Metadata-Version: 2.1
Name: bpl-lib
Version: 0.1.0
Summary: A library for the Blockpool Blockchain.
Home-page: https://github.com/DuneRoot/bpl-lib
Author: Alistair O'Brien
Author-email: alistair.o'brien@ellesmere.com
License: UNKNOWN
Description: # BPL lib
        
        > A simple Python package for the Blockpool Blockchain
        
        This is an easy-to-use Python package for interacting with a Blockpool Blockchain. This package provided the majority of the functionality provided by [BPL-JS](https://github.com/blockpool-io/BPL-js)
        
        ## Features
        
        ### Address
        - [x] from_secret
        - [x] from_public_key
        - [ ] from_private_key
        - [x] validate
        
        ### Network
        - [x] use
        - [x] use_custom
        - [x] get_begin_epoch
        - [x] get_version
        
        ### Transaction Entity
        - [x] generate
        - [x] get_id
        - [x] get_hash
        - [x] sign
        - [x] second_sign
        - [x] to_bytes
        - [x] to_dict
        - [x] from_dict
        - [x] verify
        - [x] second_verify
        
        ### Transaction Types
        - [x] Transfer Transaction
        - [x] Vote Transaction
        - [x] Second Signature Transaction
        - [x] Multi-Signature Transaction
        - [x] Delegate Transaction
        - [x] IPFS Transaction
        
        ### Time
        - [x] get_time
        - [x] get_real_time
        - [x] get_slot_number
        - [x] get_slot_time
        
        ## Installation
        
        ```sh 
        python -m pip install --no-cache-dir --index-url https://test.pypi.org/simple/ bpl-lib
        ```
        
        Note: package has been uploaded to test.pypi. Some dependencies might not be able to be install (e.g. base58) due to this. If this occurs use:
        ```sh
        pip install base58
        pip install ecdsa
        ```
        
        Then 
        ```sh 
        python -m pip install --no-cache-dir --index-url https://test.pypi.org/simple/ bpl-lib
        ```
        
        
        ## Usage
        
        There are 6 main sub-packages in bpl-lib:
        
        - ``bpl_lib.address``
        - ``bpl_lib.crypto``
        - ``bpl_lib.helpers``
        - ``bpl_lib.network``
        - ``bpl_lib.time``
        - ``bpl_lib.transactions``
        
        ***
        
        ### Addresses
        
        #### Generating an Address
        
        There are currently 2 methods for generating an address:
        - ``from_public_key``
        - ``from_secret``
        
        Note: Addresses are dependent on the ``version`` of the network, therefore to generate an address you must first select a network (see network section).
        ##### from_public_key
        
        To generate a unique Blockpool address from a given public key:
        ```python
        from bpl_lib.address import Address
        from bpl_lib.network import Network
        
        Network.use("mainnet")
        public_key = "03aacac6c98daaf3d433fe90e9295ce380916946f850bcdc6f6880ae6503ca1e40"
        address = Address.from_public_key(public_key)
        
        print(address)
        ```
        
        Printing:
        
        ```python
        b'AdzCBJt2F2Q2RYL7vnp96QhTeGdDZNZGeJ'
        ```
        
        ##### from_secret
        
        To generate a unique Blockpool address from a given secret passphrase:
        ```python
        from bpl_lib.address import Address
        from bpl_lib.network import Network
        
        Network.use("mainnet")
        address = Address.from_secret("secret passphrase")
        
        print(address)
        ```
        
        Printing:
        
        ```python
        b'AdzCBJt2F2Q2RYL7vnp96QhTeGdDZNZGeJ'
        ```
        
        #### Validation
        
        Note: Addresses are dependent on the ``version`` of the network, therefore to validate an address you must first select a network (see network section).
        
