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Differential Revision: https://reviews.llvm.org/D91483
378 lines
16 KiB
TableGen
378 lines
16 KiB
TableGen
//===- TargetInstrPredicate.td - ---------------------------*- tablegen -*-===//
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//
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// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
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// See https://llvm.org/LICENSE.txt for license information.
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// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
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//
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//===----------------------------------------------------------------------===//
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//
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// This file defines class MCInstPredicate and its subclasses.
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//
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// MCInstPredicate definitions are used by target scheduling models to describe
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// constraints on instructions.
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//
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// Here is an example of an MCInstPredicate definition in TableGen:
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//
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// def MCInstPredicateExample : CheckAll<[
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// CheckOpcode<[BLR]>,
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// CheckIsRegOperand<0>,
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// CheckNot<CheckRegOperand<0, LR>>]>;
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//
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// The syntax for MCInstPredicate is declarative, and predicate definitions can
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// be composed together in order to generate more complex constraints.
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//
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// The `CheckAll` from the example defines a composition of three different
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// predicates. Definition `MCInstPredicateExample` identifies instructions
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// whose opcode is BLR, and whose first operand is a register different from
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// register `LR`.
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//
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// Every MCInstPredicate class has a well-known semantic in tablegen. For
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// example, `CheckOpcode` is a special type of predicate used to describe a
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// constraint on the value of an instruction opcode.
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//
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// MCInstPredicate definitions are typically used by scheduling models to
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// construct MCSchedPredicate definitions (see the definition of class
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// MCSchedPredicate in llvm/Target/TargetSchedule.td).
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// In particular, an MCSchedPredicate can be used instead of a SchedPredicate
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// when defining the set of SchedReadVariant and SchedWriteVariant of a
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// processor scheduling model.
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//
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// The `MCInstPredicateExample` definition above is equivalent (and therefore
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// could replace) the following definition from a previous ExynosM3 model (see
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// AArch64SchedExynosM3.td):
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//
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// def M3BranchLinkFastPred : SchedPredicate<[{
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// MI->getOpcode() == AArch64::BLR &&
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// MI->getOperand(0).isReg() &&
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// MI->getOperand(0).getReg() != AArch64::LR}]>;
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//
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// The main advantage of using MCInstPredicate instead of SchedPredicate is
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// portability: users don't need to specify predicates in C++. As a consequence
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// of this, MCInstPredicate definitions are not bound to a particular
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// representation (i.e. MachineInstr vs MCInst).
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//
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// Tablegen backends know how to expand MCInstPredicate definitions into actual
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// C++ code that works on MachineInstr (and/or MCInst).
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//
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// Instances of class PredicateExpander (see utils/Tablegen/PredicateExpander.h)
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// know how to expand a predicate. For each MCInstPredicate class, there must be
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// an "expand" method available in the PredicateExpander interface.
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//
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// For example, a `CheckOpcode` predicate is expanded using method
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// `PredicateExpander::expandCheckOpcode()`.
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//
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// New MCInstPredicate classes must be added to this file. For each new class
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// XYZ, an "expandXYZ" method must be added to the PredicateExpander.
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//
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//===----------------------------------------------------------------------===//
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// Forward declarations.
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class Instruction;
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class SchedMachineModel;
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// A generic machine instruction predicate.
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class MCInstPredicate;
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class MCTrue : MCInstPredicate; // A predicate that always evaluates to True.
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class MCFalse : MCInstPredicate; // A predicate that always evaluates to False.
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def TruePred : MCTrue;
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def FalsePred : MCFalse;
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// A predicate used to negate the outcome of another predicate.
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// It allows to easily express "set difference" operations. For example, it
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// makes it easy to describe a check that tests if an opcode is not part of a
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// set of opcodes.
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class CheckNot<MCInstPredicate P> : MCInstPredicate {
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MCInstPredicate Pred = P;
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}
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// This class is used as a building block to define predicates on instruction
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// operands. It is used to reference a specific machine operand.
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class MCOperandPredicate<int Index> : MCInstPredicate {
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int OpIndex = Index;
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}
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// Return true if machine operand at position `Index` is a register operand.
