[mlir][Analysis][NFC] Remove code duplication around getFlattenedAffineExprs

Remove code duplication in `addLowerOrUpperBound` and `composeMatchingMap`. Differential Revision: https://reviews.llvm.org/D107814
2021-08-11 15:59:43 +09:00 · 2021-08-11 15:59:43 +09:00 · 4b56e2ee1d
parent 9e6e08149c
commit 4b56e2ee1d
2 changed files with 44 additions and 42 deletions
--- a/mlir/include/mlir/Analysis/AffineStructures.h
+++ b/mlir/include/mlir/Analysis/AffineStructures.h
@ -602,6 +602,19 @@ private:
  /// must already have a corresponding dim/symbol in this constraint system.
  AffineMap computeAlignedMap(AffineMap map, ValueRange operands) const;

+  /// Given an affine map that is aligned with this constraint system:
+  /// * Flatten the map.
+  /// * Add newly introduced local columns at the beginning of this constraint
+  ///   system (local column pos 0).
+  /// * Add equalities that define the new local columns to this constraint
+  ///   system.
+  /// * Return the flattened expressions via `flattenedExprs`.
+  ///
+  /// Note: This is a shared helper function of `addLowerOrUpperBound` and
+  ///       `composeMatchingMap`.
+  LogicalResult flattenAlignedMapAndMergeLocals(
+      AffineMap map, std::vector<SmallVector<int64_t, 8>> *flattenedExprs);
+
  // Eliminates a single identifier at 'position' from equality and inequality
  // constraints. Returns 'success' if the identifier was eliminated, and
  // 'failure' otherwise.
--- a/mlir/lib/Analysis/AffineStructures.cpp
+++ b/mlir/lib/Analysis/AffineStructures.cpp
@ -400,28 +400,10 @@ LogicalResult FlatAffineConstraints::composeMatchingMap(AffineMap other) {
  assert(other.getNumSymbols() == getNumSymbolIds() && "symbol mismatch");

  std::vector<SmallVector<int64_t, 8>> flatExprs;
-  FlatAffineConstraints localCst;
-  if (failed(getFlattenedAffineExprs(other, &flatExprs, &localCst))) {
-    LLVM_DEBUG(llvm::dbgs()
-               << "composition unimplemented for semi-affine maps\n");
+  if (failed(flattenAlignedMapAndMergeLocals(other, &flatExprs)))
    return failure();
-  }
  assert(flatExprs.size() == other.getNumResults());

-  // Add localCst information.
-  if (localCst.getNumLocalIds() > 0) {
-    unsigned numLocalIds = getNumLocalIds();
-    // Insert local dims of localCst at the beginning.
-    for (unsigned l = 0, e = localCst.getNumLocalIds(); l < e; ++l)
-      addLocalId(0);
-    // Insert local dims of `this` at the end of localCst.
-    for (unsigned l = 0; l < numLocalIds; ++l)
-      localCst.addLocalId(localCst.getNumLocalIds());
-    // Dimensions of localCst and this constraint set match. Append localCst to
-    // this constraint set.
-    append(localCst);
-  }
-
  // Add dimensions corresponding to the map's results.
  for (unsigned t = 0, e = other.getNumResults(); t < e; t++) {
    addDimId(0);
@ -429,25 +411,24 @@ LogicalResult FlatAffineConstraints::composeMatchingMap(AffineMap other) {

  // We add one equality for each result connecting the result dim of the map to
  // the other identifiers.
-  // For eg: if the expression is 16*i0 + i1, and this is the r^th
+  // E.g.: if the expression is 16*i0 + i1, and this is the r^th
  // iteration/result of the value map, we are adding the equality:
-  //  d_r - 16*i0 - i1 = 0. Hence, when flattening say (i0 + 1, i0 + 8*i2), we
-  //  add two equalities overall: d_0 - i0 - 1 == 0, d1 - i0 - 8*i2 == 0.
+  // d_r - 16*i0 - i1 = 0. Similarly, when flattening (i0 + 1, i0 + 8*i2), we
+  // add two equalities: d_0 - i0 - 1 == 0, d1 - i0 - 8*i2 == 0.
  for (unsigned r = 0, e = flatExprs.size(); r < e; r++) {
    const auto &flatExpr = flatExprs[r];
    assert(flatExpr.size() >= other.getNumInputs() + 1);

