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base: Alexander_KS:libpredict_integration
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Alexander_KS:master Alexander_KS:par_reg_merging Alexander_KS:replace_io_arrays Alexander_KS:private_arrays2 Alexander_KS:egormayorov Alexander_KS:libpredict_integration Alexander_KS:analyze_loops_with_IR
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compare: Alexander_KS:b0268f29d7f9a35cc8662586646f20a964c18441
Branches Tags
Alexander_KS:master Alexander_KS:par_reg_merging Alexander_KS:replace_io_arrays Alexander_KS:private_arrays2 Alexander_KS:egormayorov Alexander_KS:libpredict_integration Alexander_KS:analyze_loops_with_IR

2 Commits
libpredict ... b0268f29d7

Author SHA1 Message Date
xnpster
b0268f29d7 region merging: derive array types 2026-02-22 13:34:27 +03:00
xnpster
6a05bd5fc7 draft of parallel regions merging pass 2026-02-22 13:34:27 +03:00
19 changed files with 750 additions and 691 deletions
Expand all files Collapse all files

8
CMakeLists.txt
View File

@@ -166,6 +166,8 @@ set(PARALLEL_REG src/ParallelizationRegions/ParRegions.cpp
set(ARRAY_PROP src/ArrayConstantPropagation/propagation.cpp
src/ArrayConstantPropagation/propagation.h
)
set(MERGE_COPY_ARRAYS src/ParallelizationRegions/parse_merge_dirs.cpp
src/ParallelizationRegions/parse_merge_dirs.h)
set(TR_DEAD_CODE src/Transformations/DeadCodeRemoving/dead_code.cpp
src/Transformations/DeadCodeRemoving/dead_code.h)
@@ -338,9 +340,7 @@ set(MAIN src/Sapfor.cpp
src/Utils/PassManager.h)
set(PREDICTOR src/Predictor/PredictScheme.cpp
src/Predictor/PredictScheme.h
src/Predictor/PredictSchemeWithLibrary.cpp
src/Predictor/PredictSchemeWithLibrary.h)
src/Predictor/PredictScheme.h)
set(LIBPREDICTOR ${libpred_sources}/cluster.cpp
${libpred_sources}/predictor.cpp
@@ -428,6 +428,7 @@ set(SOURCE_EXE
${LOOP_ANALYZER}
${TRANSFORMS}
${PARALLEL_REG}
${MERGE_COPY_ARRAYS}
${PRIV}
${ARRAY_PROP}
${FDVM}
@@ -481,6 +482,7 @@ source_group (GraphCall FILES ${GR_CALL})
source_group (GraphLoop FILES ${GR_LOOP})
source_group (LoopAnalyzer FILES ${LOOP_ANALYZER})
source_group (ParallelizationRegions FILES ${PARALLEL_REG})
source_group (MergeCopyArrays FILES ${MERGE_COPY_ARRAYS})
source_group (PrivateAnalyzer FILES ${PRIV})
source_group (ArrayConstantPropagation FILES ${ARRAY_PROP})
source_group (FDVM_Compiler FILES ${FDVM})

2
projects/dvm

Submodule projects/dvm updated: 7d374b7cc1...cdda71deab

2
projects/libpredictor

Submodule projects/libpredictor updated: 7e57477dfa...d08cb25cc6

1
src/DirectiveProcessing/directive_creator_base.cpp
View File

@@ -122,7 +122,6 @@ static LoopGraph* createDirectiveForLoop(LoopGraph *currentLoop, MapToArray &mai
if (found == false)
{
directive->shadowRenew.push_back(make_pair(key, vector<pair<int, int>>()));
directive->shadowRenewCorner.push_back(false);
const DIST::Array *arrayRef = read;
for (int i = 0; i < arrayRef->GetDimSize(); ++i)

10
src/Distribution/DvmhDirective.cpp
View File

@@ -857,11 +857,6 @@ ParallelDirective::genDirective(File* file, const vector<pair<DIST::Array*, cons
shadowRenewShifts[i].resize(shadowRenew[i].second.size());
}
if (shadowRenewCorner.size() == 0)
{
shadowRenewCorner.resize(shadowRenew.size(), false);
}
string shadowAdd = ", SHADOW_RENEW(";
int inserted = 0;
@@ -904,10 +899,7 @@ ParallelDirective::genDirective(File* file, const vector<pair<DIST::Array*, cons
for (auto& elem : genSubscripts(shadowRenew[i1].second, shadowRenewShifts[i1]))
newArrayRef->addSubscript(*elem);
bool needCornerFlag = shadowRenew[i1].second.size() > 1 && needCorner(shadowArray, shiftsByAccess, loop);
shadowRenewCorner[i1] = needCornerFlag;
if (needCornerFlag)
if (shadowRenew[i1].second.size() > 1 && needCorner(shadowArray, shiftsByAccess, loop))
{
SgExpression* tmp = new SgExpression(ARRAY_OP, newArrayRef, NULL, NULL);
p->setLhs(*tmp);

3
src/Distribution/DvmhDirective.h
View File

@@ -102,7 +102,6 @@ public:
// origin_Name uniqName bounds
std::vector<std::pair<std::pair<std::string, std::string>, std::vector<std::pair<int, int>>>> shadowRenew;
std::vector<std::vector<std::pair<int, int>>> shadowRenewShifts;
std::vector<bool> shadowRenewCorner;
// origin_Name uniqName bounds
std::vector<std::pair<std::pair<std::string, std::string>, std::vector<std::pair<int, int>>>> across;
@@ -126,7 +125,6 @@ public:
privates = copyFrom.privates;
shadowRenew = copyFrom.shadowRenew;
shadowRenewShifts = copyFrom.shadowRenewShifts;
shadowRenewCorner = copyFrom.shadowRenewCorner;
across = copyFrom.across;
acrossShifts = copyFrom.acrossShifts;
remoteAccess = copyFrom.remoteAccess;
@@ -153,7 +151,6 @@ public:
on.clear();
privates.clear();
shadowRenew.clear();
shadowRenewCorner.clear();
across.clear();
acrossShifts.clear();
reduction.clear();

