polly/lib/ScheduleOptimizer.cpp - llvm-project - Git at Google

 //===- Schedule.cpp - Calculate an optimized schedule ---------------------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This pass the isl to calculate a schedule that is optimized for parallelism
 // and tileablility. The algorithm used in isl is an optimized version of the
 // algorithm described in following paper:
 //
 // U. Bondhugula, A. Hartono, J. Ramanujam, and P. Sadayappan.
 // A Practical Automatic Polyhedral Parallelizer and Locality Optimizer.
 // In Proceedings of the 2008 ACM SIGPLAN Conference On Programming Language
 // Design and Implementation, PLDI ’08, pages 101–113. ACM, 2008.
 //===----------------------------------------------------------------------===//

 #include "polly/ScheduleOptimizer.h"

 #include "polly/CodeGeneration.h"
 #include "polly/Dependences.h"
 #include "polly/LinkAllPasses.h"
 #include "polly/ScopInfo.h"

 #include "isl/aff.h"
 #include "isl/band.h"
 #include "isl/constraint.h"
 #include "isl/map.h"
 #include "isl/options.h"
 #include "isl/schedule.h"
 #include "isl/space.h"

 #define DEBUG_TYPE "polly-opt-isl"
 #include "llvm/Support/Debug.h"
 #include "llvm/Support/CommandLine.h"

 using namespace llvm;
 using namespace polly;

 namespace polly {
   bool DisablePollyTiling;
 }
 static cl::opt<bool, true>
 DisableTiling("polly-no-tiling",
 	      cl::desc("Disable tiling in the scheduler"), cl::Hidden,
               cl::location(polly::DisablePollyTiling), cl::init(false));

 static cl::opt<std::string>
 OptimizeDeps("polly-opt-optimize-only",
              cl::desc("Only a certain kind of dependences (all/raw)"),
              cl::Hidden, cl::init("all"));

 static cl::opt<std::string>
 SimplifyDeps("polly-opt-simplify-deps",
              cl::desc("Dependences should be simplified (yes/no)"),
              cl::Hidden, cl::init("yes"));

 static cl::opt<int>
 MaxConstantTerm("polly-opt-max-constant-term",
                 cl::desc("The maximal constant term allowed (-1 is unlimited)"),
                 cl::Hidden, cl::init(20));

 static cl::opt<int>
 MaxCoefficient("polly-opt-max-coefficient",
                cl::desc("The maximal coefficient allowed (-1 is unlimited)"),
                cl::Hidden, cl::init(20));

 static cl::opt<std::string>
 FusionStrategy("polly-opt-fusion",
                cl::desc("The fusion strategy to choose (min/max)"),
                cl::Hidden, cl::init("min"));

 static cl::opt<std::string>
 MaximizeBandDepth("polly-opt-maximize-bands",
                 cl::desc("Maximize the band depth (yes/no)"),
                 cl::Hidden, cl::init("yes"));

 namespace {

   class IslScheduleOptimizer : public ScopPass {

   public:
     static char ID;
     explicit IslScheduleOptimizer() : ScopPass(ID) {}

     virtual bool runOnScop(Scop &S);
     void printScop(llvm::raw_ostream &OS) const;
     void getAnalysisUsage(AnalysisUsage &AU) const;
   };

 }

 char IslScheduleOptimizer::ID = 0;

 static int getSingleMap(__isl_take isl_map *map, void *user) {
   isl_map **singleMap = (isl_map **) user;
   *singleMap = map;

   return 0;
 }

 static void extendScattering(Scop &S, unsigned NewDimensions) {
   for (Scop::iterator SI = S.begin(), SE = S.end(); SI != SE; ++SI) {
     ScopStmt *Stmt = *SI;
     unsigned OldDimensions = Stmt->getNumScattering();
     isl_space *Space;
     isl_basic_map *ChangeScattering;

     Space = isl_space_alloc(Stmt->getIslCtx(), 0, OldDimensions, NewDimensions);
     ChangeScattering = isl_basic_map_universe(isl_space_copy(Space));
     isl_local_space *LocalSpace = isl_local_space_from_space(Space);

     for (unsigned i = 0; i < OldDimensions; i++) {
       isl_constraint *c = isl_equality_alloc(isl_local_space_copy(LocalSpace));
       isl_constraint_set_coefficient_si(c, isl_dim_in, i, 1);
       isl_constraint_set_coefficient_si(c, isl_dim_out, i, -1);
       ChangeScattering = isl_basic_map_add_constraint(ChangeScattering, c);
     }

     for (unsigned i = OldDimensions; i < NewDimensions; i++) {
       isl_constraint *c = isl_equality_alloc(isl_local_space_copy(LocalSpace));
       isl_constraint_set_coefficient_si(c, isl_dim_out, i, 1);
       ChangeScattering = isl_basic_map_add_constraint(ChangeScattering, c);
     }

     isl_map *ChangeScatteringMap = isl_map_from_basic_map(ChangeScattering);

     ChangeScatteringMap = isl_map_align_params(ChangeScatteringMap,
                                                S.getParamSpace());
     isl_map *NewScattering = isl_map_apply_range(Stmt->getScattering(),
                                                  ChangeScatteringMap);
     Stmt->setScattering(NewScattering);
     isl_local_space_free(LocalSpace);
   }
 }

