futhark-0.25.6: src/Futhark/CodeGen/Backends/GenericPython.hs
-- | A generic Python code generator which is polymorphic in the type
-- of the operations. Concretely, we use this to handle both
-- sequential and PyOpenCL Python code.
module Futhark.CodeGen.Backends.GenericPython
( compileProg,
CompilerMode,
Constructor (..),
emptyConstructor,
compileName,
compileVar,
compileDim,
compileExp,
compilePrimExp,
compileCode,
compilePrimValue,
compilePrimType,
compilePrimTypeExt,
compilePrimToNp,
compilePrimToExtNp,
fromStorage,
toStorage,
Operations (..),
DoLMADCopy,
defaultOperations,
unpackDim,
CompilerM (..),
OpCompiler,
WriteScalar,
ReadScalar,
Allocate,
Copy,
EntryOutput,
EntryInput,
CompilerEnv (..),
CompilerState (..),
stm,
atInit,
collect',
collect,
simpleCall,
)
where
import Control.Monad
import Control.Monad.RWS hiding (reader, writer)
import Data.Char (isAlpha, isAlphaNum)
import Data.Map qualified as M
import Data.Maybe
import Data.Text qualified as T
import Futhark.CodeGen.Backends.GenericPython.AST
import Futhark.CodeGen.Backends.GenericPython.Options
import Futhark.CodeGen.ImpCode (Count (..), Elements, TExp, elements, le64, untyped)
import Futhark.CodeGen.ImpCode qualified as Imp
import Futhark.CodeGen.RTS.Python
import Futhark.Compiler.Config (CompilerMode (..))
import Futhark.IR.Prop (isBuiltInFunction, subExpVars)
import Futhark.IR.Syntax.Core (Space (..))
import Futhark.MonadFreshNames
import Futhark.Util (zEncodeText)
import Futhark.Util.Pretty (prettyString, prettyText)
import Language.Futhark.Primitive hiding (Bool)
-- | A substitute expression compiler, tried before the main
-- compilation function.
type OpCompiler op s = op -> CompilerM op s ()
-- | Write a scalar to the given memory block with the given index and
-- in the given memory space.
type WriteScalar op s =
PyExp ->
PyExp ->
PrimType ->
Imp.SpaceId ->
PyExp ->
CompilerM op s ()
-- | Read a scalar from the given memory block with the given index and
-- in the given memory space.
type ReadScalar op s =
PyExp ->
PyExp ->
PrimType ->
Imp.SpaceId ->
CompilerM op s PyExp
-- | Allocate a memory block of the given size in the given memory
-- space, saving a reference in the given variable name.
type Allocate op s =
PyExp ->
PyExp ->
Imp.SpaceId ->
CompilerM op s ()
-- | Copy from one memory block to another.
type Copy op s =
PyExp ->
PyExp ->
Imp.Space ->
PyExp ->
PyExp ->
Imp.Space ->
PyExp ->
PrimType ->
CompilerM op s ()
-- | Perform an 'Imp.LMADCopy'. It is expected that these functions
-- are each specialised on which spaces they operate on, so that is
-- not part of their arguments.
type DoLMADCopy op s =
PrimType ->
[Count Elements PyExp] ->
PyExp ->
( Count Elements PyExp,
[Count Elements PyExp]
) ->
PyExp ->
( Count Elements PyExp,
[Count Elements PyExp]
) ->
CompilerM op s ()
-- | Construct the Python array being returned from an entry point.
type EntryOutput op s =
VName ->
Imp.SpaceId ->
PrimType ->
Imp.Signedness ->
[Imp.DimSize] ->
CompilerM op s PyExp
-- | Unpack the array being passed to an entry point.
type EntryInput op s =
PyExp ->
Imp.SpaceId ->
PrimType ->
Imp.Signedness ->
[Imp.DimSize] ->
PyExp ->
CompilerM op s ()
data Operations op s = Operations
{ opsWriteScalar :: WriteScalar op s,
opsReadScalar :: ReadScalar op s,
opsAllocate :: Allocate op s,
-- | @(dst,src)@-space mapping to copy functions.
opsCopies :: M.Map (Space, Space) (DoLMADCopy op s),
opsCompiler :: OpCompiler op s,
opsEntryOutput :: EntryOutput op s,
opsEntryInput :: EntryInput op s
}
-- | A set of operations that fail for every operation involving
-- non-default memory spaces. Uses plain pointers and @malloc@ for
-- memory management.
defaultOperations :: Operations op s
defaultOperations =
Operations
{ opsWriteScalar = defWriteScalar,
opsReadScalar = defReadScalar,
opsAllocate = defAllocate,
opsCopies = M.singleton (DefaultSpace, DefaultSpace) lmadcopyCPU,
opsCompiler = defCompiler,
opsEntryOutput = defEntryOutput,
opsEntryInput = defEntryInput
}
where
defWriteScalar _ _ _ _ _ =
error "Cannot write to non-default memory space because I am dumb"
defReadScalar _ _ _ _ =
error "Cannot read from non-default memory space"
defAllocate _ _ _ =
error "Cannot allocate in non-default memory space"
defCompiler _ =
error "The default compiler cannot compile extended operations"
defEntryOutput _ _ _ _ =
error "Cannot return array not in default memory space"
defEntryInput _ _ _ _ =
error "Cannot accept array not in default memory space"
data CompilerEnv op s = CompilerEnv
{ envOperations :: Operations op s,
envVarExp :: M.Map String PyExp
}
envOpCompiler :: CompilerEnv op s -> OpCompiler op s
envOpCompiler = opsCompiler . envOperations
envReadScalar :: CompilerEnv op s -> ReadScalar op s
envReadScalar = opsReadScalar . envOperations
envWriteScalar :: CompilerEnv op s -> WriteScalar op s
envWriteScalar = opsWriteScalar . envOperations
envAllocate :: CompilerEnv op s -> Allocate op s
envAllocate = opsAllocate . envOperations
envEntryOutput :: CompilerEnv op s -> EntryOutput op s
envEntryOutput = opsEntryOutput . envOperations
envEntryInput :: CompilerEnv op s -> EntryInput op s
envEntryInput = opsEntryInput . envOperations
newCompilerEnv :: Operations op s -> CompilerEnv op s
newCompilerEnv ops =
CompilerEnv
{ envOperations = ops,
envVarExp = mempty
}
data CompilerState s = CompilerState
{ compNameSrc :: VNameSource,
compInit :: [PyStmt],
compUserState :: s
}
newCompilerState :: VNameSource -> s -> CompilerState s
newCompilerState src s =
CompilerState
{ compNameSrc = src,
compInit = [],
compUserState = s
}
newtype CompilerM op s a = CompilerM (RWS (CompilerEnv op s) [PyStmt] (CompilerState s) a)
deriving
( Functor,
Applicative,
Monad,
MonadState (CompilerState s),
MonadReader (CompilerEnv op s),
MonadWriter [PyStmt]
)
instance MonadFreshNames (CompilerM op s) where
getNameSource = gets compNameSrc
putNameSource src = modify $ \s -> s {compNameSrc = src}
collect :: CompilerM op s () -> CompilerM op s [PyStmt]
collect m = pass $ do
((), w) <- listen m
pure (w, const mempty)
collect' :: CompilerM op s a -> CompilerM op s (a, [PyStmt])
collect' m = pass $ do
(x, w) <- listen m
pure ((x, w), const mempty)
atInit :: PyStmt -> CompilerM op s ()
atInit x = modify $ \s ->
s {compInit = compInit s ++ [x]}
stm :: PyStmt -> CompilerM op s ()
stm x = tell [x]
futharkFun :: T.Text -> T.Text
futharkFun s = "futhark_" <> zEncodeText s
compileOutput :: [Imp.Param] -> [PyExp]
compileOutput = map (Var . compileName . Imp.paramName)
runCompilerM ::
Operations op s ->
VNameSource ->
s ->
CompilerM op s a ->
a
runCompilerM ops src userstate (CompilerM m) =
fst $ evalRWS m (newCompilerEnv ops) (newCompilerState src userstate)
standardOptions :: [Option]
standardOptions =
[ Option
{ optionLongName = "tuning",
optionShortName = Nothing,
optionArgument = RequiredArgument "open",
optionAction = [Exp $ simpleCall "read_tuning_file" [Var "sizes", Var "optarg"]]
},
-- Does not actually do anything for Python backends.
