-- Hoogle documentation, generated by Haddock -- See Hoogle, http://www.haskell.org/hoogle/ -- | TensorFlow bindings. -- -- Please see README.md @package tensorflow @version 0.1.0.0 -- | Originally taken from internal proto-lens code. module TensorFlow.Internal.VarInt -- | Decode an unsigned varint. getVarInt :: Parser Word64 -- | Encode a Word64. putVarInt :: Word64 -> Builder module TensorFlow.Internal.FFI data TensorFlowException TensorFlowException :: Code -> Text -> TensorFlowException data Session -- | Runs the given action after creating a session with options populated -- by the given optionSetter. withSession :: (SessionOptions -> IO ()) -> ((IO () -> IO ()) -> Session -> IO a) -> IO a extendGraph :: Session -> GraphDef -> IO () run :: Session -> [(ByteString, TensorData)] -> [ByteString] -> [ByteString] -> IO [TensorData] -- | All of the data needed to represent a tensor. data TensorData TensorData :: [Int64] -> !DataType -> !(Vector Word8) -> TensorData [tensorDataDimensions] :: TensorData -> [Int64] [tensorDataType] :: TensorData -> !DataType [tensorDataBytes] :: TensorData -> !(Vector Word8) setSessionConfig :: ConfigProto -> SessionOptions -> IO () setSessionTarget :: ByteString -> SessionOptions -> IO () -- | Returns the serialized OpList of all OpDefs defined in this address -- space. getAllOpList :: IO ByteString -- | Serializes the given msg and provides it as (ptr,len) argument to the -- given action. useProtoAsVoidPtrLen :: (Message msg, Integral c, Show c, Bits c) => msg -> (Ptr b -> c -> IO a) -> IO a instance GHC.Classes.Eq TensorFlow.Internal.FFI.TensorData instance GHC.Show.Show TensorFlow.Internal.FFI.TensorData instance GHC.Classes.Eq TensorFlow.Internal.FFI.TensorFlowException instance GHC.Show.Show TensorFlow.Internal.FFI.TensorFlowException instance GHC.Exception.Exception TensorFlow.Internal.FFI.TensorFlowException module TensorFlow.Types -- | The class of scalar types supported by tensorflow. class TensorType a tensorType :: TensorType a => a -> DataType tensorRefType :: TensorType a => a -> DataType tensorVal :: TensorType a => Lens' TensorProto [a] -- | Tensor data with the correct memory layout for tensorflow. newtype TensorData a TensorData :: TensorData -> TensorData a [unTensorData] :: TensorData a -> TensorData -- | Types that can be converted to and from TensorData. -- -- Vector is the most efficient to encode/decode for most element -- types. class TensorType a => TensorDataType s a -- | Decode the bytes of a TensorData into an s. decodeTensorData :: TensorDataType s a => TensorData a -> s a -- | Encode an s into a TensorData. -- -- The values should be in row major order, e.g., -- -- element 0: index (0, ..., 0) element 1: index (0, ..., 1) ... encodeTensorData :: TensorDataType s a => Shape -> s a -> TensorData a newtype Scalar a Scalar :: a -> Scalar a [unScalar] :: Scalar a -> a -- | Shape (dimensions) of a tensor. newtype Shape Shape :: [Int64] -> Shape protoShape :: Lens' TensorShapeProto Shape class Attribute a attrLens :: Attribute a => Lens' AttrValue a data DataType :: * DT_INVALID :: DataType DT_FLOAT :: DataType DT_DOUBLE :: DataType DT_INT32 :: DataType DT_UINT8 :: DataType DT_INT16 :: DataType DT_INT8 :: DataType DT_STRING :: DataType DT_COMPLEX64 :: DataType DT_INT64 :: DataType DT_BOOL :: DataType DT_QINT8 :: DataType DT_QUINT8 :: DataType DT_QINT32 :: DataType DT_BFLOAT16 :: DataType DT_QINT16 :: DataType DT_QUINT16 :: DataType DT_UINT16 :: DataType DT_COMPLEX128 :: DataType DT_HALF :: DataType DT_RESOURCE :: DataType DT_FLOAT_REF :: DataType DT_DOUBLE_REF :: DataType DT_INT32_REF :: DataType DT_UINT8_REF :: DataType DT_INT16_REF :: DataType DT_INT8_REF :: DataType DT_STRING_REF :: DataType DT_COMPLEX64_REF :: DataType DT_INT64_REF :: DataType DT_BOOL_REF :: DataType DT_QINT8_REF :: DataType DT_QUINT8_REF :: DataType DT_QINT32_REF :: DataType DT_BFLOAT16_REF :: DataType DT_QINT16_REF :: DataType DT_QUINT16_REF :: DataType DT_UINT16_REF :: DataType DT_COMPLEX128_REF :: DataType DT_HALF_REF :: DataType DT_RESOURCE_REF :: DataType -- | A heterogeneous list type. data ListOf f as Nil :: ListOf f '[] (:/) :: f a -> ListOf f as -> ListOf f (a : as) type List = ListOf Identity -- | Equivalent of :/ for lists. (/:/) :: a -> List as -> List (a : as) data TensorTypeProxy a TensorTypeProxy :: TensorTypeProxy a class TensorTypes (ts :: [*]) tensorTypes :: TensorTypes ts => TensorTypeList ts type TensorTypeList = ListOf TensorTypeProxy fromTensorTypeList :: TensorTypeList ts -> [DataType] fromTensorTypes :: TensorTypes as => Proxy as -> [DataType] -- | A Constraint specifying the possible choices of a -- TensorType. -- -- We implement a Constraint like OneOf '[Double, Float] -- a by turning the natural representation as a conjunction, i.e., -- --
--   a == Double || a == Float
--   
-- -- into a disjunction like -- --
--   a /= Int32 && a /= Int64 && a /= ByteString && ...