 // getTileMap - Create a map that describes a n-dimensonal tiling.
 //
 // getTileMap creates a map from a n-dimensional scattering space into an
 // 2*n-dimensional scattering space. The map describes a rectangular tiling.
 //
 // Example:
 //   scheduleDimensions = 2, parameterDimensions = 1, tileSize = 32
 //
 //   tileMap := [p0] -> {[s0, s1] -> [t0, t1, s0, s1]:
 //                        t0 % 32 = 0 and t0 <= s0 < t0 + 32 and
 //                        t1 % 32 = 0 and t1 <= s1 < t1 + 32}
 //
 //  Before tiling:
 //
 //  for (i = 0; i < N; i++)
 //    for (j = 0; j < M; j++)
 //	S(i,j)
 //
 //  After tiling:
 //
 //  for (t_i = 0; t_i < N; i+=32)
 //    for (t_j = 0; t_j < M; j+=32)
 //	for (i = t_i; i < min(t_i + 32, N); i++)  | Unknown that N % 32 = 0
 //	  for (j = t_j; j < t_j + 32; j++)        |   Known that M % 32 = 0
 //	    S(i,j)
 //
 static isl_basic_map *getTileMap(isl_ctx *ctx, int scheduleDimensions,
 				 isl_space *SpaceModel, int tileSize = 32) {
   // We construct
   //
   // tileMap := [p0] -> {[s0, s1] -> [t0, t1, p0, p1, a0, a1]:
   //	                  s0 = a0 * 32 and s0 = p0 and t0 <= p0 < t0 + 32 and
   //	                  s1 = a1 * 32 and s1 = p1 and t1 <= p1 < t1 + 32}
   //
   // and project out the auxilary dimensions a0 and a1.
   isl_space *Space = isl_space_alloc(ctx, 0, scheduleDimensions,
                                      scheduleDimensions * 3);
   isl_basic_map *tileMap = isl_basic_map_universe(isl_space_copy(Space));

   isl_local_space *LocalSpace = isl_local_space_from_space(Space);

   for (int x = 0; x < scheduleDimensions; x++) {
     int sX = x;
     int tX = x;
     int pX = scheduleDimensions + x;
     int aX = 2 * scheduleDimensions + x;

     isl_constraint *c;

     // sX = aX * tileSize;
     c = isl_equality_alloc(isl_local_space_copy(LocalSpace));
     isl_constraint_set_coefficient_si(c, isl_dim_out, sX, 1);
     isl_constraint_set_coefficient_si(c, isl_dim_out, aX, -tileSize);
     tileMap = isl_basic_map_add_constraint(tileMap, c);

     // pX = sX;
     c = isl_equality_alloc(isl_local_space_copy(LocalSpace));
     isl_constraint_set_coefficient_si(c, isl_dim_out, pX, 1);
     isl_constraint_set_coefficient_si(c, isl_dim_in, sX, -1);
     tileMap = isl_basic_map_add_constraint(tileMap, c);

     // tX <= pX
     c = isl_inequality_alloc(isl_local_space_copy(LocalSpace));
     isl_constraint_set_coefficient_si(c, isl_dim_out, pX, 1);
     isl_constraint_set_coefficient_si(c, isl_dim_out, tX, -1);
     tileMap = isl_basic_map_add_constraint(tileMap, c);

     // pX <= tX + (tileSize - 1)
     c = isl_inequality_alloc(isl_local_space_copy(LocalSpace));
     isl_constraint_set_coefficient_si(c, isl_dim_out, tX, 1);
     isl_constraint_set_coefficient_si(c, isl_dim_out, pX, -1);
     isl_constraint_set_constant_si(c, tileSize - 1);
     tileMap = isl_basic_map_add_constraint(tileMap, c);
   }

   // Project out auxilary dimensions.
   //
   // The auxilary dimensions are transformed into existentially quantified ones.
   // This reduces the number of visible scattering dimensions and allows Cloog
   // to produces better code.
   tileMap = isl_basic_map_project_out(tileMap, isl_dim_out,
 				      2 * scheduleDimensions,
 				      scheduleDimensions);
   isl_local_space_free(LocalSpace);
   return tileMap;
 }

 // getScheduleForBand - Get the schedule for this band.
 //
 // Polly applies transformations like tiling on top of the isl calculated value.
 // This can influence the number of scheduling dimension. The number of
 // schedule dimensions is returned in the parameter 'Dimension'.
 isl_union_map *getScheduleForBand(isl_band *Band, int *Dimensions) {
   isl_union_map *PartialSchedule;
   isl_ctx *ctx;
   isl_space *Space;
   isl_basic_map *TileMap;
   isl_union_map *TileUMap;

   PartialSchedule = isl_band_get_partial_schedule(Band);
   *Dimensions = isl_band_n_member(Band);

   if (DisableTiling)
     return PartialSchedule;

   // It does not make any sense to tile a band with just one dimension.
   if (*Dimensions == 1)
     return PartialSchedule;

   ctx = isl_union_map_get_ctx(PartialSchedule);
   Space = isl_union_map_get_space(PartialSchedule);

   TileMap = getTileMap(ctx, *Dimensions, Space);
   TileUMap = isl_union_map_from_map(isl_map_from_basic_map(TileMap));
   TileUMap = isl_union_map_align_params(TileUMap, Space);
   *Dimensions = 2 * *Dimensions;

   return isl_union_map_apply_range(PartialSchedule, TileUMap);
 }

 // Create a map that pre-vectorizes one scheduling dimension.
 //
 // getPrevectorMap creates a map that maps each input dimension to the same
 // output dimension, except for the dimension DimToVectorize. DimToVectorize is
 // strip mined by 'VectorWidth' and the newly created point loop of
 // DimToVectorize is moved to the innermost level.
 //
 // Example (DimToVectorize=0, ScheduleDimensions=2, VectorWidth=4):
 //
 // | Before transformation
 // |
 // | A[i,j] -> [i,j]
 // |
 // | for (i = 0; i < 128; i++)
 // |    for (j = 0; j < 128; j++)
 // |      A(i,j);
 //
 //   Prevector map:
 //   [i,j] -> [it,j,ip] : it % 4 = 0 and it <= ip <= it + 3 and i = ip
 //
 // | After transformation:
 // |
 // | A[i,j] -> [it,j,ip] : it % 4 = 0 and it <= ip <= it + 3 and i = ip
 // |
 // | for (it = 0; it < 128; it+=4)
 // |    for (j = 0; j < 128; j++)
 // |      for (ip = max(0,it); ip < min(128, it + 3); ip++)
 // |        A(ip,j);
 //
 // The goal of this transformation is to create a trivially vectorizable loop.
 // This means a parallel loop at the innermost level that has a constant number
 // of iterations corresponding to the target vector width.
 //
 // This transformation creates a loop at the innermost level. The loop has a
 // constant number of iterations, if the number of loop iterations at
 // DimToVectorize can be divided by VectorWidth. The default VectorWidth is
 // currently constant and not yet target specific. This function does not reason
 // about parallelism.
 static isl_map *getPrevectorMap(isl_ctx *ctx, int DimToVectorize,
 				int ScheduleDimensions,
 				int VectorWidth = 4) {
   isl_space *Space;
   isl_local_space *LocalSpace, *LocalSpaceRange;
   isl_set *Modulo;
   isl_map *TilingMap;
   isl_constraint *c;
   isl_aff *Aff;
   int PointDimension; /* ip */
   int TileDimension;  /* it */
   isl_int VectorWidthMP;

   assert (0 <= DimToVectorize && DimToVectorize < ScheduleDimensions);

