{- This file was auto-generated from google_protobuf.proto by the proto-lens-protoc program. -} {-# LANGUAGE ScopedTypeVariables, DataKinds, TypeFamilies, UndecidableInstances, GeneralizedNewtypeDeriving, MultiParamTypeClasses, FlexibleContexts, FlexibleInstances, PatternSynonyms, MagicHash, NoImplicitPrelude, DataKinds, BangPatterns, TypeApplications, OverloadedStrings, DerivingStrategies#-} {-# OPTIONS_GHC -Wno-unused-imports#-} {-# OPTIONS_GHC -Wno-duplicate-exports#-} {-# OPTIONS_GHC -Wno-dodgy-exports#-} module Proto.GoogleProtobuf ( BoolValue(), BytesValue(), DoubleValue(), FloatValue(), Int32Value(), Int64Value(), StringValue(), Timestamp(), UInt32Value(), UInt64Value() ) where import qualified Data.ProtoLens.Runtime.Control.DeepSeq as Control.DeepSeq import qualified Data.ProtoLens.Runtime.Data.ProtoLens.Prism as Data.ProtoLens.Prism import qualified Data.ProtoLens.Runtime.Prelude as Prelude import qualified Data.ProtoLens.Runtime.Data.Int as Data.Int import qualified Data.ProtoLens.Runtime.Data.Monoid as Data.Monoid import qualified Data.ProtoLens.Runtime.Data.Word as Data.Word import qualified Data.ProtoLens.Runtime.Data.ProtoLens as Data.ProtoLens import qualified Data.ProtoLens.Runtime.Data.ProtoLens.Encoding.Bytes as Data.ProtoLens.Encoding.Bytes import qualified Data.ProtoLens.Runtime.Data.ProtoLens.Encoding.Growing as Data.ProtoLens.Encoding.Growing import qualified Data.ProtoLens.Runtime.Data.ProtoLens.Encoding.Parser.Unsafe as Data.ProtoLens.Encoding.Parser.Unsafe import qualified Data.ProtoLens.Runtime.Data.ProtoLens.Encoding.Wire as Data.ProtoLens.Encoding.Wire import qualified Data.ProtoLens.Runtime.Data.ProtoLens.Field as Data.ProtoLens.Field import qualified Data.ProtoLens.Runtime.Data.ProtoLens.Message.Enum as Data.ProtoLens.Message.Enum import qualified Data.ProtoLens.Runtime.Data.ProtoLens.Service.Types as Data.ProtoLens.Service.Types import qualified Data.ProtoLens.Runtime.Lens.Family2 as Lens.Family2 import qualified Data.ProtoLens.Runtime.Lens.Family2.Unchecked as Lens.Family2.Unchecked import qualified Data.ProtoLens.Runtime.Data.Text as Data.Text import qualified Data.ProtoLens.Runtime.Data.Map as Data.Map import qualified Data.ProtoLens.Runtime.Data.ByteString as Data.ByteString import qualified Data.ProtoLens.Runtime.Data.ByteString.Char8 as Data.ByteString.Char8 import qualified Data.ProtoLens.Runtime.Data.Text.Encoding as Data.Text.Encoding import qualified Data.ProtoLens.Runtime.Data.Vector as Data.Vector import qualified Data.ProtoLens.Runtime.Data.Vector.Generic as Data.Vector.Generic import qualified Data.ProtoLens.Runtime.Data.Vector.Unboxed as Data.Vector.Unboxed import qualified Data.ProtoLens.Runtime.Text.Read as Text.Read {- | Fields : * 'Proto.GoogleProtobuf_Fields.value' @:: Lens' BoolValue Prelude.Bool@ -} data BoolValue = BoolValue'_constructor {_BoolValue'value :: !Prelude.Bool, _BoolValue'_unknownFields :: !Data.ProtoLens.FieldSet} deriving stock (Prelude.Eq, Prelude.Ord) instance Prelude.Show BoolValue where showsPrec _ __x __s = Prelude.showChar '{' (Prelude.showString (Data.ProtoLens.showMessageShort __x) (Prelude.showChar '}' __s)) instance Data.ProtoLens.Field.HasField BoolValue "value" Prelude.Bool where fieldOf _ = (Prelude..) (Lens.Family2.Unchecked.lens _BoolValue'value (\ x__ y__ -> x__ {_BoolValue'value = y__})) Prelude.id instance Data.ProtoLens.Message BoolValue where messageName _ = Data.Text.pack "Google.Protobuf.BoolValue" packedMessageDescriptor _ = "\n\ \\tBoolValue\DC2\DC4\n\ \\ENQvalue\CAN\SOH \SOH(\bR\ENQvalue" packedFileDescriptor _ = packedFileDescriptor fieldsByTag = let value__field_descriptor = Data.ProtoLens.FieldDescriptor "value" (Data.ProtoLens.ScalarField Data.ProtoLens.BoolField :: Data.ProtoLens.FieldTypeDescriptor Prelude.Bool) (Data.ProtoLens.PlainField Data.ProtoLens.Optional (Data.ProtoLens.Field.field @"value")) :: Data.ProtoLens.FieldDescriptor BoolValue in Data.Map.fromList [(Data.ProtoLens.Tag 1, value__field_descriptor)] unknownFields = Lens.Family2.Unchecked.lens _BoolValue'_unknownFields (\ x__ y__ -> x__ {_BoolValue'_unknownFields = y__}) defMessage = BoolValue'_constructor {_BoolValue'value = Data.ProtoLens.fieldDefault, _BoolValue'_unknownFields = []} parseMessage = let loop :: BoolValue -> Data.ProtoLens.Encoding.Bytes.Parser BoolValue loop x = do end <- Data.ProtoLens.Encoding.Bytes.atEnd if end then do (let missing = [] in if Prelude.null missing then Prelude.return () else Prelude.fail ((Prelude.++) "Missing required fields: " (Prelude.show (missing :: [Prelude.String])))) Prelude.return (Lens.Family2.over Data.ProtoLens.unknownFields (\ !t -> Prelude.reverse t) x) else do tag <- Data.ProtoLens.Encoding.Bytes.getVarInt case tag of 8 -> do y <- (Data.ProtoLens.Encoding.Bytes.) (Prelude.fmap ((Prelude./=) 0) Data.ProtoLens.Encoding.Bytes.getVarInt) "value" loop (Lens.Family2.set (Data.ProtoLens.Field.field @"value") y x) wire -> do !y <- Data.ProtoLens.Encoding.Wire.parseTaggedValueFromWire wire loop (Lens.Family2.over Data.ProtoLens.unknownFields (\ !t -> (:) y t) x) in (Data.ProtoLens.Encoding.Bytes.) (do loop Data.ProtoLens.defMessage) "BoolValue" buildMessage = \ _x -> (Data.Monoid.<>) (let _v = Lens.Family2.view (Data.ProtoLens.Field.field @"value") _x in if (Prelude.==) _v Data.ProtoLens.fieldDefault then Data.Monoid.mempty else (Data.Monoid.