--   
-- -- using an enumeration of all the possible TensorTypes. type OneOf ts a = (TensorType a, TensorTypes ts, NoneOf (AllTensorTypes \\ ts) a) -- | A constraint checking that two types are different. type OneOfs ts as = (TensorTypes as, TensorTypes ts, NoneOfs (AllTensorTypes \\ ts) as) -- | Helper types to produce a reasonable type error message when the -- Constraint "a /= a" fails. TODO(judahjacobson): Use ghc-8's -- CustomTypeErrors for this. data TypeError a data ExcludedCase -- | A constraint that the type a doesn't appear in the type list -- ts. Assumes that a and each of the elements of -- ts are TensorTypes. -- | Takes the difference of two lists of types. -- | Removes a type from the given list of types. -- | An enumeration of all valid TensorTypes. type AllTensorTypes = '[Float, Double, Int8, Int16, Int32, Int64, Word8, Word16, ByteString, Bool] instance GHC.Show.Show TensorFlow.Types.Shape instance Data.String.IsString a => Data.String.IsString (TensorFlow.Types.Scalar a) instance GHC.Real.RealFrac a => GHC.Real.RealFrac (TensorFlow.Types.Scalar a) instance GHC.Float.RealFloat a => GHC.Float.RealFloat (TensorFlow.Types.Scalar a) instance GHC.Real.Real a => GHC.Real.Real (TensorFlow.Types.Scalar a) instance GHC.Float.Floating a => GHC.Float.Floating (TensorFlow.Types.Scalar a) instance GHC.Real.Fractional a => GHC.Real.Fractional (TensorFlow.Types.Scalar a) instance GHC.Num.Num a => GHC.Num.Num (TensorFlow.Types.Scalar a) instance GHC.Classes.Ord a => GHC.Classes.Ord (TensorFlow.Types.Scalar a) instance GHC.Classes.Eq a => GHC.Classes.Eq (TensorFlow.Types.Scalar a) instance GHC.Show.Show a => GHC.Show.Show (TensorFlow.Types.Scalar a) instance TensorFlow.Types.TensorType GHC.Types.Float instance TensorFlow.Types.TensorType GHC.Types.Double instance TensorFlow.Types.TensorType GHC.Int.Int32 instance TensorFlow.Types.TensorType GHC.Int.Int64 instance TensorFlow.Types.TensorType GHC.Word.Word8 instance TensorFlow.Types.TensorType GHC.Word.Word16 instance TensorFlow.Types.TensorType GHC.Int.Int16 instance TensorFlow.Types.TensorType GHC.Int.Int8 instance TensorFlow.Types.TensorType Data.ByteString.Internal.ByteString instance TensorFlow.Types.TensorType GHC.Types.Bool instance TensorFlow.Types.TensorType (Data.Complex.Complex GHC.Types.Float) instance TensorFlow.Types.TensorType (Data.Complex.Complex GHC.Types.Double) instance TensorFlow.Types.TensorDataType Data.Vector.Storable.Vector GHC.Types.Float instance TensorFlow.Types.TensorDataType Data.Vector.Storable.Vector GHC.Types.Double instance TensorFlow.Types.TensorDataType Data.Vector.Storable.Vector GHC.Int.Int8 instance TensorFlow.Types.TensorDataType Data.Vector.Storable.Vector GHC.Int.Int16 instance TensorFlow.Types.TensorDataType Data.Vector.Storable.Vector GHC.Int.Int32 instance TensorFlow.Types.TensorDataType Data.Vector.Storable.Vector GHC.Int.Int64 instance TensorFlow.Types.TensorDataType Data.Vector.Storable.Vector GHC.Word.Word8 instance TensorFlow.Types.TensorDataType Data.Vector.Storable.Vector GHC.Word.Word16 instance TensorFlow.Types.TensorDataType Data.Vector.Storable.Vector GHC.Types.Bool instance (Foreign.Storable.Storable a, TensorFlow.Types.TensorDataType Data.Vector.Storable.Vector a) => TensorFlow.Types.TensorDataType Data.Vector.Vector a instance TensorFlow.Types.TensorDataType Data.Vector.Vector (Data.Complex.Complex GHC.Types.Float) instance TensorFlow.Types.TensorDataType Data.Vector.Vector (Data.Complex.Complex GHC.Types.Double) instance TensorFlow.Types.TensorDataType Data.Vector.Vector Data.ByteString.Internal.ByteString instance TensorFlow.Types.TensorDataType Data.Vector.Vector a => TensorFlow.Types.TensorDataType TensorFlow.Types.Scalar a instance GHC.Exts.IsList TensorFlow.Types.Shape instance TensorFlow.Types.Attribute GHC.Types.Float instance TensorFlow.Types.Attribute Data.ByteString.Internal.ByteString instance TensorFlow.Types.Attribute GHC.Int.Int64 instance TensorFlow.Types.Attribute Proto.Tensorflow.Core.Framework.Types.DataType instance TensorFlow.Types.Attribute Proto.Tensorflow.Core.Framework.Tensor.TensorProto instance TensorFlow.Types.Attribute GHC.Types.Bool instance TensorFlow.Types.Attribute TensorFlow.Types.Shape instance TensorFlow.Types.Attribute Proto.Tensorflow.Core.Framework.AttrValue.AttrValue'ListValue instance TensorFlow.Types.Attribute [Proto.Tensorflow.Core.Framework.Types.DataType] instance TensorFlow.Types.Attribute [GHC.Int.Int64] instance TensorFlow.Types.All GHC.Classes.Eq (TensorFlow.Types.Map f as) => GHC.Classes.Eq (TensorFlow.Types.ListOf f as) instance TensorFlow.Types.All GHC.Show.Show (TensorFlow.Types.Map f as) => GHC.Show.Show (TensorFlow.Types.ListOf f as) instance TensorFlow.Types.TensorTypes '[] instance (TensorFlow.Types.TensorType t, TensorFlow.Types.TensorTypes ts) => TensorFlow.Types.TensorTypes (t : ts) module TensorFlow.Output -- | A type of graph node which has no outputs. These nodes are valuable -- for causing side effects when they are run. newtype ControlNode ControlNode :: NodeName -> ControlNode [unControlNode] :: ControlNode -> NodeName -- | A device that a node can be assigned to. There's a naming convention -- where the device names are constructed from job and replica names. newtype Device Device :: Text -> Device [deviceName] :: Device -> Text -- | The name of a node in the graph. This corresponds to the proto field -- NodeDef.name. Includes the scope prefix (if any) and a unique -- identifier (if the node was implicitly named). newtype NodeName NodeName :: Text -> NodeName [unNodeName] :: NodeName -> Text -- | Op definition. This corresponds somewhat to the NodeDef -- proto. data OpDef OpDef :: !PendingNodeName -> !OpType -> !