  // Constant term.
1257  int64_t constTerm = flatExprs.back();
1258  if (constTerm != 0)
1259  expr = expr + constTerm;
1260  return expr;
1261 }
1262 
1264  unsigned numSymbols)
1265  : numDims(numDims), numSymbols(numSymbols), numLocals(0) {
1266  operandExprStack.reserve(8);
1267 }
1268 
1269 // In pure affine t = expr * c, we multiply each coefficient of lhs with c.
1270 //
1271 // In case of semi affine multiplication expressions, t = expr * symbolic_expr,
1272 // introduce a local variable p (= expr * symbolic_expr), and the affine
1273 // expression expr * symbolic_expr is added to `localExprs`.
1275  assert(operandExprStack.size() >= 2);
1277  operandExprStack.pop_back();
1279 
1280  // Flatten semi-affine multiplication expressions by introducing a local
1281  // variable in place of the product; the affine expression
1282  // corresponding to the quantifier is added to `localExprs`.
1283  if (!isa<AffineConstantExpr>(expr.getRHS())) {
1284  SmallVector<int64_t, 8> mulLhs(lhs);
1285  MLIRContext *context = expr.getContext();
1287  localExprs, context);
1289  localExprs, context);
1290  return addLocalVariableSemiAffine(mulLhs, rhs, a * b, lhs, lhs.size());
1291  }
1292 
1293  // Get the RHS constant.
1294  int64_t rhsConst = rhs[getConstantIndex()];
1295  for (int64_t &lhsElt : lhs)
1296  lhsElt *= rhsConst;
1297 
1298  return success();
1299 }
1300 
1302  assert(operandExprStack.size() >= 2);
1303  const auto &rhs = operandExprStack.back();
1304  auto &lhs = operandExprStack[operandExprStack.size() - 2];
1305  assert(lhs.size() == rhs.size());
1306  // Update the LHS in place.
1307  for (unsigned i = 0, e = rhs.size(); i < e; i++) {
1308  lhs[i] += rhs[i];
1309  }
1310  // Pop off the RHS.
1311  operandExprStack.pop_back();
1312  return success();
1313 }
1314 
1315 //
1316 // t = expr mod c <=> t = expr - c*q and c*q <= expr <= c*q + c - 1
1317 //
1318 // A mod expression "expr mod c" is thus flattened by introducing a new local
1319 // variable q (= expr floordiv c), such that expr mod c is replaced with
1320 // 'expr - c * q' and c * q <= expr <= c * q + c - 1 are added to localVarCst.
1321 //
1322 // In case of semi-affine modulo expressions, t = expr mod symbolic_expr,
1323 // introduce a local variable m (= expr mod symbolic_expr), and the affine
1324 // expression expr mod symbolic_expr is added to `localExprs`.
1326  assert(operandExprStack.size() >= 2);
1327 
1329  operandExprStack.pop_back();
1331  MLIRContext *context = expr.getContext();
1332 
1333  // Flatten semi affine modulo expressions by introducing a local
1334  // variable in place of the modulo value, and the affine expression
1335  // corresponding to the quantifier is added to `localExprs`.
1336  if (!isa<AffineConstantExpr>(expr.getRHS())) {
1337  SmallVector<int64_t, 8> modLhs(lhs);
1338  AffineExpr dividendExpr = getAffineExprFromFlatForm(
1339  lhs, numDims, numSymbols, localExprs, context);
1341  localExprs, context);
1342  AffineExpr modExpr = dividendExpr % divisorExpr;
1343  return addLocalVariableSemiAffine(modLhs, rhs, modExpr, lhs, lhs.size());
1344  }
1345 
1346  int64_t rhsConst = rhs[getConstantIndex()];
1347  if (rhsConst <= 0)
1348  return failure();
1349 
1350  // Check if the LHS expression is a multiple of modulo factor.
1351  unsigned i, e;
1352  for (i = 0, e = lhs.size(); i < e; i++)
1353  if (lhs[i] % rhsConst != 0)
1354  break;
1355  // If yes, modulo expression here simplifies to zero.
