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#117 in Parser implementations
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miniconf: serialize/deserialize/access reflection for trees
miniconf
enables lightweight (no_std
/no alloc) serialization, deserialization,
and access within a tree of heretogeneous types by keys.
Example
See below for an example showing some of the features of the Tree*
traits.
See also the documentation and doctests of the TreeKey
trait for a detailed description.
Note that the example below focuses on JSON and slash-separated paths while in fact
any serde
backend (or dyn Any
trait objects) and many different Keys
/Transcode
providers are supported.
use serde::{Deserialize, Serialize};
use miniconf::{Error, json, JsonPath, Traversal, Tree, TreeKey, Path, Packed, Node, Leaf, Metadata};
#[derive(Deserialize, Serialize, Default, Tree)]
pub struct Inner {
a: Leaf<i32>,
b: Leaf<i32>,
}
#[derive(Deserialize, Serialize, Default, Tree)]
pub enum Either {
#[default]
Bad,
Good,
A(Leaf<i32>),
B(Inner),
C([Inner; 2]),
}
#[derive(Tree, Default)]
pub struct Settings {
foo: Leaf<bool>,
enum_: Leaf<Either>,
struct_: Leaf<Inner>,
array: Leaf<[i32; 2]>,
option: Leaf<Option<i32>>,
#[tree(skip)]
#[allow(unused)]
skipped: (),
struct_tree: Inner,
enum_tree: Either,
array_tree: [Leaf<i32>; 2],
array_tree2: [Inner; 2],
tuple_tree: (Leaf<i32>, Inner),
option_tree: Option<Leaf<i32>>,
option_tree2: Option<Inner>,
array_option_tree: [Option<Inner>; 2],
}
let mut settings = Settings::default();
// Access nodes by field name
json::set(&mut settings,"/foo", b"true")?;
assert_eq!(*settings.foo, true);
json::set(&mut settings, "/enum_", br#""Good""#)?;
json::set(&mut settings, "/struct_", br#"{"a": 3, "b": 3}"#)?;
json::set(&mut settings, "/array", b"[6, 6]")?;
json::set(&mut settings, "/option", b"12")?;
json::set(&mut settings, "/option", b"null")?;
// Nodes inside containers
// ... by field name in a struct
json::set(&mut settings, "/struct_tree/a", b"4")?;
// ... or by index in an array
json::set(&mut settings, "/array_tree/0", b"7")?;
// ... or by index and then struct field name
json::set(&mut settings, "/array_tree2/0/a", b"11")?;
// ... or by hierarchical index
json::set_by_key(&mut settings, [8, 0, 1], b"8")?;
// ... or by packed index
let (packed, node): (Packed, _) = Settings::transcode([8, 1, 0]).unwrap();
assert_eq!(packed.into_lsb().get(), 0b1_1000_1_0);
assert_eq!(node, Node::leaf(3));
json::set_by_key(&mut settings, packed, b"9")?;
// ... or by JSON path
json::set_by_key(&mut settings, &JsonPath(".array_tree2[1].b"), b"10")?;
// Hiding paths by setting an Option to `None` at runtime
assert_eq!(json::set(&mut settings, "/option_tree", b"13"), Err(Traversal::Absent(1).into()));
settings.option_tree = Some(0.into());
json::set(&mut settings, "/option_tree", b"13")?;
// Hiding a path and descending into the inner `Tree`
settings.option_tree2 = Some(Inner::default());
json::set(&mut settings, "/option_tree2/a", b"14")?;
// Hiding items of an array of `Tree`s
settings.array_option_tree[1] = Some(Inner::default());
json::set(&mut settings, "/array_option_tree/1/a", b"15")?;
let mut buf = [0; 16];
// Serializing nodes by path
let len = json::get(&settings, "/struct_", &mut buf).unwrap();
assert_eq!(&buf[..len], br#"{"a":3,"b":3}"#);
// Tree metadata
let meta: Metadata = Settings::traverse_all().unwrap();
assert!(meta.max_depth <= 6);
assert!(meta.max_length("/") <= 32);
// Iterating over all leaf paths
for path in Settings::nodes::<Path<heapless::String<32>, '/'>, 6>() {
let (path, node) = path.unwrap();
assert!(node.is_leaf());
// Serialize each
match json::get(&settings, &path, &mut buf) {
// Full round-trip: deserialize and set again
Ok(len) => { json::set(&mut settings, &path, &buf[..len])?; }
// Some Options are `None`, some enum variants are absent
Err(Error::Traversal(Traversal::Absent(_))) => {}
e => { e.unwrap(); }
}
}
# Ok::<(), Error<serde_json_core::de::Error>>(())
Settings management
One possible use of miniconf
is a backend for run-time settings management in embedded devices.
It was originally designed to work with JSON (serde_json_core
)
payloads over MQTT (minimq
) and provides a MQTT settings management
client in the miniconf_mqtt
crate and a Python reference implementation to interact with it.
Miniconf is agnostic of the serde
backend/format, key type/format, and transport/protocol.
Formats
miniconf
can be used with any serde::Serializer
/serde::Deserializer
backend, and key format.
