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base: Alexander_KS:a6e6af7577d2906a7362941a060b174bb9968462
Branches Tags
Alexander_KS:master Alexander_KS:fix_array_analysis Alexander_KS:replace_io_arrays Alexander_KS:par_reg_merging Alexander_KS:egormayorov Alexander_KS:private_arrays Alexander_KS:libpredict_integration Alexander_KS:analyze_loops_with_IR
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compare: Alexander_KS:replace_io_arrays
Branches Tags
Alexander_KS:master Alexander_KS:fix_array_analysis Alexander_KS:replace_io_arrays Alexander_KS:par_reg_merging Alexander_KS:egormayorov Alexander_KS:private_arrays Alexander_KS:libpredict_integration Alexander_KS:analyze_loops_with_IR

40 Commits
a6e6af7577 ... replace_io

Author SHA1 Message Date
xnpster
486b4c1a13 REMOVE_DIST_ARRAYS_FROM_IO: fix type, add TODO 2026-01-31 17:12:27 +03:00
ALEXks
331d4f9d99 fixed private analysis 2026-01-19 21:01:49 +03:00
ALEXks
904292f109 updated submodule libpredictor 2026-01-18 16:50:57 +03:00
ALEXks
c36326660c fixed submodule libpredictor 2026-01-06 18:50:54 +03:00
ALEXks
ec08e3af0e version updated 2026-01-06 18:36:07 +03:00
ALEXks
b1ef5d0b67 dvm submodule updated 2026-01-06 18:35:34 +03:00
Alexander_KS
d6c046ea57 Merge pull request 'egormayorov' (#72) from egormayorov into master 2025-12-29 18:26:19 +00:00
ALEXks
af85311480 refactored, added pass to Visualizer calls 2025-12-29 21:22:53 +03:00
ALEXks
d9f54739d2 refactored 2025-12-29 21:10:55 +03:00
Egor Mayorov
6907f44ac5 fixes & improvements 2025-12-25 15:01:01 +03:00
Egor Mayorov
582d2d5e70 Adding handing of nested loops and conditional statements 2025-12-24 21:08:42 +03:00
Egor Mayorov
1c37336459 Make pass correct 2025-12-24 21:08:42 +03:00
Egor Mayorov
f527deb02c attempt to build new ast 2025-12-24 21:08:42 +03:00
Alexander
d09e92a947 moved to transformations 2025-12-24 21:08:42 +03:00
Egor Mayorov
029da32719 swap operators in AST 2025-12-24 21:08:42 +03:00
Egor Mayorov
085e6312a3 Use more complex algorythm for building new order of statements 2025-12-24 21:08:42 +03:00
Egor Mayorov
c5927fe80f update in new order 2025-12-24 21:08:42 +03:00
Egor Mayorov
8728f84546 biulding new order 2025-12-24 21:08:42 +03:00
Egor Mayorov
9e4db270fc some loop analysis done 2025-12-24 21:08:42 +03:00
Egor Mayorov
0c20b37923 Add _bin to gitignore 2025-12-24 21:08:42 +03:00
Egor Mayorov
61c6ad1363 Some actions simplify analyzing IR 2025-12-24 21:08:42 +03:00
Egor Mayorov
e5fa2e41b3 Pass with output file added 2025-12-24 21:08:42 +03:00
Egor Mayorov
3b9e4653b6 change pass deps 2025-12-24 21:08:42 +03:00
Egor Mayorov
2d84aaff1f New pass 2025-12-24 21:08:42 +03:00
Alexander_KS
032cdb9b03 Merge pull request 'private_arrays' (#71) from private_arrays into master 2025-12-24 05:59:30 +00:00
ALEXks
a8f8f44ac1 corrected style, updated version 2025-12-24 08:58:28 +03:00
Oleg Nikitin
1c39001e28 small fix 2025-12-23 16:29:10 +03:00
Oleg Nikitin
7802f538e8 add whole array assign 2025-12-23 02:03:57 +03:00
Oleg Nikitin
93fa183b63 fix 2025-12-21 03:58:45 +03:00
Alexander_KS
a07a701826 Merge pull request 'fix private arrays search' (#70) from private_arrays into master 2025-12-19 18:07:14 +00:00
ALEXks
e99855cdff updated version, fixed code style 2025-12-19 21:06:55 +03:00
Oleg Nikitin
f07bea4980 fix FIND_PRIVATE_ARRAYS 2025-12-19 04:52:31 +03:00
ALEXks
3de06d9261 finalyze first version of private arrays search 2025-12-11 12:26:39 +03:00
Alexander_KS
678c2cf351 Merge pull request 'add directives' (#69) from private_arrays into master 2025-12-11 08:30:47 +00:00
Oleg Nikitin
40cfd83de5 add directives 2025-12-10 01:46:26 +03:00
ALEXks
a0cea2df91 added new function for visualizer 2025-11-08 20:17:32 +03:00
ALEXks
4b7df86b8a version updated 2025-11-08 20:08:22 +03:00
Alexander_KS
836894fef1 Merge pull request 'private_arrays' (#68) from private_arrays into master 2025-11-08 17:07:07 +00:00
Oleg Nikitin
9ac15eec79 fix codestyle 2025-11-08 20:06:07 +03:00
Oleg Nikitin
03f565f50b add multifile support 2025-11-08 20:06:07 +03:00
29 changed files with 1494 additions and 708 deletions
Expand all files Collapse all files

16
CMakeLists.txt
View File

@@ -163,6 +163,10 @@ set(PARALLEL_REG src/ParallelizationRegions/ParRegions.cpp
src/ParallelizationRegions/resolve_par_reg_conflicts.cpp
src/ParallelizationRegions/resolve_par_reg_conflicts.h)
set(ARRAY_PROP src/ArrayConstantPropagation/propagation.cpp
src/ArrayConstantPropagation/propagation.h
)
set(TR_DEAD_CODE src/Transformations/DeadCodeRemoving/dead_code.cpp
src/Transformations/DeadCodeRemoving/dead_code.h)
set(TR_CP src/Transformations/CheckPoints/checkpoints.cpp
@@ -203,9 +207,9 @@ set(TR_EXPR_TRANSFORM src/Transformations/ExpressionSubstitution/control_flow_gr
set(TR_INLINER src/Transformations/FunctionInlining/inliner.cpp
src/Transformations/FunctionInlining/inliner.h)
set(TR_RENAME_SYMBOLS src/Transformations/RenameSymbols/rename_symbols.cpp
src/Transformations/RenameSymbols/rename_symbols.h)
SET(TR_SWAP_OPERATORS src/Transformations/SwapOperators/swap_operators.cpp
src/Transformations/SwapOperators/swap_operators.h)
src/Transformations/RenameSymbols/rename_symbols.h)
SET(TR_MOVE_OPERATORS src/Transformations/MoveOperators/move_operators.cpp
src/Transformations/MoveOperators/move_operators.h)
set(TRANSFORMS
${TR_DEAD_CODE}
@@ -229,7 +233,7 @@ set(TRANSFORMS
${TR_EXPR_TRANSFORM}
${TR_INLINER}
${TR_RENAME_SYMBOLS}
${TR_SWAP_OPERATORS})
${TR_MOVE_OPERATORS})
set(CFG src/CFGraph/IR.cpp
src/CFGraph/IR.h
@@ -423,6 +427,7 @@ set(SOURCE_EXE
${TRANSFORMS}
${PARALLEL_REG}
${PRIV}
${ARRAY_PROP}
${FDVM}
${OMEGA}
${UTILS}
@@ -462,7 +467,7 @@ source_group (Transformations\\GlobalVariables FILES ${TR_GV})
source_group (Transformations\\ConvertToC FILES ${TR_CONV})
source_group (Transformations\\SetImplicitNone FILES ${TR_IMPLICIT_NONE})
source_group (Transformations\\ReplaceArraysInIO FILES ${TR_REPLACE_ARRAYS_IN_IO})
source_group (Transformations\\SwapOperators FILES ${TR_SWAP_OPERATORS})
source_group (Transformations\\MoveOperators FILES ${TR_MOVE_OPERATORS})
source_group (CreateIntervals FILES ${CREATE_INTER_T})
@@ -475,6 +480,7 @@ source_group (GraphLoop FILES ${GR_LOOP})
source_group (LoopAnalyzer FILES ${LOOP_ANALYZER})
source_group (ParallelizationRegions FILES ${PARALLEL_REG})
source_group (PrivateAnalyzer FILES ${PRIV})
source_group (ArrayConstantPropagation FILES ${ARRAY_PROP})
source_group (FDVM_Compiler FILES ${FDVM})
source_group (SageExtension FILES ${OMEGA})
source_group (Utils FILES ${UTILS})

2
projects/dvm

Submodule projects/dvm updated: 4b7ef11871...3aad02affb

2
projects/libpredictor

Submodule projects/libpredictor updated: d0772cdb57...d08cb25cc6

301
src/ArrayConstantPropagation/propagation.cpp Normal file
View File

@@ -0,0 +1,301 @@
#include "propagation.h"
#include "../Utils/SgUtils.h"
#include <iostream>
#include <unordered_map>
#include <unordered_set>
#include <vector>
using namespace std;
static SgStatement* declPlace = NULL;
static bool CheckConstIndexes(SgExpression* exp)
{
if (!exp)
{
return true;
}
SgExpression* lhs = exp->lhs();
SgExpression* rhs = exp->rhs();
do
{
if (lhs->variant() != INT_VAL)
{
return false;
}
if (rhs)
{
lhs = rhs->lhs();
rhs = rhs->rhs();
}
} while (rhs);
return true;
}
static SgExpression* CreateVar(int& variableNumber, SgType* type)
{
string varName = "__tmp_prop_var";
string name = varName + std::to_string(variableNumber) + "__";
variableNumber++;
SgSymbol* varSymbol = new SgSymbol(VARIABLE_NAME, name.c_str(), *type, *declPlace->controlParent());
const string commonBlockName = "__propagation_common__";
SgStatement* funcStart = declPlace->controlParent();
SgStatement* commonStat = NULL;
SgExpression* commonList = NULL;
SgStatement* funcEnd = funcStart->lastNodeOfStmt();
SgStatement* current = funcStart->lexNext();
while (current != funcEnd && current)
{
if (current->variant() == COMM_STAT)
{
for (SgExpression* exp = current->expr(0); exp; exp = exp->rhs())
{
if (exp->variant() == COMM_LIST)
{
string existingName = exp->symbol() ?
string(exp->symbol()->identifier()) :
string("spf_unnamed");
if (existingName == commonBlockName)
{
commonStat = current;
commonList = exp;
break;
}
}
}
if (commonStat)
break;
}
current = current->lexNext();
}
vector<SgExpression*> varRefs;
if (commonList)
{
SgExpression* varList = commonList->lhs();
if (varList)
{
auto extractSymbol = [](SgExpression* exp) -> SgSymbol* {
if (!exp)
return NULL;
if (exp->symbol())
return exp->symbol();
if (exp->lhs() && exp->lhs()->symbol())
return exp->lhs()->symbol();
return NULL;
};
if (varList->variant() == EXPR_LIST)
{
for (SgExpression* exp = varList; exp; exp = exp->rhs())
{
SgExpression* varExp = exp->lhs();
SgSymbol* sym = extractSymbol(varExp);
if (sym)
{
varRefs.push_back(new SgVarRefExp(sym));
}
}
}
else
{
for (SgExpression* varExp = varList; varExp; varExp = varExp->rhs())
{
SgSymbol* sym = extractSymbol(varExp);
if (sym)
{
varRefs.push_back(new SgVarRefExp(sym));
}
}
}
}
}
if (!commonList)
{
current = funcStart->lexNext();
while (current != funcEnd && current)
{
if (current->variant() == COMM_STAT)
{
commonStat = current;
break;
}
current = current->lexNext();
}
SgSymbol* commonSymbol = new SgSymbol(COMMON_NAME, commonBlockName.c_str());
commonList = new SgExpression(COMM_LIST, NULL, NULL, commonSymbol);
if (commonStat)
{
SgExpression* lastCommList = commonStat->expr(0);
if (lastCommList)
{
while (lastCommList->rhs())
lastCommList = lastCommList->rhs();
lastCommList->setRhs(commonList);
}
else
{
commonStat->setExpression(0, commonList);
}
}
else
{
commonStat = new SgStatement(COMM_STAT);
commonStat->setFileName(declPlace->fileName());
commonStat->setFileId(declPlace->getFileId());
commonStat->setProject(declPlace->getProject());
commonStat->setlineNumber(getNextNegativeLineNumber());
commonStat->setExpression(0, commonList);
declPlace->insertStmtBefore(*commonStat, *declPlace->controlParent());
}
}
varRefs.push_back(new SgVarRefExp(varSymbol));
if (varRefs.size() > 0)
{
std::reverse(varRefs.begin(), varRefs.end());
SgExpression* varList = makeExprList(varRefs, false);
commonList->setLhs(varList);
}
return new SgExpression(VAR_REF, NULL, NULL, varSymbol, type->copyPtr());
}
static void TransformRightPart(SgStatement* st, SgExpression* exp, unordered_map<string, SgExpression*>& arrayToVariable, int& variableNumber)
{
if (!exp)
{
return;
}
vector<SgExpression*> subnodes = { exp->lhs(), exp->rhs() };
string expUnparsed;
SgExpression* toAdd = NULL;
if (exp->variant() == ARRAY_REF && CheckConstIndexes(exp->lhs()))
{
cout << st->unparse() << endl;
if (arrayToVariable.find(expUnparsed) == arrayToVariable.end() && exp->symbol()->type()->baseType())
{
arrayToVariable[expUnparsed] = CreateVar(variableNumber, exp->symbol()->type()->baseType());
}
st->setExpression(1, arrayToVariable[expUnparsed]->copyPtr());
return;
}
for (int i = 0; i < 2; i++)
{
if (subnodes[i] && subnodes[i]->variant() == ARRAY_REF && subnodes[i]->symbol()->type()->baseType() && CheckConstIndexes(subnodes[i]->lhs()))
{
expUnparsed = subnodes[i]->unparse();
if (arrayToVariable.find(expUnparsed) == arrayToVariable.end())
{
arrayToVariable[expUnparsed] = CreateVar(variableNumber, subnodes[i]->symbol()->type()->baseType());;
}
toAdd = arrayToVariable[expUnparsed]->copyPtr();
if (toAdd)
{
if (i == 0)
{
exp->setLhs(toAdd);
}
else
{
exp->setRhs(toAdd);
}
}
}
else
{
TransformRightPart(st, subnodes[i], arrayToVariable, variableNumber);
}
}
}
static void TransformLeftPart(SgStatement* st, SgExpression* exp, unordered_map<string, SgExpression*>& arrayToVariable, int& variableNumber)
{
if (exp->symbol()->type()->variant() == T_STRING)
return;
string expUnparsed = exp->unparse();
if (arrayToVariable.find(expUnparsed) == arrayToVariable.end() && exp->symbol()->type()->baseType())
{
arrayToVariable[expUnparsed] = CreateVar(variableNumber, exp->symbol()->type()->baseType());
}
SgStatement* newStatement = new SgStatement(ASSIGN_STAT, NULL, NULL, arrayToVariable[expUnparsed]->copyPtr(), st->expr(1)->copyPtr(), NULL);
newStatement->setFileId(st->getFileId());
newStatement->setProject(st->getProject());
newStatement->setlineNumber(getNextNegativeLineNumber());
newStatement->setLocalLineNumber(st->lineNumber());
st->insertStmtBefore(*newStatement, *st->controlParent());
}
void ArrayConstantPropagation(SgProject& project)
{
unordered_map<string, SgExpression*> arrayToVariable;
int variableNumber = 0;
for (int i = 0; i < project.numberOfFiles(); i++)
{
SgFile* file = &(project.file(i));
if (!file)
continue;
const int funcNum = file->numberOfFunctions();
for (int i = 0; i < funcNum; ++i)
{
SgStatement* st = file->functions(i);
declPlace = st->lexNext();
SgStatement* lastNode = st->lastNodeOfStmt();
for (; st != lastNode; st = st->lexNext())
{
if (st->variant() == ASSIGN_STAT)
{
if (st->expr(1))
{
TransformRightPart(st, st->expr(1), arrayToVariable, variableNumber);
}
if (st->expr(0) && st->expr(0)->variant() == ARRAY_REF && CheckConstIndexes(st->expr(0)->lhs()))
{
TransformLeftPart(st, st->expr(0), arrayToVariable, variableNumber);
}
}
else if (st->variant() == FOR_NODE)
{
SgExpression* lowerBound = st->expr(0)->lhs();
SgExpression* upperBound = st->expr(0)->rhs();
string lowerBoundUnparsed = lowerBound->unparse(), upperBoundUnparsed = upperBound->unparse();
if (upperBound->variant() == ARRAY_REF && upperBound->symbol()->type()->baseType() && CheckConstIndexes(upperBound->lhs()))
{
if (arrayToVariable.find(upperBoundUnparsed) == arrayToVariable.end())
{
arrayToVariable[upperBoundUnparsed] = CreateVar(variableNumber, upperBound->symbol()->type()->baseType());
}
st->expr(0)->setRhs(arrayToVariable[upperBoundUnparsed]->copyPtr());
}
if (lowerBound->variant() == ARRAY_REF && lowerBound->symbol()->type()->baseType() && CheckConstIndexes(lowerBound->lhs()))
{
if (arrayToVariable.find(lowerBoundUnparsed) == arrayToVariable.end())
{
arrayToVariable[lowerBoundUnparsed] = CreateVar(variableNumber, lowerBound->symbol()->type()->baseType());
}
st->expr(0)->setLhs(arrayToVariable[lowerBoundUnparsed]->copyPtr());
}
}
}
}
}
}