<>) (Data.ProtoLens.Encoding.Bytes.putVarInt 8) ((Prelude..) Data.ProtoLens.Encoding.Bytes.putVarInt (\ b -> if b then 1 else 0) _v)) (Data.ProtoLens.Encoding.Wire.buildFieldSet (Lens.Family2.view Data.ProtoLens.unknownFields _x)) instance Control.DeepSeq.NFData BoolValue where rnf = \ x__ -> Control.DeepSeq.deepseq (_BoolValue'_unknownFields x__) (Control.DeepSeq.deepseq (_BoolValue'value x__) ()) {- | Fields : * 'Proto.GoogleProtobuf_Fields.value' @:: Lens' BytesValue Data.ByteString.ByteString@ -} data BytesValue = BytesValue'_constructor {_BytesValue'value :: !Data.ByteString.ByteString, _BytesValue'_unknownFields :: !Data.ProtoLens.FieldSet} deriving stock (Prelude.Eq, Prelude.Ord) instance Prelude.Show BytesValue where showsPrec _ __x __s = Prelude.showChar '{' (Prelude.showString (Data.ProtoLens.showMessageShort __x) (Prelude.showChar '}' __s)) instance Data.ProtoLens.Field.HasField BytesValue "value" Data.ByteString.ByteString where fieldOf _ = (Prelude..) (Lens.Family2.Unchecked.lens _BytesValue'value (\ x__ y__ -> x__ {_BytesValue'value = y__})) Prelude.id instance Data.ProtoLens.Message BytesValue where messageName _ = Data.Text.pack "Google.Protobuf.BytesValue" packedMessageDescriptor _ = "\n\ \\n\ \BytesValue\DC2\DC4\n\ \\ENQvalue\CAN\SOH \SOH(\fR\ENQvalue" packedFileDescriptor _ = packedFileDescriptor fieldsByTag = let value__field_descriptor = Data.ProtoLens.FieldDescriptor "value" (Data.ProtoLens.ScalarField Data.ProtoLens.BytesField :: Data.ProtoLens.FieldTypeDescriptor Data.ByteString.ByteString) (Data.ProtoLens.PlainField Data.ProtoLens.Optional (Data.ProtoLens.Field.field @"value")) :: Data.ProtoLens.FieldDescriptor BytesValue in Data.Map.fromList [(Data.ProtoLens.Tag 1, value__field_descriptor)] unknownFields = Lens.Family2.Unchecked.lens _BytesValue'_unknownFields (\ x__ y__ -> x__ {_BytesValue'_unknownFields = y__}) defMessage = BytesValue'_constructor {_BytesValue'value = Data.ProtoLens.fieldDefault, _BytesValue'_unknownFields = []} parseMessage = let loop :: BytesValue -> Data.ProtoLens.Encoding.Bytes.Parser BytesValue loop x = do end <- Data.ProtoLens.Encoding.Bytes.atEnd if end then do (let missing = [] in if Prelude.null missing then Prelude.return () else Prelude.fail ((Prelude.++) "Missing required fields: " (Prelude.show (missing :: [Prelude.String])))) Prelude.return (Lens.Family2.over Data.ProtoLens.unknownFields (\ !t -> Prelude.reverse t) x) else do tag <- Data.ProtoLens.Encoding.Bytes.getVarInt case tag of 10 -> do y <- (Data.ProtoLens.Encoding.Bytes.) (do len <- Data.ProtoLens.Encoding.Bytes.getVarInt Data.ProtoLens.Encoding.Bytes.getBytes (Prelude.fromIntegral len)) "value" loop (Lens.Family2.set (Data.ProtoLens.Field.field @"value") y x) wire -> do !y <- Data.ProtoLens.Encoding.Wire.parseTaggedValueFromWire wire loop (Lens.Family2.over Data.ProtoLens.unknownFields (\ !t -> (:) y t) x) in (Data.ProtoLens.Encoding.Bytes.) (do loop Data.ProtoLens.defMessage) "BytesValue" buildMessage = \ _x -> (Data.Monoid.<>) (let _v = Lens.Family2.view (Data.ProtoLens.Field.field @"value") _x in if (Prelude.==) _v Data.ProtoLens.fieldDefault then Data.Monoid.mempty else (Data.Monoid.<>) (Data.ProtoLens.Encoding.Bytes.putVarInt 10) ((\ bs -> (Data.Monoid.<>) (Data.ProtoLens.Encoding.Bytes.putVarInt (Prelude.fromIntegral (Data.ByteString.length bs))) (Data.ProtoLens.Encoding.Bytes.putBytes bs)) _v)) (Data.ProtoLens.Encoding.Wire.buildFieldSet (Lens.Family2.view Data.ProtoLens.unknownFields _x)) instance Control.DeepSeq.NFData BytesValue where rnf = \ x__ -> Control.DeepSeq.deepseq (_BytesValue'_unknownFields x__) (Control.DeepSeq.deepseq (_BytesValue'value x__) ()) {- | Fields : * 'Proto.GoogleProtobuf_Fields.value' @:: Lens' DoubleValue Prelude.Double@ -} data DoubleValue = DoubleValue'_constructor {_DoubleValue'value :: !Prelude.Double, _DoubleValue'_unknownFields :: !Data.ProtoLens.FieldSet} deriving stock (Prelude.Eq, Prelude.Ord) instance Prelude.Show DoubleValue where showsPrec _ __x __s = Prelude.showChar '{' (Prelude.showString (Data.ProtoLens.showMessageShort __x) (Prelude.showChar '}' __s)) instance Data.ProtoLens.Field.HasField DoubleValue "value" Prelude.Double where fieldOf _ = (Prelude..) (Lens.Family2.Unchecked.lens _DoubleValue'value (\ x__ y__ -> x__ {_DoubleValue'value = y__})) Prelude.id instance Data.ProtoLens.Message DoubleValue where messageName _ = Data.Text.pack "Google.Protobuf.DoubleValue" packedMessageDescriptor _ = "\n\ \\vDoubleValue\DC2\DC4\n\ \\ENQvalue\CAN\SOH \SOH(\SOHR\ENQvalue" packedFileDescriptor _ = packedFileDescriptor fieldsByTag = let value__field_descriptor = Data.ProtoLens.FieldDescriptor "value" (Data.ProtoLens.ScalarField Data.ProtoLens.DoubleField :: Data.ProtoLens.FieldTypeDescriptor Prelude.Double) (Data.ProtoLens.PlainField Data.ProtoLens.Optional (Data.ProtoLens.Field.field @"value")) :: Data.ProtoLens.FieldDescriptor DoubleValue in Data.Map.fromList [(Data.ProtoLens.Tag 1, value__field_descriptor)] unknownFields = Lens.Family2.Unchecked.lens _DoubleValue'_unknownFields (\ x__ y__ -> x__ {_DoubleValue'_unknownFields = y__}) defMessage = DoubleValue'_constructor {_DoubleValue'value = Data.ProtoLens.fieldDefault, _DoubleValue'_unknownFields = []} parseMessage = let loop :: DoubleValue -> Data.ProtoLens.Encoding.Bytes.Parser DoubleValue loop x = do end <- Data.ProtoLens.Encoding.Bytes.atEnd if end then do (let missing = [] in if Prelude.null missing then Prelude.return () else Prelude.fail ((Prelude.++) "Missing required fields: " (Prelude.show (missing :: [Prelude.String])))) Prelude.return (Lens.Family2.over Data.ProtoLens.unknownFields (\ !t -> Prelude.reverse t) x) else do tag <- Data.ProtoLens.Encoding.Bytes.getVarInt case tag of 9 -> do y <- (Data.ProtoLens.Encoding.Bytes.) (Prelude.fmap Data.ProtoLens.Encoding.Bytes.wordToDouble Data.ProtoLens.Encoding.Bytes.getFixed64) "value" loop (Lens.Family2.set (Data.ProtoLens.Field.field @"value") y x) wire -> do !y <- Data.ProtoLens.Encoding.Wire.parseTaggedValueFromWire wire loop (Lens.Family2.over Data.ProtoLens.unknownFields (\ !t -> (:) y t) x) in (Data.ProtoLens.Encoding.Bytes.) (do loop Data.ProtoLens.defMessage) "DoubleValue" buildMessage = \ _x -> (Data.Monoid.<>) (let _v = Lens.Family2.view (Data.ProtoLens.Field.field @"value") _x in if (Prelude.==) _v Data.ProtoLens.fieldDefault then Data.Monoid.mempty else (Data.Monoid.