1356  if (i == lhs.size()) {
1357  std::fill(lhs.begin(), lhs.end(), 0);
1358  return success();
1359  }
1360 
1361  // Add a local variable for the quotient, i.e., expr % c is replaced by
1362  // (expr - q * c) where q = expr floordiv c. Do this while canceling out
1363  // the GCD of expr and c.
1364  SmallVector<int64_t, 8> floorDividend(lhs);
1365  uint64_t gcd = rhsConst;
1366  for (int64_t lhsElt : lhs)
1367  gcd = std::gcd(gcd, (uint64_t)std::abs(lhsElt));
1368  // Simplify the numerator and the denominator.
1369  if (gcd != 1) {
1370  for (int64_t &floorDividendElt : floorDividend)
1371  floorDividendElt = floorDividendElt / static_cast<int64_t>(gcd);
1372  }
1373  int64_t floorDivisor = rhsConst / static_cast<int64_t>(gcd);
1374 
1375  // Construct the AffineExpr form of the floordiv to store in localExprs.
1376 
1377  AffineExpr dividendExpr = getAffineExprFromFlatForm(
1378  floorDividend, numDims, numSymbols, localExprs, context);
1379  AffineExpr divisorExpr = getAffineConstantExpr(floorDivisor, context);
1380  AffineExpr floorDivExpr = dividendExpr.floorDiv(divisorExpr);
1381  int loc;
1382  if ((loc = findLocalId(floorDivExpr)) == -1) {
1383  addLocalFloorDivId(floorDividend, floorDivisor, floorDivExpr);
1384  // Set result at top of stack to "lhs - rhsConst * q".
1385  lhs[getLocalVarStartIndex() + numLocals - 1] = -rhsConst;
1386  } else {
1387  // Reuse the existing local id.
1388  lhs[getLocalVarStartIndex() + loc] -= rhsConst;
1389  }
1390  return success();
1391 }
1392 
1393 LogicalResult
1395  return visitDivExpr(expr, /*isCeil=*/true);
1396 }
1397 LogicalResult
1399  return visitDivExpr(expr, /*isCeil=*/false);
1400 }
1401 
1403  operandExprStack.emplace_back(SmallVector<int64_t, 32>(getNumCols(), 0));
1404  auto &eq = operandExprStack.back();
1405  assert(expr.getPosition() < numDims && "Inconsistent number of dims");
1406  eq[getDimStartIndex() + expr.getPosition()] = 1;
1407  return success();
1408 }
1409 
1410 LogicalResult
1412  operandExprStack.emplace_back(SmallVector<int64_t, 32>(getNumCols(), 0));
1413  auto &eq = operandExprStack.back();
1414  assert(expr.getPosition() < numSymbols && "inconsistent number of symbols");
1415  eq[getSymbolStartIndex() + expr.getPosition()] = 1;
1416  return success();
1417 }
1418 
1419 LogicalResult
1421  operandExprStack.emplace_back(SmallVector<int64_t, 32>(getNumCols(), 0));
1422  auto &eq = operandExprStack.back();
1423  eq[getConstantIndex()] = expr.getValue();
1424  return success();
1425 }
1426 
1427 LogicalResult SimpleAffineExprFlattener::addLocalVariableSemiAffine(
1428  ArrayRef<int64_t> lhs, ArrayRef<int64_t> rhs, AffineExpr localExpr,
1429  SmallVectorImpl<int64_t> &result, unsigned long resultSize) {
1430  assert(result.size() == resultSize &&
1431  "`result` vector passed is not of correct size");
1432  int loc;
1433  if ((loc = findLocalId(localExpr)) == -1) {
1434  if (failed(addLocalIdSemiAffine(lhs, rhs, localExpr)))
1435  return failure();
1436  }
1437  std::fill(result.begin(), result.end(), 0);
1438  if (loc == -1)
1439  result[getLocalVarStartIndex() + numLocals - 1] = 1;
1440  else
1441  result[getLocalVarStartIndex() + loc] = 1;
1442  return success();
1443 }
1444 
1445 // t = expr floordiv c <=> t = q, c * q <= expr <= c * q + c - 1
1446 // A floordiv is thus flattened by introducing a new local variable q, and
1447 // replacing that expression with 'q' while adding the constraints
1448 // c * q <= expr <= c * q + c - 1 to localVarCst (done by
1449 // IntegerRelation::addLocalFloorDiv).