4
src/ArrayConstantPropagation/propagation.h Normal file
View File

@@ -0,0 +1,4 @@
#pragma once
#include "../Utils/SgUtils.h"
void ArrayConstantPropagation(SgProject& project);

46
src/CFGraph/private_variables_analysis.cpp
View File

@@ -200,20 +200,46 @@ static void fillOutForFunc(const FuncInfo* func, const vector<SAPFOR::BasicBlock
outForFunc[func->funcName] = { defined, common_defined };
}
static void getDefsFromBlock(SAPFOR::BasicBlock* block, set<SAPFOR::Argument*>& res,
static bool isInstructionSpfParameter(SAPFOR::Instruction* instr)
{
SgStatement* st = instr->getOperator();
// check if this operator is SPF(ANALYSIS(PARAMETER( )))
if (st && st->variant() == ASSIGN_STAT)
{
if (st->lineNumber() < 0 && st->numberOfAttributes())
{
for (int i = 0; i < st->numberOfAttributes(); ++i)
{
SgAttribute* attr = st->getAttribute(i);
SgStatement* attributeStatement = (SgStatement*)(attr->getAttributeData());
int type = st->attributeType(i);
if (type == SPF_PARAMETER_OP)
return true;
}
}
}
return false;
}
static void getDefsFromBlock(SAPFOR::BasicBlock* block, set<SAPFOR::Argument*>& res,
const vector<pair<const Variable*, CommonBlock*>>& commonVars,
const FuncInfo* func)
{
vector<SAPFOR::Argument*> lastParamRef;
for (auto ir_block : block->getInstructions())
for (const auto &ir_block : block->getInstructions())
{
SAPFOR::Instruction* instr = ir_block->getInstruction();
if (isInstructionSpfParameter(instr))
continue;
SAPFOR::CFG_OP instr_operation = instr->getOperation();
if (instr_operation == SAPFOR::CFG_OP::PARAM)
{
SAPFOR::Argument* arg = instr->getArg1();
if(arg->getType() == SAPFOR::CFG_ARG_TYPE::VAR)
if (arg->getType() == SAPFOR::CFG_ARG_TYPE::VAR)
addPlaceWithDef(commonVars, func, arg, instr);
lastParamRef.push_back(arg);
@@ -236,12 +262,20 @@ static void getDefsFromBlock(SAPFOR::BasicBlock* block, set<SAPFOR::Argument*>&
int last_instr_num = block->getInstructions().back()->getNumber();
for (const auto& def : block->getRD_Out())
{
for (int place : def.second)
{
if (place >= first_instr_num && place <= last_instr_num && def.first->getType() == SAPFOR::CFG_ARG_TYPE::VAR)
{
SAPFOR::Instruction* instr = block->getInstructions()[place - first_instr_num]->getInstruction();
if (isInstructionSpfParameter(instr))
continue;
res.insert(def.first);
addPlaceWithDef(commonVars, func, def.first, block->getInstructions()[place - first_instr_num]->getInstruction());
addPlaceWithDef(commonVars, func, def.first, instr);
}
}
}
}
// recursively analyze FOR loops
@@ -266,7 +300,7 @@ static set<SAPFOR::BasicBlock*> analyzeLoop(LoopGraph* loop, const set<SAPFOR::B
SAPFOR::BasicBlock* head_block = NULL;
int loop_start = loop->lineNum, loop_end = loop->lineNumAfterLoop;
for (auto bb : blocks)
for (const auto &bb : blocks)
{
if (!bb || (bb->getInstructions().size() == 0))
continue;
@@ -348,7 +382,7 @@ static set<SAPFOR::BasicBlock*> analyzeLoop(LoopGraph* loop, const set<SAPFOR::B
getDefsFromBlock(*loop_it, changeValueOnExit, commonVars, func);
for (auto bb : currentLoop)
for (const auto &bb : currentLoop)
{
//fill LiveWhenLoopEnds
bool has_next_outside_body = false;

10
src/Distribution/CreateDistributionDirs.cpp
View File

@@ -274,7 +274,7 @@ static void convertTrees(const map<DIST::Array*, int> &treesIn, map<int, vector<
static DIST::Array* findBestInEqual(vector<DIST::Array*> &arrays, DIST::GraphCSR<int, double, attrType> &reducedG, DIST::Arrays<int> &allArrays)
{
DIST::Array *retVal = NULL;
vector<vector<attrType>> coefsByDims;
vector<vector<attrType>> coeffsByDims;
for (auto &array : arrays)
{
vector<int> verts;
@@ -285,7 +285,7 @@ static DIST::Array* findBestInEqual(vector<DIST::Array*> &arrays, DIST::GraphCSR
{
retVal = array;
for (auto &V : verts)
coefsByDims.push_back(reducedG.GetAllAttributes(V));
coeffsByDims.push_back(reducedG.GetAllAttributes(V));
}
else
{
@@ -294,11 +294,11 @@ static DIST::Array* findBestInEqual(vector<DIST::Array*> &arrays, DIST::GraphCSR
toCmp.push_back(reducedG.GetAllAttributes(V));
for (int z = 0; z < toCmp.size(); ++z)
{
if (toCmp[z].size() && coefsByDims[z].size())
if (toCmp[z].size() && coeffsByDims[z].size())
{
if (toCmp[z].back().first.first > coefsByDims[z].back().first.first)
if (toCmp[z].back().first.first > coeffsByDims[z].back().first.first)
{
coefsByDims = toCmp;
coeffsByDims = toCmp;
retVal = array;
break;
}

6
src/Distribution/DvmhDirective.cpp
View File

@@ -45,10 +45,10 @@ static bool findArrayRefAndCheck(SgExpression *ex, const DIST::Array* currArray,
int countOfShadows = 0;
for (int i = 0; i < ref->numberOfSubscripts(); ++i)
{
const vector<int*> &coefs = getAttributes<SgExpression*, int*>(ref->subscript(i), set<int>{ INT_VAL });
if (coefs.size() == 1)
const vector<int*> &coeffs = getAttributes<SgExpression*, int*>(ref->subscript(i), set<int>{ INT_VAL });
if (coeffs.size() == 1)
{
const pair<int, int> coef(coefs[0][0], coefs[0][1]);
const pair<int, int> coef(coeffs[0][0], coeffs[0][1]);
auto it = shiftsByAccess[i].find(coef);
if (it != shiftsByAccess[i].end())
if (it->second != 0)

12
src/Distribution/DvmhDirectiveBase.cpp
View File

@@ -364,11 +364,11 @@ static inline string calculateShifts(DIST::GraphCSR<int, double, attrType> &redu
{
if (sharedMemoryParallelization)
{
for (auto& coefs : currReadOp->first[k].coefficients)
for (auto& coeffs : currReadOp->first[k].coefficients)
{
auto currAccess = coefs.first;
auto currAccess = coeffs.first;
const int currShift = coefs.first.second;
const int currShift = coeffs.first.second;
auto itFound = shiftsByAccess[k].find(currAccess);
if (itFound == shiftsByAccess[k].end())
@@ -393,9 +393,9 @@ static inline string calculateShifts(DIST::GraphCSR<int, double, attrType> &redu
int minShift = 9999999;
int maxShift = -9999999;
for (auto &coefs : currReadOp->first[k].coefficients)
for (auto &coeffs : currReadOp->first[k].coefficients)
{
auto currAccess = coefs.first;
auto currAccess = coeffs.first;
auto result = DIST::Fx(currAccess, currRuleShadow);
if (result.first == loopRule.first)
@@ -417,7 +417,7 @@ static inline string calculateShifts(DIST::GraphCSR<int, double, attrType> &redu
auto it = remoteRegularReads.find(calcForArray);
if (it == remoteRegularReads.end())
it = remoteRegularReads.insert(it, make_pair(calcForArray, vector<ArrayOp>(calcForArray->GetDimSize())));
it->second[k].coefficients.insert(coefs);
it->second[k].coefficients.insert(coeffs);
}
}

4
src/GraphLoop/graph_loops_base.cpp
View File

@@ -1137,9 +1137,9 @@ static bool isMapped(const vector<ArrayOp> &allOps)
bool mapped = false;
for (auto &ops : allOps)
{
for (auto &coefs : ops.coefficients)
for (auto &coeffs : ops.coefficients)
{
if (coefs.first.first != 0)
if (coeffs.first.first != 0)
{
mapped = true;
break;