616
src/ParallelizationRegions/parse_merge_dirs.cpp Normal file
View File

@@ -0,0 +1,616 @@
#include "parse_merge_dirs.h"
#include <unordered_set>
using std::map;
using std::pair;
using std::string;
using std::unordered_map;
using std::unordered_set;
using std::vector;
static void parseMergeDirective(const char *comment,
vector<pair<string, string>> &parsed_mapping)
{
while (comment)
{
auto *line_end = strchr(comment, '\n');
static const char prefix[] = "!!SPF TRANSFORM(MERGE_ARRAYS(";
static const auto compare_chars = sizeof(prefix) - 1;
if (strncasecmp(comment, prefix, compare_chars) == 0)
{
auto *pair_start = comment + compare_chars;
auto *comma = strchr(pair_start, ',');
if (comma)
{
auto *close_br = strchr(comma + 1, ')');
if (close_br)
{
parsed_mapping.emplace_back(
string(pair_start, comma - pair_start),
string(comma + 1, close_br - comma - 1));
}
}
}
comment = line_end;
if (comment)
comment++;
}
}
static string getNonDefaultRegion(DIST::Array *a)
{
string result;
if (!a)
return result;
for (const auto &reg_name : a->GetRegionsName())
{
if (reg_name != "default")
{
if (!result.empty())
printInternalError(convertFileName(__FILE__).c_str(), __LINE__);
result = reg_name;
}
}
return result;
}
static bool hasSameSizes(DIST::Array *a, DIST::Array *b)
{
for (auto *array : {a, b})
{
for (const auto &p : array->GetSizes())
{
if (p.first < 0 || p.second < 0)
return false;
}
}
return a->GetSizes() == b->GetSizes() && a->GetTypeSize() == b->GetTypeSize();
}
static bool checkSimilarTemplates(vector<ParallelRegion *> &regions,
const unordered_map<string, string> &new_region_mapping)
{
// new region -> old regions
unordered_map<string, unordered_set<string>> new_region_inverse_mapping;
for (const auto &p : new_region_mapping)
new_region_inverse_mapping[p.second].insert(p.first);
for (const auto &new_reg : new_region_inverse_mapping)
{
DIST::Array *template_array = nullptr;
string first_reg_name;
for (const auto &old_region_name : new_reg.second)
{
auto *old_reg = getRegionByName(regions, old_region_name);
if (!old_reg)
printInternalError(convertFileName(__FILE__).c_str(), __LINE__);
const auto &distr_rules = old_reg->GetDataDir().GetDistrRules();
if (distr_rules.size() != 1)
printInternalError(convertFileName(__FILE__).c_str(), __LINE__);
auto *current_template = distr_rules.front().first;
if (template_array)
{
if (!hasSameSizes(template_array, current_template))
{
__spf_print(1, "Templates of %s and %s has different sizes\n",
first_reg_name.c_str(),
old_region_name.c_str());
return false;
}
// else everything OK
}
else
{
template_array = current_template;
first_reg_name = old_region_name;
}
}
}
return true;
}
static bool hasSameAlignment(const std::unordered_set<const AlignRule *> &align_a,
const std::unordered_set<const AlignRule *> &align_b)
{
if (align_a.size() != 1 || align_b.size() != 1)
return false;
const auto *rule_a = *align_a.begin();
const auto *rule_b = *align_b.begin();
if (rule_a->alignRule != rule_b->alignRule)
return false;
return true;
}
static void printExpr(SgExpression *e, string pad)
{
if (!e)
return;
__spf_print(1, "%s%d: %s\n", pad.c_str(), e->variant(), e->unparse());
printExpr(e->lhs(), pad + " ");
printExpr(e->rhs(), pad + " ");
}
static pair<vector<SgStatement *>, SgSymbol *> generateDeclaration(const string &array_name, const string &common_block_name,
const vector<pair<int, int>> &sizes, SgType *type, SgStatement *scope)
{
auto *array_symbol = new SgSymbol(VARIABLE_NAME, array_name.c_str(), new SgType(T_ARRAY), scope);
auto *decl = new SgDeclarationStatement(VAR_DECL);
decl->setExpression(1, new SgTypeExp(*type));
SgExpression *subs = new SgExprListExp();
auto *array_ref = new SgArrayRefExp(*array_symbol, *subs);
for (int i = 0; i < sizes.size(); i++)
{
const auto &p = sizes[i];
auto *d = new SgExpression(DDOT, new SgValueExp(p.first), new SgValueExp(p.second));
subs->setLhs(d);
if (i + 1 < sizes.size())
{
subs->setRhs(new SgExprListExp());
subs = subs->rhs();
}
}
decl->setExpression(0, array_ref);
auto comm = new SgStatement(COMM_STAT);
comm->setExpression(0, new SgExpression(COMM_LIST,
new SgVarRefExp(array_symbol),
NULL,
new SgSymbol(COMMON_NAME, common_block_name.c_str())));
return {{decl, comm}, array_symbol};
}
static SgExpression* findExprWithVariant(SgExpression* exp, int variant)
{
if (exp)
{
if (exp->variant() == variant)
return exp;
auto *l = findExprWithVariant(exp->lhs(), variant);
if (l)
return l;
auto *r = findExprWithVariant(exp->rhs(), variant);
if (r)
return r;
}
return NULL;
}
SgType* GetArrayType(DIST::Array *array)
{
if (!array)
return NULL;
for (const auto& decl_place : array->GetDeclInfo())
{
if (SgFile::switchToFile(decl_place.first) != -1)
{
auto* decl = SgStatement::getStatementByFileAndLine(decl_place.first, decl_place.second);
if (decl)
{
for (int i = 0; i < 3; i++)
{
auto* found_type = isSgTypeExp(findExprWithVariant(decl->expr(i), TYPE_OP));
if (found_type)
return found_type->type();
}
}
}
}
return NULL;
}
SgSymbol *insertDeclIfNeeded(const string &array_name,
const string &common_block_name,
DIST::Array *example_array,
FuncInfo *dest,
unordered_map<FuncInfo *, unordered_map<string, SgSymbol *>> &inserted_arrays)
{
auto *type = GetArrayType(example_array);
if (!type)
printInternalError(convertFileName(__FILE__).c_str(), __LINE__);
if (SgFile::switchToFile(dest->fileName) == -1)
printInternalError(convertFileName(__FILE__).c_str(), __LINE__);
auto &by_func = inserted_arrays[dest];
auto it = by_func.find(array_name);
if (it != by_func.end())
return it->second;
SgStatement *st = dest->funcPointer;
auto *end = st->lastNodeOfStmt();
st = st->lexNext();
while (st != end && !isSgExecutableStatement(st))
{
st = st->lexNext();
}
auto generated = generateDeclaration(array_name, common_block_name,
example_array->GetSizes(),
type, dest->funcPointer);
for (auto *new_stmt : generated.first)
st->insertStmtBefore(*new_stmt, *dest->funcPointer);
by_func[array_name] = generated.second;
return generated.second;
}
static pair<string, string> createNewArray(DIST::Array *example_array, const string &base_name,
const map<string, vector<FuncInfo *>> &allFuncInfo,
unordered_map<FuncInfo *, unordered_map<string, SgSymbol *>> &inserted_arrays)
{
auto common_block_name = base_name + "_merge_cb";
auto array_name = base_name;
for (const auto &by_file : allFuncInfo)
{
for (auto *func_info : by_file.second)
{
if (func_info->isMain)
{
insertDeclIfNeeded(
array_name,
common_block_name,
example_array,
func_info,
inserted_arrays);
}
}
}
return std::make_pair(array_name, common_block_name);
}
static void replaceArrayRec(SgExpression *e,
const unordered_set<string> &arrays_to_replace,
SgSymbol **func_symbol_hint,
const pair<string, string> &replace_by,
DIST::Array *example_array,
FuncInfo *func,
unordered_map<FuncInfo *, unordered_map<string, SgSymbol *>> &inserted_arrays)
{
if (!e)
return;
if (isArrayRef(e) && arrays_to_replace.find(e->symbol()->identifier()) != arrays_to_replace.end())
{
if (!(*func_symbol_hint))
{
*func_symbol_hint = insertDeclIfNeeded(
