futhark-0.15.3: src/Futhark/CodeGen/ImpGen/Kernels/SegRed.hs
{-# LANGUAGE TypeFamilies #-}
{-# LANGUAGE FlexibleContexts #-}
-- | We generate code for non-segmented/single-segment SegRed using
-- the basic approach outlined in the paper "Design and GPGPU
-- Performance of Futhark’s Redomap Construct" (ARRAY '16). The main
-- deviations are:
--
-- * While we still use two-phase reduction, we use only a single
-- kernel, with the final workgroup to write a result (tracked via
-- an atomic counter) performing the final reduction as well.
--
-- * Instead of depending on storage layout transformations to handle
-- non-commutative reductions efficiently, we slide a
-- 'groupsize'-sized window over the input, and perform a parallel
-- reduction for each window. This sacrifices the notion of
-- efficient sequentialisation, but is sometimes faster and
-- definitely simpler and more predictable (and uses less auxiliary
-- storage).
--
-- For segmented reductions we use the approach from "Strategies for
-- Regular Segmented Reductions on GPU" (FHPC '17). This involves
-- having two different strategies, and dynamically deciding which one
-- to use based on the number of segments and segment size. We use the
-- (static) @group_size@ to decide which of the following two
-- strategies to choose:
--
-- * Large: uses one or more groups to process a single segment. If
-- multiple groups are used per segment, the intermediate reduction
-- results must be recursively reduced, until there is only a single
-- value per segment.
--
-- Each thread /can/ read multiple elements, which will greatly
-- increase performance; however, if the reduction is
-- non-commutative we will have to use a less efficient traversal
-- (with interim group-wide reductions) to enable coalesced memory
-- accesses, just as in the non-segmented case.
--
-- * Small: is used to let each group process *multiple* segments
-- within a group. We will only use this approach when we can
-- process at least two segments within a single group. In those
-- cases, we would allocate a /whole/ group per segment with the
-- large strategy, but at most 50% of the threads in the group would
-- have any element to read, which becomes highly inefficient.
module Futhark.CodeGen.ImpGen.Kernels.SegRed
( compileSegRed
, compileSegRed'
, DoSegBody
)
where
import Control.Monad.Except
import Data.Maybe
import Data.List (genericLength, zip4, zip7)
import Prelude hiding (quot, rem)
import Futhark.Error
import Futhark.Transform.Rename
import Futhark.Representation.ExplicitMemory
import qualified Futhark.CodeGen.ImpCode.Kernels as Imp
import Futhark.CodeGen.ImpGen
import Futhark.CodeGen.ImpGen.Kernels.Base
import qualified Futhark.Representation.ExplicitMemory.IndexFunction as IxFun
import Futhark.Util (chunks)
import Futhark.Util.IntegralExp (quotRoundingUp, quot, rem)
-- | The maximum number of operators we support in a single SegRed.
-- This limit arises out of the static allocation of counters.
maxNumOps :: Int32
maxNumOps = 10
type DoSegBody = (KernelConstants -> ([(SubExp, [Imp.Exp])] -> InKernelGen ()) -> InKernelGen ())
-- | Compile 'SegRed' instance to host-level code with calls to
-- various kernels.
compileSegRed :: Pattern ExplicitMemory
-> SegLevel -> SegSpace
-> [SegRedOp ExplicitMemory]
-> KernelBody ExplicitMemory
-> CallKernelGen ()
compileSegRed pat lvl space reds body =
compileSegRed' pat lvl space reds $ \constants red_cont ->
compileStms mempty (kernelBodyStms body) $ do
let (red_res, map_res) = splitAt (segRedResults reds) $ kernelBodyResult body
sComment "save map-out results" $ do
let map_arrs = drop (segRedResults reds) $ patternElements pat
zipWithM_ (compileThreadResult space constants) map_arrs map_res
red_cont $ zip (map kernelResultSubExp red_res) $ repeat []
-- | Like 'compileSegRed', but where the body is a monadic action.
