llvm-project/polly/lib/Transform/FlattenAlgo.cpp
Tobias Grosser 75aa1a9a49 Use isl C++ foreach implementation
This commit switches Polly over to the isl::obj::foreach_* implementation, which
is part of the new isl bindings and follows the foreach pattern established in
Polly by Michael Kruse.

The original isl C function:

  isl_stat isl_union_set_foreach_set(__isl_keep isl_union_set *uset,
      isl_stat (*fn)(__isl_take isl_set *set, void *user), void *user);

which required the user to define a static callback function to which all
interesting parameters are passed via a 'void *' user-pointer, is on the
C++ side available as a function that takes a std::function<>, which can
carry any additional arguments without the need for a user pointer:

  stat UnionSet::foreach_set(const std::function<stat(set)> &fn) const;

The following code illustrates the use of the new C++ interface:

  auto Lambda = [=, &Result](isl::set Set) -> isl::stat {
    auto Shifted = shiftDimension(Set, Pos, Amount);
    Result = Result.add(Shifted);
    return isl::stat::ok;
  }

  UnionSet.foreach_set(Lambda);

Polly had some specialized foreach functions which did not require the lambdas
to return a status flag. We remove these functions in this commit to move Polly
completely over to the new isl interface. We may in the future discuss if
functors without return values can be supported easily.

Another extension proposed by Michael Kruse is the use of C++ iterators to allow
the use of normal for loops to iterate over these sets. Such an extension would
allow us to further simplify the code.

