Metadata-Version: 2.4
Name: json-fingerprint
Version: 0.14.1
Summary: Create consistent and comparable fingerprints with secure hashes from unordered JSON data
Home-page: https://github.com/cobaltine/json-fingerprint
Author: Ville Lehtinen
Author-email: ville.lehtinen@cobaltine.fi
License: MIT
Project-URL: Changelog, https://github.com/cobaltine/json-fingerprint/releases
Project-URL: Homepage, https://github.com/cobaltine/json-fingerprint
Project-URL: Source, https://github.com/cobaltine/json-fingerprint
Project-URL: Tracker, https://github.com/cobaltine/json-fingerprint/issues
Keywords: json fingerprint hash
Classifier: License :: OSI Approved :: MIT License
Classifier: Development Status :: 4 - Beta
Classifier: Topic :: File Formats :: JSON
Classifier: Operating System :: OS Independent
Classifier: Programming Language :: Python :: 3
Classifier: Programming Language :: Python :: 3.8
Classifier: Programming Language :: Python :: 3.9
Classifier: Programming Language :: Python :: 3.10
Classifier: Programming Language :: Python :: 3.11
Classifier: Programming Language :: Python :: 3.12
Classifier: Programming Language :: Python :: 3.13
Requires-Python: >=3.8
Description-Content-Type: text/markdown
License-File: LICENSE
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# json-fingerprint

![](https://img.shields.io/github/license/cobaltine/json-fingerprint)
[![](https://img.shields.io/pypi/v/json-fingerprint)](https://pypi.org/project/json-fingerprint/)
![](https://img.shields.io/pypi/pyversions/json-fingerprint)
[![Coverage Status](https://coveralls.io/repos/github/cobaltine/json-fingerprint/badge.svg?branch=main)](https://coveralls.io/github/cobaltine/json-fingerprint?branch=main)

Create consistent and comparable fingerprints with secure hashes from unordered JSON data.

Common use cases include:
- Detecting duplicate payloads in a data pipeline
- Generating cache keys in a distributed environment
- Data integrity checks for JSON datasets

A JSON fingerprint consists of three parts: the version of the underlying canonicalization algorithm, the hash function used and a hexadecimal digest of the hash function output. An example output could look like this: `jfpv1$sha256$5815eb0ce6f4e5ab0a771cce2a8c5432f64222f8fd84b4cc2d38e4621fae86af`.

| Fingerprint element | Description                                                                          |
|:--------------------|:-------------------------------------------------------------------------------------|
| jfpv1               | JSON fingerprint version identifier: **j**son **f**inger**p**rint **v**ersion **1**  | 
| $                   | JSON fingerprint element separator                                                   |
| sha256              | Hash function identifier (sha256, sha384 or sha512)                                  |
| 5815eb0c...1fae86af | The secure hash function output in hexadecimal format                                |


<!-- TOC titleSize:2 tabSpaces:2 depthFrom:2 depthTo:6 withLinks:1 updateOnSave:1 orderedList:0 skip:0 title:1 charForUnorderedList:* -->
## Table of Contents
* [v1 release checklist (jfpv1)](#v1-release-checklist-jfpv1)
* [Installation](#installation)
* [Examples](#examples)
  * [Create JSON fingerprints](#create-json-fingerprints)
  * [Decode JSON fingerprints](#decode-json-fingerprints)
  * [Match fingerprints](#match-fingerprints)
  * [Find matches in fingerprint lists](#find-matches-in-fingerprint-lists)
* [JSON normalization](#json-normalization)
  * [Alternative specifications](#alternative-specifications)
  * [JSON Fingerprint v1 (jfpv1)](#json-fingerprint-v1-jfpv1)
* [Performance](#performance)
  * [Example 1: flat data structures](#example-1-flat-data-structures)
  * [Example 2: nested data structures](#example-2-nested-data-structures)
  * [Example 3: big JSON objects](#example-3-big-json-objects)
* [Running tests](#running-tests)
<!-- /TOC -->

**NB:** JSON fingerprints up until `v0.12.2` ignored empty objects and arrays as values. This behavior was changed in `v0.13.0` which means that JSON fingerprints created with earlier versions may produce different and incomparable hashes depending on the presence of empty objects or arrays.