34
src/LoopAnalyzer/loop_analyzer.cpp
View File

@@ -247,7 +247,7 @@ static vector<int> matchSubscriptToLoopSymbols(const vector<SgForStmt*> &parentL
}
}
pair<int, int> coefs = pair<int, int>(0, 0);
pair<int, int> coeffs = pair<int, int>(0, 0);
// more than one loop symbol in subscription
if (countOfSymbols > 1)
{
@@ -326,16 +326,16 @@ static vector<int> matchSubscriptToLoopSymbols(const vector<SgForStmt*> &parentL
{
if (subscr->symbol()->id() == (parentLoops[position]->doName())->id())
{
coefs.first = 1;
coeffs.first = 1;
needToCacl = false;
}
}
if (needToCacl)
getCoefsOfSubscript(coefs, subscr, parentLoops[position]->doName());
__spf_print(PRINT_ARRAY_ARCS, " <%d %d> ", coefs.first, coefs.second);
getCoefsOfSubscript(coeffs, subscr, parentLoops[position]->doName());
__spf_print(PRINT_ARRAY_ARCS, " <%d %d> ", coeffs.first, coeffs.second);
if (coefs.first == 0) // && coefs.second == 0)
if (coeffs.first == 0) // && coeffs.second == 0)
{
if (currRegime == REMOTE_ACC)
{
@@ -346,7 +346,7 @@ static vector<int> matchSubscriptToLoopSymbols(const vector<SgForStmt*> &parentL
{
const pair<bool, string> &arrayRefString = constructArrayRefForPrint(arrayRef, dimNum, origSubscr);
__spf_print(1, "WARN: can not calculate index expression for array ref '%s' at line %d\n", arrayRefString.second.c_str(), currLine);
addInfoToVectors(loopInfo, parentLoops[position], currOrigArrayS, dimNum, coefs, UNREC_OP, numOfSubscriptions, currentW);
addInfoToVectors(loopInfo, parentLoops[position], currOrigArrayS, dimNum, coeffs, UNREC_OP, numOfSubscriptions, currentW);
if (side == LEFT)
allPositions.clear();
@@ -371,19 +371,19 @@ static vector<int> matchSubscriptToLoopSymbols(const vector<SgForStmt*> &parentL
currOp.resize(numOfSubscriptions);
//add only uniq
auto itAdd = currOp[dimNum].coefficients.find(coefs);
auto itAdd = currOp[dimNum].coefficients.find(coeffs);
if (itAdd == currOp[dimNum].coefficients.end())
itAdd = currOp[dimNum].coefficients.insert(itAdd, make_pair(coefs, currentW));
itAdd = currOp[dimNum].coefficients.insert(itAdd, make_pair(coeffs, currentW));
}
if (coefs.first < 0)
if (coeffs.first < 0)
addInfoToMap(loopInfo, parentLoops[position], currOrigArrayS, arrayRef, dimNum, REMOTE_TRUE, currLine, numOfSubscriptions);
else
//if we found regular access to array - set it false
addInfoToMap(loopInfo, parentLoops[position], currOrigArrayS, arrayRef, dimNum, REMOTE_FALSE, currLine, numOfSubscriptions);
}
if (coefs.first < 0 && sharedMemoryParallelization == 0)
if (coeffs.first < 0 && sharedMemoryParallelization == 0)
{
if (currRegime == DATA_DISTR)
{
@@ -402,15 +402,15 @@ static vector<int> matchSubscriptToLoopSymbols(const vector<SgForStmt*> &parentL
if (side == LEFT)
allPositions.clear();
else
addInfoToVectors(loopInfo, parentLoops[position], currOrigArrayS, dimNum, coefs, UNREC_OP, numOfSubscriptions, currentW);
addInfoToVectors(loopInfo, parentLoops[position], currOrigArrayS, dimNum, coeffs, UNREC_OP, numOfSubscriptions, currentW);
}
}
else
{
if (side == LEFT)
addInfoToVectors(loopInfo, parentLoops[position], currOrigArrayS, dimNum, coefs, WRITE_OP, numOfSubscriptions, currentW);
addInfoToVectors(loopInfo, parentLoops[position], currOrigArrayS, dimNum, coeffs, WRITE_OP, numOfSubscriptions, currentW);
else
addInfoToVectors(loopInfo, parentLoops[position], currOrigArrayS, dimNum, coefs, READ_OP, numOfSubscriptions, currentW);
addInfoToVectors(loopInfo, parentLoops[position], currOrigArrayS, dimNum, coeffs, READ_OP, numOfSubscriptions, currentW);
}
}
}
@@ -418,13 +418,13 @@ static vector<int> matchSubscriptToLoopSymbols(const vector<SgForStmt*> &parentL
if (currRegime == ARRAY_ACC_CORNER)
{
int *valueSubs = new int[2];
valueSubs[0] = coefs.first;
valueSubs[1] = coefs.second;
valueSubs[0] = coeffs.first;
valueSubs[1] = coeffs.second;
#ifdef __SPF
addToCollection(__LINE__, __FILE__, valueSubs, 2);
#endif
const vector<int*> &coefs = getAttributes<SgExpression*, int*>(subscr, set<int>{ INT_VAL });
if (coefs.size() == 0)
const vector<int*> &coeffs = getAttributes<SgExpression*, int*>(subscr, set<int>{ INT_VAL });
if (coeffs.size() == 0)
{
subscr->addAttribute(INT_VAL, valueSubs, sizeof(int*));
if (position != -1 && allPositions.size() == 1 && position < parentLoops.size())

16
src/Predictor/PredictScheme.cpp
View File

@@ -326,7 +326,7 @@ static json parseAlign(const map<DIST::Array*, int>& byPos, SgSymbol* srcArr, Sg
list = list->rhs();
}
vector<pair<int, int>> coefs(srcSymbs.size());
vector<pair<int, int>> coeffs(srcSymbs.size());
list = listTgt;
while (list)
{
@@ -337,8 +337,8 @@ static json parseAlign(const map<DIST::Array*, int>& byPos, SgSymbol* srcArr, Sg
has = recSymbolFind(exp, srcSymbs[z].first, VAR_REF);
if (has)
{
getCoefsOfSubscript(coefs[z], exp, srcSymbs[z].second);
if (coefs[z].first == 0)
getCoefsOfSubscript(coeffs[z], exp, srcSymbs[z].second);
if (coeffs[z].first == 0)
printInternalError(convertFileName(__FILE__).c_str(), __LINE__);
break;
}
@@ -346,14 +346,14 @@ static json parseAlign(const map<DIST::Array*, int>& byPos, SgSymbol* srcArr, Sg
list = list->rhs();
}
for (int z = 0; z < coefs.size(); ++z)
for (int z = 0; z < coeffs.size(); ++z)
{
if (coefs[z].first == 0)
if (coeffs[z].first == 0)
continue;
if (coefs[z].second)
align["rules"].push_back({ z, coefs[z].first });
if (coeffs[z].second)
align["rules"].push_back({ z, coeffs[z].first });
else
align["rules"].push_back({ z, coefs[z].first, coefs[z].second });
align["rules"].push_back({ z, coeffs[z].first, coeffs[z].second });
}
return align;
}

123
src/PrivateAnalyzer/private_arrays_search.cpp
View File

@@ -12,9 +12,38 @@
#include "SgUtils.h"
#include "graph_loops.h"
#include "CFGraph/CFGraph.h"
#include "utils.h"
using namespace std;
static void RemoveEmptyPoints(ArrayAccessingIndexes& container)
{
ArrayAccessingIndexes resultContainer;
unordered_set<string> toRemove;
for (auto& [arrayName, accessingSet] : container)
{
vector<vector<ArrayDimension>> points;
for (auto& arrayPoint : accessingSet.GetElements())
{
if (!arrayPoint.empty())
points.push_back(arrayPoint);
}
if (points.size() < accessingSet.GetElements().size() && !points.empty())
resultContainer[arrayName] = points;
if (points.empty())
toRemove.insert(arrayName);
}
for (const string& name : toRemove)
container.erase(name);
for (auto& [arrayName, accessingSet] : resultContainer)
container[arrayName] = accessingSet;
}
static void Collapse(Region* region)
{
if (region->getBasickBlocks().empty())
@@ -37,13 +66,13 @@ static void Collapse(Region* region)
region->array_use[arrayName] = region->array_use[arrayName].Union(diff);
}
}
ArrayAccessingIndexes useUnion;
for (auto& byBlock : region->getBasickBlocks())
for (auto& [arrayName, arrayRanges] : byBlock->array_use)
useUnion[arrayName] = useUnion[arrayName].Union(byBlock->array_use[arrayName]);
for (auto& [arrayName, arrayRanges] : useUnion)
region->array_priv[arrayName] = useUnion[arrayName].Diff(region->array_use[arrayName]);
region->array_priv = region->array_use;
for (Region* prevBlock : region->getHeader()->getPrevRegions())
prevBlock->replaceInNextRegions(region, region->getHeader());
@@ -74,6 +103,7 @@ static void SolveDataFlowIteratively(Region* DFG)
newIn.clear();
continue;
}
for (const auto& [arrayName, accessSet] : prevBlock->array_out)
{
if (newIn.find(arrayName) != newIn.end())
@@ -86,6 +116,7 @@ static void SolveDataFlowIteratively(Region* DFG)
b->array_in = move(newIn);
ArrayAccessingIndexes newOut;
if (b->array_def.empty())
newOut = b->array_in;
else if (b->array_in.empty())
@@ -121,21 +152,83 @@ static void SolveDataFlow(Region* DFG)
Collapse(DFG);
}
map<LoopGraph*, ArrayAccessingIndexes> FindPrivateArrays(map<string, vector<LoopGraph*>> &loopGraph, map<FuncInfo*, vector<SAPFOR::BasicBlock*>>& FullIR)
{
map<LoopGraph*, ArrayAccessingIndexes> result;
for (const auto& [loopName, loops] : loopGraph)
static void AddPrivateArraysToLoop(LoopGraph* loop, const ArrayAccessingIndexes& privates, set<SgStatement*>& insertedPrivates)
{
SgStatement* spfStat = new SgStatement(SPF_ANALYSIS_DIR);
spfStat->setlineNumber(loop->loop->lineNumber());
spfStat->setFileName(loop->loop->fileName());
SgExpression* toAdd = new SgExpression(EXPR_LIST, new SgExpression(ACC_PRIVATE_OP), NULL, NULL);
set<SgSymbol*> arraysToInsert;
for (const auto& [_, accessingSet] : privates)
{
for (const auto& loop : loops)
for (const auto& arrayElement : accessingSet.GetElements())
{
for (const auto& [funcInfo, blocks]: FullIR)
{
Region* loopRegion = new Region(loop, blocks);
SolveDataFlow(loopRegion);
result[loop] = loopRegion->array_priv;
delete(loopRegion);
}
if (arrayElement.empty())
continue;
arraysToInsert.insert(arrayElement[0].array->symbol());
}
}
spfStat->setExpression(0, *toAdd);
toAdd = toAdd->lhs();
bool first = true;
for (auto& elem : arraysToInsert)
{
if (first)
{
toAdd->setLhs(new SgExpression(EXPR_LIST));
toAdd = toAdd->lhs();
first = false;
}
else
{
toAdd->setRhs(new SgExpression(EXPR_LIST));
toAdd = toAdd->rhs();
}
toAdd->setLhs(new SgVarRefExp(elem));
}
if (arraysToInsert.size() == 0)
printInternalError(convertFileName(__FILE__).c_str(), __LINE__);
loop->loop->insertStmtBefore(*spfStat, *loop->loop->controlParent());
insertedPrivates.insert(spfStat);
}
void FindPrivateArrays(map<string, vector<LoopGraph*>> &loopGraph, map<FuncInfo*, vector<SAPFOR::BasicBlock*>>& FullIR, set<SgStatement*> &insertedPrivates)
{
map<LoopGraph*, ArrayAccessingIndexes> result;
for (const auto& [fileName, loops] : loopGraph)
{
SgFile::switchToFile(fileName);
for (const auto& loop : loops)
{
if (!loop->isFor())
continue;
SgStatement* search_func = loop->loop->GetOriginal();
while (search_func && (!isSgProgHedrStmt(search_func)))
search_func = search_func->controlParent();
for (const auto& [funcInfo, blocks]: FullIR)
{
if (funcInfo->fileName == fileName && funcInfo->funcPointer->GetOriginal() == search_func)
{
Region* loopRegion = new Region(loop, blocks);
if (loopRegion->getBasickBlocks().size() <= 1)
{
delete(loopRegion);
continue;
}
SolveDataFlow(loopRegion);
RemoveEmptyPoints(loopRegion->array_priv);
result[loop] = loopRegion->array_priv;
delete(loopRegion);
}
}
if (result.find(loop) != result.end() && !result[loop].empty())
AddPrivateArraysToLoop(loop, result[loop], insertedPrivates);
}
}
return result;
}

3
src/PrivateAnalyzer/private_arrays_search.h
View File

@@ -2,11 +2,12 @@
#include <vector>
#include <map>
#include <set>
#include <unordered_set>
#include "range_structures.h"
#include "graph_loops.h"
#include "CFGraph/CFGraph.h"
std::map<LoopGraph*, ArrayAccessingIndexes> FindPrivateArrays(std::map<std::string, std::vector<LoopGraph*>>& loopGraph, std::map<FuncInfo*, std::vector<SAPFOR::BasicBlock*>>& FullIR);
void FindPrivateArrays(std::map<std::string, std::vector<LoopGraph*>>& loopGraph, std::map<FuncInfo*, std::vector<SAPFOR::BasicBlock*>>& FullIR, std::set<SgStatement*>& insertedPrivates);
std::pair<SAPFOR::BasicBlock*, std::unordered_set<SAPFOR::BasicBlock*>> GetBasicBlocksForLoop(const LoopGraph* loop, const std::vector<SAPFOR::BasicBlock*> blocks);

25
src/PrivateAnalyzer/range_structures.cpp
View File

@@ -47,7 +47,7 @@ static ArrayDimension* DimensionIntersection(const ArrayDimension& dim1, const A
uint64_t start3 = dim1.start + x0 * dim1.step;
uint64_t step3 = c * dim1.step;
ArrayDimension* result = new(ArrayDimension){ start3, step3, tMax + 1 };
ArrayDimension* result = new(ArrayDimension){ start3, step3, tMax + 1 , dim1.array};
return result;
}
@@ -61,21 +61,16 @@ static vector<ArrayDimension> DimensionDifference(const ArrayDimension& dim1, co
vector<ArrayDimension> result;
/* add the part before intersection */
if (dim1.start < intersection->start)
result.push_back({ dim1.start, dim1.step, (intersection->start - dim1.start) / dim1.step });
result.push_back({ dim1.start, dim1.step, (intersection->start - dim1.start) / dim1.step, dim1.array});
/* add the parts between intersection steps */
uint64_t start = (intersection->start - dim1.start) / dim1.step;
uint64_t interValue = intersection->start;
for (int64_t i = start; dim1.start + i * dim1.step <= intersection->start + intersection->step * (intersection->tripCount - 1); i++)
if (intersection->step > dim1.step)
{
uint64_t centerValue = dim1.start + i * dim1.step;
if (centerValue == interValue)
uint64_t start = (intersection->start - dim1.start) / dim1.step;
uint64_t interValue = intersection->start;
for (int64_t i = start; interValue <= intersection->start + intersection->step * (intersection->tripCount - 1); i++)
{
if (i - start > 1)
{
result.push_back({ dim1.start + (start + 1) * dim1.step, dim1.step, i - start - 1 });
start = i;
}
result.push_back({interValue + dim1.step, dim1.step, intersection->step / dim1.step, dim1.array});
interValue += intersection->step;
}
}
@@ -85,7 +80,7 @@ static vector<ArrayDimension> DimensionDifference(const ArrayDimension& dim1, co
/* first value after intersection */
uint64_t right_start = intersection->start + intersection->step * (intersection->tripCount - 1) + dim1.step;
uint64_t tripCount = (dim1.start + dim1.step * dim1.tripCount - right_start) / dim1.step;
result.push_back({ right_start, dim1.step, tripCount });
result.push_back({ right_start, dim1.step, tripCount, dim1.array });
}
delete(intersection);
return result;
@@ -216,6 +211,10 @@ void AccessingSet::Insert(const vector<ArrayDimension>& element)
}
AccessingSet AccessingSet::Union(const AccessingSet& source) {
if (source.GetElements().empty())
return *this;
if (allElements.empty())
return source;
AccessingSet result;
for (auto& element : source.GetElements())
result.Insert(element);