replace_by.first, replace_by.second,
example_array,
func,
inserted_arrays);
}
e->setSymbol(*func_symbol_hint);
}
replaceArrayRec(
e->lhs(),
arrays_to_replace,
func_symbol_hint,
replace_by,
example_array,
func,
inserted_arrays);
replaceArrayRec(
e->rhs(),
arrays_to_replace,
func_symbol_hint,
replace_by,
example_array,
func,
inserted_arrays);
}
static void replaceRegion(SgStatement* st, const unordered_map<string, string> &new_region_mapping)
{
if (!st)
return;
if(isSPF_stat(st) && st->variant() == SPF_PARALLEL_REG_DIR)
{
auto it = new_region_mapping.find(st->symbol()->identifier());
if (it != new_region_mapping.end())
st->setSymbol(*(new SgSymbol(CONST_NAME, it->second.c_str())));
}
}
void mergeCopyArrays(vector<ParallelRegion *> &regions, const map<string, vector<FuncInfo *>> &allFuncInfo)
{
for (const auto *region : regions)
{
__spf_print(1, "region %s\n", region->GetName().c_str());
const auto &dirs = region->GetDataDir();
__spf_print(1, " distr rules: %d\n", dirs.distrRules.size());
const auto &currentVariant = region->GetCurrentVariant();
int distr_idx = 0;
for (const auto &distr : dirs.distrRules)
{
const auto &dist_rule = distr.second.back().distRule;
string sizes;
for (const auto &p : distr.first->GetSizes())
{
if (!sizes.empty())
sizes.push_back(',');
sizes += std::to_string(p.first) + ":" + std::to_string(p.second);
}
__spf_print(1, " DIST %s(%s)", distr.first->GetName().c_str(), sizes.c_str());
for (const auto &dim : dist_rule)
__spf_print(1, " %c", dim == dist::BLOCK ? 'B' : '*');
__spf_print(1, "\n");
distr_idx++;
}
__spf_print(1, " align rules: %d\n", dirs.alignRules.size());
for (const auto &align : dirs.alignRules)
{
string sub_a, sub_b;
int i = 0;
for (const auto coefs : align.alignRule)
{
if (!sub_a.empty())
sub_a.push_back(',');
sub_a += std::to_string(coefs.first) + "*i" +
std::to_string(i) + "+" + std::to_string(coefs.second);
i++;
}
for (const auto coefs : align.alignRuleWith)
{
if (!sub_b.empty())
sub_b.push_back(',');
sub_b += std::to_string(coefs.second.first) + "*i" +
std::to_string(coefs.first) + "+" + std::to_string(coefs.second.second);
}
__spf_print(1, " ALIGN %s(%s) WITH %s(%s)\n",
align.alignArray->GetName().c_str(), sub_a.c_str(),
align.alignWith->GetName().c_str(), sub_b.c_str());
}
}
// parse directives
// new array name -> current arrays
unordered_map<string, unordered_set<DIST::Array *>> arrays_to_merge;
unordered_map<DIST::Array *, unordered_set<const AlignRule *>> array_alignment;
for (const auto &by_file : allFuncInfo)
{
const auto current_file_name = by_file.first;
if (SgFile::switchToFile(current_file_name) == -1)
printInternalError(convertFileName(__FILE__).c_str(), __LINE__);
for (auto *func_info : by_file.second)
{
SgStatement *curr_stmt = func_info->funcPointer;
if (!curr_stmt)
continue;
auto *stmt_end = curr_stmt->lastDeclaration();
if (!stmt_end)
continue;
stmt_end = stmt_end->lexNext();
for (; curr_stmt && curr_stmt != stmt_end; curr_stmt = curr_stmt->lexNext())
{
if (curr_stmt->comments())
{
vector<pair<string, string>> parsed_mapping;
parseMergeDirective(curr_stmt->comments(), parsed_mapping);
for (const auto &p : parsed_mapping)
{
auto *found_array = getArrayFromDeclarated(curr_stmt, p.first);
if (found_array)
{
arrays_to_merge[p.second].insert(found_array);
array_alignment[found_array] = {};
}
}
}
}
}
}
// find alignment rules for array
for (const auto *region : regions)
{
const auto &dirs = region->GetDataDir();
for (const auto &align : dirs.alignRules)
{
auto it = array_alignment.find(align.alignArray);
if (it != array_alignment.end())
it->second.insert(&align);
}
}
// old region -> new region
unordered_map<string, string> new_region_mapping;
// new array -> new region
unordered_map<string, string> arrays_new_region_mapping;
vector<string> created_region_names;
for (const auto &by_new_array : arrays_to_merge)
{
string new_region_name;
for (auto *current_array : by_new_array.second)
{
auto current_array_region = getNonDefaultRegion(current_array);
auto it = new_region_mapping.find(current_array_region);
if (it != new_region_mapping.end())
{
if (new_region_name.empty())
new_region_name = it->second;
else if (new_region_name != it->second)
printInternalError(convertFileName(__FILE__).c_str(), __LINE__);
}
}
if (new_region_name.empty())
{
new_region_name = "merged_reg_" + std::to_string(created_region_names.size());
created_region_names.push_back(new_region_name);
}
for (auto *current_array : by_new_array.second)
{
auto current_array_region = getNonDefaultRegion(current_array);
new_region_mapping[current_array_region] = new_region_name;
}
arrays_new_region_mapping[by_new_array.first] = new_region_name;
}
if (!checkSimilarTemplates(regions, new_region_mapping))
printInternalError(convertFileName(__FILE__).c_str(), __LINE__);
unordered_map<FuncInfo *, unordered_map<string, SgSymbol *>> inserted_arrays;
for (const auto &by_dest_array : arrays_to_merge)
{
const auto &copy_arrays = by_dest_array.second;
if (copy_arrays.empty())
printInternalError(convertFileName(__FILE__).c_str(), __LINE__);
auto *first_element = *copy_arrays.begin();
auto first_elem_rules_it = array_alignment.find(first_element);
if (first_elem_rules_it == array_alignment.end())
continue;
const auto &first_elem_rules = first_elem_rules_it->second;
for (auto *array_to_merge : copy_arrays)
{
auto array_rules_it = array_alignment.find(array_to_merge);
if (array_rules_it == array_alignment.end())
printInternalError(convertFileName(__FILE__).c_str(), __LINE__);
const auto &array_rules = array_rules_it->second;
if (!hasSameSizes(array_to_merge, first_element) || !hasSameAlignment(first_elem_rules, array_rules))
{
__spf_print(1, "Arrays %s and %s has different sizes or align rules\n",
array_to_merge->GetName().c_str(),
first_element->GetName().c_str());
printInternalError(convertFileName(__FILE__).c_str(), __LINE__);
}
}
__spf_print(1, "merge into %s (%s):\n", by_dest_array.first.c_str(), arrays_new_region_mapping[by_dest_array.first].c_str());
for (auto *array_to_merge : copy_arrays)
__spf_print(1, "%s\n", array_to_merge->GetName().c_str());
auto created_array_info = createNewArray(first_element, by_dest_array.first, allFuncInfo, inserted_arrays);
unordered_set<string> arrays_to_replace;
for (auto *array_to_merge : copy_arrays)
arrays_to_replace.insert(array_to_merge->GetShortName());
for (const auto &by_file : allFuncInfo)
{
if (SgFile::switchToFile(by_file.first) == -1)
printInternalError(convertFileName(__FILE__).c_str(), __LINE__);
for (auto *func_info : by_file.second)
{
SgSymbol *func_symbol_hint = nullptr;
SgStatement *st = func_info->funcPointer;
auto *func_end = st->lastNodeOfStmt();
st = st->lexNext();
while (st && !isSgExecutableStatement(st) && st != func_end)
st = st->lexNext();
while (st && st != func_end)
{
for (int i = 0; i < 3; i++)
{
replaceArrayRec(
st->expr(i),
arrays_to_replace,
&func_symbol_hint,
created_array_info,
first_element,
func_info,
inserted_arrays);
}
replaceRegion(st, new_region_mapping);
st = st->lexNext();
}
}
}
}
}

