caio/clang-p2996
1
0
Fork 0
Code Issues Pull Requests Actions Packages Projects Releases Wiki Activity
Files
05b02bb98e2ea1b3d433e2b5721dadfc3554936d
clang-p2996/mlir/lib/TableGen/Predicate.cpp
Alex Zinenko 05b02bb98e TableGen: implement predicate tree and basic simplification 
A recent change in TableGen definitions allowed arbitrary AND/OR predicate
compositions at the cost of removing known-true predicate simplification.
Introduce a more advanced simplification mechanism instead.

In particular, instead of folding predicate C++ expressions directly in
TableGen, keep them as is and build a predicate tree in TableGen C++ library.
The predicate expression-substitution mechanism, necessary to implement complex
predicates for nested classes such as `ContainerType`, is replaced by a
dedicated predicate.  This predicate appears in the predicate tree and can be
used for tree matching and separation.  More specifically, subtrees defined
below such predicate may be subject to different transformations than those
that appear above.  For example, a subtree known to be true above the
substitution predicate is not necessarily true below it.

Use the predicate tree structure to eliminate known-true and known-false
predicates before code emission, as well as to collapse AND and OR predicates
if their value can be deduced based on the value of one child.

PiperOrigin-RevId: 229605997
2019-03-29 15:22:58 -07:00

347 lines
13 KiB
C++
Raw Blame History

//===- Predicate.cpp - Predicate class ------------------------------------===//
//
// Copyright 2019 The MLIR Authors.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
// =============================================================================
//
// Wrapper around predicates defined in TableGen.
//
//===----------------------------------------------------------------------===//
#include "mlir/TableGen/Predicate.h"
#include "llvm/ADT/SetVector.h"
#include "llvm/ADT/SmallPtrSet.h"
#include "llvm/ADT/StringExtras.h"
#include "llvm/Support/FormatVariadic.h"
#include "llvm/TableGen/Error.h"
#include "llvm/TableGen/Record.h"
using namespace mlir;
// Construct a Predicate from a record.
tblgen::Pred::Pred(const llvm::Record *record) : def(record) {
assert(def->isSubClassOf("Pred") &&
"must be a subclass of TableGen 'Pred' class");
}
// Construct a Predicate from an initializer.
tblgen::Pred::Pred(const llvm::Init *init) : def(nullptr) {
if (const auto *defInit = dyn_cast_or_null<llvm::DefInit>(init))
def = defInit->getDef();
}
std::string tblgen::Pred::getCondition() const {
// Static dispatch to subclasses.
if (def->isSubClassOf("CombinedPred"))
return static_cast<const CombinedPred *>(this)->getConditionImpl();
if (def->isSubClassOf("CPred"))
return static_cast<const CPred *>(this)->getConditionImpl();
llvm_unreachable("Pred::getCondition must be overridden in subclasses");
}
bool tblgen::Pred::isCombined() const {
return def && def->isSubClassOf("CombinedPred");
}
ArrayRef<llvm::SMLoc> tblgen::Pred::getLoc() const { return def->getLoc(); }
tblgen::CPred::CPred(const llvm::Record *record) : Pred(record) {
assert(def->isSubClassOf("CPred") &&
"must be a subclass of Tablegen 'CPred' class");
}
tblgen::CPred::CPred(const llvm::Init *init) : Pred(init) {
assert((!def || def->isSubClassOf("CPred")) &&
"must be a subclass of Tablegen 'CPred' class");
}
// Get condition of the C Predicate.
std::string tblgen::CPred::getConditionImpl() const {
assert(!isNull() && "null predicate does not have a condition");
return def->getValueAsString("predCall");
}
tblgen::CombinedPred::CombinedPred(const llvm::Record *record) : Pred(record) {
assert(def->isSubClassOf("CombinedPred") &&
"must be a subclass of Tablegen 'CombinedPred' class");
}
tblgen::CombinedPred::CombinedPred(const llvm::Init *init) : Pred(init) {
assert((!def || def->isSubClassOf("CombinedPred")) &&
"must be a subclass of Tablegen 'CombinedPred' class");
}
const llvm::Record *tblgen::CombinedPred::getCombinerDef() const {
assert(def->getValue("kind") && "CombinedPred must have a value 'kind'");
return def->getValueAsDef("kind");
}
const std::vector<llvm::Record *> tblgen::CombinedPred::getChildren() const {
assert(def->getValue("children") &&
"CombinedPred must have a value 'children'");
return def->getValueAsListOfDefs("children");
}
namespace {
// Kinds of nodes in a logical predicate tree.