3
src/PrivateAnalyzer/range_structures.h
View File

@@ -6,9 +6,12 @@
#include <string>
#include <cstdint>
#include "SgUtils.h"
struct ArrayDimension
{
uint64_t start, step, tripCount;
SgArrayRefExp* array;
};
class AccessingSet {

83
src/PrivateAnalyzer/region.cpp
View File

@@ -4,6 +4,7 @@
#include<unordered_map>
#include<string>
#include <numeric>
#include <iostream>
#include "range_structures.h"
#include "region.h"
@@ -104,15 +105,33 @@ static int GetDefUseArray(SAPFOR::BasicBlock* block, LoopGraph* loop, ArrayAcces
auto operation = instruction->getInstruction()->getOperation();
auto type = instruction->getInstruction()->getArg1()->getType();
if (operation == SAPFOR::CFG_OP::ASSIGN && instruction->getInstruction()->getResult()->getType() == SAPFOR::CFG_ARG_TYPE::ARRAY)
{
SgStatement* op = instruction->getInstruction()->getOperator();
if (op && op->expr(0) && isArrayRef(op->expr(0)) && op->expr(0)->symbol() && op->expr(0)->type())
{
if (isSgArrayType(op->expr(0)->symbol()->type()))
{
SgArrayType* arrayType = (SgArrayType*)op->expr(0)->symbol()->type();
int dimCount = ((SgArrayType*)op->expr(0)->symbol()->type())->dimension();
vector<ArrayDimension> point;
for (int i = 0; i < dimCount; i++)
{
string strDimLength = arrayType->sizeInDim(i)->unparse();
if (arrayType->sizeInDim(i)->variant() == INT_VAL && strDimLength != "0")
point.push_back({ 1ULL, 1ULL, (uint64_t)stoi(strDimLength), (SgArrayRefExp*)op->expr(0) });
}
if (point.size() == dimCount)
def[instruction->getInstruction()->getResult()->getValue()] = AccessingSet({point});
}
}
}
if ((operation == SAPFOR::CFG_OP::STORE || operation == SAPFOR::CFG_OP::LOAD) && type == SAPFOR::CFG_ARG_TYPE::ARRAY)
{
vector<SAPFOR::Argument*> index_vars;
vector<int> refPos;
string array_name;
if (operation == SAPFOR::CFG_OP::STORE)
array_name = instruction->getInstruction()->getArg1()->getValue();
else
array_name = instruction->getInstruction()->getArg2()->getValue();
string array_name = instruction->getInstruction()->getArg1()->getValue();
int j = i - 1;
while (j >= 0 && instructions[j]->getInstruction()->getOperation() == SAPFOR::CFG_OP::REF)
@@ -127,29 +146,15 @@ static int GetDefUseArray(SAPFOR::BasicBlock* block, LoopGraph* loop, ArrayAcces
vector<ArrayDimension> accessPoint(n);
auto* ref = isSgArrayRefExp(instruction->getInstruction()->getExpression());
vector<pair<int, int>> coefsForDims;
for (int i = 0; ref && i < ref->numberOfSubscripts(); ++i)
{
const vector<int*>& coefs = getAttributes<SgExpression*, int*>(ref->subscript(i), set<int>{ INT_VAL });
if (coefs.size() == 1)
{
const pair<int, int> coef(coefs[0][0], coefs[0][1]);
coefsForDims.push_back(coef);
}
int fillCount = 0;
}
if(coefsForDims.empty())
printInternalError(convertFileName(__FILE__).c_str(), __LINE__);
while (!index_vars.empty())
while (!index_vars.empty() && !refPos.empty())
{
auto var = index_vars.back();
int currentVarPos = refPos.back();
pair<int, int> currentCoefs = coefsForDims.back();
ArrayDimension current_dim;
if (var->getType() == SAPFOR::CFG_ARG_TYPE::CONST)
current_dim = { stoul(var->getValue()), 1, 1 };
current_dim = { stoul(var->getValue()), 1, 1, ref};
else
{
string name, full_name = var->getValue();
@@ -175,21 +180,28 @@ static int GetDefUseArray(SAPFOR::BasicBlock* block, LoopGraph* loop, ArrayAcces
return -1;
}
uint64_t start = currentLoop->startVal * currentCoefs.first + currentCoefs.second;
uint64_t step = currentCoefs.first;
current_dim = { start, step, (uint64_t)currentLoop->calculatedCountOfIters };
uint64_t start = currentLoop->startVal;
uint64_t step = currentLoop->stepVal;
uint64_t iters = currentLoop->calculatedCountOfIters;
current_dim = { start, step, iters, ref };
}
accessPoint[n - index_vars.size()] = current_dim;
if (current_dim.start != 0 && current_dim.step != 0 && current_dim.tripCount != 0)
{
accessPoint[n - index_vars.size()] = current_dim;
fillCount++;
}
index_vars.pop_back();
refPos.pop_back();
coefsForDims.pop_back();
}
if (operation == SAPFOR::CFG_OP::STORE)
def[array_name].Insert(accessPoint);
else
use[array_name].Insert(accessPoint);
if (fillCount == accessPoint.size())
{
if (operation == SAPFOR::CFG_OP::STORE)
def[array_name].Insert(accessPoint);
else
use[array_name].Insert(accessPoint);
}
}
}
return 0;
@@ -227,8 +239,11 @@ static Region* CreateSubRegion(LoopGraph* loop, const vector<SAPFOR::BasicBlock*
region->addBasickBlocks(bbToRegion.at(block));
for (LoopGraph* childLoop : loop->children)
{
if (!childLoop->isFor())
continue;
region->addSubRegions(CreateSubRegion(childLoop, Blocks, bbToRegion));
}
return region;
}
@@ -247,5 +262,9 @@ Region::Region(LoopGraph* loop, const vector<SAPFOR::BasicBlock*>& Blocks)
SetConnections(bbToRegion, blockSet);
//create subRegions
for (LoopGraph* childLoop : loop->children)
{
if (!childLoop->isFor())
continue;
subRegions.insert(CreateSubRegion(childLoop, Blocks, bbToRegion));
}
}

24
src/Sapfor.cpp
View File

@@ -46,6 +46,7 @@
#include "DynamicAnalysis/gCov_parser_func.h"
#include "DynamicAnalysis/createParallelRegions.h"
#include "ArrayConstantPropagation/propagation.h"
#include "DirectiveProcessing/directive_analyzer.h"
#include "DirectiveProcessing/directive_creator.h"
#include "DirectiveProcessing/insert_directive.h"
@@ -89,7 +90,7 @@
#include "Transformations/DeadCodeRemoving/dead_code.h"
#include "Transformations/RenameSymbols/rename_symbols.h"
#include "Transformations/FunctionInlining/inliner.h"
#include "Transformations/SwapOperators/swap_operators.h"
#include "Transformations/MoveOperators/move_operators.h"
#include "ProjectParameters/projectParameters.h"
@@ -280,7 +281,8 @@ static string unparseProjectIfNeed(SgFile* file, const int curr_regime, const bo
for (SgStatement* st = file->firstStatement(); st; st = st->lexNext())
if (isSPF_stat(st)) // except sapfor parallel regions and if attributes dont move
if (st->variant() != SPF_PARALLEL_REG_DIR && st->variant() != SPF_END_PARALLEL_REG_DIR)
toDel.push_back(st);
if (insertedPrivates.find(st) == insertedPrivates.end())
toDel.push_back(st);
for (auto& elem : toDel)
elem->deleteStmt();
@@ -940,8 +942,8 @@ static bool runAnalysis(SgProject &project, const int curr_regime, const bool ne
internalExit = err;
}
}
else if (curr_regime == SWAP_OPERATORS)
runSwapOperators(file, loopGraph, fullIR, countOfTransform);
else if (curr_regime == MOVE_OPERATORS)
moveOperators(file, loopGraph, fullIR, countOfTransform);
else if (curr_regime == PRIVATE_REMOVING_ANALYSIS)
{
auto itFound = loopGraph.find(file->filename());
@@ -1022,8 +1024,6 @@ static bool runAnalysis(SgProject &project, const int curr_regime, const bool ne
if(func->funcPointer->variant() != ENTRY_STAT)
countOfTransform += removeDeadCode(func->funcPointer, allFuncInfo, commonBlocks);
}
else if (curr_regime == FIND_PRIVATE_ARRAYS)
FindPrivateArrays(loopGraph, fullIR);
else if (curr_regime == TEST_PASS)
{
//test pass
@@ -1041,7 +1041,7 @@ static bool runAnalysis(SgProject &project, const int curr_regime, const bool ne
PRIVATE_ARRAYS_EXPANSION,
PRIVATE_ARRAYS_SHRINKING,
REMOVE_DEAD_CODE,
SWAP_OPERATORS };
MOVE_OPERATORS };
if ((countOfTransform == 0 || internalExit > 0) && applyFor.find(curr_regime) != applyFor.end())
{
@@ -1920,6 +1920,11 @@ static bool runAnalysis(SgProject &project, const int curr_regime, const bool ne
}
else if (curr_regime == TRANSFORM_ASSUMED_SIZE_PARAMETERS)
transformAssumedSizeParameters(allFuncInfo);
else if (curr_regime == FIND_PRIVATE_ARRAYS_ANALYSIS)
FindPrivateArrays(loopGraph, fullIR, insertedPrivates);
else if (curr_regime == ARRAY_PROPAGATION)
ArrayConstantPropagation(project);
const float elapsed = duration_cast<milliseconds>(high_resolution_clock::now() - timeForPass).count() / 1000.;
const float elapsedGlobal = duration_cast<milliseconds>(high_resolution_clock::now() - globalTime).count() / 1000.;
@@ -2338,7 +2343,7 @@ void runPass(const int curr_regime, const char *proj_name, const char *folderNam
case INSERT_NO_DISTR_FLAGS_FROM_GUI:
case PRIVATE_REMOVING:
case RENAME_INLCUDES:
case SWAP_OPERATORS:
case MOVE_OPERATORS:
runAnalysis(*project, curr_regime, true, "", folderName);
break;
case INLINE_PROCEDURES:
@@ -2378,6 +2383,7 @@ void runPass(const int curr_regime, const char *proj_name, const char *folderNam
case SUBST_EXPR_RD_AND_UNPARSE:
case SUBST_EXPR_AND_UNPARSE:
case REMOVE_DEAD_CODE_AND_UNPARSE:
case FIND_PRIVATE_ARRAYS:
if (folderName)
runAnalysis(*project, UNPARSE_FILE, true, "", folderName);
else
@@ -2639,7 +2645,7 @@ int main(int argc, char **argv)
}
}
if (curr_regime == INSERT_PARALLEL_DIRS_NODIST)
if (curr_regime == INSERT_PARALLEL_DIRS_NODIST || curr_regime == FIND_PRIVATE_ARRAYS)
{
ignoreArrayDistributeState = true;
sharedMemoryParallelization = 1;

8
src/Sapfor.h
View File

@@ -122,7 +122,7 @@ enum passes {
CREATE_INTER_TREE,
INSERT_INTER_TREE,
SWAP_OPERATORS,
MOVE_OPERATORS,
SHADOW_GROUPING,
INLINE_PROCEDURES,
@@ -185,9 +185,11 @@ enum passes {
SET_IMPLICIT_NONE,
RENAME_INLCUDES,
FIND_PRIVATE_ARRAYS_ANALYSIS,
FIND_PRIVATE_ARRAYS,
TRANSFORM_ASSUMED_SIZE_PARAMETERS,
ARRAY_PROPAGATION,
TEST_PASS,
EMPTY_PASS
@@ -321,7 +323,7 @@ static void setPassValues()
passNames[CHECK_PAR_REG_DIR] = "CHECK_PAR_REG_DIR";
passNames[CREATE_INTER_TREE] = "CREATE_INTER_TREE";
passNames[INSERT_INTER_TREE] = "INSERT_INTER_TREE";
passNames[SWAP_OPERATORS] = "SWAP_OPERATORS";
passNames[MOVE_OPERATORS] = "MOVE_OPERATORS";
passNames[CREATE_PARALLEL_REGIONS] = "CREATE_PARALLEL_REGIONS";
passNames[PRIVATE_REMOVING_ANALYSIS] = "PRIVATE_REMOVING_ANALYSIS";
passNames[PRIVATE_REMOVING] = "PRIVATE_REMOVING";
@@ -374,9 +376,11 @@ static void setPassValues()
passNames[SET_IMPLICIT_NONE] = "SET_IMPLICIT_NONE";
passNames[RENAME_INLCUDES] = "RENAME_INLCUDES";
passNames[INSERT_NO_DISTR_FLAGS_FROM_GUI] = "INSERT_NO_DISTR_FLAGS_FROM_GUI";
passNames[FIND_PRIVATE_ARRAYS_ANALYSIS] = "FIND_PRIVATE_ARRAYS_ANALYSIS";
passNames[FIND_PRIVATE_ARRAYS] = "FIND_PRIVATE_ARRAYS";
passNames[TRANSFORM_ASSUMED_SIZE_PARAMETERS] = "TRANSFORM_ASSUMED_SIZE_PARAMETERS";
passNames[ARRAY_PROPAGATION] = "ARRAY_PROPAGATION";
passNames[TEST_PASS] = "TEST_PASS";
}