Option
{ optionLongName = "cache-file",
optionShortName = Nothing,
optionArgument = RequiredArgument "str",
optionAction = [Pass]
},
Option
{ optionLongName = "log",
optionShortName = Just 'L',
optionArgument = NoArgument,
optionAction = [Pass]
}
]
executableOptions :: [Option]
executableOptions =
standardOptions
++ [ Option
{ optionLongName = "write-runtime-to",
optionShortName = Just 't',
optionArgument = RequiredArgument "str",
optionAction =
[ If
(Var "runtime_file")
[Exp $ simpleCall "runtime_file.close" []]
[],
Assign (Var "runtime_file") $
simpleCall "open" [Var "optarg", String "w"]
]
},
Option
{ optionLongName = "runs",
optionShortName = Just 'r',
optionArgument = RequiredArgument "str",
optionAction =
[ Assign (Var "num_runs") $ Var "optarg",
Assign (Var "do_warmup_run") $ Bool True
]
},
Option
{ optionLongName = "entry-point",
optionShortName = Just 'e',
optionArgument = RequiredArgument "str",
optionAction =
[Assign (Var "entry_point") $ Var "optarg"]
},
Option
{ optionLongName = "binary-output",
optionShortName = Just 'b',
optionArgument = NoArgument,
optionAction = [Assign (Var "binary_output") $ Bool True]
}
]
functionExternalValues :: Imp.EntryPoint -> [Imp.ExternalValue]
functionExternalValues entry =
map snd (Imp.entryPointResults entry) ++ map snd (Imp.entryPointArgs entry)
-- | Is this name a valid Python identifier? If not, it should be escaped
-- before being emitted.
isValidPyName :: T.Text -> Bool
isValidPyName = maybe True check . T.uncons
where
check (c, cs) = isAlpha c && T.all constituent cs
constituent c = isAlphaNum c || c == '_'
-- | If the provided text is a valid identifier, then return it
-- verbatim. Otherwise, escape it such that it becomes valid.
escapeName :: Name -> T.Text
escapeName v
| isValidPyName v' = v'
| otherwise = zEncodeText v'
where
v' = nameToText v
opaqueDefs :: Imp.Functions a -> M.Map T.Text [PyExp]
opaqueDefs (Imp.Functions funs) =
mconcat
. map evd
. concatMap functionExternalValues
. mapMaybe (Imp.functionEntry . snd)
$ funs
where
evd Imp.TransparentValue {} = mempty
evd (Imp.OpaqueValue name vds) = M.singleton (nameToText name) $ map (String . vd) vds
vd (Imp.ScalarValue pt s _) =
readTypeEnum pt s
vd (Imp.ArrayValue _ _ pt s dims) =
mconcat (replicate (length dims) "[]") <> readTypeEnum pt s
-- | The class generated by the code generator must have a
-- constructor, although it can be vacuous.
data Constructor = Constructor [String] [PyStmt]
-- | A constructor that takes no arguments and does nothing.
