futhark-0.25.10: src/Futhark/CodeGen/ImpGen/GPU/SegScan/SinglePass.hs
{-# LANGUAGE TypeFamilies #-}
-- | Code generation for segmented and non-segmented scans. Uses a
-- fast single-pass algorithm, but which only works on NVIDIA GPUs and
-- with some constraints on the operator. We use this when we can.
module Futhark.CodeGen.ImpGen.GPU.SegScan.SinglePass (compileSegScan) where
import Control.Monad
import Data.List (zip4, zip7)
import Data.Map qualified as M
import Data.Maybe
import Futhark.CodeGen.ImpCode.GPU qualified as Imp
import Futhark.CodeGen.ImpGen
import Futhark.CodeGen.ImpGen.GPU.Base
import Futhark.IR.GPUMem
import Futhark.IR.Mem.LMAD qualified as LMAD
import Futhark.Transform.Rename
import Futhark.Util (mapAccumLM, takeLast)
import Futhark.Util.IntegralExp (IntegralExp (mod, rem), divUp, nextMul, quot)
import Prelude hiding (mod, quot, rem)
xParams, yParams :: SegBinOp GPUMem -> [LParam GPUMem]
xParams scan =
take (length (segBinOpNeutral scan)) (lambdaParams (segBinOpLambda scan))
yParams scan =
drop (length (segBinOpNeutral scan)) (lambdaParams (segBinOpLambda scan))
createLocalArrays ::
Count GroupSize SubExp ->
SubExp ->
[PrimType] ->
InKernelGen (VName, [VName], [VName], VName, [VName])
createLocalArrays (Count groupSize) chunk types = do
let groupSizeE = pe64 groupSize
workSize = pe64 chunk * groupSizeE
prefixArraysSize =
foldl (\acc tySize -> nextMul acc tySize + tySize * groupSizeE) 0 $
map primByteSize types
maxTransposedArraySize =
foldl1 sMax64 $ map (\ty -> workSize * primByteSize ty) types
warpSize :: (Num a) => a
warpSize = 32
maxWarpExchangeSize =
foldl (\acc tySize -> nextMul acc tySize + tySize * fromInteger warpSize) 0 $
map primByteSize types
maxLookbackSize = maxWarpExchangeSize + warpSize
size = Imp.bytes $ maxLookbackSize `sMax64` prefixArraysSize `sMax64` maxTransposedArraySize
(_, byteOffsets) <-
mapAccumLM
( \off tySize -> do
off' <- dPrimVE "byte_offsets" $ nextMul off tySize + pe64 groupSize * tySize
pure (off', off)
)
0
$ map primByteSize types
(_, warpByteOffsets) <-
mapAccumLM
( \off tySize -> do
off' <- dPrimVE "warp_byte_offset" $ nextMul off tySize + warpSize * tySize
pure (off', off)
)
warpSize
$ map primByteSize types
sComment "Allocate reusable shared memory" $ pure ()
localMem <- sAlloc "local_mem" size (Space "local")
transposeArrayLength <- dPrimV "trans_arr_len" workSize
sharedId <- sArrayInMem "shared_id" int32 (Shape [constant (1 :: Int32)]) localMem
transposedArrays <-
forM types $ \ty ->
sArrayInMem
"local_transpose_arr"
ty
(Shape [tvSize transposeArrayLength])
localMem
prefixArrays <-
forM (zip byteOffsets types) $ \(off, ty) -> do
let off' = off `quot` primByteSize ty
sArray
"local_prefix_arr"
ty
(Shape [groupSize])
localMem
$ LMAD.iota off' [pe64 groupSize]
warpscan <- sArrayInMem "warpscan" int8 (Shape [constant (warpSize :: Int64)]) localMem
warpExchanges <-
forM (zip warpByteOffsets types) $ \(off, ty) -> do
let off' = off `quot` primByteSize ty
sArray
"warp_exchange"
ty
(Shape [constant (warpSize :: Int64)])
localMem
