AbstractCallSite -- A unified interface for (in)direct and callback calls

An abstract call site is a wrapper that allows to treat direct,
  indirect, and callback calls the same. If an abstract call site
  represents a direct or indirect call site it behaves like a stripped
  down version of a normal call site object. The abstract call site can
  also represent a callback call, thus the fact that the initially
  called function (=broker) may invoke a third one (=callback callee).
  In this case, the abstract call side hides the middle man, hence the
  broker function. The result is a representation of the callback call,
  inside the broker, but in the context of the original instruction that
  invoked the broker.

  Again, there are up to three functions involved when we talk about
  callback call sites. The caller (1), which invokes the broker
  function. The broker function (2), that may or may not invoke the
  callback callee. And finally the callback callee (3), which is the
  target of the callback call.

  The abstract call site will handle the mapping from parameters to
  arguments depending on the semantic of the broker function. However,
  it is important to note that the mapping is often partial. Thus, some
  arguments of the call/invoke instruction are mapped to parameters of
  the callee while others are not. At the same time, arguments of the
  callback callee might be unknown, thus "null" if queried.

  This patch introduces also !callback metadata which describe how a
  callback broker maps from parameters to arguments. This metadata is
  directly created by clang for known broker functions, provided through
  source code attributes by the user, or later deduced by analyses.

For motivation and additional information please see the corresponding
talk (slides/video)
  https://llvm.org/devmtg/2018-10/talk-abstracts.html#talk20
as well as the LCPC paper
  http://compilers.cs.uni-saarland.de/people/doerfert/par_opt_lcpc18.pdf

Differential Revision: https://reviews.llvm.org/D54498

llvm-svn: 351627
This commit is contained in:
Johannes Doerfert 2019-01-19 05:19:06 +00:00
parent 5ef26aee50
commit 12be682413
9 changed files with 437 additions and 2 deletions

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@ -5066,6 +5066,72 @@ For example, in the code below, the call instruction may only target the
... ...
!0 = !{i64 (i64, i64)* @add, i64 (i64, i64)* @sub} !0 = !{i64 (i64, i64)* @add, i64 (i64, i64)* @sub}
'``callback``' Metadata
^^^^^^^^^^^^^^^^^^^^^^
``callback`` metadata may be attached to a function declaration, or definition.
(Call sites are excluded only due to the lack of a use case.) For ease of
exposition, we'll refer to the function annotated w/ metadata as a broker
function. The metadata describes how the arguments of a call to the broker are
in turn passed to the callback function specified by the metadata. Thus, the
``callback`` metadata provides a partial description of a call site inside the
broker function with regards to the arguments of a call to the broker. The only
semantic restriction on the broker function itself is that it is not allowed to
inspect or modify arguments referenced in the ``callback`` metadata as
pass-through to the callback function.
The broker is not required to actually invoke the callback function at runtime.
However, the assumptions about not inspecting or modifying arguments that would
be passed to the specified callback function still hold, even if the callback
function is not dynamically invoked. The broker is allowed to invoke the
callback function more than once per invocation of the broker. The broker is
also allowed to invoke (directly or indirectly) the function passed as a
callback through another use. Finally, the broker is also allowed to relay the
callback callee invocation to a different thread.
The metadata is structured as follows: At the outer level, ``callback``
metadata is a list of ``callback`` encodings. Each encoding starts with a
constant ``i64`` which describes the argument position of the callback function
in the call to the broker. The following elements, except the last, describe
what arguments are passed to the callback function. Each element is again an
``i64`` constant identifying the argument of the broker that is passed through,
or ``i64 -1`` to indicate an unknown or inspected argument. The order in which
they are listed has to be the same in which they are passed to the callback
callee. The last element of the encoding is a boolean which specifies how
variadic arguments of the broker are handled. If it is true, all variadic
arguments of the broker are passed through to the callback function *after* the
arguments encoded explicitly before.
In the code below, the ``pthread_create`` function is marked as a broker
through the ``!callback !1`` metadata. In the example, there is only one
callback encoding, namely ``!2``, associated with the broker. This encoding
identifies the callback function as the second argument of the broker (``i64
2``) and the sole argument of the callback function as the third one of the
broker function (``i64 3``).
.. code-block:: llvm
declare !callback !1 dso_local i32 @pthread_create(i64*, %union.pthread_attr_t*, i8* (i8*)*, i8*)
...
!2 = !{i64 2, i64 3, i1 false}
!1 = !{!2}
Another example is shown below. The callback callee is the second argument of
the ``__kmpc_fork_call`` function (``i64 2``). The callee is given two unknown
values (each identified by a ``i64 -1``) and afterwards all
variadic arguments that are passed to the ``__kmpc_fork_call`` call (due to the
final ``i1 true``).
.. code-block:: llvm
declare !callback !0 dso_local void @__kmpc_fork_call(%struct.ident_t*, i32, void (i32*, i32*, ...)*, ...)
...
!1 = !{i64 2, i64 -1, i64 -1, i1 true}
!0 = !{!1}
'``unpredictable``' Metadata '``unpredictable``' Metadata
^^^^^^^^^^^^^^^^^^^^^^^^^^^^ ^^^^^^^^^^^^^^^^^^^^^^^^^^^^

