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llvm-mirror/include/llvm/Target/TargetInstrPredicate.td
Chandler Carruth ae65e281f3 Update the file headers across all of the LLVM projects in the monorepo
to reflect the new license.

We understand that people may be surprised that we're moving the header
entirely to discuss the new license. We checked this carefully with the
Foundation's lawyer and we believe this is the correct approach.

Essentially, all code in the project is now made available by the LLVM
project under our new license, so you will see that the license headers
include that license only. Some of our contributors have contributed
code under our old license, and accordingly, we have retained a copy of
our old license notice in the top-level files in each project and
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llvm-svn: 351636
2019-01-19 08:50:56 +00:00

359 lines
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TableGen

//===- TargetInstrPredicate.td - ---------------------------*- tablegen -*-===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
//
// This file defines class MCInstPredicate and its subclasses.
//
// MCInstPredicate definitions are used by target scheduling models to describe
// constraints on instructions.
//
// Here is an example of an MCInstPredicate definition in tablegen:
//
// def MCInstPredicateExample : CheckAll<[
// CheckOpcode<[BLR]>,
// CheckIsRegOperand<0>,
// CheckNot<CheckRegOperand<0, LR>>]>;
//
// The syntax for MCInstPredicate is declarative, and predicate definitions can
// be composed together in order to generate more complex constraints.
//
// The `CheckAll` from the example defines a composition of three different
// predicates. Definition `MCInstPredicateExample` identifies instructions
// whose opcode is BLR, and whose first operand is a register different from
// register `LR`.
//
// Every MCInstPredicate class has a well-known semantic in tablegen. For
// example, `CheckOpcode` is a special type of predicate used to describe a
// constraint on the value of an instruction opcode.
//
// MCInstPredicate definitions are typically used by scheduling models to
// construct MCSchedPredicate definitions (see the definition of class
// MCSchedPredicate in llvm/Target/TargetSchedule.td).
// In particular, an MCSchedPredicate can be used instead of a SchedPredicate
// when defining the set of SchedReadVariant and SchedWriteVariant of a
// processor scheduling model.
//
// The `MCInstPredicateExample` definition above is equivalent (and therefore
// could replace) the following definition from a previous ExynosM3 model (see
// AArch64SchedExynosM3.td):
//
// def M3BranchLinkFastPred : SchedPredicate<[{
// MI->getOpcode() == AArch64::BLR &&
// MI->getOperand(0).isReg() &&
// MI->getOperand(0).getReg() != AArch64::LR}]>;
//
// The main advantage of using MCInstPredicate instead of SchedPredicate is
// portability: users don't need to specify predicates in C++. As a consequence
// of this, MCInstPredicate definitions are not bound to a particular
// representation (i.e. MachineInstr vs MCInst).
//
// Tablegen backends know how to expand MCInstPredicate definitions into actual
// C++ code that works on MachineInstr (and/or MCInst).
//
// Instances of class PredicateExpander (see utils/Tablegen/PredicateExpander.h)
// know how to expand a predicate. For each MCInstPredicate class, there must be
// an "expand" method available in the PredicateExpander interface.
//
// For example, a `CheckOpcode` predicate is expanded using method
// `PredicateExpander::expandCheckOpcode()`.
//
// New MCInstPredicate classes must be added to this file. For each new class
// XYZ, an "expandXYZ" method must be added to the PredicateExpander.
//
//===----------------------------------------------------------------------===//
// Forward declarations.
class Instruction;
class SchedMachineModel;
// A generic machine instruction predicate.
class MCInstPredicate;
class MCTrue : MCInstPredicate; // A predicate that always evaluates to True.
class MCFalse : MCInstPredicate; // A predicate that always evaluates to False.
def TruePred : MCTrue;
def FalsePred : MCFalse;
// A predicate used to negate the outcome of another predicate.
// It allows to easily express "set difference" operations. For example, it
// makes it easy to describe a check that tests if an opcode is not part of a
// set of opcodes.
class CheckNot<MCInstPredicate P> : MCInstPredicate {
MCInstPredicate Pred = P;
}
// This class is used as a building block to define predicates on instruction
// operands. It is used to reference a specific machine operand.
class MCOperandPredicate<int Index> : MCInstPredicate {
int OpIndex = Index;
}
// Return true if machine operand at position `Index` is a register operand.
class CheckIsRegOperand<int Index> : MCOperandPredicate<Index>;
// Return true if machine operand at position `Index` is an immediate operand.
class CheckIsImmOperand<int Index> : MCOperandPredicate<Index>;
// Check if machine operands at index `First` and index `Second` both reference
// the same register.
class CheckSameRegOperand<int First, int Second> : MCInstPredicate {
int FirstIndex = First;
int SecondIndex = Second;
}
// Base class for checks on register/immediate operands.