   Space = isl_space_alloc(ctx, 0, ScheduleDimensions, ScheduleDimensions + 1);
   TilingMap = isl_map_universe(isl_space_copy(Space));
   LocalSpace = isl_local_space_from_space(Space);
   PointDimension = ScheduleDimensions;
   TileDimension = DimToVectorize;

   // Create an identity map for everything except DimToVectorize and map
   // DimToVectorize to the point loop at the innermost dimension.
   for (int i = 0; i < ScheduleDimensions; i++) {
     c = isl_equality_alloc(isl_local_space_copy(LocalSpace));
     isl_constraint_set_coefficient_si(c, isl_dim_in, i, -1);

     if (i == DimToVectorize)
       isl_constraint_set_coefficient_si(c, isl_dim_out, PointDimension, 1);
     else
       isl_constraint_set_coefficient_si(c, isl_dim_out, i, 1);

     TilingMap = isl_map_add_constraint(TilingMap, c);
   }

   // it % 'VectorWidth' = 0
   LocalSpaceRange = isl_local_space_range(isl_local_space_copy(LocalSpace));
   Aff = isl_aff_zero_on_domain(LocalSpaceRange);
   Aff = isl_aff_set_constant_si(Aff, VectorWidth);
   Aff = isl_aff_set_coefficient_si(Aff, isl_dim_in, TileDimension, 1);
   isl_int_init(VectorWidthMP);
   isl_int_set_si(VectorWidthMP, VectorWidth);
   Aff = isl_aff_mod(Aff, VectorWidthMP);
   isl_int_clear(VectorWidthMP);
   Modulo = isl_pw_aff_zero_set(isl_pw_aff_from_aff(Aff));
   TilingMap = isl_map_intersect_range(TilingMap, Modulo);

   // it <= ip
   c = isl_inequality_alloc(isl_local_space_copy(LocalSpace));
   isl_constraint_set_coefficient_si(c, isl_dim_out, TileDimension, -1);
   isl_constraint_set_coefficient_si(c, isl_dim_out, PointDimension, 1);
   TilingMap = isl_map_add_constraint(TilingMap, c);

   // ip <= it + ('VectorWidth' - 1)
   c = isl_inequality_alloc(LocalSpace);
   isl_constraint_set_coefficient_si(c, isl_dim_out, TileDimension, 1);
   isl_constraint_set_coefficient_si(c, isl_dim_out, PointDimension, -1);
   isl_constraint_set_constant_si(c, VectorWidth - 1);
   TilingMap = isl_map_add_constraint(TilingMap, c);

   return TilingMap;
 }

 // getScheduleForBandList - Get the scheduling map for a list of bands.
 //
 // We walk recursively the forest of bands to combine the schedules of the
 // individual bands to the overall schedule. In case tiling is requested,
 // the individual bands are tiled.
 static isl_union_map *getScheduleForBandList(isl_band_list *BandList) {
   int NumBands;
   isl_union_map *Schedule;
   isl_ctx *ctx;

   ctx = isl_band_list_get_ctx(BandList);
   NumBands = isl_band_list_n_band(BandList);
   Schedule = isl_union_map_empty(isl_space_params_alloc(ctx, 0));

   for (int i = 0; i < NumBands; i++) {
     isl_band *Band;
     isl_union_map *PartialSchedule;
     int ScheduleDimensions;
     isl_space *Space;

     Band = isl_band_list_get_band(BandList, i);
     PartialSchedule = getScheduleForBand(Band, &ScheduleDimensions);
     Space = isl_union_map_get_space(PartialSchedule);

     if (isl_band_has_children(Band)) {
       isl_band_list *Children;
       isl_union_map *SuffixSchedule;

       Children = isl_band_get_children(Band);
       SuffixSchedule = getScheduleForBandList(Children);
       PartialSchedule = isl_union_map_flat_range_product(PartialSchedule,
 							 SuffixSchedule);
       isl_band_list_free(Children);
     } else if (EnablePollyVector) {
       for (int j = 0;  j < isl_band_n_member(Band); j++) {
 	if (isl_band_member_is_zero_distance(Band, j)) {
           isl_map *TileMap;
           isl_union_map *TileUMap;

 	  TileMap = getPrevectorMap(ctx, ScheduleDimensions - j - 1,
                                     ScheduleDimensions);
 	  TileUMap = isl_union_map_from_map(TileMap);
           TileUMap = isl_union_map_align_params(TileUMap,
                                                 isl_space_copy(Space));
 	  PartialSchedule = isl_union_map_apply_range(PartialSchedule,
 						      TileUMap);
 	  break;
 	}
       }
     }

     Schedule = isl_union_map_union(Schedule, PartialSchedule);

     isl_band_free(Band);
     isl_space_free(Space);
   }

   return Schedule;
 }

 static isl_union_map *getScheduleMap(isl_schedule *Schedule) {
   isl_band_list *BandList = isl_schedule_get_band_forest(Schedule);
   isl_union_map *ScheduleMap = getScheduleForBandList(BandList);
   isl_band_list_free(BandList);
   return ScheduleMap;
 }

 bool IslScheduleOptimizer::runOnScop(Scop &S) {
   Dependences *D = &getAnalysis<Dependences>();