## Installation

To install the json-fingerprint package, run `pip install json-fingerprint`.


## Examples

The complete working examples below show how to use all core features of the `json_fingerprint` package.


### Create JSON fingerprints

JSON fingerprints can be created with the `create()` function, which requires three arguments: input (valid JSON string), hash function (SHA256, SHA384 and SHA512 are supported) and JSON fingerprint version (1).

```python
import json

import json_fingerprint
from json_fingerprint import hash_functions

json_1 = json.dumps([3, 2, 1, [True, False], {"foo": "bar"}])
json_2 = json.dumps([2, {"foo": "bar"}, 1, [False, True], 3])  # Different order
fp_1 = json_fingerprint.create(input=json_1, hash_function=hash_functions.SHA256, version=1)
fp_2 = json_fingerprint.create(input=json_2, hash_function=hash_functions.SHA256, version=1)
print(f"Fingerprint 1: {fp_1}")
print(f"Fingerprint 2: {fp_2}")
```

This will output two identical fingerprints regardless of the different order of the json elements:
```text
Fingerprint 1: jfpv1$sha256$2ecb0c919fcb06024f55380134da3bbaac3879f98adce89a8871706fe50dda03
Fingerprint 2: jfpv1$sha256$2ecb0c919fcb06024f55380134da3bbaac3879f98adce89a8871706fe50dda03
```

Since JSON objects with identical data content and structure will always produce identical fingerprints, the fingerprints can be used effectively for various purposes. These include finding duplicate JSON data from a larger dataset, JSON data cache validation/invalidation and data integrity checking.


### Decode JSON fingerprints

JSON fingerprints can be decoded with the `decode()` convenience function. It returns the version, hash function and secure hash in a tuple.

```python
import json_fingerprint

fp = "jfpv1$sha256$2ecb0c919fcb06024f55380134da3bbaac3879f98adce89a8871706fe50dda03"
version, hash_function, hash = json_fingerprint.decode(fingerprint=fp)
print(f"JSON fingerprint version: {version}")
print(f"Hash function: {hash_function}")
print(f"Hash hex digest: {hash}")
```

This will output the individual elements that make up a fingerprint as follows:
```text
JSON fingerprint version: 1
Hash function: sha256
Hash hex digest: 2ecb0c919fcb06024f55380134da3bbaac3879f98adce89a8871706fe50dda03
```


### Match fingerprints

The `match()` is another convenience function that matches JSON data against a fingerprint, and returns either `True` or `False` depending on whether the data matches the fingerprint or not. Internally, it will automatically choose the correct version and hash function based on the `target_fingerprint` argument.

```python
import json

import json_fingerprint

json_1 = json.dumps([3, 2, 1, [True, False], {"foo": "bar"}])
json_2 = json.dumps([3, 2, 1])
# "target_fp" contains the JSON fingerprint of "json_1"
target_fp = "jfpv1$sha256$2ecb0c919fcb06024f55380134da3bbaac3879f98adce89a8871706fe50dda03"
match_1 = json_fingerprint.match(input=json_1, target_fingerprint=target_fp)
match_2 = json_fingerprint.match(input=json_2, target_fingerprint=target_fp)
print(f"Fingerprint matches with json_1: {match_1}")
print(f"Fingerprint matches with json_2: {match_2}")
```

This will output the following:
```text
Fingerprint matches with json_1: True
Fingerprint matches with json_2: False
```