8
src/ParallelizationRegions/parse_merge_dirs.h Normal file
View File

@@ -0,0 +1,8 @@
#include "../GraphCall/graph_calls.h"
#include "ParRegions.h"
#include <string>
#include <vector>
#include <map>
void mergeCopyArrays(std::vector<ParallelRegion*> &regions, const std::map<std::string, std::vector<FuncInfo*>> &allFuncInfo);

104
src/Predictor/PredictScheme.cpp
View File

@@ -23,7 +23,6 @@
#include "expr_transform.h"
#include "../LoopAnalyzer/loop_analyzer.h"
#include "CFGraph/CFGraph.h"
#include "../Utils/utils.h"
#include "json.hpp"
@@ -38,109 +37,6 @@ using SAPFOR::CFG_Settings;
using json = nlohmann::json;
void runPredictSchemeOld(SgProject &project,
vector<vector<size_t>> &topologies,
vector<ParallelRegion*> &parallelRegions,
map<string, vector<LoopGraph*>> &loopGraph,
map<string, vector<SpfInterval*>> &intervals,
map<string, vector<Messages>> &SPF_messages)
{
int maxSizeDist = 0;
for (int z = 0; z < parallelRegions.size(); ++z)
{
const DataDirective &dataDirectives = parallelRegions[z]->GetDataDir();
const vector<int> &currentVariant = parallelRegions[z]->GetCurrentVariant();
auto &tmp = dataDirectives.distrRules;
vector<pair<DIST::Array*, const DistrVariant*>> currentVar;
for (int z1 = 0; z1 < currentVariant.size(); ++z1)
currentVar.push_back(std::make_pair(tmp[z1].first, &tmp[z1].second[currentVariant[z1]]));
for (auto &elem : currentVar)
{
DIST::Array *array = elem.first;
const DistrVariant *var = elem.second;
int countBlock = 0;
for (int z = 0; z < var->distRule.size(); ++z)
if (var->distRule[z] == dist::BLOCK)
++countBlock;
maxSizeDist = std::max(maxSizeDist, countBlock);
}
}
SpfInterval *mainIterval = getMainInterval(&project, intervals, SPF_messages);
topologies.clear();
if (maxSizeDist)
{
const int procNum = 8;
//TODO:
//topologies = getTopologies(procNum, maxSizeDist);
throw -10;
const int countOfTop = topologies.size();
if (countOfTop < 0)
printInternalError(convertFileName(__FILE__).c_str(), __LINE__);
for (auto &inter : intervals)
initTimeForIntervalTree(countOfTop, inter.second);
for (int z = 0; z < parallelRegions.size(); ++z)
{
const DataDirective &dataDirectives = parallelRegions[z]->GetDataDir();
const vector<int> &currentVariant = parallelRegions[z]->GetCurrentVariant();
DIST::Arrays<int> &allArrays = parallelRegions[z]->GetAllArraysToModify();
auto &tmp = dataDirectives.distrRules;
vector<pair<DIST::Array*, const DistrVariant*>> currentVar;
for (int z1 = 0; z1 < currentVariant.size(); ++z1)
currentVar.push_back(std::make_pair(tmp[z1].first, &tmp[z1].second[currentVariant[z1]]));
map<LoopGraph*, ParallelDirective*> parallelDirs;
vector<std::tuple<DIST::Array*, vector<long>, pair<string, int>>> allSingleRemotes;
for (int i = project.numberOfFiles() - 1; i >= 0; --i)
{
SgFile *file = &(project.file(i));
auto fountInfo = findAllDirectives(file, getObjectForFileFromMap(file->filename(), loopGraph), parallelRegions[z]->GetId());
parallelDirs.insert(fountInfo.begin(), fountInfo.end());
auto fountRem = findAllSingleRemotes(file, parallelRegions[z]->GetId(), parallelRegions);
allSingleRemotes.insert(allSingleRemotes.end(), fountRem.begin(), fountRem.end());
}
//TODO!
//int err = predictScheme(parallelRegions[z], currentVar, allArrays.GetArrays(), parallelDirs, intervals, SPF_messages, allSingleRemotes, maxSizeDist, procNum);
/*if (err != 0)
internalExit = err;*/
}
vector<SpfInterval*> tmp = { mainIterval };
aggregatePredictedTimes(tmp);
int idx = 0;
int best = -1;
double bestSpeedUp = 0;
for (auto &top : topologies)
{
string outStr = "";
for (auto &elem : top)
outStr += std::to_string(elem) + " ";
double currS = mainIterval->exec_time / mainIterval->predictedTimes[idx];
__spf_print(1, "%d: speed up %f for top. %s\n", idx, currS, outStr.c_str());
if (best == -1 || bestSpeedUp < currS)
{
bestSpeedUp = currS;
best = idx;
}
++idx;
}
__spf_print(1, "best topology %d with speed up %f\n", best, bestSpeedUp);
}
else
for (auto &inter : intervals)
initTimeForIntervalTree(0, inter.second);
}
static void fillParallel(SgExpression *exp, ParallelStats &parStats, int &totalScoreComm)
{
if (exp)

4
src/Predictor/PredictScheme.h
View File

@@ -60,6 +60,4 @@ public:
void processFileToPredict(SgFile *file, PredictorStats &predictorCounts);
void calculateStatsForPredictor(const std::map<std::string, std::vector<FuncInfo*>>& allFuncInfo, const std::map<std::string, std::map<int, Gcov_info>>& gCovInfo);
void parseDvmDirForPredictor(const std::map<std::tuple<int, std::string, std::string>, std::pair<DIST::Array*, DIST::ArrayAccessInfo*>>& declaredArrays, const std::map<std::string, CommonBlock*>& commonBlocks, const std::map<std::string, std::vector<FuncInfo*>>& allFuncInfo, const std::map<std::string, std::map<int, Gcov_info>>& gCovInfo);
void runPredictSchemeOld(SgProject &project, std::vector<std::vector<size_t>> &topologies, std::vector<ParallelRegion*> &parallelRegions, std::map<std::string, std::vector<LoopGraph*>> &loopGraph, std::map<std::string, std::vector<SpfInterval*>> &intervals, std::map<std::string, std::vector<Messages>> &SPF_messages);
void parseDvmDirForPredictor(const std::map<std::tuple<int, std::string, std::string>, std::pair<DIST::Array*, DIST::ArrayAccessInfo*>>& declaredArrays, const std::map<std::string, CommonBlock*>& commonBlocks, const std::map<std::string, std::vector<FuncInfo*>>& allFuncInfo, const std::map<std::string, std::map<int, Gcov_info>>& gCovInfo);