<>) (Data.ProtoLens.Encoding.Bytes.putVarInt 9) ((Prelude..) Data.ProtoLens.Encoding.Bytes.putFixed64 Data.ProtoLens.Encoding.Bytes.doubleToWord _v)) (Data.ProtoLens.Encoding.Wire.buildFieldSet (Lens.Family2.view Data.ProtoLens.unknownFields _x)) instance Control.DeepSeq.NFData DoubleValue where rnf = \ x__ -> Control.DeepSeq.deepseq (_DoubleValue'_unknownFields x__) (Control.DeepSeq.deepseq (_DoubleValue'value x__) ()) {- | Fields : * 'Proto.GoogleProtobuf_Fields.value' @:: Lens' FloatValue Prelude.Float@ -} data FloatValue = FloatValue'_constructor {_FloatValue'value :: !Prelude.Float, _FloatValue'_unknownFields :: !Data.ProtoLens.FieldSet} deriving stock (Prelude.Eq, Prelude.Ord) instance Prelude.Show FloatValue where showsPrec _ __x __s = Prelude.showChar '{' (Prelude.showString (Data.ProtoLens.showMessageShort __x) (Prelude.showChar '}' __s)) instance Data.ProtoLens.Field.HasField FloatValue "value" Prelude.Float where fieldOf _ = (Prelude..) (Lens.Family2.Unchecked.lens _FloatValue'value (\ x__ y__ -> x__ {_FloatValue'value = y__})) Prelude.id instance Data.ProtoLens.Message FloatValue where messageName _ = Data.Text.pack "Google.Protobuf.FloatValue" packedMessageDescriptor _ = "\n\ \\n\ \FloatValue\DC2\DC4\n\ \\ENQvalue\CAN\SOH \SOH(\STXR\ENQvalue" packedFileDescriptor _ = packedFileDescriptor fieldsByTag = let value__field_descriptor = Data.ProtoLens.FieldDescriptor "value" (Data.ProtoLens.ScalarField Data.ProtoLens.FloatField :: Data.ProtoLens.FieldTypeDescriptor Prelude.Float) (Data.ProtoLens.PlainField Data.ProtoLens.Optional (Data.ProtoLens.Field.field @"value")) :: Data.ProtoLens.FieldDescriptor FloatValue in Data.Map.fromList [(Data.ProtoLens.Tag 1, value__field_descriptor)] unknownFields = Lens.Family2.Unchecked.lens _FloatValue'_unknownFields (\ x__ y__ -> x__ {_FloatValue'_unknownFields = y__}) defMessage = FloatValue'_constructor {_FloatValue'value = Data.ProtoLens.fieldDefault, _FloatValue'_unknownFields = []} parseMessage = let loop :: FloatValue -> Data.ProtoLens.Encoding.Bytes.Parser FloatValue loop x = do end <- Data.ProtoLens.Encoding.Bytes.atEnd if end then do (let missing = [] in if Prelude.null missing then Prelude.return () else Prelude.fail ((Prelude.++) "Missing required fields: " (Prelude.show (missing :: [Prelude.String])))) Prelude.return (Lens.Family2.over Data.ProtoLens.unknownFields (\ !t -> Prelude.reverse t) x) else do tag <- Data.ProtoLens.Encoding.Bytes.getVarInt case tag of 13 -> do y <- (Data.ProtoLens.Encoding.Bytes.) (Prelude.fmap Data.ProtoLens.Encoding.Bytes.wordToFloat Data.ProtoLens.Encoding.Bytes.getFixed32) "value" loop (Lens.Family2.set (Data.ProtoLens.Field.field @"value") y x) wire -> do !y <- Data.ProtoLens.Encoding.Wire.parseTaggedValueFromWire wire loop (Lens.Family2.over Data.ProtoLens.unknownFields (\ !t -> (:) y t) x) in (Data.ProtoLens.Encoding.Bytes.) (do loop Data.ProtoLens.defMessage) "FloatValue" buildMessage = \ _x -> (Data.Monoid.<>) (let _v = Lens.Family2.view (Data.ProtoLens.Field.field @"value") _x in if (Prelude.==) _v Data.ProtoLens.fieldDefault then Data.Monoid.mempty else (Data.Monoid.<>) (Data.ProtoLens.Encoding.Bytes.putVarInt 13) ((Prelude..) Data.ProtoLens.Encoding.Bytes.putFixed32 Data.ProtoLens.Encoding.Bytes.floatToWord _v)) (Data.ProtoLens.Encoding.Wire.buildFieldSet (Lens.Family2.view Data.ProtoLens.unknownFields _x)) instance Control.DeepSeq.NFData FloatValue where rnf = \ x__ -> Control.DeepSeq.deepseq (_FloatValue'_unknownFields x__) (Control.DeepSeq.deepseq (_FloatValue'value x__) ()) {- | Fields : * 'Proto.GoogleProtobuf_Fields.value' @:: Lens' Int32Value Data.Int.Int32@ -} data Int32Value = Int32Value'_constructor {_Int32Value'value :: !Data.Int.Int32, _Int32Value'_unknownFields :: !Data.ProtoLens.FieldSet} deriving stock (Prelude.Eq, Prelude.Ord) instance Prelude.Show Int32Value where showsPrec _ __x __s = Prelude.showChar '{' (Prelude.showString (Data.ProtoLens.showMessageShort __x) (Prelude.showChar '}' __s)) instance Data.ProtoLens.Field.HasField Int32Value "value" Data.Int.Int32 where fieldOf _ = (Prelude..) (Lens.Family2.Unchecked.lens _Int32Value'value (\ x__ y__ -> x__ {_Int32Value'value = y__})) Prelude.id instance Data.ProtoLens.Message Int32Value where messageName _ = Data.Text.pack "Google.Protobuf.Int32Value" packedMessageDescriptor _ = "\n\ \\n\ \Int32Value\DC2\DC4\n\ \\ENQvalue\CAN\SOH \SOH(\ENQR\ENQvalue" packedFileDescriptor _ = packedFileDescriptor fieldsByTag = let value__field_descriptor = Data.ProtoLens.FieldDescriptor "value" (Data.ProtoLens.ScalarField Data.ProtoLens.Int32Field :: Data.ProtoLens.FieldTypeDescriptor Data.Int.Int32) (Data.ProtoLens.PlainField Data.ProtoLens.Optional (Data.ProtoLens.Field.field @"value")) :: Data.ProtoLens.FieldDescriptor Int32Value in Data.Map.fromList [(Data.ProtoLens.Tag 1, value__field_descriptor)] unknownFields = Lens.Family2.Unchecked.lens _Int32Value'_unknownFields (\ x__ y__ -> x__ {_Int32Value'_unknownFields = y__}) defMessage = Int32Value'_constructor {_Int32Value'value = Data.ProtoLens.fieldDefault, _Int32Value'_unknownFields = []} parseMessage = let loop :: Int32Value -> Data.ProtoLens.Encoding.Bytes.Parser Int32Value loop x = do end <- Data.ProtoLens.Encoding.Bytes.atEnd if end then do (let missing = [] in if Prelude.null missing then Prelude.return () else Prelude.fail ((Prelude.++) "Missing required fields: " (Prelude.show (missing :: [Prelude.String])))) Prelude.return (Lens.Family2.over Data.ProtoLens.unknownFields (\ !t -> Prelude.reverse t) x) else do tag <- Data.ProtoLens.Encoding.Bytes.getVarInt case tag of 8 -> do y <- (Data.ProtoLens.Encoding.Bytes.) (Prelude.fmap Prelude.fromIntegral Data.ProtoLens.Encoding.Bytes.getVarInt) "value" loop (Lens.Family2.set (Data.ProtoLens.Field.field @"value") y x) wire -> do !y <- Data.ProtoLens.Encoding.Wire.parseTaggedValueFromWire wire loop (Lens.Family2.over Data.ProtoLens.unknownFields (\ !t -> (:) y t) x) in (Data.ProtoLens.Encoding.Bytes.) (do loop Data.ProtoLens.defMessage) "Int32Value" buildMessage = \ _x -> (Data.Monoid.<>) (let _v = Lens.Family2.view (Data.ProtoLens.Field.field @"value") _x in if (Prelude.==) _v Data.ProtoLens.fieldDefault then Data.Monoid.mempty else (Data.Monoid.