1450 //
1451 // A ceildiv is similarly flattened:
1452 // t = expr ceildiv c <=> t = (expr + c - 1) floordiv c
1453 //
1454 // In case of semi affine division expressions, t = expr floordiv symbolic_expr
1455 // or t = expr ceildiv symbolic_expr, introduce a local variable q (= expr
1456 // floordiv/ceildiv symbolic_expr), and the affine floordiv/ceildiv is added to
1457 // `localExprs`.
1458 LogicalResult SimpleAffineExprFlattener::visitDivExpr(AffineBinaryOpExpr expr,
1459  bool isCeil) {
1460  assert(operandExprStack.size() >= 2);
1461 
1462  MLIRContext *context = expr.getContext();
1464  operandExprStack.pop_back();
1466 
1467  // Flatten semi affine division expressions by introducing a local
1468  // variable in place of the quotient, and the affine expression corresponding
1469  // to the quantifier is added to `localExprs`.
1470  if (!isa<AffineConstantExpr>(expr.getRHS())) {
1471  SmallVector<int64_t, 8> divLhs(lhs);
1473  localExprs, context);
1475  localExprs, context);
1476  AffineExpr divExpr = isCeil ? a.ceilDiv(b) : a.floorDiv(b);
1477  return addLocalVariableSemiAffine(divLhs, rhs, divExpr, lhs, lhs.size());
1478  }
1479 
1480  // This is a pure affine expr; the RHS is a positive constant.
1481  int64_t rhsConst = rhs[getConstantIndex()];
1482  if (rhsConst <= 0)
1483  return failure();
1484 
1485  // Simplify the floordiv, ceildiv if possible by canceling out the greatest
1486  // common divisors of the numerator and denominator.
1487  uint64_t gcd = std::abs(rhsConst);
1488  for (int64_t lhsElt : lhs)
1489  gcd = std::gcd(gcd, (uint64_t)std::abs(lhsElt));
1490  // Simplify the numerator and the denominator.
1491  if (gcd != 1) {
1492  for (int64_t &lhsElt : lhs)
1493  lhsElt = lhsElt / static_cast<int64_t>(gcd);
1494  }
1495  int64_t divisor = rhsConst / static_cast<int64_t>(gcd);
1496  // If the divisor becomes 1, the updated LHS is the result. (The
1497  // divisor can't be negative since rhsConst is positive).
1498  if (divisor == 1)
1499  return success();
1500 
1501  // If the divisor cannot be simplified to one, we will have to retain
1502  // the ceil/floor expr (simplified up until here). Add an existential
1503  // quantifier to express its result, i.e., expr1 div expr2 is replaced
1504  // by a new identifier, q.
1505  AffineExpr a =
1507  AffineExpr b = getAffineConstantExpr(divisor, context);
1508 
1509  int loc;
1510  AffineExpr divExpr = isCeil ? a.ceilDiv(b) : a.floorDiv(b);
1511  if ((loc = findLocalId(divExpr)) == -1) {
1512  if (!isCeil) {
1513  SmallVector<int64_t, 8> dividend(lhs);
1514  addLocalFloorDivId(dividend, divisor, divExpr);
1515  } else {
1516  // lhs ceildiv c <=> (lhs + c - 1) floordiv c
1517  SmallVector<int64_t, 8> dividend(lhs);
1518  dividend.back() += divisor - 1;
1519  addLocalFloorDivId(dividend, divisor, divExpr);
1520  }
1521  }
1522  // Set the expression on stack to the local var introduced to capture the
1523  // result of the division (floor or ceil).