compileSegRed' :: Pattern ExplicitMemory
-> SegLevel -> SegSpace
-> [SegRedOp ExplicitMemory]
-> DoSegBody
-> CallKernelGen ()
compileSegRed' pat lvl space reds body
| genericLength reds > maxNumOps =
compilerLimitationS $
"compileSegRed': at most " ++ show maxNumOps ++ " reduction operators are supported."
| [(_, Constant (IntValue (Int32Value 1))), _] <- unSegSpace space =
nonsegmentedReduction pat num_groups group_size space reds body
| otherwise = do
group_size' <- toExp $ unCount group_size
segment_size <- toExp $ last $ segSpaceDims space
let use_small_segments = segment_size * 2 .<. group_size'
sIf use_small_segments
(smallSegmentsReduction pat num_groups group_size space reds body)
(largeSegmentsReduction pat num_groups group_size space reds body)
where num_groups = segNumGroups lvl
group_size = segGroupSize lvl
-- | Prepare intermediate arrays for the reduction. Prim-typed
-- arguments go in local memory (so we need to do the allocation of
-- those arrays inside the kernel), while array-typed arguments go in
-- global memory. Allocations for the former have already been
-- performed. This policy is baked into how the allocations are done
-- in ExplicitAllocations.
intermediateArrays :: Count GroupSize SubExp -> SubExp
-> SegRedOp ExplicitMemory
-> InKernelGen [VName]
intermediateArrays (Count group_size) num_threads (SegRedOp _ red_op nes _) = do
let red_op_params = lambdaParams red_op
(red_acc_params, _) = splitAt (length nes) red_op_params
forM red_acc_params $ \p ->
case paramAttr p of
MemArray pt shape _ (ArrayIn mem _) -> do
let shape' = Shape [num_threads] <> shape
sArray "red_arr" pt shape' $
ArrayIn mem $ IxFun.iota $ map (primExpFromSubExp int32) $ shapeDims shape'
_ -> do
let pt = elemType $ paramType p
shape = Shape [group_size]
sAllocArray "red_arr" pt shape $ Space "local"
-- | Arrays for storing group results.
--
-- The group-result arrays have an extra dimension (of size groupsize)
-- because they are also used for keeping vectorised accumulators for
-- first-stage reduction, if necessary. When actually storing group
-- results, the first index is set to 0.
groupResultArrays :: Count NumGroups SubExp -> Count GroupSize SubExp
-> [SegRedOp ExplicitMemory]
-> CallKernelGen [[VName]]
groupResultArrays (Count virt_num_groups) (Count group_size) reds =
forM reds $ \(SegRedOp _ lam _ shape) ->
forM (lambdaReturnType lam) $ \t -> do
let pt = elemType t
full_shape = Shape [group_size, virt_num_groups] <> shape <> arrayShape t
-- Move the groupsize dimension last to ensure coalesced
-- memory access.
perm = [1..shapeRank full_shape-1] ++ [0]
sAllocArrayPerm "group_res_arr" pt full_shape (Space "device") perm
nonsegmentedReduction :: Pattern ExplicitMemory
-> Count NumGroups SubExp -> Count GroupSize SubExp -> SegSpace
-> [SegRedOp ExplicitMemory]
-> DoSegBody
-> CallKernelGen ()
nonsegmentedReduction segred_pat num_groups group_size space reds body = do
let (gtids, dims) = unzip $ unSegSpace space
dims' <- mapM toExp dims
num_groups' <- traverse toExp num_groups
group_size' <- traverse toExp group_size
let global_tid = Imp.vi32 $ segFlat space
w = last dims'
counter <-
sStaticArray "counter" (Space "device") int32 $
Imp.ArrayValues $ replicate (fromIntegral maxNumOps) $ IntValue $ Int32Value 0
reds_group_res_arrs <- groupResultArrays num_groups group_size reds
num_threads <- dPrimV "num_threads" $ unCount num_groups' * unCount group_size'
emit $ Imp.DebugPrint "\n# SegRed" Nothing
sKernelThread "segred_nonseg" num_groups' group_size' (segFlat space) $ \constants -> do
sync_arr <- sAllocArray "sync_arr" Bool (Shape [intConst Int32 1]) $ Space "local"
reds_arrs <- mapM (intermediateArrays group_size (Var num_threads)) reds
-- Since this is the nonsegmented case, all outer segment IDs must
-- necessarily be 0.