-    // eqToAdd is the equality corresponding to the flattened affine expression.
    SmallVector<int64_t, 8> eqToAdd(getNumCols(), 0);
    // Set the coefficient for this result to one.
    eqToAdd[r] = 1;

    // Dims and symbols.
    for (unsigned i = 0, f = other.getNumInputs(); i < f; i++) {
-      // Negate 'eq[r]' since the newly added dimension will be set to this one.
+      // Negate `eq[r]` since the newly added dimension will be set to this one.
      eqToAdd[e + i] = -flatExpr[i];
    }
-    // Local vars common to eq and localCst are at the beginning.
+    // Local columns of `eq` are at the beginning.
    unsigned j = getNumDimIds() + getNumSymbolIds();
    unsigned end = flatExpr.size() - 1;
    for (unsigned i = other.getNumInputs(); i < end; i++, j++) {
@ -1872,27 +1853,14 @@ void FlatAffineConstraints::getSliceBounds(unsigned offset, unsigned num,
  }
 }

-LogicalResult FlatAffineConstraints::addLowerOrUpperBound(unsigned pos,
-                                                          AffineMap boundMap,
-                                                          bool eq, bool lower) {
-  assert(boundMap.getNumDims() == getNumDimIds() && "dim mismatch");
-  assert(boundMap.getNumSymbols() == getNumSymbolIds() && "symbol mismatch");
-  assert(pos < getNumDimAndSymbolIds() && "invalid position");
-
-  // Equality follows the logic of lower bound except that we add an equality
-  // instead of an inequality.
-  assert((!eq || boundMap.getNumResults() == 1) && "single result expected");
-  if (eq)
-    lower = true;
-
-  std::vector<SmallVector<int64_t, 8>> flatExprs;
+LogicalResult FlatAffineConstraints::flattenAlignedMapAndMergeLocals(
+    AffineMap map, std::vector<SmallVector<int64_t, 8>> *flattenedExprs) {
  FlatAffineConstraints localCst;
-  if (failed(getFlattenedAffineExprs(boundMap, &flatExprs, &localCst))) {
+  if (failed(getFlattenedAffineExprs(map, flattenedExprs, &localCst))) {
    LLVM_DEBUG(llvm::dbgs()
               << "composition unimplemented for semi-affine maps\n");
    return failure();
  }
-  assert(flatExprs.size() == boundMap.getNumResults());

  // Add localCst information.
  if (localCst.getNumLocalIds() > 0) {
@ -1908,6 +1876,27 @@ LogicalResult FlatAffineConstraints::addLowerOrUpperBound(unsigned pos,
    append(localCst);
  }

+  return success();
+}
+
+LogicalResult FlatAffineConstraints::addLowerOrUpperBound(unsigned pos,
+                                                          AffineMap boundMap,
+                                                          bool eq, bool lower) {
+  assert(boundMap.getNumDims() == getNumDimIds() && "dim mismatch");
+  assert(boundMap.getNumSymbols() == getNumSymbolIds() && "symbol mismatch");
+  assert(pos < getNumDimAndSymbolIds() && "invalid position");
+
+  // Equality follows the logic of lower bound except that we add an equality
+  // instead of an inequality.
+  assert((!eq || boundMap.getNumResults() == 1) && "single result expected");
+  if (eq)
+    lower = true;
+
+  std::vector<SmallVector<int64_t, 8>> flatExprs;
+  if (failed(flattenAlignedMapAndMergeLocals(boundMap, &flatExprs)))
+    return failure();
+  assert(flatExprs.size() == boundMap.getNumResults());
+
  // Add one (in)equality for each result.
  for (const auto &flatExpr : flatExprs) {
    SmallVector<int64_t> ineq(getNumCols(), 0);
@ -1921,7 +1910,7 @@ LogicalResult FlatAffineConstraints::addLowerOrUpperBound(unsigned pos,
    if (ineq[pos] != 0)
      continue;
    ineq[pos] = lower ? 1 : -1;
-    // Local vars common to eq and localCst are at the beginning.
+    // Local columns of `ineq` are at the beginning.
    unsigned j = getNumDimIds() + getNumSymbolIds();
    unsigned end = flatExpr.size() - 1;
    for (unsigned i = boundMap.getNumInputs(); i < end; i++, j++) {