<>) (Data.ProtoLens.Encoding.Bytes.putVarInt 8) ((Prelude..) Data.ProtoLens.Encoding.Bytes.putVarInt Prelude.fromIntegral _v)) (Data.ProtoLens.Encoding.Wire.buildFieldSet (Lens.Family2.view Data.ProtoLens.unknownFields _x)) instance Control.DeepSeq.NFData Int32Value where rnf = \ x__ -> Control.DeepSeq.deepseq (_Int32Value'_unknownFields x__) (Control.DeepSeq.deepseq (_Int32Value'value x__) ()) {- | Fields : * 'Proto.GoogleProtobuf_Fields.value' @:: Lens' Int64Value Data.Int.Int64@ -} data Int64Value = Int64Value'_constructor {_Int64Value'value :: !Data.Int.Int64, _Int64Value'_unknownFields :: !Data.ProtoLens.FieldSet} deriving stock (Prelude.Eq, Prelude.Ord) instance Prelude.Show Int64Value where showsPrec _ __x __s = Prelude.showChar '{' (Prelude.showString (Data.ProtoLens.showMessageShort __x) (Prelude.showChar '}' __s)) instance Data.ProtoLens.Field.HasField Int64Value "value" Data.Int.Int64 where fieldOf _ = (Prelude..) (Lens.Family2.Unchecked.lens _Int64Value'value (\ x__ y__ -> x__ {_Int64Value'value = y__})) Prelude.id instance Data.ProtoLens.Message Int64Value where messageName _ = Data.Text.pack "Google.Protobuf.Int64Value" packedMessageDescriptor _ = "\n\ \\n\ \Int64Value\DC2\DC4\n\ \\ENQvalue\CAN\SOH \SOH(\ETXR\ENQvalue" packedFileDescriptor _ = packedFileDescriptor fieldsByTag = let value__field_descriptor = Data.ProtoLens.FieldDescriptor "value" (Data.ProtoLens.ScalarField Data.ProtoLens.Int64Field :: Data.ProtoLens.FieldTypeDescriptor Data.Int.Int64) (Data.ProtoLens.PlainField Data.ProtoLens.Optional (Data.ProtoLens.Field.field @"value")) :: Data.ProtoLens.FieldDescriptor Int64Value in Data.Map.fromList [(Data.ProtoLens.Tag 1, value__field_descriptor)] unknownFields = Lens.Family2.Unchecked.lens _Int64Value'_unknownFields (\ x__ y__ -> x__ {_Int64Value'_unknownFields = y__}) defMessage = Int64Value'_constructor {_Int64Value'value = Data.ProtoLens.fieldDefault, _Int64Value'_unknownFields = []} parseMessage = let loop :: Int64Value -> Data.ProtoLens.Encoding.Bytes.Parser Int64Value loop x = do end <- Data.ProtoLens.Encoding.Bytes.atEnd if end then do (let missing = [] in if Prelude.null missing then Prelude.return () else Prelude.fail ((Prelude.++) "Missing required fields: " (Prelude.show (missing :: [Prelude.String])))) Prelude.return (Lens.Family2.over Data.ProtoLens.unknownFields (\ !t -> Prelude.reverse t) x) else do tag <- Data.ProtoLens.Encoding.Bytes.getVarInt case tag of 8 -> do y <- (Data.ProtoLens.Encoding.Bytes.) (Prelude.fmap Prelude.fromIntegral Data.ProtoLens.Encoding.Bytes.getVarInt) "value" loop (Lens.Family2.set (Data.ProtoLens.Field.field @"value") y x) wire -> do !y <- Data.ProtoLens.Encoding.Wire.parseTaggedValueFromWire wire loop (Lens.Family2.over Data.ProtoLens.unknownFields (\ !t -> (:) y t) x) in (Data.ProtoLens.Encoding.Bytes.) (do loop Data.ProtoLens.defMessage) "Int64Value" buildMessage = \ _x -> (Data.Monoid.<>) (let _v = Lens.Family2.view (Data.ProtoLens.Field.field @"value") _x in if (Prelude.==) _v Data.ProtoLens.fieldDefault then Data.Monoid.mempty else (Data.Monoid.<>) (Data.ProtoLens.Encoding.Bytes.putVarInt 8) ((Prelude..) Data.ProtoLens.Encoding.Bytes.putVarInt Prelude.fromIntegral _v)) (Data.ProtoLens.Encoding.Wire.buildFieldSet (Lens.Family2.view Data.ProtoLens.unknownFields _x)) instance Control.DeepSeq.NFData Int64Value where rnf = \ x__ -> Control.DeepSeq.deepseq (_Int64Value'_unknownFields x__) (Control.DeepSeq.deepseq (_Int64Value'value x__) ()) {- | Fields : * 'Proto.GoogleProtobuf_Fields.value' @:: Lens' StringValue Data.Text.Text@ -} data StringValue = StringValue'_constructor {_StringValue'value :: !Data.Text.Text, _StringValue'_unknownFields :: !Data.ProtoLens.FieldSet} deriving stock (Prelude.Eq, Prelude.Ord) instance Prelude.Show StringValue where showsPrec _ __x __s = Prelude.showChar '{' (Prelude.showString (Data.ProtoLens.showMessageShort __x) (Prelude.showChar '}' __s)) instance Data.ProtoLens.Field.HasField StringValue "value" Data.Text.Text where fieldOf _ = (Prelude..) (Lens.Family2.Unchecked.lens _StringValue'value (\ x__ y__ -> x__ {_StringValue'value = y__})) Prelude.id instance Data.ProtoLens.Message StringValue where messageName _ = Data.Text.pack "Google.Protobuf.StringValue" packedMessageDescriptor _ = "\n\ \\vStringValue\DC2\DC4\n\ \\ENQvalue\CAN\SOH \SOH(\tR\ENQvalue" packedFileDescriptor _ = packedFileDescriptor fieldsByTag = let value__field_descriptor = Data.ProtoLens.FieldDescriptor "value" (Data.ProtoLens.ScalarField Data.ProtoLens.StringField :: Data.ProtoLens.FieldTypeDescriptor Data.Text.Text) (Data.ProtoLens.PlainField Data.ProtoLens.Optional (Data.ProtoLens.Field.field @"value")) :: Data.ProtoLens.FieldDescriptor StringValue in Data.Map.fromList [(Data.ProtoLens.Tag 1, value__field_descriptor)] unknownFields = Lens.Family2.Unchecked.lens _StringValue'_unknownFields (\ x__ y__ -> x__ {_StringValue'_unknownFields = y__}) defMessage = StringValue'_constructor {_StringValue'value = Data.ProtoLens.fieldDefault, _StringValue'_unknownFields = []} parseMessage = let loop :: StringValue -> Data.ProtoLens.Encoding.Bytes.Parser StringValue loop x = do end <- Data.ProtoLens.Encoding.Bytes.atEnd if end then do (let missing = [] in if Prelude.null missing then Prelude.return () else Prelude.fail ((Prelude.++) "Missing required fields: " (Prelude.show (missing :: [Prelude.String])))) Prelude.return (Lens.Family2.over Data.ProtoLens.unknownFields (\ !t -> Prelude.reverse t) x) else do tag <- Data.ProtoLens.Encoding.Bytes.getVarInt case tag of 10 -> do y <- (Data.ProtoLens.Encoding.Bytes.) (do value <- do len <- Data.ProtoLens.Encoding.Bytes.getVarInt Data.ProtoLens.Encoding.Bytes.getBytes (Prelude.fromIntegral len) Data.ProtoLens.Encoding.Bytes.runEither (case Data.Text.Encoding.decodeUtf8' value of (Prelude.Left err) -> Prelude.Left (Prelude.show err) (Prelude.Right r) -> Prelude.Right r)) "value" loop (Lens.Family2.set (Data.ProtoLens.Field.field @"value") y x) wire -> do !y <- Data.ProtoLens.Encoding.Wire.parseTaggedValueFromWire wire loop (Lens.Family2.over Data.ProtoLens.unknownFields (\ !t -> (:) y t) x) in (Data.ProtoLens.Encoding.Bytes.) (do loop Data.ProtoLens.defMessage) "StringValue" buildMessage = \ _x -> (Data.Monoid.<>) (let _v = Lens.Family2.view (Data.ProtoLens.Field.field @"value") _x in if (Prelude.