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class CheckIsRegOperand<int Index> : MCOperandPredicate<Index>;
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// Return true if machine operand at position `Index` is an immediate operand.
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class CheckIsImmOperand<int Index> : MCOperandPredicate<Index>;
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// Check if machine operands at index `First` and index `Second` both reference
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// the same register.
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class CheckSameRegOperand<int First, int Second> : MCInstPredicate {
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int FirstIndex = First;
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int SecondIndex = Second;
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}
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// Base class for checks on register/immediate operands.
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// It allows users to define checks like:
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// MyFunction(MI->getOperand(Index).getImm()) == Val;
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//
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// In the example above, `MyFunction` is a function that takes as input an
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// immediate operand value, and returns another value. Field `FunctionMapper` is
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// the name of the function to call on the operand value.
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class CheckOperandBase<int Index, string Fn = ""> : MCOperandPredicate<Index> {
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string FunctionMapper = Fn;
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}
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// Check that the machine register operand at position `Index` references
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// register R. This predicate assumes that we already checked that the machine
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// operand at position `Index` is a register operand.
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class CheckRegOperand<int Index, Register R> : CheckOperandBase<Index> {
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Register Reg = R;
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}
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// Check if register operand at index `Index` is the invalid register.
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class CheckInvalidRegOperand<int Index> : CheckOperandBase<Index>;
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// Return true if machine operand at position `Index` is a valid
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// register operand.
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class CheckValidRegOperand<int Index> :
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CheckNot<CheckInvalidRegOperand<Index>>;
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// Check that the operand at position `Index` is immediate `Imm`.
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// If field `FunctionMapper` is a non-empty string, then function
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// `FunctionMapper` is applied to the operand value, and the return value is then
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// compared against `Imm`.
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class CheckImmOperand<int Index, int Imm> : CheckOperandBase<Index> {
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int ImmVal = Imm;
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}
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// Similar to CheckImmOperand, however the immediate is not a literal number.
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// This is useful when we want to compare the value of an operand against an
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// enum value, and we know the actual integer value of that enum.
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class CheckImmOperand_s<int Index, string Value> : CheckOperandBase<Index> {
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string ImmVal = Value;
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}
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// Expands to a call to `FunctionMapper` if field `FunctionMapper` is set.
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// Otherwise, it expands to a CheckNot<CheckInvalidRegOperand<Index>>.
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class CheckRegOperandSimple<int Index> : CheckOperandBase<Index>;
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// Expands to a call to `FunctionMapper` if field `FunctionMapper` is set.
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// Otherwise, it simply evaluates to TruePred.
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class CheckImmOperandSimple<int Index> : CheckOperandBase<Index>;
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// Check that the operand at position `Index` is immediate value zero.
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class CheckZeroOperand<int Index> : CheckImmOperand<Index, 0>;
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// Check that the instruction has exactly `Num` operands.
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class CheckNumOperands<int Num> : MCInstPredicate {
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int NumOps = Num;
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}
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// Check that the instruction opcode is one of the opcodes in set `Opcodes`.
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// This is a simple set membership query. The easier way to check if an opcode
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// is not a member of the set is by using a `CheckNot<CheckOpcode<[...]>>`
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// sequence.
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class CheckOpcode<list<Instruction> Opcodes> : MCInstPredicate {
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list<Instruction> ValidOpcodes = Opcodes;
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}
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// Check that the instruction opcode is a pseudo opcode member of the set
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// `Opcodes`. This check is always expanded to "false" if we are generating
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// code for MCInst.
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class CheckPseudo<list<Instruction> Opcodes> : CheckOpcode<Opcodes>;
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// A non-portable predicate. Only to use as a last resort when a block of code
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// cannot possibly be converted in a declarative way using other MCInstPredicate
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// classes. This check is always expanded to "false" when generating code for
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// MCInst.
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class CheckNonPortable<string Code> : MCInstPredicate {
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string CodeBlock = Code;
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}
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// A sequence of predicates. It is used as the base class for CheckAll, and
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// CheckAny. It allows to describe compositions of predicates.