5
src/SapforData.h
View File

@@ -175,6 +175,11 @@ std::set<std::tuple<std::string, int, std::string>> parametersOfProject; // [fil
//for GET_MIN_MAX_BLOCK_DIST
std::pair<int, int> min_max_block = std::make_pair(-1, -1);
//
//for FIND_PRIVATE_ARRAYS
std::set<SgStatement*> insertedPrivates;
//
const char* passNames[EMPTY_PASS + 1];
const char* optionNames[EMPTY_OPTION + 1];
bool passNamesWasInit = false;

66
src/Transformations/LoopCombining/loops_combiner.cpp
View File

@@ -1123,7 +1123,7 @@ static bool hasDependenciesBetweenArrays(LoopGraph* firstLoop, LoopGraph* loop,
for (int d = 0; d < dimensions; ++d)
{
//по измерениям массива отображение на цикл вложенности d
vector<set<pair<int, int>>> coefsRead[2], coefsWrite[2];
vector<set<pair<int, int>>> coeffsRead[2], coeffsWrite[2];
checkNull(currLoop[0], convertFileName(__FILE__).c_str(), __LINE__);
checkNull(currLoop[1], convertFileName(__FILE__).c_str(), __LINE__);
@@ -1133,31 +1133,31 @@ static bool hasDependenciesBetweenArrays(LoopGraph* firstLoop, LoopGraph* loop,
auto it = currLoop[k]->readOpsForLoop.find(array);
if (it != currLoop[k]->readOpsForLoop.end())
{
if (coefsRead[k].size() == 0)
coefsRead[k].resize(it->second.size());
if (coeffsRead[k].size() == 0)
coeffsRead[k].resize(it->second.size());
for (int z = 0; z < it->second.size(); ++z)
if (it->second[z].coefficients.size())
for (auto& coef : it->second[z].coefficients)
coefsRead[k][z].insert(coef.first);
coeffsRead[k][z].insert(coef.first);
}
auto itW = currLoop[k]->writeOpsForLoop.find(array);
if (itW != currLoop[k]->writeOpsForLoop.end())
{
if (coefsWrite[k].size() == 0)
coefsWrite[k].resize(itW->second.size());
if (coeffsWrite[k].size() == 0)
coeffsWrite[k].resize(itW->second.size());
for (int z = 0; z < itW->second.size(); ++z)
if (itW->second[z].coefficients.size())
for (auto& coef : itW->second[z].coefficients)
coefsWrite[k][z].insert(coef.first);
coeffsWrite[k][z].insert(coef.first);
}
}
//нет записей, значит нет зависимости
bool nulWrite = true;
for (auto& wr : coefsWrite)
for (auto& wr : coeffsWrite)
for (auto& elem : wr)
if (elem.size() != 0)
nulWrite = false;
@@ -1168,62 +1168,62 @@ static bool hasDependenciesBetweenArrays(LoopGraph* firstLoop, LoopGraph* loop,
// если чтение в одном цикле и запись (и наоборот) в другом идут по разным правилам, то пока что это зависимость.
// здесь можно уточнить.
const int len = std::max(coefsWrite[0].size(), coefsRead[0].size());
const int len = std::max(coeffsWrite[0].size(), coeffsRead[0].size());
int countW[2] = { 0, 0 };
int countR[2] = { 0, 0 };
for (int L = 0; L < 2; ++L)
for (int z = 0; z < coefsWrite[L].size(); ++z)
countW[L] += (coefsWrite[L][z].size() ? 1 : 0);
for (int z = 0; z < coeffsWrite[L].size(); ++z)
countW[L] += (coeffsWrite[L][z].size() ? 1 : 0);
for (int L = 0; L < 2; ++L)
for (int z = 0; z < coefsRead[L].size(); ++z)
countR[L] += (coefsRead[L][z].size() ? 1 : 0);
for (int z = 0; z < coeffsRead[L].size(); ++z)
countR[L] += (coeffsRead[L][z].size() ? 1 : 0);
for (int p = 0; p < len; ++p)
{
if (coefsWrite[1].size() && coefsWrite[0].size())
if (coefsWrite[0][p].size() != 0 && coefsWrite[1][p].size() != 0)
if (coefsWrite[0][p] != coefsWrite[1][p])
if (coeffsWrite[1].size() && coeffsWrite[0].size())
if (coeffsWrite[0][p].size() != 0 && coeffsWrite[1][p].size() != 0)
if (coeffsWrite[0][p] != coeffsWrite[1][p])
return true;
if (coefsRead[1].size() && coefsWrite[0].size())
if (coefsWrite[0][p].size() != 0 && coefsRead[1][p].size() != 0)
if (coefsWrite[0][p] != coefsRead[1][p])
if (coeffsRead[1].size() && coeffsWrite[0].size())
if (coeffsWrite[0][p].size() != 0 && coeffsRead[1][p].size() != 0)
if (coeffsWrite[0][p] != coeffsRead[1][p])
return true;
if (coefsWrite[1].size() && coefsRead[0].size())
if (coefsWrite[1][p].size() != 0 && coefsRead[0][p].size() != 0)
if (coefsWrite[1][p] != coefsRead[0][p])
if (coeffsWrite[1].size() && coeffsRead[0].size())
if (coeffsWrite[1][p].size() != 0 && coeffsRead[0][p].size() != 0)
if (coeffsWrite[1][p] != coeffsRead[0][p])
return true;
//отображение на разные измерения
if (coefsWrite[1].size() && coefsWrite[0].size())
if (coeffsWrite[1].size() && coeffsWrite[0].size())
{
if (coefsWrite[0][p].size() != 0 && coefsWrite[1][p].size() == 0 && countW[1] ||
coefsWrite[0][p].size() == 0 && coefsWrite[1][p].size() != 0 && countW[0])
if (coeffsWrite[0][p].size() != 0 && coeffsWrite[1][p].size() == 0 && countW[1] ||
coeffsWrite[0][p].size() == 0 && coeffsWrite[1][p].size() != 0 && countW[0])
return true;
}
if (coefsRead[1].size() && coefsWrite[0].size())
if (coeffsRead[1].size() && coeffsWrite[0].size())
{
if (coefsWrite[0][p].size() != 0 && coefsRead[1][p].size() == 0 && countR[1] ||
coefsWrite[0][p].size() == 0 && coefsRead[1][p].size() != 0 && countW[0])
if (coeffsWrite[0][p].size() != 0 && coeffsRead[1][p].size() == 0 && countR[1] ||
coeffsWrite[0][p].size() == 0 && coeffsRead[1][p].size() != 0 && countW[0])
return true;
}
if (coefsWrite[1].size() && coefsRead[1].size())
if (coeffsWrite[1].size() && coeffsRead[1].size())
{
if (coefsWrite[1][p].size() != 0 && coefsRead[0][p].size() == 0 && countR[0] ||
coefsWrite[1][p].size() == 0 && coefsRead[0][p].size() != 0 && countW[1])
if (coeffsWrite[1][p].size() != 0 && coeffsRead[0][p].size() == 0 && countR[0] ||
coeffsWrite[1][p].size() == 0 && coeffsRead[0][p].size() != 0 && countW[1])
return true;
}
//где то нет правил отображения вообще, но есть факт его наличия.
if ( ((coefsWrite[0].size() == 0 && coefsRead[0].size() == 0) && (countW[0] == 0 && countR[0] == 0))
if ( ((coeffsWrite[0].size() == 0 && coeffsRead[0].size() == 0) && (countW[0] == 0 && countR[0] == 0))
||
((coefsWrite[1].size() == 0 && coefsRead[1].size() == 0) && (countW[1] == 0 && countR[1] == 0)) )
((coeffsWrite[1].size() == 0 && coeffsRead[1].size() == 0) && (countW[1] == 0 && countR[1] == 0)) )
return true;
}