1524  std::fill(lhs.begin(), lhs.end(), 0);
1525  if (loc == -1)
1526  lhs[getLocalVarStartIndex() + numLocals - 1] = 1;
1527  else
1528  lhs[getLocalVarStartIndex() + loc] = 1;
1529  return success();
1530 }
1531 
1532 // Add a local identifier (needed to flatten a mod, floordiv, ceildiv expr).
1533 // The local identifier added is always a floordiv of a pure add/mul affine
1534 // function of other identifiers, coefficients of which are specified in
1535 // dividend and with respect to a positive constant divisor. localExpr is the
1536 // simplified tree expression (AffineExpr) corresponding to the quantifier.
1538  int64_t divisor,
1539  AffineExpr localExpr) {
1540  assert(divisor > 0 && "positive constant divisor expected");
1541  for (SmallVector<int64_t, 8> &subExpr : operandExprStack)
1542  subExpr.insert(subExpr.begin() + getLocalVarStartIndex() + numLocals, 0);
1543  localExprs.push_back(localExpr);
1544  numLocals++;
1545  // dividend and divisor are not used here; an override of this method uses it.
1546 }
1547 
1549  ArrayRef<int64_t> lhs, ArrayRef<int64_t> rhs, AffineExpr localExpr) {
1550  for (SmallVector<int64_t, 8> &subExpr : operandExprStack)
1551  subExpr.insert(subExpr.begin() + getLocalVarStartIndex() + numLocals, 0);
1552  localExprs.push_back(localExpr);
1553  ++numLocals;
1554  // lhs and rhs are not used here; an override of this method uses them.
1555  return success();
1556 }
1557 
1558 int SimpleAffineExprFlattener::findLocalId(AffineExpr localExpr) {
1560  if ((it = llvm::find(localExprs, localExpr)) == localExprs.end())
1561  return -1;
1562  return it - localExprs.begin();
1563 }
1564 
1565 /// Simplify the affine expression by flattening it and reconstructing it.
1567  unsigned numSymbols) {
1568  // Simplify semi-affine expressions separately.
1569  if (!expr.isPureAffine())
1570  expr = simplifySemiAffine(expr, numDims, numSymbols);
1571 
1572  SimpleAffineExprFlattener flattener(numDims, numSymbols);
1573  // has poison expression
1574  if (failed(flattener.walkPostOrder(expr)))
1575  return expr;
1576  ArrayRef<int64_t> flattenedExpr = flattener.operandExprStack.back();
1577  if (!expr.isPureAffine() &&
1578  expr == getAffineExprFromFlatForm(flattenedExpr, numDims, numSymbols,
1579  flattener.localExprs,
1580  expr.getContext()))
1581  return expr;
1582  AffineExpr simplifiedExpr =
1583  expr.isPureAffine()
1584  ? getAffineExprFromFlatForm(flattenedExpr, numDims, numSymbols,
1585  flattener.localExprs, expr.getContext())
1586  : getSemiAffineExprFromFlatForm(flattenedExpr, numDims, numSymbols,
1587  flattener.localExprs,
1588  expr.getContext());
1589 
1590  flattener.operandExprStack.pop_back();
1591  assert(flattener.operandExprStack.empty());
1592  return simplifiedExpr;
1593 }
1594 
1595 std::optional<int64_t> mlir::getBoundForAffineExpr(
1596  AffineExpr expr, unsigned numDims, unsigned numSymbols,
1597  ArrayRef<std::optional<int64_t>> constLowerBounds,
1598  ArrayRef<std::optional<int64_t>> constUpperBounds, bool isUpper) {
1599  // Handle divs and mods.
1600  if (auto binOpExpr = dyn_cast<AffineBinaryOpExpr>(expr)) {
1601  // If the LHS of a floor or ceil is bounded and the RHS is a constant, we
1602  // can compute an upper bound.
