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llvm-mirror/include/llvm/IR/Intrinsics.td
Daniel Neilson f59acc15ad Remove alignment argument from memcpy/memmove/memset in favour of alignment attributes (Step 1) 
Summary:
 This is a resurrection of work first proposed and discussed in Aug 2015:
   http://lists.llvm.org/pipermail/llvm-dev/2015-August/089384.html
and initially landed (but then backed out) in Nov 2015:
   http://lists.llvm.org/pipermail/llvm-commits/Week-of-Mon-20151109/312083.html

 The @llvm.memcpy/memmove/memset intrinsics currently have an explicit argument
which is required to be a constant integer. It represents the alignment of the
dest (and source), and so must be the minimum of the actual alignment of the
two.

 This change is the first in a series that allows source and dest to each
have their own alignments by using the alignment attribute on their arguments.

 In this change we:
1) Remove the alignment argument.
2) Add alignment attributes to the source & dest arguments. We, temporarily,
   require that the alignments for source & dest be equal.

 For example, code which used to read:
  call void @llvm.memcpy.p0i8.p0i8.i32(i8* %dest, i8* %src, i32 100, i32 4, i1 false)
will now read
  call void @llvm.memcpy.p0i8.p0i8.i32(i8* align 4 %dest, i8* align 4 %src, i32 100, i1 false)

 Downstream users may have to update their lit tests that check for
@llvm.memcpy/memmove/memset call/declaration patterns. The following extended sed script
may help with updating the majority of your tests, but it does not catch all possible
patterns so some manual checking and updating will be required.

s~declare void @llvm\.mem(set|cpy|move)\.p([^(]*)\((.*), i32, i1\)~declare void @llvm.mem\1.p\2(\3, i1)~g
s~call void @llvm\.memset\.p([^(]*)i8\(i8([^*]*)\* (.*), i8 (.*), i8 (.*), i32 [01], i1 ([^)]*)\)~call void @llvm.memset.p\1i8(i8\2* \3, i8 \4, i8 \5, i1 \6)~g
s~call void @llvm\.memset\.p([^(]*)i16\(i8([^*]*)\* (.*), i8 (.*), i16 (.*), i32 [01], i1 ([^)]*)\)~call void @llvm.memset.p\1i16(i8\2* \3, i8 \4, i16 \5, i1 \6)~g
s~call void @llvm\.memset\.p([^(]*)i32\(i8([^*]*)\* (.*), i8 (.*), i32 (.*), i32 [01], i1 ([^)]*)\)~call void @llvm.memset.p\1i32(i8\2* \3, i8 \4, i32 \5, i1 \6)~g
s~call void @llvm\.memset\.p([^(]*)i64\(i8([^*]*)\* (.*), i8 (.*), i64 (.*), i32 [01], i1 ([^)]*)\)~call void @llvm.memset.p\1i64(i8\2* \3, i8 \4, i64 \5, i1 \6)~g
s~call void @llvm\.memset\.p([^(]*)i128\(i8([^*]*)\* (.*), i8 (.*), i128 (.*), i32 [01], i1 ([^)]*)\)~call void @llvm.memset.p\1i128(i8\2* \3, i8 \4, i128 \5, i1 \6)~g
s~call void @llvm\.memset\.p([^(]*)i8\(i8([^*]*)\* (.*), i8 (.*), i8 (.*), i32 ([0-9]*), i1 ([^)]*)\)~call void @llvm.memset.p\1i8(i8\2* align \6 \3, i8 \4, i8 \5, i1 \7)~g
s~call void @llvm\.memset\.p([^(]*)i16\(i8([^*]*)\* (.*), i8 (.*), i16 (.*), i32 ([0-9]*), i1 ([^)]*)\)~call void @llvm.memset.p\1i16(i8\2* align \6 \3, i8 \4, i16 \5, i1 \7)~g
s~call void @llvm\.memset\.p([^(]*)i32\(i8([^*]*)\* (.*), i8 (.*), i32 (.*), i32 ([0-9]*), i1 ([^)]*)\)~call void @llvm.memset.p\1i32(i8\2* align \6 \3, i8 \4, i32 \5, i1 \7)~g
s~call void @llvm\.memset\.p([^(]*)i64\(i8([^*]*)\* (.*), i8 (.*), i64 (.*), i32 ([0-9]*), i1 ([^)]*)\)~call void @llvm.memset.p\1i64(i8\2* align \6 \3, i8 \4, i64 \5, i1 \7)~g
s~call void @llvm\.memset\.p([^(]*)i128\(i8([^*]*)\* (.*), i8 (.*), i128 (.*), i32 ([0-9]*), i1 ([^)]*)\)~call void @llvm.memset.p\1i128(i8\2* align \6 \3, i8 \4, i128 \5, i1 \7)~g
s~call void @llvm\.mem(cpy|move)\.p([^(]*)i8\(i8([^*]*)\* (.*), i8([^*]*)\* (.*), i8 (.*), i32 [01], i1 ([^)]*)\)~call void @llvm.mem\1.p\2i8(i8\3* \4, i8\5* \6, i8 \7, i1 \8)~g
s~call void @llvm\.mem(cpy|move)\.p([^(]*)i16\(i8([^*]*)\* (.*), i8([^*]*)\* (.*), i16 (.*), i32 [01], i1 ([^)]*)\)~call void @llvm.mem\1.p\2i16(i8\3* \4, i8\5* \6, i16 \7, i1 \8)~g
s~call void @llvm\.mem(cpy|move)\.p([^(]*)i32\(i8([^*]*)\* (.*), i8([^*]*)\* (.*), i32 (.*), i32 [01], i1 ([^)]*)\)~call void @llvm.mem\1.p\2i32(i8\3* \4, i8\5* \6, i32 \7, i1 \8)~g
s~call void @llvm\.mem(cpy|move)\.p([^(]*)i64\(i8([^*]*)\* (.*), i8([^*]*)\* (.*), i64 (.*), i32 [01], i1 ([^)]*)\)~call void @llvm.mem\1.p\2i64(i8\3* \4, i8\5* \6, i64 \7, i1 \8)~g
s~call void @llvm\.mem(cpy|move)\.p([^(]*)i128\(i8([^*]*)\* (.*), i8([^*]*)\* (.*), i128 (.*), i32 [01], i1 ([^)]*)\)~call void @llvm.mem\1.p\2i128(i8\3* \4, i8\5* \6, i128 \7, i1 \8)~g
s~call void @llvm\.mem(cpy|move)\.p([^(]*)i8\(i8([^*]*)\* (.*), i8([^*]*)\* (.*), i8 (.*), i32 ([0-9]*), i1 ([^)]*)\)~call void @llvm.mem\1.p\2i8(i8\3* align \8 \4, i8\5* align \8 \6, i8 \7, i1 \9)~g
s~call void @llvm\.mem(cpy|move)\.p([^(]*)i16\(i8([^*]*)\* (.*), i8([^*]*)\* (.*), i16 (.*), i32 ([0-9]*), i1 ([^)]*)\)~call void @llvm.mem\1.p\2i16(i8\3* align \8 \4, i8\5* align \8 \6, i16 \7, i1 \9)~g
s~call void @llvm\.mem(cpy|move)\.p([^(]*)i32\(i8([^*]*)\* (.*), i8([^*]*)\* (.*), i32 (.*), i32 ([0-9]*), i1 ([^)]*)\)~call void @llvm.mem\1.p\2i32(i8\3* align \8 \4, i8\5* align \8 \6, i32 \7, i1 \9)~g
s~call void @llvm\.mem(cpy|move)\.p([^(]*)i64\(i8([^*]*)\* (.*), i8([^*]*)\* (.*), i64 (.*), i32 ([0-9]*), i1 ([^)]*)\)~call void @llvm.mem\1.p\2i64(i8\3* align \8 \4, i8\5* align \8 \6, i64 \7, i1 \9)~g
s~call void @llvm\.mem(cpy|move)\.p([^(]*)i128\(i8([^*]*)\* (.*), i8([^*]*)\* (.*), i128 (.*), i32 ([0-9]*), i1 ([^)]*)\)~call void @llvm.mem\1.p\2i128(i8\3* align \8 \4, i8\5* align \8 \6, i128 \7, i1 \9)~g

 The remaining changes in the series will:
Step 2) Expand the IRBuilder API to allow creation of memcpy/memmove with differing
   source and dest alignments.