826
src/Transformations/MoveOperators/move_operators.cpp Normal file
View File

@@ -0,0 +1,826 @@
#include <map>
#include <unordered_set>
#include <vector>
#include <queue>
#include <iostream>
#include <algorithm>
#include "../../Utils/errors.h"
#include "../../Utils/SgUtils.h"
#include "../../GraphCall/graph_calls.h"
#include "../../GraphCall/graph_calls_func.h"
#include "../../CFGraph/CFGraph.h"
#include "../../CFGraph/IR.h"
#include "../../GraphLoop/graph_loops.h"
#include "move_operators.h"
using namespace std;
static vector<SAPFOR::IR_Block*> findInstructionsFromOperator(SgStatement* st, const vector<SAPFOR::BasicBlock*>& Blocks) {
vector<SAPFOR::IR_Block*> result;
string filename = st->fileName();
for (auto& block: Blocks) {
vector<SAPFOR::IR_Block*> instructionsInBlock = block->getInstructions();
for (auto& instruction: instructionsInBlock) {
SgStatement* curOperator = instruction->getInstruction()->getOperator();
if (curOperator->lineNumber() == st->lineNumber())
result.push_back(instruction);
}
}
return result;
}
const unordered_set<int> loop_tags = { FOR_NODE };
const unordered_set<int> control_tags = { IF_NODE, ELSEIF_NODE, DO_WHILE_NODE, WHILE_NODE, LOGIF_NODE };
const unordered_set<int> control_end_tags = { CONTROL_END };
struct OperatorInfo {
SgStatement* stmt;
set<string> usedVars;
set<string> definedVars;
int lineNumber;
bool isMovable;
OperatorInfo(SgStatement* s) : stmt(s), lineNumber(s->lineNumber()), isMovable(true) { }
};
static bool isStatementEmbedded(SgStatement* stmt, SgStatement* parent) {
if (!stmt || !parent || stmt == parent)
return false;
if (parent->variant() == LOGIF_NODE) {
if (stmt->lineNumber() == parent->lineNumber())
return true;
SgStatement* current = parent;
SgStatement* lastNode = parent->lastNodeOfStmt();
while (current && current != lastNode) {
if (current == stmt)
return true;
if (current->isIncludedInStmt(*stmt))
return true;
current = current->lexNext();
}
}
if (parent->isIncludedInStmt(*stmt))
return true;
return false;
}
static bool isLoopBoundary(SgStatement* stmt) {
if (!stmt)
return false;
if (stmt->variant() == FOR_NODE || stmt->variant() == CONTROL_END)
return true;
return false;
}
static bool isPartOfNestedLoop(SgStatement* stmt, SgForStmt* loop) {
if (!stmt || !loop)
return false;
SgStatement* loopStart = loop->lexNext();
SgStatement* loopEnd = loop->lastNodeOfStmt();
if (!loopStart || !loopEnd)
return false;
if (stmt->lineNumber() < loopStart->lineNumber() || stmt->lineNumber() > loopEnd->lineNumber())
return false;
SgStatement* current = loopStart;
while (current && current != loopEnd) {
if (current->variant() == FOR_NODE && current != loop) {
SgForStmt* nestedLoop = (SgForStmt*)current;
SgStatement* nestedStart = nestedLoop->lexNext();
SgStatement* nestedEnd = nestedLoop->lastNodeOfStmt();
if (nestedStart && nestedEnd &&
stmt->lineNumber() >= nestedStart->lineNumber() &&
stmt->lineNumber() <= nestedEnd->lineNumber()) {
return true;
}
}
current = current->lexNext();
}
return false;
}
static bool canSafelyExtract(SgStatement* stmt, SgForStmt* loop) {
if (!stmt || !loop)
return false;
if (isLoopBoundary(stmt))
return false;
if (control_tags.find(stmt->variant()) != control_tags.end())
return false;
if (isPartOfNestedLoop(stmt, loop))
return false;
SgStatement* loopStart = loop->lexNext();
SgStatement* loopEnd = loop->lastNodeOfStmt();
if (!loopStart || !loopEnd)
return false;
SgStatement* current = loopStart;
while (current && current != loopEnd) {
if (current->variant() == LOGIF_NODE && current->lineNumber() == stmt->lineNumber())
return false;
if (control_tags.find(current->variant()) != control_tags.end())
if (isStatementEmbedded(stmt, current))
return false;
if (current == stmt)
break;
current = current->lexNext();
}
return true;
}
static vector<OperatorInfo> analyzeOperatorsInLoop(SgForStmt* loop, const vector<SAPFOR::BasicBlock*>& blocks,
const map<FuncInfo*, vector<SAPFOR::BasicBlock*>>& FullIR) {
vector<OperatorInfo> operators;
SgStatement* loopStart = loop->lexNext();
SgStatement* loopEnd = loop->lastNodeOfStmt();
if (!loopStart || !loopEnd)
return operators;
SgStatement* current = loopStart;
unordered_set<SgStatement*> visited;
while (current && current != loopEnd) {
if (visited.find(current) != visited.end())
break;
visited.insert(current);
if (isLoopBoundary(current)) {
current = current->lexNext();
continue;
}
if (current->variant() == FOR_NODE && current != loop) {
SgStatement* nestedEnd = current->lastNodeOfStmt();
if (nestedEnd)
current = nestedEnd->lexNext();
else
current = current->lexNext();
continue;
}
if (isSgExecutableStatement(current)) {
if (control_tags.find(current->variant()) != control_tags.end()) {
current = current->lexNext();
continue;
}
if (current->variant() != ASSIGN_STAT) {
current = current->lexNext();
continue;
}
OperatorInfo opInfo(current);
vector<SAPFOR::IR_Block*> irBlocks = findInstructionsFromOperator(current, blocks);
for (auto irBlock : irBlocks) {
if (!irBlock || !irBlock->getInstruction())
continue;
const SAPFOR::Instruction* instr = irBlock->getInstruction();
if (instr->getArg1()) {
string varName = getNameByArg(instr->getArg1());
if (!varName.empty())
opInfo.usedVars.insert(varName);
}
if (instr->getArg2()) {
string varName = getNameByArg(instr->getArg2());
if (!varName.empty())
opInfo.usedVars.insert(varName);
}
if (instr->getResult()) {
string varName = getNameByArg(instr->getResult());
if (!varName.empty())
opInfo.definedVars.insert(varName);
}
}
operators.push_back(opInfo);
}
current = current->lexNext();
}
return operators;
}
static map<string, vector<SgStatement*>> findVariableDefinitions(SgForStmt* loop, vector<OperatorInfo>& operators) {
map<string, vector<SgStatement*>> varDefinitions;
for (auto& op : operators)
for (const string& var : op.definedVars)
varDefinitions[var].push_back(op.stmt);
return varDefinitions;
}
static int calculateDistance(SgStatement* from, SgStatement* to) {
if (!from || !to)
return INT_MAX;
return abs(to->lineNumber() - from->lineNumber());
}
static SgStatement* findBestPosition(SgStatement* operatorStmt, const vector<OperatorInfo>& operators,
const map<string, vector<SgStatement*>>& varDefinitions, SgForStmt* loop) {
const OperatorInfo* opInfo = nullptr;
for (auto& op : operators) {
if (op.stmt == operatorStmt) {
opInfo = &op;
break;
}
}
if (!opInfo || !opInfo->isMovable)
return nullptr;
SgStatement* bestPos = nullptr;
int bestLine = -1;
for (const string& usedVar : opInfo->usedVars) {
if (varDefinitions.find(usedVar) != varDefinitions.end()) {
for (SgStatement* defStmt : varDefinitions.at(usedVar)) {
if (defStmt->lineNumber() < operatorStmt->lineNumber()) {
if (defStmt->controlParent() == operatorStmt->controlParent()) {
if (defStmt->lineNumber() > bestLine) {
bestLine = defStmt->lineNumber();
bestPos = defStmt;
}
}
}
}
}
}
if (!bestPos) {
bool allLoopCarried = true;
bool hasAnyDefinition = false;
for (const string& usedVar : opInfo->usedVars) {
if (varDefinitions.find(usedVar) != varDefinitions.end()) {
for (SgStatement* defStmt : varDefinitions.at(usedVar)) {
if (defStmt == operatorStmt)
continue;
hasAnyDefinition = true;
if (defStmt->lineNumber() < operatorStmt->lineNumber() &&
defStmt->controlParent() == operatorStmt->controlParent()) {
allLoopCarried = false;
break;
}
}
}
if (!allLoopCarried)
break;
}
if (allLoopCarried || (!hasAnyDefinition && !opInfo->usedVars.empty())) {
SgStatement* loopStart = loop->lexNext();
return loopStart;
}
}
return bestPos;
}
static bool canMoveTo(SgStatement* from, SgStatement* to, SgForStmt* loop) {
if (!from || !to || from == to)
return false;
SgStatement* loopStart = loop->lexNext();
SgStatement* loopEnd = loop->lastNodeOfStmt();
if (!loopStart || !loopEnd)
return false;
if (to == loopStart) {
SgStatement* fromControlParent = from->controlParent();
if (!fromControlParent) fromControlParent = loop;
return fromControlParent == loop || fromControlParent == loopStart->controlParent();
}
if (from->lineNumber() < loopStart->lineNumber() || from->lineNumber() > loopEnd->lineNumber())
return false;
if (to->lineNumber() < loopStart->lineNumber() || to->lineNumber() > loopEnd->lineNumber())
return false;
if (to->lineNumber() >= from->lineNumber())
return false;
if (from->controlParent() != to->controlParent())
return false;
SgStatement* current = to->lexNext();
while (current && current != from && current != loopEnd) {
if (control_tags.find(current->variant()) != control_tags.end()) {
SgStatement* controlEnd = current->lastNodeOfStmt();
if (controlEnd && from->lineNumber() <= controlEnd->lineNumber()) {
if (from->controlParent() == current && to->controlParent() != current) {
return false;
}
}
}
current = current->lexNext();
}
return true;
}
static vector<SgStatement*> optimizeOperatorOrder(SgForStmt* loop,
const vector<OperatorInfo>& operators,
const map<string, vector<SgStatement*>>& varDefinitions) {
vector<SgStatement*> newOrder;
for (auto& op : operators)
newOrder.push_back(op.stmt);
map<SgStatement*, const OperatorInfo*> stmtToOpInfo;
for (auto& op : operators)
stmtToOpInfo[op.stmt] = &op;
bool changed = true;
while (changed) {
changed = false;
for (int i = operators.size() - 1; i >= 0; i--) {
if (!operators[i].isMovable)
continue;
SgStatement* stmt = operators[i].stmt;
const OperatorInfo* opInfo = stmtToOpInfo[stmt];
if (!opInfo)
continue;
size_t currentPos = 0;
for (size_t j = 0; j < newOrder.size(); j++) {
if (newOrder[j] == stmt) {
currentPos = j;
break;
}
}
SgStatement* bestPos = findBestPosition(stmt, operators, varDefinitions, loop);
if (!bestPos) {
bool hasDependents = false;
for (size_t j = currentPos + 1; j < newOrder.size(); j++) {
SgStatement* candidate = newOrder[j];
const OperatorInfo* candidateOpInfo = stmtToOpInfo[candidate];
if (candidateOpInfo) {
for (const string& definedVar : opInfo->definedVars) {
if (candidateOpInfo->usedVars.find(definedVar) != candidateOpInfo->usedVars.end()) {
hasDependents = true;
break;
}
}
if (hasDependents)
break;
}
}
continue;
}
size_t targetPos = 0;
bool foundTarget = false;
if (bestPos == loop->lexNext()) {
targetPos = 0;
for (size_t j = 0; j < currentPos && j < newOrder.size(); j++) {
SgStatement* candidate = newOrder[j];
const OperatorInfo* candidateOpInfo = stmtToOpInfo[candidate];
if (candidateOpInfo) {
bool usesDefinedVar = false;
for (const string& definedVar : opInfo->definedVars) {
if (candidateOpInfo->usedVars.find(definedVar) != candidateOpInfo->usedVars.end()) {
usesDefinedVar = true;
break;
}
}
if (usesDefinedVar) {
targetPos = j;
break;
}
}
}
foundTarget = true;
if (currentPos != targetPos && canMoveTo(stmt, bestPos, loop)) {
newOrder.erase(newOrder.begin() + currentPos);
newOrder.insert(newOrder.begin() + targetPos, stmt);
changed = true;
}
} else {
size_t bestPosIdx = 0;
bool foundBestPos = false;
for (size_t j = 0; j < newOrder.size(); j++) {
if (newOrder[j] == bestPos) {
bestPosIdx = j;
foundBestPos = true;
break;
}
}
if (foundBestPos) {
targetPos = bestPosIdx + 1;
for (size_t j = bestPosIdx + 1; j < currentPos && j < newOrder.size(); j++) {
SgStatement* candidate = newOrder[j];
const OperatorInfo* candidateOpInfo = stmtToOpInfo[candidate];
if (candidateOpInfo) {
bool definesUsedVar = false;
for (const string& usedVar : opInfo->usedVars) {
if (candidateOpInfo->definedVars.find(usedVar) != candidateOpInfo->definedVars.end()) {
definesUsedVar = true;
break;
}
}
if (definesUsedVar)
targetPos = j + 1;
}
}
bool wouldBreakDependency = false;
for (size_t j = targetPos; j < currentPos && j < newOrder.size(); j++) {
SgStatement* candidate = newOrder[j];
const OperatorInfo* candidateOpInfo = stmtToOpInfo[candidate];
if (candidateOpInfo) {
for (const string& definedVar : opInfo->definedVars) {
if (candidateOpInfo->usedVars.find(definedVar) != candidateOpInfo->usedVars.end()) {
wouldBreakDependency = true;
break;
}
}
if (wouldBreakDependency)
break;
}
}
if (!wouldBreakDependency && currentPos > targetPos && canMoveTo(stmt, bestPos, loop)) {
newOrder.erase(newOrder.begin() + currentPos);
newOrder.insert(newOrder.begin() + targetPos, stmt);
changed = true;
}
}
}
}
}
bool dependencyViolation = true;
set<pair<SgStatement*, SgStatement*>> triedPairs;
while (dependencyViolation) {
dependencyViolation = false;
triedPairs.clear();
for (size_t i = 0; i < newOrder.size(); i++) {
SgStatement* stmt = newOrder[i];
const OperatorInfo* opInfo = stmtToOpInfo[stmt];
if (!opInfo)
continue;
for (size_t j = 0; j < i; j++) {
SgStatement* prevStmt = newOrder[j];
const OperatorInfo* prevOpInfo = stmtToOpInfo[prevStmt];
if (!prevOpInfo)
continue;
pair<SgStatement*, SgStatement*> key = make_pair(stmt, prevStmt);
if (triedPairs.find(key) != triedPairs.end())
continue;
bool violation = false;
for (const string& definedVar : opInfo->definedVars) {
if (prevOpInfo->usedVars.find(definedVar) != prevOpInfo->usedVars.end()) {
violation = true;
break;
}
}
if (violation) {
triedPairs.insert(key);
bool wouldCreateViolation = false;
for (size_t k = j; k < i; k++) {
SgStatement* betweenStmt = newOrder[k];
const OperatorInfo* betweenOpInfo = stmtToOpInfo[betweenStmt];
if (!betweenOpInfo)
continue;
for (const string& usedVar : opInfo->usedVars) {
if (betweenOpInfo->definedVars.find(usedVar) != betweenOpInfo->definedVars.end()) {
wouldCreateViolation = true;
break;
}
}
if (wouldCreateViolation)
break;
}
if (!wouldCreateViolation) {
newOrder.erase(newOrder.begin() + i);
newOrder.insert(newOrder.begin() + j, stmt);
dependencyViolation = true;
break;
}
}
}
if (dependencyViolation)
break;
}
}
return newOrder;
}
static bool applyOperatorReordering(SgForStmt* loop, const vector<SgStatement*>& newOrder) {
if (!loop || newOrder.empty())
return false;
SgStatement* loopStart = loop->lexNext();
SgStatement* loopEnd = loop->lastNodeOfStmt();
if (!loopStart || !loopEnd)
return false;
vector<SgStatement*> originalOrder;
SgStatement* current = loopStart;
while (current && current != loopEnd) {
if (isSgExecutableStatement(current) && current->variant() == ASSIGN_STAT)
originalOrder.push_back(current);
current = current->lexNext();
}
bool orderChanged = false;
if (originalOrder.size() == newOrder.size()) {
for (size_t i = 0; i < originalOrder.size(); i++) {
if (originalOrder[i] != newOrder[i]) {
orderChanged = true;
break;
}
}
}
else
orderChanged = true;
if (!orderChanged)
return false;
vector<SgStatement*> extractedStatements;
vector<char*> savedComments;
unordered_set<SgStatement*> extractedSet;
map<SgStatement*, int> originalLineNumbers;
map<SgStatement*, SgStatement*> stmtToExtracted;
for (SgStatement* stmt : newOrder) {
if (stmt && stmt != loop && stmt != loopEnd && extractedSet.find(stmt) == extractedSet.end()) {
if (control_tags.find(stmt->variant()) != control_tags.end())
continue;
if (!canSafelyExtract(stmt, loop))
continue;
bool isMoving = false;
for (size_t i = 0; i < originalOrder.size(); i++) {
if (originalOrder[i] == stmt) {
for (size_t j = 0; j < newOrder.size(); j++) {
if (newOrder[j] == stmt && i != j) {
isMoving = true;
break;
}
}
break;
}
}
if (!isMoving)
continue;
originalLineNumbers[stmt] = stmt->lineNumber();
savedComments.push_back(stmt->comments() ? strdup(stmt->comments()) : nullptr);
SgStatement* extracted = stmt->extractStmt();
if (extracted) {
extractedStatements.push_back(extracted);
extractedSet.insert(stmt);
stmtToExtracted[stmt] = extracted;
}
}
}
map<SgStatement*, SgStatement*> insertedStatements;
for (size_t idx = 0; idx < newOrder.size(); idx++) {
SgStatement* stmt = newOrder[idx];
if (extractedSet.find(stmt) != extractedSet.end()) {
SgStatement* stmtToInsert = stmtToExtracted[stmt];
if (!stmtToInsert)
continue;
SgStatement* insertAfter = loop;
for (int i = idx - 1; i >= 0; i--) {
SgStatement* prevStmt = newOrder[i];
if (extractedSet.find(prevStmt) != extractedSet.end()) {
if (insertedStatements.find(prevStmt) != insertedStatements.end()) {
insertAfter = insertedStatements[prevStmt];
break;
}
} else {
SgStatement* search = loop->lexNext();
while (search && search != loopEnd) {
bool skip = false;
for (size_t j = idx; j < newOrder.size(); j++) {
if (extractedSet.find(newOrder[j]) != extractedSet.end() &&
search == newOrder[j]) {
skip = true;
break;
}
}
if (skip) {
search = search->lexNext();
continue;
}
if (search == prevStmt) {
insertAfter = search;
break;
}
search = search->lexNext();
}
if (insertAfter != loop) break;
}
}
size_t commentIdx = 0;
for (size_t i = 0; i < extractedStatements.size(); i++) {
if (extractedStatements[i] == stmtToInsert) {
commentIdx = i;
break;
}
}
if (commentIdx < savedComments.size() && savedComments[commentIdx])
stmtToInsert->setComments(savedComments[commentIdx]);
if (originalLineNumbers.find(stmt) != originalLineNumbers.end())
stmtToInsert->setlineNumber(originalLineNumbers[stmt]);
SgStatement* controlParent = stmt->controlParent();
if (!controlParent)
controlParent = loop;
insertAfter->insertStmtAfter(*stmtToInsert, *controlParent);
insertedStatements[stmt] = stmtToInsert;
}
}
for (char* comment : savedComments) {
if (comment)
free(comment);
}
return true;
}
vector<SAPFOR::BasicBlock*> findFuncBlocksByFuncStatement(SgStatement *st, const map<FuncInfo*, vector<SAPFOR::BasicBlock*>>& FullIR) {
vector<SAPFOR::BasicBlock*> result;
Statement* forSt = (Statement*)st;
for (auto& func: FullIR) {
if (func.first->funcPointer->getCurrProcessFile() == forSt->getCurrProcessFile()
&& func.first->funcPointer->lineNumber() == forSt->lineNumber())
{
result = func.second;
}
}
return result;
}
map<SgForStmt*, vector<SAPFOR::BasicBlock*>> findAndAnalyzeLoops(SgStatement *st, const vector<SAPFOR::BasicBlock*>& blocks) {
map<SgForStmt*, vector<SAPFOR::BasicBlock*>> result;
SgStatement *lastNode = st->lastNodeOfStmt();
while (st && st != lastNode) {
if (loop_tags.find(st -> variant()) != loop_tags.end()) {
SgForStmt *forSt = (SgForStmt*)st;
SgStatement *loopBody = forSt -> body();
SgStatement *lastLoopNode = st->lastNodeOfStmt();
unordered_set<int> blocks_nums;
while (loopBody && loopBody != lastLoopNode) {
vector<SAPFOR::IR_Block*> irBlocks = findInstructionsFromOperator(loopBody, blocks);
if (!irBlocks.empty()) {
SAPFOR::IR_Block* IR = irBlocks.front();
if (IR && IR->getBasicBlock()) {
if (blocks_nums.find(IR -> getBasicBlock() -> getNumber()) == blocks_nums.end()) {
result[forSt].push_back(IR -> getBasicBlock());
blocks_nums.insert(IR -> getBasicBlock() -> getNumber());
}
}
}
loopBody = loopBody -> lexNext();
}
sort(result[forSt].begin(), result[forSt].end());
}
st = st -> lexNext();
}
return result;
}
static void processLoopRecursively(SgForStmt* loop, const vector<SAPFOR::BasicBlock*>& blocks,
const map<FuncInfo*, vector<SAPFOR::BasicBlock*>>& FullIR) {
if (!loop)
return;
SgStatement* loopStart = loop->lexNext();
SgStatement* loopEnd = loop->lastNodeOfStmt();
if (loopStart && loopEnd) {
SgStatement* current = loopStart;
while (current && current != loopEnd) {
if (current->variant() == FOR_NODE && current != loop) {
SgForStmt* nestedLoop = (SgForStmt*)current;
processLoopRecursively(nestedLoop, blocks, FullIR);
SgStatement* nestedEnd = nestedLoop->lastNodeOfStmt();
if (nestedEnd)
current = nestedEnd->lexNext();
else
current = current->lexNext();
}
else
current = current->lexNext();
}
}
vector<OperatorInfo> operators = analyzeOperatorsInLoop(loop, blocks, FullIR);
if (!operators.empty()) {
map<string, vector<SgStatement*>> varDefinitions = findVariableDefinitions(loop, operators);
vector<SgStatement*> newOrder = optimizeOperatorOrder(loop, operators, varDefinitions);
applyOperatorReordering(loop, newOrder);
}
}
void moveOperators(SgFile *file, map<string, vector<LoopGraph*>>& loopGraph,
const map<FuncInfo*, vector<SAPFOR::BasicBlock*>>& FullIR,
int& countOfTransform) {
countOfTransform += 1;
//cout << "MOVE_OPERATORS Pass Started" << endl;
const int funcNum = file -> numberOfFunctions();
for (int i = 0; i < funcNum; ++i) {
SgStatement *st = file -> functions(i);
vector<SAPFOR::BasicBlock*> blocks = findFuncBlocksByFuncStatement(st, FullIR);
map<SgForStmt*, vector<SAPFOR::BasicBlock*>> loopsMapping = findAndAnalyzeLoops(st, blocks);
for (auto& loopForAnalyze: loopsMapping)
processLoopRecursively(loopForAnalyze.first, loopForAnalyze.second, FullIR);
}
//cout << "MOVE_OPERATORS Pass Completed" << endl;
}