enum class PredCombinerKind {
Leaf,
And,
Or,
Not,
SubstLeaves,
// Special kinds that are used in simplification.
False,
True
};
// A node in a logical predicate tree.
struct PredNode {
PredCombinerKind kind;
const tblgen::Pred *predicate;
SmallVector<PredNode *, 4> children;
std::string expr;
};
} // end anonymous namespace
// Get a predicate tree node kind based on the kind used in the predicate
// TableGen record.
static PredCombinerKind getPredCombinerKind(const tblgen::Pred &pred) {
if (!pred.isCombined())
return PredCombinerKind::Leaf;
const auto &combinedPred = static_cast<const tblgen::CombinedPred &>(pred);
return llvm::StringSwitch<PredCombinerKind>(
combinedPred.getCombinerDef()->getName())
.Case("PredCombinerAnd", PredCombinerKind::And)
.Case("PredCombinerOr", PredCombinerKind::Or)
.Case("PredCombinerNot", PredCombinerKind::Not)
.Case("PredCombinerSubstLeaves", PredCombinerKind::SubstLeaves);
}
namespace {
// Substitution<pattern, replacement>.
using Subst = std::pair<StringRef, StringRef>;
} // end anonymous namespace
// Build the predicate tree starting from the top-level predicate, which may
// have children, and perform leaf substitutions inplace. Note that after
// substitution, nodes are still pointing to the original TableGen record.
// All nodes are created within "allocator".
static PredNode *buildPredicateTree(const tblgen::Pred &root,
llvm::BumpPtrAllocator &allocator,
ArrayRef<Subst> substitutions) {
auto *rootNode = allocator.Allocate<PredNode>();
new (rootNode) PredNode;
rootNode->kind = getPredCombinerKind(root);
rootNode->predicate = &root;
if (!root.isCombined()) {
rootNode->expr = root.getCondition();
// Apply all parent substitutions from innermost to outermost.
for (const auto &subst : llvm::reverse(substitutions)) {
size_t start = 0;
while (auto pos =
rootNode->expr.find(subst.first, start) != std::string::npos) {
rootNode->expr.replace(pos, subst.first.size(), subst.second);
start = pos + subst.second.size();
}
}
return rootNode;
}
// If the current combined predicate is a leaf substitution, append it to the
// list before contiuing.
auto allSubstitutions = llvm::to_vector<4>(substitutions);
if (rootNode->kind == PredCombinerKind::SubstLeaves) {
const auto &substPred = static_cast<const tblgen::SubstLeavesPred &>(root);
allSubstitutions.push_back(
{substPred.getPattern(), substPred.getReplacement()});
}
// Build child subtrees.
auto combined = static_cast<const tblgen::CombinedPred &>(root);
for (const auto *record : combined.getChildren()) {
auto childTree =
buildPredicateTree(tblgen::Pred(record), allocator, allSubstitutions);
rootNode->children.push_back(childTree);
}
return rootNode;
}
// Simplify a predicate tree rooted at "node" using the predicates that are
// known to be true(false). For AND(OR) combined predicates, if any of the
// children is known to be false(true), the result is also false(true).
// Furthermore, for AND(OR) combined predicates, children that are known to be
// true(false) don't have to be checked dynamically.
static PredNode *propagateGroundTruth(
PredNode *node, const llvm::SmallPtrSetImpl<tblgen::Pred *> &knownTruePreds,
const llvm::SmallPtrSetImpl<tblgen::Pred *> &knownFalsePreds) {
// If the current predicate is known to be true or false, change the kind of
// the node and return immediately.
if (knownTruePreds.count(node->predicate) != 0) {
node->kind = PredCombinerKind::True;
node->children.clear();
return node;
}
if (knownFalsePreds.count(node->predicate) != 0) {
node->kind = PredCombinerKind::False;
node->children.clear();
return node;
}
// If the current node is a substitution, stop recursion now.
// The expressions in the leaves below this node were rewritten, but the nodes
// still point to the original predicate records. While the original
// predicate may be known to be true or false, it is not necessarily the case
// after rewriting.
// TODO(zinenko,jpienaar): we can support ground truth for rewritten
// predicates by either (a) having our own unique'ing of the predicates
// instead of relying on TableGen record pointers or (b) taking ground truth
// values optinally prefixed with a list of substitutions to apply, e.g.
// "predX is true by itself as well as predSubY leaf substitution had been
// applied to it".
if (node->kind == PredCombinerKind::SubstLeaves) {
return node;
}
// Otherwise, look at child nodes.