$ LMAD.iota off' [warpSize]
pure (sharedId, transposedArrays, prefixArrays, warpscan, warpExchanges)
statusX, statusA, statusP :: (Num a) => a
statusX = 0
statusA = 1
statusP = 2
inBlockScanLookback ::
KernelConstants ->
Imp.TExp Int64 ->
VName ->
[VName] ->
Lambda GPUMem ->
InKernelGen ()
inBlockScanLookback constants arrs_full_size flag_arr arrs scan_lam = everythingVolatile $ do
flg_x <- dPrim "flg_x" p_int8
flg_y <- dPrim "flg_y" p_int8
let flg_param_x = Param mempty (tvVar flg_x) (MemPrim p_int8)
flg_param_y = Param mempty (tvVar flg_y) (MemPrim p_int8)
flg_y_exp = tvExp flg_y
statusP_e = statusP :: Imp.TExp Int8
statusX_e = statusX :: Imp.TExp Int8
dLParams (lambdaParams scan_lam)
skip_threads <- dPrim "skip_threads" int32
let in_block_thread_active =
tvExp skip_threads .<=. in_block_id
actual_params = lambdaParams scan_lam
(x_params, y_params) =
splitAt (length actual_params `div` 2) actual_params
y_to_x =
forM_ (zip x_params y_params) $ \(x, y) ->
when (primType (paramType x)) $
copyDWIM (paramName x) [] (Var (paramName y)) []
y_to_x_flg =
copyDWIM (tvVar flg_x) [] (Var (tvVar flg_y)) []
-- Set initial y values
sComment "read input for in-block scan" $ do
zipWithM_ readInitial (flg_param_y : y_params) (flag_arr : arrs)
-- Since the final result is expected to be in x_params, we may
-- need to copy it there for the first thread in the block.
sWhen (in_block_id .==. 0) $ do
y_to_x
y_to_x_flg
when array_scan barrier
let op_to_x = do
sIf
(flg_y_exp .==. statusP_e .||. flg_y_exp .==. statusX_e)
( do
y_to_x_flg
y_to_x
)
(compileBody' x_params $ lambdaBody scan_lam)
sComment "in-block scan (hopefully no barriers needed)" $ do
skip_threads <-- 1
sWhile (tvExp skip_threads .<. block_size) $ do
sWhen in_block_thread_active $ do
sComment "read operands" $
zipWithM_
(readParam (sExt64 $ tvExp skip_threads))
(flg_param_x : x_params)
(flag_arr : arrs)
sComment "perform operation" op_to_x
sComment "write result" $
sequence_ $
zipWith3
writeResult
(flg_param_x : x_params)
(flg_param_y : y_params)
(flag_arr : arrs)
skip_threads <-- tvExp skip_threads * 2
where
p_int8 = IntType Int8
block_size = 32
block_id = ltid32 `quot` block_size
in_block_id = ltid32 - block_id * block_size
ltid32 = kernelLocalThreadId constants
ltid = sExt64 ltid32
gtid = sExt64 $ kernelGlobalThreadId constants
array_scan = not $ all primType $ lambdaReturnType scan_lam
barrier
| array_scan =
sOp $ Imp.Barrier Imp.FenceGlobal
| otherwise =
sOp $ Imp.Barrier Imp.FenceLocal
readInitial p arr
| primType $ paramType p =
copyDWIMFix (paramName p) [] (Var arr) [ltid]
| otherwise =
copyDWIMFix (paramName p) [] (Var arr) [gtid]
readParam behind p arr
| primType $ paramType p =
copyDWIMFix (paramName p) [] (Var arr) [ltid - behind]
| otherwise =
copyDWIMFix (paramName p) [] (Var arr) [gtid - behind + arrs_full_size]
writeResult x y arr = do
when (isPrimParam x) $
copyDWIMFix arr [ltid] (Var $ paramName x) []
copyDWIM (paramName y) [] (Var $ paramName x) []
-- | Compile 'SegScan' instance to host-level code with calls to a
-- single-pass kernel.