// It allows users to define checks like:
// MyFunction(MI->getOperand(Index).getImm()) == Val;
//
// In the example above, `MyFunction` is a function that takes as input an
// immediate operand value, and returns another value. Field `FunctionMapper` is
// the name of the function to call on the operand value.
class CheckOperandBase<int Index, string Fn = ""> : MCOperandPredicate<Index> {
string FunctionMapper = Fn;
}
// Check that the machine register operand at position `Index` references
// register R. This predicate assumes that we already checked that the machine
// operand at position `Index` is a register operand.
class CheckRegOperand<int Index, Register R> : CheckOperandBase<Index> {
Register Reg = R;
}
// Check if register operand at index `Index` is the invalid register.
class CheckInvalidRegOperand<int Index> : CheckOperandBase<Index>;
// Check that the operand at position `Index` is immediate `Imm`.
// If field `FunctionMapper` is a non-empty string, then function
// `FunctionMapper` is applied to the operand value, and the return value is then
// compared against `Imm`.
class CheckImmOperand<int Index, int Imm> : CheckOperandBase<Index> {
int ImmVal = Imm;
}
// Similar to CheckImmOperand, however the immediate is not a literal number.
// This is useful when we want to compare the value of an operand against an
// enum value, and we know the actual integer value of that enum.
class CheckImmOperand_s<int Index, string Value> : CheckOperandBase<Index> {
string ImmVal = Value;
}
// Expands to a call to `FunctionMapper` if field `FunctionMapper` is set.
// Otherwise, it expands to a CheckNot<CheckInvalidRegOperand<Index>>.
class CheckRegOperandSimple<int Index> : CheckOperandBase<Index>;
// Expands to a call to `FunctionMapper` if field `FunctionMapper` is set.
// Otherwise, it simply evaluates to TruePred.
class CheckImmOperandSimple<int Index> : CheckOperandBase<Index>;
// Check that the operand at position `Index` is immediate value zero.
class CheckZeroOperand<int Index> : CheckImmOperand<Index, 0>;
// Check that the instruction has exactly `Num` operands.
class CheckNumOperands<int Num> : MCInstPredicate {
int NumOps = Num;
}
// Check that the instruction opcode is one of the opcodes in set `Opcodes`.
// This is a simple set membership query. The easier way to check if an opcode
// is not a member of the set is by using a `CheckNot<CheckOpcode<[...]>>`
// sequence.
class CheckOpcode<list<Instruction> Opcodes> : MCInstPredicate {
list<Instruction> ValidOpcodes = Opcodes;
}
// Check that the instruction opcode is a pseudo opcode member of the set
// `Opcodes`. This check is always expanded to "false" if we are generating
// code for MCInst.
class CheckPseudo<list<Instruction> Opcodes> : CheckOpcode<Opcodes>;
// A non-portable predicate. Only to use as a last resort when a block of code
// cannot possibly be converted in a declarative way using other MCInstPredicate
// classes. This check is always expanded to "false" when generating code for
// MCInst.
class CheckNonPortable<string Code> : MCInstPredicate {
string CodeBlock = Code;
}
// A sequence of predicates. It is used as the base class for CheckAll, and
// CheckAny. It allows to describe compositions of predicates.
class CheckPredicateSequence<list<MCInstPredicate> Preds> : MCInstPredicate {
list<MCInstPredicate> Predicates = Preds;
}
// Check that all of the predicates in `Preds` evaluate to true.
class CheckAll<list<MCInstPredicate> Sequence>
: CheckPredicateSequence<Sequence>;
// Check that at least one of the predicates in `Preds` evaluates to true.
class CheckAny<list<MCInstPredicate> Sequence>
: CheckPredicateSequence<Sequence>;
// Used to expand the body of a function predicate. See the definition of
// TIIPredicate below.
class MCStatement;
// Expands to a return statement. The return expression is a boolean expression
// described by a MCInstPredicate.
class MCReturnStatement<MCInstPredicate predicate> : MCStatement {
MCInstPredicate Pred = predicate;
}
// Used to automatically construct cases of a switch statement where the switch
// variable is an instruction opcode. There is a 'case' for every opcode in the
// `opcodes` list, and each case is associated with MCStatement `caseStmt`.
class MCOpcodeSwitchCase<list<Instruction> opcodes, MCStatement caseStmt> {
list<Instruction> Opcodes = opcodes;
MCStatement CaseStmt = caseStmt;
}
// Expands to a switch statement. The switch variable is an instruction opcode.
// The auto-generated switch is populated by a number of cases based on the
// `cases` list in input. A default case is automatically generated, and it
// evaluates to `default`.
class MCOpcodeSwitchStatement<list<MCOpcodeSwitchCase> cases,
MCStatement default> : MCStatement {
list<MCOpcodeSwitchCase> Cases = cases;
MCStatement DefaultCase = default;
}
// Base class for function predicates.
class FunctionPredicateBase<string name, MCStatement body> {
string FunctionName = name;
MCStatement Body = body;
}
// Check that a call to method `Name` in class "XXXInstrInfo" (where XXX is
// the name of a target) returns true.
//
// TIIPredicate definitions are used to model calls to the target-specific
// InstrInfo. A TIIPredicate is treated specially by the InstrInfoEmitter
// tablegen backend, which will use it to automatically generate a definition in
// the target specific `InstrInfo` class.
