A lightweight package for validating JSON like Python objects
Project description
vtjson
A lightweight package for validating JSON like Python objects.
Schemas
Validation of JSON like Python objects is done according to a "schema" which is somewhat inspired by a typescript type. The format of a schema is more or less self explanatory as the following example shows.
Example
Below is the schema of the run object in the mongodb database underlying the Fishtest web application https://tests.stockfishchess.org/tests
import math
from datetime import datetime
from bson.objectid import ObjectId
from vtjson import ip_address, number, regex, url
net_name = regex("nn-[a-z0-9]{12}.nnue", name="net_name")
tc = regex(r"([1-9]\d*/)?\d+(\.\d+)?(\+\d+(\.\d+)?)?", name="tc")
str_int = regex(r"[1-9]\d*", name="str_int")
sha = regex(r"[a-f0-9]{40}", name="sha")
country_code = regex(r"[A-Z][A-Z]", name="country_code")
run_id = regex(r"[a-f0-9]{24}", name="run_id")
worker_info_schema = {
"uname": str,
"architecture": [str, str],
"concurrency": int,
"max_memory": int,
"min_threads": int,
"username": str,
"version": int,
"python_version": [int, int, int],
"gcc_version": [int, int, int],
"compiler": {"clang++", "g++"},
"unique_key": str,
"modified": bool,
"ARCH": str,
"nps": number,
"near_github_api_limit": bool,
"remote_addr": ip_address,
"country_code": {country_code, "?"},
}
results_schema = {
"wins": int,
"losses": int,
"draws": int,
"crashes": int,
"time_losses": int,
"pentanomial": [int, int, int, int, int],
}
schema = {
"_id?": ObjectId,
"start_time": datetime,
"last_updated": datetime,
"tc_base": number,
"base_same_as_master": bool,
"results_stale?": bool,
"rescheduled_from?": run_id,
"approved": bool,
"approver": str,
"finished": bool,
"deleted": bool,
"failed": bool,
"is_green": bool,
"is_yellow": bool,
"workers?": int,
"cores?": int,
"results": results_schema,
"results_info?": {
"style": str,
"info": [str, ...],
},
"args": {
"base_tag": str,
"new_tag": str,
"base_net": net_name,
"new_net": net_name,
"num_games": int,
"tc": tc,
"new_tc": tc,
"book": str,
"book_depth": str_int,
"threads": int,
"resolved_base": sha,
"resolved_new": sha,
"msg_base": str,
"msg_new": str,
"base_options": str,
"new_options": str,
"info": str,
"base_signature": str_int,
"new_signature": str_int,
"username": str,
"tests_repo": url,
"auto_purge": bool,
"throughput": number,
"itp": number,
"priority": number,
"adjudication": bool,
"sprt?": {
"alpha": 0.05,
"beta": 0.05,
"elo0": number,
"elo1": number,
"elo_model": "normalized",
"state": {"", "accepted", "rejected"},
"llr": number,
"batch_size": int,
"lower_bound": -math.log(19),
"upper_bound": math.log(19),
"lost_samples?": int,
"illegal_update?": int,
"overshoot?": {
"last_update": int,
"skipped_updates": int,
"ref0": number,
"m0": number,
"sq0": number,
"ref1": number,
"m1": number,
"sq1": number,
},
},
"spsa?": {
"A": number,
"alpha": number,
"gamma": number,
"raw_params": str,
"iter": int,
"num_iter": int,
"params": [
{
"name": str,
"start": number,
"min": number,
"max": number,
"c_end": number,
"r_end": number,
"c": number,
"a_end": number,
"a": number,
"theta": number,
},
...,
],
"param_history?": [
[{"theta": number, "R": number, "c": number}, ...],
...,
],
},
},
"tasks": [
{
"num_games": int,
"active": bool,
"last_updated": datetime,
"start": int,
"residual?": number,
"residual_color?": str,
"bad?": True,
"stats": results_schema,
"worker_info": worker_info_schema,
},
...,
],
"bad_tasks?": [
{
"num_games": int,
"active": False,
"last_updated": datetime,
"start": int,
"residual": number,
"residual_color": str,
"bad": True,
"task_id": int,
"stats": results_schema,
"worker_info": worker_info_schema,
},
...,
],
}
Conventions
- As in typescript, a (string) key ending in "?" represents an optional key. The corresponding schema (the item the key points to) will only be used for validation when the key is present in the object that should be validated. A key can also be made optional by wrapping it as
optional_key(key)
. - If in a list/tuple the last entry is
...