6
src/Transformations/MoveOperators/move_operators.h Normal file
View File

@@ -0,0 +1,6 @@
#pragma once
#include "../../GraphLoop/graph_loops.h"
#include "../../CFGraph/CFGraph.h"
void moveOperators(SgFile *file, std::map<std::string, std::vector<LoopGraph*>>& loopGraph, const std::map<FuncInfo*, std::vector<SAPFOR::BasicBlock*>>& FullIR, int& countOfTransform);

7
src/Transformations/ReplaceArraysInIO/replace_dist_arrays_in_io.cpp
View File

@@ -504,7 +504,7 @@ static void replaceArrayInFragment(SgSymbol* replace_symb,
}
}
static bool ioReginBorder(SgStatement* stat, SgStatement* last_io_bound)
static bool ioRegionBorder(SgStatement* stat, SgStatement* last_io_bound)
{
auto var = stat->variant();
@@ -535,8 +535,6 @@ static bool ioReginBorder(SgStatement* stat, SgStatement* last_io_bound)
if (last_io_bound && last_io_bound->lastNodeOfStmt() && last_io_bound->lastNodeOfStmt() == stat)
return true;
int parent_var;
if (var == CONTROL_END && border_stats.find(stat->controlParent()->variant()) != border_stats.end())
return true;
@@ -602,6 +600,7 @@ void replaceDistributedArraysInIO(vector<ParallelRegion*>& regions,
auto var = curr_stmt->variant();
// TODO: does not work with user regions
if (var == PROC_HEDR || var == PROG_HEDR || var == FUNC_HEDR)
{
current_func_info = NULL;
@@ -628,7 +627,7 @@ void replaceDistributedArraysInIO(vector<ParallelRegion*>& regions,
break;
}
if (ioReginBorder(curr_stmt, last_io_bound))
if (ioRegionBorder(curr_stmt, last_io_bound))
{
for (const auto& by_array_to_copy : need_replace)
{