emptyConstructor :: Constructor
emptyConstructor = Constructor ["self"] [Pass]
constructorToFunDef :: Constructor -> [PyStmt] -> PyFunDef
constructorToFunDef (Constructor params body) at_init =
Def "__init__" params $ body <> at_init
compileProg ::
(MonadFreshNames m) =>
CompilerMode ->
String ->
Constructor ->
[PyStmt] ->
[PyStmt] ->
Operations op s ->
s ->
[PyStmt] ->
[Option] ->
Imp.Definitions op ->
m T.Text
compileProg mode class_name constructor imports defines ops userstate sync options prog = do
src <- getNameSource
let prog' = runCompilerM ops src userstate compileProg'
pure . prettyText . PyProg $
imports
++ [ Import "argparse" Nothing,
Assign (Var "sizes") $ Dict []
]
++ defines
++ [ Escape valuesPy,
Escape memoryPy,
Escape panicPy,
Escape tuningPy,
Escape scalarPy,
Escape serverPy
]
++ prog'
where
Imp.Definitions _types consts (Imp.Functions funs) = prog
compileProg' = withConstantSubsts consts $ do
compileConstants consts
definitions <- mapM compileFunc funs
at_inits <- gets compInit
let constructor' = constructorToFunDef constructor at_inits
case mode of
ToLibrary -> do
(entry_points, entry_point_types) <-
unzip . catMaybes <$> mapM (compileEntryFun sync DoNotReturnTiming) funs
pure
[ ClassDef $
Class class_name $
Assign (Var "entry_points") (Dict entry_point_types)
: Assign
(Var "opaques")
(Dict $ zip (map String opaque_names) (map Tuple opaque_payloads))
: map FunDef (constructor' : definitions ++ entry_points)
]
ToServer -> do
(entry_points, entry_point_types) <-
unzip . catMaybes <$> mapM (compileEntryFun sync ReturnTiming) funs
pure $
parse_options_server
++ [ ClassDef
( Class class_name $
Assign (Var "entry_points") (Dict entry_point_types)
: Assign
(Var "opaques")
(Dict $ zip (map String opaque_names) (map Tuple opaque_payloads))
: map FunDef (constructor' : definitions ++ entry_points)
),
Assign
(Var "server")
(simpleCall "Server" [simpleCall class_name []]),
Exp $ simpleCall "server.run" []
]
ToExecutable -> do
let classinst = Assign (Var "self") $ simpleCall class_name []
(entry_point_defs, entry_point_names, entry_points) <-
unzip3 . catMaybes <$> mapM (callEntryFun sync) funs
pure $
parse_options_executable
++ ClassDef
( Class class_name $
map FunDef $
constructor' : definitions
)
: classinst
: map FunDef entry_point_defs
++ selectEntryPoint entry_point_names entry_points
parse_options_executable =
Assign (Var "runtime_file") None
: Assign (Var "do_warmup_run") (Bool False)
: Assign (Var "num_runs") (Integer 1)
: Assign (Var "entry_point") (String "main")
: Assign (Var "binary_output") (Bool False)
: generateOptionParser (executableOptions ++ options)
parse_options_server =
generateOptionParser (standardOptions ++ options)
(opaque_names, opaque_payloads) =
unzip $ M.toList $ opaqueDefs $ Imp.defFuns prog
selectEntryPoint entry_point_names entry_points =
[ Assign (Var "entry_points") $
Dict $
zip (map String entry_point_names) entry_points,
Assign (Var "entry_point_fun") $
simpleCall "entry_points.get" [Var "entry_point"],
If
(BinOp "==" (Var "entry_point_fun") None)
[ Exp $
simpleCall
"sys.exit"
[ Call
( Field
(String "No entry point '{}'. Select another with --entry point. Options are:\n{}")
"format"
)
[ Arg $ Var "entry_point",
Arg $
Call
(Field (String "\n") "join")
[Arg $ simpleCall "entry_points.keys" []]
]
]
]
[Exp $ simpleCall "entry_point_fun" []]
]
withConstantSubsts :: Imp.Constants op -> CompilerM op s a -> CompilerM op s a
withConstantSubsts (Imp.Constants ps _) =
local $ \env -> env {envVarExp = foldMap constExp ps}
where
constExp p =
M.singleton
(compileName $ Imp.paramName p)
(Index (Var "self.constants") $ IdxExp $ String $ prettyText $ Imp.paramName p)
compileConstants :: Imp.Constants op -> CompilerM op s ()
compileConstants (Imp.Constants _ init_consts) = do
atInit $ Assign (Var "self.constants") $ Dict []
mapM_ atInit =<< collect (compileCode init_consts)
compileFunc :: (Name, Imp.Function op) -> CompilerM op s PyFunDef
compileFunc (fname, Imp.Function _ outputs inputs body) = do
body' <- collect $ compileCode body
let inputs' = map (compileName . Imp.paramName) inputs
let ret = Return $ tupleOrSingle $ compileOutput outputs
pure $
Def (T.unpack $ futharkFun $ nameToText fname) ("self" : inputs') $
body' ++ [ret]
tupleOrSingle :: [PyExp] -> PyExp
tupleOrSingle [e] = e
tupleOrSingle es = Tuple es
-- | A 'Call' where the function is a variable and every argument is a
-- simple 'Arg'.
simpleCall :: String -> [PyExp] -> PyExp
simpleCall fname = Call (Var fname) . map Arg
compileName :: VName -> String
compileName = T.unpack . zEncodeText . prettyText
compileDim :: Imp.DimSize -> CompilerM op s PyExp
compileDim (Imp.Constant v) = pure $ compilePrimValue v
compileDim (Imp.Var v) = compileVar v
unpackDim :: PyExp -> Imp.DimSize -> Int32 -> CompilerM op s ()
unpackDim arr_name (Imp.Constant c) i = do
let shape_name = Field arr_name "shape"
let constant_c = compilePrimValue c
let constant_i = Integer $ toInteger i
stm $
Assert (BinOp "==" constant_c (Index shape_name $ IdxExp constant_i)) $
String "Entry point arguments have invalid sizes."
unpackDim arr_name (Imp.Var var) i = do
let shape_name = Field arr_name "shape"
src = Index shape_name $ IdxExp $ Integer $ toInteger i
var' <- compileVar var
stm $
If
(BinOp "==" var' None)
[Assign var' $ simpleCall "np.int64" [src]]
[ Assert (BinOp "==" var' src) $
String "Error: entry point arguments have invalid sizes."