forM_ gtids $ \v -> dPrimV_ v 0
let num_elements = Imp.elements w
let elems_per_thread = num_elements `quotRoundingUp` Imp.elements (kernelNumThreads constants)
slugs <- mapM (segRedOpSlug (kernelLocalThreadId constants) (kernelGroupId constants)) $
zip3 reds reds_arrs reds_group_res_arrs
reds_op_renamed <-
reductionStageOne constants (zip gtids dims') num_elements
global_tid elems_per_thread num_threads
slugs body
let segred_pes = chunks (map (length . segRedNeutral) reds) $
patternElements segred_pat
forM_ (zip7 reds reds_arrs reds_group_res_arrs segred_pes
slugs reds_op_renamed [0..]) $
\(SegRedOp _ red_op nes _,
red_arrs, group_res_arrs, pes, slug, red_op_renamed, i) -> do
let red_acc_params = take (length nes) $ lambdaParams red_op
reductionStageTwo constants pes (kernelGroupId constants) 0 [0] 0
(kernelNumGroups constants) slug red_acc_params red_op_renamed nes
1 counter (ValueExp $ IntValue $ Int32Value i)
sync_arr group_res_arrs red_arrs
smallSegmentsReduction :: Pattern ExplicitMemory
-> Count NumGroups SubExp -> Count GroupSize SubExp
-> SegSpace
-> [SegRedOp ExplicitMemory]
-> DoSegBody
-> CallKernelGen ()
smallSegmentsReduction (Pattern _ segred_pes) num_groups group_size space reds body = do
let (gtids, dims) = unzip $ unSegSpace space
dims' <- mapM toExp dims
let segment_size = last dims'
-- Careful to avoid division by zero now.
segment_size_nonzero_v <- dPrimV "segment_size_nonzero" $
BinOpExp (SMax Int32) 1 segment_size
num_groups' <- traverse toExp num_groups
group_size' <- traverse toExp group_size
num_threads <- dPrimV "num_threads" $ unCount num_groups' * unCount group_size'
let segment_size_nonzero = Imp.var segment_size_nonzero_v int32
num_segments = product $ init dims'
segments_per_group = unCount group_size' `quot` segment_size_nonzero
required_groups = num_segments `quotRoundingUp` segments_per_group
emit $ Imp.DebugPrint "\n# SegRed-small" Nothing
emit $ Imp.DebugPrint "num_segments" $ Just num_segments
emit $ Imp.DebugPrint "segment_size" $ Just segment_size
emit $ Imp.DebugPrint "segments_per_group" $ Just segments_per_group
emit $ Imp.DebugPrint "required_groups" $ Just required_groups
sKernelThread "segred_small" num_groups' group_size' (segFlat space) $ \constants -> do
reds_arrs <- mapM (intermediateArrays group_size (Var num_threads)) reds
-- We probably do not have enough actual workgroups to cover the
-- entire iteration space. Some groups thus have to perform double
-- duty; we put an outer loop to accomplish this.
virtualiseGroups constants SegVirt required_groups $ \group_id_var' -> do
let group_id' = Imp.vi32 group_id_var'
-- Compute the 'n' input indices. The outer 'n-1' correspond to
-- the segment ID, and are computed from the group id. The inner
-- is computed from the local thread id, and may be out-of-bounds.