(Map Text AttrValue) -> [Output] -> [NodeName] -> OpDef [_opName] :: OpDef -> !PendingNodeName [_opType] :: OpDef -> !OpType [_opAttrs] :: OpDef -> !(Map Text AttrValue) [_opInputs] :: OpDef -> [Output] [_opControlInputs] :: OpDef -> [NodeName] opName :: Lens' OpDef PendingNodeName opType :: Lens' OpDef OpType opAttr :: Attribute a => Text -> Lens' OpDef a opInputs :: Lens' OpDef [Output] opControlInputs :: Lens' OpDef [NodeName] -- | The type of op of a node in the graph. This corresponds to the proto -- field NodeDef.op. newtype OpType OpType :: Text -> OpType [unOpType] :: OpType -> Text newtype OutputIx OutputIx :: Int -> OutputIx [unOutputIx] :: OutputIx -> Int -- | An output of a TensorFlow node. data Output Output :: !OutputIx -> !NodeName -> Output [outputIndex] :: Output -> !OutputIx [outputNodeName] :: Output -> !NodeName output :: OutputIx -> NodeName -> Output -- | The name specified for an unrendered Op. If an Op has an ImplicitName, -- it will be assigned based on the opType plus a unique identifier. Does -- not contain the "scope" prefix. data PendingNodeName ExplicitName :: !Text -> PendingNodeName ImplicitName :: PendingNodeName -- | Opaque handle to a mutable resource in the graph. Typical such -- resources are variables. newtype ResourceHandle ResourceHandle :: Output -> ResourceHandle instance GHC.Classes.Ord TensorFlow.Output.OpDef instance GHC.Classes.Eq TensorFlow.Output.OpDef instance GHC.Show.Show TensorFlow.Output.Output instance GHC.Classes.Ord TensorFlow.Output.Output instance GHC.Classes.Eq TensorFlow.Output.Output instance GHC.Show.Show TensorFlow.Output.NodeName instance GHC.Classes.Ord TensorFlow.Output.NodeName instance GHC.Classes.Eq TensorFlow.Output.NodeName instance GHC.Show.Show TensorFlow.Output.PendingNodeName instance GHC.Classes.Ord TensorFlow.Output.PendingNodeName instance GHC.Classes.Eq TensorFlow.Output.PendingNodeName instance Data.String.IsString TensorFlow.Output.Device instance GHC.Classes.Ord TensorFlow.Output.Device instance GHC.Classes.Eq TensorFlow.Output.Device instance GHC.Show.Show TensorFlow.Output.OutputIx instance GHC.Enum.Enum TensorFlow.Output.OutputIx instance GHC.Num.Num TensorFlow.Output.OutputIx instance GHC.Classes.Ord TensorFlow.Output.OutputIx instance GHC.Classes.Eq TensorFlow.Output.OutputIx instance GHC.Show.Show TensorFlow.Output.OpType instance GHC.Classes.Ord TensorFlow.Output.OpType instance GHC.Classes.Eq TensorFlow.Output.OpType instance Data.String.IsString TensorFlow.Output.OpType instance GHC.Show.Show TensorFlow.Output.Device instance Data.String.IsString TensorFlow.Output.PendingNodeName instance Data.String.IsString TensorFlow.Output.Output module TensorFlow.Build -- | A type of graph node which has no outputs. These nodes are valuable -- for causing side effects when they are run. newtype ControlNode ControlNode :: NodeName -> ControlNode [unControlNode] :: ControlNode -> NodeName data Unique explicitName :: Text -> PendingNodeName implicitName :: PendingNodeName opDef :: OpType -> OpDef opDefWithName :: PendingNodeName -> OpType -> OpDef opName :: Lens' OpDef PendingNodeName opType :: Lens' OpDef OpType opAttr :: Attribute a => Text -> Lens' OpDef a opInputs :: Lens' OpDef [Output] opControlInputs :: Lens' OpDef [NodeName] data GraphState renderedNodeDefs :: Lens' GraphState (Map NodeName NodeDef) -- | An action for building nodes in a TensorFlow graph. Used to manage -- build state internally as part of the Session monad. data BuildT m a -- | An action for building nodes in a TensorFlow graph. type Build = BuildT Identity -- | Lift a Build action into a monad, including any explicit op -- renderings. class Monad m => MonadBuild m build :: MonadBuild m => Build a -> m a -- | Registers the given node to be executed before the next run. addInitializer :: MonadBuild m => ControlNode -> m () -- | This is Control.Monad.Morph.hoist sans the dependency. hoistBuildT :: (forall a. m a -> n a) -> BuildT m b -> BuildT n b evalBuildT :: Monad m => BuildT m a -> m a runBuildT :: BuildT m a -> m (a, GraphState) -- | Produce a GraphDef proto representation of the nodes that are rendered -- in the given Build action. asGraphDef :: Build a -> GraphDef addGraphDef :: MonadBuild m => GraphDef -> m () -- | Get all the initializers that have accumulated so far, and clear that -- buffer. flushInitializers :: Monad m => BuildT m [NodeName] -- | Get all the NodeDefs that have accumulated so far, and clear that -- buffer. flushNodeBuffer :: MonadBuild m => m [NodeDef] summaries :: Lens' GraphState [Output] -- | Render the given op if it hasn't been rendered already, and return its -- name. getOrAddOp :: OpDef -> Build NodeName -- | Add a new node for a given OpDef. This is used for making -- "stateful" ops which are not safe to dedup (e.g, "variable" and -- "assign"). addNewOp :: OpDef -> Build NodeName -- | Turn an Output into a string representation for the TensorFlow -- foreign APIs. encodeOutput :: Output -> Text lookupNode :: NodeName -> Build NodeDef -- | Modify some part of the state, run an action, and restore the state -- after that action is done. withStateLens :: MonadBuild m => Lens' GraphState a -> (a -> a) -> m b -> m b -- | Set a device for all nodes rendered in the given Build action -- (unless further overridden by another use of withDevice). withDevice :: MonadBuild m => Maybe Device -> m a -> m a -- | Prepend a scope to all nodes rendered in the given Build -- action. withNameScope :: MonadBuild m => Text -> m a -> m a -- | Add control inputs to all nodes rendered in the given Build -- action. withNodeDependencies :: MonadBuild m => Set NodeName -> m a -> m a instance Control.Monad.Catch.MonadMask m => Control.Monad.Catch.MonadMask (TensorFlow.Build.BuildT m) instance Control.Monad.Catch.MonadCatch m => Control.Monad.Catch.MonadCatch (TensorFlow.Build.BuildT m) instance Control.Monad.Catch.MonadThrow m => Control.Monad.Catch.MonadThrow (TensorFlow.Build.BuildT m) instance GHC.Base.Monad m => Control.Monad.State.Class.MonadState TensorFlow.Build.GraphState (TensorFlow.Build.BuildT m) instance Control.Monad.Trans.Class.MonadTrans TensorFlow.Build.BuildT instance Control.Monad.IO.Class.MonadIO m => Control.Monad.IO.Class.MonadIO (TensorFlow.Build.BuildT m) instance GHC.Base.Monad m => GHC.Base.Monad (TensorFlow.Build.BuildT m) instance GHC.Base.Monad m => GHC.Base.Applicative (TensorFlow.Build.BuildT m) instance GHC.Base.Functor m => GHC.Base.Functor (TensorFlow.Build.BuildT m) instance GHC.Classes.Ord TensorFlow.Build.PendingNode instance GHC.Classes.Eq TensorFlow.Build.PendingNode instance Data.String.IsString TensorFlow.Build.Scope instance GHC.Classes.Ord TensorFlow.Build.Scope instance GHC.Classes.Eq TensorFlow.Build.Scope instance GHC.Enum.Enum TensorFlow.Build.Unique instance GHC.Classes.Ord TensorFlow.Build.Unique instance GHC.Classes.Eq TensorFlow.Build.Unique instance GHC.Show.Show TensorFlow.Build.Scope instance GHC.Base.Monad m => TensorFlow.Build.MonadBuild (TensorFlow.Build.BuildT m) module TensorFlow.Tensor -- | A named output of a TensorFlow operation. -- -- The type parameter a is the type of the elements in the -- Tensor. The parameter v is either: -- -- -- -- Note that expr, value, render and -- renderValue can help convert between the different types of -- Tensor. data Tensor v a Tensor :: v Output -> Tensor v a [tensorOutput] :: Tensor v a -> v Output newtype Value a Value :: a -> Value a [runValue] :: Value a -> a newtype Ref a Ref :: a -> Ref a [runRef] :: Ref a -> a -- | Cast a 'Tensor Ref' into a 'Tensor Value'. This behaves like a no-op. value :: Tensor Ref a -> Tensor Value a renderValue :: MonadBuild m => Tensor v a -> m (Tensor Value a) -- | A pair of a Tensor and some data that should be fed into that -- Tensor when running the graph. data Feed Feed :: Output -> TensorData -> Feed -- | A class ensuring that a given tensor is rendered, i.e., has a fixed -- name, device, etc. class TensorKind v => Rendered v rendered :: Rendered v => v a -> a renderedOutput :: Rendered v => Tensor v a -> Output tensorNodeName :: Rendered v => Tensor v a -> NodeName -- | Create a Feed for feeding the given data into a Tensor -- when running the graph. -- -- Note that if a Tensor is rendered, its identity may change; so -- feeding the rendered Tensor may be different than feeding the -- original Tensor. feed :: Rendered v => Tensor v a -> TensorData a -> Feed -- | Create a Tensor for a given name. This can be used to reference -- nodes in a GraphDef that was loaded via addGraphDef. -- TODO(judahjacobson): add more safety checks here. tensorFromName :: TensorKind v => Text -> Tensor v a -- | Like tensorFromName, but type-restricted to Value. tensorValueFromName :: Text -> Tensor Value a -- | Like tensorFromName, but type-restricted to Ref. tensorRefFromName :: Text -> Tensor Ref a type TensorList v = ListOf (Tensor v) tensorListOutputs :: Rendered v => TensorList v as -> [Output] -- | Places all nodes rendered in the given Build action on the same -- device as the given Tensor (see also withDevice). Make sure -- that the action has side effects of rendering the desired tensors. A -- pure return would not have the desired effect. colocateWith :: (MonadBuild m, Rendered v) => Tensor v b -> m a -> m a -- | Render a Tensor, fixing its name, scope, device and control -- inputs from the MonadBuild context. Also renders any -- dependencies of the Tensor that weren't already rendered. -- -- This operation is idempotent; calling render on the same input -- in the same context will produce the same result. However, rendering -- the