### Find matches in fingerprint lists

The `find_matches()` function takes a JSON string and a list of JSON fingerprints as input. It creates a fingerprint of the JSON input string of each different variant in the target list, and looks for matches in the fingerprint list. It can optionally also deduplicate the fingerprint input list, and results list.

```python
import json

import json_fingerprint

# "data" produces jfpv1 (SHA256): jfpv1$sha256$d119f4d8...b1710d9f
# "data produces jfpv1 (SHA384): jfpv1$sha384$9bca46fd...fd0e2e9c
json_data = json.dumps({"foo": "bar"})

fingerprints = [
    # SHA256 match
    "jfpv1$sha256$d119f4d8b802091520162b78f57a995a9ecbc88b20573b0c7e474072b1710d9f",
    # SHA256 match (duplicate)
    "jfpv1$sha256$d119f4d8b802091520162b78f57a995a9ecbc88b20573b0c7e474072b1710d9f",
    # SHA384 match
    ("jfpv1$sha384$9bca46fd7ef7aa2e16e68978b5eb5c294bd5b380780e81bcb1af97d4b339bca"
     "f7f6a622b2f1a955eea2fadb8fd0e2e9c"),
    # SHA256, not a match
    "jfpv1$sha256$73f7bb145f268c033ec22a0b74296cdbab1405415a3d64a1c79223aa9a9f7643",
]

# Output all matches, including the two identical SHA256 fingerprints
matches = json_fingerprint.find_matches(input=json_data, fingerprints=fingerprints)
print(*(f"\nMatch: {match[0:30]}..." for match in matches))

# Output deduplicated matches, removing one redundant SHA256 match
deduplicated_matches = json_fingerprint.find_matches(input=json_data,
                                                     fingerprints=fingerprints,
                                                     deduplicate=True)
print(*(f"\nDeduplicated match: {match[0:30]}..." for match in deduplicated_matches))
```

This will output the following results, first the list with a duplicate and the latter with deduplicated results:
```text
Match: jfpv1$sha256$d119f4d8b80209152...
Match: jfpv1$sha256$d119f4d8b80209152...
Match: jfpv1$sha384$9bca46fd7ef7aa2e1...

Deduplicated match: jfpv1$sha384$9bca46fd7ef7aa2e1...
Deduplicated match: jfpv1$sha256$d119f4d8b80209152...
```


## JSON normalization

The jfpv1 JSON fingerprint function transforms the data internally into a normalized (canonical) format before hashing the output.


### Alternative specifications

Most existing JSON normalization/canonicalization specifications, and related implementations, operate on three key aspects: data structures, values and data ordering. While the ordering of key-value pairs (objects) is straightforward, issues usually arise from the ordering of arrays.

The JSON specifications, including the most recent [RFC 8259](https://tools.ietf.org/html/rfc8259), have always considered the order of array elements to be _meaningful_. As data gets serialized, transferred, deserialized and serialized again throughout various systems, maintaining the order of array elements becomes impractical if not impossible in many cases. As a consequence, this makes the creation and comparison of secure hashes of JSON data across multiple systems a complex process.


### JSON Fingerprint v1 (jfpv1)

The jfpv1 specification takes a more _value-oriented_ approach toward JSON normalization and secure hash creation: values and value-related metadata bear most significance when JSON data gets normalized into the jfpv1 format. The original JSON data gets transformed into a flattened list of small objects, which are then hashed and sorted, and ultimately hashed again as a whole.

In practice, the jfpv1 specification purposefully ignores the original order of data elements in an array. The jfpv1 specification focuses instead on verifying that the following aspects of JSON datasets being compared match:

 * All values in the compared datasets are identical
 * The values exist in identical paths (arrays, object key-value pairs)

In the case of arrays, each array gets a unique hash identifier based on the data elements it holds. This way, each flattened value "knows" to which array it belongs to. This identifier is called a _sibling hash_ because it is derived from each array element's value as well as its neighboring values.


## Performance

The JSON fingerprint v1 specification and its first implementation have been designed with a primary focus on functional utility over performance. There are some performance-related characteristics that are good to be aware of:

 * Due to the way the internal _sibling hashes_ are computed, highly nested data structures will increase the processing time significantly
 * The amount of data in a single data element, or the number of elements in a flat array, is much less meaningful performance-wise than the overall depth of the data structure

Below are some examples of the performance impact when processing different types of data structures.


