Flexible JSON serialization does not rely on run-time type information.
nim-json-serialization offers rich features on top of nim-serialization framework. The following is available but not an exhaustive list of features:
- Decode into Nim data types efficiently without an intermediate token.
- Able to parse full spec of JSON including the notorious JSON number.
- Support stdlib/JsonNode out of the box.
- While stdlib/JsonNode does not support the full spec of the Json number, we offer an alternative
JsonValueRef
. - Skipping Json value is an efficient process, no token is generated at all and at the same time, the grammar is checked.
- Skipping is also free from custom serializer interference.
- An entire Json value can be parsed into a valid Json document string. This string document can be parsed again without losing any information.
- Custom serialization is easy and safe to implement with the help of many built-in parsers.
- Nonstandard features are put behind flags. You can choose which features to switch on or off.
- Because the intended usage of this library will be in a security-demanding application, we make sure malicious inputs will not crash this library through fuzz tests.
- The user also can tweak certain limits of the lexer/parser behavior using the configuration object.
createJsonFlavor
is a powerful way to prevent cross contamination between different subsystem using different custom serializar on the same type.
nim-json-serialization implements RFC8259 JSON spec and pass these test suites:
Many of these switchable features are widely used features in various projects but are not standard JSON features. But you can access them using the flags:
- allowUnknownFields[=off]: enable unknown fields to be skipped instead of throwing an error.
- requireAllFields[=off]: if one of the required fields is missing, the serializer will throw an error.
- escapeHex[=off]: JSON doesn't support
\xHH
escape sequence, but it is a common thing in many languages. - relaxedEscape[=off]: only '0x00'..'0x1F' can be prepended by escape char
\\
, turn this on and you can escape any char. - portableInt[=off]: set the limit of integer to
-2**53 + 1
and+2**53 - 1
. - trailingComma[=on]: allow the presence of a trailing comma after the last object member or array element.
- allowComments[=on]: JSOn standard doesn't mention about comments. Turn this on to parse both C style comments of
//..EOL
and/* .. */
. - leadingFraction[=on]: something like
.123
is not a valid JSON number, but its widespread usage sometimes creeps into Json documents. - integerPositiveSign[=on]:
+123
is also not a valid JSON number, but since-123
is a valid JSON number, why not parse it safely?
You can modify these default configurations to suit your needs.
- nestedDepthLimit: 512: maximum depth of the nested structure, they are a combination of objects and arrays depth(0=disable).
- arrayElementsLimit: 0: maximum number of allowed array elements(0=disable).
- objectMembersLimit: 0: maximum number of key-value pairs in an object(0=disable).
- integerDigitsLimit: 128: limit the maximum digits of the integer part of JSON number.
- fractionDigitsLimit: 128: limit the maximum digits of faction part of JSON number.
- exponentDigitsLimit: 32: limit the maximum digits of the exponent part of JSON number.
- stringLengthLimit: 0: limit the maximum bytes of string(0=disable).
- JsonString: Use this type if you want to parse a Json value to a valid Json document contained in a string.
- JsonVoid: Use this type to skip a valid Json value.
- JsonNumber: Use this to parse a valid Json number including the fraction and exponent part.
- Please note that this type is a generic, it support
uint64
andstring
as generic param. - The generic param will define the integer and exponent part as
uint64
orstring
. - If the generic param is
uint64
, overflow can happen, or max digit limit will apply. - If the generic param is
string
, the max digit limit will apply. - The fraction part is always a string to keep the leading zero of the fractional number.
- Please note that this type is a generic, it support
- JsonValueRef: Use this type to parse any valid Json value into something like stdlib/JsonNode.
JsonValueRef
is usingJsonNumber
instead ofint
orfloat
like stdlib/JsonNode.
While flags and limits are runtime configuration, flavor is a powerful compile time mechanism to prevent
cross contamination between different custom serializer operated the same type. For example,
json-rpc
subsystem dan json-rest
subsystem maybe have different custom serializer for the same UInt256
.
Json-Flavor will make sure, the compiler picks the right serializer for the right subsystem.
You can use useDefaultSerializationIn
to add serializers of a flavor to a specific type.
# These are the parameters you can pass to `createJsonFlavor` to create a new flavor.
FlavorName: untyped
mimeTypeValue = "application/json"
automaticObjectSerialization = false
requireAllFields = true
omitOptionalFields = true
allowUnknownFields = true
skipNullFields = false
type
OptionalFields = object
one: Opt[string]
two: Option[int]
createJsonFlavor OptJson
OptionalFields.useDefaultSerializationIn OptJson
omitOptionalFields
is used by the Writer to ignore fields with null value.
skipNullFields
is used by the Reader to ignore fields with null value.
type
NimServer = object
name: string
port: int
MixedServer = object
name: JsonValueRef
port: int
StringServer = object
name: JsonString
port: JsonString
# decode into native Nim
var nim_native = Json.decode(rawJson, NimServer)
# decode into mixed Nim + JsonValueRef
var nim_mixed = Json.decode(rawJson, MixedServer)
# decode any value into string
var nim_string = Json.decode(rawJson, StringServer)
# decode any valid JSON
var json_value = Json.decode(rawJson, JsonValueRef)
var server = Json.loadFile("filename.json", Server)
var server_string = Json.loadFile("filename.json", JsonString)
Json.saveFile("filename.json", server)
Decoding an object can be achieved via the parseObject
template.
To parse the value, you can use one of the helper functions or use readValue
.
readObject
and readObjectFields
iterators are also handy when creating a custom object parser.
proc readValue*(r: var JsonReader, table: var Table[string, int]) =
parseObject(r, key):
table[key] = r.parseInt(int)
Similar to Object
, sets and list or array-like data structures can be parsed using
parseArray
template. It comes in two variations, indexed and non-indexed.