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@ -683,6 +683,182 @@ private:
User::op_iterator getCallee() const; User::op_iterator getCallee() const;
}; };
/// AbstractCallSite
///
/// An abstract call site is a wrapper that allows to treat direct,
/// indirect, and callback calls the same. If an abstract call site
/// represents a direct or indirect call site it behaves like a stripped
/// down version of a normal call site object. The abstract call site can
/// also represent a callback call, thus the fact that the initially
/// called function (=broker) may invoke a third one (=callback callee).
/// In this case, the abstract call site hides the middle man, hence the
/// broker function. The result is a representation of the callback call,
/// inside the broker, but in the context of the original call to the broker.
///
/// There are up to three functions involved when we talk about callback call
/// sites. The caller (1), which invokes the broker function. The broker
/// function (2), that will invoke the callee zero or more times. And finally
/// the callee (3), which is the target of the callback call.
///
/// The abstract call site will handle the mapping from parameters to arguments
/// depending on the semantic of the broker function. However, it is important
/// to note that the mapping is often partial. Thus, some arguments of the
/// call/invoke instruction are mapped to parameters of the callee while others
/// are not.
class AbstractCallSite {
public:
/// The encoding of a callback with regards to the underlying instruction.
struct CallbackInfo {
/// For direct/indirect calls the parameter encoding is empty. If it is not,
/// the abstract call site represents a callback. In that case, the first
/// element of the encoding vector represents which argument of the call
/// site CS is the callback callee. The remaining elements map parameters
/// (identified by their position) to the arguments that will be passed
/// through (also identified by position but in the call site instruction).
///
/// NOTE that we use LLVM argument numbers (starting at 0) and not
/// clang/soruce argument numbers (starting at 1). The -1 entries represent
/// unknown values that are passed to the callee.
using ParameterEncodingTy = SmallVector<int, 0>;
ParameterEncodingTy ParameterEncoding;
};
private:
/// The underlying call site:
/// caller -> callee, if this is a direct or indirect call site
/// caller -> broker function, if this is a callback call site
CallSite CS;
/// The encoding of a callback with regards to the underlying instruction.
CallbackInfo CI;
public:
/// Sole constructor for abstract call sites (ACS).
///
/// An abstract call site can only be constructed through a llvm::Use because
/// each operand (=use) of an instruction could potentially be a different
/// abstract call site. Furthermore, even if the value of the llvm::Use is the
/// same, and the user is as well, the abstract call sites might not be.
///
/// If a use is not associated with an abstract call site the constructed ACS
/// will evaluate to false if converted to a boolean.
///
/// If the use is the callee use of a call or invoke instruction, the
/// constructed abstract call site will behave as a llvm::CallSite would.
///
/// If the use is not a callee use of a call or invoke instruction, the
/// callback metadata is used to determine the argument <-> parameter mapping
/// as well as the callee of the abstract call site.
AbstractCallSite(const Use *U);