Step 3) Update Clang to use the new IRBuilder API.
Step 4) Update Polly to use the new IRBuilder API.
Step 5) Update LLVM passes that create memcpy/memmove calls to use the new IRBuilder API,
        and those that use use MemIntrinsicInst::[get|set]Alignment() to use
        getDestAlignment() and getSourceAlignment() instead.
Step 6) Remove the single-alignment IRBuilder API for memcpy/memmove, and the
        MemIntrinsicInst::[get|set]Alignment() methods.

Reviewers: pete, hfinkel, lhames, reames, bollu

Reviewed By: reames

Subscribers: niosHD, reames, jholewinski, qcolombet, jfb, sanjoy, arsenm, dschuff, dylanmckay, mehdi_amini, sdardis, nemanjai, david2050, nhaehnle, javed.absar, sbc100, jgravelle-google, eraman, aheejin, kbarton, JDevlieghere, asb, rbar, johnrusso, simoncook, jordy.potman.lists, apazos, sabuasal, llvm-commits

Differential Revision: https://reviews.llvm.org/D41675

llvm-svn: 322965
2018-01-19 17:13:12 +00:00

982 lines
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TableGen
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//===- Intrinsics.td - Defines all LLVM intrinsics ---------*- 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 properties of all LLVM intrinsics.
//
//===----------------------------------------------------------------------===//
include "llvm/CodeGen/ValueTypes.td"
include "llvm/CodeGen/SDNodeProperties.td"
//===----------------------------------------------------------------------===//
// Properties we keep track of for intrinsics.
//===----------------------------------------------------------------------===//
class IntrinsicProperty;
// Intr*Mem - Memory properties. If no property is set, the worst case
// is assumed (it may read and write any memory it can get access to and it may
// have other side effects).
// IntrNoMem - The intrinsic does not access memory or have any other side
// effects. It may be CSE'd deleted if dead, etc.
def IntrNoMem : IntrinsicProperty;
// IntrReadMem - This intrinsic only reads from memory. It does not write to
// memory and has no other side effects. Therefore, it cannot be moved across
// potentially aliasing stores. However, it can be reordered otherwise and can
// be deleted if dead.
def IntrReadMem : IntrinsicProperty;
// IntrWriteMem - This intrinsic only writes to memory, but does not read from
// memory, and has no other side effects. This means dead stores before calls
// to this intrinsics may be removed.
def IntrWriteMem : IntrinsicProperty;
// IntrArgMemOnly - This intrinsic only accesses memory that its pointer-typed
// argument(s) points to, but may access an unspecified amount. Other than
// reads from and (possibly volatile) writes to memory, it has no side effects.
def IntrArgMemOnly : IntrinsicProperty;
// IntrInaccessibleMemOnly -- This intrinsic only accesses memory that is not
// accessible by the module being compiled. This is a weaker form of IntrNoMem.
def IntrInaccessibleMemOnly : IntrinsicProperty;
// IntrInaccessibleMemOrArgMemOnly -- This intrinsic only accesses memory that
// its pointer-typed arguments point to or memory that is not accessible
// by the module being compiled. This is a weaker form of IntrArgMemOnly.
def IntrInaccessibleMemOrArgMemOnly : IntrinsicProperty;
// Commutative - This intrinsic is commutative: X op Y == Y op X.
def Commutative : IntrinsicProperty;
// Throws - This intrinsic can throw.
def Throws : IntrinsicProperty;
// NoCapture - The specified argument pointer is not captured by the intrinsic.
class NoCapture<int argNo> : IntrinsicProperty {
int ArgNo = argNo;
}
// Returned - The specified argument is always the return value of the
// intrinsic.
class Returned<int argNo> : IntrinsicProperty {
int ArgNo = argNo;
}
// ReadOnly - The specified argument pointer is not written to through the
// pointer by the intrinsic.
class ReadOnly<int argNo> : IntrinsicProperty {
int ArgNo = argNo;
}
// WriteOnly - The intrinsic does not read memory through the specified
// argument pointer.
class WriteOnly<int argNo> : IntrinsicProperty {
int ArgNo = argNo;
}
// ReadNone - The specified argument pointer is not dereferenced by the
// intrinsic.
class ReadNone<int argNo> : IntrinsicProperty {
int ArgNo = argNo;
}
def IntrNoReturn : IntrinsicProperty;
// IntrNoduplicate - Calls to this intrinsic cannot be duplicated.
// Parallels the noduplicate attribute on LLVM IR functions.
def IntrNoDuplicate : IntrinsicProperty;
// IntrConvergent - Calls to this intrinsic are convergent and may not be made
// control-dependent on any additional values.
// Parallels the convergent attribute on LLVM IR functions.
def IntrConvergent : IntrinsicProperty;
// This property indicates that the intrinsic is safe to speculate.
def IntrSpeculatable : IntrinsicProperty;
// This property can be used to override the 'has no other side effects'
// language of the IntrNoMem, IntrReadMem, IntrWriteMem, and IntrArgMemOnly
// intrinsic properties. By default, intrinsics are assumed to have side
// effects, so this property is only necessary if you have defined one of
// the memory properties listed above.
// For this property, 'side effects' has the same meaning as 'side effects'
// defined by the hasSideEffects property of the TableGen Instruction class.
def IntrHasSideEffects : IntrinsicProperty;
//===----------------------------------------------------------------------===//
// Types used by intrinsics.
//===----------------------------------------------------------------------===//
class LLVMType<ValueType vt> {
ValueType VT = vt;
}
class LLVMQualPointerType<LLVMType elty, int addrspace>
: LLVMType<iPTR>{
LLVMType ElTy = elty;
int AddrSpace = addrspace;
}
class LLVMPointerType<LLVMType elty>
: LLVMQualPointerType<elty, 0>;
class LLVMAnyPointerType<LLVMType elty>
: LLVMType<iPTRAny>{
LLVMType ElTy = elty;
}
// Match the type of another intrinsic parameter. Number is an index into the
// list of overloaded types for the intrinsic, excluding all the fixed types.