Built-in readValue
for regular seq
and array
is implemented for you.
No built-in readValue
for set
or set-like
is provided, you must overload it yourself depending on your need.
type
HoldArray = object
data: array[3, int]
HoldSeq = object
data: seq[int]
WelderFlag = enum
TIG
MIG
MMA
Welder = object
flags: set[WelderFlag]
proc readValue*(r: var JsonReader, value: var HoldArray) =
# parseArray with index, `i` can be any valid identifier
r.parseArray(i):
value.data[i] = r.parseInt(int)
proc readValue*(r: var JsonReader, value: var HoldSeq) =
# parseArray without index
r.parseArray:
let lastPos = value.data.len
value.data.setLen(lastPos + 1)
readValue(r, value.data[lastPos])
proc readValue*(r: var JsonReader, value: var Welder) =
# populating set also okay
r.parseArray:
value.flags.incl r.parseInt(int).WelderFlag
Using these custom iterators, you can have access to sub-token elements.
customIntValueIt(r: var JsonReader; body: untyped)
customNumberValueIt(r: var JsonReader; body: untyped)
customStringValueIt(r: var JsonReader; limit: untyped; body: untyped)
customStringValueIt(r: var JsonReader; body: untyped)
readArray(r: var JsonReader, ElemType: typedesc): ElemType
readObjectFields(r: var JsonReader, KeyType: type): KeyType
readObjectFields(r: var JsonReader): string
readObject(r: var JsonReader, KeyType: type, ValueType: type): (KeyType, ValueType)
When crafting a custom serializer, use these parsers, they are safe and intuitive. Avoid using the lexer directly.
tokKind(r: var JsonReader): JsonValueKind
parseString(r: var JsonReader, limit: int): string
parseString(r: var JsonReader): string
parseBool(r: var JsonReader): bool
parseNull(r: var JsonReader)
parseNumber(r: var JsonReader, T: type): JsonNumber[T: string or uint64]
parseNumber(r: var JsonReader, val: var JsonNumber)
toInt(r: var JsonReader, val: JsonNumber, T: type SomeInteger, portable: bool): T
parseInt(r: var JsonReader, T: type SomeInteger, portable: bool = false): T
toFloat(r: var JsonReader, val: JsonNumber, T: type SomeFloat): T
parseFloat(r: var JsonReader, T: type SomeFloat): T
parseAsString(r: var JsonReader, val: var string)
parseAsString(r: var JsonReader): JsonString
parseValue(r: var JsonReader, T: type): JsonValueRef[T: string or uint64]
parseValue(r: var JsonReader, val: var JsonValueRef)
parseArray(r: var JsonReader; body: untyped)
parseArray(r: var JsonReader; idx: untyped; body: untyped)
parseObject(r: var JsonReader, key: untyped, body: untyped)
parseObjectWithoutSkip(r: var JsonReader, key: untyped, body: untyped)
parseObjectSkipNullFields(r: var JsonReader, key: untyped, body: untyped)
parseObjectCustomKey(r: var JsonReader, keyAction: untyped, body: untyped)
parseJsonNode(r: var JsonReader): JsonNode
skipSingleJsValue(r: var JsonReader)
readRecordValue[T](r: var JsonReader, value: var T)
beginRecord(w: var JsonWriter, T: type)
beginRecord(w: var JsonWriter)
endRecord(w: var JsonWriter)
writeObject(w: var JsonWriter, T: type)
writeObject(w: var JsonWriter)
writeFieldName(w: var JsonWriter, name: string)
writeField(w: var JsonWriter, name: string, value: auto)
iterator stepwiseArrayCreation[C](w: var JsonWriter, collection: C): auto
writeIterable(w: var JsonWriter, collection: auto)
writeArray[T](w: var JsonWriter, elements: openArray[T])
writeNumber[F,T](w: var JsonWriter[F], value: JsonNumber[T])
writeJsonValueRef[F,T](w: var JsonWriter[F], value: JsonValueRef[T])
type
Fruit = enum
Apple = "Apple"
Banana = "Banana"
Drawer = enum
One
Two
Number = enum
Three = 3
Four = 4
Mixed = enum
Six = 6
Seven = "Seven"
nim-json-serialization automatically detect which representation an enum should be parsed. The detection occurs when parse json literal and from the enum declaration itself. 'Fruit' expect string literal. 'Drawer' or 'Number' expect numeric literal. 'Mixed' is disallowed. If the json literal does not match the expected enum style, exception will be raised. But you can configure individual enum type with:
configureJsonDeserialization(
T: type[enum], allowNumericRepr: static[bool] = false,
stringNormalizer: static[proc(s: string): string] = strictNormalize)
# example:
Mixed.configureJsonDeserialization(allowNumericRepr = true) # only at top level
When encode an enum, user is also given flexibility to configure at Flavor level or for individual enum type.
type
EnumRepresentation* = enum
EnumAsString
EnumAsNumber
EnumAsStringifiedNumber
# examples:
# Flavor level
Json.flavorEnumRep(EnumAsString) # default flavor, can be called from non top level
Flavor.flavorEnumRep(EnumAsNumber) # custom flavor, can be called from non top level
# individual enum type no matter what flavor
Fruit.configureJsonSerialization(EnumAsNumber) # only at top level
# individual enum type of specific flavor
MyJson.flavorEnumRep(Drawer, EnumAsString) # only at top level
Licensed and distributed under either of
- MIT license: LICENSE-MIT or http://opensource.org/licenses/MIT
or
- Apache License, Version 2.0, (LICENSE-APACHEv2 or http://www.apache.org/licenses/LICENSE-2.0)
at your option. These files may not be copied, modified, or distributed except according to those terms.