// Move child nodes into some local variable so that they can be optimized
// separately and re-added if necessary.
llvm::SmallVector<PredNode *, 4> children;
std::swap(node->children, children);
for (auto &child : children) {
// First, simplify the child. This maintains the predicate as it was.
auto simplifiedChild =
propagateGroundTruth(child, knownTruePreds, knownFalsePreds);
// Just add the child if we don't know how to simplify the current node.
if (node->kind != PredCombinerKind::And &&
node->kind != PredCombinerKind::Or) {
node->children.push_back(simplifiedChild);
continue;
}
// Second, based on the type define which known values of child predicates
// immediately collapse this predicate to a known value, and which others
// may be safely ignored.
// OR(..., True, ...) = True
// OR(..., False, ...) = OR(..., ...)
// AND(..., False, ...) = False
// AND(..., True, ...) = AND(..., ...)
auto collapseKind = node->kind == PredCombinerKind::And
? PredCombinerKind::False
: PredCombinerKind::True;
auto eraseKind = node->kind == PredCombinerKind::And
? PredCombinerKind::True
: PredCombinerKind::False;
const auto &collapseList =
node->kind == PredCombinerKind::And ? knownFalsePreds : knownTruePreds;
const auto &eraseList =
node->kind == PredCombinerKind::And ? knownTruePreds : knownFalsePreds;
if (simplifiedChild->kind == collapseKind ||
collapseList.count(simplifiedChild->predicate) != 0) {
node->kind = collapseKind;
node->children.clear();
return node;
} else if (simplifiedChild->kind == eraseKind ||
eraseList.count(simplifiedChild->predicate) != 0) {
continue;
}
node->children.push_back(simplifiedChild);
}
return node;
}
// Combine a list of predicate expressions using a binary combiner. If a list
// is empty, return "init".
static std::string combineBinary(ArrayRef<std::string> children,
std::string combiner, std::string init) {
if (children.empty())
return init;
auto size = children.size();
if (size == 1)
return children.front();
std::string str;
llvm::raw_string_ostream os(str);
os << '(' << children.front() << ')';
for (unsigned i = 1; i < size; ++i) {
os << ' ' << combiner << " (" << children[i] << ')';
}
return os.str();
}
// Prepend negation to the only condition in the predicate expression list.
static std::string combineNot(ArrayRef<std::string> children) {
assert(children.size() == 1 && "expected exactly one child predicate of Neg");
return (Twine("!(") + children.front() + Twine(')')).str();
}
// Recursively traverse the predicate tree in depth-first post-order and build
// the final expression.
static std::string getCombinedCondition(const PredNode &root) {
// Immediately return for non-combiner predicates that don't have children.
if (root.kind == PredCombinerKind::Leaf)
return root.expr;
if (root.kind == PredCombinerKind::True)
return "true";
if (root.kind == PredCombinerKind::False)
return "false";
// Recurse into children.
llvm::SmallVector<std::string, 4> childExpressions;
childExpressions.reserve(root.children.size());
for (const auto &child : root.children)
childExpressions.push_back(getCombinedCondition(*child));
// Combine the expressions based on the predicate node kind.
if (root.kind == PredCombinerKind::And)
return combineBinary(childExpressions, "&&", "true");
if (root.kind == PredCombinerKind::Or)
return combineBinary(childExpressions, "||", "false");
if (root.kind == PredCombinerKind::Not)
return combineNot(childExpressions);
// Substitutions were applied before so just ignore them.
if (root.kind == PredCombinerKind::SubstLeaves) {
assert(childExpressions.size() == 1 &&
"substitution predicate must have one child");
return childExpressions[0];
}
llvm::PrintFatalError(root.predicate->getLoc(), "unsupported predicate kind");
}
std::string tblgen::CombinedPred::getConditionImpl() const {
llvm::BumpPtrAllocator allocator;
auto predicateTree = buildPredicateTree(*this, allocator, {});
predicateTree = propagateGroundTruth(
predicateTree,
/*knownTruePreds=*/llvm::SmallPtrSet<tblgen::Pred *, 2>(),
/*knownFalsePreds=*/llvm::SmallPtrSet<tblgen::Pred *, 2>());
return getCombinedCondition(*predicateTree);
}
StringRef tblgen::SubstLeavesPred::getPattern() const {
return def->getValueAsString("pattern");
}
StringRef tblgen::SubstLeavesPred::getReplacement() const {
return def->getValueAsString("replacement");
}
Reference in New Issue View Git Blame Copy Permalink