1
0
mirror of https://github.com/RPCS3/llvm-mirror.git synced 2024-11-24 03:33:20 +01:00
llvm-mirror/include/llvm/Target/Target.td
Oliver Stannard 20a7d7760f [AsmParser] Add DiagnosticString to register classes in tablegen
This allows a DiagnosticType and/or DiagnosticString to be associated
with a RegisterClass in tablegen, so that we can emit diagnostics in the
assembler when a register operand is incorrect.

DiagnosticType creates a predictable enum value, which gets returned as
the error code when an operand does not match, and can be used by the
assembly parser to map to a user-facing diagnostic. DiagnosticString
creates an anonymous enum value (currently based on the tablegen class
name), and a function to map from enum values to strings will be
generated. Both of these work the same was as they do for AsmOperand.

This isn't used by any targets yet, but has one (positive) side-effect.
It improves the diagnostic codes returned by validateOperandClass - we
always want to emit the diagnostic that relates to the expected operand
class, but this wasn't always being done when the expected and actual
classes were completely different (token/register/custom). This causes a
few AArch64 diagnostics to be improved, as Match_InvalidOperand was
being returned instead of a specific diagnostic type.

Differential revision: https://reviews.llvm.org/D36691

llvm-svn: 315295
2017-10-10 11:00:40 +00:00

1474 lines
59 KiB
TableGen

//===- Target.td - Target Independent TableGen interface ---*- tablegen -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file defines the target-independent interfaces which should be
// implemented by each target which is using a TableGen based code generator.
//
//===----------------------------------------------------------------------===//
// Include all information about LLVM intrinsics.
include "llvm/IR/Intrinsics.td"
//===----------------------------------------------------------------------===//
// Register file description - These classes are used to fill in the target
// description classes.
class RegisterClass; // Forward def
class HwMode<string FS> {
// A string representing subtarget features that turn on this HW mode.
// For example, "+feat1,-feat2" will indicate that the mode is active
// when "feat1" is enabled and "feat2" is disabled at the same time.
// Any other features are not checked.
// When multiple modes are used, they should be mutually exclusive,
// otherwise the results are unpredictable.
string Features = FS;
}
// A special mode recognized by tablegen. This mode is considered active
// when no other mode is active. For targets that do not use specific hw
// modes, this is the only mode.
def DefaultMode : HwMode<"">;
// A class used to associate objects with HW modes. It is only intended to
// be used as a base class, where the derived class should contain a member
// "Objects", which is a list of the same length as the list of modes.
// The n-th element on the Objects list will be associated with the n-th
// element on the Modes list.
class HwModeSelect<list<HwMode> Ms> {
list<HwMode> Modes = Ms;
}
// A common class that implements a counterpart of ValueType, which is
// dependent on a HW mode. This class inherits from ValueType itself,
// which makes it possible to use objects of this class where ValueType
// objects could be used. This is specifically applicable to selection
// patterns.
class ValueTypeByHwMode<list<HwMode> Ms, list<ValueType> Ts>
: HwModeSelect<Ms>, ValueType<0, 0> {
// The length of this list must be the same as the length of Ms.
list<ValueType> Objects = Ts;
}
// A class representing the register size, spill size and spill alignment
// in bits of a register.
class RegInfo<int RS, int SS, int SA> {
int RegSize = RS; // Register size in bits.
int SpillSize = SS; // Spill slot size in bits.
int SpillAlignment = SA; // Spill slot alignment in bits.
}
// The register size/alignment information, parameterized by a HW mode.
class RegInfoByHwMode<list<HwMode> Ms = [], list<RegInfo> Ts = []>
: HwModeSelect<Ms> {
// The length of this list must be the same as the length of Ms.
list<RegInfo> Objects = Ts;
}
// SubRegIndex - Use instances of SubRegIndex to identify subregisters.
class SubRegIndex<int size, int offset = 0> {
string Namespace = "";
// Size - Size (in bits) of the sub-registers represented by this index.
int Size = size;
// Offset - Offset of the first bit that is part of this sub-register index.
// Set it to -1 if the same index is used to represent sub-registers that can
// be at different offsets (for example when using an index to access an
// element in a register tuple).
int Offset = offset;
// ComposedOf - A list of two SubRegIndex instances, [A, B].
// This indicates that this SubRegIndex is the result of composing A and B.
// See ComposedSubRegIndex.
list<SubRegIndex> ComposedOf = [];
// CoveringSubRegIndices - A list of two or more sub-register indexes that
// cover this sub-register.
//
// This field should normally be left blank as TableGen can infer it.
//
// TableGen automatically detects sub-registers that straddle the registers
// in the SubRegs field of a Register definition. For example:
//
// Q0 = dsub_0 -> D0, dsub_1 -> D1
// Q1 = dsub_0 -> D2, dsub_1 -> D3
// D1_D2 = dsub_0 -> D1, dsub_1 -> D2
// QQ0 = qsub_0 -> Q0, qsub_1 -> Q1
//
// TableGen will infer that D1_D2 is a sub-register of QQ0. It will be given
// the synthetic index dsub_1_dsub_2 unless some SubRegIndex is defined with
// CoveringSubRegIndices = [dsub_1, dsub_2].
list<SubRegIndex> CoveringSubRegIndices = [];
}
// ComposedSubRegIndex - A sub-register that is the result of composing A and B.
// Offset is set to the sum of A and B's Offsets. Size is set to B's Size.
class ComposedSubRegIndex<SubRegIndex A, SubRegIndex B>
: SubRegIndex<B.Size, !if(!eq(A.Offset, -1), -1,
!if(!eq(B.Offset, -1), -1,
!add(A.Offset, B.Offset)))> {
// See SubRegIndex.
let ComposedOf = [A, B];
}
// RegAltNameIndex - The alternate name set to use for register operands of
// this register class when printing.
class RegAltNameIndex {
string Namespace = "";
}
def NoRegAltName : RegAltNameIndex;
// Register - You should define one instance of this class for each register
// in the target machine. String n will become the "name" of the register.
class Register<string n, list<string> altNames = []> {
string Namespace = "";
string AsmName = n;
list<string> AltNames = altNames;
// Aliases - A list of registers that this register overlaps with. A read or
// modification of this register can potentially read or modify the aliased
// registers.
list<Register> Aliases = [];
// SubRegs - A list of registers that are parts of this register. Note these
// are "immediate" sub-registers and the registers within the list do not
// themselves overlap. e.g. For X86, EAX's SubRegs list contains only [AX],
// not [AX, AH, AL].
list<Register> SubRegs = [];
// SubRegIndices - For each register in SubRegs, specify the SubRegIndex used
// to address it. Sub-sub-register indices are automatically inherited from
// SubRegs.
list<SubRegIndex> SubRegIndices = [];
// RegAltNameIndices - The alternate name indices which are valid for this
// register.
list<RegAltNameIndex> RegAltNameIndices = [];
// DwarfNumbers - Numbers used internally by gcc/gdb to identify the register.