        ```python
        from bpl_lib.address import Address
        from bpl_lib.network import Network
        
        Network.use("mainnet")
        address = "AdzCBJt2F2Q2RYL7vnp96QhTeGdDZNZGeJ"
        is_valid = Address.validate(address)
        
        print(is_valid)
        ```
        
        Printing:
        
        ```python
        True
        ```
        
        ***
        
        ### Cryptography
        
        #### Generating Keys
        ```python
        from bpl_lib.crypto import Keys
        
        keys = Keys("secret passphrase").to_dict()
        
        print(keys)
        ```
        
        Printing:
        
        ```python
        {
            "public_key": "03aacac6c98daaf3d433fe90e9295ce380916946f850bcdc6f6880ae6503ca1e40",
            "private_key": "b6a2b12beb4179538bfb42423cce2e98ccdebcc684145ba977f2f80630eb278e"
        }
        ```
        
        #### Signatures
         ```python
        from bpl_lib.crypto import Signature, sha256
        
        message = sha256("message".encode())
        signature = Signature("secret passphrase").sign(message)["signature"]
        
        print(signature)
        ```
        
        Printing:
        ```python
        "30440220622b8edf8fc5cf4522a13489a9b710b1bf94b6e37722d2278a0069ae3c67088b0220206e202dcad8e4ee2100716ce0d2c7d08a685f983c21dfbccdd6ecec50268b6f"
        ```
        
        #### Hashing
        The ``crypto`` sub-package also provides common hashing algorithms such as:
        - ``sha1(bytes)``
        - ``sha256(bytes)``
        - ``ripemd160(bytes)``
        - ``hash160(bytes)``
        - ``hash256(bytes)``
        
        ***
        
        ### Helpers
        The helpers package contains useful contains and classes:
        - ``TRANSACTION_TYPE`` - Enum Class containing all 6 transaction types
        - ``TRANSACTION_FEES`` - Transaction fees depending on `TRANSACTION_TYPE`
        - ``NETWORKS_DB`` - Networks database file location
        
        ***
        
        ### Network
        The networks sub-package is an interface for network configurations.  The networks sub-package makes use of a local SQLite database, which stores the network identifier, begin epoch time and network version. These setting / fields are require for calculations such as addresses and timestamps.
        
        #### Using a network
        There are current 2 methods that allows a client to use a network:
        - ``use``
        - ``use_custom``
        
        ##### use
        The `use` method requires a network ``identifier`` and queries the local network database for the specified configuration. The method then stores the configuration in memory. 
        
        ```python
        from bpl_lib.network import Network
        
        Network.use("mainnet")
        
        print(Network.get_begin_epoch())
        print(Network.get_version())
        ```
        
        Printing:
        
        ```python
        "2017-03-21 13:00:00"
        23
        ```
        
        ##### use_custom
        The `use_custom` method requires a network `identifier`, `begin_epoch` and `version`. The method first inserts this custom configuration into the local network database, this will allow you to make use of the custom configuration in other applications. After that the method stores the custom configuration in memory. 
        
        Note: ``identifier`` is used as the primary key in the database, this implies that the identifier for the network must be unique. If the identifier is not unique a `BPLNetworkException` is raised.
        ```python
        from datetime import datetime 
         
        from bpl_lib.network import Network
        
        identifier = "test_use_custom_method"
        begin_epoch = datetime.strptime("2018-07-25 15:30:00", "%Y-%m-%d %H:%M:%S")
        version = 0x19
        
        Network.use_custom(identifier, begin_epoch, version)
        
        print(Network.get_begin_epoch())
        print(Network.get_version())
        ```
        
        Printing:
        
        ```python
        "2018-07-25 15:30:00"
        25
        ```
        
        #### Accessing the current configuration
        After loading a network configuration into memory, there are 2 settings that can be accessed via the `Network` interface:
        - `begin_epoch`
        - `version`
        
        ##### Accessing begin_epoch
        To access `begin_epoch` the `Network.get_begin_epoch` method must be used. 
        ```python
        from bpl_lib.network import Network
        
        Network.use("testnet")
        
        print(Network.get_begin_epoch())
        ```
        
        Printing:
        
        ```python
        "2017-03-21 13:00:00"
        ```
        
        ##### Accessing version
        To access `version` the `Network.get_version` method must be used.
        ```python
        from bpl_lib.network import Network
        