1603  if (binOpExpr.getKind() == AffineExprKind::FloorDiv) {
1604  auto rhsConst = dyn_cast<AffineConstantExpr>(binOpExpr.getRHS());
1605  if (!rhsConst || rhsConst.getValue() < 1)
1606  return std::nullopt;
1607  auto bound =
1608  getBoundForAffineExpr(binOpExpr.getLHS(), numDims, numSymbols,
1609  constLowerBounds, constUpperBounds, isUpper);
1610  if (!bound)
1611  return std::nullopt;
1612  return divideFloorSigned(*bound, rhsConst.getValue());
1613  }
1614  if (binOpExpr.getKind() == AffineExprKind::CeilDiv) {
1615  auto rhsConst = dyn_cast<AffineConstantExpr>(binOpExpr.getRHS());
1616  if (rhsConst && rhsConst.getValue() >= 1) {
1617  auto bound =
1618  getBoundForAffineExpr(binOpExpr.getLHS(), numDims, numSymbols,
1619  constLowerBounds, constUpperBounds, isUpper);
1620  if (!bound)
1621  return std::nullopt;
1622  return divideCeilSigned(*bound, rhsConst.getValue());
1623  }
1624  return std::nullopt;
1625  }
1626  if (binOpExpr.getKind() == AffineExprKind::Mod) {
1627  // lhs mod c is always <= c - 1 and non-negative. In addition, if `lhs` is
1628  // bounded such that lb <= lhs <= ub and lb floordiv c == ub floordiv c
1629  // (same "interval"), then lb mod c <= lhs mod c <= ub mod c.
1630  auto rhsConst = dyn_cast<AffineConstantExpr>(binOpExpr.getRHS());
1631  if (rhsConst && rhsConst.getValue() >= 1) {
1632  int64_t rhsConstVal = rhsConst.getValue();
1633  auto lb = getBoundForAffineExpr(binOpExpr.getLHS(), numDims, numSymbols,
1634  constLowerBounds, constUpperBounds,
1635  /*isUpper=*/false);
1636  auto ub =
1637  getBoundForAffineExpr(binOpExpr.getLHS(), numDims, numSymbols,
1638  constLowerBounds, constUpperBounds, isUpper);
1639  if (ub && lb &&
1640  divideFloorSigned(*lb, rhsConstVal) ==
1641  divideFloorSigned(*ub, rhsConstVal))
1642  return isUpper ? mod(*ub, rhsConstVal) : mod(*lb, rhsConstVal);
1643  return isUpper ? rhsConstVal - 1 : 0;
1644  }
1645  }
1646  }
1647  // Flatten the expression.
1648  SimpleAffineExprFlattener flattener(numDims, numSymbols);
1649  auto simpleResult = flattener.walkPostOrder(expr);
1650  // has poison expression
1651  if (failed(simpleResult))
1652  return std::nullopt;
1653  ArrayRef<int64_t> flattenedExpr = flattener.operandExprStack.back();
1654  // TODO: Handle local variables. We can get hold of flattener.localExprs and
1655  // get bound on the local expr recursively.
1656  if (flattener.numLocals > 0)
1657  return std::nullopt;
1658  int64_t bound = 0;
1659  // Substitute the constant lower or upper bound for the dimensional or
1660  // symbolic input depending on `isUpper` to determine the bound.
1661  for (unsigned i = 0, e = numDims + numSymbols; i < e; ++i) {
1662  if (flattenedExpr[i] > 0) {
1663  auto &constBound = isUpper ? constUpperBounds[i] : constLowerBounds[i];
1664  if (!constBound)
1665  return std::nullopt;
1666  bound += *constBound * flattenedExpr[i];
1667  } else if (flattenedExpr[i] < 0) {
1668  auto &constBound = isUpper ? constLowerBounds[i] : constUpperBounds[i];
1669  if (!constBound)
1670  return std::nullopt;
1671  bound += *constBound * flattenedExpr[i];
1672  }
1673  }
1674  // Constant term.