]
entryPointOutput :: Imp.ExternalValue -> CompilerM op s PyExp
entryPointOutput (Imp.OpaqueValue desc vs) =
simpleCall "opaque" . (String (prettyText desc) :)
<$> mapM (entryPointOutput . Imp.TransparentValue) vs
entryPointOutput (Imp.TransparentValue (Imp.ScalarValue bt ept name)) = do
name' <- compileVar name
pure $ simpleCall tf [name']
where
tf = compilePrimToExtNp bt ept
entryPointOutput (Imp.TransparentValue (Imp.ArrayValue mem (Imp.Space sid) bt ept dims)) = do
pack_output <- asks envEntryOutput
pack_output mem sid bt ept dims
entryPointOutput (Imp.TransparentValue (Imp.ArrayValue mem _ bt ept dims)) = do
mem' <- compileVar mem
dims' <- mapM compileDim dims
pure $
simpleCall
"np.reshape"
[ Index
(Call (Field mem' "view") [Arg $ Var $ compilePrimToExtNp bt ept])
(IdxRange (Integer 0) (foldl1 (BinOp "*") dims')),
Tuple dims'
]
badInput :: Int -> PyExp -> T.Text -> PyStmt
badInput i e t =
Raise $
simpleCall
"TypeError"
[ Call
(Field (String err_msg) "format")
[Arg (String t), Arg $ simpleCall "type" [e], Arg e]
]
where
err_msg =
T.unlines
[ "Argument #" <> prettyText i <> " has invalid value",
"Futhark type: {}",
"Argument has Python type {} and value: {}"
]
badInputType :: Int -> PyExp -> T.Text -> PyExp -> PyExp -> PyStmt
badInputType i e t de dg =
Raise $
simpleCall
"TypeError"
[ Call
(Field (String err_msg) "format")
[Arg (String t), Arg $ simpleCall "type" [e], Arg e, Arg de, Arg dg]
]
where
err_msg =
T.unlines
[ "Argument #" <> prettyText i <> " has invalid value",
"Futhark type: {}",
"Argument has Python type {} and value: {}",
"Expected array with elements of dtype: {}",
"The array given has elements of dtype: {}"
]
badInputDim :: Int -> PyExp -> T.Text -> Int -> PyStmt
badInputDim i e typ dimf =
Raise $
simpleCall
"TypeError"
[ Call
(Field (String err_msg) "format")
[Arg eft, Arg aft]
]
where
eft = String (mconcat (replicate dimf "[]") <> typ)
aft = BinOp "+" (BinOp "*" (String "[]") (Field e "ndim")) (String typ)
err_msg =
T.unlines
[ "Argument #" <> prettyText i <> " has invalid value",
"Dimensionality mismatch",
"Expected Futhark type: {}",
"Bad Python value passed",
"Actual Futhark type: {}"
]
declEntryPointInputSizes :: [Imp.ExternalValue] -> CompilerM op s ()
declEntryPointInputSizes = mapM_ onSize . concatMap sizes
where
sizes (Imp.TransparentValue v) = valueSizes v
sizes (Imp.OpaqueValue _ vs) = concatMap valueSizes vs
valueSizes (Imp.ArrayValue _ _ _ _ dims) = subExpVars dims
valueSizes Imp.ScalarValue {} = []
onSize v = stm $ Assign (Var (compileName v)) None
entryPointInput :: (Int, Imp.ExternalValue, PyExp) -> CompilerM op s ()
entryPointInput (i, Imp.OpaqueValue desc vs, e) = do
let type_is_ok =
BinOp
"and"
(simpleCall "isinstance" [e, Var "opaque"])
(BinOp "==" (Field e "desc") (String (nameToText desc)))
stm $ If (UnOp "not" type_is_ok) [badInput i e (nameToText desc)] []
mapM_ entryPointInput $
zip3 (repeat i) (map Imp.TransparentValue vs) $
map (Index (Field e "data") . IdxExp . Integer) [0 ..]
entryPointInput (i, Imp.TransparentValue (Imp.ScalarValue bt s name), e) = do
vname' <- compileVar name
let -- HACK: A Numpy int64 will signal an OverflowError if we pass
-- it a number bigger than 2**63. This does not happen if we
-- pass e.g. int8 a number bigger than 2**7. As a workaround,
-- we first go through the corresponding ctypes type, which does
-- not have this problem.
ctobject = compilePrimType bt
npobject = compilePrimToNp bt
npcall =
simpleCall
npobject
[ case bt of
IntType Int64 -> simpleCall ctobject [e]
_ -> e
]
stm $
Try
[Assign vname' npcall]
[ Catch
(Tuple [Var "TypeError", Var "AssertionError"])
[badInput i e $ prettySigned (s == Imp.Unsigned) bt]
]
entryPointInput (i, Imp.TransparentValue (Imp.ArrayValue mem (Imp.Space sid) bt ept dims), e) = do
unpack_input <- asks envEntryInput
mem' <- compileVar mem
unpack <- collect $ unpack_input mem' sid bt ept dims e
stm $
Try
unpack
[ Catch
(Tuple [Var "TypeError", Var "AssertionError"])
[ badInput i e $
mconcat (replicate (length dims) "[]")
<> prettySigned (ept == Imp.Unsigned) bt
]
]
entryPointInput (i, Imp.TransparentValue (Imp.ArrayValue mem _ t s dims), e) = do
let type_is_wrong = UnOp "not" $ BinOp "in" (simpleCall "type" [e]) $ List [Var "np.ndarray"]
let dtype_is_wrong = UnOp "not" $ BinOp "==" (Field e "dtype") $ Var $ compilePrimToExtNp t s
let dim_is_wrong = UnOp "not" $ BinOp "==" (Field e "ndim") $ Integer $ toInteger $ length dims
stm $
If
type_is_wrong
[ badInput i e $
mconcat (replicate (length dims) "[]")
<> prettySigned (s == Imp.Unsigned) t
]
[]
stm $
If
dtype_is_wrong
[ badInputType
i
e
(mconcat (replicate (length dims) "[]") <> prettySigned (s == Imp.Unsigned) t)
(simpleCall "np.dtype" [Var (compilePrimToExtNp t s)])
(Field e "dtype")
]
[]
stm $
If
dim_is_wrong
[badInputDim i e (prettySigned (s == Imp.Unsigned) t) (length dims)]
[]
zipWithM_ (unpackDim e) dims [0 ..]
dest <- compileVar mem
let unwrap_call = simpleCall "unwrapArray" [e]
stm $ Assign dest unwrap_call
extValueDescName :: Imp.ExternalValue -> T.Text
extValueDescName (Imp.TransparentValue v) = extName $ T.pack $ compileName $ valueDescVName v
extValueDescName (Imp.OpaqueValue desc []) = extName $ zEncodeText $ nameToText desc
extValueDescName (Imp.OpaqueValue desc (v : _)) =
extName $ zEncodeText (nameToText desc) <> "_" <> prettyText (baseTag (valueDescVName v))
extName :: T.Text -> T.Text
extName = (<> "_ext")
valueDescVName :: Imp.ValueDesc -> VName
valueDescVName (Imp.ScalarValue _ _ vname) = vname
valueDescVName (Imp.ArrayValue vname _ _ _ _) = vname
-- Key into the FUTHARK_PRIMTYPES dict.
readTypeEnum :: PrimType -> Imp.Signedness -> T.Text
readTypeEnum (IntType Int8) Imp.Unsigned = "u8"
readTypeEnum (IntType Int16) Imp.Unsigned = "u16"
readTypeEnum (IntType Int32) Imp.Unsigned = "u32"
readTypeEnum (IntType Int64) Imp.Unsigned = "u64"
readTypeEnum (IntType Int8) Imp.Signed = "i8"
readTypeEnum (IntType Int16) Imp.Signed = "i16"
readTypeEnum (IntType Int32) Imp.Signed = "i32"
readTypeEnum (IntType Int64) Imp.Signed = "i64"
readTypeEnum (FloatType Float16) _ = "f16"
readTypeEnum (FloatType Float32) _ = "f32"
readTypeEnum (FloatType Float64) _ = "f64"
readTypeEnum Imp.Bool _ = "bool"
readTypeEnum Unit _ = "bool"
readInput :: Imp.ExternalValue -> PyStmt
readInput (Imp.OpaqueValue desc _) =
Raise $
simpleCall
"Exception"
[String $ "Cannot read argument of type " <> nameToText desc <> "."]