==) _v Data.ProtoLens.fieldDefault then Data.Monoid.mempty else (Data.Monoid.<>) (Data.ProtoLens.Encoding.Bytes.putVarInt 10) ((Prelude..) (\ bs -> (Data.Monoid.<>) (Data.ProtoLens.Encoding.Bytes.putVarInt (Prelude.fromIntegral (Data.ByteString.length bs))) (Data.ProtoLens.Encoding.Bytes.putBytes bs)) Data.Text.Encoding.encodeUtf8 _v)) (Data.ProtoLens.Encoding.Wire.buildFieldSet (Lens.Family2.view Data.ProtoLens.unknownFields _x)) instance Control.DeepSeq.NFData StringValue where rnf = \ x__ -> Control.DeepSeq.deepseq (_StringValue'_unknownFields x__) (Control.DeepSeq.deepseq (_StringValue'value x__) ()) {- | Fields : * 'Proto.GoogleProtobuf_Fields.seconds' @:: Lens' Timestamp Data.Int.Int64@ * 'Proto.GoogleProtobuf_Fields.nanos' @:: Lens' Timestamp Data.Int.Int32@ -} data Timestamp = Timestamp'_constructor {_Timestamp'seconds :: !Data.Int.Int64, _Timestamp'nanos :: !Data.Int.Int32, _Timestamp'_unknownFields :: !Data.ProtoLens.FieldSet} deriving stock (Prelude.Eq, Prelude.Ord) instance Prelude.Show Timestamp where showsPrec _ __x __s = Prelude.showChar '{' (Prelude.showString (Data.ProtoLens.showMessageShort __x) (Prelude.showChar '}' __s)) instance Data.ProtoLens.Field.HasField Timestamp "seconds" Data.Int.Int64 where fieldOf _ = (Prelude..) (Lens.Family2.Unchecked.lens _Timestamp'seconds (\ x__ y__ -> x__ {_Timestamp'seconds = y__})) Prelude.id instance Data.ProtoLens.Field.HasField Timestamp "nanos" Data.Int.Int32 where fieldOf _ = (Prelude..) (Lens.Family2.Unchecked.lens _Timestamp'nanos (\ x__ y__ -> x__ {_Timestamp'nanos = y__})) Prelude.id instance Data.ProtoLens.Message Timestamp where messageName _ = Data.Text.pack "Google.Protobuf.Timestamp" packedMessageDescriptor _ = "\n\ \\tTimestamp\DC2\CAN\n\ \\aseconds\CAN\SOH \SOH(\ETXR\aseconds\DC2\DC4\n\ \\ENQnanos\CAN\STX \SOH(\ENQR\ENQnanos" packedFileDescriptor _ = packedFileDescriptor fieldsByTag = let seconds__field_descriptor = Data.ProtoLens.FieldDescriptor "seconds" (Data.ProtoLens.ScalarField Data.ProtoLens.Int64Field :: Data.ProtoLens.FieldTypeDescriptor Data.Int.Int64) (Data.ProtoLens.PlainField Data.ProtoLens.Optional (Data.ProtoLens.Field.field @"seconds")) :: Data.ProtoLens.FieldDescriptor Timestamp nanos__field_descriptor = Data.ProtoLens.FieldDescriptor "nanos" (Data.ProtoLens.ScalarField Data.ProtoLens.Int32Field :: Data.ProtoLens.FieldTypeDescriptor Data.Int.Int32) (Data.ProtoLens.PlainField Data.ProtoLens.Optional (Data.ProtoLens.Field.field @"nanos")) :: Data.ProtoLens.FieldDescriptor Timestamp in Data.Map.fromList [(Data.ProtoLens.Tag 1, seconds__field_descriptor), (Data.ProtoLens.Tag 2, nanos__field_descriptor)] unknownFields = Lens.Family2.Unchecked.lens _Timestamp'_unknownFields (\ x__ y__ -> x__ {_Timestamp'_unknownFields = y__}) defMessage = Timestamp'_constructor {_Timestamp'seconds = Data.ProtoLens.fieldDefault, _Timestamp'nanos = Data.ProtoLens.fieldDefault, _Timestamp'_unknownFields = []} parseMessage = let loop :: Timestamp -> Data.ProtoLens.Encoding.Bytes.Parser Timestamp loop x = do end <- Data.ProtoLens.Encoding.Bytes.atEnd if end then do (let missing = [] in if Prelude.null missing then Prelude.return () else Prelude.fail ((Prelude.++) "Missing required fields: " (Prelude.show (missing :: [Prelude.String])))) Prelude.return (Lens.Family2.over Data.ProtoLens.unknownFields (\ !t -> Prelude.reverse t) x) else do tag <- Data.ProtoLens.Encoding.Bytes.getVarInt case tag of 8 -> do y <- (Data.ProtoLens.Encoding.Bytes.) (Prelude.fmap Prelude.fromIntegral Data.ProtoLens.Encoding.Bytes.getVarInt) "seconds" loop (Lens.Family2.set (Data.ProtoLens.Field.field @"seconds") y x) 16 -> do y <- (Data.ProtoLens.Encoding.Bytes.) (Prelude.fmap Prelude.fromIntegral Data.ProtoLens.Encoding.Bytes.getVarInt) "nanos" loop (Lens.Family2.set (Data.ProtoLens.Field.field @"nanos") y x) wire -> do !y <- Data.ProtoLens.Encoding.Wire.parseTaggedValueFromWire wire loop (Lens.Family2.over Data.ProtoLens.unknownFields (\ !t -> (:) y t) x) in (Data.ProtoLens.Encoding.Bytes.) (do loop Data.ProtoLens.defMessage) "Timestamp" buildMessage = \ _x -> (Data.Monoid.<>) (let _v = Lens.Family2.view (Data.ProtoLens.Field.field @"seconds") _x in if (Prelude.==) _v Data.ProtoLens.fieldDefault then Data.Monoid.mempty else (Data.Monoid.<>) (Data.ProtoLens.Encoding.Bytes.putVarInt 8) ((Prelude..) Data.ProtoLens.Encoding.Bytes.putVarInt Prelude.fromIntegral _v)) ((Data.Monoid.<>) (let _v = Lens.Family2.view (Data.ProtoLens.Field.field @"nanos") _x in if (Prelude.==) _v Data.ProtoLens.fieldDefault then Data.Monoid.mempty else (Data.Monoid.<>) (Data.ProtoLens.Encoding.Bytes.putVarInt 16) ((Prelude..) Data.ProtoLens.Encoding.Bytes.putVarInt Prelude.fromIntegral _v)) (Data.ProtoLens.Encoding.Wire.buildFieldSet (Lens.Family2.view Data.ProtoLens.unknownFields _x))) instance Control.DeepSeq.NFData Timestamp where rnf = \ x__ -> Control.DeepSeq.deepseq (_Timestamp'_unknownFields x__) (Control.DeepSeq.deepseq (_Timestamp'seconds x__) (Control.DeepSeq.deepseq (_Timestamp'nanos x__) ())) {- | Fields : * 'Proto.GoogleProtobuf_Fields.value' @:: Lens' UInt32Value Data.Word.Word32@ -} data UInt32Value = UInt32Value'_constructor {_UInt32Value'value :: !Data.Word.Word32, _UInt32Value'_unknownFields :: !Data.ProtoLens.FieldSet} deriving stock (Prelude.Eq, Prelude.Ord) instance Prelude.Show UInt32Value where showsPrec _ __x __s = Prelude.showChar '{' (Prelude.showString (Data.ProtoLens.showMessageShort __x) (Prelude.showChar '}' __s)) instance Data.ProtoLens.Field.HasField UInt32Value "value" Data.Word.Word32 where fieldOf _ = (Prelude..) (Lens.Family2.Unchecked.lens _UInt32Value'value (\ x__ y__ -> x__ {_UInt32Value'value = y__})) Prelude.id instance Data.ProtoLens.Message UInt32Value where messageName _ = Data.Text.pack "Google.Protobuf.UInt32Value" packedMessageDescriptor _ = "\n\ \\vUInt32Value\DC2\DC4\n\ \\ENQvalue\CAN\SOH \SOH(\rR\ENQvalue" packedFileDescriptor _ = packedFileDescriptor fieldsByTag = let value__field_descriptor = Data.ProtoLens.FieldDescriptor "value" (Data.ProtoLens.ScalarField Data.ProtoLens.UInt32Field :: Data.ProtoLens.FieldTypeDescriptor Data.Word.Word32) (Data.ProtoLens.PlainField Data.ProtoLens.Optional (Data.ProtoLens.Field.field @"value")) :: Data.ProtoLens.FieldDescriptor UInt32Value in Data.Map.fromList [(Data.ProtoLens.Tag 1, value__field_descriptor)] unknownFields = Lens.Family2.Unchecked.lens _UInt32Value'_unknownFields (\ x__ y__ -> x__ {_UInt32Value'_unknownFields = y__}) defMessage = UInt32Value'_constructor {_UInt32Value'value = Data.ProtoLens.fieldDefault, _UInt32Value'_unknownFields = []} parseMessage = let loop :: UInt32Value -> Data.ProtoLens.Encoding.Bytes.Parser UInt32Value loop x = do end <- Data.ProtoLens.Encoding.Bytes.atEnd if end then do (let missing = [] in if Prelude.null missing then Prelude.return () else Prelude.fail ((Prelude.