compileSegScan ::
Pat LetDecMem ->
SegLevel ->
SegSpace ->
SegBinOp GPUMem ->
KernelBody GPUMem ->
CallKernelGen ()
compileSegScan pat lvl space scan_op map_kbody = do
attrs <- lvlKernelAttrs lvl
let Pat all_pes = pat
scanop_nes = segBinOpNeutral scan_op
n = product $ map pe64 $ segSpaceDims space
tys' = lambdaReturnType $ segBinOpLambda scan_op
tys = map elemType tys'
group_size_e = pe64 $ unCount $ kAttrGroupSize attrs
num_physgroups_e = pe64 $ unCount $ kAttrNumGroups attrs
let chunk_const = getChunkSize tys'
chunk_v <- dPrimV "chunk_size" . isInt64 =<< kernelConstToExp chunk_const
let chunk = tvExp chunk_v
num_virtgroups <-
tvSize <$> dPrimV "num_virtgroups" (n `divUp` (group_size_e * chunk))
let num_virtgroups_e = pe64 num_virtgroups
num_virt_threads <-
dPrimVE "num_virt_threads" $ num_virtgroups_e * group_size_e
let (gtids, dims) = unzip $ unSegSpace space
dims' = map pe64 dims
segmented = length dims' > 1
not_segmented_e = fromBool $ not segmented
segment_size = last dims'
emit $ Imp.DebugPrint "Sequential elements per thread (chunk)" $ Just $ untyped chunk
statusFlags <- sAllocArray "status_flags" int8 (Shape [num_virtgroups]) (Space "device")
sReplicate statusFlags $ intConst Int8 statusX
(aggregateArrays, incprefixArrays) <-
fmap unzip $
forM tys $ \ty ->
(,)
<$> sAllocArray "aggregates" ty (Shape [num_virtgroups]) (Space "device")
<*> sAllocArray "incprefixes" ty (Shape [num_virtgroups]) (Space "device")
global_id <- genZeroes "global_dynid" 1
let attrs' = attrs {kAttrConstExps = M.singleton (tvVar chunk_v) chunk_const}
sKernelThread "segscan" (segFlat space) attrs' $ do
chunk32 <- dPrimVE "chunk_size_32b" $ sExt32 $ tvExp chunk_v
constants <- kernelConstants <$> askEnv
let ltid32 = kernelLocalThreadId constants
ltid = sExt64 ltid32
(sharedId, transposedArrays, prefixArrays, warpscan, exchanges) <-
createLocalArrays (kAttrGroupSize attrs) (tvSize chunk_v) tys
-- We wrap the entire kernel body in a virtualisation loop to handle the
-- case where we do not have enough workgroups to cover the iteration space.
-- Dynamic group indexing has no implication on this, since each group
-- simply fetches a new dynamic ID upon entry into the virtualisation loop.
--
-- We could use virtualiseGroups, but this introduces a barrier which is
-- redundant in this case, and also we don't need to base virtual group IDs
-- on the loop variable, but rather on the dynamic IDs.