1675  bound += flattenedExpr.back();
1676  return bound;
1677 }
static int64_t product(ArrayRef< int64_t > vals)
static AffineExpr symbolicDivide(AffineExpr expr, unsigned symbolPos, AffineExprKind opKind)
Divides the given expression by the given symbol at position symbolPos.
Definition: AffineExpr.cpp:427
static AffineExpr simplifyMul(AffineExpr lhs, AffineExpr rhs)
Simplify a multiply expression. Return nullptr if it can't be simplified.
Definition: AffineExpr.cpp:796
static AffineExpr simplifyMod(AffineExpr lhs, AffineExpr rhs)
Definition: AffineExpr.cpp:977
static AffineExpr simplifyAdd(AffineExpr lhs, AffineExpr rhs)
Simplify add expression. Return nullptr if it can't be simplified.
Definition: AffineExpr.cpp:659
static AffineExpr getSemiAffineExprFromFlatForm(ArrayRef< int64_t > flatExprs, unsigned numDims, unsigned numSymbols, ArrayRef< AffineExpr > localExprs, MLIRContext *context)
Constructs a semi-affine expression from a flat ArrayRef.
static bool canSimplifyDivisionBySymbol(AffineExpr expr, unsigned symbolPos, AffineExprKind opKind, bool fromMul=false)
Returns true if the expression is divisible by the given symbol with position symbolPos.
Definition: AffineExpr.cpp:359
static AffineExpr simplifyCeilDiv(AffineExpr lhs, AffineExpr rhs)
Definition: AffineExpr.cpp:930
static AffineExpr simplifyFloorDiv(AffineExpr lhs, AffineExpr rhs)
Definition: AffineExpr.cpp:871
static bool isNegatedAffineExpr(AffineExpr candidate, AffineExpr &expr)
Return "true" if candidate is a negated expression, i.e., Mul(-1, expr).
Definition: AffineExpr.cpp:495
static AffineExpr getAffineDimOrSymbol(AffineExprKind kind, unsigned position, MLIRContext *context)
Definition: AffineExpr.cpp:606
static bool isModOfModSubtraction(AffineExpr lhs, AffineExpr rhs, unsigned numDims, unsigned numSymbols)
Return "true" if lhs % rhs is guaranteed to evaluate to zero based on the fact that lhs contains anot...
Definition: AffineExpr.cpp:522
static void getSummandExprs(AffineExpr expr, SmallVector< AffineExpr > &result)
Populate result with all summand operands of given (potentially nested) addition.
Definition: AffineExpr.cpp:483
static AffineExpr simplifySemiAffine(AffineExpr expr, unsigned numDims, unsigned numSymbols)
Simplify a semi-affine expression by handling modulo, floordiv, or ceildiv operations when the second...
Definition: AffineExpr.cpp:560
static MLIRContext * getContext(OpFoldResult val)
static Value max(ImplicitLocOpBuilder &builder, Value value, Value bound)
Affine binary operation expression.
Definition: AffineExpr.h:227
AffineExpr getLHS() const
Definition: AffineExpr.cpp:340
AffineBinaryOpExpr(AffineExpr::ImplType *ptr)
Definition: AffineExpr.cpp:338
AffineExpr getRHS() const
Definition: AffineExpr.cpp:343
An integer constant appearing in affine expression.
Definition: AffineExpr.h:252
AffineConstantExpr(AffineExpr::ImplType *ptr=nullptr)
Definition: AffineExpr.cpp:631
int64_t getValue() const
Definition: AffineExpr.cpp:633
A dimensional identifier appearing in an affine expression.
Definition: AffineExpr.h:236
AffineDimExpr(AffineExpr::ImplType *ptr)
Definition: AffineExpr.cpp:347
unsigned getPosition() const
Definition: AffineExpr.cpp:348
See documentation for AffineExprVisitorBase.
RetTy walkPostOrder(AffineExpr expr)
Base type for affine expression.