same Tensor Build in two different contexts may result in -- two different Tensor Values. render :: MonadBuild m => Tensor Build a -> m (Tensor Value a) expr :: TensorKind v => Tensor v a -> Tensor Build a -- | Records the given summary action in Build for retrieval with Summary -- protocol buffer in string form. For safety, use the pre-composed -- functions: Logging.scalarSummary and Logging.histogramSummary. addSummary :: (MonadBuild m, TensorKind v) => Tensor v ByteString -> m () -- | Retrieves the summary ops collected thus far. Typically this only -- happens once, but if buildWithSummary is used repeatedly, the -- values accumulate. collectAllSummaries :: MonadBuild m => m [SummaryTensor] -- | Synonym for the tensors that return serialized Summary proto. type SummaryTensor = Tensor Value ByteString -- | An internal class for kinds of Tensors. class Monad v => TensorKind v toBuild :: TensorKind v => v a -> Build a instance GHC.Base.Functor TensorFlow.Tensor.Ref instance GHC.Base.Functor TensorFlow.Tensor.Value instance GHC.Base.Applicative TensorFlow.Tensor.Value instance GHC.Base.Monad TensorFlow.Tensor.Value instance GHC.Base.Applicative TensorFlow.Tensor.Ref instance GHC.Base.Monad TensorFlow.Tensor.Ref instance TensorFlow.Tensor.Rendered TensorFlow.Tensor.Value instance TensorFlow.Tensor.Rendered TensorFlow.Tensor.Ref instance TensorFlow.Tensor.TensorKind TensorFlow.Tensor.Value instance TensorFlow.Tensor.TensorKind TensorFlow.Tensor.Ref instance TensorFlow.Tensor.TensorKind TensorFlow.Build.Build module TensorFlow.BuildOp -- | Class of types that can be used as op outputs. class BuildResult a buildResult :: BuildResult a => Result a buildOp :: BuildResult a => [Int64] -> OpDef -> Build a -- | Class of types that can be used as op outputs. class PureResult a pureResult :: PureResult a => ReaderT (Build OpDef) (State ResultState) a pureOp :: PureResult a => [Int64] -> Build OpDef -> a -- | Returns true if all the integers in each tuple are identical. Throws -- an error with a descriptive message if not. eqLengthGuard :: [(String, [(String, Int)])] -> Bool class BuildInputs a buildInputs :: BuildInputs a => a -> Build [Output] -- | Parameters to build an op (for example, the node name or optional -- attributes). TODO: be more type safe. type OpParams = OpDef -> OpDef instance GHC.Show.Show TensorFlow.BuildOp.ResultState instance (TensorFlow.BuildOp.BuildResult a1, TensorFlow.BuildOp.BuildResult a2) => TensorFlow.BuildOp.BuildResult (a1, a2) instance (TensorFlow.BuildOp.BuildResult a1, TensorFlow.BuildOp.BuildResult a2, TensorFlow.BuildOp.BuildResult a3) => TensorFlow.BuildOp.BuildResult (a1, a2, a3) instance (TensorFlow.BuildOp.BuildResult a1, TensorFlow.BuildOp.BuildResult a2, TensorFlow.BuildOp.BuildResult a3, TensorFlow.BuildOp.BuildResult a4) => TensorFlow.BuildOp.BuildResult (a1, a2, a3, a4) instance (TensorFlow.BuildOp.BuildResult a1, TensorFlow.BuildOp.BuildResult a2, TensorFlow.BuildOp.BuildResult a3, TensorFlow.BuildOp.BuildResult a4, TensorFlow.BuildOp.BuildResult a5) => TensorFlow.BuildOp.BuildResult (a1, a2, a3, a4, a5) instance (TensorFlow.BuildOp.BuildResult a1, TensorFlow.BuildOp.BuildResult a2, TensorFlow.BuildOp.BuildResult a3, TensorFlow.BuildOp.BuildResult a4, TensorFlow.BuildOp.BuildResult a5, TensorFlow.BuildOp.BuildResult a6) => TensorFlow.BuildOp.BuildResult (a1, a2, a3, a4, a5, a6) instance (TensorFlow.BuildOp.BuildResult a1, TensorFlow.BuildOp.BuildResult a2, TensorFlow.BuildOp.BuildResult a3, TensorFlow.BuildOp.BuildResult a4, TensorFlow.BuildOp.BuildResult a5, TensorFlow.BuildOp.BuildResult a6, TensorFlow.BuildOp.BuildResult a7) => TensorFlow.BuildOp.BuildResult (a1, a2, a3, a4, a5, a6, a7) instance (TensorFlow.BuildOp.BuildResult a1, TensorFlow.BuildOp.BuildResult a2, TensorFlow.BuildOp.BuildResult a3, TensorFlow.BuildOp.BuildResult a4, TensorFlow.BuildOp.BuildResult a5, TensorFlow.BuildOp.BuildResult a6, TensorFlow.BuildOp.BuildResult a7, TensorFlow.BuildOp.BuildResult a8) => TensorFlow.BuildOp.BuildResult (a1, a2, a3, a4, a5, a6, a7, a8) instance TensorFlow.BuildOp.BuildResult TensorFlow.Output.ResourceHandle instance TensorFlow.Tensor.Rendered v => TensorFlow.BuildOp.BuildResult (TensorFlow.Tensor.Tensor v a) instance TensorFlow.BuildOp.BuildResult TensorFlow.Output.ControlNode instance (TensorFlow.Tensor.Rendered v, TensorFlow.Types.TensorTypes as) => TensorFlow.BuildOp.BuildResult (TensorFlow.Tensor.TensorList v as) instance TensorFlow.BuildOp.BuildResult a => TensorFlow.BuildOp.BuildResult [a] instance TensorFlow.BuildOp.PureResult (TensorFlow.Tensor.Tensor TensorFlow.Build.Build a) instance (TensorFlow.BuildOp.PureResult a1, TensorFlow.BuildOp.PureResult a2) => TensorFlow.BuildOp.PureResult (a1, a2) instance (TensorFlow.BuildOp.PureResult a1, TensorFlow.BuildOp.PureResult a2, TensorFlow.BuildOp.PureResult a3) => TensorFlow.BuildOp.PureResult (a1, a2, a3) instance (TensorFlow.BuildOp.PureResult a1, TensorFlow.BuildOp.PureResult a2, TensorFlow.BuildOp.PureResult a3, TensorFlow.BuildOp.PureResult a4) => TensorFlow.BuildOp.PureResult (a1, a2, a3, a4) instance (TensorFlow.BuildOp.PureResult a1, TensorFlow.BuildOp.PureResult a2, TensorFlow.BuildOp.PureResult a3, TensorFlow.BuildOp.PureResult a4, TensorFlow.BuildOp.PureResult a5) => TensorFlow.BuildOp.PureResult (a1, a2, a3, a4, a5) instance (TensorFlow.BuildOp.PureResult a1, TensorFlow.BuildOp.PureResult a2, TensorFlow.BuildOp.PureResult a3, TensorFlow.BuildOp.PureResult a4, TensorFlow.BuildOp.PureResult a5, TensorFlow.BuildOp.PureResult a6) => TensorFlow.BuildOp.PureResult (a1, a2, a3, a4, a5, a6) instance (TensorFlow.BuildOp.PureResult a1, TensorFlow.BuildOp.PureResult a2, TensorFlow.BuildOp.PureResult a3, TensorFlow.BuildOp.PureResult a4, TensorFlow.BuildOp.PureResult a5, TensorFlow.BuildOp.PureResult a6, TensorFlow.BuildOp.PureResult a7) => TensorFlow.BuildOp.PureResult (a1, a2, a3, a4, a5, a6, a7) instance (TensorFlow.BuildOp.PureResult a1, TensorFlow.BuildOp.PureResult a2, TensorFlow.BuildOp.PureResult a3, TensorFlow.BuildOp.PureResult a4, TensorFlow.BuildOp.PureResult a5, TensorFlow.BuildOp.PureResult a6, TensorFlow.BuildOp.PureResult a7, TensorFlow.BuildOp.PureResult a8) => TensorFlow.BuildOp.PureResult (a1, a2, a3, a4, a5, a6, a7, a8) instance TensorFlow.BuildOp.PureResult a => TensorFlow.BuildOp.PureResult [a] instance TensorFlow.Types.TensorTypes as => TensorFlow.BuildOp.PureResult (TensorFlow.Tensor.TensorList TensorFlow.Build.Build as) instance TensorFlow.BuildOp.BuildInputs a => TensorFlow.BuildOp.BuildInputs [a] instance TensorFlow.BuildOp.BuildInputs (TensorFlow.Tensor.Tensor v a) instance TensorFlow.BuildOp.BuildInputs (TensorFlow.Types.ListOf (TensorFlow.Tensor.Tensor v) as) instance TensorFlow.BuildOp.BuildInputs TensorFlow.Output.ResourceHandle module TensorFlow.Nodes -- | Types that contain ops which can be run. class Nodes t getNodes :: Nodes t => t -> Build (Set NodeName) -- | Types that tensor representations (e.g. Tensor, -- ControlNode) can be fetched into. -- -- Includes collections of tensors (e.g. tuples). class Nodes t => Fetchable t a getFetch :: Fetchable t a => t -> Build (Fetch a) -- | Fetch action. Keeps track of what needs to be fetched and how to -- decode the fetched data. data Fetch a Fetch :: Set Text -> (Map Text TensorData -> a) -> Fetch a -- | Nodes to fetch [fetches] :: Fetch a -> Set Text -- | Function to create an a from the fetched data. [fetchRestore] :: Fetch a -> Map Text TensorData -> a nodesUnion :: (Monoid b, Traversable t, Applicative f) => t (f b) -> f b fetchTensorVector :: (TensorType a) => Tensor v a -> Build (Fetch (TensorData a)) instance GHC.Base.Functor TensorFlow.Nodes.Fetch instance GHC.Base.Applicative TensorFlow.Nodes.Fetch instance (TensorFlow.Nodes.Nodes t1, TensorFlow.Nodes.Nodes t2) => TensorFlow.Nodes.Nodes (t1, t2) instance (TensorFlow.Nodes.Nodes t1, TensorFlow.Nodes.Nodes t2, TensorFlow.Nodes.Nodes t3) => TensorFlow.Nodes.Nodes (t1, t2, t3) instance (TensorFlow.Nodes.Fetchable t1 a1, TensorFlow.Nodes.Fetchable t2 a2) => TensorFlow.Nodes.Fetchable (t1, t2) (a1, a2) instance (TensorFlow.Nodes.Fetchable t1 a1, TensorFlow.Nodes.Fetchable t2 a2, TensorFlow.Nodes.Fetchable t3 a3) => TensorFlow.Nodes.Fetchable (t1, t2, t3) (a1, a2, a3) instance TensorFlow.Nodes.Nodes t => TensorFlow.Nodes.Nodes [t] instance TensorFlow.Nodes.Fetchable t a => TensorFlow.Nodes.Fetchable [t] [a] instance TensorFlow.Nodes.Nodes TensorFlow.Output.ControlNode instance (a ~ ()) => TensorFlow.Nodes.Fetchable TensorFlow.Output.ControlNode a instance TensorFlow.Nodes.Nodes (TensorFlow.Types.ListOf f '[]) instance (TensorFlow.Nodes.Nodes (f a), TensorFlow.Nodes.Nodes (TensorFlow.Types.ListOf f as)) => TensorFlow.Nodes.Nodes (TensorFlow.Types.ListOf f (a : as)) instance (l ~ TensorFlow.Types.List '[]) => TensorFlow.Nodes.Fetchable (TensorFlow.Types.ListOf f '[]) l instance (TensorFlow.Nodes.Fetchable (f t) a, TensorFlow.Nodes.Fetchable (TensorFlow.Types.ListOf f ts) (TensorFlow.Types.List as), i ~ Data.Functor.Identity.Identity) => TensorFlow.Nodes.Fetchable (TensorFlow.Types.ListOf f (t : ts)) (TensorFlow.Types.ListOf i (a : as)) instance TensorFlow.Nodes.Nodes (TensorFlow.Tensor.Tensor v a) instance (TensorFlow.Types.TensorType a, a ~ a') => TensorFlow.Nodes.Fetchable (TensorFlow.Tensor.Tensor v a) (TensorFlow.Types.TensorData a') instance (TensorFlow.Types.TensorType a, TensorFlow.Types.TensorDataType s a, a ~ a') => TensorFlow.Nodes.Fetchable (TensorFlow.Tensor.Tensor v a) (s a') module TensorFlow.ControlFlow -- | Modify a Build action, such that all new ops rendered in it -- will depend on the nodes in the first argument. withControlDependencies :: (MonadBuild m, Nodes t) => t -> m a -> m a -- | Create an op that groups multiple operations. -- -- When this op finishes, all ops in the input n have finished. -- This op has no output. group :: (MonadBuild m, Nodes t) => t -> m ControlNode -- | Does nothing. Only useful as a placeholder for control edges. noOp :: MonadBuild m => m ControlNode module TensorFlow.Session data Session a -- | Customization for session. Use the lenses to update: -- sessionTarget, sessionTracer, sessionConfig. data Options -- | Uses the specified