let ltid = kernelLocalThreadId constants
segment_index = (ltid `quot` segment_size_nonzero) + (group_id' * segments_per_group)
index_within_segment = ltid `rem` segment_size
zipWithM_ dPrimV_ (init gtids) $ unflattenIndex (init dims') segment_index
dPrimV_ (last gtids) index_within_segment
let out_of_bounds =
forM_ (zip reds reds_arrs) $ \(SegRedOp _ _ nes _, red_arrs) ->
forM_ (zip red_arrs nes) $ \(arr, ne) ->
copyDWIMFix arr [ltid] ne []
in_bounds =
body constants $ \red_res ->
sComment "save results to be reduced" $ do
let red_dests = zip (concat reds_arrs) $ repeat [ltid]
forM_ (zip red_dests red_res) $ \((d,d_is), (res, res_is)) ->
copyDWIMFix d d_is res res_is
sComment "apply map function if in bounds" $
sIf (segment_size .>. 0 .&&.
isActive (init $ zip gtids dims) .&&.
ltid .<. segment_size * segments_per_group) in_bounds out_of_bounds
sOp $ Imp.ErrorSync Imp.FenceLocal -- Also implicitly barrier.
let crossesSegment from to = (to-from) .>. (to `rem` segment_size)
sWhen (segment_size .>. 0) $
sComment "perform segmented scan to imitate reduction" $
forM_ (zip reds reds_arrs) $ \(SegRedOp _ red_op _ _, red_arrs) ->
groupScan constants (Just crossesSegment) (Imp.vi32 num_threads)
(segment_size*segments_per_group) red_op red_arrs
sOp $ Imp.Barrier Imp.FenceLocal
sComment "save final values of segments" $
sWhen (group_id' * segments_per_group + ltid .<. num_segments .&&.
ltid .<. segments_per_group) $
forM_ (zip segred_pes (concat reds_arrs)) $ \(pe, arr) -> do
-- Figure out which segment result this thread should write...
let flat_segment_index = group_id' * segments_per_group + ltid
gtids' = unflattenIndex (init dims') flat_segment_index
copyDWIMFix (patElemName pe) gtids'
(Var arr) [(ltid+1) * segment_size_nonzero - 1]
-- Finally another barrier, because we will be writing to the
-- local memory array first thing in the next iteration.
sOp $ Imp.Barrier Imp.FenceLocal
largeSegmentsReduction :: Pattern ExplicitMemory
-> Count NumGroups SubExp -> Count GroupSize SubExp
-> SegSpace
-> [SegRedOp ExplicitMemory]
-> DoSegBody
-> CallKernelGen ()
largeSegmentsReduction segred_pat num_groups group_size space reds body = do
let (gtids, dims) = unzip $ unSegSpace space
dims' <- mapM toExp dims
let segment_size = last dims'
num_segments = product $ init dims'
num_groups' <- traverse toExp num_groups
group_size' <- traverse toExp group_size
let (groups_per_segment, elems_per_thread) =
groupsPerSegmentAndElementsPerThread segment_size num_segments
num_groups' group_size'
virt_num_groups <- dPrimV "vit_num_groups" $
groups_per_segment * num_segments
num_threads <- dPrimV "num_threads" $ unCount num_groups' * unCount group_size'
threads_per_segment <- dPrimV "thread_per_segment" $
groups_per_segment * unCount group_size'
emit $ Imp.DebugPrint "\n# SegRed-large" Nothing
emit $ Imp.DebugPrint "num_segments" $ Just num_segments
emit $ Imp.DebugPrint "segment_size" $ Just segment_size
emit $ Imp.DebugPrint "virt_num_groups" $ Just $ Imp.vi32 virt_num_groups
emit $ Imp.DebugPrint "num_groups" $ Just $ Imp.unCount num_groups'
emit $ Imp.DebugPrint "group_size" $ Just $ Imp.unCount group_size'
emit $ Imp.DebugPrint "elems_per_thread" $ Just $ Imp.unCount elems_per_thread
emit $ Imp.DebugPrint "groups_per_segment" $ Just groups_per_segment
reds_group_res_arrs <- groupResultArrays (Count (Var virt_num_groups)) group_size reds
-- In principle we should have a counter for every segment. Since
-- the number of segments is a dynamic quantity, we would have to
-- allocate and zero out an array here, which is expensive.