// These values can be determined by locating the <target>.h file in the
// directory llvmgcc/gcc/config/<target>/ and looking for REGISTER_NAMES. The
// order of these names correspond to the enumeration used by gcc. A value of
// -1 indicates that the gcc number is undefined and -2 that register number
// is invalid for this mode/flavour.
list<int> DwarfNumbers = [];
// CostPerUse - Additional cost of instructions using this register compared
// to other registers in its class. The register allocator will try to
// minimize the number of instructions using a register with a CostPerUse.
// This is used by the x86-64 and ARM Thumb targets where some registers
// require larger instruction encodings.
int CostPerUse = 0;
// CoveredBySubRegs - When this bit is set, the value of this register is
// completely determined by the value of its sub-registers. For example, the
// x86 register AX is covered by its sub-registers AL and AH, but EAX is not
// covered by its sub-register AX.
bit CoveredBySubRegs = 0;
// HWEncoding - The target specific hardware encoding for this register.
bits<16> HWEncoding = 0;
}
// RegisterWithSubRegs - This can be used to define instances of Register which
// need to specify sub-registers.
// List "subregs" specifies which registers are sub-registers to this one. This
// is used to populate the SubRegs and AliasSet fields of TargetRegisterDesc.
// This allows the code generator to be careful not to put two values with
// overlapping live ranges into registers which alias.
class RegisterWithSubRegs<string n, list<Register> subregs> : Register<n> {
let SubRegs = subregs;
}
// DAGOperand - An empty base class that unifies RegisterClass's and other forms
// of Operand's that are legal as type qualifiers in DAG patterns. This should
// only ever be used for defining multiclasses that are polymorphic over both
// RegisterClass's and other Operand's.
class DAGOperand {
string OperandNamespace = "MCOI";
string DecoderMethod = "";
}
// RegisterClass - Now that all of the registers are defined, and aliases
// between registers are defined, specify which registers belong to which
// register classes. This also defines the default allocation order of
// registers by register allocators.
//
class RegisterClass<string namespace, list<ValueType> regTypes, int alignment,
dag regList, RegAltNameIndex idx = NoRegAltName>
: DAGOperand {
string Namespace = namespace;
// The register size/alignment information, parameterized by a HW mode.
RegInfoByHwMode RegInfos;
// RegType - Specify the list ValueType of the registers in this register
// class. Note that all registers in a register class must have the same
// ValueTypes. This is a list because some targets permit storing different
// types in same register, for example vector values with 128-bit total size,
// but different count/size of items, like SSE on x86.
//
list<ValueType> RegTypes = regTypes;
// Size - Specify the spill size in bits of the registers. A default value of
// zero lets tablgen pick an appropriate size.
int Size = 0;
// Alignment - Specify the alignment required of the registers when they are
// stored or loaded to memory.
//
int Alignment = alignment;
// CopyCost - This value is used to specify the cost of copying a value
// between two registers in this register class. The default value is one
// meaning it takes a single instruction to perform the copying. A negative
// value means copying is extremely expensive or impossible.
int CopyCost = 1;
// MemberList - Specify which registers are in this class. If the
// allocation_order_* method are not specified, this also defines the order of
// allocation used by the register allocator.
//
dag MemberList = regList;
// AltNameIndex - The alternate register name to use when printing operands
// of this register class. Every register in the register class must have
// a valid alternate name for the given index.
RegAltNameIndex altNameIndex = idx;
// isAllocatable - Specify that the register class can be used for virtual
// registers and register allocation. Some register classes are only used to
// model instruction operand constraints, and should have isAllocatable = 0.
bit isAllocatable = 1;
// AltOrders - List of alternative allocation orders. The default order is
// MemberList itself, and that is good enough for most targets since the
// register allocators automatically remove reserved registers and move
// callee-saved registers to the end.
list<dag> AltOrders = [];
// AltOrderSelect - The body of a function that selects the allocation order
// to use in a given machine function. The code will be inserted in a
// function like this:
//
// static inline unsigned f(const MachineFunction &MF) { ... }
//
// The function should return 0 to select the default order defined by
// MemberList, 1 to select the first AltOrders entry and so on.
code AltOrderSelect = [{}];
// Specify allocation priority for register allocators using a greedy
// heuristic. Classes with higher priority values are assigned first. This is
// useful as it is sometimes beneficial to assign registers to highly
// constrained classes first. The value has to be in the range [0,63].
int AllocationPriority = 0;
// The diagnostic type to present when referencing this operand in a match
// failure error message. If this is empty, the default Match_InvalidOperand
// diagnostic type will be used. If this is "<name>", a Match_<name> enum
// value will be generated and used for this operand type. The target
// assembly parser is responsible for converting this into a user-facing
// diagnostic message.
string DiagnosticType = "";
// A diagnostic message to emit when an invalid value is provided for this
// register class when it is being used an an assembly operand. If this is
// non-empty, an anonymous diagnostic type enum value will be generated, and
// the assembly matcher will provide a function to map from diagnostic types
// to message strings.
string DiagnosticString = "";
}
// The memberList in a RegisterClass is a dag of set operations. TableGen
// evaluates these set operations and expand them into register lists. These
// are the most common operation, see test/TableGen/SetTheory.td for more
// examples of what is possible:
//
// (add R0, R1, R2) - Set Union. Each argument can be an individual register, a
// register class, or a sub-expression. This is also the way to simply list
// registers.
//
// (sub GPR, SP) - Set difference. Subtract the last arguments from the first.
//
// (and GPR, CSR) - Set intersection. All registers from the first set that are
// also in the second set.
//
// (sequence "R%u", 0, 15) -> [R0, R1, ..., R15]. Generate a sequence of
// numbered registers. Takes an optional 4th operand which is a stride to use
// when generating the sequence.
//
// (shl GPR, 4) - Remove the first N elements.
//
// (trunc GPR, 4) - Truncate after the first N elements.
//
// (rotl GPR, 1) - Rotate N places to the left.
//
// (rotr GPR, 1) - Rotate N places to the right.
//
// (decimate GPR, 2) - Pick every N'th element, starting with the first.
//
// (interleave A, B, ...) - Interleave the elements from each argument list.
//
// All of these operators work on ordered sets, not lists. That means
// duplicates are removed from sub-expressions.
// Set operators. The rest is defined in TargetSelectionDAG.td.
def sequence;
def decimate;
def interleave;
// RegisterTuples - Automatically generate super-registers by forming tuples of
// sub-registers. This is useful for modeling register sequence constraints
// with pseudo-registers that are larger than the architectural registers.
//
// The sub-register lists are zipped together:
//
// def EvenOdd : RegisterTuples<[sube, subo], [(add R0, R2), (add R1, R3)]>;
//
// Generates the same registers as:
//
// let SubRegIndices = [sube, subo] in {
// def R0_R1 : RegisterWithSubRegs<"", [R0, R1]>;
// def R2_R3 : RegisterWithSubRegs<"", [R2, R3]>;
// }
//
// The generated pseudo-registers inherit super-classes and fields from their
// first sub-register. Most fields from the Register class are inferred, and
// the AsmName and Dwarf numbers are cleared.