470
src/Predictor/PredictSchemeWithLibrary.cpp
View File

@@ -1,470 +0,0 @@
#include "leak_detector.h"
#include <limits>
#include <map>
#include <vector>
#include <string>
#include <tuple>
#include "dvm.h"
#include "PredictSchemeWithLibrary.h"
#include "../../projects/libpredictor/include/libpredict/predictor.h"
#include "../DirectiveProcessing/directive_parser.h"
#include "../Distribution/DvmhDirective.h"
#include "../ParallelizationRegions/ParRegions.h"
#include "../GraphLoop/graph_loops_func.h"
#include "../Utils/errors.h"
#include "../Utils/utils.h"
using std::map;
using std::pair;
using std::string;
using std::tuple;
using std::vector;
map<size_t, size_t> createTemplateIdMapping(const vector<ParallelRegion*>& parallelRegions)
{
size_t maxArrayId = 0;
for (int z = 0; z < parallelRegions.size(); ++z) {
const DataDirective& dataDirectives = parallelRegions[z]->GetDataDir();
for (const auto& distrRule : dataDirectives.distrRules) {
if (distrRule.first && !distrRule.first->IsTemplate()) {
maxArrayId = std::max(maxArrayId, (size_t)distrRule.first->GetId());
}
}
for (const auto& alignRule : dataDirectives.alignRules) {
if (alignRule.alignArray && !alignRule.alignArray->IsTemplate()) {
maxArrayId = std::max(maxArrayId, (size_t)alignRule.alignArray->GetId());
}
}
}
map<size_t, size_t> templateIdMapping;
size_t nextTemplateId = maxArrayId + 1;
for (int z = 0; z < parallelRegions.size(); ++z) {
const DataDirective& dataDirectives = parallelRegions[z]->GetDataDir();
for (const auto& distrRule : dataDirectives.distrRules) {
if (distrRule.first && distrRule.first->IsTemplate()) {
size_t originalId = distrRule.first->GetId();
if (templateIdMapping.find(originalId) == templateIdMapping.end()) {
templateIdMapping[originalId] = nextTemplateId++;
}
}
}
for (const auto& alignRule : dataDirectives.alignRules) {
if (alignRule.alignWith && alignRule.alignWith->IsTemplate()) {
size_t originalId = alignRule.alignWith->GetId();
if (templateIdMapping.find(originalId) == templateIdMapping.end()) {
templateIdMapping[originalId] = nextTemplateId++;
}
}
}
}
return templateIdMapping;
}
PrecomputedLibpredictParams precomputeLibpredictParams(
SgProject& project,
const vector<ParallelRegion*>& parallelRegions,
const map<string, vector<LoopGraph*>>& loopGraph,
const map<size_t, size_t>& templateIdMapping)
{
PrecomputedLibpredictParams result;
// distribute and align from parallelRegions
for (int z = 0; z < parallelRegions.size(); ++z) {
const DataDirective& dataDirectives = parallelRegions[z]->GetDataDir();
const vector<int>& currentVariant = parallelRegions[z]->GetCurrentVariant();
const DIST::Arrays<int>& allArrays = parallelRegions[z]->GetAllArrays();
auto& tmp = dataDirectives.distrRules;
vector<pair<DIST::Array*, const DistrVariant*>> currentVar;
for (int z1 = 0; z1 < currentVariant.size(); ++z1) {
currentVar.push_back(std::make_pair(tmp[z1].first, &tmp[z1].second[currentVariant[z1]]));
}
// distribute
for (const auto& distrRule : currentVar) {
DIST::Array* array = distrRule.first;
const DistrVariant* variant = distrRule.second;
if (array && variant && !array->IsNotDistribute()) {
PrecomputedDistributeParams params;
size_t originalId = array->GetId();
params.arrayId = originalId;
if (array->IsTemplate()) {
auto it = templateIdMapping.find(originalId);
if (it != templateIdMapping.end()) {
params.arrayId = it->second;
}
}
params.elemSize = array->GetTypeSize();
params.array = array;
const auto& arraySizes = array->GetSizes();
for (int dim = 0; dim < array->GetDimSize(); ++dim) {
size_t dimSize = arraySizes[dim].second - arraySizes[dim].first + 1;
if (dim < variant->distRule.size() && variant->distRule[dim] == dist::BLOCK) {
params.axisDistributions.emplace_back(dimSize, libpredict::TypeDistribute::BLOCK);
} else {
params.axisDistributions.emplace_back(dimSize, libpredict::TypeDistribute::NONE);
}
}
const auto& shadowSpec = array->GetShadowSpec();
for (int dim = 0; dim < shadowSpec.size() && dim < array->GetDimSize(); ++dim) {
if (dim < variant->distRule.size() && variant->distRule[dim] == dist::BLOCK) {
params.shadowEdges.emplace_back(shadowSpec[dim].first, shadowSpec[dim].second);
}
}
result.distributeParams.push_back(params);
}
}
// align
for (const auto& alignRule : dataDirectives.alignRules) {
DIST::Array* alignArray = alignRule.alignArray;
DIST::Array* alignWithArray = alignRule.alignWith;
if (alignArray && alignWithArray && !alignArray->IsNotDistribute()) {
PrecomputedAlignParams params;
params.arrayId = alignArray->GetId();
size_t originalDistributedArrayId = alignWithArray->GetId();
params.distributedArrayId = originalDistributedArrayId;
if (alignWithArray->IsTemplate()) {
auto it = templateIdMapping.find(originalDistributedArrayId);
if (it != templateIdMapping.end()) {
params.distributedArrayId = it->second;
}
}
params.elemSize = alignArray->GetTypeSize();
params.alignArray = alignArray;
params.alignWithArray = alignWithArray;
const auto& arraySizes = alignArray->GetSizes();
for (int dim = 0; dim < alignArray->GetDimSize(); ++dim) {
size_t dimSize = arraySizes[dim].second - arraySizes[dim].first + 1;
params.dimensions.push_back(dimSize);
}
for (int dim = 0; dim < alignWithArray->GetDimSize(); ++dim) {
bool found = false;
for (int i = 0; i < alignRule.alignRuleWith.size(); ++i) {
const auto& ruleWith = alignRule.alignRuleWith[i];
if (ruleWith.first == dim) {
const auto& rule = ruleWith.second;
if (rule.first == 0) {
// constant
params.distributionExpressions.emplace_back(rule.second);
} else {
// linear expression a * I + b
params.distributionExpressions.emplace_back(i, rule.first, rule.second);
}
found = true;
break;
}
}
if (!found) {
// There is no rule for this measurement
params.distributionExpressions.emplace_back();
}
}
const auto& shadowSpec = alignArray->GetShadowSpec();
for (int dim = 0; dim < shadowSpec.size() && dim < alignArray->GetDimSize(); ++dim) {
params.shadowEdges.emplace_back(shadowSpec[dim].first, shadowSpec[dim].second);
}
result.alignParams.push_back(params);
}
}
// shadow_renew
map<LoopGraph*, ParallelDirective*> parallelDirs;
for (int i = project.numberOfFiles() - 1; i >= 0; --i) {
SgFile* file = &(project.file(i));
auto fountInfo = findAllDirectives(
file,
getObjectForFileFromMap(file->filename(), const_cast<map<string, vector<LoopGraph*>>&>(loopGraph)),
parallelRegions[z]->GetId());
parallelDirs.insert(fountInfo.begin(), fountInfo.end());
}
for (auto& dirPair : parallelDirs) {
LoopGraph* loopPtr = dirPair.first;
ParallelDirective* directive = dirPair.second;
if (directive && !directive->shadowRenew.empty()) {
for (size_t shadowIdx = 0; shadowIdx < directive->shadowRenew.size(); ++shadowIdx) {
const auto& shadowRenewItem = directive->shadowRenew[shadowIdx];
const string& arrayName = shadowRenewItem.first.second; // uniqName
const vector<pair<int, int>>& bounds = shadowRenewItem.second;
DIST::Array* shadowArray = allArrays.GetArrayByName(arrayName);
if (shadowArray == NULL) {
continue;
}
if (shadowArray && !shadowArray->IsNotDistribute()) {
PrecomputedShadowRenewParams params;
params.arrayId = shadowArray->GetId();
params.shadowArray = shadowArray;
for (const auto& bound : bounds) {
params.shadow_renew.emplace_back(static_cast<size_t>(bound.first),
static_cast<size_t>(bound.second));
}
params.corner = directive->shadowRenewCorner[shadowIdx];
params.number_loop_iterations = loopPtr ? static_cast<size_t>(loopPtr->countOfIters) : 1;
result.shadowRenewParams.push_back(params);
}
}
}
}
}
return result;
}
double runLibpredictCalc(const vector<size_t>& topology,
const string& clusterConfStr,
const PrecomputedLibpredictParams& precomputedParams,
map<string, vector<Messages>>& SPF_messages)
{
libpredict::RetInitGrid retInitGrid = libpredict::InitGrid(topology[0], topology[1], topology[2], topology[3]);
if (retInitGrid != libpredict::INIT_GRID_SUCCESS) {
__spf_print(1, "ERROR: Failed to initialize libpredict grid with topology: %zu %zu %zu %zu, return code: %d\n",
topology[0], topology[1], topology[2], topology[3], (int)retInitGrid);
std::wstring messageR, messageE;
__spf_printToLongBuf(messageE, L"Failed to initialize libpredict grid with topology: %zu %zu %zu %zu, return code: %d",
topology[0], topology[1], topology[2], topology[3], (int)retInitGrid);