   // Build input data.
   int ValidityKinds = Dependences::TYPE_RAW | Dependences::TYPE_WAR
                       | Dependences::TYPE_WAW;
   int ProximityKinds;

   if (OptimizeDeps == "all")
     ProximityKinds = Dependences::TYPE_RAW | Dependences::TYPE_WAR
                      | Dependences::TYPE_WAW;
   else if (OptimizeDeps == "raw")
     ProximityKinds = Dependences::TYPE_RAW;
   else {
     errs() << "Do not know how to optimize for '" << OptimizeDeps << "'"
         << " Falling back to optimizing all dependences.\n";
     ProximityKinds = Dependences::TYPE_RAW | Dependences::TYPE_WAR
                      | Dependences::TYPE_WAW;

   }


   isl_union_set *Domain = S.getDomains();

   if (!Domain)
     return false;

   isl_union_map *Validity = D->getDependences(ValidityKinds);
   isl_union_map *Proximity = D->getDependences(ProximityKinds);

   // Simplify the dependences by removing the constraints introduced by the
   // domains. This can speed up the scheduling time significantly, as large
   // constant coefficients will be removed from the dependences. The
   // introduction of some additional dependences reduces the possible
   // transformations, but in most cases, such transformation do not seem to be
   // interesting anyway. In some cases this option may stop the scheduler to
   // find any schedule.
   if (SimplifyDeps == "yes") {
     Validity = isl_union_map_gist_domain(Validity, isl_union_set_copy(Domain));
     Validity = isl_union_map_gist_range(Validity, isl_union_set_copy(Domain));
     Proximity = isl_union_map_gist_domain(Proximity,
                                           isl_union_set_copy(Domain));
     Proximity = isl_union_map_gist_range(Proximity, isl_union_set_copy(Domain));
   } else if (SimplifyDeps != "no") {
     errs() << "warning: Option -polly-opt-simplify-deps should either be 'yes' "
               "or 'no'. Falling back to default: 'yes'\n";
   }

   DEBUG(dbgs() << "\n\nCompute schedule from: ");
   DEBUG(dbgs() << "Domain := "; isl_union_set_dump(Domain); dbgs() << ";\n");
   DEBUG(dbgs() << "Proximity := "; isl_union_map_dump(Proximity);
         dbgs() << ";\n");
   DEBUG(dbgs() << "Validity := "; isl_union_map_dump(Validity);
         dbgs() << ";\n");

   int IslFusionStrategy;

   if (FusionStrategy == "max") {
     IslFusionStrategy = ISL_SCHEDULE_FUSE_MAX;
   } else if (FusionStrategy == "min") {
     IslFusionStrategy = ISL_SCHEDULE_FUSE_MIN;
   } else {
     errs() << "warning: Unknown fusion strategy. Falling back to maximal "
               "fusion.\n";
     IslFusionStrategy = ISL_SCHEDULE_FUSE_MAX;
   }

   int IslMaximizeBands;

   if (MaximizeBandDepth == "yes") {
     IslMaximizeBands = 1;
   } else if (MaximizeBandDepth == "no") {
     IslMaximizeBands = 0;
   } else {
     errs() << "warning: Option -polly-opt-maximize-bands should either be 'yes'"
               " or 'no'. Falling back to default: 'yes'\n";
     IslMaximizeBands = 1;
   }

   isl_options_set_schedule_fuse(S.getIslCtx(), IslFusionStrategy);
   isl_options_set_schedule_maximize_band_depth(S.getIslCtx(), IslMaximizeBands);
   isl_options_set_schedule_max_constant_term(S.getIslCtx(), MaxConstantTerm);
   isl_options_set_schedule_max_coefficient(S.getIslCtx(), MaxCoefficient);

   isl_options_set_on_error(S.getIslCtx(), ISL_ON_ERROR_CONTINUE);
   isl_schedule *Schedule;
   Schedule  = isl_union_set_compute_schedule(Domain, Validity, Proximity);
   isl_options_set_on_error(S.getIslCtx(), ISL_ON_ERROR_ABORT);

   // In cases the scheduler is not able to optimize the code, we just do not
   // touch the schedule.
   if (!Schedule)
     return false;

   DEBUG(dbgs() << "Schedule := "; isl_schedule_dump(Schedule);
         dbgs() << ";\n");

   isl_union_map *ScheduleMap = getScheduleMap(Schedule);

   for (Scop::iterator SI = S.begin(), SE = S.end(); SI != SE; ++SI) {
     ScopStmt *Stmt = *SI;
     isl_set *Domain = Stmt->getDomain();
     isl_union_map *StmtBand;
     StmtBand = isl_union_map_intersect_domain(isl_union_map_copy(ScheduleMap),
 					      isl_union_set_from_set(Domain));
     isl_map *StmtSchedule;
     isl_union_map_foreach_map(StmtBand, getSingleMap, &StmtSchedule);
     Stmt->setScattering(StmtSchedule);
     isl_union_map_free(StmtBand);
   }

   isl_union_map_free(ScheduleMap);
   isl_schedule_free(Schedule);

   unsigned MaxScatDims = 0;

   for (Scop::iterator SI = S.begin(), SE = S.end(); SI != SE; ++SI)
     MaxScatDims = std::max((*SI)->getNumScattering(), MaxScatDims);

   extendScattering(S, MaxScatDims);
   return false;
 }

 void IslScheduleOptimizer::printScop(raw_ostream &OS) const {
 }

 void IslScheduleOptimizer::getAnalysisUsage(AnalysisUsage &AU) const {
   ScopPass::getAnalysisUsage(AU);
   AU.addRequired<Dependences>();
 }

 INITIALIZE_PASS_BEGIN(IslScheduleOptimizer, "polly-opt-isl",
                       "Polly - Optimize schedule of SCoP", false, false)
 INITIALIZE_PASS_DEPENDENCY(Dependences)
 INITIALIZE_PASS_DEPENDENCY(ScopInfo)
 INITIALIZE_PASS_END(IslScheduleOptimizer, "polly-opt-isl",
                       "Polly - Optimize schedule of SCoP", false, false)