//
// RegisterTuples instances can be used in other set operations to form
// register classes and so on. This is the only way of using the generated
// registers.
class RegisterTuples<list<SubRegIndex> Indices, list<dag> Regs> {
// SubRegs - N lists of registers to be zipped up. Super-registers are
// synthesized from the first element of each SubRegs list, the second
// element and so on.
list<dag> SubRegs = Regs;
// SubRegIndices - N SubRegIndex instances. This provides the names of the
// sub-registers in the synthesized super-registers.
list<SubRegIndex> SubRegIndices = Indices;
}
//===----------------------------------------------------------------------===//
// DwarfRegNum - This class provides a mapping of the llvm register enumeration
// to the register numbering used by gcc and gdb. These values are used by a
// debug information writer to describe where values may be located during
// execution.
class DwarfRegNum<list<int> Numbers> {
// DwarfNumbers - Numbers used internally by gcc/gdb to identify the register.
// These values can be determined by locating the <target>.h file in the
// directory llvmgcc/gcc/config/<target>/ and looking for REGISTER_NAMES. The
// order of these names correspond to the enumeration used by gcc. A value of
// -1 indicates that the gcc number is undefined and -2 that register number
// is invalid for this mode/flavour.
list<int> DwarfNumbers = Numbers;
}
// DwarfRegAlias - This class declares that a given register uses the same dwarf
// numbers as another one. This is useful for making it clear that the two
// registers do have the same number. It also lets us build a mapping
// from dwarf register number to llvm register.
class DwarfRegAlias<Register reg> {
Register DwarfAlias = reg;
}
//===----------------------------------------------------------------------===//
// Pull in the common support for scheduling
//
include "llvm/Target/TargetSchedule.td"
class Predicate; // Forward def
//===----------------------------------------------------------------------===//
// Instruction set description - These classes correspond to the C++ classes in
// the Target/TargetInstrInfo.h file.
//
class Instruction {
string Namespace = "";
dag OutOperandList; // An dag containing the MI def operand list.
dag InOperandList; // An dag containing the MI use operand list.
string AsmString = ""; // The .s format to print the instruction with.
// Pattern - Set to the DAG pattern for this instruction, if we know of one,
// otherwise, uninitialized.
list<dag> Pattern;
// The follow state will eventually be inferred automatically from the
// instruction pattern.
list<Register> Uses = []; // Default to using no non-operand registers
list<Register> Defs = []; // Default to modifying no non-operand registers
// Predicates - List of predicates which will be turned into isel matching
// code.
list<Predicate> Predicates = [];
// Size - Size of encoded instruction, or zero if the size cannot be determined
// from the opcode.
int Size = 0;
// DecoderNamespace - The "namespace" in which this instruction exists, on
// targets like ARM which multiple ISA namespaces exist.
string DecoderNamespace = "";
// Code size, for instruction selection.
// FIXME: What does this actually mean?
int CodeSize = 0;
// Added complexity passed onto matching pattern.
int AddedComplexity = 0;
// These bits capture information about the high-level semantics of the
// instruction.
bit isReturn = 0; // Is this instruction a return instruction?
bit isBranch = 0; // Is this instruction a branch instruction?
bit isIndirectBranch = 0; // Is this instruction an indirect branch?
bit isCompare = 0; // Is this instruction a comparison instruction?
bit isMoveImm = 0; // Is this instruction a move immediate instruction?
bit isBitcast = 0; // Is this instruction a bitcast instruction?
bit isSelect = 0; // Is this instruction a select instruction?
bit isBarrier = 0; // Can control flow fall through this instruction?
bit isCall = 0; // Is this instruction a call instruction?
bit isAdd = 0; // Is this instruction an add instruction?
bit canFoldAsLoad = 0; // Can this be folded as a simple memory operand?
bit mayLoad = ?; // Is it possible for this inst to read memory?
bit mayStore = ?; // Is it possible for this inst to write memory?
bit isConvertibleToThreeAddress = 0; // Can this 2-addr instruction promote?
bit isCommutable = 0; // Is this 3 operand instruction commutable?
bit isTerminator = 0; // Is this part of the terminator for a basic block?
bit isReMaterializable = 0; // Is this instruction re-materializable?
bit isPredicable = 0; // Is this instruction predicable?
bit hasDelaySlot = 0; // Does this instruction have an delay slot?
bit usesCustomInserter = 0; // Pseudo instr needing special help.
bit hasPostISelHook = 0; // To be *adjusted* after isel by target hook.
bit hasCtrlDep = 0; // Does this instruction r/w ctrl-flow chains?
bit isNotDuplicable = 0; // Is it unsafe to duplicate this instruction?
bit isConvergent = 0; // Is this instruction convergent?
bit isAsCheapAsAMove = 0; // As cheap (or cheaper) than a move instruction.
bit hasExtraSrcRegAllocReq = 0; // Sources have special regalloc requirement?
bit hasExtraDefRegAllocReq = 0; // Defs have special regalloc requirement?
bit isRegSequence = 0; // Is this instruction a kind of reg sequence?
// If so, make sure to override
// TargetInstrInfo::getRegSequenceLikeInputs.
bit isPseudo = 0; // Is this instruction a pseudo-instruction?
// If so, won't have encoding information for
// the [MC]CodeEmitter stuff.
bit isExtractSubreg = 0; // Is this instruction a kind of extract subreg?
// If so, make sure to override
// TargetInstrInfo::getExtractSubregLikeInputs.
bit isInsertSubreg = 0; // Is this instruction a kind of insert subreg?
// If so, make sure to override
// TargetInstrInfo::getInsertSubregLikeInputs.
// Does the instruction have side effects that are not captured by any
// operands of the instruction or other flags?
bit hasSideEffects = ?;
// Is this instruction a "real" instruction (with a distinct machine
// encoding), or is it a pseudo instruction used for codegen modeling
// purposes.
// FIXME: For now this is distinct from isPseudo, above, as code-gen-only
// instructions can (and often do) still have encoding information
// associated with them. Once we've migrated all of them over to true
// pseudo-instructions that are lowered to real instructions prior to
// the printer/emitter, we can remove this attribute and just use isPseudo.
//
// The intended use is:
// isPseudo: Does not have encoding information and should be expanded,
// at the latest, during lowering to MCInst.
//
// isCodeGenOnly: Does have encoding information and can go through to the
// CodeEmitter unchanged, but duplicates a canonical instruction
// definition's encoding and should be ignored when constructing the
// assembler match tables.
bit isCodeGenOnly = 0;
// Is this instruction a pseudo instruction for use by the assembler parser.
bit isAsmParserOnly = 0;
// This instruction is not expected to be queried for scheduling latencies
// and therefore needs no scheduling information even for a complete
// scheduling model.
bit hasNoSchedulingInfo = 0;
InstrItinClass Itinerary = NoItinerary;// Execution steps used for scheduling.
// Scheduling information from TargetSchedule.td.
list<SchedReadWrite> SchedRW;
string Constraints = ""; // OperandConstraint, e.g. $src = $dst.