Definition: AffineExpr.h:68
AffineExpr replaceDimsAndSymbols(ArrayRef< AffineExpr > dimReplacements, ArrayRef< AffineExpr > symReplacements) const
This method substitutes any uses of dimensions and symbols (e.g.
Definition: AffineExpr.cpp:89
AffineExpr shiftDims(unsigned numDims, unsigned shift, unsigned offset=0) const
Replace dims[offset ...
Definition: AffineExpr.cpp:133
AffineExpr operator+(int64_t v) const
Definition: AffineExpr.cpp:783
bool isSymbolicOrConstant() const
Returns true if this expression is made out of only symbols and constants, i.e., it does not involve ...
Definition: AffineExpr.cpp:188
AffineExpr operator*(int64_t v) const
Definition: AffineExpr.cpp:848
bool operator==(AffineExpr other) const
Definition: AffineExpr.h:76
bool isPureAffine() const
Returns true if this is a pure affine expression, i.e., multiplication, floordiv, ceildiv,...
Definition: AffineExpr.cpp:212
AffineExpr shiftSymbols(unsigned numSymbols, unsigned shift, unsigned offset=0) const
Replace symbols[offset ...
Definition: AffineExpr.cpp:145
AffineExpr operator-() const
Definition: AffineExpr.cpp:861
AffineExpr floorDiv(uint64_t v) const
Definition: AffineExpr.cpp:917
ImplType * expr
Definition: AffineExpr.h:209
RetT walk(FnT &&callback) const
Walk all of the AffineExpr's in this expression in postorder.
Definition: AffineExpr.h:130
AffineExprKind getKind() const
Return the classification for this type.
Definition: AffineExpr.cpp:35
bool isMultipleOf(int64_t factor) const
Return true if the affine expression is a multiple of 'factor'.
Definition: AffineExpr.cpp:283
int64_t getLargestKnownDivisor() const
Returns the greatest known integral divisor of this affine expression.
Definition: AffineExpr.cpp:243
AffineExpr compose(AffineMap map) const
Compose with an AffineMap.
bool isFunctionOfDim(unsigned position) const
Return true if the affine expression involves AffineDimExpr position.
Definition: AffineExpr.cpp:316
bool isFunctionOfSymbol(unsigned position) const
Return true if the affine expression involves AffineSymbolExpr position.
Definition: AffineExpr.cpp:327
AffineExpr replaceDims(ArrayRef< AffineExpr > dimReplacements) const
Dim-only version of replaceDimsAndSymbols.
Definition: AffineExpr.cpp:122
AffineExpr operator%(uint64_t v) const
MLIRContext * getContext() const
Definition: AffineExpr.cpp:33
AffineExpr replace(AffineExpr expr, AffineExpr replacement) const
Sparse replace method.
Definition: AffineExpr.cpp:181
AffineExpr replaceSymbols(ArrayRef< AffineExpr > symReplacements) const
Symbol-only version of replaceDimsAndSymbols.
Definition: AffineExpr.cpp:127
AffineExpr ceilDiv(uint64_t v) const
Definition: AffineExpr.cpp:964
void print(raw_ostream &os) const
A multi-dimensional affine map Affine map's are immutable like Type's, and they are uniqued.
Definition: AffineMap.h:46
ArrayRef< AffineExpr > getResults() const
Definition: AffineMap.cpp:407
A symbolic identifier appearing in an affine expression.
Definition: AffineExpr.h:244
AffineSymbolExpr(AffineExpr::ImplType *ptr)
Definition: AffineExpr.cpp:621
unsigned getPosition() const
Definition: AffineExpr.cpp:623
MLIRContext is the top-level object for a collection of MLIR operations.
