An automated Bitcoin wallet collider that brute forces random wallet addresses 50% faster!
1AE49AcJKLYd3XCgLdHaSGyZGVLeR8Pzo7
Python 3.6 or higher
Python modules listed in the requirements.txt
Minimum RAM requirements
$ git clone https://github.com/imcmurray/Plutus-fastecdsa.git
$ cd Plutus-fastecdsa && pip3 install -r requirements.txt
$ python3 plutus.py
Bitcoin private keys allow a person to control the wallet that it correlates to. If the wallet has Bitcoins in it, then the private key will allow the person to spend whatever balance the wallet has.
This program attempts to brute force Bitcoin private keys in an attempt to successfully find a correlating wallet with a positive balance. In the event that a balance is found, the wallet's private key, public key and wallet address are stored in the text file plutus.txt on the user's hard drive.
This program is essentially a brute forcing algorithm. It continuously generates random Bitcoin private keys, converts the private keys into their respective wallet addresses, then checks the balance of the addresses. The ultimate goal is to randomly find a wallet with a balance out of the 2160 possible wallets in existence.
Private keys are generated randomly to create a 32 byte hexidecimal string using the cryptographically secure os.urandom() function.
The private keys are converted into their respective public keys using the fastecdsa starkbank-ecdsabinascii and hashlib standard libraries.
A pre-calculated database of every P2PKH Bitcoin address with a positive balance is included in this project. The generated address is searched within the database, and if it is found that the address has a balance, then the private key, public key and wallet address are saved to the text file plutus.txt on the user's hard drive.
This program also utilizes multiprocessing through the multiprocessing.Process() function in order to make concurrent calculations.
With Fastecdsa the efficieny of this code has increased by an average of 50%, from 0.0032457721 seconds (without Fastecdsa) to 0.0017291287 seconds (with Fastecdsa) for this progam to brute force a single Bitcoin address.
However, through multiprocessing.Process() a concurrent process is created for every CPU your computer has. So this program can brute force addresses at a speed of 0.0017291287 ÷ cpu_count() seconds.
Visit /database for information
Every time this program checks the balance of a generated address, it will print the result to the user. If an empty wallet was generated, then the wallet address will be printed to the terminal. An example is:
1Kz2CTvjzkZ3p2BQb5x5DX6GEoHX2jFS45
However, if a balance is found, then all necessary information about the wallet will be saved to the text file plutus.txt. An example is:
hex private key: 5A4F3F1CAB44848B2C2C515AE74E9CC487A9982C9DD695810230EA48B1DCEADD
public key: 04393B30BC950F358326062FF28D194A5B28751C1FF2562C02CA4DFB2A864DE63280CC140D0D540EA1A5711D1E519C842684F42445C41CB501B7EA00361699C320
address: 1Kz2CTvjzkZ3p2BQb5x5DX6GEoHX2jFS45
This program uses approximately 2GB of RAM per CPU. Becuase this program uses multiprocessing, some data gets shared between threads, making it difficult to accurately measure RAM usage. But the stack trace below is as precise as I could get it:
The memory consumption stack trace was made by using mprof to monitor this program brute force 10,000 addresses on a 4 logical processor machine with 8GB of RAM. As a result, 4 child processes were created, each consuming 2100MiB of RAM (~2GB).
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Added RAM requirements
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Database now only has P2PKH addresses. Addresses of other types have been removed
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Fastecdsa support for faster public key creation