/// DisableEncoding - List of operand names (e.g. "$op1,$op2") that should not
/// be encoded into the output machineinstr.
string DisableEncoding = "";
string PostEncoderMethod = "";
string DecoderMethod = "";
// Is the instruction decoder method able to completely determine if the
// given instruction is valid or not. If the TableGen definition of the
// instruction specifies bitpattern A??B where A and B are static bits, the
// hasCompleteDecoder flag says whether the decoder method fully handles the
// ?? space, i.e. if it is a final arbiter for the instruction validity.
// If not then the decoder attempts to continue decoding when the decoder
// method fails.
//
// This allows to handle situations where the encoding is not fully
// orthogonal. Example:
// * InstA with bitpattern 0b0000????,
// * InstB with bitpattern 0b000000?? but the associated decoder method
// DecodeInstB() returns Fail when ?? is 0b00 or 0b11.
//
// The decoder tries to decode a bitpattern that matches both InstA and
// InstB bitpatterns first as InstB (because it is the most specific
// encoding). In the default case (hasCompleteDecoder = 1), when
// DecodeInstB() returns Fail the bitpattern gets rejected. By setting
// hasCompleteDecoder = 0 in InstB, the decoder is informed that
// DecodeInstB() is not able to determine if all possible values of ?? are
// valid or not. If DecodeInstB() returns Fail the decoder will attempt to
// decode the bitpattern as InstA too.
bit hasCompleteDecoder = 1;
/// Target-specific flags. This becomes the TSFlags field in TargetInstrDesc.
bits<64> TSFlags = 0;
///@name Assembler Parser Support
///@{
string AsmMatchConverter = "";
/// TwoOperandAliasConstraint - Enable TableGen to auto-generate a
/// two-operand matcher inst-alias for a three operand instruction.
/// For example, the arm instruction "add r3, r3, r5" can be written
/// as "add r3, r5". The constraint is of the same form as a tied-operand
/// constraint. For example, "$Rn = $Rd".
string TwoOperandAliasConstraint = "";
/// Assembler variant name to use for this instruction. If specified then
/// instruction will be presented only in MatchTable for this variant. If
/// not specified then assembler variants will be determined based on
/// AsmString
string AsmVariantName = "";
///@}
/// UseNamedOperandTable - If set, the operand indices of this instruction
/// can be queried via the getNamedOperandIdx() function which is generated
/// by TableGen.
bit UseNamedOperandTable = 0;
}
/// PseudoInstExpansion - Expansion information for a pseudo-instruction.
/// Which instruction it expands to and how the operands map from the
/// pseudo.
class PseudoInstExpansion<dag Result> {
dag ResultInst = Result; // The instruction to generate.
bit isPseudo = 1;
}
/// Predicates - These are extra conditionals which are turned into instruction
/// selector matching code. Currently each predicate is just a string.
class Predicate<string cond> {
string CondString = cond;
/// AssemblerMatcherPredicate - If this feature can be used by the assembler
/// matcher, this is true. Targets should set this by inheriting their
/// feature from the AssemblerPredicate class in addition to Predicate.
bit AssemblerMatcherPredicate = 0;
/// AssemblerCondString - Name of the subtarget feature being tested used
/// as alternative condition string used for assembler matcher.
/// e.g. "ModeThumb" is translated to "(Bits & ModeThumb) != 0".
/// "!ModeThumb" is translated to "(Bits & ModeThumb) == 0".
/// It can also list multiple features separated by ",".
/// e.g. "ModeThumb,FeatureThumb2" is translated to
/// "(Bits & ModeThumb) != 0 && (Bits & FeatureThumb2) != 0".
string AssemblerCondString = "";
/// PredicateName - User-level name to use for the predicate. Mainly for use
/// in diagnostics such as missing feature errors in the asm matcher.
string PredicateName = "";
/// Setting this to '1' indicates that the predicate must be recomputed on
/// every function change. Most predicates can leave this at '0'.
///
/// Ignored by SelectionDAG, it always recomputes the predicate on every use.
bit RecomputePerFunction = 0;
}
/// NoHonorSignDependentRounding - This predicate is true if support for
/// sign-dependent-rounding is not enabled.
def NoHonorSignDependentRounding
: Predicate<"!TM.Options.HonorSignDependentRoundingFPMath()">;
class Requires<list<Predicate> preds> {
list<Predicate> Predicates = preds;
}
/// ops definition - This is just a simple marker used to identify the operand
/// list for an instruction. outs and ins are identical both syntactically and
/// semantically; they are used to define def operands and use operands to
/// improve readibility. This should be used like this:
/// (outs R32:$dst), (ins R32:$src1, R32:$src2) or something similar.
def ops;
def outs;
def ins;
/// variable_ops definition - Mark this instruction as taking a variable number
/// of operands.
def variable_ops;
/// PointerLikeRegClass - Values that are designed to have pointer width are
/// derived from this. TableGen treats the register class as having a symbolic
/// type that it doesn't know, and resolves the actual regclass to use by using
/// the TargetRegisterInfo::getPointerRegClass() hook at codegen time.
class PointerLikeRegClass<int Kind> {
int RegClassKind = Kind;
}
/// ptr_rc definition - Mark this operand as being a pointer value whose
/// register class is resolved dynamically via a callback to TargetInstrInfo.
/// FIXME: We should probably change this to a class which contain a list of
/// flags. But currently we have but one flag.
def ptr_rc : PointerLikeRegClass<0>;
/// unknown definition - Mark this operand as being of unknown type, causing
/// it to be resolved by inference in the context it is used.
class unknown_class;
def unknown : unknown_class;
/// AsmOperandClass - Representation for the kinds of operands which the target
/// specific parser can create and the assembly matcher may need to distinguish.
///
/// Operand classes are used to define the order in which instructions are
/// matched, to ensure that the instruction which gets matched for any
/// particular list of operands is deterministic.
///
/// The target specific parser must be able to classify a parsed operand into a
/// unique class which does not partially overlap with any other classes. It can
/// match a subset of some other class, in which case the super class field
/// should be defined.
class AsmOperandClass {
/// The name to use for this class, which should be usable as an enum value.
string Name = ?;
/// The super classes of this operand.
list<AsmOperandClass> SuperClasses = [];
/// The name of the method on the target specific operand to call to test
/// whether the operand is an instance of this class. If not set, this will
/// default to "isFoo", where Foo is the AsmOperandClass name. The method
/// signature should be:
/// bool isFoo() const;
string PredicateMethod = ?;
/// The name of the method on the target specific operand to call to add the
/// target specific operand to an MCInst. If not set, this will default to
/// "addFooOperands", where Foo is the AsmOperandClass name. The method
/// signature should be:
/// void addFooOperands(MCInst &Inst, unsigned N) const;
string RenderMethod = ?;
/// The name of the method on the target specific operand to call to custom
/// handle the operand parsing. This is useful when the operands do not relate
/// to immediates or registers and are very instruction specific (as flags to
/// set in a processor register, coprocessor number, ...).
string ParserMethod = ?;
// The diagnostic type to present when referencing this operand in a
// match failure error message. By default, use a generic "invalid operand"
// diagnostic. The target AsmParser maps these codes to text.
string DiagnosticType = "";
/// A diagnostic message to emit when an invalid value is provided for this
/// operand.
string DiagnosticString = "";
/// Set to 1 if this operand is optional and not always required. Typically,
/// the AsmParser will emit an error when it finishes parsing an
/// instruction if it hasn't matched all the operands yet. However, this
/// error will be suppressed if all of the remaining unmatched operands are
/// marked as IsOptional.