Definition: MLIRContext.h:60
StorageUniquer & getAffineUniquer()
Returns the storage uniquer used for creating affine constructs.
virtual void addLocalFloorDivId(ArrayRef< int64_t > dividend, int64_t divisor, AffineExpr localExpr)
LogicalResult visitSymbolExpr(AffineSymbolExpr expr)
std::vector< SmallVector< int64_t, 8 > > operandExprStack
LogicalResult visitDimExpr(AffineDimExpr expr)
LogicalResult visitFloorDivExpr(AffineBinaryOpExpr expr)
LogicalResult visitConstantExpr(AffineConstantExpr expr)
virtual LogicalResult addLocalIdSemiAffine(ArrayRef< int64_t > lhs, ArrayRef< int64_t > rhs, AffineExpr localExpr)
Add a local identifier (needed to flatten a mod, floordiv, ceildiv, mul expr) when the rhs is a symbo...
LogicalResult visitModExpr(AffineBinaryOpExpr expr)
LogicalResult visitAddExpr(AffineBinaryOpExpr expr)
LogicalResult visitCeilDivExpr(AffineBinaryOpExpr expr)
LogicalResult visitMulExpr(AffineBinaryOpExpr expr)
SmallVector< AffineExpr, 4 > localExprs
SimpleAffineExprFlattener(unsigned numDims, unsigned numSymbols)
A utility class to get or create instances of "storage classes".
Storage * get(function_ref< void(Storage *)> initFn, TypeID id, Args &&...args)
Gets a uniqued instance of 'Storage'.
A utility result that is used to signal how to proceed with an ongoing walk:
Definition: Visitors.h:33
AttrTypeReplacer.
constexpr void enumerate(std::tuple< Tys... > &tuple, CallbackT &&callback)
Definition: Matchers.h:344
Fraction abs(const Fraction &f)
Definition: Fraction.h:107
Include the generated interface declarations.
std::optional< int64_t > getBoundForAffineExpr(AffineExpr expr, unsigned numDims, unsigned numSymbols, ArrayRef< std::optional< int64_t >> constLowerBounds, ArrayRef< std::optional< int64_t >> constUpperBounds, bool isUpper)
Get a lower or upper (depending on isUpper) bound for expr while using the constant lower and upper b...
AffineExprKind
Definition: AffineExpr.h:40
@ CeilDiv
RHS of ceildiv is always a constant or a symbolic expression.
@ Mul
RHS of mul is always a constant or a symbolic expression.
@ Mod
RHS of mod is always a constant or a symbolic expression with a positive value.
@ DimId
Dimensional identifier.
@ FloorDiv
RHS of floordiv is always a constant or a symbolic expression.
@ Constant
Constant integer.
@ SymbolId
Symbolic identifier.
AffineExpr getAffineBinaryOpExpr(AffineExprKind kind, AffineExpr lhs, AffineExpr rhs)
Definition: AffineExpr.cpp:70
AffineExpr getAffineExprFromFlatForm(ArrayRef< int64_t > flatExprs, unsigned numDims, unsigned numSymbols, ArrayRef< AffineExpr > localExprs, MLIRContext *context)
Constructs an affine expression from a flat ArrayRef.
AffineExpr getAffineConstantExpr(int64_t constant, MLIRContext *context)
Definition: AffineExpr.cpp:641
AffineExpr simplifyAffineExpr(AffineExpr expr, unsigned numDims, unsigned numSymbols)
Simplify an affine expression by flattening and some amount of simple analysis.
SmallVector< AffineExpr > getAffineConstantExprs(ArrayRef< int64_t > constants, MLIRContext *context)
Definition: AffineExpr.cpp:651
AffineExpr getAffineDimExpr(unsigned position, MLIRContext *context)
These free functions allow clients of the API to not use classes in detail.
Definition: AffineExpr.cpp:617
AffineExpr getAffineSymbolExpr(unsigned position, MLIRContext *context)
Definition: AffineExpr.cpp:627
raw_ostream & operator<<(raw_ostream &os, const AliasResult &result)
Definition: AliasAnalysis.h:78
A binary operation appearing in an affine expression.
An integer constant appearing in affine expression.
A dimensional or symbolic identifier appearing in an affine expression.
Base storage class appearing in an affine expression.
Eliminates variable at the specified position using Fourier-Motzkin variable elimination.