 Pass* polly::createIslScheduleOptimizerPass() {
   return new IslScheduleOptimizer();
 }
	//===- Schedule.cpp - Calculate an optimized schedule ---------------------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This pass the isl to calculate a schedule that is optimized for parallelism
	// and tileablility. The algorithm used in isl is an optimized version of the
	// algorithm described in following paper:
	//
	// U. Bondhugula, A. Hartono, J. Ramanujam, and P. Sadayappan.
	// A Practical Automatic Polyhedral Parallelizer and Locality Optimizer.
	// In Proceedings of the 2008 ACM SIGPLAN Conference On Programming Language
	// Design and Implementation, PLDI ’08, pages 101–113. ACM, 2008.
	//===----------------------------------------------------------------------===//

	#include "polly/ScheduleOptimizer.h"

	#include "polly/CodeGeneration.h"
	#include "polly/Dependences.h"
	#include "polly/LinkAllPasses.h"
	#include "polly/ScopInfo.h"

	#include "isl/aff.h"
	#include "isl/band.h"
	#include "isl/constraint.h"
	#include "isl/map.h"
	#include "isl/options.h"
	#include "isl/schedule.h"
	#include "isl/space.h"

	#define DEBUG_TYPE "polly-opt-isl"
	#include "llvm/Support/Debug.h"
	#include "llvm/Support/CommandLine.h"

	using namespace llvm;
	using namespace polly;

	namespace polly {
	bool DisablePollyTiling;
	}
	static cl::opt<bool, true>
	DisableTiling("polly-no-tiling",
	cl::desc("Disable tiling in the scheduler"), cl::Hidden,
	cl::location(polly::DisablePollyTiling), cl::init(false));

	static cl::opt<std::string>
	OptimizeDeps("polly-opt-optimize-only",
	cl::desc("Only a certain kind of dependences (all/raw)"),
	cl::Hidden, cl::init("all"));

	static cl::opt<std::string>
	SimplifyDeps("polly-opt-simplify-deps",
	cl::desc("Dependences should be simplified (yes/no)"),
	cl::Hidden, cl::init("yes"));

	static cl::opt<int>
	MaxConstantTerm("polly-opt-max-constant-term",
	cl::desc("The maximal constant term allowed (-1 is unlimited)"),
	cl::Hidden, cl::init(20));

	static cl::opt<int>
	MaxCoefficient("polly-opt-max-coefficient",
	cl::desc("The maximal coefficient allowed (-1 is unlimited)"),
	cl::Hidden, cl::init(20));

	static cl::opt<std::string>
	FusionStrategy("polly-opt-fusion",
	cl::desc("The fusion strategy to choose (min/max)"),
	cl::Hidden, cl::init("min"));

	static cl::opt<std::string>
	MaximizeBandDepth("polly-opt-maximize-bands",
	cl::desc("Maximize the band depth (yes/no)"),
	cl::Hidden, cl::init("yes"));

	namespace {

	class IslScheduleOptimizer : public ScopPass {

	public:
	static char ID;
	explicit IslScheduleOptimizer() : ScopPass(ID) {}

	virtual bool runOnScop(Scop &S);
	void printScop(llvm::raw_ostream &OS) const;
	void getAnalysisUsage(AnalysisUsage &AU) const;
	};

	}

	char IslScheduleOptimizer::ID = 0;

	static int getSingleMap(__isl_take isl_map map, void user) {
	isl_map singleMap = (isl_map ) user;
	*singleMap = map;

	return 0;
	}

	static void extendScattering(Scop &S, unsigned NewDimensions) {
	for (Scop::iterator SI = S.begin(), SE = S.end(); SI != SE; ++SI) {
	ScopStmt Stmt = SI;
	unsigned OldDimensions = Stmt->getNumScattering();
	isl_space *Space;
	isl_basic_map *ChangeScattering;

	Space = isl_space_alloc(Stmt->getIslCtx(), 0, OldDimensions, NewDimensions);
	ChangeScattering = isl_basic_map_universe(isl_space_copy(Space));
	isl_local_space *LocalSpace = isl_local_space_from_space(Space);

	for (unsigned i = 0; i < OldDimensions; i++) {
	isl_constraint *c = isl_equality_alloc(isl_local_space_copy(LocalSpace));
	isl_constraint_set_coefficient_si(c, isl_dim_in, i, 1);
	isl_constraint_set_coefficient_si(c, isl_dim_out, i, -1);
	ChangeScattering = isl_basic_map_add_constraint(ChangeScattering, c);
	}

	for (unsigned i = OldDimensions; i < NewDimensions; i++) {
	isl_constraint *c = isl_equality_alloc(isl_local_space_copy(LocalSpace));
	isl_constraint_set_coefficient_si(c, isl_dim_out, i, 1);
	ChangeScattering = isl_basic_map_add_constraint(ChangeScattering, c);
	}

	isl_map *ChangeScatteringMap = isl_map_from_basic_map(ChangeScattering);

	ChangeScatteringMap = isl_map_align_params(ChangeScatteringMap,
	S.getParamSpace());
	isl_map *NewScattering = isl_map_apply_range(Stmt->getScattering(),
	ChangeScatteringMap);
	Stmt->setScattering(NewScattering);
	isl_local_space_free(LocalSpace);
	}
	}