// The Number value must refer to a previously listed type. For example:
// Intrinsic<[llvm_i32_ty], [llvm_i32_ty, llvm_anyfloat_ty, LLVMMatchType<0>]>
// has two overloaded types, the 2nd and 3rd arguments. LLVMMatchType<0>
// refers to the first overloaded type, which is the 2nd argument.
class LLVMMatchType<int num>
: LLVMType<OtherVT>{
int Number = num;
}
// Match the type of another intrinsic parameter that is expected to be based on
// an integral type (i.e. either iN or <N x iM>), but change the scalar size to
// be twice as wide or half as wide as the other type. This is only useful when
// the intrinsic is overloaded, so the matched type should be declared as iAny.
class LLVMExtendedType<int num> : LLVMMatchType<num>;
class LLVMTruncatedType<int num> : LLVMMatchType<num>;
class LLVMVectorSameWidth<int num, LLVMType elty>
: LLVMMatchType<num> {
ValueType ElTy = elty.VT;
}
class LLVMPointerTo<int num> : LLVMMatchType<num>;
class LLVMPointerToElt<int num> : LLVMMatchType<num>;
class LLVMVectorOfAnyPointersToElt<int num> : LLVMMatchType<num>;
// Match the type of another intrinsic parameter that is expected to be a
// vector type, but change the element count to be half as many
class LLVMHalfElementsVectorType<int num> : LLVMMatchType<num>;
def llvm_void_ty : LLVMType<isVoid>;
def llvm_any_ty : LLVMType<Any>;
def llvm_anyint_ty : LLVMType<iAny>;
def llvm_anyfloat_ty : LLVMType<fAny>;
def llvm_anyvector_ty : LLVMType<vAny>;
def llvm_i1_ty : LLVMType<i1>;
def llvm_i8_ty : LLVMType<i8>;
def llvm_i16_ty : LLVMType<i16>;
def llvm_i32_ty : LLVMType<i32>;
def llvm_i64_ty : LLVMType<i64>;
def llvm_half_ty : LLVMType<f16>;
def llvm_float_ty : LLVMType<f32>;
def llvm_double_ty : LLVMType<f64>;
def llvm_f80_ty : LLVMType<f80>;
def llvm_f128_ty : LLVMType<f128>;
def llvm_ppcf128_ty : LLVMType<ppcf128>;
def llvm_ptr_ty : LLVMPointerType<llvm_i8_ty>; // i8*
def llvm_ptrptr_ty : LLVMPointerType<llvm_ptr_ty>; // i8**
def llvm_anyptr_ty : LLVMAnyPointerType<llvm_i8_ty>; // (space)i8*
def llvm_empty_ty : LLVMType<OtherVT>; // { }
def llvm_descriptor_ty : LLVMPointerType<llvm_empty_ty>; // { }*
def llvm_metadata_ty : LLVMType<MetadataVT>; // !{...}
def llvm_token_ty : LLVMType<token>; // token
def llvm_x86mmx_ty : LLVMType<x86mmx>;
def llvm_ptrx86mmx_ty : LLVMPointerType<llvm_x86mmx_ty>; // <1 x i64>*
def llvm_v2i1_ty : LLVMType<v2i1>; // 2 x i1
def llvm_v4i1_ty : LLVMType<v4i1>; // 4 x i1
def llvm_v8i1_ty : LLVMType<v8i1>; // 8 x i1
def llvm_v16i1_ty : LLVMType<v16i1>; // 16 x i1
def llvm_v32i1_ty : LLVMType<v32i1>; // 32 x i1
def llvm_v64i1_ty : LLVMType<v64i1>; // 64 x i1
def llvm_v512i1_ty : LLVMType<v512i1>; // 512 x i1
def llvm_v1024i1_ty : LLVMType<v1024i1>; //1024 x i1
def llvm_v1i8_ty : LLVMType<v1i8>; // 1 x i8
def llvm_v2i8_ty : LLVMType<v2i8>; // 2 x i8
def llvm_v4i8_ty : LLVMType<v4i8>; // 4 x i8
def llvm_v8i8_ty : LLVMType<v8i8>; // 8 x i8
def llvm_v16i8_ty : LLVMType<v16i8>; // 16 x i8
def llvm_v32i8_ty : LLVMType<v32i8>; // 32 x i8
def llvm_v64i8_ty : LLVMType<v64i8>; // 64 x i8
def llvm_v128i8_ty : LLVMType<v128i8>; //128 x i8
def llvm_v256i8_ty : LLVMType<v256i8>; //256 x i8
def llvm_v1i16_ty : LLVMType<v1i16>; // 1 x i16
def llvm_v2i16_ty : LLVMType<v2i16>; // 2 x i16
def llvm_v4i16_ty : LLVMType<v4i16>; // 4 x i16
def llvm_v8i16_ty : LLVMType<v8i16>; // 8 x i16
def llvm_v16i16_ty : LLVMType<v16i16>; // 16 x i16
def llvm_v32i16_ty : LLVMType<v32i16>; // 32 x i16
def llvm_v64i16_ty : LLVMType<v64i16>; // 64 x i16
def llvm_v128i16_ty : LLVMType<v128i16>; //128 x i16
def llvm_v1i32_ty : LLVMType<v1i32>; // 1 x i32
def llvm_v2i32_ty : LLVMType<v2i32>; // 2 x i32
def llvm_v4i32_ty : LLVMType<v4i32>; // 4 x i32
def llvm_v8i32_ty : LLVMType<v8i32>; // 8 x i32
def llvm_v16i32_ty : LLVMType<v16i32>; // 16 x i32
def llvm_v32i32_ty : LLVMType<v32i32>; // 32 x i32
def llvm_v64i32_ty : LLVMType<v64i32>; // 64 x i32
def llvm_v1i64_ty : LLVMType<v1i64>; // 1 x i64
def llvm_v2i64_ty : LLVMType<v2i64>; // 2 x i64
def llvm_v4i64_ty : LLVMType<v4i64>; // 4 x i64
def llvm_v8i64_ty : LLVMType<v8i64>; // 8 x i64
def llvm_v16i64_ty : LLVMType<v16i64>; // 16 x i64
def llvm_v32i64_ty : LLVMType<v32i64>; // 32 x i64
def llvm_v1i128_ty : LLVMType<v1i128>; // 1 x i128
def llvm_v2f16_ty : LLVMType<v2f16>; // 2 x half (__fp16)
def llvm_v4f16_ty : LLVMType<v4f16>; // 4 x half (__fp16)
def llvm_v8f16_ty : LLVMType<v8f16>; // 8 x half (__fp16)
def llvm_v1f32_ty : LLVMType<v1f32>; // 1 x float
def llvm_v2f32_ty : LLVMType<v2f32>; // 2 x float
def llvm_v4f32_ty : LLVMType<v4f32>; // 4 x float
def llvm_v8f32_ty : LLVMType<v8f32>; // 8 x float
def llvm_v16f32_ty : LLVMType<v16f32>; // 16 x float
def llvm_v1f64_ty : LLVMType<v1f64>; // 1 x double
def llvm_v2f64_ty : LLVMType<v2f64>; // 2 x double
def llvm_v4f64_ty : LLVMType<v4f64>; // 4 x double
def llvm_v8f64_ty : LLVMType<v8f64>; // 8 x double
def llvm_vararg_ty : LLVMType<isVoid>; // this means vararg here
//===----------------------------------------------------------------------===//
// Intrinsic Definitions.
//===----------------------------------------------------------------------===//
// Intrinsic class - This is used to define one LLVM intrinsic. The name of the
// intrinsic definition should start with "int_", then match the LLVM intrinsic
// name with the "llvm." prefix removed, and all "."s turned into "_"s. For
// example, llvm.bswap.i16 -> int_bswap_i16.