physgroup_id <- dPrim "physgroup_id" int32
sOp $ Imp.GetGroupId (tvVar physgroup_id) 0
iters <-
dPrimVE "virtloop_bound" $
(num_virtgroups_e - tvExp physgroup_id)
`divUp` num_physgroups_e
sFor "virtloop_i" iters $ const $ do
dyn_id <- dPrim "dynamic_id" int32
sComment "First thread in block fetches this block's dynamic_id" $ do
sWhen (ltid32 .==. 0) $ do
(globalIdMem, _, globalIdOff) <- fullyIndexArray global_id [0]
sOp $
Imp.Atomic DefaultSpace $
Imp.AtomicAdd
Int32
(tvVar dyn_id)
globalIdMem
(Count $ unCount globalIdOff)
(untyped (1 :: Imp.TExp Int32))
sComment "Set dynamic id for this block" $ do
copyDWIMFix sharedId [0] (tvSize dyn_id) []
sComment "First thread in last (virtual) block resets global dynamic_id" $ do
sWhen (tvExp dyn_id .==. num_virtgroups_e - 1) $
copyDWIMFix global_id [0] (intConst Int32 0) []
let local_barrier = Imp.Barrier Imp.FenceLocal
local_fence = Imp.MemFence Imp.FenceLocal
global_fence = Imp.MemFence Imp.FenceGlobal
sOp local_barrier
copyDWIMFix (tvVar dyn_id) [] (Var sharedId) [0]
sOp local_barrier
block_offset <-
dPrimVE "block_offset" $
sExt64 (tvExp dyn_id) * chunk * group_size_e
sgm_idx <- dPrimVE "sgm_idx" $ block_offset `mod` segment_size
boundary <-
dPrimVE "boundary" $
sExt32 $
sMin64 (chunk * group_size_e) (segment_size - sgm_idx)
segsize_compact <-
dPrimVE "segsize_compact" $
sExt32 $
sMin64 (chunk * group_size_e) segment_size
private_chunks <-
forM tys $ \ty ->
sAllocArray
"private"
ty
(Shape [tvSize chunk_v])
(ScalarSpace [tvSize chunk_v] ty)
thd_offset <- dPrimVE "thd_offset" $ block_offset + ltid
sComment "Load and map" $
sFor "i" chunk $ \i -> do
-- The map's input index
virt_tid <- dPrimVE "virt_tid" $ thd_offset + i * group_size_e
dIndexSpace (zip gtids dims') virt_tid
-- Perform the map
let in_bounds =
compileStms mempty (kernelBodyStms map_kbody) $ do
let (all_scan_res, map_res) =
splitAt (segBinOpResults [scan_op]) $ kernelBodyResult map_kbody
-- Write map results to their global memory destinations
forM_ (zip (takeLast (length map_res) all_pes) map_res) $ \(dest, src) ->
copyDWIMFix (patElemName dest) (map Imp.le64 gtids) (kernelResultSubExp src) []
-- Write to-scan results to private memory.
forM_ (zip private_chunks $ map kernelResultSubExp all_scan_res) $ \(dest, src) ->
copyDWIMFix dest [i] src []
out_of_bounds =
forM_ (zip private_chunks scanop_nes) $ \(dest, ne) ->
copyDWIMFix dest [i] ne []
sIf (virt_tid .<. n) in_bounds out_of_bounds
sOp $ Imp.ErrorSync Imp.FenceLocal
sComment "Transpose scan inputs" $ do
forM_ (zip transposedArrays private_chunks) $ \(trans, priv) -> do
sFor "i" chunk $ \i -> do
sharedIdx <- dPrimVE "sharedIdx" $ ltid + i * group_size_e
copyDWIMFix trans [sharedIdx] (Var priv) [i]
sOp local_barrier
sFor "i" chunk $ \i -> do
sharedIdx <- dPrimV "sharedIdx" $ ltid * chunk + i
copyDWIMFix priv [sExt64 i] (Var trans) [sExt64 $ tvExp sharedIdx]
sOp local_barrier
sComment "Per thread scan" $ do
-- We don't need to touch the first element, so only m-1
-- iterations here.