535
src/Transformations/SwapOperators/swap_operators.cpp
View File

@@ -1,535 +0,0 @@
#include <map>
#include <unordered_set>
#include <vector>
#include <queue>
#include <iostream>
#include <algorithm>
#include "../../Utils/errors.h"
#include "../../Utils/SgUtils.h"
#include "../../GraphCall/graph_calls.h"
#include "../../GraphCall/graph_calls_func.h"
#include "../../CFGraph/CFGraph.h"
#include "../../CFGraph/IR.h"
#include "../../GraphLoop/graph_loops.h"
#include "swap_operators.h"
using namespace std;
string getNameByArg(SAPFOR::Argument* arg);
static vector<SAPFOR::IR_Block*> findInstructionsFromOperator(SgStatement* st, vector<SAPFOR::BasicBlock*> Blocks) {
vector<SAPFOR::IR_Block*> result;
string filename = st->fileName();
for (auto& block: Blocks) {
vector<SAPFOR::IR_Block*> instructionsInBlock = block->getInstructions();
for (auto& instruction: instructionsInBlock) {
SgStatement* curOperator = instruction->getInstruction()->getOperator();
// Match by line number to find corresponding IR instruction
if (curOperator->lineNumber() == st->lineNumber()) {
result.push_back(instruction);
}
}
}
return result;
}
unordered_set<int> loop_tags = {FOR_NODE}; // Loop statements
unordered_set<int> control_tags = {IF_NODE, ELSEIF_NODE, DO_WHILE_NODE, WHILE_NODE, LOGIF_NODE}; // Control structures that cannot be moved
unordered_set<int> control_end_tags = {CONTROL_END}; // End marker
struct OperatorInfo {
SgStatement* stmt;
set<string> usedVars;
set<string> definedVars;
int lineNumber;
bool isMovable;
OperatorInfo(SgStatement* s) : stmt(s), lineNumber(s->lineNumber()), isMovable(true) {}
};
static bool isStatementEmbedded(SgStatement* stmt, SgStatement* parent) {
if (!stmt || !parent || stmt == parent) return false;
if (parent->variant() == LOGIF_NODE) {
if (stmt->lineNumber() == parent->lineNumber()) {
return true;
}
SgStatement* current = parent;
SgStatement* lastNode = parent->lastNodeOfStmt();
while (current && current != lastNode) {
if (current == stmt) {
return true;
}
if (current->isIncludedInStmt(*stmt)) {
return true;
}
current = current->lexNext();
}
}
if (parent->isIncludedInStmt(*stmt)) {
return true;
}
return false;
}
static bool isLoopBoundary(SgStatement* stmt) {
if (!stmt) return false;
if (stmt->variant() == FOR_NODE || stmt->variant() == CONTROL_END) {
return true;
}
return false;
}
static bool isPartOfNestedLoop(SgStatement* stmt, SgForStmt* loop) {
if (!stmt || !loop) return false;
SgStatement* loopStart = loop->lexNext();
SgStatement* loopEnd = loop->lastNodeOfStmt();
if (!loopStart || !loopEnd) return false;
if (stmt->lineNumber() < loopStart->lineNumber() || stmt->lineNumber() > loopEnd->lineNumber()) {
return false;
}
SgStatement* current = loopStart;
while (current && current != loopEnd) {
if (current->variant() == FOR_NODE && current != loop) {
SgForStmt* nestedLoop = (SgForStmt*)current;
SgStatement* nestedStart = nestedLoop->lexNext();
SgStatement* nestedEnd = nestedLoop->lastNodeOfStmt();
if (nestedStart && nestedEnd &&
stmt->lineNumber() >= nestedStart->lineNumber() &&
stmt->lineNumber() <= nestedEnd->lineNumber()) {
return true;
}
}
current = current->lexNext();
}
return false;
}
static bool canSafelyExtract(SgStatement* stmt, SgForStmt* loop) {
if (!stmt || !loop) return false;
if (isLoopBoundary(stmt)) {
return false;
}
if (control_tags.find(stmt->variant()) != control_tags.end()) {
return false;
}
if (isPartOfNestedLoop(stmt, loop)) {
return false;
}
SgStatement* loopStart = loop->lexNext();
SgStatement* loopEnd = loop->lastNodeOfStmt();
if (!loopStart || !loopEnd) return false;
SgStatement* current = loopStart;
while (current && current != loopEnd) {
if (current->variant() == LOGIF_NODE && current->lineNumber() == stmt->lineNumber()) {
return false;
}
if (control_tags.find(current->variant()) != control_tags.end()) {
if (isStatementEmbedded(stmt, current)) {
return false;
}
}
if (current == stmt) break;
current = current->lexNext();
}
return true;
}
static vector<OperatorInfo> analyzeOperatorsInLoop(SgForStmt* loop, vector<SAPFOR::BasicBlock*> blocks, map<FuncInfo*, vector<SAPFOR::BasicBlock*>>& FullIR) {
vector<OperatorInfo> operators;
SgStatement* loopStart = loop->lexNext();
SgStatement* loopEnd = loop->lastNodeOfStmt();
if (!loopStart || !loopEnd) {
return operators;
}
SgStatement* current = loopStart;
unordered_set<SgStatement*> visited;
while (current && current != loopEnd) {
if (visited.find(current) != visited.end()) {
break;
}
visited.insert(current);
if (isLoopBoundary(current)) {
current = current->lexNext();
continue;
}
if (current->variant() == FOR_NODE && current != loop) {
SgStatement* nestedEnd = current->lastNodeOfStmt();
if (nestedEnd) {
current = nestedEnd->lexNext();
} else {
current = current->lexNext();
}
continue;
}
if (isSgExecutableStatement(current)) {
if (control_tags.find(current->variant()) != control_tags.end()) {
current = current->lexNext();
continue;
}
if (current->variant() != ASSIGN_STAT) {
current = current->lexNext();
continue;
}
OperatorInfo opInfo(current);
vector<SAPFOR::IR_Block*> irBlocks = findInstructionsFromOperator(current, blocks);
for (auto irBlock : irBlocks) {
if (!irBlock || !irBlock->getInstruction()) continue;
SAPFOR::Instruction* instr = irBlock->getInstruction();
if (instr->getArg1()) {
string varName = getNameByArg(instr->getArg1());
if (!varName.empty()) {
opInfo.usedVars.insert(varName);
}
}
if (instr->getArg2()) {
string varName = getNameByArg(instr->getArg2());
if (!varName.empty()) {
opInfo.usedVars.insert(varName);
}
}
if (instr->getResult()) {
string varName = getNameByArg(instr->getResult());
if (!varName.empty()) {
opInfo.definedVars.insert(varName);
}
}
}
operators.push_back(opInfo);
}
current = current->lexNext();
}
return operators;
}
static map<string, vector<SgStatement*>> findVariableDefinitions(SgForStmt* loop, vector<OperatorInfo>& operators) {
map<string, vector<SgStatement*>> varDefinitions;
for (auto& op : operators) {
for (const string& var : op.definedVars) {
varDefinitions[var].push_back(op.stmt);
}
}
return varDefinitions;
}
static int calculateDistance(SgStatement* from, SgStatement* to) {
if (!from || !to) return INT_MAX;
return abs(to->lineNumber() - from->lineNumber());
}
static SgStatement* findBestPosition(SgStatement* operatorStmt, vector<OperatorInfo>& operators, map<string, vector<SgStatement*>>& varDefinitions) {
OperatorInfo* opInfo = nullptr;
for (auto& op : operators) {
if (op.stmt == operatorStmt) {
opInfo = &op;
break;
}
}
if (!opInfo || !opInfo->isMovable) {
return nullptr;
}
SgStatement* bestPos = nullptr;
int minDistance = INT_MAX;
for (const string& usedVar : opInfo->usedVars) {
if (varDefinitions.find(usedVar) != varDefinitions.end()) {
for (SgStatement* defStmt : varDefinitions[usedVar]) {
int distance = calculateDistance(operatorStmt, defStmt);
if (distance < minDistance) {
minDistance = distance;
bestPos = defStmt;
}
}
}
}
return bestPos;
}
static bool canMoveTo(SgStatement* from, SgStatement* to, SgForStmt* loop) {
if (!from || !to || from == to) return false;
SgStatement* loopStart = loop->lexNext();
SgStatement* loopEnd = loop->lastNodeOfStmt();
if (!loopStart || !loopEnd) return false;
if (to->lineNumber() < loopStart->lineNumber() || to->lineNumber() > loopEnd->lineNumber()) {
return false;
}
SgStatement* current = from;
unordered_set<SgStatement*> visited;
while (current && current != loopEnd) {
if (visited.find(current) != visited.end()) {
return false;
}
visited.insert(current);
if (control_tags.find(current->variant()) != control_tags.end()) {
return false;
}
if (current == to) break;
current = current->lexNext();
}
return true;
}
static vector<SgStatement*> optimizeOperatorOrder(SgForStmt* loop, vector<OperatorInfo>& operators, map<string, vector<SgStatement*>>& varDefinitions) {
vector<SgStatement*> newOrder;
vector<bool> moved(operators.size(), false);
for (size_t i = 0; i < operators.size(); i++) {
if (moved[i] || !operators[i].isMovable) {
newOrder.push_back(operators[i].stmt);
moved[i] = true;
continue;
}
SgStatement* bestPos = findBestPosition(operators[i].stmt, operators, varDefinitions);
if (bestPos && canMoveTo(operators[i].stmt, bestPos, loop)) {
bool inserted = false;
for (size_t j = 0; j < newOrder.size(); j++) {
if (newOrder[j] == bestPos) {
newOrder.insert(newOrder.begin() + j + 1, operators[i].stmt);
inserted = true;
break;
}
}
if (!inserted) {
newOrder.push_back(operators[i].stmt);
}
} else {
newOrder.push_back(operators[i].stmt);
}
moved[i] = true;
}
return newOrder;
}
static bool applyOperatorReordering(SgForStmt* loop, vector<SgStatement*>& newOrder) {
if (!loop || newOrder.empty()) return false;
SgStatement* loopStart = loop->lexNext();
SgStatement* loopEnd = loop->lastNodeOfStmt();
if (!loopStart || !loopEnd) return false;
vector<SgStatement*> originalOrder;
SgStatement* current = loopStart;
while (current && current != loopEnd) {
if (isSgExecutableStatement(current) && current->variant() == ASSIGN_STAT) {
originalOrder.push_back(current);
}
current = current->lexNext();
}
bool orderChanged = false;
if (originalOrder.size() == newOrder.size()) {
for (size_t i = 0; i < originalOrder.size(); i++) {
if (originalOrder[i] != newOrder[i]) {
orderChanged = true;
break;
}
}
} else {
orderChanged = true;
}
if (!orderChanged) {
return false;
}
vector<SgStatement*> extractedStatements;
vector<char*> savedComments;
unordered_set<SgStatement*> extractedSet;
map<SgStatement*, int> originalLineNumbers;
for (SgStatement* stmt : newOrder) {
if (stmt && stmt != loop && stmt != loopEnd && extractedSet.find(stmt) == extractedSet.end()) {
if (control_tags.find(stmt->variant()) != control_tags.end()) {
continue;
}
if (!canSafelyExtract(stmt, loop)) {
continue;
}
bool isMoving = false;
for (size_t i = 0; i < originalOrder.size(); i++) {
if (originalOrder[i] == stmt) {
for (size_t j = 0; j < newOrder.size(); j++) {
if (newOrder[j] == stmt && i != j) {
isMoving = true;
break;
}
}
break;
}
}
if (!isMoving) {
continue;
}
originalLineNumbers[stmt] = stmt->lineNumber();
savedComments.push_back(stmt->comments() ? strdup(stmt->comments()) : nullptr);
SgStatement* extracted = stmt->extractStmt();
if (extracted) {
extractedStatements.push_back(extracted);
extractedSet.insert(stmt);
}
}
}
SgStatement* currentPos = loop;
for (size_t i = 0; i < extractedStatements.size(); i++) {
SgStatement* stmt = extractedStatements[i];
if (stmt) {
SgStatement* nextPos = currentPos->lexNext();
if (nextPos && nextPos != loopEnd) {
if (nextPos->variant() == FOR_NODE && nextPos != loop) {
continue;
}
if (nextPos->variant() == CONTROL_END) {
continue;
}
}
if (i < savedComments.size() && savedComments[i]) {
stmt->setComments(savedComments[i]);
}
if (originalLineNumbers.find(stmt) != originalLineNumbers.end()) {
stmt->setlineNumber(originalLineNumbers[stmt]);
}
currentPos->insertStmtAfter(*stmt, *loop);
currentPos = stmt;
}
}
for (char* comment : savedComments) {
if (comment) {
free(comment);
}
}
if (currentPos && currentPos->lexNext() != loopEnd) {
currentPos->setLexNext(*loopEnd);
}
return true;
}
vector<SAPFOR::BasicBlock*> findFuncBlocksByFuncStatement(SgStatement *st, map<FuncInfo*, vector<SAPFOR::BasicBlock*>>& FullIR) {
vector<SAPFOR::BasicBlock*> result;
Statement* forSt = (Statement*)st;
for (auto& func: FullIR) {
if (func.first -> funcPointer -> getCurrProcessFile() == forSt -> getCurrProcessFile()
&& func.first -> funcPointer -> lineNumber() == forSt -> lineNumber())
result = func.second;
}
return result;
}
map<SgForStmt*, vector<SAPFOR::BasicBlock*>> findAndAnalyzeLoops(SgStatement *st, vector<SAPFOR::BasicBlock*> blocks) {
map<SgForStmt*, vector<SAPFOR::BasicBlock*>> result;
SgStatement *lastNode = st->lastNodeOfStmt();
while (st && st != lastNode) {
if (loop_tags.find(st -> variant()) != loop_tags.end()) {
SgForStmt *forSt = (SgForStmt*)st;
SgStatement *loopBody = forSt -> body();
SgStatement *lastLoopNode = st->lastNodeOfStmt();
unordered_set<int> blocks_nums;
while (loopBody && loopBody != lastLoopNode) {
vector<SAPFOR::IR_Block*> irBlocks = findInstructionsFromOperator(loopBody, blocks);
if (!irBlocks.empty()) {
SAPFOR::IR_Block* IR = irBlocks.front();
if (IR && IR->getBasicBlock()) {
if (blocks_nums.find(IR -> getBasicBlock() -> getNumber()) == blocks_nums.end()) {
result[forSt].push_back(IR -> getBasicBlock());
blocks_nums.insert(IR -> getBasicBlock() -> getNumber());
}
}
}
loopBody = loopBody -> lexNext();
}
std::sort(result[forSt].begin(), result[forSt].end());
}
st = st -> lexNext();
}
return result;
}
void runSwapOperators(SgFile *file, std::map<std::string, std::vector<LoopGraph*>>& loopGraph, std::map<FuncInfo*, std::vector<SAPFOR::BasicBlock*>>& FullIR, int& countOfTransform) {
countOfTransform += 1;
std::cout << "SWAP_OPERATORS Pass Started" << std::endl;
const int funcNum = file -> numberOfFunctions();
for (int i = 0; i < funcNum; ++i) {
SgStatement *st = file -> functions(i);
vector<SAPFOR::BasicBlock*> blocks = findFuncBlocksByFuncStatement(st, FullIR);
map<SgForStmt*, vector<SAPFOR::BasicBlock*>> loopsMapping = findAndAnalyzeLoops(st, blocks);
for (pair<SgForStmt*, vector<SAPFOR::BasicBlock*>> loopForAnalyze: loopsMapping) {
vector<OperatorInfo> operators = analyzeOperatorsInLoop(loopForAnalyze.first, loopForAnalyze.second, FullIR);
map<string, vector<SgStatement*>> varDefinitions = findVariableDefinitions(loopForAnalyze.first, operators);
vector<SgStatement*> newOrder = optimizeOperatorOrder(loopForAnalyze.first, operators, varDefinitions);
applyOperatorReordering(loopForAnalyze.first, newOrder);
}
}
std::cout << "SWAP_OPERATORS Pass Completed" << std::endl;
}

6
src/Transformations/SwapOperators/swap_operators.h
View File

@@ -1,6 +0,0 @@
#pragma once
#include "../../GraphLoop/graph_loops.h"
#include "../../CFGraph/CFGraph.h"
void runSwapOperators(SgFile *file, std::map<std::string, std::vector<LoopGraph*>>& loopGraph, std::map<FuncInfo*, std::vector<SAPFOR::BasicBlock*>>& FullIR, int& countOfTransform);

7
src/Utils/PassManager.h
View File

@@ -212,8 +212,6 @@ void InitPassesDependencies(map<passes, vector<passes>> &passDepsIn, set<passes>
Pass(BUILD_IR) <= Pass(SUBST_EXPR_RD) <= Pass(SUBST_EXPR_RD_AND_UNPARSE);
list({BUILD_IR, CALL_GRAPH2}) <= Pass(SWAP_OPERATORS);
list({ LOOP_ANALYZER_DATA_DIST_S1, SUBST_EXPR_RD } ) <= Pass(PRIVATE_REMOVING_ANALYSIS);
list({ PRIVATE_REMOVING_ANALYSIS, REVERT_SUBST_EXPR_RD }) <= Pass(PRIVATE_REMOVING);
@@ -318,7 +316,10 @@ void InitPassesDependencies(map<passes, vector<passes>> &passDepsIn, set<passes>
list({ VERIFY_INCLUDES, CORRECT_VAR_DECL }) <= Pass(SET_IMPLICIT_NONE);
list({ CALL_GRAPH2, CALL_GRAPH, BUILD_IR, LOOP_GRAPH, LOOP_ANALYZER_DATA_DIST_S2 }) <= Pass(FIND_PRIVATE_ARRAYS);
list({ CALL_GRAPH2, CALL_GRAPH, BUILD_IR, LOOP_GRAPH, LOOP_ANALYZER_DATA_DIST_S2 }) <= Pass(FIND_PRIVATE_ARRAYS_ANALYSIS);
list({ FIND_PRIVATE_ARRAYS_ANALYSIS, CONVERT_LOOP_TO_ASSIGN, RESTORE_LOOP_FROM_ASSIGN, REVERT_SUBST_EXPR_RD }) <= Pass(FIND_PRIVATE_ARRAYS);
list({ BUILD_IR, CALL_GRAPH2, RESTORE_LOOP_FROM_ASSIGN, REVERT_SUBST_EXPR_RD }) <= Pass(MOVE_OPERATORS);
passesIgnoreStateDone.insert({ CREATE_PARALLEL_DIRS, INSERT_PARALLEL_DIRS, INSERT_SHADOW_DIRS, EXTRACT_PARALLEL_DIRS,
EXTRACT_SHADOW_DIRS, CREATE_REMOTES, UNPARSE_FILE, REMOVE_AND_CALC_SHADOW,

2
src/Utils/version.h
View File

@@ -1,3 +1,3 @@
#pragma once
#define VERSION_SPF "2446"
#define VERSION_SPF "2453"

20
src/VisualizerCalls/get_information.cpp
View File

@@ -1793,6 +1793,22 @@ int SPF_RenameIncludes(void*& context, int winHandler, short* options, short* pr
return simpleTransformPass(RENAME_INLCUDES, options, projName, folderName, output, outputMessage);
}
int SPF_InsertPrivateArrayDirectives(void*& context, int winHandler, short* options, short* projName, short* folderName, string& output, string& outputMessage)
{
MessageManager::clearCache();
MessageManager::setWinHandler(winHandler);
ignoreArrayDistributeState = true;
sharedMemoryParallelization = 1;
return simpleTransformPass(FIND_PRIVATE_ARRAYS, options, projName, folderName, output, outputMessage);
}
int SPF_MoveOperators(void*& context, int winHandler, short* options, short* projName, short* folderName, string& output, string& outputMessage)
{
MessageManager::clearCache();
MessageManager::setWinHandler(winHandler);
return simpleTransformPass(MOVE_OPERATORS, options, projName, folderName, output, outputMessage);
}
static inline void convertBackSlash(char *str, int strL)
{
for (int z = 0; z < strL; ++z)
@@ -2499,6 +2515,10 @@ const wstring Sapfor_RunTransformation(const char* transformName_c, const char*
retCode = SPF_InsertImplicitNone(context, winHandler, optSh, projSh, fold, output, outputMessage);
else if (whichRun == "SPF_RenameIncludes")
retCode = SPF_RenameIncludes(context, winHandler, optSh, projSh, fold, output, outputMessage);
else if (whichRun == "SPF_InsertPrivateArrayDirectives")
retCode = SPF_InsertPrivateArrayDirectives(context, winHandler, optSh, projSh, fold, output, outputMessage);
else if (whichRun == "SPF_MoveOperators")
retCode = SPF_MoveOperators(context, winHandler, optSh, projSh, fold, output, outputMessage);
else if (whichRun == "SPF_CreateParallelVariant")
{
vector<string> splited;