readInput decl@(Imp.TransparentValue (Imp.ScalarValue bt ept _)) =
let type_name = readTypeEnum bt ept
in Assign (Var $ T.unpack $ extValueDescName decl) $ simpleCall "read_value" [String type_name]
readInput decl@(Imp.TransparentValue (Imp.ArrayValue _ _ bt ept dims)) =
let type_name = readTypeEnum bt ept
in Assign (Var $ T.unpack $ extValueDescName decl) $
simpleCall
"read_value"
[String $ mconcat (replicate (length dims) "[]") <> type_name]
printValue :: [(Imp.ExternalValue, PyExp)] -> CompilerM op s [PyStmt]
printValue = fmap concat . mapM (uncurry printValue')
where
-- We copy non-host arrays to the host before printing. This is
-- done in a hacky way - we assume the value has a .get()-method
-- that returns an equivalent Numpy array. This works for PyOpenCL,
-- but we will probably need yet another plugin mechanism here in
-- the future.
printValue' (Imp.OpaqueValue desc _) _ =
pure
[ Exp $
simpleCall
"sys.stdout.write"
[String $ "#<opaque " <> nameToText desc <> ">"]
]
printValue' (Imp.TransparentValue (Imp.ArrayValue mem (Space _) bt ept shape)) e =
printValue' (Imp.TransparentValue (Imp.ArrayValue mem DefaultSpace bt ept shape)) $
simpleCall (prettyString e ++ ".get") []
printValue' (Imp.TransparentValue _) e =
pure
[ Exp $
Call
(Var "write_value")
[ Arg e,
ArgKeyword "binary" (Var "binary_output")
],
Exp $ simpleCall "sys.stdout.write" [String "\n"]
]
prepareEntry ::
Imp.EntryPoint ->
(Name, Imp.Function op) ->
CompilerM
op
s
( [String],
[PyStmt],
[PyStmt],
[PyStmt],
[(Imp.ExternalValue, PyExp)]
)
prepareEntry (Imp.EntryPoint _ results args) (fname, Imp.Function _ outputs inputs _) = do
let output_paramNames = map (compileName . Imp.paramName) outputs
funTuple = tupleOrSingle $ fmap Var output_paramNames
prepareIn <- collect $ do
declEntryPointInputSizes $ map snd args
mapM_ entryPointInput . zip3 [0 ..] (map snd args) $
map (Var . T.unpack . extValueDescName . snd) args
(res, prepareOut) <- collect' $ mapM (entryPointOutput . snd) results
let argexps_lib = map (compileName . Imp.paramName) inputs
fname' = "self." <> futharkFun (nameToText fname)
-- We ignore overflow errors and the like for executable entry
-- points. These are (somewhat) well-defined in Futhark.
ignore s = ArgKeyword s $ String "ignore"
errstate = Call (Var "np.errstate") $ map ignore ["divide", "over", "under", "invalid"]
call argexps =
[ With
errstate
[Assign funTuple $ simpleCall (T.unpack fname') (fmap Var argexps)]
]
pure
( map (T.unpack . extValueDescName . snd) args,
prepareIn,
call argexps_lib,
prepareOut,
zip (map snd results) res
)
data ReturnTiming = ReturnTiming | DoNotReturnTiming
compileEntryFun ::
[PyStmt] ->
ReturnTiming ->
(Name, Imp.Function op) ->
CompilerM op s (Maybe (PyFunDef, (PyExp, PyExp)))
compileEntryFun sync timing fun
| Just entry <- Imp.functionEntry $ snd fun = do
let ename = Imp.entryPointName entry
(params, prepareIn, body_lib, prepareOut, res) <- prepareEntry entry fun
let (maybe_sync, ret) =
case timing of
DoNotReturnTiming ->
( [],
Return $ tupleOrSingle $ map snd res
)
ReturnTiming ->
( sync,
Return $
Tuple
[ Var "runtime",
tupleOrSingle $ map snd res
]
)
(pts, rts) = entryTypes entry
do_run =
Assign (Var "time_start") (simpleCall "time.time" [])
: body_lib
++ maybe_sync
++ [ Assign (Var "runtime") $
BinOp
"-"
(toMicroseconds (simpleCall "time.time" []))
(toMicroseconds (Var "time_start"))
]
pure $
Just
( Def (T.unpack (escapeName ename)) ("self" : params) $
prepareIn ++ do_run ++ prepareOut ++ sync ++ [ret],
( String (nameToText ename),
Tuple
[ String (escapeName ename),
List (map String pts),
List (map String rts)
]
)
)
| otherwise = pure Nothing
entryTypes :: Imp.EntryPoint -> ([T.Text], [T.Text])
entryTypes (Imp.EntryPoint _ res args) =
(map descArg args, map desc res)
where
descArg ((_, u), d) = desc (u, d)
desc (u, Imp.OpaqueValue d _) = prettyText u <> nameToText d
desc (u, Imp.TransparentValue (Imp.ScalarValue pt s _)) = prettyText u <> readTypeEnum pt s
desc (u, Imp.TransparentValue (Imp.ArrayValue _ _ pt s dims)) =
prettyText u <> mconcat (replicate (length dims) "[]") <> readTypeEnum pt s
callEntryFun ::
[PyStmt] ->
(Name, Imp.Function op) ->
CompilerM op s (Maybe (PyFunDef, T.Text, PyExp))
callEntryFun _ (_, Imp.Function Nothing _ _ _) = pure Nothing
callEntryFun pre_timing fun@(fname, Imp.Function (Just entry) _ _ _) = do
let Imp.EntryPoint ename _ decl_args = entry
(_, prepare_in, body_bin, _, res) <- prepareEntry entry fun
let str_input = map (readInput . snd) decl_args
end_of_input = [Exp $ simpleCall "end_of_input" [String $ prettyText fname]]
exitcall = [Exp $ simpleCall "sys.exit" [Field (String "Assertion.{} failed") "format(e)"]]
except' = Catch (Var "AssertionError") exitcall
do_run = body_bin ++ pre_timing
(do_run_with_timing, close_runtime_file) = addTiming do_run
do_warmup_run =
If (Var "do_warmup_run") do_run []
do_num_runs =
For
"i"
(simpleCall "range" [simpleCall "int" [Var "num_runs"]])
do_run_with_timing
str_output <- printValue res
let fname' = "entry_" ++ T.unpack (escapeName fname)
pure $
Just
( Def fname' [] $
str_input
++ end_of_input
++ prepare_in
++ [Try [do_warmup_run, do_num_runs] [except']]
++ [close_runtime_file]
++ str_output,
nameToText ename,
Var fname'
)
addTiming :: [PyStmt] -> ([PyStmt], PyStmt)
addTiming statements =
( [Assign (Var "time_start") $ simpleCall "time.time" []]
++ statements
++ [ Assign (Var "time_end") $ simpleCall "time.time" [],
If (Var "runtime_file") print_runtime []
],
If (Var "runtime_file") [Exp $ simpleCall "runtime_file.close" []] []
)
where
print_runtime =
[ Exp $
simpleCall
"runtime_file.write"
[ simpleCall
"str"
[ BinOp
"-"
(toMicroseconds (Var "time_end"))
(toMicroseconds (Var "time_start"))
]
],
Exp $ simpleCall "runtime_file.write" [String "\n"],
Exp $ simpleCall "runtime_file.flush" []
]
toMicroseconds :: PyExp -> PyExp
toMicroseconds x =
simpleCall "int" [BinOp "*" x $ Integer 1000000]
compileUnOp :: Imp.UnOp -> String
compileUnOp op =
case op of
Not -> "not"
Complement {} -> "~"
Abs {} -> "abs"
FAbs {} -> "abs"
SSignum {} -> "ssignum"
USignum {} -> "usignum"
FSignum {} -> "np.sign"
compileBinOpLike ::
(Monad m) =>
(v -> m PyExp) ->
Imp.PrimExp v ->
Imp.PrimExp v ->
m (PyExp, PyExp, String -> m PyExp)
compileBinOpLike f x y = do
x' <- compilePrimExp f x
y' <- compilePrimExp f y
let simple s = pure $ BinOp s x' y'
pure (x', y', simple)
-- | The ctypes type corresponding to a 'PrimType'.