(ellipsis) it means that the next to last entry will be repeated zero or more times. In this way generic types can be created. For example the schema[str, ...]
represents a list of strings.
Usage
To validate an object against a schema one can simply do
validate(schema, object)
If the validation fails this will throw a ValidationError
and the exception contains an explanation about what went wrong. The full signature of validate
is
validate(schema, object, name="object", strict=True)
- The optional
name
argument is used to refer to the object being validated in the returned message. - The optional argument
strict
indicates whether or not the object being validated is allowed to have keys/entries which are not in the schema.
Wrappers
A wrapper takes one or more schemas as arguments and produces a new schema.
- An object matches the schema
union(schema1, ..., schemaN)
if it matches one of the schemasschema1, ..., schemaN
. This is almost the same as{schema1, ..., schemaN}
, or equivalentlyset((schema1, ..., schemaN))
ifschema1, ..., schemaN
are hashable. - An object matches the schema
intersect(schema1, ..., schemaN)
if it matches all the schemasschema1, ..., schemaN
. - An object matches the schema
complement(schema)
if it does not matchschema
. - An object matches the schema
lax(schema)
when it matchesschema
withstrict=False
, see below. - An object matches the schema
strict(schema)
when it matchesschema
withstrict=True
, see below. - An object matches the schema
quote(schema)
if it is equal toschema
. For example the schema{"cats", "dogs"}
matches the strings"cats"
and"dogs"
but the schemaquote({"cats", "dogs"})
matches the set{"cats", "dogs"}
. - An object matches the schema
set_name(schema, name)
if it matchesschema
. But thename
argument will be used in non-validation messages.
Built-ins
Some built-ins take arguments. If no arguments are given then the ()
can be omitted. So email
is equivalent to email()
.
regex(pattern, name=None, fullmatch=True, flags=0)
. This matches the strings which match the given pattern. The optionalname
argument may be used to give the regular expression a descriptive name. By default the entire string is matched, but this can be overruled via thefullmatch
argument. Theflags
argument has the usual meaning.interval(lowerbound, upperbound)
. This checks iflowerbound <= object <= upperbound
, provided the comparisons make sense. An upper/lowerbound...
(ellipsis) means that the corresponding inequality is not checked.number
. Matchesint
andfloat
.email
. Checks if the object is a valid email address. This uses the packageemail_validator
. Theemail
schema accepts the same options asvalidate_email
in loc. cit.ip_address
andurl
. These are similar toemail
.domain_name(ascii_only=True)
. Checks if the object is a valid domain name. Ifascii_only=False
then allow IDNA domain names.date
. Without argument this represents an ISO 8601 date. An argument corresponds to a format string forstrftime
.
Format
A schema can be, in order of precedence:
- An object having a
__validate__
attribute with signature__validate__(object, name, strict)
This is for example how the wrapper schemas are implemented internally. The parameters of__validate__()
have the same semantics as those ofvalidate()
. The return value of__validate__()
should be the empty string if validation succeeds, and otherwise it should be an explanation about what went wrong. - A Python type. In that case validation is done by checking membership.
- A callable. Validation is done by applying the callable to the object.
- A
list
or atuple
. Validation is done by first checking membership of the corresponding types, and then performing validation for each of the entries of the object being validated against the corresponding entries of the schema. - A dictionary. Validation is done by first checking membership of the
dict
type, and then performing validation for each of the items of the object being validated against the corresponding items of the schema. - A
set
. A set validates an object, if one of its members does. - An arbitrary Python object. Validation is done by checking equality of the schema and the object, except when the schema is of type
float
, in which casemath.isclose
is used.
Creating types
A cool feature of vtjson
is that one can transform a schema into a genuine Python type via
t = make_type(schema)
so that validation can be done via
isinstance(object, t)
The drawback, compared to using validate
directly, is that there is no feedback when validation fails. You can get it back as a console debug message via the optional debug
argument to make_type
.
The full signature of make_type
is
make_type(schema, name=None, strict=True, debug=False)
The optional name
argument is used to set the __name__
attribute of the type. If it is not supplied then vtjson
tries to make an educated guess.