///
/// Optional arguments must be at the end of the operand list.
bit IsOptional = 0;
/// The name of the method on the target specific asm parser that returns the
/// default operand for this optional operand. This method is only used if
/// IsOptional == 1. If not set, this will default to "defaultFooOperands",
/// where Foo is the AsmOperandClass name. The method signature should be:
/// std::unique_ptr<MCParsedAsmOperand> defaultFooOperands() const;
string DefaultMethod = ?;
}
def ImmAsmOperand : AsmOperandClass {
let Name = "Imm";
}
/// Operand Types - These provide the built-in operand types that may be used
/// by a target. Targets can optionally provide their own operand types as
/// needed, though this should not be needed for RISC targets.
class Operand<ValueType ty> : DAGOperand {
ValueType Type = ty;
string PrintMethod = "printOperand";
string EncoderMethod = "";
bit hasCompleteDecoder = 1;
string OperandType = "OPERAND_UNKNOWN";
dag MIOperandInfo = (ops);
// MCOperandPredicate - Optionally, a code fragment operating on
// const MCOperand &MCOp, and returning a bool, to indicate if
// the value of MCOp is valid for the specific subclass of Operand
code MCOperandPredicate;
// ParserMatchClass - The "match class" that operands of this type fit
// in. Match classes are used to define the order in which instructions are
// match, to ensure that which instructions gets matched is deterministic.
//
// The target specific parser must be able to classify an parsed operand into
// a unique class, which does not partially overlap with any other classes. It
// can match a subset of some other class, in which case the AsmOperandClass
// should declare the other operand as one of its super classes.
AsmOperandClass ParserMatchClass = ImmAsmOperand;
}
class RegisterOperand<RegisterClass regclass, string pm = "printOperand">
: DAGOperand {
// RegClass - The register class of the operand.
RegisterClass RegClass = regclass;
// PrintMethod - The target method to call to print register operands of
// this type. The method normally will just use an alt-name index to look
// up the name to print. Default to the generic printOperand().
string PrintMethod = pm;
// EncoderMethod - The target method name to call to encode this register
// operand.
string EncoderMethod = "";
// ParserMatchClass - The "match class" that operands of this type fit
// in. Match classes are used to define the order in which instructions are
// match, to ensure that which instructions gets matched is deterministic.
//
// The target specific parser must be able to classify an parsed operand into
// a unique class, which does not partially overlap with any other classes. It
// can match a subset of some other class, in which case the AsmOperandClass
// should declare the other operand as one of its super classes.
AsmOperandClass ParserMatchClass;
string OperandType = "OPERAND_REGISTER";
}
let OperandType = "OPERAND_IMMEDIATE" in {
def i1imm : Operand<i1>;
def i8imm : Operand<i8>;
def i16imm : Operand<i16>;
def i32imm : Operand<i32>;
def i64imm : Operand<i64>;
def f32imm : Operand<f32>;
def f64imm : Operand<f64>;
}
// Register operands for generic instructions don't have an MVT, but do have
// constraints linking the operands (e.g. all operands of a G_ADD must
// have the same LLT).
class TypedOperand<string Ty> : Operand<untyped> {
let OperandType = Ty;
}
def type0 : TypedOperand<"OPERAND_GENERIC_0">;
def type1 : TypedOperand<"OPERAND_GENERIC_1">;
def type2 : TypedOperand<"OPERAND_GENERIC_2">;
def type3 : TypedOperand<"OPERAND_GENERIC_3">;
def type4 : TypedOperand<"OPERAND_GENERIC_4">;
def type5 : TypedOperand<"OPERAND_GENERIC_5">;
/// zero_reg definition - Special node to stand for the zero register.
///
def zero_reg;
/// All operands which the MC layer classifies as predicates should inherit from
/// this class in some manner. This is already handled for the most commonly
/// used PredicateOperand, but may be useful in other circumstances.
class PredicateOp;
/// OperandWithDefaultOps - This Operand class can be used as the parent class
/// for an Operand that needs to be initialized with a default value if
/// no value is supplied in a pattern. This class can be used to simplify the
/// pattern definitions for instructions that have target specific flags
/// encoded as immediate operands.
class OperandWithDefaultOps<ValueType ty, dag defaultops>
: Operand<ty> {
dag DefaultOps = defaultops;
}
/// PredicateOperand - This can be used to define a predicate operand for an
/// instruction. OpTypes specifies the MIOperandInfo for the operand, and
/// AlwaysVal specifies the value of this predicate when set to "always
/// execute".
class PredicateOperand<ValueType ty, dag OpTypes, dag AlwaysVal>
: OperandWithDefaultOps<ty, AlwaysVal>, PredicateOp {
let MIOperandInfo = OpTypes;
}
/// OptionalDefOperand - This is used to define a optional definition operand
/// for an instruction. DefaultOps is the register the operand represents if
/// none is supplied, e.g. zero_reg.
class OptionalDefOperand<ValueType ty, dag OpTypes, dag defaultops>
: OperandWithDefaultOps<ty, defaultops> {
let MIOperandInfo = OpTypes;
}
// InstrInfo - This class should only be instantiated once to provide parameters
// which are global to the target machine.
//
class InstrInfo {
// Target can specify its instructions in either big or little-endian formats.
// For instance, while both Sparc and PowerPC are big-endian platforms, the
// Sparc manual specifies its instructions in the format [31..0] (big), while
// PowerPC specifies them using the format [0..31] (little).
bit isLittleEndianEncoding = 0;
// The instruction properties mayLoad, mayStore, and hasSideEffects are unset
// by default, and TableGen will infer their value from the instruction
// pattern when possible.
//
// Normally, TableGen will issue an error it it can't infer the value of a
// property that hasn't been set explicitly. When guessInstructionProperties
// is set, it will guess a safe value instead.
//
// This option is a temporary migration help. It will go away.
bit guessInstructionProperties = 1;
// TableGen's instruction encoder generator has support for matching operands
// to bit-field variables both by name and by position. While matching by
// name is preferred, this is currently not possible for complex operands,
// and some targets still reply on the positional encoding rules. When
// generating a decoder for such targets, the positional encoding rules must
// be used by the decoder generator as well.
//
// This option is temporary; it will go away once the TableGen decoder
// generator has better support for complex operands and targets have
// migrated away from using positionally encoded operands.
bit decodePositionallyEncodedOperands = 0;
// When set, this indicates that there will be no overlap between those
// operands that are matched by ordering (positional operands) and those
// matched by name.
//
// This option is temporary; it will go away once the TableGen decoder
// generator has better support for complex operands and targets have
// migrated away from using positionally encoded operands.
bit noNamedPositionallyEncodedOperands = 0;
}
// Standard Pseudo Instructions.