-- However, we exploit the fact that the number of segments being
-- reduced at any point in time is limited by the number of
-- workgroups. If we bound the number of workgroups, we can get away
-- with using that many counters. FIXME: Is this limit checked
-- anywhere? There are other places in the compiler that will fail
-- if the group count exceeds the maximum group size, which is at
-- most 1024 anyway.
let num_counters = fromIntegral maxNumOps * 1024
counter <-
sStaticArray "counter" (Space "device") int32 $
Imp.ArrayZeros num_counters
sKernelThread "segred_large" num_groups' group_size' (segFlat space) $ \constants -> do
reds_arrs <- mapM (intermediateArrays group_size (Var num_threads)) reds
sync_arr <- sAllocArray "sync_arr" Bool (Shape [intConst Int32 1]) $ Space "local"
-- We probably do not have enough actual workgroups to cover the
-- entire iteration space. Some groups thus have to perform double
-- duty; we put an outer loop to accomplish this.
virtualiseGroups constants SegVirt (Imp.vi32 virt_num_groups) $ \group_id_var -> do
let segment_gtids = init gtids
group_id = Imp.vi32 group_id_var
flat_segment_id = group_id `quot` groups_per_segment
local_tid = kernelLocalThreadId constants
global_tid = (group_id * unCount group_size' + local_tid)
`rem` (unCount group_size' * groups_per_segment)
w = last dims
first_group_for_segment = flat_segment_id * groups_per_segment
zipWithM_ dPrimV_ segment_gtids $ unflattenIndex (init dims') flat_segment_id
dPrim_ (last gtids) int32
num_elements <- Imp.elements <$> toExp w
slugs <- mapM (segRedOpSlug local_tid group_id) $
zip3 reds reds_arrs reds_group_res_arrs
reds_op_renamed <-
reductionStageOne constants (zip gtids dims') num_elements
global_tid elems_per_thread threads_per_segment
slugs body
let segred_pes = chunks (map (length . segRedNeutral) reds) $
patternElements segred_pat
multiple_groups_per_segment =
forM_ (zip7 reds reds_arrs reds_group_res_arrs segred_pes
slugs reds_op_renamed [0..]) $
\(SegRedOp _ red_op nes _, red_arrs, group_res_arrs, pes,
slug, red_op_renamed, i) -> do
let red_acc_params = take (length nes) $ lambdaParams red_op
reductionStageTwo constants pes
group_id flat_segment_id (map (`Imp.var` int32) segment_gtids)
first_group_for_segment groups_per_segment
slug red_acc_params red_op_renamed nes
(fromIntegral num_counters) counter (ValueExp $ IntValue $ Int32Value i)
sync_arr group_res_arrs red_arrs
one_group_per_segment =
comment "first thread in group saves final result to memory" $
forM_ (zip slugs segred_pes) $ \(slug, pes) ->
sWhen (local_tid .==. 0) $
forM_ (zip pes (slugAccs slug)) $ \(v, (acc, acc_is)) ->
copyDWIMFix (patElemName v) (map (`Imp.var` int32) segment_gtids) (Var acc) acc_is
sIf (groups_per_segment .==. 1) one_group_per_segment multiple_groups_per_segment
-- Careful to avoid division by zero here. We have at least one group
-- per segment.