/// Conversion operator to conveniently check for a valid/initialized ACS.
explicit operator bool() const { return (bool)CS; }
/// Return the underlying instruction.
Instruction *getInstruction() const { return CS.getInstruction(); }
/// Return the call site abstraction for the underlying instruction.
CallSite getCallSite() const { return CS; }
/// Return true if this ACS represents a direct call.
bool isDirectCall() const {
return !isCallbackCall() && !CS.isIndirectCall();
}
/// Return true if this ACS represents an indirect call.
bool isIndirectCall() const {
return !isCallbackCall() && CS.isIndirectCall();
}
/// Return true if this ACS represents a callback call.
bool isCallbackCall() const {
// For a callback call site the callee is ALWAYS stored first in the
// transitive values vector. Thus, a non-empty vector indicates a callback.
return !CI.ParameterEncoding.empty();
}
/// Return true if @p UI is the use that defines the callee of this ACS.
bool isCallee(Value::const_user_iterator UI) const {
return isCallee(&UI.getUse());
}
/// Return true if @p U is the use that defines the callee of this ACS.
bool isCallee(const Use *U) const {
if (isDirectCall())
return CS.isCallee(U);
assert(!CI.ParameterEncoding.empty() &&
"Callback without parameter encoding!");
return (int)CS.getArgumentNo(U) == CI.ParameterEncoding[0];
}
/// Return the number of parameters of the callee.
unsigned getNumArgOperands() const {
if (isDirectCall())
return CS.getNumArgOperands();
// Subtract 1 for the callee encoding.
return CI.ParameterEncoding.size() - 1;
}
/// Return the operand index of the underlying instruction associated with @p
/// Arg.
int getCallArgOperandNo(Argument &Arg) const {
return getCallArgOperandNo(Arg.getArgNo());
}
/// Return the operand index of the underlying instruction associated with
/// the function parameter number @p ArgNo or -1 if there is none.
int getCallArgOperandNo(unsigned ArgNo) const {
if (isDirectCall())
return ArgNo;
// Add 1 for the callee encoding.
return CI.ParameterEncoding[ArgNo + 1];
}
/// Return the operand of the underlying instruction associated with @p Arg.
Value *getCallArgOperand(Argument &Arg) const {
return getCallArgOperand(Arg.getArgNo());
}
/// Return the operand of the underlying instruction associated with the
/// function parameter number @p ArgNo or nullptr if there is none.
Value *getCallArgOperand(unsigned ArgNo) const {
if (isDirectCall())
return CS.getArgOperand(ArgNo);
// Add 1 for the callee encoding.
return CI.ParameterEncoding[ArgNo + 1] >= 0
? CS.getArgOperand(CI.ParameterEncoding[ArgNo + 1])
: nullptr;
}
/// Return the operand index of the underlying instruction associated with the
/// callee of this ACS. Only valid for callback calls!
int getCallArgOperandNoForCallee() const {
assert(isCallbackCall());
assert(CI.ParameterEncoding.size() && CI.ParameterEncoding[0] > 0);
return CI.ParameterEncoding[0];
}
/// Return the pointer to function that is being called.
Value *getCalledValue() const {
if (isDirectCall())
return CS.getCalledValue();
return CS.getArgOperand(getCallArgOperandNoForCallee());
}
/// Return the function being called if this is a direct call, otherwise
/// return null (if it's an indirect call).
Function *getCalledFunction() const {
Value *V = getCalledValue();
return V ? dyn_cast<Function>(V->stripPointerCasts()) : nullptr;
}
};
template <> struct DenseMapInfo<CallSite> { template <> struct DenseMapInfo<CallSite> {
using BaseInfo = DenseMapInfo<decltype(CallSite::I)>; using BaseInfo = DenseMapInfo<decltype(CallSite::I)>;