++) "Missing required fields: " (Prelude.show (missing :: [Prelude.String])))) Prelude.return (Lens.Family2.over Data.ProtoLens.unknownFields (\ !t -> Prelude.reverse t) x) else do tag <- Data.ProtoLens.Encoding.Bytes.getVarInt case tag of 8 -> do y <- (Data.ProtoLens.Encoding.Bytes.) (Prelude.fmap Prelude.fromIntegral Data.ProtoLens.Encoding.Bytes.getVarInt) "value" loop (Lens.Family2.set (Data.ProtoLens.Field.field @"value") y x) wire -> do !y <- Data.ProtoLens.Encoding.Wire.parseTaggedValueFromWire wire loop (Lens.Family2.over Data.ProtoLens.unknownFields (\ !t -> (:) y t) x) in (Data.ProtoLens.Encoding.Bytes.) (do loop Data.ProtoLens.defMessage) "UInt32Value" buildMessage = \ _x -> (Data.Monoid.<>) (let _v = Lens.Family2.view (Data.ProtoLens.Field.field @"value") _x in if (Prelude.==) _v Data.ProtoLens.fieldDefault then Data.Monoid.mempty else (Data.Monoid.<>) (Data.ProtoLens.Encoding.Bytes.putVarInt 8) ((Prelude..) Data.ProtoLens.Encoding.Bytes.putVarInt Prelude.fromIntegral _v)) (Data.ProtoLens.Encoding.Wire.buildFieldSet (Lens.Family2.view Data.ProtoLens.unknownFields _x)) instance Control.DeepSeq.NFData UInt32Value where rnf = \ x__ -> Control.DeepSeq.deepseq (_UInt32Value'_unknownFields x__) (Control.DeepSeq.deepseq (_UInt32Value'value x__) ()) {- | Fields : * 'Proto.GoogleProtobuf_Fields.value' @:: Lens' UInt64Value Data.Word.Word64@ -} data UInt64Value = UInt64Value'_constructor {_UInt64Value'value :: !Data.Word.Word64, _UInt64Value'_unknownFields :: !Data.ProtoLens.FieldSet} deriving stock (Prelude.Eq, Prelude.Ord) instance Prelude.Show UInt64Value where showsPrec _ __x __s = Prelude.showChar '{' (Prelude.showString (Data.ProtoLens.showMessageShort __x) (Prelude.showChar '}' __s)) instance Data.ProtoLens.Field.HasField UInt64Value "value" Data.Word.Word64 where fieldOf _ = (Prelude..) (Lens.Family2.Unchecked.lens _UInt64Value'value (\ x__ y__ -> x__ {_UInt64Value'value = y__})) Prelude.id instance Data.ProtoLens.Message UInt64Value where messageName _ = Data.Text.pack "Google.Protobuf.UInt64Value" packedMessageDescriptor _ = "\n\ \\vUInt64Value\DC2\DC4\n\ \\ENQvalue\CAN\SOH \SOH(\EOTR\ENQvalue" packedFileDescriptor _ = packedFileDescriptor fieldsByTag = let value__field_descriptor = Data.ProtoLens.FieldDescriptor "value" (Data.ProtoLens.ScalarField Data.ProtoLens.UInt64Field :: Data.ProtoLens.FieldTypeDescriptor Data.Word.Word64) (Data.ProtoLens.PlainField Data.ProtoLens.Optional (Data.ProtoLens.Field.field @"value")) :: Data.ProtoLens.FieldDescriptor UInt64Value in Data.Map.fromList [(Data.ProtoLens.Tag 1, value__field_descriptor)] unknownFields = Lens.Family2.Unchecked.lens _UInt64Value'_unknownFields (\ x__ y__ -> x__ {_UInt64Value'_unknownFields = y__}) defMessage = UInt64Value'_constructor {_UInt64Value'value = Data.ProtoLens.fieldDefault, _UInt64Value'_unknownFields = []} parseMessage = let loop :: UInt64Value -> Data.ProtoLens.Encoding.Bytes.Parser UInt64Value loop x = do end <- Data.ProtoLens.Encoding.Bytes.atEnd if end then do (let missing = [] in if Prelude.null missing then Prelude.return () else Prelude.fail ((Prelude.++) "Missing required fields: " (Prelude.show (missing :: [Prelude.String])))) Prelude.return (Lens.Family2.over Data.ProtoLens.unknownFields (\ !t -> Prelude.reverse t) x) else do tag <- Data.ProtoLens.Encoding.Bytes.getVarInt case tag of 8 -> do y <- (Data.ProtoLens.Encoding.Bytes.) Data.ProtoLens.Encoding.Bytes.getVarInt "value" loop (Lens.Family2.set (Data.ProtoLens.Field.field @"value") y x) wire -> do !y <- Data.ProtoLens.Encoding.Wire.parseTaggedValueFromWire wire loop (Lens.Family2.over Data.ProtoLens.unknownFields (\ !t -> (:) y t) x) in (Data.ProtoLens.Encoding.Bytes.) (do loop Data.ProtoLens.defMessage) "UInt64Value" buildMessage = \ _x -> (Data.Monoid.<>) (let _v = Lens.Family2.view (Data.ProtoLens.Field.field @"value") _x in if (Prelude.==) _v Data.ProtoLens.fieldDefault then Data.Monoid.mempty else (Data.Monoid.<>) (Data.ProtoLens.Encoding.Bytes.putVarInt 8) (Data.ProtoLens.Encoding.Bytes.putVarInt _v)) (Data.ProtoLens.Encoding.Wire.buildFieldSet (Lens.Family2.view Data.ProtoLens.unknownFields _x)) instance Control.DeepSeq.NFData UInt64Value where rnf = \ x__ -> Control.DeepSeq.deepseq (_UInt64Value'_unknownFields x__) (Control.DeepSeq.deepseq (_UInt64Value'value x__) ()) packedFileDescriptor :: Data.ByteString.ByteString packedFileDescriptor = "\n\ \\NAKgoogle_protobuf.proto\DC2\SIGoogle.Protobuf\"#\n\ \\vDoubleValue\DC2\DC4\n\ \\ENQvalue\CAN\SOH \SOH(\SOHR\ENQvalue\"\"\n\ \\n\ \FloatValue\DC2\DC4\n\ \\ENQvalue\CAN\SOH \SOH(\STXR\ENQvalue\"\"\n\ \\n\ \Int64Value\DC2\DC4\n\ \\ENQvalue\CAN\SOH \SOH(\ETXR\ENQvalue\"#\n\ \\vUInt64Value\DC2\DC4\n\ \\ENQvalue\CAN\SOH \SOH(\EOTR\ENQvalue\"\"\n\ \\n\ \Int32Value\DC2\DC4\n\ \\ENQvalue\CAN\SOH \SOH(\ENQR\ENQvalue\"#\n\ \\vUInt32Value\DC2\DC4\n\ \\ENQvalue\CAN\SOH \SOH(\rR\ENQvalue\"!\n\ \\tBoolValue\DC2\DC4\n\ \\ENQvalue\CAN\SOH \SOH(\bR\ENQvalue\"#\n\ \\vStringValue\DC2\DC4\n\ \\ENQvalue\CAN\SOH \SOH(\tR\ENQvalue\"\"\n\ \\n\ \BytesValue\DC2\DC4\n\ \\ENQvalue\CAN\SOH \SOH(\fR\ENQvalue\";\n\ \\tTimestamp\DC2\CAN\n\ \\aseconds\CAN\SOH \SOH(\ETXR\aseconds\DC2\DC4\n\ \\ENQnanos\CAN\STX \SOH(\ENQR\ENQnanosB|\n\ \\DC3com.google.protobufB\rWrappersProtoP\SOHZ*github.com/golang/protobuf/ptypes/wrappers\248\SOH\SOH\162\STX\ETXGPB\170\STX\RSGoogle.Protobuf.WellKnownTypesJ\214@\n\ \\a\DC2\ENQ(\NUL\219\SOH\SOH\n\ \\219\DLE\n\ \\SOH\f\DC2\ETX(\NUL\DC22\193\f Protocol Buffers - Google's data interchange format\n\ \ Copyright 2008 Google Inc. All rights reserved.