//
// There cannot be multiple TIIPredicate definitions with the same name for the
// same target.
class TIIPredicate<string Name, MCStatement body>
: FunctionPredicateBase<Name, body>, MCInstPredicate;
// A function predicate that takes as input a machine instruction, and returns
// a boolean value.
//
// This predicate is expanded into a function call by the PredicateExpander.
// In particular, the PredicateExpander would either expand this predicate into
// a call to `MCInstFn`, or into a call to`MachineInstrFn` depending on whether
// it is lowering predicates for MCInst or MachineInstr.
//
// In this context, `MCInstFn` and `MachineInstrFn` are both function names.
class CheckFunctionPredicate<string MCInstFn, string MachineInstrFn> : MCInstPredicate {
string MCInstFnName = MCInstFn;
string MachineInstrFnName = MachineInstrFn;
}
// Used to classify machine instructions based on a machine instruction
// predicate.
//
// Let IC be an InstructionEquivalenceClass definition, and MI a machine
// instruction. We say that MI belongs to the equivalence class described by IC
// if and only if the following two conditions are met:
// a) MI's opcode is in the `opcodes` set, and
// b) `Predicate` evaluates to true when applied to MI.
//
// Instances of this class can be used by processor scheduling models to
// describe instructions that have a property in common. For example,
// InstructionEquivalenceClass definitions can be used to identify the set of
// dependency breaking instructions for a processor model.
//
// An (optional) list of operand indices can be used to further describe
// properties that apply to instruction operands. For example, it can be used to
// identify register uses of a dependency breaking instructions that are not in
// a RAW dependency.
class InstructionEquivalenceClass<list<Instruction> opcodes,
MCInstPredicate pred,
list<int> operands = []> {
list<Instruction> Opcodes = opcodes;
MCInstPredicate Predicate = pred;
list<int> OperandIndices = operands;
}
// Used by processor models to describe dependency breaking instructions.
//
// This is mainly an alias for InstructionEquivalenceClass. Input operand
// `BrokenDeps` identifies the set of "broken dependencies". There is one bit
// per each implicit and explicit input operand. An empty set of broken
// dependencies means: "explicit input register operands are independent."
class DepBreakingClass<list<Instruction> opcodes, MCInstPredicate pred,
list<int> BrokenDeps = []>
: InstructionEquivalenceClass<opcodes, pred, BrokenDeps>;
// A function descriptor used to describe the signature of a predicate methods
// which will be expanded by the STIPredicateExpander into a tablegen'd
// XXXGenSubtargetInfo class member definition (here, XXX is a target name).
//
// It describes the signature of a TargetSubtarget hook, as well as a few extra
// properties. Examples of extra properties are:
// - The default return value for the auto-generate function hook.
// - A list of subtarget hooks (Delegates) that are called from this function.
//
class STIPredicateDecl<string name, MCInstPredicate default = FalsePred,
bit overrides = 1, bit expandForMC = 1,
bit updatesOpcodeMask = 0,
list<STIPredicateDecl> delegates = []> {
string Name = name;
MCInstPredicate DefaultReturnValue = default;
// True if this method is declared as virtual in class TargetSubtargetInfo.
bit OverridesBaseClassMember = overrides;
// True if we need an equivalent predicate function in the MC layer.
bit ExpandForMC = expandForMC;
// True if the autogenerated method has a extra in/out APInt param used as a
// mask of operands.
bit UpdatesOpcodeMask = updatesOpcodeMask;
// A list of STIPredicates used by this definition to delegate part of the
// computation. For example, STIPredicateFunction `isDependencyBreaking()`
// delegates to `isZeroIdiom()` part of its computation.
list<STIPredicateDecl> Delegates = delegates;
}
// A predicate function definition member of class `XXXGenSubtargetInfo`.
//
// If `Declaration.ExpandForMC` is true, then SubtargetEmitter
// will also expand another definition of this method that accepts a MCInst.
class STIPredicate<STIPredicateDecl declaration,
list<InstructionEquivalenceClass> classes> {
STIPredicateDecl Declaration = declaration;
list<InstructionEquivalenceClass> Classes = classes;
SchedMachineModel SchedModel = ?;
}
// Convenience classes and definitions used by processor scheduling models to
// describe dependency breaking instructions and move elimination candidates.
let UpdatesOpcodeMask = 1 in {
def IsZeroIdiomDecl : STIPredicateDecl<"isZeroIdiom">;
let Delegates = [IsZeroIdiomDecl] in
def IsDepBreakingDecl : STIPredicateDecl<"isDependencyBreaking">;
} // UpdatesOpcodeMask
def IsOptimizableRegisterMoveDecl
: STIPredicateDecl<"isOptimizableRegisterMove">;
class IsZeroIdiomFunction<list<DepBreakingClass> classes>
: STIPredicate<IsZeroIdiomDecl, classes>;
class IsDepBreakingFunction<list<DepBreakingClass> classes>
: STIPredicate<IsDepBreakingDecl, classes>;
class IsOptimizableRegisterMove<list<InstructionEquivalenceClass> classes>
: STIPredicate<IsOptimizableRegisterMoveDecl, classes>;