// This list must match TargetOpcodes.h and CodeGenTarget.cpp.
// Only these instructions are allowed in the TargetOpcode namespace.
let isCodeGenOnly = 1, isPseudo = 1, hasNoSchedulingInfo = 1,
Namespace = "TargetOpcode" in {
def PHI : Instruction {
let OutOperandList = (outs unknown:$dst);
let InOperandList = (ins variable_ops);
let AsmString = "PHINODE";
}
def INLINEASM : Instruction {
let OutOperandList = (outs);
let InOperandList = (ins variable_ops);
let AsmString = "";
let hasSideEffects = 0; // Note side effect is encoded in an operand.
}
def CFI_INSTRUCTION : Instruction {
let OutOperandList = (outs);
let InOperandList = (ins i32imm:$id);
let AsmString = "";
let hasCtrlDep = 1;
let isNotDuplicable = 1;
}
def EH_LABEL : Instruction {
let OutOperandList = (outs);
let InOperandList = (ins i32imm:$id);
let AsmString = "";
let hasCtrlDep = 1;
let isNotDuplicable = 1;
}
def GC_LABEL : Instruction {
let OutOperandList = (outs);
let InOperandList = (ins i32imm:$id);
let AsmString = "";
let hasCtrlDep = 1;
let isNotDuplicable = 1;
}
def ANNOTATION_LABEL : Instruction {
let OutOperandList = (outs);
let InOperandList = (ins i32imm:$id);
let AsmString = "";
let hasCtrlDep = 1;
let isNotDuplicable = 1;
}
def KILL : Instruction {
let OutOperandList = (outs);
let InOperandList = (ins variable_ops);
let AsmString = "";
let hasSideEffects = 0;
}
def EXTRACT_SUBREG : Instruction {
let OutOperandList = (outs unknown:$dst);
let InOperandList = (ins unknown:$supersrc, i32imm:$subidx);
let AsmString = "";
let hasSideEffects = 0;
}
def INSERT_SUBREG : Instruction {
let OutOperandList = (outs unknown:$dst);
let InOperandList = (ins unknown:$supersrc, unknown:$subsrc, i32imm:$subidx);
let AsmString = "";
let hasSideEffects = 0;
let Constraints = "$supersrc = $dst";
}
def IMPLICIT_DEF : Instruction {
let OutOperandList = (outs unknown:$dst);
let InOperandList = (ins);
let AsmString = "";
let hasSideEffects = 0;
let isReMaterializable = 1;
let isAsCheapAsAMove = 1;
}
def SUBREG_TO_REG : Instruction {
let OutOperandList = (outs unknown:$dst);
let InOperandList = (ins unknown:$implsrc, unknown:$subsrc, i32imm:$subidx);
let AsmString = "";
let hasSideEffects = 0;
}
def COPY_TO_REGCLASS : Instruction {
let OutOperandList = (outs unknown:$dst);
let InOperandList = (ins unknown:$src, i32imm:$regclass);
let AsmString = "";
let hasSideEffects = 0;
let isAsCheapAsAMove = 1;
}
def DBG_VALUE : Instruction {
let OutOperandList = (outs);
let InOperandList = (ins variable_ops);
let AsmString = "DBG_VALUE";
let hasSideEffects = 0;
}
def REG_SEQUENCE : Instruction {
let OutOperandList = (outs unknown:$dst);
let InOperandList = (ins unknown:$supersrc, variable_ops);
let AsmString = "";
let hasSideEffects = 0;
let isAsCheapAsAMove = 1;
}
def COPY : Instruction {
let OutOperandList = (outs unknown:$dst);
let InOperandList = (ins unknown:$src);
let AsmString = "";
let hasSideEffects = 0;
let isAsCheapAsAMove = 1;
let hasNoSchedulingInfo = 0;
}
def BUNDLE : Instruction {
let OutOperandList = (outs);
let InOperandList = (ins variable_ops);
let AsmString = "BUNDLE";
}
def LIFETIME_START : Instruction {
let OutOperandList = (outs);
let InOperandList = (ins i32imm:$id);
let AsmString = "LIFETIME_START";
let hasSideEffects = 0;
}
def LIFETIME_END : Instruction {
let OutOperandList = (outs);
let InOperandList = (ins i32imm:$id);
let AsmString = "LIFETIME_END";
let hasSideEffects = 0;
}
def STACKMAP : Instruction {
let OutOperandList = (outs);
let InOperandList = (ins i64imm:$id, i32imm:$nbytes, variable_ops);
let isCall = 1;
let mayLoad = 1;
let usesCustomInserter = 1;
}
def PATCHPOINT : Instruction {
let OutOperandList = (outs unknown:$dst);
let InOperandList = (ins i64imm:$id, i32imm:$nbytes, unknown:$callee,
i32imm:$nargs, i32imm:$cc, variable_ops);
let isCall = 1;
let mayLoad = 1;
let usesCustomInserter = 1;
}
def STATEPOINT : Instruction {
let OutOperandList = (outs);
let InOperandList = (ins variable_ops);
let usesCustomInserter = 1;
let mayLoad = 1;
let mayStore = 1;
let hasSideEffects = 1;
let isCall = 1;
}
def LOAD_STACK_GUARD : Instruction {
let OutOperandList = (outs ptr_rc:$dst);
let InOperandList = (ins);
let mayLoad = 1;
bit isReMaterializable = 1;
let hasSideEffects = 0;
bit isPseudo = 1;
}
def LOCAL_ESCAPE : Instruction {
// This instruction is really just a label. It has to be part of the chain so
// that it doesn't get dropped from the DAG, but it produces nothing and has
// no side effects.
let OutOperandList = (outs);
let InOperandList = (ins ptr_rc:$symbol, i32imm:$id);
let hasSideEffects = 0;
let hasCtrlDep = 1;
}
def FAULTING_OP : Instruction {
let OutOperandList = (outs unknown:$dst);
let InOperandList = (ins variable_ops);
let usesCustomInserter = 1;
let mayLoad = 1;
let mayStore = 1;
let isTerminator = 1;
let isBranch = 1;
}
def PATCHABLE_OP : Instruction {
let OutOperandList = (outs unknown:$dst);
let InOperandList = (ins variable_ops);
let usesCustomInserter = 1;
let mayLoad = 1;
let mayStore = 1;
let hasSideEffects = 1;
}
def PATCHABLE_FUNCTION_ENTER : Instruction {
let OutOperandList = (outs);
let InOperandList = (ins);
let AsmString = "# XRay Function Enter.";
let usesCustomInserter = 1;
let hasSideEffects = 0;
}
def PATCHABLE_RET : Instruction {
let OutOperandList = (outs unknown:$dst);
let InOperandList = (ins variable_ops);
let AsmString = "# XRay Function Patchable RET.";
let usesCustomInserter = 1;
let hasSideEffects = 1;
let isTerminator = 1;
let isReturn = 1;
}
def PATCHABLE_FUNCTION_EXIT : Instruction {
let OutOperandList = (outs);
let InOperandList = (ins);
let AsmString = "# XRay Function Exit.";
let usesCustomInserter = 1;
let hasSideEffects = 0; // FIXME: is this correct?