//
// * RetTypes is a list containing the return types expected for the
// intrinsic.
// * ParamTypes is a list containing the parameter types expected for the
// intrinsic.
// * Properties can be set to describe the behavior of the intrinsic.
//
class Intrinsic<list<LLVMType> ret_types,
list<LLVMType> param_types = [],
list<IntrinsicProperty> intr_properties = [],
string name = "",
list<SDNodeProperty> sd_properties = []> : SDPatternOperator {
string LLVMName = name;
string TargetPrefix = ""; // Set to a prefix for target-specific intrinsics.
list<LLVMType> RetTypes = ret_types;
list<LLVMType> ParamTypes = param_types;
list<IntrinsicProperty> IntrProperties = intr_properties;
let Properties = sd_properties;
bit isTarget = 0;
}
/// GCCBuiltin - If this intrinsic exactly corresponds to a GCC builtin, this
/// specifies the name of the builtin. This provides automatic CBE and CFE
/// support.
class GCCBuiltin<string name> {
string GCCBuiltinName = name;
}
class MSBuiltin<string name> {
string MSBuiltinName = name;
}
//===--------------- Variable Argument Handling Intrinsics ----------------===//
//
def int_vastart : Intrinsic<[], [llvm_ptr_ty], [], "llvm.va_start">;
def int_vacopy : Intrinsic<[], [llvm_ptr_ty, llvm_ptr_ty], [],
"llvm.va_copy">;
def int_vaend : Intrinsic<[], [llvm_ptr_ty], [], "llvm.va_end">;
//===------------------- Garbage Collection Intrinsics --------------------===//
//
def int_gcroot : Intrinsic<[],
[llvm_ptrptr_ty, llvm_ptr_ty]>;
def int_gcread : Intrinsic<[llvm_ptr_ty],
[llvm_ptr_ty, llvm_ptrptr_ty],
[IntrReadMem, IntrArgMemOnly]>;
def int_gcwrite : Intrinsic<[],
[llvm_ptr_ty, llvm_ptr_ty, llvm_ptrptr_ty],
[IntrArgMemOnly, NoCapture<1>, NoCapture<2>]>;
//===--------------------- Code Generator Intrinsics ----------------------===//
//
def int_returnaddress : Intrinsic<[llvm_ptr_ty], [llvm_i32_ty], [IntrNoMem]>;
def int_addressofreturnaddress : Intrinsic<[llvm_ptr_ty], [], [IntrNoMem]>;
def int_frameaddress : Intrinsic<[llvm_ptr_ty], [llvm_i32_ty], [IntrNoMem]>;
def int_read_register : Intrinsic<[llvm_anyint_ty], [llvm_metadata_ty],
[IntrReadMem], "llvm.read_register">;
def int_write_register : Intrinsic<[], [llvm_metadata_ty, llvm_anyint_ty],
[], "llvm.write_register">;
// Gets the address of the local variable area. This is typically a copy of the
// stack, frame, or base pointer depending on the type of prologue.
def int_localaddress : Intrinsic<[llvm_ptr_ty], [], [IntrNoMem]>;
// Escapes local variables to allow access from other functions.
def int_localescape : Intrinsic<[], [llvm_vararg_ty]>;
// Given a function and the localaddress of a parent frame, returns a pointer
// to an escaped allocation indicated by the index.
def int_localrecover : Intrinsic<[llvm_ptr_ty],
[llvm_ptr_ty, llvm_ptr_ty, llvm_i32_ty],
[IntrNoMem]>;
// Note: we treat stacksave/stackrestore as writemem because we don't otherwise
// model their dependencies on allocas.
def int_stacksave : Intrinsic<[llvm_ptr_ty]>,
GCCBuiltin<"__builtin_stack_save">;
def int_stackrestore : Intrinsic<[], [llvm_ptr_ty]>,
GCCBuiltin<"__builtin_stack_restore">;
def int_get_dynamic_area_offset : Intrinsic<[llvm_anyint_ty]>;
def int_thread_pointer : Intrinsic<[llvm_ptr_ty], [], [IntrNoMem]>,
GCCBuiltin<"__builtin_thread_pointer">;
// IntrInaccessibleMemOrArgMemOnly is a little more pessimistic than strictly
// necessary for prefetch, however it does conveniently prevent the prefetch
// from being reordered overly much with respect to nearby access to the same
// memory while not impeding optimization.
def int_prefetch
: Intrinsic<[], [ llvm_ptr_ty, llvm_i32_ty, llvm_i32_ty, llvm_i32_ty ],
[ IntrInaccessibleMemOrArgMemOnly, ReadOnly<0>, NoCapture<0> ]>;
def int_pcmarker : Intrinsic<[], [llvm_i32_ty]>;
def int_readcyclecounter : Intrinsic<[llvm_i64_ty]>;
// The assume intrinsic is marked as arbitrarily writing so that proper
// control dependencies will be maintained.
def int_assume : Intrinsic<[], [llvm_i1_ty], []>;
// Stack Protector Intrinsic - The stackprotector intrinsic writes the stack
// guard to the correct place on the stack frame.
def int_stackprotector : Intrinsic<[], [llvm_ptr_ty, llvm_ptrptr_ty], []>;
def int_stackguard : Intrinsic<[llvm_ptr_ty], [], []>;
// A counter increment for instrumentation based profiling.
def int_instrprof_increment : Intrinsic<[],
[llvm_ptr_ty, llvm_i64_ty,
llvm_i32_ty, llvm_i32_ty],
[]>;
// A counter increment with step for instrumentation based profiling.
def int_instrprof_increment_step : Intrinsic<[],
[llvm_ptr_ty, llvm_i64_ty,
llvm_i32_ty, llvm_i32_ty, llvm_i64_ty],
[]>;
// A call to profile runtime for value profiling of target expressions
// through instrumentation based profiling.
def int_instrprof_value_profile : Intrinsic<[],
[llvm_ptr_ty, llvm_i64_ty,
llvm_i64_ty, llvm_i32_ty,
llvm_i32_ty],
[]>;
//===------------------- Standard C Library Intrinsics --------------------===//
//
def int_memcpy : Intrinsic<[],
[llvm_anyptr_ty, llvm_anyptr_ty, llvm_anyint_ty,
llvm_i1_ty],
[IntrArgMemOnly, NoCapture<0>, NoCapture<1>,
WriteOnly<0>, ReadOnly<1>]>;
def int_memmove : Intrinsic<[],
[llvm_anyptr_ty, llvm_anyptr_ty, llvm_anyint_ty,
llvm_i1_ty],
[IntrArgMemOnly, NoCapture<0>, NoCapture<1>,
ReadOnly<1>]>;
def int_memset : Intrinsic<[],
[llvm_anyptr_ty, llvm_i8_ty, llvm_anyint_ty,
llvm_i1_ty],
[IntrArgMemOnly, NoCapture<0>, WriteOnly<0>]>;
// FIXME: Add version of these floating point intrinsics which allow non-default
// rounding modes and FP exception handling.
let IntrProperties = [IntrNoMem, IntrSpeculatable] in {
def int_fma : Intrinsic<[llvm_anyfloat_ty],
[LLVMMatchType<0>, LLVMMatchType<0>,
LLVMMatchType<0>]>;
def int_fmuladd : Intrinsic<[llvm_anyfloat_ty],
[LLVMMatchType<0>, LLVMMatchType<0>,
LLVMMatchType<0>]>;
// These functions do not read memory, but are sensitive to the
// rounding mode. LLVM purposely does not model changes to the FP
// environment so they can be treated as readnone.