        Network.use("testnet")
        
        print(Network.get_version())
        ```
        
        Printing:
        ```python
        82
        ```
        
        ***
        
        ### Time
        The time sub-package contains 4 methods:
        - `get_time` - returns the timestamp for the blockchain
        - `get_real_time` - converts blockchain timestamp to datetime
        - `get_slot_number` - converts blockchain timestamp to slot number
        - `get_slot_time` - converts slot number to blockchain timestamp
        
        #### get_time
        The `get_time` method converts a datetime object to a blockchain timestamp. The method has an optional argument `time`. If `time` is not provided then the current time will be used. (See code)
        ```python
        from bpl_lib.time import Time
        
        print(Time.get_time())
        ```
        
        Printing:
        
        ```python
        42429391
        ```
        
        #### get_real_time
        The `get_real_time` method converts a blockchain timestamp into a datetime object. The method has an optional argument `timestamp`. If `timestamp` is not provided then the current timestamp will be used. (See code)
        ```python
        from bpl_lib.time import Time
        
        print(Time.get_real_time(42429391))
        ```
        
        Printing:
        
        ```python
        "2018-07-25 14:56:31"
        ```
        
        #### get_slot_number
        The `get_slot_number` method converts a blockchain timestamp into a slot number. The method has an optional argument `timestamp`. If `timestamp` is not provided then the current timestamp will be used. (See code)
        ```python
        from bpl_lib.time import Time
        
        print(Time.get_slot_number())
        ```
        
        Printing:
        
        ```python
        5303721
        ```
        
        #### get_slot_time
        The `get_slot_time` method converts a slot number into a blockchain timestamp. The method has an optional argument `slot_number`. If `slot_number` is not provided then the current slot number will be used. (See code)
        ```python
        from bpl_lib.time import Time
        
        print(Time.get_slot_time(5303721))
        ```
        
        Printing:
        
        ```python
        42429768
        ```
        
        ***
        
        ### Transactions
        Each transaction is built from the Transaction Entity (See Features). There are 2 currently possible ways of building a BPL transaction:
         - `Transaction.generate`
         - `Transaction.from_dict`
         
        #### Buidling a transaction using generate
        `Transaction.generate` automatically calculates the timestamp for the transaction, therefore a network must be selected before a transaction can be built. (See network)
        
        ```python
        from bpl_lib.transactions.Transfer import Transfer
        from bpl_lib.network import Network
        
        Network.use("mainnet")
        transaction = Transfer.generate("BCU4rocsgw2GNihtnzAgFzRfx7XebZRpRi", 1000, "passphrase")
        
        print(transaction.to_dict())
        ```
        Printing:
        
        ```python
        {  
           'recipientId': 'BCU4rocsgw2GNihtnzAgFzRfx7XebZRpRi',
           'senderPublicKey': '02e012f0a7cac12a74bdc17d844cbc9f637177b470019c32a53cef94c7a56e2ea9',
           'type': "<TRANSACTION_TYPE.TRANSFER: 0>",
           'id': '9bfa3aee9ed984f856c6268b0b03dd908d3541c4c94f614fdae5c66c587560b2',
           'asset': {},
           'venderField': None,
           'fee': 10000000,
           'signature': '3045022100faf1e2bb7388caf0ba4ca26d6bddf9ea39197365d369f63efe271ad183745a77022047865c97baa925369ee099594010f7e7912772febbb83bcb9512f9b2759ac97d',
           'timestamp': 42430405,
           'amount': 1000,
           'signSignature': None
        }
        ```
        
        To see how each transaction is built see the documentation in the code. 
        
        ***
        
        ## Security or Errors
        
        If you discover a security vulnerability or error within this package, please email [me](mailto:alistair.o'brien@ellesmere.com) or message me on the [BPL discord](https://discordapp.com/invite/67HxSKq).
        
        ***
        
        ## Credits
        
        - [Alistair O'Brien](https://github.com/johnyob)
Platform: UNKNOWN
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