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class CheckPredicateSequence<list<MCInstPredicate> Preds> : MCInstPredicate {
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list<MCInstPredicate> Predicates = Preds;
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}
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// Check that all of the predicates in `Preds` evaluate to true.
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class CheckAll<list<MCInstPredicate> Sequence>
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: CheckPredicateSequence<Sequence>;
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// Check that at least one of the predicates in `Preds` evaluates to true.
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class CheckAny<list<MCInstPredicate> Sequence>
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: CheckPredicateSequence<Sequence>;
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// Used to expand the body of a function predicate. See the definition of
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// TIIPredicate below.
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class MCStatement;
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// Expands to a return statement. The return expression is a boolean expression
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// described by a MCInstPredicate.
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class MCReturnStatement<MCInstPredicate predicate> : MCStatement {
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MCInstPredicate Pred = predicate;
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}
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// Used to automatically construct cases of a switch statement where the switch
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// variable is an instruction opcode. There is a 'case' for every opcode in the
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// `opcodes` list, and each case is associated with MCStatement `caseStmt`.
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class MCOpcodeSwitchCase<list<Instruction> opcodes, MCStatement caseStmt> {
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list<Instruction> Opcodes = opcodes;
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MCStatement CaseStmt = caseStmt;
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}
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// Expands to a switch statement. The switch variable is an instruction opcode.
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// The auto-generated switch is populated by a number of cases based on the
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// `cases` list in input. A default case is automatically generated, and it
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// evaluates to `default`.
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class MCOpcodeSwitchStatement<list<MCOpcodeSwitchCase> cases,
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MCStatement default> : MCStatement {
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list<MCOpcodeSwitchCase> Cases = cases;
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MCStatement DefaultCase = default;
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}
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// Base class for function predicates.
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class FunctionPredicateBase<string name, MCStatement body> {
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string FunctionName = name;
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MCStatement Body = body;
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}
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// Check that a call to method `Name` in class "XXXInstrInfo" (where XXX is
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// the name of a target) returns true.
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//
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// TIIPredicate definitions are used to model calls to the target-specific
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// InstrInfo. A TIIPredicate is treated specially by the InstrInfoEmitter
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// tablegen backend, which will use it to automatically generate a definition in
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// the target specific `InstrInfo` class.
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//
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// There cannot be multiple TIIPredicate definitions with the same name for the
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// same target.
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class TIIPredicate<string Name, MCStatement body>
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: FunctionPredicateBase<Name, body>, MCInstPredicate;
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// A function predicate that takes as input a machine instruction, and returns
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// a boolean value.
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//
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// This predicate is expanded into a function call by the PredicateExpander.
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// In particular, the PredicateExpander would either expand this predicate into
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// a call to `MCInstFn`, or into a call to`MachineInstrFn` depending on whether
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// it is lowering predicates for MCInst or MachineInstr.
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//
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// In this context, `MCInstFn` and `MachineInstrFn` are both function names.
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class CheckFunctionPredicate<string MCInstFn, string MachineInstrFn> : MCInstPredicate {
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string MCInstFnName = MCInstFn;
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string MachineInstrFnName = MachineInstrFn;
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}
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// Similar to CheckFunctionPredicate. However it assumes that MachineInstrFn is
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// a method in TargetInstrInfo, and MCInstrFn takes an extra pointer to
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// MCInstrInfo.
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//
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// It Expands to:
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// - TIIPointer->MachineInstrFn(MI)
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// - MCInstrFn(MI, MCII);
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class CheckFunctionPredicateWithTII<string MCInstFn, string MachineInstrFn, string
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TIIPointer = "TII"> : MCInstPredicate {
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string MCInstFnName = MCInstFn;
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string TIIPtrName = TIIPointer;
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string MachineInstrFnName = MachineInstrFn;
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}
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// Used to classify machine instructions based on a machine instruction
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// predicate.
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//
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// Let IC be an InstructionEquivalenceClass definition, and MI a machine
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// instruction. We say that MI belongs to the equivalence class described by IC
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// if and only if the following two conditions are met:
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// a) MI's opcode is in the `opcodes` set, and
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// b) `Predicate` evaluates to true when applied to MI.