def int_sqrt : Intrinsic<[llvm_anyfloat_ty], [LLVMMatchType<0>]>;
def int_powi : Intrinsic<[llvm_anyfloat_ty], [LLVMMatchType<0>, llvm_i32_ty]>;
def int_sin : Intrinsic<[llvm_anyfloat_ty], [LLVMMatchType<0>]>;
def int_cos : Intrinsic<[llvm_anyfloat_ty], [LLVMMatchType<0>]>;
def int_pow : Intrinsic<[llvm_anyfloat_ty],
[LLVMMatchType<0>, LLVMMatchType<0>]>;
def int_log : Intrinsic<[llvm_anyfloat_ty], [LLVMMatchType<0>]>;
def int_log10: Intrinsic<[llvm_anyfloat_ty], [LLVMMatchType<0>]>;
def int_log2 : Intrinsic<[llvm_anyfloat_ty], [LLVMMatchType<0>]>;
def int_exp : Intrinsic<[llvm_anyfloat_ty], [LLVMMatchType<0>]>;
def int_exp2 : Intrinsic<[llvm_anyfloat_ty], [LLVMMatchType<0>]>;
def int_fabs : Intrinsic<[llvm_anyfloat_ty], [LLVMMatchType<0>]>;
def int_copysign : Intrinsic<[llvm_anyfloat_ty],
[LLVMMatchType<0>, LLVMMatchType<0>]>;
def int_floor : Intrinsic<[llvm_anyfloat_ty], [LLVMMatchType<0>]>;
def int_ceil : Intrinsic<[llvm_anyfloat_ty], [LLVMMatchType<0>]>;
def int_trunc : Intrinsic<[llvm_anyfloat_ty], [LLVMMatchType<0>]>;
def int_rint : Intrinsic<[llvm_anyfloat_ty], [LLVMMatchType<0>]>;
def int_nearbyint : Intrinsic<[llvm_anyfloat_ty], [LLVMMatchType<0>]>;
def int_round : Intrinsic<[llvm_anyfloat_ty], [LLVMMatchType<0>]>;
def int_canonicalize : Intrinsic<[llvm_anyfloat_ty], [LLVMMatchType<0>],
[IntrNoMem]>;
}
def int_minnum : Intrinsic<[llvm_anyfloat_ty],
[LLVMMatchType<0>, LLVMMatchType<0>],
[IntrNoMem, IntrSpeculatable, Commutative]
>;
def int_maxnum : Intrinsic<[llvm_anyfloat_ty],
[LLVMMatchType<0>, LLVMMatchType<0>],
[IntrNoMem, IntrSpeculatable, Commutative]
>;
// NOTE: these are internal interfaces.
def int_setjmp : Intrinsic<[llvm_i32_ty], [llvm_ptr_ty]>;
def int_longjmp : Intrinsic<[], [llvm_ptr_ty, llvm_i32_ty], [IntrNoReturn]>;
def int_sigsetjmp : Intrinsic<[llvm_i32_ty] , [llvm_ptr_ty, llvm_i32_ty]>;
def int_siglongjmp : Intrinsic<[], [llvm_ptr_ty, llvm_i32_ty], [IntrNoReturn]>;
// Internal interface for object size checking
def int_objectsize : Intrinsic<[llvm_anyint_ty],
[llvm_anyptr_ty, llvm_i1_ty, llvm_i1_ty],
[IntrNoMem, IntrSpeculatable]>,
GCCBuiltin<"__builtin_object_size">;
//===--------------- Constrained Floating Point Intrinsics ----------------===//
//
let IntrProperties = [IntrInaccessibleMemOnly] in {
def int_experimental_constrained_fadd : Intrinsic<[ llvm_anyfloat_ty ],
[ LLVMMatchType<0>,
LLVMMatchType<0>,
llvm_metadata_ty,
llvm_metadata_ty ]>;
def int_experimental_constrained_fsub : Intrinsic<[ llvm_anyfloat_ty ],
[ LLVMMatchType<0>,
LLVMMatchType<0>,
llvm_metadata_ty,
llvm_metadata_ty ]>;
def int_experimental_constrained_fmul : Intrinsic<[ llvm_anyfloat_ty ],
[ LLVMMatchType<0>,
LLVMMatchType<0>,
llvm_metadata_ty,
llvm_metadata_ty ]>;
def int_experimental_constrained_fdiv : Intrinsic<[ llvm_anyfloat_ty ],
[ LLVMMatchType<0>,
LLVMMatchType<0>,
llvm_metadata_ty,
llvm_metadata_ty ]>;
def int_experimental_constrained_frem : Intrinsic<[ llvm_anyfloat_ty ],
[ LLVMMatchType<0>,
LLVMMatchType<0>,
llvm_metadata_ty,
llvm_metadata_ty ]>;
def int_experimental_constrained_fma : Intrinsic<[ llvm_anyfloat_ty ],
[ LLVMMatchType<0>,
LLVMMatchType<0>,
LLVMMatchType<0>,
llvm_metadata_ty,
llvm_metadata_ty ]>;
// These intrinsics are sensitive to the rounding mode so we need constrained
// versions of each of them. When strict rounding and exception control are
// not required the non-constrained versions of these intrinsics should be
// used.
def int_experimental_constrained_sqrt : Intrinsic<[ llvm_anyfloat_ty ],
[ LLVMMatchType<0>,
llvm_metadata_ty,
llvm_metadata_ty ]>;
def int_experimental_constrained_powi : Intrinsic<[ llvm_anyfloat_ty ],
[ LLVMMatchType<0>,
llvm_i32_ty,
llvm_metadata_ty,
llvm_metadata_ty ]>;
def int_experimental_constrained_sin : Intrinsic<[ llvm_anyfloat_ty ],
[ LLVMMatchType<0>,
llvm_metadata_ty,
llvm_metadata_ty ]>;
def int_experimental_constrained_cos : Intrinsic<[ llvm_anyfloat_ty ],
[ LLVMMatchType<0>,
llvm_metadata_ty,
llvm_metadata_ty ]>;
def int_experimental_constrained_pow : Intrinsic<[ llvm_anyfloat_ty ],
[ LLVMMatchType<0>,
LLVMMatchType<0>,
llvm_metadata_ty,
llvm_metadata_ty ]>;
def int_experimental_constrained_log : Intrinsic<[ llvm_anyfloat_ty ],
[ LLVMMatchType<0>,
llvm_metadata_ty,
llvm_metadata_ty ]>;
def int_experimental_constrained_log10: Intrinsic<[ llvm_anyfloat_ty ],
[ LLVMMatchType<0>,
llvm_metadata_ty,
llvm_metadata_ty ]>;
def int_experimental_constrained_log2 : Intrinsic<[ llvm_anyfloat_ty ],
[ LLVMMatchType<0>,
llvm_metadata_ty,
llvm_metadata_ty ]>;
def int_experimental_constrained_exp : Intrinsic<[ llvm_anyfloat_ty ],
[ LLVMMatchType<0>,
llvm_metadata_ty,
llvm_metadata_ty ]>;
def int_experimental_constrained_exp2 : Intrinsic<[ llvm_anyfloat_ty ],
[ LLVMMatchType<0>,
llvm_metadata_ty,
llvm_metadata_ty ]>;
def int_experimental_constrained_rint : Intrinsic<[ llvm_anyfloat_ty ],
[ LLVMMatchType<0>,
llvm_metadata_ty,
llvm_metadata_ty ]>;
def int_experimental_constrained_nearbyint : Intrinsic<[ llvm_anyfloat_ty ],
[ LLVMMatchType<0>,
llvm_metadata_ty,
llvm_metadata_ty ]>;
}
// FIXME: Add intrinsics for fcmp, fptrunc, fpext, fptoui and fptosi.