compilePrimType :: PrimType -> String
compilePrimType t =
case t of
IntType Int8 -> "ct.c_int8"
IntType Int16 -> "ct.c_int16"
IntType Int32 -> "ct.c_int32"
IntType Int64 -> "ct.c_int64"
FloatType Float16 -> "ct.c_uint16"
FloatType Float32 -> "ct.c_float"
FloatType Float64 -> "ct.c_double"
Imp.Bool -> "ct.c_bool"
Unit -> "ct.c_bool"
-- | The ctypes type corresponding to a 'PrimType', taking sign into account.
compilePrimTypeExt :: PrimType -> Imp.Signedness -> String
compilePrimTypeExt t ept =
case (t, ept) of
(IntType Int8, Imp.Unsigned) -> "ct.c_uint8"
(IntType Int16, Imp.Unsigned) -> "ct.c_uint16"
(IntType Int32, Imp.Unsigned) -> "ct.c_uint32"
(IntType Int64, Imp.Unsigned) -> "ct.c_uint64"
(IntType Int8, _) -> "ct.c_int8"
(IntType Int16, _) -> "ct.c_int16"
(IntType Int32, _) -> "ct.c_int32"
(IntType Int64, _) -> "ct.c_int64"
(FloatType Float16, _) -> "ct.c_uint16"
(FloatType Float32, _) -> "ct.c_float"
(FloatType Float64, _) -> "ct.c_double"
(Imp.Bool, _) -> "ct.c_bool"
(Unit, _) -> "ct.c_byte"
-- | The Numpy type corresponding to a 'PrimType'.
compilePrimToNp :: Imp.PrimType -> String
compilePrimToNp bt =
case bt of
IntType Int8 -> "np.int8"
IntType Int16 -> "np.int16"
IntType Int32 -> "np.int32"
IntType Int64 -> "np.int64"
FloatType Float16 -> "np.float16"
FloatType Float32 -> "np.float32"
FloatType Float64 -> "np.float64"
Imp.Bool -> "np.byte"
Unit -> "np.byte"
-- | The Numpy type corresponding to a 'PrimType', taking sign into account.
compilePrimToExtNp :: Imp.PrimType -> Imp.Signedness -> String
compilePrimToExtNp bt ept =
case (bt, ept) of
(IntType Int8, Imp.Unsigned) -> "np.uint8"
(IntType Int16, Imp.Unsigned) -> "np.uint16"
(IntType Int32, Imp.Unsigned) -> "np.uint32"
(IntType Int64, Imp.Unsigned) -> "np.uint64"
(IntType Int8, _) -> "np.int8"
(IntType Int16, _) -> "np.int16"
(IntType Int32, _) -> "np.int32"
(IntType Int64, _) -> "np.int64"
(FloatType Float16, _) -> "np.float16"
(FloatType Float32, _) -> "np.float32"
(FloatType Float64, _) -> "np.float64"
(Imp.Bool, _) -> "np.bool_"
(Unit, _) -> "np.byte"
-- | Convert from scalar to storage representation for the given type.
toStorage :: PrimType -> PyExp -> PyExp
toStorage (FloatType Float16) e =
simpleCall "ct.c_int16" [simpleCall "futhark_to_bits16" [e]]
toStorage t e = simpleCall (compilePrimType t) [e]
-- | Convert from storage to scalar representation for the given type.
fromStorage :: PrimType -> PyExp -> PyExp
fromStorage (FloatType Float16) e =
simpleCall "futhark_from_bits16" [simpleCall "np.int16" [e]]
fromStorage t e = simpleCall (compilePrimToNp t) [e]
compilePrimValue :: Imp.PrimValue -> PyExp
compilePrimValue (IntValue (Int8Value v)) =
simpleCall "np.int8" [Integer $ toInteger v]
compilePrimValue (IntValue (Int16Value v)) =
simpleCall "np.int16" [Integer $ toInteger v]
compilePrimValue (IntValue (Int32Value v)) =
simpleCall "np.int32" [Integer $ toInteger v]
compilePrimValue (IntValue (Int64Value v)) =
simpleCall "np.int64" [Integer $ toInteger v]
compilePrimValue (FloatValue (Float16Value v))
| isInfinite v =
if v > 0 then Var "np.float16(np.inf)" else Var "np.float16(-np.inf)"
| isNaN v =
Var "np.float16(np.nan)"
| otherwise = simpleCall "np.float16" [Float $ fromRational $ toRational v]
compilePrimValue (FloatValue (Float32Value v))
| isInfinite v =
if v > 0 then Var "np.float32(np.inf)" else Var "np.float32(-np.inf)"
| isNaN v =
Var "np.float32(np.nan)"
| otherwise = simpleCall "np.float32" [Float $ fromRational $ toRational v]
compilePrimValue (FloatValue (Float64Value v))
| isInfinite v =
if v > 0 then Var "np.inf" else Var "-np.inf"
| isNaN v =
Var "np.float64(np.nan)"
| otherwise = simpleCall "np.float64" [Float $ fromRational $ toRational v]
compilePrimValue (BoolValue v) = Bool v
compilePrimValue UnitValue = Var "np.byte(0)"
compileVar :: VName -> CompilerM op s PyExp
compileVar v = asks $ fromMaybe (Var v') . M.lookup v' . envVarExp
where
v' = compileName v
-- | Tell me how to compile a @v@, and I'll Compile any @PrimExp v@ for you.