Examples
>>> from vtjson import set_name, validate
>>> schema = {"fruit" : {"apple", "pear", "strawberry"}, "price" : float}
>>> object = {"fruit" : "dog", "price": 1.0 }
>>> validate(schema, object)
...
vtjson.ValidationError: object['fruit'] (value:dog) is not equal to 'pear' and object['fruit'] (value:dog) is not equal to 'strawberry' and object['fruit'] (value:dog) is not equal to 'apple'
>>> fruit = set_name({"apple", "pear", "strawberry"}, "fruit")
>>> schema = {"fruit" : fruit, "price" : float}
>>> validate(schema, object)
...
vtjson.ValidationError: object['fruit'] (value:dog) is not of type 'fruit'
>>> object = {"fruit" : "apple"}
>>> validate(schema, object)
...
vtjson.ValidationError: object['price'] is missing
For many more examples see the file test_validate.py
in the source distribution.
FAQ
Q: Why not just use the Python implementation of JSON schema
(see https://pypi.org/project/jsonschema/)?
A: Various reasons.
- A
vtjson
schema is much more concise than aJSON
schema! vtjson
can validate objects which are more general than strictlyJSON
. See the introductory example above.- More fundamentally the design philosophy of
vtsjon
is different. Avtjson
schema leverages the versatile Python language whereas aJSON
schema is language independent and fully declarative. Both of these are of course a very nice properties, but, this being said, declarative languages have a tendency to suffer from feature creep when trying to deal with more and more exotic use cases (e.g.css
).vtjson
on the other hand is partially declarative, with a limited, but easily extendable set of primitives. Additional functionality can be provided with bits of imperative code when appropriate (see theordered_pair
example below). In practice this is what you will need anyway since a purely declarative language will never be able to deal with every possible validation scenario.
Q: How is this different from https://pypi.org/project/json-checker/ ?
A: Good question! I discovered json-checker
after I had written vtjson
. Although the details are different json-checker
and vtjson
share many of the same principles.
Q: How to combine validations?
A: Use intersect
. For example the following schema validates positive integers but reject positive floats.
schema = intersect(int, interval(0, ...))
More generally one may use the pattern intersect(schema, more_validations)
where the first argument makes sure that the object to be validated has the required layout to be an acceptable input for the later arguments. For example an ordered pair of integers can be validated using the schema
def ordered_pair(o):
return o[0] <= o[1]
schema = intersect((int, int), ordered_pair)
Or in a one liner
schema = intersect((int, int), set_name(lambda o: o[0] <= o[1], "ordered_pair"))
The following also works if you are content with less nice output on validation failure (try it)
schema = intersect((int, int), lambda o: o[0] <= o[1])
Project details
Release history Release notifications | RSS feed
Download files
Download the file for your platform. If you're not sure which to choose, learn more about installing packages.
Source Distribution
Built Distribution
File details
Details for the file vtjson-1.1.21.tar.gz
.
File metadata
- Download URL: vtjson-1.1.21.tar.gz
- Upload date:
- Size: 9.7 kB
- Tags: Source
- Uploaded using Trusted Publishing? No
- Uploaded via: twine/4.0.2 CPython/3.9.18
File hashes
Algorithm | Hash digest | |
---|---|---|
SHA256 | ed89edf09c0518778bd2553c0de3c9bcbbd6408e5e21e509dacdb1e00f79a800 |
|
MD5 | 0423c465b6ce7ac38db2fabeb74eeed3 |
|
BLAKE2b-256 | 6611603e91917b28516545a1a0b03462891cedbd706b8eb3fc878f04c1277207 |
File details
Details for the file vtjson-1.1.21-py3-none-any.whl
.
File metadata
- Download URL: vtjson-1.1.21-py3-none-any.whl
- Upload date:
- Size: 9.5 kB
- Tags: Python 3
- Uploaded using Trusted Publishing? No
- Uploaded via: twine/4.0.2 CPython/3.9.18
File hashes
Algorithm | Hash digest | |
---|---|---|
SHA256 | 04ccaceb16ef33599d6bd445f5b9a6802aca19d5ef2c7bd80e226827e24e2854 |
|
MD5 | 5ca76fcd01afe4ffe2bdbd5a7af55962 |
|
BLAKE2b-256 | a4e8377c7c81db61a1d72364872b265e00253377c4b9784bdcbeae1b0c158580 |