Reviewed-by: Michael Kruse <llvm@meinersbur.de>

Differential Revision: https://reviews.llvm.org/D30620

llvm-svn: 300323
2017-04-14 13:39:40 +00:00

384 lines
14 KiB
C++

//===------ FlattenAlgo.cpp ------------------------------------*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// Main algorithm of the FlattenSchedulePass. This is a separate file to avoid
// the unittest for this requiring linking against LLVM.
//
//===----------------------------------------------------------------------===//
#include "polly/FlattenAlgo.h"
#include "llvm/Support/Debug.h"
#define DEBUG_TYPE "polly-flatten-algo"
using namespace polly;
using namespace llvm;
namespace {
/// Whether a dimension of a set is bounded (lower and upper) by a constant,
/// i.e. there are two constants Min and Max, such that every value x of the
/// chosen dimensions is Min <= x <= Max.
bool isDimBoundedByConstant(isl::set Set, unsigned dim) {
auto ParamDims = Set.dim(isl::dim::param);
Set = Set.project_out(isl::dim::param, 0, ParamDims);
Set = Set.project_out(isl::dim::set, 0, dim);
auto SetDims = Set.dim(isl::dim::set);
Set = Set.project_out(isl::dim::set, 1, SetDims - 1);
return bool(Set.is_bounded());
}
/// Whether a dimension of a set is (lower and upper) bounded by a constant or
/// parameters, i.e. there are two expressions Min_p and Max_p of the parameters
/// p, such that every value x of the chosen dimensions is
/// Min_p <= x <= Max_p.
bool isDimBoundedByParameter(isl::set Set, unsigned dim) {
Set = Set.project_out(isl::dim::set, 0, dim);
auto SetDims = Set.dim(isl::dim::set);
Set = Set.project_out(isl::dim::set, 1, SetDims - 1);
return bool(Set.is_bounded());
}
/// Whether BMap's first out-dimension is not a constant.
bool isVariableDim(const isl::basic_map &BMap) {
auto FixedVal = BMap.plain_get_val_if_fixed(isl::dim::out, 0);
return !FixedVal || FixedVal.is_nan();
}
/// Whether Map's first out dimension is no constant nor piecewise constant.
bool isVariableDim(const isl::map &Map) {
return Map.foreach_basic_map([](isl::basic_map BMap) -> isl::stat {
if (isVariableDim(BMap))
return isl::stat::error;
return isl::stat::ok;
}) == isl::stat::ok;
}
/// Whether UMap's first out dimension is no (piecewise) constant.
bool isVariableDim(const isl::union_map &UMap) {
return UMap.foreach_map([](isl::map Map) -> isl::stat {
if (isVariableDim(Map))
return isl::stat::error;
return isl::stat::ok;
}) == isl::stat::ok;
}
/// If @p PwAff maps to a constant, return said constant. If @p Max/@p Min, it
/// can also be a piecewise constant and it would return the minimum/maximum
/// value. Otherwise, return NaN.
isl::val getConstant(isl::pw_aff PwAff, bool Max, bool Min) {
assert(!Max || !Min);
isl::val Result;
PwAff.foreach_piece([=, &Result](isl::set Set, isl::aff Aff) -> isl::stat {
if (Result && Result.is_nan())
return isl::stat::ok;
// TODO: If Min/Max, we can also determine a minimum/maximum value if
// Set is constant-bounded.
if (!Aff.is_cst()) {
Result = isl::val::nan(Aff.get_ctx());
return isl::stat::error;
}
auto ThisVal = Aff.get_constant();
if (!Result) {
Result = ThisVal;
return isl::stat::ok;
}
if (Result.eq(ThisVal))
return isl::stat::ok;
if (Max && ThisVal.gt(Result)) {
Result = ThisVal;
return isl::stat::ok;
}
if (Min && ThisVal.lt(Result)) {
Result = ThisVal;
return isl::stat::ok;
}
// Not compatible
Result = isl::val::nan(Aff.get_ctx());
return isl::stat::error;
});
return Result;
}
/// Compute @p UPwAff - @p Val.
isl::union_pw_aff subtract(isl::union_pw_aff UPwAff, isl::val Val) {
if (Val.is_zero())
return UPwAff;
auto Result = isl::union_pw_aff::empty(UPwAff.get_space());
UPwAff.foreach_pw_aff([=, &Result](isl::pw_aff PwAff) -> isl::stat {
auto ValAff =
isl::pw_aff(isl::set::universe(PwAff.get_space().domain()), Val);
auto Subtracted = PwAff.sub(ValAff);
Result = Result.union_add(isl::union_pw_aff(Subtracted));
return isl::stat::ok;
});
return Result;
}
/// Compute @UPwAff * @p Val.
isl::union_pw_aff multiply(isl::union_pw_aff UPwAff, isl::val Val) {
if (Val.is_one())
return UPwAff;
auto Result = isl::union_pw_aff::empty(UPwAff.get_space());
UPwAff.foreach_pw_aff([=, &Result](isl::pw_aff PwAff) -> isl::stat {
auto ValAff =
isl::pw_aff(isl::set::universe(PwAff.get_space().domain()), Val);
auto Multiplied = PwAff.mul(ValAff);
Result = Result.union_add(Multiplied);
return isl::stat::ok;
});
return Result;
}
/// Remove @p n dimensions from @p UMap's range, starting at @p first.
///