sFor "i" (chunk - 1) $ \i -> do
let xs = map paramName $ xParams scan_op
ys = map paramName $ yParams scan_op
-- determine if start of segment
new_sgm <-
if segmented
then do
gidx <- dPrimVE "gidx" $ (ltid32 * chunk32) + 1
dPrimVE "new_sgm" $ (gidx + sExt32 i - boundary) `mod` segsize_compact .==. 0
else pure false
-- skip scan of first element in segment
sUnless new_sgm $ do
forM_ (zip4 private_chunks xs ys tys) $ \(src, x, y, ty) -> do
dPrim_ x ty
dPrim_ y ty
copyDWIMFix x [] (Var src) [i]
copyDWIMFix y [] (Var src) [i + 1]
compileStms mempty (bodyStms $ lambdaBody $ segBinOpLambda scan_op) $
forM_ (zip private_chunks $ map resSubExp $ bodyResult $ lambdaBody $ segBinOpLambda scan_op) $ \(dest, res) ->
copyDWIMFix dest [i + 1] res []
sComment "Publish results in shared memory" $ do
forM_ (zip prefixArrays private_chunks) $ \(dest, src) ->
copyDWIMFix dest [ltid] (Var src) [chunk - 1]
sOp local_barrier
let crossesSegment = do
guard segmented
Just $ \from to ->
let from' = (from + 1) * chunk32 - 1
to' = (to + 1) * chunk32 - 1
in (to' - from') .>. (to' + segsize_compact - boundary) `mod` segsize_compact
scan_op1 <- renameLambda $ segBinOpLambda scan_op
accs <- mapM (dPrim "acc") tys
sComment "Scan results (with warp scan)" $ do
groupScan
crossesSegment
group_size_e
num_virt_threads
scan_op1
prefixArrays
sOp $ Imp.ErrorSync Imp.FenceLocal
let firstThread acc prefixes =
copyDWIMFix (tvVar acc) [] (Var prefixes) [sExt64 group_size_e - 1]
notFirstThread acc prefixes =
copyDWIMFix (tvVar acc) [] (Var prefixes) [ltid - 1]
sIf
(ltid32 .==. 0)
(zipWithM_ firstThread accs prefixArrays)
(zipWithM_ notFirstThread accs prefixArrays)
sOp local_barrier
prefixes <- forM (zip scanop_nes tys) $ \(ne, ty) ->
dPrimV "prefix" $ TPrimExp $ toExp' ty ne
blockNewSgm <- dPrimVE "block_new_sgm" $ sgm_idx .==. 0
sComment "Perform lookback" $ do
sWhen (blockNewSgm .&&. ltid32 .==. 0) $ do
everythingVolatile $
forM_ (zip accs incprefixArrays) $ \(acc, incprefixArray) ->
copyDWIMFix incprefixArray [tvExp dyn_id] (tvSize acc) []
sOp global_fence
everythingVolatile $
copyDWIMFix statusFlags [tvExp dyn_id] (intConst Int8 statusP) []
forM_ (zip scanop_nes accs) $ \(ne, acc) ->
copyDWIMFix (tvVar acc) [] ne []
-- end sWhen
let warpSize = kernelWaveSize constants
sWhen (bNot blockNewSgm .&&. ltid32 .<. warpSize) $ do
sWhen (ltid32 .==. 0) $ do
sIf
(not_segmented_e .||. boundary .==. sExt32 (group_size_e * chunk))
( do
everythingVolatile $
forM_ (zip aggregateArrays accs) $ \(aggregateArray, acc) ->
copyDWIMFix aggregateArray [tvExp dyn_id] (tvSize acc) []
sOp global_fence
everythingVolatile $
copyDWIMFix statusFlags [tvExp dyn_id] (intConst Int8 statusA) []
)
( do
everythingVolatile $
forM_ (zip incprefixArrays accs) $ \(incprefixArray, acc) ->
copyDWIMFix incprefixArray [tvExp dyn_id] (tvSize acc) []
sOp global_fence
everythingVolatile $
copyDWIMFix statusFlags [tvExp dyn_id] (intConst Int8 statusP) []
)
everythingVolatile $