	// getTileMap - Create a map that describes a n-dimensonal tiling.
	//
	// getTileMap creates a map from a n-dimensional scattering space into an
	// 2*n-dimensional scattering space. The map describes a rectangular tiling.
	//
	// Example:
	// scheduleDimensions = 2, parameterDimensions = 1, tileSize = 32
	//
	// tileMap := [p0] -> {[s0, s1] -> [t0, t1, s0, s1]:
	// t0 % 32 = 0 and t0 <= s0 < t0 + 32 and
	// t1 % 32 = 0 and t1 <= s1 < t1 + 32}
	//
	// Before tiling:
	//
	// for (i = 0; i < N; i++)
	// for (j = 0; j < M; j++)
	// S(i,j)
	//
	// After tiling:
	//
	// for (t_i = 0; t_i < N; i+=32)
	// for (t_j = 0; t_j < M; j+=32)
	// for (i = t_i; i < min(t_i + 32, N); i++) \| Unknown that N % 32 = 0
	// for (j = t_j; j < t_j + 32; j++) \| Known that M % 32 = 0
	// S(i,j)
	//
	static isl_basic_map getTileMap(isl_ctx ctx, int scheduleDimensions,
	isl_space *SpaceModel, int tileSize = 32) {
	// We construct
	//
	// tileMap := [p0] -> {[s0, s1] -> [t0, t1, p0, p1, a0, a1]:
	// s0 = a0 * 32 and s0 = p0 and t0 <= p0 < t0 + 32 and
	// s1 = a1 * 32 and s1 = p1 and t1 <= p1 < t1 + 32}
	//
	// and project out the auxilary dimensions a0 and a1.
	isl_space *Space = isl_space_alloc(ctx, 0, scheduleDimensions,
	scheduleDimensions * 3);
	isl_basic_map *tileMap = isl_basic_map_universe(isl_space_copy(Space));

	isl_local_space *LocalSpace = isl_local_space_from_space(Space);

	for (int x = 0; x < scheduleDimensions; x++) {
	int sX = x;
	int tX = x;
	int pX = scheduleDimensions + x;
	int aX = 2 * scheduleDimensions + x;

	isl_constraint *c;

	// sX = aX * tileSize;
	c = isl_equality_alloc(isl_local_space_copy(LocalSpace));
	isl_constraint_set_coefficient_si(c, isl_dim_out, sX, 1);
	isl_constraint_set_coefficient_si(c, isl_dim_out, aX, -tileSize);
	tileMap = isl_basic_map_add_constraint(tileMap, c);

	// pX = sX;
	c = isl_equality_alloc(isl_local_space_copy(LocalSpace));
	isl_constraint_set_coefficient_si(c, isl_dim_out, pX, 1);
	isl_constraint_set_coefficient_si(c, isl_dim_in, sX, -1);
	tileMap = isl_basic_map_add_constraint(tileMap, c);

	// tX <= pX
	c = isl_inequality_alloc(isl_local_space_copy(LocalSpace));
	isl_constraint_set_coefficient_si(c, isl_dim_out, pX, 1);
	isl_constraint_set_coefficient_si(c, isl_dim_out, tX, -1);
	tileMap = isl_basic_map_add_constraint(tileMap, c);

	// pX <= tX + (tileSize - 1)
	c = isl_inequality_alloc(isl_local_space_copy(LocalSpace));
	isl_constraint_set_coefficient_si(c, isl_dim_out, tX, 1);
	isl_constraint_set_coefficient_si(c, isl_dim_out, pX, -1);
	isl_constraint_set_constant_si(c, tileSize - 1);
	tileMap = isl_basic_map_add_constraint(tileMap, c);
	}

	// Project out auxilary dimensions.
	//
	// The auxilary dimensions are transformed into existentially quantified ones.
	// This reduces the number of visible scattering dimensions and allows Cloog
	// to produces better code.
	tileMap = isl_basic_map_project_out(tileMap, isl_dim_out,
	2 * scheduleDimensions,
	scheduleDimensions);
	isl_local_space_free(LocalSpace);
	return tileMap;
	}

	// getScheduleForBand - Get the schedule for this band.
	//
	// Polly applies transformations like tiling on top of the isl calculated value.
	// This can influence the number of scheduling dimension. The number of
	// schedule dimensions is returned in the parameter 'Dimension'.
	isl_union_map getScheduleForBand(isl_band Band, int *Dimensions) {
	isl_union_map *PartialSchedule;
	isl_ctx *ctx;
	isl_space *Space;
	isl_basic_map *TileMap;
	isl_union_map *TileUMap;

	PartialSchedule = isl_band_get_partial_schedule(Band);
	*Dimensions = isl_band_n_member(Band);

	if (DisableTiling)
	return PartialSchedule;

	// It does not make any sense to tile a band with just one dimension.
	if (*Dimensions == 1)
	return PartialSchedule;

	ctx = isl_union_map_get_ctx(PartialSchedule);
	Space = isl_union_map_get_space(PartialSchedule);

	TileMap = getTileMap(ctx, *Dimensions, Space);
	TileUMap = isl_union_map_from_map(isl_map_from_basic_map(TileMap));
	TileUMap = isl_union_map_align_params(TileUMap, Space);
	Dimensions = 2 *Dimensions;

	return isl_union_map_apply_range(PartialSchedule, TileUMap);
	}

	// Create a map that pre-vectorizes one scheduling dimension.
	//
	// getPrevectorMap creates a map that maps each input dimension to the same
	// output dimension, except for the dimension DimToVectorize. DimToVectorize is
	// strip mined by 'VectorWidth' and the newly created point loop of
	// DimToVectorize is moved to the innermost level.
	//
	// Example (DimToVectorize=0, ScheduleDimensions=2, VectorWidth=4):
	//
	// \| Before transformation
	// \|
	// \| A[i,j] -> [i,j]
	// \|
	// \| for (i = 0; i < 128; i++)
	// \| for (j = 0; j < 128; j++)
	// \| A(i,j);
	//
	// Prevector map:
	// [i,j] -> [it,j,ip] : it % 4 = 0 and it <= ip <= it + 3 and i = ip
	//
	// \| After transformation:
	// \|
	// \| A[i,j] -> [it,j,ip] : it % 4 = 0 and it <= ip <= it + 3 and i = ip
	// \|
	// \| for (it = 0; it < 128; it+=4)
	// \| for (j = 0; j < 128; j++)
	// \| for (ip = max(0,it); ip < min(128, it + 3); ip++)
	// \| A(ip,j);
	//
	// The goal of this transformation is to create a trivially vectorizable loop.
	// This means a parallel loop at the innermost level that has a constant number
	// of iterations corresponding to the target vector width.
	//
	// This transformation creates a loop at the innermost level. The loop has a
	// constant number of iterations, if the number of loop iterations at
	// DimToVectorize can be divided by VectorWidth. The default VectorWidth is
	// currently constant and not yet target specific. This function does not reason
	// about parallelism.
	static isl_map getPrevectorMap(isl_ctx ctx, int DimToVectorize,
	int ScheduleDimensions,
	int VectorWidth = 4) {
	isl_space *Space;
	isl_local_space LocalSpace, LocalSpaceRange;
	isl_set *Modulo;
	isl_map *TilingMap;
	isl_constraint *c;
	isl_aff *Aff;
	int PointDimension; /* ip */
	int TileDimension; /* it */
	isl_int VectorWidthMP;

	assert (0 <= DimToVectorize && DimToVectorize < ScheduleDimensions);