let isReturn = 0; // Original return instruction will follow
}
def PATCHABLE_TAIL_CALL : Instruction {
let OutOperandList = (outs unknown:$dst);
let InOperandList = (ins variable_ops);
let AsmString = "# XRay Tail Call Exit.";
let usesCustomInserter = 1;
let hasSideEffects = 1;
let isReturn = 1;
}
def PATCHABLE_EVENT_CALL : Instruction {
let OutOperandList = (outs);
let InOperandList = (ins ptr_rc:$event, i8imm:$size);
let AsmString = "# XRay Custom Event Log.";
let usesCustomInserter = 1;
let isCall = 1;
let mayLoad = 1;
let mayStore = 1;
let hasSideEffects = 1;
}
def FENTRY_CALL : Instruction {
let OutOperandList = (outs unknown:$dst);
let InOperandList = (ins variable_ops);
let AsmString = "# FEntry call";
let usesCustomInserter = 1;
let mayLoad = 1;
let mayStore = 1;
let hasSideEffects = 1;
}
// Generic opcodes used in GlobalISel.
include "llvm/Target/GenericOpcodes.td"
}
//===----------------------------------------------------------------------===//
// AsmParser - This class can be implemented by targets that wish to implement
// .s file parsing.
//
// Subtargets can have multiple different assembly parsers (e.g. AT&T vs Intel
// syntax on X86 for example).
//
class AsmParser {
// AsmParserClassName - This specifies the suffix to use for the asmparser
// class. Generated AsmParser classes are always prefixed with the target
// name.
string AsmParserClassName = "AsmParser";
// AsmParserInstCleanup - If non-empty, this is the name of a custom member
// function of the AsmParser class to call on every matched instruction.
// This can be used to perform target specific instruction post-processing.
string AsmParserInstCleanup = "";
// ShouldEmitMatchRegisterName - Set to false if the target needs a hand
// written register name matcher
bit ShouldEmitMatchRegisterName = 1;
// Set to true if the target needs a generated 'alternative register name'
// matcher.
//
// This generates a function which can be used to lookup registers from
// their aliases. This function will fail when called on targets where
// several registers share the same alias (i.e. not a 1:1 mapping).
bit ShouldEmitMatchRegisterAltName = 0;
// HasMnemonicFirst - Set to false if target instructions don't always
// start with a mnemonic as the first token.
bit HasMnemonicFirst = 1;
// ReportMultipleNearMisses -
// When 0, the assembly matcher reports an error for one encoding or operand
// that did not match the parsed instruction.
// When 1, the assmebly matcher returns a list of encodings that were close
// to matching the parsed instruction, so to allow more detailed error
// messages.
bit ReportMultipleNearMisses = 0;
}
def DefaultAsmParser : AsmParser;
//===----------------------------------------------------------------------===//
// AsmParserVariant - Subtargets can have multiple different assembly parsers
// (e.g. AT&T vs Intel syntax on X86 for example). This class can be
// implemented by targets to describe such variants.
//
class AsmParserVariant {
// Variant - AsmParsers can be of multiple different variants. Variants are
// used to support targets that need to parser multiple formats for the
// assembly language.
int Variant = 0;
// Name - The AsmParser variant name (e.g., AT&T vs Intel).
string Name = "";
// CommentDelimiter - If given, the delimiter string used to recognize
// comments which are hard coded in the .td assembler strings for individual
// instructions.
string CommentDelimiter = "";
// RegisterPrefix - If given, the token prefix which indicates a register
// token. This is used by the matcher to automatically recognize hard coded
// register tokens as constrained registers, instead of tokens, for the
// purposes of matching.
string RegisterPrefix = "";
// TokenizingCharacters - Characters that are standalone tokens
string TokenizingCharacters = "[]*!";
// SeparatorCharacters - Characters that are not tokens
string SeparatorCharacters = " \t,";
// BreakCharacters - Characters that start new identifiers
string BreakCharacters = "";
}
def DefaultAsmParserVariant : AsmParserVariant;
/// AssemblerPredicate - This is a Predicate that can be used when the assembler
/// matches instructions and aliases.
class AssemblerPredicate<string cond, string name = ""> {
bit AssemblerMatcherPredicate = 1;
string AssemblerCondString = cond;
string PredicateName = name;
}
/// TokenAlias - This class allows targets to define assembler token
/// operand aliases. That is, a token literal operand which is equivalent
/// to another, canonical, token literal. For example, ARM allows:
/// vmov.u32 s4, #0 -> vmov.i32, #0
/// 'u32' is a more specific designator for the 32-bit integer type specifier
/// and is legal for any instruction which accepts 'i32' as a datatype suffix.
/// def : TokenAlias<".u32", ".i32">;
///
/// This works by marking the match class of 'From' as a subclass of the
/// match class of 'To'.
class TokenAlias<string From, string To> {
string FromToken = From;
string ToToken = To;
}
/// MnemonicAlias - This class allows targets to define assembler mnemonic
/// aliases. This should be used when all forms of one mnemonic are accepted
/// with a different mnemonic. For example, X86 allows:
/// sal %al, 1 -> shl %al, 1
/// sal %ax, %cl -> shl %ax, %cl
/// sal %eax, %cl -> shl %eax, %cl
/// etc. Though "sal" is accepted with many forms, all of them are directly
/// translated to a shl, so it can be handled with (in the case of X86, it
/// actually has one for each suffix as well):
/// def : MnemonicAlias<"sal", "shl">;
///
/// Mnemonic aliases are mapped before any other translation in the match phase,
/// and do allow Requires predicates, e.g.:
///
/// def : MnemonicAlias<"pushf", "pushfq">, Requires<[In64BitMode]>;
/// def : MnemonicAlias<"pushf", "pushfl">, Requires<[In32BitMode]>;
///
/// Mnemonic aliases can also be constrained to specific variants, e.g.:
///
/// def : MnemonicAlias<"pushf", "pushfq", "att">, Requires<[In64BitMode]>;
///
/// If no variant (e.g., "att" or "intel") is specified then the alias is
/// applied unconditionally.
class MnemonicAlias<string From, string To, string VariantName = ""> {
string FromMnemonic = From;
string ToMnemonic = To;
string AsmVariantName = VariantName;
// Predicates - Predicates that must be true for this remapping to happen.
list<Predicate> Predicates = [];
}
/// InstAlias - This defines an alternate assembly syntax that is allowed to
/// match an instruction that has a different (more canonical) assembly
/// representation.
class InstAlias<string Asm, dag Result, int Emit = 1> {
string AsmString = Asm; // The .s format to match the instruction with.
dag ResultInst = Result; // The MCInst to generate.
// This determines which order the InstPrinter detects aliases for
// printing. A larger value makes the alias more likely to be
// emitted. The Instruction's own definition is notionally 0.5, so 0
// disables printing and 1 enables it if there are no conflicting aliases.
int EmitPriority = Emit;
// Predicates - Predicates that must be true for this to match.
list<Predicate> Predicates = [];
// If the instruction specified in Result has defined an AsmMatchConverter
// then setting this to 1 will cause the alias to use the AsmMatchConverter
// function when converting the OperandVector into an MCInst instead of the
// function that is generated by the dag Result.