Explicit support for /
as the path hierarchy separator and JSON (serde_json_core
) is implemented.
Support for the postcard
wire format with any postcard
flavor and
any Keys
type is implemented. Combined with the Packed
key representation, this is a very
space-efficient serde-by-key API.
Blanket implementations are provided for all
TreeSerialize
+TreeDeserialize
types for all formats.
Transport
miniconf
is also protocol-agnostic. Any means that can receive or emit serialized key-value data
can be used to access nodes by path.
The MqttClient
in the miniconf_mqtt
crate implements settings management over the MQTT
protocol with JSON payloads. A Python reference library is provided that
interfaces with it. This example discovers the unique prefix of an application listening to messages
under the topic quartiq/application/12345
and set its /foo
setting to true
.
python -m miniconf -d quartiq/application/+ /foo=true
Derive macros
For structs miniconf
offers derive macros for [macro@TreeKey
], [macro@TreeSerialize
], [macro@TreeDeserialize
], and [macro@TreeAny
].
The macros implements the TreeKey
, TreeSerialize
, TreeDeserialize
, and TreeAny
traits.
Fields/variants that form internal nodes (non-leaf) need to implement the respective Tree{Key,Serialize,Deserialize,Any}
trait.
Leaf fields/items need to support the respective serde
(and the desired serde::Serializer
/serde::Deserializer
backend) or core::any
trait.
Structs, enums, arrays, Options, and many other containers can then be cascaded to construct more complex trees.
See also the TreeKey
trait documentation for details.
Keys and paths
Lookup into the tree is done using a Keys
implementation. A blanket implementation through IntoKeys
is provided for IntoIterator
s over [Key
] items. The [Key
] lookup capability is implemented
for usize
indices and &str
names.
Path iteration is supported with arbitrary separator char
s between names.
Very compact hierarchical indices encodings can be obtained from the Packed
structure.
It implements Keys
.
Limitations
enum
: The derive macros don't support enums with record (named fields) variants or tuple variants with more than one (non-skip) field. Only unit, newtype and skipped variants are supported. Without the derive macros, anyenum
is still however usable as aLeaf
node. Note also that netwype variants with a single inline tuple are supported.- The derive macros only support flattening in non-ambiguous situations (single field structs and single variant enums, both modulo skipped fields/variants and unit variants).
Features
json-core
: Enable helper functions for serializing from and into json slices (using theserde_json_core
crate).postcard
: Enable helper functions for serializing from and into the postcard compact binary format (using thepostcard
crate).derive
: Enable the derive macros inminiconf_derive
. Enabled by default.
Reflection
miniconf
enables certain kinds of reflective access to heterogeneous trees.
Let's compare it to bevy_reflect
which is a comprehensive and mature reflection crate:
bevy_reflect
is thoroughly std
while miniconf
aims at no_std
.
bevy_reflect
uses its Reflect
trait to operate on and pass nodes as trait objects.
miniconf
uses serialized data or Any
to access leaf nodes and pure "code" to traverse through internal nodes.
The Tree*
traits like Reflect
thus give access to nodes but unlike Reflect
they are all decidedly not object-safe
and can not be used as trait objects. This allows miniconf
to support non-'static
borrowed data
(only for TreeAny
the leaf nodes need to be 'static
)
while bevy_reflect
requires 'static
for Reflect
types.
miniconf
supports at least the following reflection features mentioned in the bevy_reflect
README:
- ➕ Derive the traits:
miniconf
hasTree*
derive macros and blanket implementations for arrays and Options. Leaf nodes just need some impls ofSerialize/Deserialize/Any
where desired. - ➕ Interact with fields using their names
- ➖ "Patch" your types with new values:
miniconf
only supports limited changes to the tree structure at runtime (Option
and custom accessors) whilebevy_reflect
has powerful dynamic typing tools. - ➕ Look up nested fields using "path strings": In addition to a superset of JSON path style
"path strings"
miniconf
supports hierarchical indices and bit-packed ordered keys. - ➕ Iterate over struct fields:
miniconf
Supports recursive iteration over node keys. - ➕ Automatically serialize and deserialize via Serde without explicit serde impls:
miniconf
supports automatic serializing/deserializing into key-value pairs without an explicit container serde impls. - ➕ Trait "reflection": Together with
crosstrait
supports building the type registry and enables casting fromdyn Any
returned byTreeAny
to other desired trait objects. Together witherased-serde
it can be used to implement node serialization/deserialization usingminiconf
'sTreeAny
without usingTreeSerialize
/TreeDeserialize
similar tobevy_reflect
.
Some tangential crates:
serde-reflection
: extract schemata from serde implstypetag
: "derive serde for trait objects" (local traits and impls)deflect
: reflection on trait objects using adjacent DWARF debug info as the type registryintertrait
: inspiration and source of ideas forcrosstrait
Functional Programming, Polymorphism
The type-heterogeneity of miniconf
also borders on functional programming features. For that crates like the
following may also be relevant:
Dependencies
~0.4–1.2MB
~27K SLoC