	Space = isl_space_alloc(ctx, 0, ScheduleDimensions, ScheduleDimensions + 1);
	TilingMap = isl_map_universe(isl_space_copy(Space));
	LocalSpace = isl_local_space_from_space(Space);
	PointDimension = ScheduleDimensions;
	TileDimension = DimToVectorize;

	// Create an identity map for everything except DimToVectorize and map
	// DimToVectorize to the point loop at the innermost dimension.
	for (int i = 0; i < ScheduleDimensions; i++) {
	c = isl_equality_alloc(isl_local_space_copy(LocalSpace));
	isl_constraint_set_coefficient_si(c, isl_dim_in, i, -1);

	if (i == DimToVectorize)
	isl_constraint_set_coefficient_si(c, isl_dim_out, PointDimension, 1);
	else
	isl_constraint_set_coefficient_si(c, isl_dim_out, i, 1);

	TilingMap = isl_map_add_constraint(TilingMap, c);
	}

	// it % 'VectorWidth' = 0
	LocalSpaceRange = isl_local_space_range(isl_local_space_copy(LocalSpace));
	Aff = isl_aff_zero_on_domain(LocalSpaceRange);
	Aff = isl_aff_set_constant_si(Aff, VectorWidth);
	Aff = isl_aff_set_coefficient_si(Aff, isl_dim_in, TileDimension, 1);
	isl_int_init(VectorWidthMP);
	isl_int_set_si(VectorWidthMP, VectorWidth);
	Aff = isl_aff_mod(Aff, VectorWidthMP);
	isl_int_clear(VectorWidthMP);
	Modulo = isl_pw_aff_zero_set(isl_pw_aff_from_aff(Aff));
	TilingMap = isl_map_intersect_range(TilingMap, Modulo);

	// it <= ip
	c = isl_inequality_alloc(isl_local_space_copy(LocalSpace));
	isl_constraint_set_coefficient_si(c, isl_dim_out, TileDimension, -1);
	isl_constraint_set_coefficient_si(c, isl_dim_out, PointDimension, 1);
	TilingMap = isl_map_add_constraint(TilingMap, c);

	// ip <= it + ('VectorWidth' - 1)
	c = isl_inequality_alloc(LocalSpace);
	isl_constraint_set_coefficient_si(c, isl_dim_out, TileDimension, 1);
	isl_constraint_set_coefficient_si(c, isl_dim_out, PointDimension, -1);
	isl_constraint_set_constant_si(c, VectorWidth - 1);
	TilingMap = isl_map_add_constraint(TilingMap, c);

	return TilingMap;
	}

	// getScheduleForBandList - Get the scheduling map for a list of bands.
	//
	// We walk recursively the forest of bands to combine the schedules of the
	// individual bands to the overall schedule. In case tiling is requested,
	// the individual bands are tiled.
	static isl_union_map getScheduleForBandList(isl_band_list BandList) {
	int NumBands;
	isl_union_map *Schedule;
	isl_ctx *ctx;

	ctx = isl_band_list_get_ctx(BandList);
	NumBands = isl_band_list_n_band(BandList);
	Schedule = isl_union_map_empty(isl_space_params_alloc(ctx, 0));

	for (int i = 0; i < NumBands; i++) {
	isl_band *Band;
	isl_union_map *PartialSchedule;
	int ScheduleDimensions;
	isl_space *Space;

	Band = isl_band_list_get_band(BandList, i);
	PartialSchedule = getScheduleForBand(Band, &ScheduleDimensions);
	Space = isl_union_map_get_space(PartialSchedule);

	if (isl_band_has_children(Band)) {
	isl_band_list *Children;
	isl_union_map *SuffixSchedule;

	Children = isl_band_get_children(Band);
	SuffixSchedule = getScheduleForBandList(Children);
	PartialSchedule = isl_union_map_flat_range_product(PartialSchedule,
	SuffixSchedule);
	isl_band_list_free(Children);
	} else if (EnablePollyVector) {
	for (int j = 0; j < isl_band_n_member(Band); j++) {
	if (isl_band_member_is_zero_distance(Band, j)) {
	isl_map *TileMap;
	isl_union_map *TileUMap;

	TileMap = getPrevectorMap(ctx, ScheduleDimensions - j - 1,
	ScheduleDimensions);
	TileUMap = isl_union_map_from_map(TileMap);
	TileUMap = isl_union_map_align_params(TileUMap,
	isl_space_copy(Space));
	PartialSchedule = isl_union_map_apply_range(PartialSchedule,
	TileUMap);
	break;
	}
	}
	}

	Schedule = isl_union_map_union(Schedule, PartialSchedule);

	isl_band_free(Band);
	isl_space_free(Space);
	}

	return Schedule;
	}

	static isl_union_map getScheduleMap(isl_schedule Schedule) {
	isl_band_list *BandList = isl_schedule_get_band_forest(Schedule);
	isl_union_map *ScheduleMap = getScheduleForBandList(BandList);
	isl_band_list_free(BandList);
	return ScheduleMap;
	}

	bool IslScheduleOptimizer::runOnScop(Scop &S) {
	Dependences *D = &getAnalysis<Dependences>();

