Metadata-Version: 2.0
Name: coincurve
Version: 4.5.1
Summary: Cross-platform Python CFFI bindings for libsecp256k1
Home-page: https://github.com/ofek/coincurve
Author: Ofek Lev
Author-email: ofekmeister@gmail.com
License: MIT
Download-URL: https://github.com/ofek/coincurve
Keywords: secp256k1,elliptic curves,bitcoin,ethereum,cryptocurrency
Platform: UNKNOWN
Classifier: Development Status :: 5 - Production/Stable
Classifier: Intended Audience :: Developers
Classifier: License :: OSI Approved :: MIT License
Classifier: Natural Language :: English
Classifier: Operating System :: OS Independent
Classifier: Programming Language :: Python :: 2.7
Classifier: Programming Language :: Python :: 3
Classifier: Programming Language :: Python :: 3.5
Classifier: Programming Language :: Python :: 3.6
Classifier: Programming Language :: Python :: Implementation :: CPython
Classifier: Programming Language :: Python :: Implementation :: PyPy
Classifier: Topic :: Software Development :: Libraries
Classifier: Topic :: Security :: Cryptography
Requires-Dist: asn1crypto
Requires-Dist: cffi (>=1.3.0)

Coincurve
=========

.. image:: https://img.shields.io/pypi/v/coincurve.svg?style=flat-square
    :target: https://pypi.org/project/coincurve

.. image:: https://img.shields.io/travis/ofek/coincurve.svg?branch=master&style=flat-square
    :target: https://travis-ci.org/ofek/coincurve

.. image:: https://img.shields.io/pypi/pyversions/coincurve.svg?style=flat-square
    :target: https://pypi.org/project/coincurve

.. image:: https://img.shields.io/badge/license-MIT-blue.svg?style=flat-square
    :target: https://en.wikipedia.org/wiki/MIT_License

-----

This library provides well-tested Python CFFI bindings for
`libsecp256k1 <https://github.com/bitcoin-core/secp256k1>`_, the heavily
optimized C library used by `Bitcoin Core <https://github.com/bitcoin/bitcoin>`_
for operations on elliptic curve secp256k1.

Coincurve replaces `secp256k1-py <https://github.com/ludbb/secp256k1-py>`_.

New features include:

- Cleaner API
- Uses newest version of `libsecp256k1 <https://github.com/bitcoin-core/secp256k1>`_
- Support for Windows
- Linux, macOS, and Windows all have binary packages for both 64 and 32-bit architectures
- Linux & macOS use GMP for faster computation
- Endomorphism optimization is enabled
- A global context is used by default, drastically increasing performance
- Fixed ECDH
- A fix to remove CFFI warnings
- Implements a fix for `<https://bugs.python.org/issue28150>`_ to support Python 3.6+ on macOS

Installation
------------

Coincurve is distributed on PyPI and is available on Linux/macOS and Windows and
supports Python 2.7/3.5+ and PyPy3.5-v5.7.1+.

.. code-block:: bash

    $ pip install coincurve

If you are on a system that doesn't have a precompiled binary wheel (e.g. FreeBSD)
then pip will fetch source to build yourself. You must have the necessary packages.

On Debian/Ubuntu for example the necessary packages are:

- build-essential
- automake
- pkg-config
- libtool
- libffi-dev
- libgmp-dev

API
---

Coincurve provides a simple API.

coincurve.verify_signature
^^^^^^^^^^^^^^^^^^^^^^^^^^

``verify_signature(signature, message, public_key, hasher=sha256, context=GLOBAL_CONTEXT)``

Verifies some message was signed by the owner of a public key.

* Parameters:

    - **signature** (``bytes``) - The signature to verify.
    - **message** (``bytes``) - The message that was supposedly signed.
    - **public_key** (``bytes``) - A public key in compressed or uncompressed form.
    - **hasher** - The hash function to use. hasher(message) must return 32 bytes.
    - **context** (``coincurve.Context``)

* Returns: ``bool``

coincurve.PrivateKey
^^^^^^^^^^^^^^^^^^^^

All instances have a ``public_key`` of type ``coincurve.PublicKey``

``PrivateKey(secret=None, context=GLOBAL_CONTEXT)``

* Parameters:

    - **secret** (``bytes``) - The secret to use.
    - **context** (``coincurve.Context``)

Methods
~~~~~~~

*classmethod* ``from_hex(hexed, context=GLOBAL_CONTEXT)``

*classmethod* ``from_int(num, context=GLOBAL_CONTEXT)``

*classmethod* ``from_pem(pem, context=GLOBAL_CONTEXT)``

*classmethod* ``from_der(der, context=GLOBAL_CONTEXT)``

``sign(message, hasher=sha256)``

* Parameters:

    - **message** (``bytes``) - The message to sign.
    - **hasher** - The hash function to use. hasher(message) must return 32 bytes.

* Returns: ``bytes``. 71 <= len(signature) <= 72

``sign_recoverable(message, hasher=sha256)``

* Parameters:

    - **message** (``bytes``) - The message to sign.
    - **hasher** - The hash function to use. hasher(message) must return 32 bytes.

* Returns: ``bytes``

``ecdh(public_key)``

Computes a Diffie-Hellman secret in constant time.

* Parameters:

    - **public_key** (``bytes``) - Another party's public key in compressed or uncompressed form.

* Returns: ``bytes``

``add(scalar, update=False)``

* Parameters:

    - **scalar** (``bytes``) - The scalar to add.
    - **update** - If ``True``, will update and return ``self``.

* Returns: ``coincurve.PrivateKey``

``multiply(scalar, update=False)``

* Parameters:

    - **scalar** (``bytes``) - The scalar to multiply.
    - **update** - If ``True``, will update and return ``self``.

* Returns: ``coincurve.PrivateKey``

``to_hex()``

``to_int()``

``to_pem()``

``to_der()``

coincurve.PublicKey
^^^^^^^^^^^^^^^^^^^

``PublicKey(data, context=GLOBAL_CONTEXT)``

* Parameters:

    - **data** (``bytes``) - The public key in compressed or uncompressed form.
    - **context** (``coincurve.Context``)

Methods
~~~~~~~

*classmethod* ``from_secret(secret, context=GLOBAL_CONTEXT)``

*classmethod* ``from_valid_secret(secret, context=GLOBAL_CONTEXT)``

*classmethod* ``from_point(x, y, context=GLOBAL_CONTEXT)``

*classmethod* ``from_signature_and_message(serialized_sig, message, hasher=sha256, context=GLOBAL_CONTEXT)``

``format(compressed=True)``

* Parameters:

    - **compressed** (``bool``)

* Returns: The public key serialized to ``bytes``.

``point()``

* Returns: (x, y)

``verify(signature, message, hasher=sha256)``

Verifies some message was signed by the owner of this public key.

* Parameters:

    - **signature** (``bytes``) - The signature to verify.
    - **message** (``bytes``) - The message that was supposedly signed.
    - **hasher** - The hash function to use. hasher(message) must return 32 bytes.

* Returns: ``bool``

``add(scalar, update=False)``

* Parameters:

    - **scalar** (``bytes``) - The scalar to add.
    - **update** - If ``True``, will update and return ``self``.

* Returns: ``coincurve.PublicKey``

``multiply(scalar, update=False)``

* Parameters:

    - **scalar** (``bytes``) - The scalar to multiply.
    - **update** - If ``True``, will update and return ``self``.

* Returns: ``coincurve.PublicKey``