/// It is assumed that all maps in the maps have at least the necessary number
/// of out dimensions.
isl::union_map scheduleProjectOut(const isl::union_map &UMap, unsigned first,
unsigned n) {
if (n == 0)
return UMap; /* isl_map_project_out would also reset the tuple, which should
have no effect on schedule ranges */
auto Result = isl::union_map::empty(UMap.get_space());
UMap.foreach_map([=, &Result](isl::map Map) -> isl::stat {
auto Outprojected = Map.project_out(isl::dim::out, first, n);
Result = Result.add_map(Outprojected);
return isl::stat::ok;
});
return Result;
}
/// Return the number of dimensions in the input map's range.
///
/// Because this function takes an isl_union_map, the out dimensions could be
/// different. We return the maximum number in this case. However, a different
/// number of dimensions is not supported by the other code in this file.
size_t scheduleScatterDims(const isl::union_map &Schedule) {
unsigned Dims = 0;
Schedule.foreach_map([&Dims](isl::map Map) -> isl::stat {
Dims = std::max(Dims, Map.dim(isl::dim::out));
return isl::stat::ok;
});
return Dims;
}
/// Return the @p pos' range dimension, converted to an isl_union_pw_aff.
isl::union_pw_aff scheduleExtractDimAff(isl::union_map UMap, unsigned pos) {
auto SingleUMap = isl::union_map::empty(UMap.get_space());
UMap.foreach_map([=, &SingleUMap](isl::map Map) -> isl::stat {
auto MapDims = Map.dim(isl::dim::out);
auto SingleMap = Map.project_out(isl::dim::out, 0, pos);
SingleMap = SingleMap.project_out(isl::dim::out, 1, MapDims - pos - 1);
SingleUMap = SingleUMap.add_map(SingleMap);
return isl::stat::ok;
});
auto UAff = isl::union_pw_multi_aff(SingleUMap);
auto FirstMAff = isl::multi_union_pw_aff(UAff);
return FirstMAff.get_union_pw_aff(0);
}
/// Flatten a sequence-like first dimension.
///
/// A sequence-like scatter dimension is constant, or at least only small
/// variation, typically the result of ordering a sequence of different
/// statements. An example would be:
/// { Stmt_A[] -> [0, X, ...]; Stmt_B[] -> [1, Y, ...] }
/// to schedule all instances of Stmt_A before any instance of Stmt_B.
///
/// To flatten, first begin with an offset of zero. Then determine the lowest
/// possible value of the dimension, call it "i" [In the example we start at 0].
/// Considering only schedules with that value, consider only instances with
/// that value and determine the extent of the next dimension. Let l_X(i) and
/// u_X(i) its minimum (lower bound) and maximum (upper bound) value. Add them
/// as "Offset + X - l_X(i)" to the new schedule, then add "u_X(i) - l_X(i) + 1"
/// to Offset and remove all i-instances from the old schedule. Repeat with the
/// remaining lowest value i' until there are no instances in the old schedule
/// left.
/// The example schedule would be transformed to:
/// { Stmt_X[] -> [X - l_X, ...]; Stmt_B -> [l_X - u_X + 1 + Y - l_Y, ...] }
isl::union_map tryFlattenSequence(isl::union_map Schedule) {
auto IslCtx = Schedule.get_ctx();
auto ScatterSet = isl::set(Schedule.range());
auto ParamSpace = Schedule.get_space().params();
auto Dims = ScatterSet.dim(isl::dim::set);
assert(Dims >= 2);
// Would cause an infinite loop.
if (!isDimBoundedByConstant(ScatterSet, 0)) {
DEBUG(dbgs() << "Abort; dimension is not of fixed size\n");
return nullptr;
}
auto AllDomains = Schedule.domain();
auto AllDomainsToNull = isl::union_pw_multi_aff(AllDomains);
auto NewSchedule = isl::union_map::empty(ParamSpace);
auto Counter = isl::pw_aff(isl::local_space(ParamSpace.set_from_params()));
while (!ScatterSet.is_empty()) {
DEBUG(dbgs() << "Next counter:\n " << Counter << "\n");
DEBUG(dbgs() << "Remaining scatter set:\n " << ScatterSet << "\n");
auto ThisSet = ScatterSet.project_out(isl::dim::set, 1, Dims - 1);
auto ThisFirst = ThisSet.lexmin();
auto ScatterFirst = ThisFirst.add_dims(isl::dim::set, Dims - 1);
auto SubSchedule = Schedule.intersect_range(ScatterFirst);
SubSchedule = scheduleProjectOut(SubSchedule, 0, 1);
SubSchedule = flattenSchedule(SubSchedule);
auto SubDims = scheduleScatterDims(SubSchedule);
auto FirstSubSchedule = scheduleProjectOut(SubSchedule, 1, SubDims - 1);
auto FirstScheduleAff = scheduleExtractDimAff(FirstSubSchedule, 0);
auto RemainingSubSchedule = scheduleProjectOut(SubSchedule, 0, 1);
auto FirstSubScatter = isl::set(FirstSubSchedule.range());
DEBUG(dbgs() << "Next step in sequence is:\n " << FirstSubScatter << "\n");
if (!isDimBoundedByParameter(FirstSubScatter, 0)) {
DEBUG(dbgs() << "Abort; sequence step is not bounded\n");