	// Build input data.
	int ValidityKinds = Dependences::TYPE_RAW \| Dependences::TYPE_WAR
	\| Dependences::TYPE_WAW;
	int ProximityKinds;

	if (OptimizeDeps == "all")
	ProximityKinds = Dependences::TYPE_RAW \| Dependences::TYPE_WAR
	\| Dependences::TYPE_WAW;
	else if (OptimizeDeps == "raw")
	ProximityKinds = Dependences::TYPE_RAW;
	else {
	errs() << "Do not know how to optimize for '" << OptimizeDeps << "'"
	<< " Falling back to optimizing all dependences.\n";
	ProximityKinds = Dependences::TYPE_RAW \| Dependences::TYPE_WAR
	\| Dependences::TYPE_WAW;

	}


	isl_union_set *Domain = S.getDomains();

	if (!Domain)
	return false;

	isl_union_map *Validity = D->getDependences(ValidityKinds);
	isl_union_map *Proximity = D->getDependences(ProximityKinds);

	// Simplify the dependences by removing the constraints introduced by the
	// domains. This can speed up the scheduling time significantly, as large
	// constant coefficients will be removed from the dependences. The
	// introduction of some additional dependences reduces the possible
	// transformations, but in most cases, such transformation do not seem to be
	// interesting anyway. In some cases this option may stop the scheduler to
	// find any schedule.
	if (SimplifyDeps == "yes") {
	Validity = isl_union_map_gist_domain(Validity, isl_union_set_copy(Domain));
	Validity = isl_union_map_gist_range(Validity, isl_union_set_copy(Domain));
	Proximity = isl_union_map_gist_domain(Proximity,
	isl_union_set_copy(Domain));
	Proximity = isl_union_map_gist_range(Proximity, isl_union_set_copy(Domain));
	} else if (SimplifyDeps != "no") {
	errs() << "warning: Option -polly-opt-simplify-deps should either be 'yes' "
	"or 'no'. Falling back to default: 'yes'\n";
	}

	DEBUG(dbgs() << "\n\nCompute schedule from: ");
	DEBUG(dbgs() << "Domain := "; isl_union_set_dump(Domain); dbgs() << ";\n");
	DEBUG(dbgs() << "Proximity := "; isl_union_map_dump(Proximity);
	dbgs() << ";\n");
	DEBUG(dbgs() << "Validity := "; isl_union_map_dump(Validity);
	dbgs() << ";\n");

	int IslFusionStrategy;

	if (FusionStrategy == "max") {
	IslFusionStrategy = ISL_SCHEDULE_FUSE_MAX;
	} else if (FusionStrategy == "min") {
	IslFusionStrategy = ISL_SCHEDULE_FUSE_MIN;
	} else {
	errs() << "warning: Unknown fusion strategy. Falling back to maximal "
	"fusion.\n";
	IslFusionStrategy = ISL_SCHEDULE_FUSE_MAX;
	}

	int IslMaximizeBands;

	if (MaximizeBandDepth == "yes") {
	IslMaximizeBands = 1;
	} else if (MaximizeBandDepth == "no") {
	IslMaximizeBands = 0;
	} else {
	errs() << "warning: Option -polly-opt-maximize-bands should either be 'yes'"
	" or 'no'. Falling back to default: 'yes'\n";
	IslMaximizeBands = 1;
	}

	isl_options_set_schedule_fuse(S.getIslCtx(), IslFusionStrategy);
	isl_options_set_schedule_maximize_band_depth(S.getIslCtx(), IslMaximizeBands);
	isl_options_set_schedule_max_constant_term(S.getIslCtx(), MaxConstantTerm);
	isl_options_set_schedule_max_coefficient(S.getIslCtx(), MaxCoefficient);

	isl_options_set_on_error(S.getIslCtx(), ISL_ON_ERROR_CONTINUE);
	isl_schedule *Schedule;
	Schedule = isl_union_set_compute_schedule(Domain, Validity, Proximity);
	isl_options_set_on_error(S.getIslCtx(), ISL_ON_ERROR_ABORT);

	// In cases the scheduler is not able to optimize the code, we just do not
	// touch the schedule.
	if (!Schedule)
	return false;

	DEBUG(dbgs() << "Schedule := "; isl_schedule_dump(Schedule);
	dbgs() << ";\n");

	isl_union_map *ScheduleMap = getScheduleMap(Schedule);

	for (Scop::iterator SI = S.begin(), SE = S.end(); SI != SE; ++SI) {
	ScopStmt Stmt = SI;
	isl_set *Domain = Stmt->getDomain();
	isl_union_map *StmtBand;
	StmtBand = isl_union_map_intersect_domain(isl_union_map_copy(ScheduleMap),
	isl_union_set_from_set(Domain));
	isl_map *StmtSchedule;
	isl_union_map_foreach_map(StmtBand, getSingleMap, &StmtSchedule);
	Stmt->setScattering(StmtSchedule);
	isl_union_map_free(StmtBand);
	}

	isl_union_map_free(ScheduleMap);
	isl_schedule_free(Schedule);

	unsigned MaxScatDims = 0;

	for (Scop::iterator SI = S.begin(), SE = S.end(); SI != SE; ++SI)
	MaxScatDims = std::max((*SI)->getNumScattering(), MaxScatDims);

	extendScattering(S, MaxScatDims);
	return false;
	}

	void IslScheduleOptimizer::printScop(raw_ostream &OS) const {
	}

	void IslScheduleOptimizer::getAnalysisUsage(AnalysisUsage &AU) const {
	ScopPass::getAnalysisUsage(AU);
	AU.addRequired<Dependences>();
	}

	INITIALIZE_PASS_BEGIN(IslScheduleOptimizer, "polly-opt-isl",
	"Polly - Optimize schedule of SCoP", false, false)
	INITIALIZE_PASS_DEPENDENCY(Dependences)
	INITIALIZE_PASS_DEPENDENCY(ScopInfo)
	INITIALIZE_PASS_END(IslScheduleOptimizer, "polly-opt-isl",
	"Polly - Optimize schedule of SCoP", false, false)

	Pass* polly::createIslScheduleOptimizerPass() {
	return new IslScheduleOptimizer();
	}