__spf_printToLongBuf(messageR, R207);
getObjectForFileFromMap(clusterConfStr.c_str(), SPF_messages).push_back(Messages(ERROR, 1, messageR, messageE, 1064));
return -1;
}
// distribute
for (const auto& params : precomputedParams.distributeParams) {
libpredict::RetDistribute retDistribute = libpredict::Distribute(
params.arrayId, params.elemSize, params.axisDistributions, params.shadowEdges);
if (retDistribute != libpredict::DISTRIBUTE_SUCCESS) {
__spf_print(1, "ERROR: Failed to distribute array '%s' (id=%zu) with libpredict, return code: %d\n",
params.array->GetShortName().c_str(), params.arrayId, (int)retDistribute);
std::wstring messageR, messageE;
__spf_printToLongBuf(messageE, L"Failed to distribute array '%s' with libpredict, return code: %d",
to_wstring(params.array->GetShortName()).c_str(), (int)retDistribute);
__spf_printToLongBuf(messageR, R208);
getObjectForFileFromMap(params.array->GetDeclInfo().begin()->first.c_str(), SPF_messages).push_back(Messages(ERROR, params.array->GetDeclInfo().begin()->second, messageR, messageE, 1065));
}
}
// align
for (const auto& params : precomputedParams.alignParams) {
libpredict::RetAlign retAlign = libpredict::Align(
params.arrayId, params.distributedArrayId, params.elemSize,
params.dimensions, params.distributionExpressions, params.shadowEdges);
if (retAlign != libpredict::ALIGN_SUCCESS) {
__spf_print(1, "ERROR: Failed to align array '%s' (id=%zu) with array '%s' (id=%zu), return code: %d\n",
params.alignArray->GetShortName().c_str(), params.arrayId,
params.alignWithArray->GetShortName().c_str(), params.distributedArrayId, (int)retAlign);
std::wstring messageR, messageE;
__spf_printToLongBuf(messageE, L"Failed to align array '%s' with array '%s' using libpredict, return code: %d",
to_wstring(params.alignArray->GetShortName()).c_str(),
to_wstring(params.alignWithArray->GetShortName()).c_str(), (int)retAlign);
__spf_printToLongBuf(messageR, R209);
getObjectForFileFromMap(params.alignArray->GetDeclInfo().begin()->first.c_str(), SPF_messages).push_back(Messages(ERROR, params.alignArray->GetDeclInfo().begin()->second, messageR, messageE, 1066));
}
}
// shadow_renew
for (const auto& params : precomputedParams.shadowRenewParams) {
libpredict::RetShadowRenew retShadowRenew = libpredict::ShadowRenew(
params.arrayId, params.shadow_renew, params.corner, params.number_loop_iterations);
if (retShadowRenew != libpredict::SHADOW_RENEW_SUCCESS) {
__spf_print(1, "ERROR: Failed to process shadow_renew for array '%s' (id=%zu), return code: %d\n",
params.shadowArray->GetShortName().c_str(), params.arrayId, (int)retShadowRenew);
std::wstring messageR, messageE;
__spf_printToLongBuf(messageE, L"Failed to process shadow_renew for array '%s' with libpredict, return code: %d",
to_wstring(params.shadowArray->GetShortName()).c_str(), (int)retShadowRenew);
__spf_printToLongBuf(messageR, R210);
getObjectForFileFromMap(params.shadowArray->GetDeclInfo().begin()->first.c_str(), SPF_messages).push_back(Messages(ERROR, params.shadowArray->GetDeclInfo().begin()->second, messageR, messageE, 1067));
}
}
return libpredict::GetTime();
}
void runPredictScheme(SgProject& project,
const vector<ParallelRegion*>& parallelRegions,
map<string, vector<LoopGraph*>>& loopGraph,
map<string, vector<Messages>>& SPF_messages)
{
// calculating maximum dimension of distribution
int maxSizeDist = 0;
for (int z = 0; z < parallelRegions.size(); ++z) {
const DataDirective& dataDirectives = parallelRegions[z]->GetDataDir();
const vector<int>& currentVariant = parallelRegions[z]->GetCurrentVariant();
auto& tmp = dataDirectives.distrRules;
vector<const DistrVariant*> currentVar;
for (int z1 = 0; z1 < currentVariant.size(); ++z1) {
currentVar.push_back(&tmp[z1].second[currentVariant[z1]]);
}
for (auto var : currentVar) {
int countBlock = 0;
for (int z = 0; z < var->distRule.size(); ++z) {
if (var->distRule[z] == dist::BLOCK) {
++countBlock;
}
}
maxSizeDist = std::max(maxSizeDist, countBlock);
}
}
// calculating name of a cluster configuration file
string clusterConfStr;
if (project.numberOfFiles() > 0) {
string firstFilePath = project.fileName(0);
size_t lastSlash = firstFilePath.find_last_of("/\\");
clusterConfStr = firstFilePath.substr(0, lastSlash + 1) + "cluster.conf";
}
// creating template ID display to avoid conflicts
map<size_t, size_t> templateIdMapping = createTemplateIdMapping(parallelRegions);
// Precomputing parameters of directive functions from libpredict
PrecomputedLibpredictParams precomputedParams = precomputeLibpredictParams(
project, parallelRegions, loopGraph, templateIdMapping);
// iterating through topologies and processes_per_processor to find most optimal one
if (maxSizeDist) {
if (maxSizeDist > 4) {
maxSizeDist = 4;
}
// Initialize cluster
int maxCoresCount = 0;
libpredict::RetInitCluster retInitCluster = libpredict::InitCluster(clusterConfStr, maxCoresCount);
if (retInitCluster != libpredict::INIT_CLUSTER_SUCCESS) {
__spf_print(1, "ERROR: Failed to initialize libpredict cluster with config: %s, return code: %d\n", clusterConfStr.c_str(), (int)retInitCluster);
std::wstring messageR, messageE;
__spf_printToLongBuf(messageE, L"Failed to initialize libpredict cluster with config: %s, return code: %d",
to_wstring(clusterConfStr).c_str(), (int)retInitCluster);
__spf_printToLongBuf(messageR, R206);
getObjectForFileFromMap(clusterConfStr.c_str(), SPF_messages).push_back(Messages(ERROR, 1, messageR, messageE, 1063));
return;
}
vector<size_t> bestTopology;
double bestTime = std::numeric_limits<double>::max();
size_t bestProcessesPerProcessor = 0;
int prevProcCount = -1;
for (size_t processes_per_processor = 1; processes_per_processor <= maxCoresCount; ++processes_per_processor) {
int procCount = 0;
libpredict::RetInitMapping retInitMapping = libpredict::InitMapping(processes_per_processor, procCount);
if (retInitMapping != libpredict::INIT_MAPPING_SUCCESS) {
__spf_print(1, "ERROR: Failed to initialize libpredict mapping with processes_per_processor: %zu, return code: %d\n",
processes_per_processor, (int)retInitMapping);
std::wstring messageR, messageE;
__spf_printToLongBuf(messageE, L"Failed to initialize libpredict mapping with processes_per_processor: %zu, return code: %d",
processes_per_processor, (int)retInitMapping);
__spf_printToLongBuf(messageR, R211);
getObjectForFileFromMap(clusterConfStr.c_str(), SPF_messages).push_back(Messages(ERROR, 1, messageR, messageE, 1068));
continue;
}
if (procCount == 0) {
break; // No more processors available
}
if (procCount == prevProcCount) {
continue; // Skip with procCount value unchanged for different processes_per_processor
}
prevProcCount = procCount;
__spf_print(1, "Calculate with processes_per_processor=%zu, procCount=%d\n", processes_per_processor, procCount);
for (size_t n1 = 2; n1 <= procCount; ++n1) {
for (size_t n2 = 1; n2 <= n1 && n1 * n2 <= procCount; ++n2) {
if (n2 != 1 && maxSizeDist < 2 || n2 == 1 && maxSizeDist == 2) {
continue;
}
for (size_t n3 = 1; n3 <= n2 && n1 * n2 * n3 <= procCount; ++n3) {
if (n3 != 1 && maxSizeDist < 3 || n3 == 1 && maxSizeDist == 3) {
continue;
}
for (size_t n4 = 1; n4 <= n3 && n1 * n2 * n3 * n4 <= procCount; ++n4) {
if (n4 != 1 && maxSizeDist < 4 || n4 == 1 && maxSizeDist == 4) {
continue;
}
vector<size_t> topology = {n1, n2, n3, n4};
double currTime = runLibpredictCalc(topology, clusterConfStr, precomputedParams, SPF_messages);
string outStr = "";
for (const auto& elem : topology) {
outStr += std::to_string(elem) + " ";
}
__spf_print(1, "topology %s has time %f\n", outStr.c_str(), currTime);
if (currTime == -1) {
continue;
}
if (currTime < bestTime) {
bestTime = currTime;
bestTopology = topology;
bestProcessesPerProcessor = processes_per_processor;
}
}
}
}
}
}
if (!bestTopology.empty()) {
string outStr;
for (const auto& elem : bestTopology) {
outStr += std::to_string(elem) + " ";
}
__spf_print(1, "best topology %s with time %f (processes_per_processor=%zu)\n",
outStr.c_str(), bestTime, bestProcessesPerProcessor);
}
} else {
__spf_print(1, "impossible to calculate best topology: project does not contain distribution directives\n");
}
}