return nullptr;
}
auto FirstSubScatterMap = isl::map::from_range(FirstSubScatter);
// isl_set_dim_max returns a strange isl_pw_aff with domain tuple_id of
// 'none'. It doesn't match with any space including a 0-dimensional
// anonymous tuple.
// Interesting, one can create such a set using
// isl_set_universe(ParamSpace). Bug?
auto PartMin = FirstSubScatterMap.dim_min(0);
auto PartMax = FirstSubScatterMap.dim_max(0);
auto One = isl::pw_aff(isl::set::universe(ParamSpace.set_from_params()),
isl::val::one(IslCtx));
auto PartLen = PartMax.add(PartMin.neg()).add(One);
auto AllPartMin = isl::union_pw_aff(PartMin).pullback(AllDomainsToNull);
auto FirstScheduleAffNormalized = FirstScheduleAff.sub(AllPartMin);
auto AllCounter = isl::union_pw_aff(Counter).pullback(AllDomainsToNull);
auto FirstScheduleAffWithOffset =
FirstScheduleAffNormalized.add(AllCounter);
auto ScheduleWithOffset = isl::union_map(FirstScheduleAffWithOffset)
.flat_range_product(RemainingSubSchedule);
NewSchedule = NewSchedule.unite(ScheduleWithOffset);
ScatterSet = ScatterSet.subtract(ScatterFirst);
Counter = Counter.add(PartLen);
}
DEBUG(dbgs() << "Sequence-flatten result is:\n " << NewSchedule << "\n");
return NewSchedule;
}
/// Flatten a loop-like first dimension.
///
/// A loop-like dimension is one that depends on a variable (usually a loop's
/// induction variable). Let the input schedule look like this:
/// { Stmt[i] -> [i, X, ...] }
///
/// To flatten, we determine the largest extent of X which may not depend on the
/// actual value of i. Let l_X() the smallest possible value of X and u_X() its
/// largest value. Then, construct a new schedule
/// { Stmt[i] -> [i * (u_X() - l_X() + 1), ...] }
isl::union_map tryFlattenLoop(isl::union_map Schedule) {
assert(scheduleScatterDims(Schedule) >= 2);
auto Remaining = scheduleProjectOut(Schedule, 0, 1);
auto SubSchedule = flattenSchedule(Remaining);
auto SubDims = scheduleScatterDims(SubSchedule);
auto SubExtent = isl::set(SubSchedule.range());
auto SubExtentDims = SubExtent.dim(isl::dim::param);
SubExtent = SubExtent.project_out(isl::dim::param, 0, SubExtentDims);
SubExtent = SubExtent.project_out(isl::dim::set, 1, SubDims - 1);
if (!isDimBoundedByConstant(SubExtent, 0)) {
DEBUG(dbgs() << "Abort; dimension not bounded by constant\n");
return nullptr;
}
auto Min = SubExtent.dim_min(0);
DEBUG(dbgs() << "Min bound:\n " << Min << "\n");
auto MinVal = getConstant(Min, false, true);
auto Max = SubExtent.dim_max(0);
DEBUG(dbgs() << "Max bound:\n " << Max << "\n");
auto MaxVal = getConstant(Max, true, false);
if (!MinVal || !MaxVal || MinVal.is_nan() || MaxVal.is_nan()) {
DEBUG(dbgs() << "Abort; dimension bounds could not be determined\n");
return nullptr;
}
auto FirstSubScheduleAff = scheduleExtractDimAff(SubSchedule, 0);
auto RemainingSubSchedule = scheduleProjectOut(std::move(SubSchedule), 0, 1);
auto LenVal = MaxVal.sub(MinVal).add_ui(1);
auto FirstSubScheduleNormalized = subtract(FirstSubScheduleAff, MinVal);
// TODO: Normalize FirstAff to zero (convert to isl_map, determine minimum,
// subtract it)
auto FirstAff = scheduleExtractDimAff(Schedule, 0);
auto Offset = multiply(FirstAff, LenVal);
auto Index = FirstSubScheduleNormalized.add(Offset);
auto IndexMap = isl::union_map(Index);
auto Result = IndexMap.flat_range_product(RemainingSubSchedule);
DEBUG(dbgs() << "Loop-flatten result is:\n " << Result << "\n");
return Result;
}
} // anonymous namespace
isl::union_map polly::flattenSchedule(isl::union_map Schedule) {
auto Dims = scheduleScatterDims(Schedule);
DEBUG(dbgs() << "Recursive schedule to process:\n " << Schedule << "\n");
// Base case; no dimensions left
if (Dims == 0) {
// TODO: Add one dimension?
return Schedule;
}
// Base case; already one-dimensional
if (Dims == 1)
return Schedule;
// Fixed dimension; no need to preserve variabledness.
if (!isVariableDim(Schedule)) {
DEBUG(dbgs() << "Fixed dimension; try sequence flattening\n");
auto NewScheduleSequence = tryFlattenSequence(Schedule);
if (NewScheduleSequence)
return NewScheduleSequence;
}
// Constant stride
DEBUG(dbgs() << "Try loop flattening\n");
auto NewScheduleLoop = tryFlattenLoop(Schedule);
if (NewScheduleLoop)
return NewScheduleLoop;
// Try again without loop condition (may blow up the number of pieces!!)
DEBUG(dbgs() << "Try sequence flattening again\n");
auto NewScheduleSequence = tryFlattenSequence(Schedule);
if (NewScheduleSequence)
return NewScheduleSequence;
// Cannot flatten
return Schedule;
}