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//
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// Instances of this class can be used by processor scheduling models to
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// describe instructions that have a property in common. For example,
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// InstructionEquivalenceClass definitions can be used to identify the set of
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// dependency breaking instructions for a processor model.
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//
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// An (optional) list of operand indices can be used to further describe
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// properties that apply to instruction operands. For example, it can be used to
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// identify register uses of a dependency breaking instructions that are not in
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// a RAW dependency.
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class InstructionEquivalenceClass<list<Instruction> opcodes,
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MCInstPredicate pred,
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list<int> operands = []> {
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list<Instruction> Opcodes = opcodes;
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MCInstPredicate Predicate = pred;
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list<int> OperandIndices = operands;
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}
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// Used by processor models to describe dependency breaking instructions.
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//
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// This is mainly an alias for InstructionEquivalenceClass. Input operand
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// `BrokenDeps` identifies the set of "broken dependencies". There is one bit
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// per each implicit and explicit input operand. An empty set of broken
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// dependencies means: "explicit input register operands are independent."
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class DepBreakingClass<list<Instruction> opcodes, MCInstPredicate pred,
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list<int> BrokenDeps = []>
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: InstructionEquivalenceClass<opcodes, pred, BrokenDeps>;
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// A function descriptor used to describe the signature of a predicate methods
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// which will be expanded by the STIPredicateExpander into a tablegen'd
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// XXXGenSubtargetInfo class member definition (here, XXX is a target name).
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//
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// It describes the signature of a TargetSubtarget hook, as well as a few extra
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// properties. Examples of extra properties are:
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// - The default return value for the auto-generate function hook.
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// - A list of subtarget hooks (Delegates) that are called from this function.
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//
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class STIPredicateDecl<string name, MCInstPredicate default = FalsePred,
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bit overrides = true, bit expandForMC = true,
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bit updatesOpcodeMask = false,
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list<STIPredicateDecl> delegates = []> {
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string Name = name;
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MCInstPredicate DefaultReturnValue = default;
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// True if this method is declared as virtual in class TargetSubtargetInfo.
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bit OverridesBaseClassMember = overrides;
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// True if we need an equivalent predicate function in the MC layer.
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bit ExpandForMC = expandForMC;
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// True if the autogenerated method has a extra in/out APInt param used as a
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// mask of operands.
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bit UpdatesOpcodeMask = updatesOpcodeMask;
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// A list of STIPredicates used by this definition to delegate part of the
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// computation. For example, STIPredicateFunction `isDependencyBreaking()`
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// delegates to `isZeroIdiom()` part of its computation.
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list<STIPredicateDecl> Delegates = delegates;
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}
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// A predicate function definition member of class `XXXGenSubtargetInfo`.
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//
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// If `Declaration.ExpandForMC` is true, then SubtargetEmitter
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// will also expand another definition of this method that accepts a MCInst.
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class STIPredicate<STIPredicateDecl declaration,
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list<InstructionEquivalenceClass> classes> {
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STIPredicateDecl Declaration = declaration;
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list<InstructionEquivalenceClass> Classes = classes;
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SchedMachineModel SchedModel = ?;
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}
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// Convenience classes and definitions used by processor scheduling models to
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// describe dependency breaking instructions and move elimination candidates.
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let UpdatesOpcodeMask = true in {
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def IsZeroIdiomDecl : STIPredicateDecl<"isZeroIdiom">;
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let Delegates = [IsZeroIdiomDecl] in
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def IsDepBreakingDecl : STIPredicateDecl<"isDependencyBreaking">;
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} // UpdatesOpcodeMask
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def IsOptimizableRegisterMoveDecl
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: STIPredicateDecl<"isOptimizableRegisterMove">;
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class IsZeroIdiomFunction<list<DepBreakingClass> classes>
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: STIPredicate<IsZeroIdiomDecl, classes>;
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class IsDepBreakingFunction<list<DepBreakingClass> classes>
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: STIPredicate<IsDepBreakingDecl, classes>;
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class IsOptimizableRegisterMove<list<InstructionEquivalenceClass> classes>
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: STIPredicate<IsOptimizableRegisterMoveDecl, classes>;
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