// Setting this to 0 will cause the alias to ignore the Result instruction's
// defined AsmMatchConverter and instead use the function generated by the
// dag Result.
bit UseInstAsmMatchConverter = 1;
// Assembler variant name to use for this alias. If not specified then
// assembler variants will be determined based on AsmString
string AsmVariantName = "";
}
//===----------------------------------------------------------------------===//
// AsmWriter - This class can be implemented by targets that need to customize
// the format of the .s file writer.
//
// Subtargets can have multiple different asmwriters (e.g. AT&T vs Intel syntax
// on X86 for example).
//
class AsmWriter {
// AsmWriterClassName - This specifies the suffix to use for the asmwriter
// class. Generated AsmWriter classes are always prefixed with the target
// name.
string AsmWriterClassName = "InstPrinter";
// PassSubtarget - Determines whether MCSubtargetInfo should be passed to
// the various print methods.
// FIXME: Remove after all ports are updated.
int PassSubtarget = 0;
// Variant - AsmWriters can be of multiple different variants. Variants are
// used to support targets that need to emit assembly code in ways that are
// mostly the same for different targets, but have minor differences in
// syntax. If the asmstring contains {|} characters in them, this integer
// will specify which alternative to use. For example "{x|y|z}" with Variant
// == 1, will expand to "y".
int Variant = 0;
}
def DefaultAsmWriter : AsmWriter;
//===----------------------------------------------------------------------===//
// Target - This class contains the "global" target information
//
class Target {
// InstructionSet - Instruction set description for this target.
InstrInfo InstructionSet;
// AssemblyParsers - The AsmParser instances available for this target.
list<AsmParser> AssemblyParsers = [DefaultAsmParser];
/// AssemblyParserVariants - The AsmParserVariant instances available for
/// this target.
list<AsmParserVariant> AssemblyParserVariants = [DefaultAsmParserVariant];
// AssemblyWriters - The AsmWriter instances available for this target.
list<AsmWriter> AssemblyWriters = [DefaultAsmWriter];
}
//===----------------------------------------------------------------------===//
// SubtargetFeature - A characteristic of the chip set.
//
class SubtargetFeature<string n, string a, string v, string d,
list<SubtargetFeature> i = []> {
// Name - Feature name. Used by command line (-mattr=) to determine the
// appropriate target chip.
//
string Name = n;
// Attribute - Attribute to be set by feature.
//
string Attribute = a;
// Value - Value the attribute to be set to by feature.
//
string Value = v;
// Desc - Feature description. Used by command line (-mattr=) to display help
// information.
//
string Desc = d;
// Implies - Features that this feature implies are present. If one of those
// features isn't set, then this one shouldn't be set either.
//
list<SubtargetFeature> Implies = i;
}
/// Specifies a Subtarget feature that this instruction is deprecated on.
class Deprecated<SubtargetFeature dep> {
SubtargetFeature DeprecatedFeatureMask = dep;
}
/// A custom predicate used to determine if an instruction is
/// deprecated or not.
class ComplexDeprecationPredicate<string dep> {
string ComplexDeprecationPredicate = dep;
}
//===----------------------------------------------------------------------===//
// Processor chip sets - These values represent each of the chip sets supported
// by the scheduler. Each Processor definition requires corresponding
// instruction itineraries.
//
class Processor<string n, ProcessorItineraries pi, list<SubtargetFeature> f> {
// Name - Chip set name. Used by command line (-mcpu=) to determine the
// appropriate target chip.
//
string Name = n;
// SchedModel - The machine model for scheduling and instruction cost.
//
SchedMachineModel SchedModel = NoSchedModel;
// ProcItin - The scheduling information for the target processor.
//
ProcessorItineraries ProcItin = pi;
// Features - list of
list<SubtargetFeature> Features = f;
}
// ProcessorModel allows subtargets to specify the more general
// SchedMachineModel instead if a ProcessorItinerary. Subtargets will
// gradually move to this newer form.
//
// Although this class always passes NoItineraries to the Processor
// class, the SchedMachineModel may still define valid Itineraries.
class ProcessorModel<string n, SchedMachineModel m, list<SubtargetFeature> f>
: Processor<n, NoItineraries, f> {
let SchedModel = m;
}
//===----------------------------------------------------------------------===//
// InstrMapping - This class is used to create mapping tables to relate
// instructions with each other based on the values specified in RowFields,
// ColFields, KeyCol and ValueCols.
//
class InstrMapping {
// FilterClass - Used to limit search space only to the instructions that
// define the relationship modeled by this InstrMapping record.
string FilterClass;
// RowFields - List of fields/attributes that should be same for all the
// instructions in a row of the relation table. Think of this as a set of
// properties shared by all the instructions related by this relationship
// model and is used to categorize instructions into subgroups. For instance,
// if we want to define a relation that maps 'Add' instruction to its
// predicated forms, we can define RowFields like this:
//
// let RowFields = BaseOp
// All add instruction predicated/non-predicated will have to set their BaseOp
// to the same value.
//
// def Add: { let BaseOp = 'ADD'; let predSense = 'nopred' }
// def Add_predtrue: { let BaseOp = 'ADD'; let predSense = 'true' }
// def Add_predfalse: { let BaseOp = 'ADD'; let predSense = 'false' }
list<string> RowFields = [];
// List of fields/attributes that are same for all the instructions
// in a column of the relation table.
// Ex: let ColFields = 'predSense' -- It means that the columns are arranged
// based on the 'predSense' values. All the instruction in a specific
// column have the same value and it is fixed for the column according
// to the values set in 'ValueCols'.
list<string> ColFields = [];
// Values for the fields/attributes listed in 'ColFields'.
// Ex: let KeyCol = 'nopred' -- It means that the key instruction (instruction
// that models this relation) should be non-predicated.
// In the example above, 'Add' is the key instruction.
list<string> KeyCol = [];
// List of values for the fields/attributes listed in 'ColFields', one for
// each column in the relation table.
//
// Ex: let ValueCols = [['true'],['false']] -- It adds two columns in the
// table. First column requires all the instructions to have predSense
// set to 'true' and second column requires it to be 'false'.
list<list<string> > ValueCols = [];
}
//===----------------------------------------------------------------------===//
// Pull in the common support for calling conventions.
//
include "llvm/Target/TargetCallingConv.td"
//===----------------------------------------------------------------------===//
// Pull in the common support for DAG isel generation.
//
include "llvm/Target/TargetSelectionDAG.td"
//===----------------------------------------------------------------------===//
// Pull in the common support for Global ISel register bank info generation.
//
include "llvm/Target/GlobalISel/RegisterBank.td"
//===----------------------------------------------------------------------===//
// Pull in the common support for DAG isel generation.
//
include "llvm/Target/GlobalISel/Target.td"
//===----------------------------------------------------------------------===//
// Pull in the common support for the Global ISel DAG-based selector generation.
//
include "llvm/Target/GlobalISel/SelectionDAGCompat.td"