// FIXME: Add intrinsics for fabs, copysign, floor, ceil, trunc and round?
//===------------------------- Expect Intrinsics --------------------------===//
//
def int_expect : Intrinsic<[llvm_anyint_ty], [LLVMMatchType<0>,
LLVMMatchType<0>], [IntrNoMem]>;
//===-------------------- Bit Manipulation Intrinsics ---------------------===//
//
// None of these intrinsics accesses memory at all.
let IntrProperties = [IntrNoMem, IntrSpeculatable] in {
def int_bswap: Intrinsic<[llvm_anyint_ty], [LLVMMatchType<0>]>;
def int_ctpop: Intrinsic<[llvm_anyint_ty], [LLVMMatchType<0>]>;
def int_ctlz : Intrinsic<[llvm_anyint_ty], [LLVMMatchType<0>, llvm_i1_ty]>;
def int_cttz : Intrinsic<[llvm_anyint_ty], [LLVMMatchType<0>, llvm_i1_ty]>;
def int_bitreverse : Intrinsic<[llvm_anyint_ty], [LLVMMatchType<0>]>;
}
//===------------------------ Debugger Intrinsics -------------------------===//
//
// None of these intrinsics accesses memory at all...but that doesn't
// mean the optimizers can change them aggressively. Special handling
// needed in a few places. These synthetic intrinsics have no
// side-effects and just mark information about their operands.
let IntrProperties = [IntrNoMem, IntrSpeculatable] in {
def int_dbg_declare : Intrinsic<[],
[llvm_metadata_ty,
llvm_metadata_ty,
llvm_metadata_ty]>;
def int_dbg_value : Intrinsic<[],
[llvm_metadata_ty,
llvm_metadata_ty,
llvm_metadata_ty]>;
def int_dbg_addr : Intrinsic<[],
[llvm_metadata_ty,
llvm_metadata_ty,
llvm_metadata_ty]>;
}
//===------------------ Exception Handling Intrinsics----------------------===//
//
// The result of eh.typeid.for depends on the enclosing function, but inside a
// given function it is 'const' and may be CSE'd etc.
def int_eh_typeid_for : Intrinsic<[llvm_i32_ty], [llvm_ptr_ty], [IntrNoMem]>;
def int_eh_return_i32 : Intrinsic<[], [llvm_i32_ty, llvm_ptr_ty]>;
def int_eh_return_i64 : Intrinsic<[], [llvm_i64_ty, llvm_ptr_ty]>;
// eh.exceptionpointer returns the pointer to the exception caught by
// the given `catchpad`.
def int_eh_exceptionpointer : Intrinsic<[llvm_anyptr_ty], [llvm_token_ty],
[IntrNoMem]>;
// Gets the exception code from a catchpad token. Only used on some platforms.
def int_eh_exceptioncode : Intrinsic<[llvm_i32_ty], [llvm_token_ty], [IntrNoMem]>;
// __builtin_unwind_init is an undocumented GCC intrinsic that causes all
// callee-saved registers to be saved and restored (regardless of whether they
// are used) in the calling function. It is used by libgcc_eh.
def int_eh_unwind_init: Intrinsic<[]>,
GCCBuiltin<"__builtin_unwind_init">;
def int_eh_dwarf_cfa : Intrinsic<[llvm_ptr_ty], [llvm_i32_ty]>;
let IntrProperties = [IntrNoMem] in {
def int_eh_sjlj_lsda : Intrinsic<[llvm_ptr_ty]>;
def int_eh_sjlj_callsite : Intrinsic<[], [llvm_i32_ty]>;
}
def int_eh_sjlj_functioncontext : Intrinsic<[], [llvm_ptr_ty]>;
def int_eh_sjlj_setjmp : Intrinsic<[llvm_i32_ty], [llvm_ptr_ty]>;
def int_eh_sjlj_longjmp : Intrinsic<[], [llvm_ptr_ty], [IntrNoReturn]>;
def int_eh_sjlj_setup_dispatch : Intrinsic<[], []>;
//===---------------- Generic Variable Attribute Intrinsics----------------===//
//
def int_var_annotation : Intrinsic<[],
[llvm_ptr_ty, llvm_ptr_ty,
llvm_ptr_ty, llvm_i32_ty],
[], "llvm.var.annotation">;
def int_ptr_annotation : Intrinsic<[LLVMAnyPointerType<llvm_anyint_ty>],
[LLVMMatchType<0>, llvm_ptr_ty, llvm_ptr_ty,
llvm_i32_ty],
[], "llvm.ptr.annotation">;
def int_annotation : Intrinsic<[llvm_anyint_ty],
[LLVMMatchType<0>, llvm_ptr_ty,
llvm_ptr_ty, llvm_i32_ty],
[], "llvm.annotation">;
// Annotates the current program point with metadata strings which are emitted
// as CodeView debug info records. This is expensive, as it disables inlining
// and is modelled as having side effects.
def int_codeview_annotation : Intrinsic<[], [llvm_metadata_ty],
[IntrInaccessibleMemOnly, IntrNoDuplicate],
"llvm.codeview.annotation">;
//===------------------------ Trampoline Intrinsics -----------------------===//
//
def int_init_trampoline : Intrinsic<[],
[llvm_ptr_ty, llvm_ptr_ty, llvm_ptr_ty],
[IntrArgMemOnly, NoCapture<0>]>,
GCCBuiltin<"__builtin_init_trampoline">;
def int_adjust_trampoline : Intrinsic<[llvm_ptr_ty], [llvm_ptr_ty],
[IntrReadMem, IntrArgMemOnly]>,
GCCBuiltin<"__builtin_adjust_trampoline">;
//===------------------------ Overflow Intrinsics -------------------------===//
//
// Expose the carry flag from add operations on two integrals.