56
src/Predictor/PredictSchemeWithLibrary.h
View File

@@ -1,56 +0,0 @@
#pragma once
#include <vector>
#include <map>
#include <string>
#include "dvm.h"
#include "graph_calls.h"
#include "../../projects/libpredictor/include/libpredict/predictor.h"
struct PrecomputedDistributeParams {
size_t arrayId;
size_t elemSize;
std::vector<libpredict::DistributeAxisRule> axisDistributions;
std::vector<std::pair<size_t, size_t>> shadowEdges;
DIST::Array* array;
};
struct PrecomputedAlignParams {
size_t arrayId;
size_t distributedArrayId;
size_t elemSize;
std::vector<size_t> dimensions;
std::vector<libpredict::AlignDisplay> distributionExpressions;
std::vector<std::pair<size_t, size_t>> shadowEdges;
DIST::Array* alignArray;
DIST::Array* alignWithArray;
};
struct PrecomputedShadowRenewParams {
size_t arrayId;
std::vector<std::pair<size_t, size_t>> shadow_renew;
bool corner;
size_t number_loop_iterations;
DIST::Array* shadowArray;
};
struct PrecomputedLibpredictParams {
std::vector<PrecomputedDistributeParams> distributeParams;
std::vector<PrecomputedAlignParams> alignParams;
std::vector<PrecomputedShadowRenewParams> shadowRenewParams;
};
PrecomputedLibpredictParams precomputeLibpredictParams(
SgProject& project,
const std::vector<ParallelRegion*>& parallelRegions,
const std::map<std::string, std::vector<LoopGraph*>>& loopGraph,
const std::map<size_t, size_t>& templateIdMapping);
void runPredictScheme(SgProject& project,
const std::vector<ParallelRegion*>& parallelRegions,
std::map<std::string, std::vector<LoopGraph*>>& loopGraph,
std::map<std::string, std::vector<Messages>>& SPF_messages);
double runLibpredictCalc(const std::vector<size_t>& topology,
const std::string& clusterConfStr,
const PrecomputedLibpredictParams& precomputedParams,
std::map<std::string, std::vector<Messages>>& SPF_messages);

110
src/Sapfor.cpp
View File

@@ -23,6 +23,7 @@
#include "ParallelizationRegions/ParRegions_func.h"
#include "ParallelizationRegions/resolve_par_reg_conflicts.h"
#include "ParallelizationRegions/expand_extract_reg.h"
#include "ParallelizationRegions/parse_merge_dirs.h"
#include "Distribution/Distribution.h"
#include "Distribution/GraphCSR.h"
@@ -58,7 +59,6 @@
#include "expr_transform.h"
#include "Predictor/PredictScheme.h"
#include "Predictor/PredictSchemeWithLibrary.h"
#include "Predictor/PredictorModel.h"
#include "SageAnalysisTool/depInterfaceExt.h"
#include "DvmhRegions/DvmhRegionInserter.h"
@@ -1733,7 +1733,103 @@ static bool runAnalysis(SgProject &project, const int curr_regime, const bool ne
}
}
else if (curr_regime == PREDICT_SCHEME)
runPredictScheme(project, parallelRegions, loopGraph, SPF_messages);
{
int maxSizeDist = 0;
for (int z = 0; z < parallelRegions.size(); ++z)
{
const DataDirective &dataDirectives = parallelRegions[z]->GetDataDir();
const vector<int> &currentVariant = parallelRegions[z]->GetCurrentVariant();
auto &tmp = dataDirectives.distrRules;
vector<pair<DIST::Array*, const DistrVariant*>> currentVar;
for (int z1 = 0; z1 < currentVariant.size(); ++z1)
currentVar.push_back(make_pair(tmp[z1].first, &tmp[z1].second[currentVariant[z1]]));
for (auto &elem : currentVar)
{
DIST::Array *array = elem.first;
const DistrVariant *var = elem.second;
int countBlock = 0;
for (int z = 0; z < var->distRule.size(); ++z)
if (var->distRule[z] == dist::BLOCK)
++countBlock;
maxSizeDist = std::max(maxSizeDist, countBlock);
}
}
SpfInterval *mainIterval = getMainInterval(&project, intervals, SPF_messages);
topologies.clear();
if (maxSizeDist)
{
const int procNum = 8;
//TODO:
//topologies = getTopologies(procNum, maxSizeDist);
throw -10;
const int countOfTop = topologies.size();
if (countOfTop < 0)
printInternalError(convertFileName(__FILE__).c_str(), __LINE__);
for (auto &inter : intervals)
initTimeForIntervalTree(countOfTop, inter.second);
for (int z = 0; z < parallelRegions.size(); ++z)
{
const DataDirective &dataDirectives = parallelRegions[z]->GetDataDir();
const vector<int> &currentVariant = parallelRegions[z]->GetCurrentVariant();
DIST::Arrays<int> &allArrays = parallelRegions[z]->GetAllArraysToModify();
auto &tmp = dataDirectives.distrRules;
vector<pair<DIST::Array*, const DistrVariant*>> currentVar;
for (int z1 = 0; z1 < currentVariant.size(); ++z1)
currentVar.push_back(make_pair(tmp[z1].first, &tmp[z1].second[currentVariant[z1]]));
map<LoopGraph*, ParallelDirective*> parallelDirs;
vector<std::tuple<DIST::Array*, vector<long>, pair<string, int>>> allSingleRemotes;
for (int i = n - 1; i >= 0; --i)
{
SgFile *file = &(project.file(i));
auto fountInfo = findAllDirectives(file, getObjectForFileFromMap(file->filename(), loopGraph), parallelRegions[z]->GetId());
parallelDirs.insert(fountInfo.begin(), fountInfo.end());
auto fountRem = findAllSingleRemotes(file, parallelRegions[z]->GetId(), parallelRegions);
allSingleRemotes.insert(allSingleRemotes.end(), fountRem.begin(), fountRem.end());
}
//TODO!
//int err = predictScheme(parallelRegions[z], currentVar, allArrays.GetArrays(), parallelDirs, intervals, SPF_messages, allSingleRemotes, maxSizeDist, procNum);
/*if (err != 0)
internalExit = err;*/
}
vector<SpfInterval*> tmp = { mainIterval };
aggregatePredictedTimes(tmp);
int idx = 0;
int best = -1;
double bestSpeedUp = 0;
for (auto &top : topologies)
{
string outStr = "";
for (auto &elem : top)
outStr += std::to_string(elem) + " ";
double currS = mainIterval->exec_time / mainIterval->predictedTimes[idx];
__spf_print(1, "%d: speed up %f for top. %s\n", idx, currS, outStr.c_str());
if (best == -1 || bestSpeedUp < currS)
{
bestSpeedUp = currS;
best = idx;
}
++idx;
}
__spf_print(1, "best topology %d with speed up %f\n", best, bestSpeedUp);
}
else
for (auto &inter : intervals)
initTimeForIntervalTree(0, inter.second);
}
else if (curr_regime == CREATE_INTER_TREE)
{
if (keepFiles)
@@ -1827,6 +1923,10 @@ static bool runAnalysis(SgProject &project, const int curr_regime, const bool ne
transformAssumedSizeParameters(allFuncInfo);
else if (curr_regime == FIND_PRIVATE_ARRAYS_ANALYSIS)
FindPrivateArrays(loopGraph, fullIR, insertedPrivates);
else if (curr_regime == MERGE_COPY_ARRAYS)
{
mergeCopyArrays(parallelRegions, allFuncInfo);
}
else if (curr_regime == ARRAY_PROPAGATION)
ArrayConstantPropagation(project);
@@ -2134,8 +2234,9 @@ void runPass(const int curr_regime, const char *proj_name, const char *folderNam
runAnalysis(*project, CALCULATE_STATS_SCHEME, false);
if (!folderName && !consoleMode || predictOn)
runAnalysis(*project, PREDICT_SCHEME, false);
//TODO: need to rewrite this to new algo
/*if (!folderName && !consoleMode || predictOn)
runAnalysis(*project, PREDICT_SCHEME, false); */
runAnalysis(*project, REMOVE_COPIES, false);
runAnalysis(*project, SWAP_LOOPS, false);
@@ -2283,6 +2384,7 @@ void runPass(const int curr_regime, const char *proj_name, const char *folderNam
case FIX_COMMON_BLOCKS:
case TEST_PASS:
case SET_IMPLICIT_NONE:
case MERGE_COPY_ARRAYS:
runAnalysis(*project, curr_regime, false);
case SUBST_EXPR_RD_AND_UNPARSE:
case SUBST_EXPR_AND_UNPARSE:

3
src/Sapfor.h
View File

@@ -88,6 +88,8 @@ enum passes {
REMOVE_DVM_INTERVALS,
VERIFY_DVM_DIRS,
MERGE_COPY_ARRAYS,
REMOVE_DIST_ARRAYS_FROM_IO,
SUBST_EXPR,
@@ -273,6 +275,7 @@ static void setPassValues()
passNames[VERIFY_DVM_DIRS] = "VERIFY_DVM_DIRS";
passNames[REMOVE_DVM_DIRS_TO_COMMENTS] = "REMOVE_DVM_DIRS_TO_COMMENTS";
passNames[REMOVE_SPF_DIRS] = "REMOVE_SPF_DIRS";
passNames[MERGE_COPY_ARRAYS] = "MERGE_COPY_ARRAYS";
passNames[REMOVE_DIST_ARRAYS_FROM_IO] = "REMOVE_DIST_ARRAYS_FROM_IO";
passNames[SUBST_EXPR] = "SUBST_EXPR";
passNames[SUBST_EXPR_RD] = "SUBST_EXPR_RD";

2
src/SapforData.h
View File

@@ -132,7 +132,7 @@ std::map<std::string, PredictorStats> allPredictorStats;
//for DVM INTERVALS
std::map<std::string, std::vector<SpfInterval*>> intervals; // file -> intervals
std::vector<std::vector<size_t>> topologies; // current topologies
std::vector<std::vector<long>> topologies; // current topologies
//
//for GCOV_PARSER

1
src/Utils/PassManager.h
View File

@@ -322,6 +322,7 @@ void InitPassesDependencies(map<passes, vector<passes>> &passDepsIn, set<passes>
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);
Pass(CREATE_TEMPLATE_LINKS) <= Pass(MERGE_COPY_ARRAYS);
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,

21
src/Utils/errors.h
View File

@@ -78,12 +78,7 @@ enum typeMessage { WARR, ERROR, NOTE };
// 60 "Format misplaced"
// 61 "Array has declaration area conflict"
// 62 "need to move common declaration to main for DECLATE"
// 63 "Failed to initialize libpredict cluster"
// 64 "Failed to initialize libpredict grid"
// 65 "Failed to distribute array with libpredict"
// 66 "Failed to align array with libpredict"
// 67 "Failed to process shadow_renew with libpredict"
//
//
// 20xx TRANSFORM GROUP
// 01 "can not convert array assign to loop"
// 02 "converted arithmetic IF to simple IF"
@@ -310,7 +305,7 @@ static void printStackTrace() { };
} \
} while (0)
// Свободный - R210
// Свободный - R206
// Гайд по русификации сообщений: При добавлении нового сообщения, меняется последний сводобный идентификатор.
// В этом файле остаются только спецификаторы, для которых будет заполнен текст. Полный текст пишется в файле
// russian_errors_text.txt. Спецификаторы там тоже сохраняются, по ним в визуализаторе будет восстановлен
@@ -509,18 +504,6 @@ static const wchar_t *R183 = L"R183:";
static const wchar_t *R184 = L"R184:%s";
//1062
static const wchar_t* R205 = L"R205:%s#%s";
//1063
static const wchar_t* R206 = L"R206:";
//1064
static const wchar_t* R207 = L"R207:";
//1065
static const wchar_t* R208 = L"R208:";
//1066
static const wchar_t* R209 = L"R209:";
//1067
static const wchar_t* R210 = L"R210:";
//1068
static const wchar_t* R211 = L"R211:";
//2001
static const wchar_t *R94 = L"R94:";

14
src/Utils/russian_errors_text.txt
View File

@@ -184,20 +184,8 @@ R182 = "Редукционная операция по элементу масс
R183 = "Расположение операторов FORMAT не поддерживается, попробуйте применить проход Коррекция стиля кода".
//1061
R184 = "Область объявления массива '%s' конфликтует с предыдущей областью. Возможно, это вызвано использованием include-файлов. Попробуйте применить проход 'Подстановка заголовочных файлов'".
//1062
//1042
R205 = "Массив '%s' состоящий в common блоке '%s' должен иметь описание в главной программной единице для объявления в директиве DECLARE"
//1063
R206 = "Ошибка инициализации библиотеки libpredict с конфигурацией кластера: %s, код возврата: %d"
//1064
R207 = "Ошибка инициализации сетки libpredict с топологией: %zu %zu %zu %zu, код возврата: %d"
//1065
R208 = "Ошибка распределения массива '%s' с помощью libpredict, код возврата: %d"
//1066
R209 = "Ошибка выравнивания массива '%s' с массивом '%s' с помощью libpredict, код возврата: %d"
//1067
R210 = "Ошибка обработки shadow_renew для массива '%s' с помощью libpredict, код возврата: %d"
//1068
R211 = "Ошибка инициализации отображения libpredict с processes_per_processor: %zu, код возврата: %d"
//2001
R94 = "Невозможно автоматически преобразовать данное присваивание к циклу"

6
src/VisualizerCalls/get_information.cpp
View File

@@ -950,7 +950,7 @@ int SPF_ModifyArrayDistribution(void*& context, int winHandler, short *options,
extern map<string, PredictorStats> allPredictorStats;
extern map<string, vector<SpfInterval*>> intervals;
extern vector<vector<size_t>> topologies;
extern vector<vector<long>> topologies;
int SPF_CreateParallelVariant(void*& context, int winHandler, short *options, short *projName, short *folderName, int64_t *variants, int *varLen,
string &output, string &outputMessage, string &predictorStats)
@@ -1823,7 +1823,7 @@ static int inline runModificationPass(passes passName, short* projName, short* f
runPassesForVisualizer(projName, { passName }, folderName);
//fill data
// newFiles: <<EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD> <20><><EFBFBD><EFBFBD><EFBFBD><EFBFBD> <20><><EFBFBD> <20><><EFBFBD>, <20><><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD><EFBFBD> <20><><EFBFBD><EFBFBD><EFBFBD>>
// newFiles: <èìåíà ôàéëîâ äëÿ ìîä, ñîäåðæèìîå ôàéëà>
string newFile;
if (SgFile::switchToFile(outFileName.c_str()) == -1)
@@ -2392,7 +2392,7 @@ const wstring Sapfor_RunAnalysis(const char* analysisName_c, const char* options
retCode = SPF_GetArrayLinks(context, winHandler, optSh, projSh, result, output, outputMessage);
else if (whichRun == "SPF_GetMaxMinBlockDistribution")
retCode = SPF_GetMaxMinBlockDistribution(context, winHandler, optSh, projSh, result, output, outputMessage);
else if (whichRun == "SPF_<EFBFBD>hangeDirectory") // russian C
else if (whichRun == "SPF_ÑhangeDirectory") // russian C
{
if (options_c == NULL)
printInternalError(convertFileName(__FILE__).c_str(), __LINE__);