compilePrimExp :: (Monad m) => (v -> m PyExp) -> Imp.PrimExp v -> m PyExp
compilePrimExp _ (Imp.ValueExp v) = pure $ compilePrimValue v
compilePrimExp f (Imp.LeafExp v _) = f v
compilePrimExp f (Imp.BinOpExp op x y) = do
(x', y', simple) <- compileBinOpLike f x y
case op of
Add {} -> simple "+"
Sub {} -> simple "-"
Mul {} -> simple "*"
FAdd {} -> simple "+"
FSub {} -> simple "-"
FMul {} -> simple "*"
FDiv {} -> simple "/"
FMod {} -> simple "%"
Xor {} -> simple "^"
And {} -> simple "&"
Or {} -> simple "|"
Shl {} -> simple "<<"
LogAnd {} -> simple "and"
LogOr {} -> simple "or"
_ -> pure $ simpleCall (prettyString op) [x', y']
compilePrimExp f (Imp.ConvOpExp conv x) = do
x' <- compilePrimExp f x
pure $ simpleCall (prettyString conv) [x']
compilePrimExp f (Imp.CmpOpExp cmp x y) = do
(x', y', simple) <- compileBinOpLike f x y
case cmp of
CmpEq {} -> simple "=="
FCmpLt {} -> simple "<"
FCmpLe {} -> simple "<="
CmpLlt -> simple "<"
CmpLle -> simple "<="
_ -> pure $ simpleCall (prettyString cmp) [x', y']
compilePrimExp f (Imp.UnOpExp op exp1) =
UnOp (compileUnOp op) <$> compilePrimExp f exp1
compilePrimExp f (Imp.FunExp h args _) =
simpleCall (T.unpack (futharkFun (prettyText h))) <$> mapM (compilePrimExp f) args
compileExp :: Imp.Exp -> CompilerM op s PyExp
compileExp = compilePrimExp compileVar
errorMsgString :: Imp.ErrorMsg Imp.Exp -> CompilerM op s (T.Text, [PyExp])
errorMsgString (Imp.ErrorMsg parts) = do
let onPart (Imp.ErrorString s) = pure ("%s", String s)
onPart (Imp.ErrorVal IntType {} x) = ("%d",) <$> compileExp x
onPart (Imp.ErrorVal FloatType {} x) = ("%f",) <$> compileExp x
onPart (Imp.ErrorVal Imp.Bool x) = ("%r",) <$> compileExp x
onPart (Imp.ErrorVal Unit {} x) = ("%r",) <$> compileExp x
(formatstrs, formatargs) <- mapAndUnzipM onPart parts
pure (mconcat formatstrs, formatargs)
generateRead ::
PyExp ->
PyExp ->
PrimType ->
Space ->
CompilerM op s PyExp
generateRead _ _ Unit _ =
pure (compilePrimValue UnitValue)
generateRead _ _ _ ScalarSpace {} =
error "GenericPython.generateRead: ScalarSpace"
generateRead src iexp pt DefaultSpace = do
let pt' = compilePrimType pt
pure $ fromStorage pt $ simpleCall "indexArray" [src, iexp, Var pt']
generateRead src iexp pt (Space space) = do
reader <- asks envReadScalar
reader src iexp pt space
generateWrite ::
PyExp ->
PyExp ->
PrimType ->
Space ->
PyExp ->
CompilerM op s ()
generateWrite _ _ Unit _ _ = pure ()
generateWrite _ _ _ ScalarSpace {} _ = do
error "GenericPython.generateWrite: ScalarSpace"
generateWrite dst iexp pt (Imp.Space space) elemexp = do
writer <- asks envWriteScalar
writer dst iexp pt space elemexp
generateWrite dst iexp _ DefaultSpace elemexp =
stm $ Exp $ simpleCall "writeScalarArray" [dst, iexp, elemexp]
-- | Compile an 'LMADCopy' using sequential nested loops, but
-- parameterised over how to do the reads and writes.
compileLMADCopyWith ::
[Count Elements (TExp Int64)] ->
(PyExp -> PyExp -> CompilerM op s ()) ->
( Count Elements (TExp Int64),
[Count Elements (TExp Int64)]
) ->
(PyExp -> CompilerM op s PyExp) ->
( Count Elements (TExp Int64),
[Count Elements (TExp Int64)]
) ->
CompilerM op s ()
compileLMADCopyWith shape doWrite dst_lmad doRead src_lmad = do
let (dstoffset, dststrides) = dst_lmad
(srcoffset, srcstrides) = src_lmad
shape' <- mapM (compileExp . untyped . unCount) shape
body <- collect $ do
dst_i <-
compileExp . untyped . unCount $
dstoffset + sum (zipWith (*) is' dststrides)
src_i <-
compileExp . untyped . unCount $
srcoffset + sum (zipWith (*) is' srcstrides)
doWrite dst_i =<< doRead src_i
mapM_ stm $ loops (zip is shape') body
where
r = length shape
is = map (VName "i") [0 .. r - 1]
is' :: [Count Elements (TExp Int64)]
is' = map (elements . le64) is
loops [] body = body
loops ((i, n) : ins) body =
[For (compileName i) (simpleCall "range" [n]) $ loops ins body]
-- | Compile an 'LMADCopy' using sequential nested loops and
-- 'Imp.Read'/'Imp.Write' of individual scalars. This always works,
-- but can be pretty slow if those reads and writes are costly.