config for the created session. sessionConfig :: Lens' Options ConfigProto -- | Target can be: "local", ip:port, host:port. The set of supported -- factories depends on the linked in libraries. sessionTarget :: Lens' Options ByteString -- | Uses the given logger to monitor session progress. sessionTracer :: Lens' Options Tracer -- | Run Session actions in a new TensorFlow session. runSession :: Session a -> IO a -- | Run Session actions in a new TensorFlow session created with -- the given option setter actions (sessionTarget, -- sessionConfig). runSessionWithOptions :: Options -> Session a -> IO a -- | Lift a Build action into a monad, including any explicit op -- renderings. class Monad m => MonadBuild m build :: MonadBuild m => Build a -> m a -- | Add all pending rendered nodes to the TensorFlow graph and runs any -- pending initializers. -- -- Note that run, runWithFeeds, etc. will all call this function -- implicitly. extend :: Session () addGraphDef :: MonadBuild m => GraphDef -> m () -- | Run a subgraph t, rendering any dependent nodes that aren't -- already rendered, and fetch the corresponding values for a. run :: Fetchable t a => t -> Session a -- | Run a subgraph t, rendering any dependent nodes that aren't -- already rendered, feed the given input values, and fetch the -- corresponding result values for a. runWithFeeds :: Fetchable t a => [Feed] -> t -> Session a -- | Run a subgraph t, rendering and extending any dependent nodes -- that aren't already rendered. This behaves like run except that -- it doesn't do any fetches. run_ :: Nodes t => t -> Session () -- | Run a subgraph t, rendering any dependent nodes that aren't -- already rendered, feed the given input values, and fetch the -- corresponding result values for a. This behaves like -- runWithFeeds except that it doesn't do any fetches. runWithFeeds_ :: Nodes t => [Feed] -> t -> Session () -- | Starts a concurrent thread which evaluates the given Nodes forever -- until runSession exits or an exception occurs. Graph extension happens -- synchronously, but the resultant run proceeds as a separate thread. asyncProdNodes :: Nodes t => t -> Session () instance Control.Monad.Catch.MonadMask TensorFlow.Session.Session instance Control.Monad.Catch.MonadCatch TensorFlow.Session.Session instance Control.Monad.Catch.MonadThrow TensorFlow.Session.Session instance Control.Monad.IO.Class.MonadIO TensorFlow.Session.Session instance GHC.Base.Monad TensorFlow.Session.Session instance GHC.Base.Applicative TensorFlow.Session.Session instance GHC.Base.Functor TensorFlow.Session.Session instance Data.Default.Class.Default TensorFlow.Session.Options instance TensorFlow.Build.MonadBuild TensorFlow.Session.Session -- | The core functionality of TensorFlow. -- -- Unless you are defining ops, you do not need to import other modules -- from this package. -- -- Basic ops are provided in the tensorflow-ops and tensorflow-core-ops -- packages. module TensorFlow.Core data Session a -- | Customization for session. Use the lenses to update: -- sessionTarget, sessionTracer, sessionConfig. data Options -- | Uses the specified config for the created session. sessionConfig :: Lens' Options ConfigProto -- | Target can be: "local", ip:port, host:port. The set of supported -- factories depends on the linked in libraries. sessionTarget :: Lens' Options ByteString -- | Uses the given logger to monitor session progress. sessionTracer :: Lens' Options Tracer -- | Run Session actions in a new TensorFlow session. runSession :: Session a -> IO a -- | Run Session actions in a new TensorFlow session created with -- the given option setter actions (sessionTarget, -- sessionConfig). runSessionWithOptions :: Options -> Session a -> IO a -- | Lift a Build action into a monad, including any explicit op -- renderings. class Monad m => MonadBuild m build :: MonadBuild m => Build a -> m a -- | Types that tensor representations (e.g. Tensor, -- ControlNode) can be fetched into. -- -- Includes collections of tensors (e.g. tuples). class Nodes t => Fetchable t a -- | Types that contain ops which can be run. class Nodes t -- | Run a subgraph t, rendering any dependent nodes that aren't -- already rendered, and fetch the corresponding values for a. run :: Fetchable t a => t -> Session a -- | Run a subgraph t, rendering and extending any dependent nodes -- that aren't already rendered. This behaves like run except that -- it doesn't do any fetches. run_ :: Nodes t => t -> Session () -- | A pair of a Tensor and some data that should be fed into that -- Tensor when running the graph. data Feed -- | Create a Feed for feeding the given data into a Tensor -- when running the graph. -- -- Note that if a Tensor is rendered, its identity may change; so -- feeding the rendered Tensor may be different than feeding the -- original Tensor. feed :: Rendered v => Tensor v a -> TensorData a -> Feed -- | Run a subgraph t, rendering any dependent nodes that aren't -- already rendered, feed the given input values, and fetch the -- corresponding result values for a. runWithFeeds :: Fetchable t a => [Feed] -> t -> Session a -- | Run a subgraph t, rendering any dependent nodes that aren't -- already rendered, feed the given input values, and fetch the -- corresponding result values for a. This behaves like -- runWithFeeds except that it doesn't do any fetches. runWithFeeds_ :: Nodes t => [Feed] -> t -> Session () -- | Starts a concurrent thread which evaluates the given Nodes forever -- until runSession exits or an exception occurs. Graph extension happens -- synchronously, but the resultant run proceeds as a separate thread. asyncProdNodes :: Nodes t => t -> Session () -- | An action for building nodes in a TensorFlow graph. type Build = BuildT Identity -- | An action for building nodes in a TensorFlow graph. Used to manage -- build state internally as part of the Session monad. data BuildT m a -- | Render a Tensor, fixing its name, scope, device and control -- inputs from the MonadBuild context. Also renders any -- dependencies of the Tensor that weren't already rendered. -- -- This operation is idempotent; calling render on the same input -- in the same context will produce the same result. However, rendering -- the same Tensor Build in two different contexts may result in -- two different Tensor Values. render :: MonadBuild m => Tensor Build a -> m (Tensor Value a) -- | Produce a GraphDef proto representation of the nodes that are rendered -- in the given Build action. asGraphDef :: Build a -> GraphDef addGraphDef :: MonadBuild m => GraphDef -> m () opName :: Lens' OpDef PendingNodeName opAttr :: Attribute a => Text -> Lens' OpDef a -- | A type of graph node which has no outputs. These nodes are valuable -- for causing side effects when they are run. data ControlNode -- | A named output of a TensorFlow operation. -- -- The type parameter a is the type of the elements in the -- Tensor. The parameter v is either: -- -- -- -- Note that expr, value, render and -- renderValue can help convert between the different types of -- Tensor. data Tensor v a data Value a data Ref a -- | Cast a 'Tensor Ref' into a 'Tensor Value'. This behaves like a no-op. value :: Tensor Ref a -> Tensor Value a -- | Create a Tensor for a given name. This can be used to reference -- nodes in a GraphDef that was loaded via addGraphDef. -- TODO(judahjacobson): add more safety checks here. tensorFromName :: TensorKind v => Text -> Tensor v a expr :: TensorKind v => Tensor v a -> Tensor Build a -- | The class of scalar types supported by tensorflow. class TensorType a -- | Tensor data with the correct memory layout for tensorflow. data TensorData a -- | Types that can be converted to and from TensorData. -- -- Vector is the most efficient to encode/decode for most element -- types. class TensorType a => TensorDataType s a -- | Decode the bytes of a TensorData into an s. decodeTensorData :: TensorDataType s a => TensorData a -> s a -- | Encode an s into a TensorData. -- -- The values should be in row major order, e.g., -- -- element 0: index (0, ..., 0) element 1: index (0, ..., 1) ... encodeTensorData :: TensorDataType s a => Shape -> s a -> TensorData a newtype Scalar a Scalar :: a -> Scalar a [unScalar] :: Scalar a -> a -- | Shape (dimensions) of a tensor. newtype Shape Shape :: [Int64] -> Shape -- | A Constraint specifying the possible choices of a -- TensorType. -- -- We implement a Constraint like OneOf '[Double, Float] -- a by turning the natural representation as a conjunction, i.e., -- --
--   a == Double || a == Float
--   
-- -- into a disjunction like -- --
--   a /= Int32 && a /= Int64 && a /= ByteString && ...
--   
-- -- using an enumeration of all the possible TensorTypes. type OneOf ts a = (TensorType a, TensorTypes ts, NoneOf (AllTensorTypes \\ ts) a) -- | A constraint checking that two types are different. -- | Places all nodes rendered in the given Build action on the same -- device as the given Tensor (see also withDevice). Make sure -- that the action has side effects of rendering the desired tensors. A -- pure return would not have the desired effect. colocateWith :: (MonadBuild m, Rendered v) => Tensor v b -> m a -> m a -- | A device that a node can be assigned to. There's a naming convention -- where the device names are constructed from job and replica names. newtype Device Device :: Text -> Device [deviceName] :: Device -> Text -- | Set a device for all nodes rendered in the given Build action -- (unless further overridden by another use of withDevice). withDevice :: MonadBuild m => Maybe Device -> m a -> m a -- | Prepend a scope to all nodes rendered in the given Build -- action. withNameScope :: MonadBuild m => Text -> m a -> m a -- | Modify a Build action, such that all new ops rendered in it -- will depend on the nodes in the first argument. withControlDependencies :: (MonadBuild m, Nodes t) => t -> m a -> m a -- | Create an op that groups multiple operations. -- -- When this op finishes, all ops in the input n have finished. -- This op has no output. group :: (MonadBuild m, Nodes t) => t -> m ControlNode -- | Does nothing. Only useful as a placeholder for control edges. noOp :: MonadBuild m => m ControlNode