groupsPerSegmentAndElementsPerThread :: Imp.Exp -> Imp.Exp
-> Count NumGroups Imp.Exp -> Count GroupSize Imp.Exp
-> (Imp.Exp, Imp.Count Imp.Elements Imp.Exp)
groupsPerSegmentAndElementsPerThread segment_size num_segments num_groups_hint group_size =
let groups_per_segment =
unCount num_groups_hint `quotRoundingUp` BinOpExp (SMax Int32) 1 num_segments
elements_per_thread =
segment_size `quotRoundingUp` (unCount group_size * groups_per_segment)
in (groups_per_segment, Imp.elements elements_per_thread)
-- | A SegRedOp with auxiliary information.
data SegRedOpSlug =
SegRedOpSlug
{ slugOp :: SegRedOp ExplicitMemory
, slugArrs :: [VName]
-- ^ The arrays used for computing the intra-group reduction
-- (either local or global memory).
, slugAccs :: [(VName, [Imp.Exp])]
-- ^ Places to store accumulator in stage 1 reduction.
}
slugBody :: SegRedOpSlug -> Body ExplicitMemory
slugBody = lambdaBody . segRedLambda . slugOp
slugParams :: SegRedOpSlug -> [LParam ExplicitMemory]
slugParams = lambdaParams . segRedLambda . slugOp
slugNeutral :: SegRedOpSlug -> [SubExp]
slugNeutral = segRedNeutral . slugOp
slugShape :: SegRedOpSlug -> Shape
slugShape = segRedShape . slugOp
slugsComm :: [SegRedOpSlug] -> Commutativity
slugsComm = mconcat . map (segRedComm . slugOp)
accParams, nextParams :: SegRedOpSlug -> [LParam ExplicitMemory]
accParams slug = take (length (slugNeutral slug)) $ slugParams slug
nextParams slug = drop (length (slugNeutral slug)) $ slugParams slug
segRedOpSlug :: Imp.Exp -> Imp.Exp -> (SegRedOp ExplicitMemory, [VName], [VName]) -> InKernelGen SegRedOpSlug
segRedOpSlug local_tid group_id (op, group_res_arrs, param_arrs) =
SegRedOpSlug op group_res_arrs <$>
zipWithM mkAcc (lambdaParams (segRedLambda op)) param_arrs
where mkAcc p param_arr
| Prim t <- paramType p,
shapeRank (segRedShape op) == 0 = do
acc <- dPrim (baseString (paramName p) <> "_acc") t
return (acc, [])
| otherwise =
return (param_arr, [local_tid, group_id])
reductionStageZero :: KernelConstants
-> [(VName, Imp.Exp)]
-> Imp.Count Imp.Elements Imp.Exp
-> Imp.Exp
-> Imp.Count Imp.Elements Imp.Exp
-> VName
-> [SegRedOpSlug]
-> DoSegBody
-> InKernelGen ([Lambda ExplicitMemory], InKernelGen ())
reductionStageZero constants ispace num_elements global_tid elems_per_thread threads_per_segment slugs body = do
let (gtids, _dims) = unzip ispace
gtid = last gtids
local_tid = kernelLocalThreadId constants
-- Figure out how many elements this thread should process.
chunk_size <- dPrim "chunk_size" int32
let ordering = case slugsComm slugs of
Commutative -> SplitStrided $ Var threads_per_segment
Noncommutative -> SplitContiguous
computeThreadChunkSize ordering global_tid elems_per_thread num_elements chunk_size
dScope Nothing $ scopeOfLParams $ concatMap slugParams slugs
sComment "neutral-initialise the accumulators" $
forM_ slugs $ \slug ->
forM_ (zip (slugAccs slug) (slugNeutral slug)) $ \((acc, acc_is), ne) ->
sLoopNest (slugShape slug) $ \vec_is ->
copyDWIMFix acc (acc_is++vec_is) ne []
slugs_op_renamed <- mapM (renameLambda . segRedLambda . slugOp) slugs
let doTheReduction =
forM_ (zip slugs_op_renamed slugs) $ \(slug_op_renamed, slug) ->
sLoopNest (slugShape slug) $ \vec_is -> do
comment "to reduce current chunk, first store our result in memory" $ do
forM_ (zip (slugParams slug) (slugAccs slug)) $ \(p, (acc, acc_is)) ->
copyDWIMFix (paramName p) [] (Var acc) (acc_is++vec_is)
forM_ (zip (slugArrs slug) (slugParams slug)) $ \(arr, p) ->
when (primType $ paramType p) $
copyDWIMFix arr [local_tid] (Var $ paramName p) []
sOp $ Imp.ErrorSync Imp.FenceLocal -- Also implicitly barrier.