\n\ \ https://developers.google.com/protocol-buffers/\n\ \\n\ \ Redistribution and use in source and binary forms, with or without\n\ \ modification, are permitted provided that the following conditions are\n\ \ met:\n\ \\n\ \ * Redistributions of source code must retain the above copyright\n\ \ notice, this list of conditions and the following disclaimer.\n\ \ * Redistributions in binary form must reproduce the above\n\ \ copyright notice, this list of conditions and the following disclaimer\n\ \ in the documentation and/or other materials provided with the\n\ \ distribution.\n\ \ * Neither the name of Google Inc. nor the names of its\n\ \ contributors may be used to endorse or promote products derived from\n\ \ this software without specific prior written permission.\n\ \\n\ \ THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS\n\ \ \"AS IS\" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT\n\ \ LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR\n\ \ A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT\n\ \ OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,\n\ \ SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT\n\ \ LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,\n\ \ DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY\n\ \ THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT\n\ \ (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE\n\ \ OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.\n\ \2\140\EOT Wrappers for primitive (non-message) types. These types are useful\n\ \ for embedding primitives in the `google.protobuf.Any` type and for places\n\ \ where we need to distinguish between the absence of a primitive\n\ \ typed field and its default value.\n\ \\n\ \ These wrappers have no meaningful use within repeated fields as they lack\n\ \ the ability to detect presence on individual elements.\n\ \ These wrappers have no meaningful use within a map or a oneof since\n\ \ individual entries of a map or fields of a oneof can already detect presence.\n\ \\n\ \\b\n\ \\SOH\STX\DC2\ETX*\NUL\CAN\n\ \\b\n\ \\SOH\b\DC2\ETX,\NUL;\n\ \\t\n\ \\STX\b%\DC2\ETX,\NUL;\n\ \\b\n\ \\SOH\b\DC2\ETX-\NUL\US\n\ \\t\n\ \\STX\b\US\DC2\ETX-\NUL\US\n\ \\b\n\ \\SOH\b\DC2\ETX.\NULA\n\ \\t\n\ \\STX\b\v\DC2\ETX.\NULA\n\ \\b\n\ \\SOH\b\DC2\ETX/\NUL,\n\ \\t\n\ \\STX\b\SOH\DC2\ETX/\NUL,\n\ \\b\n\ \\SOH\b\DC2\ETX0\NUL.\n\ \\t\n\ \\STX\b\b\DC2\ETX0\NUL.\n\ \\b\n\ \\SOH\b\DC2\ETX1\NUL\"\n\ \\t\n\ \\STX\b\n\ \\DC2\ETX1\NUL\"\n\ \\b\n\ \\SOH\b\DC2\ETX2\NUL!\n\ \\t\n\ \\STX\b$\DC2\ETX2\NUL!\n\ \g\n\ \\STX\EOT\NUL\DC2\EOT7\NUL:\SOH\SUB[ Wrapper message for `double`.\n\ \\n\ \ The JSON representation for `DoubleValue` is JSON number.\n\ \\n\ \\n\ \\n\ \\ETX\EOT\NUL\SOH\DC2\ETX7\b\DC3\n\ \ \n\ \\EOT\EOT\NUL\STX\NUL\DC2\ETX9\STX\DC3\SUB\DC3 The double value.\n\ \\n\ \\r\n\ \\ENQ\EOT\NUL\STX\NUL\EOT\DC2\EOT9\STX7\NAK\n\ \\f\n\ \\ENQ\EOT\NUL\STX\NUL\ENQ\DC2\ETX9\STX\b\n\ \\f\n\ \\ENQ\EOT\NUL\STX\NUL\SOH\DC2\ETX9\t\SO\n\ \\f\n\ \\ENQ\EOT\NUL\STX\NUL\ETX\DC2\ETX9\DC1\DC2\n\ \e\n\ \\STX\EOT\SOH\DC2\EOT?\NULB\SOH\SUBY Wrapper message for `float`.\n\ \\n\ \ The JSON representation for `FloatValue` is JSON number.\n\ \\n\ \\n\ \\n\ \\ETX\EOT\SOH\SOH\DC2\ETX?\b\DC2\n\ \\US\n\ \\EOT\EOT\SOH\STX\NUL\DC2\ETXA\STX\DC2\SUB\DC2 The float value.\n\ \\n\ \\r\n\ \\ENQ\EOT\SOH\STX\NUL\EOT\DC2\EOTA\STX?\DC4\n\ \\f\n\ \\ENQ\EOT\SOH\STX\NUL\ENQ\DC2\ETXA\STX\a\n\ \\f\n\ \\ENQ\EOT\SOH\STX\NUL\SOH\DC2\ETXA\b\r\n\ \\f\n\ \\ENQ\EOT\SOH\STX\NUL\ETX\DC2\ETXA\DLE\DC1\n\ \e\n\ \\STX\EOT\STX\DC2\EOTG\NULJ\SOH\SUBY Wrapper message for `int64`.\n\ \\n\ \ The JSON representation for `Int64Value` is JSON string.\n\ \\n\ \\n\ \\n\ \\ETX\EOT\STX\SOH\DC2\ETXG\b\DC2\n\ \\US\n\ \\EOT\EOT\STX\STX\NUL\DC2\ETXI\STX\DC2\SUB\DC2 The int64 value.\n\ \\n\ \\r\n\ \\ENQ\EOT\STX\STX\NUL\EOT\DC2\EOTI\STXG\DC4\n\ \\f\n\ \\ENQ\EOT\STX\STX\NUL\ENQ\DC2\ETXI\STX\a\n\ \\f\n\ \\ENQ\EOT\STX\STX\NUL\SOH\DC2\ETXI\b\r\n\ \\f\n\ \\ENQ\EOT\STX\STX\NUL\ETX\DC2\ETXI\DLE\DC1\n\ \g\n\ \\STX\EOT\ETX\DC2\EOTO\NULR\SOH\SUB[ Wrapper message for `uint64`.\n\ \\n\ \ The JSON representation for `UInt64Value` is JSON string.\n\ \\n\ \\n\ \\n\ \\ETX\EOT\ETX\SOH\DC2\ETXO\b\DC3\n\ \ \n\ \\EOT\EOT\ETX\STX\NUL\DC2\ETXQ\STX\DC3\SUB\DC3 The uint64 value.\n\ \\n\ \\r\n\ \\ENQ\EOT\ETX\STX\NUL\EOT\DC2\EOTQ\STXO\NAK\n\ \\f\n\ \\ENQ\EOT\ETX\STX\NUL\ENQ\DC2\ETXQ\STX\b\n\ \\f\n\ \\ENQ\EOT\ETX\STX\NUL\SOH\DC2\ETXQ\t\SO\n\ \\f\n\ \\ENQ\EOT\ETX\STX\NUL\ETX\DC2\ETXQ\DC1\DC2\n\ \e\n\ \\STX\EOT\EOT\DC2\EOTW\NULZ\SOH\SUBY Wrapper message for `int32`.\n\ \\n\ \ The JSON representation for `Int32Value` is JSON number.\n\ \\n\ \\n\ \\n\ \\ETX\EOT\EOT\SOH\DC2\ETXW\b\DC2\n\ \\US\n\ \\EOT\EOT\EOT\STX\NUL\DC2\ETXY\STX\DC2\SUB\DC2 The int32 value.\n\ \\n\ \\r\n\ \\ENQ\EOT\EOT\STX\NUL\EOT\DC2\EOTY\STXW\DC4\n\ \\f\n\ \\ENQ\EOT\EOT\STX\NUL\ENQ\DC2\ETXY\STX\a\n\ \\f\n\ \\ENQ\EOT\EOT\STX\NUL\SOH\DC2\ETXY\b\r\n\ \\f\n\ \\ENQ\EOT\EOT\STX\NUL\ETX\DC2\ETXY\DLE\DC1\n\ \g\n\ \\STX\EOT\ENQ\DC2\EOT_\NULb\SOH\SUB[ Wrapper message for `uint32`.\n\ \\n\ \ The JSON representation for `UInt32Value` is JSON number.\n\ \\n\ \\n\ \\n\ \\ETX\EOT\ENQ\SOH\DC2\ETX_\b\DC3\n\ \ \n\ \\EOT\EOT\ENQ\STX\NUL\DC2\ETXa\STX\DC3\SUB\DC3 The uint32 value.\n\ \\n\ \\r\n\ \\ENQ\EOT\ENQ\STX\NUL\EOT\DC2\EOTa\STX_\NAK\n\ \\f\n\ \\ENQ\EOT\ENQ\STX\NUL\ENQ\DC2\ETXa\STX\b\n\ \\f\n\ \\ENQ\EOT\ENQ\STX\NUL\SOH\DC2\ETXa\t\SO\n\ \\f\n\ \\ENQ\EOT\ENQ\STX\NUL\ETX\DC2\ETXa\DC1\DC2\n\ \o\n\ \\STX\EOT\ACK\DC2\EOTg\NULj\SOH\SUBc Wrapper message for `bool`.\n\ \\n\ \ The JSON representation for `BoolValue` is JSON `true` and `false`.\n\ \\n\ \\n\ \\n\ \\ETX\EOT\ACK\SOH\DC2\ETXg\b\DC1\n\ \\RS\n\ \\EOT\EOT\ACK\STX\NUL\DC2\ETXi\STX\DC1\SUB\DC1 The bool value.