[Mlir-commits] [mlir] [MLIR][Presburger] Implement function to evaluate the number of terms in a generating function. (PR #78078)

Arjun P llvmlistbot at llvm.org
Sun Jan 14 09:28:05 PST 2024


================
@@ -245,3 +245,200 @@ QuasiPolynomial mlir::presburger::detail::getCoefficientInRationalFunction(
   }
   return coefficients[power].simplify();
 }
+
+// We have a generating function of the form
+// f_p(x) = \sum_i sign_i * (x^n_i(p)) / (\prod_j (1 - x^d_{ij})
+//
+// where sign_i is ±1,
+// n_i \in Q^p -> Q^d is a d-vector of affine functions on p parameters, and
+// d_{ij} \in Q^d are vectors.
+//
+// We need to find the number of terms of the form x^t in the expansion of
+// this function, for which we substitute x = (1, ..., 1).
+// However, direct substitution leads to an undefined answer due to the
+// form of the denominator.
+//
+// We therefore use the following procedure instead:
+// Find a vector μ that is not orthogonal to any of the d_{ij}.
+// Substitute x_i = (s+1)^μ_i. As μ_i is not orthogonal to d_{ij},
+// we never have (1 - (s+1)^0) = 0 in any of the terms in denominator.
+// We then find the constant term in this function, i.e., we evaluate it
+// at s = 0, which is equivalent to x = (1, ..., 1).
+//
+// Now, we have a function of the form
+// f_p(s) = \sum_i sign_i * (s+1)^n_i / (\prod_j (1 - (s+1)^d'_{ij}))
+// in which we need to find the constant term.
+// For the i'th term, we first convert all the d'_{ij} to their
+// absolute values by multiplying and dividing by (s+1)^(-d'_{ij}) if it is
+// negative. We change the sign accordingly.
+// Then, we replace each (1 - (s+1)^(d'_{ij})) with
+// (-s)(\sum_{0 ≤ k < d'_{ij}} (s+1)^k).
+// Thus the term overall has now the form
+// sign'_i * (s+1)^n'_i / (s^r * \prod_j (\sum_k (s+1)^k)).
+// This means that
+// the numerator is a polynomial in s, with coefficients as quasipolynomials,
+// and the denominator is polynomial in s, with fractional coefficients.
+// We need to find the constant term in the expansion of this term,
+// which is the same as finding the coefficient of s^r in
+// sign'_i * (s+1)^n'_i / (\prod_j (\sum_k (s+1)^k)),
+// for which we use the `getCoefficientInRationalFunction()` function.
+//
+// Verdoolaege, Sven, et al. "Counting integer points in parametric polytopes
+// using Barvinok's rational functions." Algorithmica 48 (2007): 37-66.
+QuasiPolynomial
+mlir::presburger::detail::substituteWithUnitVector(GeneratingFunction gf) {
+  std::vector<Point> allDenominators;
+  for (ArrayRef<Point> den : gf.getDenominators())
+    allDenominators.insert(allDenominators.end(), den.begin(), den.end());
+  Point mu = getNonOrthogonalVector(allDenominators);
+
+  unsigned numParams = gf.getNumParams();
+  unsigned numDims = mu.size();
+  unsigned numTerms = gf.getDenominators().size();
+
+  QuasiPolynomial totalTerm(numParams, 0);
+  for (unsigned i = 0; i < numTerms; ++i) {
+    int sign = gf.getSigns()[i];
+    ParamPoint v = gf.getNumerators()[i];
+    std::vector<Point> ds = gf.getDenominators()[i];
----------------
Superty wrote:

Are these copies actually needed or can they be const refs

https://github.com/llvm/llvm-project/pull/78078


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