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@ -103,6 +103,7 @@ public:
MD_callees = 23, // "callees" MD_callees = 23, // "callees"
MD_irr_loop = 24, // "irr_loop" MD_irr_loop = 24, // "irr_loop"
MD_access_group = 25, // "llvm.access.group" MD_access_group = 25, // "llvm.access.group"
MD_callback = 26, // "callback"
}; };
/// Known operand bundle tag IDs, which always have the same value. All /// Known operand bundle tag IDs, which always have the same value. All

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@ -94,6 +94,17 @@ public:
/// calls. /// calls.
MDNode *createCallees(ArrayRef<Function *> Callees); MDNode *createCallees(ArrayRef<Function *> Callees);
//===------------------------------------------------------------------===//
// Callback metadata.
//===------------------------------------------------------------------===//
/// Return metadata describing a callback (see llvm::AbstractCallSite).
MDNode *createCallbackEncoding(unsigned CalleeArgNo, ArrayRef<int> Arguments,
bool VarArgsArePassed);
/// Merge the new callback encoding \p NewCB into \p ExistingCallbacks.
MDNode *mergeCallbackEncodings(MDNode *ExistingCallbacks, MDNode *NewCB);
//===------------------------------------------------------------------===// //===------------------------------------------------------------------===//
// AA metadata. // AA metadata.
//===------------------------------------------------------------------===// //===------------------------------------------------------------------===//