copyDWIMFix warpscan [0] (Var statusFlags) [tvExp dyn_id - 1]
-- sWhen
sOp local_fence
status <- dPrim "status" int8 :: InKernelGen (TV Int8)
copyDWIMFix (tvVar status) [] (Var warpscan) [0]
sIf
(tvExp status .==. statusP)
( sWhen (ltid32 .==. 0) $
everythingVolatile $
forM_ (zip prefixes incprefixArrays) $ \(prefix, incprefixArray) ->
copyDWIMFix (tvVar prefix) [] (Var incprefixArray) [tvExp dyn_id - 1]
)
( do
readOffset <-
dPrimV "readOffset" $
sExt32 $
tvExp dyn_id - sExt64 (kernelWaveSize constants)
let loopStop = warpSize * (-1)
sameSegment readIdx
| segmented =
let startIdx = sExt64 (tvExp readIdx + 1) * group_size_e * chunk - 1
in block_offset - startIdx .<=. sgm_idx
| otherwise = true
sWhile (tvExp readOffset .>. loopStop) $ do
readI <- dPrimV "read_i" $ tvExp readOffset + ltid32
aggrs <- forM (zip scanop_nes tys) $ \(ne, ty) ->
dPrimV "aggr" $ TPrimExp $ toExp' ty ne
flag <- dPrimV "flag" (statusX :: Imp.TExp Int8)
everythingVolatile . sWhen (tvExp readI .>=. 0) $ do
sIf
(sameSegment readI)
( do
copyDWIMFix (tvVar flag) [] (Var statusFlags) [sExt64 $ tvExp readI]
sIf
(tvExp flag .==. statusP)
( forM_ (zip incprefixArrays aggrs) $ \(incprefix, aggr) ->
copyDWIMFix (tvVar aggr) [] (Var incprefix) [sExt64 $ tvExp readI]
)
( sWhen (tvExp flag .==. statusA) $ do
forM_ (zip aggrs aggregateArrays) $ \(aggr, aggregate) ->
copyDWIMFix (tvVar aggr) [] (Var aggregate) [sExt64 $ tvExp readI]
)
)
(copyDWIMFix (tvVar flag) [] (intConst Int8 statusP) [])
-- end sIf
-- end sWhen
forM_ (zip exchanges aggrs) $ \(exchange, aggr) ->
copyDWIMFix exchange [ltid] (tvSize aggr) []
copyDWIMFix warpscan [ltid] (tvSize flag) []
-- execute warp-parallel reduction but only if the last read flag in not STATUS_P
copyDWIMFix (tvVar flag) [] (Var warpscan) [sExt64 warpSize - 1]
sWhen (tvExp flag .<. statusP) $ do
lam' <- renameLambda scan_op1
inBlockScanLookback
constants
num_virt_threads
warpscan
exchanges
lam'
-- all threads of the warp read the result of reduction
copyDWIMFix (tvVar flag) [] (Var warpscan) [sExt64 warpSize - 1]
forM_ (zip aggrs exchanges) $ \(aggr, exchange) ->
copyDWIMFix (tvVar aggr) [] (Var exchange) [sExt64 warpSize - 1]
-- update read offset
sIf
(tvExp flag .==. statusP)
(readOffset <-- loopStop)
( sWhen (tvExp flag .==. statusA) $ do
readOffset <-- tvExp readOffset - zExt32 warpSize
)
-- update prefix if flag different than STATUS_X:
sWhen (tvExp flag .>. statusX) $ do
lam <- renameLambda scan_op1
let (xs, ys) = splitAt (length tys) $ map paramName $ lambdaParams lam
forM_ (zip xs aggrs) $ \(x, aggr) -> dPrimV_ x (tvExp aggr)
forM_ (zip ys prefixes) $ \(y, prefix) -> dPrimV_ y (tvExp prefix)
compileStms mempty (bodyStms $ lambdaBody lam) $
forM_ (zip3 prefixes tys $ map resSubExp $ bodyResult $ lambdaBody lam) $
\(prefix, ty, res) -> prefix <-- TPrimExp (toExp' ty res)
sOp local_fence
)
-- end sWhile
-- end sIf
sWhen (ltid32 .==. 0) $ do
scan_op2 <- renameLambda scan_op1
let xs = map paramName $ take (length tys) $ lambdaParams scan_op2