def int_sadd_with_overflow : Intrinsic<[llvm_anyint_ty, llvm_i1_ty],
[LLVMMatchType<0>, LLVMMatchType<0>],
[IntrNoMem, IntrSpeculatable]>;
def int_uadd_with_overflow : Intrinsic<[llvm_anyint_ty, llvm_i1_ty],
[LLVMMatchType<0>, LLVMMatchType<0>],
[IntrNoMem, IntrSpeculatable]>;
def int_ssub_with_overflow : Intrinsic<[llvm_anyint_ty, llvm_i1_ty],
[LLVMMatchType<0>, LLVMMatchType<0>],
[IntrNoMem, IntrSpeculatable]>;
def int_usub_with_overflow : Intrinsic<[llvm_anyint_ty, llvm_i1_ty],
[LLVMMatchType<0>, LLVMMatchType<0>],
[IntrNoMem, IntrSpeculatable]>;
def int_smul_with_overflow : Intrinsic<[llvm_anyint_ty, llvm_i1_ty],
[LLVMMatchType<0>, LLVMMatchType<0>],
[IntrNoMem, IntrSpeculatable]>;
def int_umul_with_overflow : Intrinsic<[llvm_anyint_ty, llvm_i1_ty],
[LLVMMatchType<0>, LLVMMatchType<0>],
[IntrNoMem, IntrSpeculatable]>;
//===------------------------- Memory Use Markers -------------------------===//
//
def int_lifetime_start : Intrinsic<[],
[llvm_i64_ty, llvm_anyptr_ty],
[IntrArgMemOnly, NoCapture<1>]>;
def int_lifetime_end : Intrinsic<[],
[llvm_i64_ty, llvm_anyptr_ty],
[IntrArgMemOnly, NoCapture<1>]>;
def int_invariant_start : Intrinsic<[llvm_descriptor_ty],
[llvm_i64_ty, llvm_anyptr_ty],
[IntrArgMemOnly, NoCapture<1>]>;
def int_invariant_end : Intrinsic<[],
[llvm_descriptor_ty, llvm_i64_ty,
llvm_anyptr_ty],
[IntrArgMemOnly, NoCapture<2>]>;
// invariant.group.barrier can't be marked with 'readnone' (IntrNoMem),
// because it would cause CSE of two barriers with the same argument.
// Readonly and argmemonly says that barrier only reads its argument and
// it can be CSE only if memory didn't change between 2 barriers call,
// which is valid.
// The argument also can't be marked with 'returned' attribute, because
// it would remove barrier.
def int_invariant_group_barrier : Intrinsic<[llvm_anyptr_ty],
[LLVMMatchType<0>],
[IntrReadMem, IntrArgMemOnly]>;
//===------------------------ Stackmap Intrinsics -------------------------===//
//
def int_experimental_stackmap : Intrinsic<[],
[llvm_i64_ty, llvm_i32_ty, llvm_vararg_ty],
[Throws]>;
def int_experimental_patchpoint_void : Intrinsic<[],
[llvm_i64_ty, llvm_i32_ty,
llvm_ptr_ty, llvm_i32_ty,
llvm_vararg_ty],
[Throws]>;
def int_experimental_patchpoint_i64 : Intrinsic<[llvm_i64_ty],
[llvm_i64_ty, llvm_i32_ty,
llvm_ptr_ty, llvm_i32_ty,
llvm_vararg_ty],
[Throws]>;
//===------------------------ Garbage Collection Intrinsics ---------------===//
// These are documented in docs/Statepoint.rst
def int_experimental_gc_statepoint : Intrinsic<[llvm_token_ty],
[llvm_i64_ty, llvm_i32_ty,
llvm_anyptr_ty, llvm_i32_ty,
llvm_i32_ty, llvm_vararg_ty],
[Throws]>;
def int_experimental_gc_result : Intrinsic<[llvm_any_ty], [llvm_token_ty],
[IntrReadMem]>;
def int_experimental_gc_relocate : Intrinsic<[llvm_any_ty],
[llvm_token_ty, llvm_i32_ty, llvm_i32_ty],
[IntrReadMem]>;
//===------------------------ Coroutine Intrinsics ---------------===//
// These are documented in docs/Coroutines.rst
// Coroutine Structure Intrinsics.
def int_coro_id : Intrinsic<[llvm_token_ty], [llvm_i32_ty, llvm_ptr_ty,
llvm_ptr_ty, llvm_ptr_ty],
[IntrArgMemOnly, IntrReadMem,
ReadNone<1>, ReadOnly<2>, NoCapture<2>]>;
def int_coro_alloc : Intrinsic<[llvm_i1_ty], [llvm_token_ty], []>;
def int_coro_begin : Intrinsic<[llvm_ptr_ty], [llvm_token_ty, llvm_ptr_ty],
[WriteOnly<1>]>;
def int_coro_free : Intrinsic<[llvm_ptr_ty], [llvm_token_ty, llvm_ptr_ty],
[IntrReadMem, IntrArgMemOnly, ReadOnly<1>,
NoCapture<1>]>;
def int_coro_end : Intrinsic<[llvm_i1_ty], [llvm_ptr_ty, llvm_i1_ty], []>;
def int_coro_frame : Intrinsic<[llvm_ptr_ty], [], [IntrNoMem]>;
def int_coro_size : Intrinsic<[llvm_anyint_ty], [], [IntrNoMem]>;
def int_coro_save : Intrinsic<[llvm_token_ty], [llvm_ptr_ty], []>;
def int_coro_suspend : Intrinsic<[llvm_i8_ty], [llvm_token_ty, llvm_i1_ty], []>;
def int_coro_param : Intrinsic<[llvm_i1_ty], [llvm_ptr_ty, llvm_ptr_ty],
[IntrNoMem, ReadNone<0>, ReadNone<1>]>;
// Coroutine Manipulation Intrinsics.
def int_coro_resume : Intrinsic<[], [llvm_ptr_ty], [Throws]>;
def int_coro_destroy : Intrinsic<[], [llvm_ptr_ty], [Throws]>;
def int_coro_done : Intrinsic<[llvm_i1_ty], [llvm_ptr_ty],
[IntrArgMemOnly, ReadOnly<0>, NoCapture<0>]>;
def int_coro_promise : Intrinsic<[llvm_ptr_ty],
[llvm_ptr_ty, llvm_i32_ty, llvm_i1_ty],
[IntrNoMem, NoCapture<0>]>;
// Coroutine Lowering Intrinsics. Used internally by coroutine passes.
def int_coro_subfn_addr : Intrinsic<[llvm_ptr_ty], [llvm_ptr_ty, llvm_i8_ty],
[IntrReadMem, IntrArgMemOnly, ReadOnly<0>,
NoCapture<0>]>;
///===-------------------------- Other Intrinsics --------------------------===//
//
def int_flt_rounds : Intrinsic<[llvm_i32_ty]>,
GCCBuiltin<"__builtin_flt_rounds">;
def int_trap : Intrinsic<[], [], [IntrNoReturn]>,
GCCBuiltin<"__builtin_trap">;
def int_debugtrap : Intrinsic<[]>,
GCCBuiltin<"__builtin_debugtrap">;
// Support for dynamic deoptimization (or de-specialization)
def int_experimental_deoptimize : Intrinsic<[llvm_any_ty], [llvm_vararg_ty],
[Throws]>;
// Support for speculative runtime guards
def int_experimental_guard : Intrinsic<[], [llvm_i1_ty, llvm_vararg_ty],
[Throws]>;
// NOP: calls/invokes to this intrinsic are removed by codegen
def int_donothing : Intrinsic<[], [], [IntrNoMem]>;
// This instruction has no actual effect, though it is treated by the optimizer
// has having opaque side effects. This may be inserted into loops to ensure
// that they are not removed even if they turn out to be empty, for languages
// which specify that infinite loops must be preserved.