groupReduce constants (kernelGroupSize constants) slug_op_renamed (slugArrs slug)
sOp $ Imp.Barrier Imp.FenceLocal
sComment "first thread saves the result in accumulator" $
sWhen (local_tid .==. 0) $
forM_ (zip (slugAccs slug) (lambdaParams slug_op_renamed)) $ \((acc, acc_is), p) ->
copyDWIMFix acc (acc_is++vec_is) (Var $ paramName p) []
-- If this is a non-commutative reduction, each thread must run the
-- loop the same number of iterations, because we will be performing
-- a group-wide reduction in there.
let comm = slugsComm slugs
(bound, check_bounds) =
case comm of
Commutative -> (Imp.var chunk_size int32, id)
Noncommutative -> (Imp.unCount elems_per_thread,
sWhen (Imp.var gtid int32 .<. Imp.unCount num_elements))
sFor "i" bound $ \i -> do
gtid <--
case comm of
Commutative ->
global_tid +
Imp.var threads_per_segment int32 * i
Noncommutative ->
let index_in_segment = global_tid `quot` kernelGroupSize constants
in local_tid +
(index_in_segment * Imp.unCount elems_per_thread + i) *
kernelGroupSize constants
check_bounds $ sComment "apply map function" $
body constants $ \all_red_res -> do
let slugs_res = chunks (map (length . slugNeutral) slugs) all_red_res
forM_ (zip slugs slugs_res) $ \(slug, red_res) ->
sLoopNest (slugShape slug) $ \vec_is -> do
sComment "load accumulator" $
forM_ (zip (accParams slug) (slugAccs slug)) $ \(p, (acc, acc_is)) ->
copyDWIMFix (paramName p) [] (Var acc) (acc_is ++ vec_is)
sComment "load new values" $
forM_ (zip (nextParams slug) red_res) $ \(p, (res, res_is)) ->
copyDWIMFix (paramName p) [] res (res_is ++ vec_is)
sComment "apply reduction operator" $
compileStms mempty (bodyStms $ slugBody slug) $
sComment "store in accumulator" $
forM_ (zip
(slugAccs slug)
(bodyResult $ slugBody slug)) $ \((acc, acc_is), se) ->
copyDWIMFix acc (acc_is ++ vec_is) se []
case comm of
Noncommutative -> do
doTheReduction
sComment "first thread keeps accumulator; others reset to neutral element" $ do
let reset_to_neutral =
forM_ slugs $ \slug ->
forM_ (zip (slugAccs slug) (slugNeutral slug)) $ \((acc, acc_is), ne) ->
sLoopNest (slugShape slug) $ \vec_is ->
copyDWIMFix acc (acc_is++vec_is) ne []
sUnless (local_tid .==. 0) reset_to_neutral
_ -> return ()
return (slugs_op_renamed, doTheReduction)
reductionStageOne :: KernelConstants
-> [(VName, Imp.Exp)]
-> Imp.Count Imp.Elements Imp.Exp
-> Imp.Exp
-> Imp.Count Imp.Elements Imp.Exp
-> VName
-> [SegRedOpSlug]
-> DoSegBody
-> InKernelGen [Lambda ExplicitMemory]
reductionStageOne constants ispace num_elements global_tid elems_per_thread threads_per_segment slugs body = do
(slugs_op_renamed, doTheReduction) <-
reductionStageZero constants ispace num_elements global_tid elems_per_thread threads_per_segment slugs body
case slugsComm slugs of
Noncommutative ->
forM_ slugs $ \slug ->
forM_ (zip (accParams slug) (slugAccs slug)) $ \(p, (acc, acc_is)) ->
copyDWIMFix (paramName p) [] (Var acc) acc_is