### Example 1: flat data structures

Processing an array of arrays with the maximum depth of 2 levels for each datum:

```python
import json
import time

import json_fingerprint
from json_fingerprint import hash_functions

data = json.dumps(
    [
        [1, 2],
        [3, 4],
        [5, 6],
        [7, 8],
        [9, 10],
        [11, 12],
    ]
)
start_time = time.time_ns()  # Measure time in nanoseconds
iterations = 1000
for i in range(iterations):
    json_fingerprint.create(input=data, hash_function=hash_functions.SHA256, version=1)
end_time = time.time_ns()
duration = round(((end_time - start_time) / iterations / 1000000), 2)  # To milliseconds
print(f"Average processing time per JSON fingerprint: {duration} milliseconds")
```

Performance test results:
```text
Average processing time per JSON fingerprint: 0.27 milliseconds
```

As seen in the test results, flat data structures perform well on modern computer hardware.


### Example 2: nested data structures

Processing a nested array of arrays with datums `11` and `12` 7 levels deep in the data structure:

```python
import json
import time

import json_fingerprint
from json_fingerprint import hash_functions

data = json.dumps(
    [
        [1, 2, [3, 4, [5, 6, [7, 8, [9, 10, [11, 12]]]]]],
    ]
)
start_time = time.time_ns()  # Measure time in nanoseconds
iterations = 1000
for i in range(iterations):
    json_fingerprint.create(input=data, hash_function=hash_functions.SHA256, version=1)
end_time = time.time_ns()
duration = round(((end_time - start_time) / iterations / 1000000), 2)  # To milliseconds
print(f"Average processing time per JSON fingerprint: {duration} milliseconds")
```

Performance test results:
```text
Average processing time per JSON fingerprint: 2.75 milliseconds
```

Compared to the flat data structure with the same amount of data, the nesting of arrays increased the processing time tenfold.


### Example 3: big JSON objects

Processing a dynamically generated JSON object of three different sizes: `~256KiB`, `~512KiB`, and `~1MiB`:

```python
import json
import time

import json_fingerprint
from json_fingerprint import hash_functions


def test_performance(data: str, size: str) -> None:
    start_time = time.time_ns()  # Measure time in nanoseconds
    iterations = 1000
    for i in range(iterations):
        json_fingerprint.create(input=data, hash_function=hash_functions.SHA256, version=1)
    end_time = time.time_ns()
    duration = round(((end_time - start_time) / iterations / 1000000), 2)  # To milliseconds
    print(f"Average processing time per JSON fingerprint ({size}): {duration} milliseconds")


text = "abcdefg " * 16384  # a single text element (~128KiB)
text_list = ["hijklmn " * 128 for i in range(128)]  # 128 * 1KiB text elements (~128KiB)
test_performance(json.dumps({"text": text, "text_list": text_list}), "~256KiB")
test_performance(json.dumps({"text": text * 2, "text_list": text_list * 2}), "~512KiB")
test_performance(json.dumps({"text": text * 4, "text_list": text_list * 4}), "~1MiB")
```

Performance test result:
```text
Average processing time per JSON fingerprint (~256KiB): 2.91 milliseconds
Average processing time per JSON fingerprint (~512KiB): 5.42 milliseconds
Average processing time per JSON fingerprint (~1MiB): 11.18 milliseconds
```

Processing fairly sizeable JSON objects with text content in a flat structure scales linearly.


## Running tests

The entire internal test suite of json-fingerprint is included in its distribution package. If you wish to run the internal test suite, install the package and run the following command:

`python -m json_fingerprint.tests.run`

If all tests ran successfully, this will produce an output similar to the following:

```text
...............................
----------------------------------------------------------------------
Ran 31 tests in 0.008s

OK
```