135
lib/IR/AbstractCallSite.cpp Normal file
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@ -0,0 +1,135 @@
//===-- AbstractCallSite.cpp - Implementation of abstract call sites ------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file implements abstract call sites which unify the interface for
// direct, indirect, and callback call sites.
//
// For more information see:
// https://llvm.org/devmtg/2018-10/talk-abstracts.html#talk20
//
//===----------------------------------------------------------------------===//
#include "llvm/ADT/Statistic.h"
#include "llvm/ADT/StringSwitch.h"
#include "llvm/IR/CallSite.h"
#include "llvm/Support/Debug.h"
using namespace llvm;
#define DEBUG_TYPE "abstract-call-sites"
STATISTIC(NumCallbackCallSites, "Number of callback call sites created");
STATISTIC(NumDirectAbstractCallSites,
"Number of direct abstract call sites created");
STATISTIC(NumInvalidAbstractCallSitesUnknownUse,
"Number of invalid abstract call sites created (unknown use)");
STATISTIC(NumInvalidAbstractCallSitesUnknownCallee,
"Number of invalid abstract call sites created (unknown callee)");
STATISTIC(NumInvalidAbstractCallSitesNoCallback,
"Number of invalid abstract call sites created (no callback)");
/// Create an abstract call site from a use.
AbstractCallSite::AbstractCallSite(const Use *U) : CS(U->getUser()) {
// First handle unknown users.
if (!CS) {
// If the use is actually in a constant cast expression which itself
// has only one use, we look through the constant cast expression.
// This happens by updating the use @p U to the use of the constant
// cast expression and afterwards re-initializing CS accordingly.
if (ConstantExpr *CE = dyn_cast<ConstantExpr>(U->getUser()))
if (CE->getNumUses() == 1 && CE->isCast()) {
U = &*CE->use_begin();
CS = CallSite(U->getUser());
}
if (!CS) {
NumInvalidAbstractCallSitesUnknownUse++;
return;
}
}
// Then handle direct or indirect calls. Thus, if U is the callee of the
// call site CS it is not a callback and we are done.
if (CS.isCallee(U)) {
NumDirectAbstractCallSites++;
return;
}
// If we cannot identify the broker function we cannot create a callback and
// invalidate the abstract call site.
Function *Callee = CS.getCalledFunction();
if (!Callee) {
NumInvalidAbstractCallSitesUnknownCallee++;
CS = CallSite();
return;
}
MDNode *CallbackMD = Callee->getMetadata(LLVMContext::MD_callback);
if (!CallbackMD) {
NumInvalidAbstractCallSitesNoCallback++;
CS = CallSite();
return;
}
unsigned UseIdx = CS.getArgumentNo(U);
MDNode *CallbackEncMD = nullptr;
for (const MDOperand &Op : CallbackMD->operands()) {
MDNode *OpMD = cast<MDNode>(Op.get());
auto *CBCalleeIdxAsCM = cast<ConstantAsMetadata>(OpMD->getOperand(0));
uint64_t CBCalleeIdx =
cast<ConstantInt>(CBCalleeIdxAsCM->getValue())->getZExtValue();
if (CBCalleeIdx != UseIdx)
continue;
CallbackEncMD = OpMD;
break;
}
if (!CallbackEncMD) {
NumInvalidAbstractCallSitesNoCallback++;
CS = CallSite();
return;
}
NumCallbackCallSites++;
assert(CallbackEncMD->getNumOperands() >= 2 && "Incomplete !callback metadata");
unsigned NumCallOperands = CS.getNumArgOperands();
// Skip the var-arg flag at the end when reading the metadata.
for (unsigned u = 0, e = CallbackEncMD->getNumOperands() - 1; u < e; u++) {
Metadata *OpAsM = CallbackEncMD->getOperand(u).get();
auto *OpAsCM = cast<ConstantAsMetadata>(OpAsM);
assert(OpAsCM->getType()->isIntegerTy(64) &&
"Malformed !callback metadata");
int64_t Idx = cast<ConstantInt>(OpAsCM->getValue())->getSExtValue();
assert(-1 <= Idx && Idx <= NumCallOperands &&
"Out-of-bounds !callback metadata index");
CI.ParameterEncoding.push_back(Idx);
}
if (!Callee->isVarArg())
return;
Metadata *VarArgFlagAsM =
CallbackEncMD->getOperand(CallbackEncMD->getNumOperands() - 1).get();
auto *VarArgFlagAsCM = cast<ConstantAsMetadata>(VarArgFlagAsM);
assert(VarArgFlagAsCM->getType()->isIntegerTy(1) &&
"Malformed !callback metadata var-arg flag");
if (VarArgFlagAsCM->getValue()->isNullValue())
return;
// Add all variadic arguments at the end.
for (unsigned u = Callee->arg_size(); u < NumCallOperands; u++)
CI.ParameterEncoding.push_back(u);
}

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@ -3,6 +3,7 @@ tablegen(LLVM AttributesCompatFunc.inc -gen-attrs)
add_public_tablegen_target(AttributeCompatFuncTableGen) add_public_tablegen_target(AttributeCompatFuncTableGen)
add_llvm_library(LLVMCore add_llvm_library(LLVMCore
AbstractCallSite.cpp
AsmWriter.cpp AsmWriter.cpp
Attributes.cpp Attributes.cpp
AutoUpgrade.cpp AutoUpgrade.cpp

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@ -62,6 +62,7 @@ LLVMContext::LLVMContext() : pImpl(new LLVMContextImpl(*this)) {
{MD_callees, "callees"}, {MD_callees, "callees"},
{MD_irr_loop, "irr_loop"}, {MD_irr_loop, "irr_loop"},
{MD_access_group, "llvm.access.group"}, {MD_access_group, "llvm.access.group"},
{MD_callback, "callback"},
}; };
for (auto &MDKind : MDKinds) { for (auto &MDKind : MDKinds) {