ys = map paramName $ drop (length tys) $ lambdaParams scan_op2
sWhen (boundary .==. sExt32 (group_size_e * chunk)) $ do
forM_ (zip xs prefixes) $ \(x, prefix) -> dPrimV_ x $ tvExp prefix
forM_ (zip ys accs) $ \(y, acc) -> dPrimV_ y $ tvExp acc
compileStms mempty (bodyStms $ lambdaBody scan_op2) $
everythingVolatile $
forM_ (zip incprefixArrays $ map resSubExp $ bodyResult $ lambdaBody scan_op2) $
\(incprefixArray, res) -> copyDWIMFix incprefixArray [tvExp dyn_id] res []
sOp global_fence
everythingVolatile $ copyDWIMFix statusFlags [tvExp dyn_id] (intConst Int8 statusP) []
forM_ (zip exchanges prefixes) $ \(exchange, prefix) ->
copyDWIMFix exchange [0] (tvSize prefix) []
forM_ (zip3 accs tys scanop_nes) $ \(acc, ty, ne) ->
tvVar acc <~~ toExp' ty ne
-- end sWhen
-- end sWhen
sWhen (bNot $ tvExp dyn_id .==. 0) $ do
sOp local_barrier
forM_ (zip exchanges prefixes) $ \(exchange, prefix) ->
copyDWIMFix (tvVar prefix) [] (Var exchange) [0]
sOp local_barrier
-- end sWhen
-- end sComment
scan_op3 <- renameLambda scan_op1
scan_op4 <- renameLambda scan_op1
sComment "Distribute results" $ do
let (xs, ys) = splitAt (length tys) $ map paramName $ lambdaParams scan_op3
(xs', ys') = splitAt (length tys) $ map paramName $ lambdaParams scan_op4
forM_ (zip7 prefixes accs xs xs' ys ys' tys) $
\(prefix, acc, x, x', y, y', ty) -> do
dPrim_ x ty
dPrim_ y ty
dPrimV_ x' $ tvExp prefix
dPrimV_ y' $ tvExp acc
sIf
(ltid32 * chunk32 .<. boundary .&&. bNot blockNewSgm)
( compileStms mempty (bodyStms $ lambdaBody scan_op4) $
forM_ (zip3 xs tys $ map resSubExp $ bodyResult $ lambdaBody scan_op4) $
\(x, ty, res) -> x <~~ toExp' ty res
)
(forM_ (zip xs accs) $ \(x, acc) -> copyDWIMFix x [] (Var $ tvVar acc) [])
-- calculate where previous thread stopped, to determine number of
-- elements left before new segment.
stop <-
dPrimVE "stopping_point" $
segsize_compact - (ltid32 * chunk32 - 1 + segsize_compact - boundary) `rem` segsize_compact
sFor "i" chunk $ \i -> do
sWhen (sExt32 i .<. stop - 1) $ do
forM_ (zip private_chunks ys) $ \(src, y) ->
-- only include prefix for the first segment part per thread
copyDWIMFix y [] (Var src) [i]
compileStms mempty (bodyStms $ lambdaBody scan_op3) $
forM_ (zip private_chunks $ map resSubExp $ bodyResult $ lambdaBody scan_op3) $
\(dest, res) ->
copyDWIMFix dest [i] res []
sComment "Transpose scan output and Write it to global memory in coalesced fashion" $ do
forM_ (zip3 transposedArrays private_chunks $ map patElemName all_pes) $ \(locmem, priv, dest) -> do
-- sOp local_barrier
sFor "i" chunk $ \i -> do
sharedIdx <-
dPrimV "sharedIdx" $
sExt64 (ltid * chunk) + i
copyDWIMFix locmem [tvExp sharedIdx] (Var priv) [i]
sOp local_barrier
sFor "i" chunk $ \i -> do
flat_idx <- dPrimVE "flat_idx" $ thd_offset + i * group_size_e
dIndexSpace (zip gtids dims') flat_idx
sWhen (flat_idx .<. n) $ do
copyDWIMFix
dest
(map Imp.le64 gtids)
(Var locmem)
[sExt64 $ flat_idx - block_offset]
sOp local_barrier
{-# NOINLINE compileSegScan #-}