\n\ \\n\ \\r\n\ \\ENQ\EOT\ACK\STX\NUL\EOT\DC2\EOTi\STXg\DC3\n\ \\f\n\ \\ENQ\EOT\ACK\STX\NUL\ENQ\DC2\ETXi\STX\ACK\n\ \\f\n\ \\ENQ\EOT\ACK\STX\NUL\SOH\DC2\ETXi\a\f\n\ \\f\n\ \\ENQ\EOT\ACK\STX\NUL\ETX\DC2\ETXi\SI\DLE\n\ \g\n\ \\STX\EOT\a\DC2\EOTo\NULr\SOH\SUB[ Wrapper message for `string`.\n\ \\n\ \ The JSON representation for `StringValue` is JSON string.\n\ \\n\ \\n\ \\n\ \\ETX\EOT\a\SOH\DC2\ETXo\b\DC3\n\ \ \n\ \\EOT\EOT\a\STX\NUL\DC2\ETXq\STX\DC3\SUB\DC3 The string value.\n\ \\n\ \\r\n\ \\ENQ\EOT\a\STX\NUL\EOT\DC2\EOTq\STXo\NAK\n\ \\f\n\ \\ENQ\EOT\a\STX\NUL\ENQ\DC2\ETXq\STX\b\n\ \\f\n\ \\ENQ\EOT\a\STX\NUL\SOH\DC2\ETXq\t\SO\n\ \\f\n\ \\ENQ\EOT\a\STX\NUL\ETX\DC2\ETXq\DC1\DC2\n\ \e\n\ \\STX\EOT\b\DC2\EOTw\NULz\SOH\SUBY Wrapper message for `bytes`.\n\ \\n\ \ The JSON representation for `BytesValue` is JSON string.\n\ \\n\ \\n\ \\n\ \\ETX\EOT\b\SOH\DC2\ETXw\b\DC2\n\ \\US\n\ \\EOT\EOT\b\STX\NUL\DC2\ETXy\STX\DC2\SUB\DC2 The bytes value.\n\ \\n\ \\r\n\ \\ENQ\EOT\b\STX\NUL\EOT\DC2\EOTy\STXw\DC4\n\ \\f\n\ \\ENQ\EOT\b\STX\NUL\ENQ\DC2\ETXy\STX\a\n\ \\f\n\ \\ENQ\EOT\b\STX\NUL\SOH\DC2\ETXy\b\r\n\ \\f\n\ \\ENQ\EOT\b\STX\NUL\ETX\DC2\ETXy\DLE\DC1\n\ \\244\ESC\n\ \\STX\EOT\t\DC2\ACK\208\SOH\NUL\219\SOH\SOH\SUB\229\ESC A Timestamp represents a point in time independent of any time zone or local\n\ \ calendar, encoded as a count of seconds and fractions of seconds at\n\ \ nanosecond resolution. The count is relative to an epoch at UTC midnight on\n\ \ January 1, 1970, in the proleptic Gregorian calendar which extends the\n\ \ Gregorian calendar backwards to year one.\n\ \\n\ \ All minutes are 60 seconds long. Leap seconds are \"smeared\" so that no leap\n\ \ second table is needed for interpretation, using a [24-hour linear\n\ \ smear](https://developers.google.com/time/smear).\n\ \\n\ \ The range is from 0001-01-01T00:00:00Z to 9999-12-31T23:59:59.999999999Z. By\n\ \ restricting to that range, we ensure that we can convert to and from [RFC\n\ \ 3339](https://www.ietf.org/rfc/rfc3339.txt) date strings.\n\ \\n\ \ # Examples\n\ \\n\ \ Example 1: Compute Timestamp from POSIX `time()`.\n\ \\n\ \ Timestamp timestamp;\n\ \ timestamp.set_seconds(time(NULL));\n\ \ timestamp.set_nanos(0);\n\ \\n\ \ Example 2: Compute Timestamp from POSIX `gettimeofday()`.\n\ \\n\ \ struct timeval tv;\n\ \ gettimeofday(&tv, NULL);\n\ \\n\ \ Timestamp timestamp;\n\ \ timestamp.set_seconds(tv.tv_sec);\n\ \ timestamp.set_nanos(tv.tv_usec * 1000);\n\ \\n\ \ Example 3: Compute Timestamp from Win32 `GetSystemTimeAsFileTime()`.\n\ \\n\ \ FILETIME ft;\n\ \ GetSystemTimeAsFileTime(&ft);\n\ \ UINT64 ticks = (((UINT64)ft.dwHighDateTime) << 32) | ft.dwLowDateTime;\n\ \\n\ \ // A Windows tick is 100 nanoseconds. Windows epoch 1601-01-01T00:00:00Z\n\ \ // is 11644473600 seconds before Unix epoch 1970-01-01T00:00:00Z.\n\ \ Timestamp timestamp;\n\ \ timestamp.set_seconds((INT64) ((ticks / 10000000) - 11644473600LL));\n\ \ timestamp.set_nanos((INT32) ((ticks % 10000000) * 100));\n\ \\n\ \ Example 4: Compute Timestamp from Java `System.currentTimeMillis()`.\n\ \\n\ \ long millis = System.currentTimeMillis();\n\ \\n\ \ Timestamp timestamp = Timestamp.newBuilder().setSeconds(millis / 1000)\n\ \ .setNanos((int) ((millis % 1000) * 1000000)).build();\n\ \\n\ \\n\ \ Example 5: Compute Timestamp from current time in Python.\n\ \\n\ \ timestamp = Timestamp()\n\ \ timestamp.GetCurrentTime()\n\ \\n\ \ # JSON Mapping\n\ \\n\ \ In JSON format, the Timestamp type is encoded as a string in the\n\ \ [RFC 3339](https://www.ietf.org/rfc/rfc3339.txt) format. That is, the\n\ \ format is \"{year}-{month}-{day}T{hour}:{min}:{sec}[.{frac_sec}]Z\"\n\ \ where {year} is always expressed using four digits while {month}, {day},\n\ \ {hour}, {min}, and {sec} are zero-padded to two digits each. The fractional\n\ \ seconds, which can go up to 9 digits (i.e. up to 1 nanosecond resolution),\n\ \ are optional. The \"Z\" suffix indicates the timezone (\"UTC\"); the timezone\n\ \ is required. A proto3 JSON serializer should always use UTC (as indicated by\n\ \ \"Z\") when printing the Timestamp type and a proto3 JSON parser should be\n\ \ able to accept both UTC and other timezones (as indicated by an offset).\n\ \\n\ \ For example, \"2017-01-15T01:30:15.01Z\" encodes 15.01 seconds past\n\ \ 01:30 UTC on January 15, 2017.\n\ \\n\ \ In JavaScript, one can convert a Date object to this format using the\n\ \ standard\n\ \ [toISOString()](https://developer.mozilla.org/en-US/docs/Web/JavaScript/Reference/Global_Objects/Date/toISOString)\n\ \ method. In Python, a standard `datetime.datetime` object can be converted\n\ \ to this format using\n\ \ [`strftime`](https://docs.python.org/2/library/time.html#time.strftime) with\n\ \ the time format spec '%Y-%m-%dT%H:%M:%S.%fZ'. Likewise, in Java, one can use\n\ \ the Joda Time's [`ISODateTimeFormat.dateTime()`](\n\ \ http://www.joda.org/joda-time/apidocs/org/joda/time/format/ISODateTimeFormat.html#dateTime%2D%2D\n\ \ ) to obtain a formatter capable of generating timestamps in this format.\n\ \\n\ \\n\ \\n\ \\v\n\ \\ETX\EOT\t\SOH\DC2\EOT\208\SOH\b\DC1\n\ \\157\SOH\n\ \\EOT\EOT\t\STX\NUL\DC2\EOT\212\SOH\STX\DC4\SUB\142\SOH Represents seconds of UTC time since Unix epoch\n\ \ 1970-01-01T00:00:00Z. Must be from 0001-01-01T00:00:00Z to\n\ \ 9999-12-31T23:59:59Z inclusive.\n\ \\n\ \\SI\n\ \\ENQ\EOT\t\STX\NUL\EOT\DC2\ACK\212\SOH\STX\208\SOH\DC3\n\ \\r\n\ \\ENQ\EOT\t\STX\NUL\ENQ\DC2\EOT\212\SOH\STX\a\n\ \\r\n\ \\ENQ\EOT\t\STX\NUL\SOH\DC2\EOT\212\SOH\b\SI\n\ \\r\n\ \\ENQ\EOT\t\STX\NUL\ETX\DC2\EOT\212\SOH\DC2\DC3\n\ \\229\SOH\n\ \\EOT\EOT\t\STX\SOH\DC2\EOT\218\SOH\STX\DC2\SUB\214\SOH Non-negative fractions of a second at nanosecond resolution. Negative\n\ \ second values with fractions must still have non-negative nanos values\n\ \ that count forward in time. Must be from 0 to 999,999,999\n\ \ inclusive.\n\ \\n\ \\SI\n\ \\ENQ\EOT\t\STX\SOH\EOT\DC2\ACK\218\SOH\STX\212\SOH\DC4\n\ \\r\n\ \\ENQ\EOT\t\STX\SOH\ENQ\DC2\EOT\218\SOH\STX\a\n\ \\r\n\ \\ENQ\EOT\t\STX\SOH\SOH\DC2\EOT\218\SOH\b\r\n\ \\r\n\ \\ENQ\EOT\t\STX\SOH\ETX\DC2\EOT\218\SOH\DLE\DC1b\ACKproto3"