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@ -107,6 +107,50 @@ MDNode *MDBuilder::createCallees(ArrayRef<Function *> Callees) {
return MDNode::get(Context, Ops); return MDNode::get(Context, Ops);
} }
MDNode *MDBuilder::createCallbackEncoding(unsigned CalleeArgNo,
ArrayRef<int> Arguments,
bool VarArgArePassed) {
SmallVector<Metadata *, 4> Ops;
Type *Int64 = Type::getInt64Ty(Context);
Ops.push_back(createConstant(ConstantInt::get(Int64, CalleeArgNo)));
for (int ArgNo : Arguments)
Ops.push_back(createConstant(ConstantInt::get(Int64, ArgNo, true)));
Type *Int1 = Type::getInt1Ty(Context);
Ops.push_back(createConstant(ConstantInt::get(Int1, VarArgArePassed)));
return MDNode::get(Context, Ops);
}
MDNode *MDBuilder::mergeCallbackEncodings(MDNode *ExistingCallbacks,
MDNode *NewCB) {
if (!ExistingCallbacks)
return MDNode::get(Context, {NewCB});
auto *NewCBCalleeIdxAsCM = cast<ConstantAsMetadata>(NewCB->getOperand(0));
uint64_t NewCBCalleeIdx =
cast<ConstantInt>(NewCBCalleeIdxAsCM->getValue())->getZExtValue();
SmallVector<Metadata *, 4> Ops;
unsigned NumExistingOps = ExistingCallbacks->getNumOperands();
Ops.resize(NumExistingOps + 1);
for (unsigned u = 0; u < NumExistingOps; u++) {
Ops[u] = ExistingCallbacks->getOperand(u);
auto *OldCBCalleeIdxAsCM = cast<ConstantAsMetadata>(Ops[u]);
uint64_t OldCBCalleeIdx =
cast<ConstantInt>(OldCBCalleeIdxAsCM->getValue())->getZExtValue();
assert(NewCBCalleeIdx != OldCBCalleeIdx &&
"Cannot map a callback callee index twice!");
}
Ops[NumExistingOps] = NewCB;
return MDNode::get(Context, Ops);
}
MDNode *MDBuilder::createAnonymousAARoot(StringRef Name, MDNode *Extra) { MDNode *MDBuilder::createAnonymousAARoot(StringRef Name, MDNode *Extra) {
// To ensure uniqueness the root node is self-referential. // To ensure uniqueness the root node is self-referential.
auto Dummy = MDNode::getTemporary(Context, None); auto Dummy = MDNode::getTemporary(Context, None);

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@ -10,13 +10,13 @@
; RUN: llvm-lto -thinlto-action=import %t2.bc -thinlto-index=%t3.bc \ ; RUN: llvm-lto -thinlto-action=import %t2.bc -thinlto-index=%t3.bc \
; RUN: -o /dev/null -stats \ ; RUN: -o /dev/null -stats \
; RUN: 2>&1 | FileCheck %s -check-prefix=LAZY ; RUN: 2>&1 | FileCheck %s -check-prefix=LAZY
; LAZY: 57 bitcode-reader - Number of Metadata records loaded ; LAZY: 59 bitcode-reader - Number of Metadata records loaded
; LAZY: 2 bitcode-reader - Number of MDStrings loaded ; LAZY: 2 bitcode-reader - Number of MDStrings loaded
; RUN: llvm-lto -thinlto-action=import %t2.bc -thinlto-index=%t3.bc \ ; RUN: llvm-lto -thinlto-action=import %t2.bc -thinlto-index=%t3.bc \
; RUN: -o /dev/null -disable-ondemand-mds-loading -stats \ ; RUN: -o /dev/null -disable-ondemand-mds-loading -stats \
; RUN: 2>&1 | FileCheck %s -check-prefix=NOTLAZY ; RUN: 2>&1 | FileCheck %s -check-prefix=NOTLAZY
; NOTLAZY: 66 bitcode-reader - Number of Metadata records loaded ; NOTLAZY: 68 bitcode-reader - Number of Metadata records loaded
; NOTLAZY: 7 bitcode-reader - Number of MDStrings loaded ; NOTLAZY: 7 bitcode-reader - Number of MDStrings loaded