_ -> doTheReduction
return slugs_op_renamed
reductionStageTwo :: KernelConstants
-> [PatElem ExplicitMemory]
-> Imp.Exp
-> Imp.Exp
-> [Imp.Exp]
-> Imp.Exp
-> Imp.Exp
-> SegRedOpSlug
-> [LParam ExplicitMemory]
-> Lambda ExplicitMemory -> [SubExp]
-> Imp.Exp -> VName -> Imp.Exp -> VName -> [VName] -> [VName]
-> InKernelGen ()
reductionStageTwo constants segred_pes
group_id flat_segment_id segment_gtids first_group_for_segment groups_per_segment
slug red_acc_params
red_op_renamed nes
num_counters counter counter_i sync_arr group_res_arrs red_arrs = do
let local_tid = kernelLocalThreadId constants
group_size = kernelGroupSize constants
old_counter <- dPrim "old_counter" int32
(counter_mem, _, counter_offset) <- fullyIndexArray counter [counter_i * num_counters +
flat_segment_id `rem` num_counters]
comment "first thread in group saves group result to global memory" $
sWhen (local_tid .==. 0) $ do
forM_ (take (length nes) $ zip group_res_arrs (slugAccs slug)) $ \(v, (acc, acc_is)) ->
copyDWIMFix v [0, group_id] (Var acc) acc_is
sOp $ Imp.MemFence Imp.FenceGlobal
-- Increment the counter, thus stating that our result is
-- available.
sOp $ Imp.Atomic DefaultSpace $ Imp.AtomicAdd old_counter counter_mem counter_offset 1
-- Now check if we were the last group to write our result. If
-- so, it is our responsibility to produce the final result.
sWrite sync_arr [0] $ Imp.var old_counter int32 .==. groups_per_segment - 1
sOp $ Imp.Barrier Imp.FenceGlobal
is_last_group <- dPrim "is_last_group" Bool
copyDWIMFix is_last_group [] (Var sync_arr) [0]
sWhen (Imp.var is_last_group Bool) $ do
-- The final group has written its result (and it was
-- us!), so read in all the group results and perform the
-- final stage of the reduction. But first, we reset the
-- counter so it is ready for next time. This is done
-- with an atomic to avoid warnings about write/write
-- races in oclgrind.
sWhen (local_tid .==. 0) $
sOp $ Imp.Atomic DefaultSpace $ Imp.AtomicAdd old_counter counter_mem counter_offset $
negate groups_per_segment
sLoopNest (slugShape slug) $ \vec_is -> do
comment "read in the per-group-results" $
forM_ (zip4 red_acc_params red_arrs nes group_res_arrs) $
\(p, arr, ne, group_res_arr) -> do
let load_group_result =
copyDWIMFix (paramName p) []
(Var group_res_arr) ([0, first_group_for_segment + local_tid] ++ vec_is)
load_neutral_element =
copyDWIMFix (paramName p) [] ne []
sIf (local_tid .<. groups_per_segment)
load_group_result load_neutral_element
when (primType $ paramType p) $
copyDWIMFix arr [local_tid] (Var $ paramName p) []
sOp $ Imp.Barrier Imp.FenceLocal
sComment "reduce the per-group results" $ do
groupReduce constants group_size red_op_renamed red_arrs
sComment "and back to memory with the final result" $
sWhen (local_tid .==. 0) $
forM_ (zip segred_pes $ lambdaParams red_op_renamed) $ \(pe, p) ->
copyDWIMFix (patElemName pe) (segment_gtids++vec_is) (Var $ paramName p) []