def int_sideeffect : Intrinsic<[], [], [IntrInaccessibleMemOnly]>;
// Intrisics to support half precision floating point format
let IntrProperties = [IntrNoMem] in {
def int_convert_to_fp16 : Intrinsic<[llvm_i16_ty], [llvm_anyfloat_ty]>;
def int_convert_from_fp16 : Intrinsic<[llvm_anyfloat_ty], [llvm_i16_ty]>;
}
// Clear cache intrinsic, default to ignore (ie. emit nothing)
// maps to void __clear_cache() on supporting platforms
def int_clear_cache : Intrinsic<[], [llvm_ptr_ty, llvm_ptr_ty],
[], "llvm.clear_cache">;
//===-------------------------- Masked Intrinsics -------------------------===//
//
def int_masked_store : Intrinsic<[], [llvm_anyvector_ty,
LLVMAnyPointerType<LLVMMatchType<0>>,
llvm_i32_ty,
LLVMVectorSameWidth<0, llvm_i1_ty>],
[IntrArgMemOnly]>;
def int_masked_load : Intrinsic<[llvm_anyvector_ty],
[LLVMAnyPointerType<LLVMMatchType<0>>, llvm_i32_ty,
LLVMVectorSameWidth<0, llvm_i1_ty>, LLVMMatchType<0>],
[IntrReadMem, IntrArgMemOnly]>;
def int_masked_gather: Intrinsic<[llvm_anyvector_ty],
[LLVMVectorOfAnyPointersToElt<0>, llvm_i32_ty,
LLVMVectorSameWidth<0, llvm_i1_ty>,
LLVMMatchType<0>],
[IntrReadMem]>;
def int_masked_scatter: Intrinsic<[],
[llvm_anyvector_ty,
LLVMVectorOfAnyPointersToElt<0>, llvm_i32_ty,
LLVMVectorSameWidth<0, llvm_i1_ty>]>;
def int_masked_expandload: Intrinsic<[llvm_anyvector_ty],
[LLVMPointerToElt<0>,
LLVMVectorSameWidth<0, llvm_i1_ty>,
LLVMMatchType<0>],
[IntrReadMem]>;
def int_masked_compressstore: Intrinsic<[],
[llvm_anyvector_ty,
LLVMPointerToElt<0>,
LLVMVectorSameWidth<0, llvm_i1_ty>],
[IntrArgMemOnly]>;
// Test whether a pointer is associated with a type metadata identifier.
def int_type_test : Intrinsic<[llvm_i1_ty], [llvm_ptr_ty, llvm_metadata_ty],
[IntrNoMem]>;
// Safely loads a function pointer from a virtual table pointer using type metadata.
def int_type_checked_load : Intrinsic<[llvm_ptr_ty, llvm_i1_ty],
[llvm_ptr_ty, llvm_i32_ty, llvm_metadata_ty],
[IntrNoMem]>;
def int_load_relative: Intrinsic<[llvm_ptr_ty], [llvm_ptr_ty, llvm_anyint_ty],
[IntrReadMem, IntrArgMemOnly]>;
// Xray intrinsics
//===----------------------------------------------------------------------===//
// Custom event logging for x-ray.
// Takes a pointer to a string and the length of the string.
def int_xray_customevent : Intrinsic<[], [llvm_ptr_ty, llvm_i32_ty],
[NoCapture<0>, ReadOnly<0>, IntrWriteMem]>;
//===----------------------------------------------------------------------===//
//===------ Memory intrinsics with element-wise atomicity guarantees ------===//
//
// @llvm.memcpy.element.unordered.atomic.*(dest, src, length, elementsize)
def int_memcpy_element_unordered_atomic
: Intrinsic<[],
[
llvm_anyptr_ty, llvm_anyptr_ty, llvm_anyint_ty, llvm_i32_ty
],
[
IntrArgMemOnly, NoCapture<0>, NoCapture<1>, WriteOnly<0>,
ReadOnly<1>
]>;
// @llvm.memmove.element.unordered.atomic.*(dest, src, length, elementsize)
def int_memmove_element_unordered_atomic
: Intrinsic<[],
[
llvm_anyptr_ty, llvm_anyptr_ty, llvm_anyint_ty, llvm_i32_ty
],
[
IntrArgMemOnly, NoCapture<0>, NoCapture<1>, WriteOnly<0>,
ReadOnly<1>
]>;
// @llvm.memset.element.unordered.atomic.*(dest, value, length, elementsize)
def int_memset_element_unordered_atomic
: Intrinsic<[], [ llvm_anyptr_ty, llvm_i8_ty, llvm_anyint_ty, llvm_i32_ty ],
[ IntrArgMemOnly, NoCapture<0>, WriteOnly<0> ]>;
//===------------------------ Reduction Intrinsics ------------------------===//
//
def int_experimental_vector_reduce_fadd : Intrinsic<[llvm_anyfloat_ty],
[llvm_anyfloat_ty,
llvm_anyvector_ty],
[IntrNoMem]>;
def int_experimental_vector_reduce_fmul : Intrinsic<[llvm_anyfloat_ty],
[llvm_anyfloat_ty,
llvm_anyvector_ty],
[IntrNoMem]>;
def int_experimental_vector_reduce_add : Intrinsic<[llvm_anyint_ty],
[llvm_anyvector_ty],
[IntrNoMem]>;
def int_experimental_vector_reduce_mul : Intrinsic<[llvm_anyint_ty],
[llvm_anyvector_ty],
[IntrNoMem]>;
def int_experimental_vector_reduce_and : Intrinsic<[llvm_anyint_ty],
[llvm_anyvector_ty],
[IntrNoMem]>;
def int_experimental_vector_reduce_or : Intrinsic<[llvm_anyint_ty],
[llvm_anyvector_ty],
[IntrNoMem]>;
def int_experimental_vector_reduce_xor : Intrinsic<[llvm_anyint_ty],
[llvm_anyvector_ty],
[IntrNoMem]>;
def int_experimental_vector_reduce_smax : Intrinsic<[llvm_anyint_ty],
[llvm_anyvector_ty],
[IntrNoMem]>;
def int_experimental_vector_reduce_smin : Intrinsic<[llvm_anyint_ty],
[llvm_anyvector_ty],
[IntrNoMem]>;
def int_experimental_vector_reduce_umax : Intrinsic<[llvm_anyint_ty],
[llvm_anyvector_ty],
[IntrNoMem]>;
def int_experimental_vector_reduce_umin : Intrinsic<[llvm_anyint_ty],
[llvm_anyvector_ty],
[IntrNoMem]>;
def int_experimental_vector_reduce_fmax : Intrinsic<[llvm_anyfloat_ty],
[llvm_anyvector_ty],
[IntrNoMem]>;
def int_experimental_vector_reduce_fmin : Intrinsic<[llvm_anyfloat_ty],
[llvm_anyvector_ty],
[IntrNoMem]>;
//===----- Intrinsics that are used to provide predicate information -----===//
def int_ssa_copy : Intrinsic<[llvm_any_ty], [LLVMMatchType<0>],
[IntrNoMem, Returned<0>]>;
//===----------------------------------------------------------------------===//
// Target-specific intrinsics
//===----------------------------------------------------------------------===//
include "llvm/IR/IntrinsicsPowerPC.td"
include "llvm/IR/IntrinsicsX86.td"
include "llvm/IR/IntrinsicsARM.td"
include "llvm/IR/IntrinsicsAArch64.td"
include "llvm/IR/IntrinsicsXCore.td"
include "llvm/IR/IntrinsicsHexagon.td"
include "llvm/IR/IntrinsicsNVVM.td"
include "llvm/IR/IntrinsicsMips.td"
include "llvm/IR/IntrinsicsAMDGPU.td"
include "llvm/IR/IntrinsicsBPF.td"
include "llvm/IR/IntrinsicsSystemZ.td"
include "llvm/IR/IntrinsicsWebAssembly.td"
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