compileLMADCopy ::
PrimType ->
[Count Elements (TExp Int64)] ->
(VName, Space) ->
( Count Elements (TExp Int64),
[Count Elements (TExp Int64)]
) ->
(VName, Space) ->
( Count Elements (TExp Int64),
[Count Elements (TExp Int64)]
) ->
CompilerM op s ()
compileLMADCopy t shape (dst, dstspace) dst_lmad (src, srcspace) src_lmad = do
src' <- compileVar src
dst' <- compileVar dst
let doWrite dst_i = generateWrite dst' dst_i t dstspace
doRead src_i = generateRead src' src_i t srcspace
compileLMADCopyWith shape doWrite dst_lmad doRead src_lmad
compileCode :: Imp.Code op -> CompilerM op s ()
compileCode Imp.DebugPrint {} =
pure ()
compileCode Imp.TracePrint {} =
pure ()
compileCode (Imp.Op op) =
join $ asks envOpCompiler <*> pure op
compileCode (Imp.If cond tb fb) = do
cond' <- compileExp $ Imp.untyped cond
tb' <- collect $ compileCode tb
fb' <- collect $ compileCode fb
stm $ If cond' tb' fb'
compileCode (c1 Imp.:>>: c2) = do
compileCode c1
compileCode c2
compileCode (Imp.While cond body) = do
cond' <- compileExp $ Imp.untyped cond
body' <- collect $ compileCode body
stm $ While cond' body'
compileCode (Imp.For i bound body) = do
bound' <- compileExp bound
let i' = compileName i
body' <- collect $ compileCode body
counter <- prettyString <$> newVName "counter"
one <- prettyString <$> newVName "one"
stm $ Assign (Var i') $ simpleCall (compilePrimToNp (Imp.primExpType bound)) [Integer 0]
stm $ Assign (Var one) $ simpleCall (compilePrimToNp (Imp.primExpType bound)) [Integer 1]
stm $
For counter (simpleCall "range" [bound']) $
body' ++ [AssignOp "+" (Var i') (Var one)]
compileCode (Imp.SetScalar name exp1) =
stm =<< Assign <$> compileVar name <*> compileExp exp1
compileCode Imp.DeclareMem {} = pure ()
compileCode (Imp.DeclareScalar v _ Unit) = do
v' <- compileVar v
stm $ Assign v' $ Var "True"
compileCode Imp.DeclareScalar {} = pure ()
compileCode (Imp.DeclareArray name t vs) = do
let arr_name = compileName name <> "_arr"
-- It is important to store the Numpy array in a temporary variable
-- to prevent it from going "out-of-scope" before calling
-- unwrapArray (which internally uses the .ctype method); see
-- https://docs.scipy.org/doc/numpy/reference/generated/numpy.ndarray.ctypes.html
stm $ Assign (Var arr_name) $ case vs of
Imp.ArrayValues vs' ->
Call
(Var "np.array")
[ Arg $ List $ map compilePrimValue vs',
ArgKeyword "dtype" $ Var $ compilePrimToNp t
]
Imp.ArrayZeros n ->
Call
(Var "np.zeros")
[ Arg $ Integer $ fromIntegral n,
ArgKeyword "dtype" $ Var $ compilePrimToNp t
]
name' <- compileVar name
stm $ Assign name' $ simpleCall "unwrapArray" [Var arr_name]
compileCode (Imp.Comment s code) = do
code' <- collect $ compileCode code
stm $ Comment (T.unpack s) code'
compileCode (Imp.Assert e msg (loc, locs)) = do
e' <- compileExp e
(formatstr, formatargs) <- errorMsgString msg
stm $
Assert
e'
( BinOp
"%"
(String $ "Error: " <> formatstr <> "\n\nBacktrace:\n" <> stacktrace)
(Tuple formatargs)
)
where
stacktrace = prettyStacktrace 0 $ map locText $ loc : locs
compileCode (Imp.Call dests fname args) = do
args' <- mapM compileArg args
dests' <- tupleOrSingle <$> mapM compileVar dests
let fname'
| isBuiltInFunction fname = futharkFun (prettyText fname)
| otherwise = "self." <> futharkFun (prettyText fname)
call' = simpleCall (T.unpack fname') args'
-- If the function returns nothing (is called only for side
-- effects), take care not to assign to an empty tuple.
stm $
if null dests
then Exp call'
else Assign dests' call'
where
compileArg (Imp.MemArg m) = compileVar m
compileArg (Imp.ExpArg e) = compileExp e
compileCode (Imp.SetMem dest src _) =
stm =<< Assign <$> compileVar dest <*> compileVar src
compileCode (Imp.Allocate name (Imp.Count (Imp.TPrimExp e)) (Imp.Space space)) =
join $
asks envAllocate
<*> compileVar name
<*> compileExp e
<*> pure space
compileCode (Imp.Allocate name (Imp.Count (Imp.TPrimExp e)) _) = do
e' <- compileExp e
let allocate' = simpleCall "allocateMem" [e']
stm =<< Assign <$> compileVar name <*> pure allocate'
compileCode (Imp.Free name _) =
stm =<< Assign <$> compileVar name <*> pure None
compileCode (Imp.LMADCopy t shape (dst, dstspace) (dstoffset, dststrides) (src, srcspace) (srcoffset, srcstrides)) = do
cp <- asks $ M.lookup (dstspace, srcspace) . opsCopies . envOperations
case cp of
Nothing ->
compileLMADCopy t shape (dst, dstspace) (dstoffset, dststrides) (src, srcspace) (srcoffset, srcstrides)
Just cp' -> do
shape' <- traverse (traverse (compileExp . untyped)) shape
dst' <- compileVar dst
src' <- compileVar src
dstoffset' <- traverse (compileExp . untyped) dstoffset
dststrides' <- traverse (traverse (compileExp . untyped)) dststrides
srcoffset' <- traverse (compileExp . untyped) srcoffset
srcstrides' <- traverse (traverse (compileExp . untyped)) srcstrides
cp' t shape' dst' (dstoffset', dststrides') src' (srcoffset', srcstrides')
compileCode (Imp.Write dst (Imp.Count idx) pt space _ elemexp) = do
dst' <- compileVar dst
idx' <- compileExp $ Imp.untyped idx
elemexp' <- compileExp elemexp
generateWrite dst' idx' pt space elemexp'
compileCode (Imp.Read x src (Imp.Count iexp) pt space _) = do
x' <- compileVar x
iexp' <- compileExp $ untyped iexp
src' <- compileVar src
stm . Assign x' =<< generateRead src' iexp' pt space
compileCode Imp.Skip = pure ()
lmadcopyCPU :: DoLMADCopy op s
lmadcopyCPU t shape dst (dstoffset, dststride) src (srcoffset, srcstride) =
stm . Exp . simpleCall "lmad_copy" $
[ Var (compilePrimType t),
dst,
unCount dstoffset,
List (map unCount dststride),
src,
unCount srcoffset,
List (map unCount srcstride),
List (map unCount shape)
]