#!/usr/bin/env python3 # # linearize-data.py: Construct a linear, no-fork version of the chain. # # Copyright (c) 2013-2016 The Bitcoin Core developers # Distributed under the MIT software license, see the accompanying # file COPYING or http://www.opensource.org/licenses/mit-license.php. # from __future__ import print_function, division import struct import re import os import os.path import sys import hashlib import datetime import time from collections import namedtuple from binascii import hexlify, unhexlify settings = {} ##### Switch endian-ness ##### def hex_switchEndian(s): """ Switches the endianness of a hex string (in pairs of hex chars) """ pairList = [s[i:i + 2].encode() for i in range(0, len(s), 2)] return b''.join(pairList[::-1]).decode() def uint32(x): return x & 0xffffffff def bytereverse(x): return uint32((((x) << 24) | (((x) << 8) & 0x00ff0000) | (((x) >> 8) & 0x0000ff00) | ((x) >> 24))) def bufreverse(in_buf): out_words = [] for i in range(0, len(in_buf), 4): word = struct.unpack('@I', in_buf[i:i + 4])[0] out_words.append(struct.pack('@I', bytereverse(word))) return b''.join(out_words) def wordreverse(in_buf): out_words = [] for i in range(0, len(in_buf), 4): out_words.append(in_buf[i:i + 4]) out_words.reverse() return b''.join(out_words) def calc_hdr_hash(blk_hdr): hash1 = hashlib.sha256() hash1.update(blk_hdr) hash1_o = hash1.digest() hash2 = hashlib.sha256() hash2.update(hash1_o) hash2_o = hash2.digest() return hash2_o def calc_hash_str(blk_hdr): hash = calc_hdr_hash(blk_hdr) hash = bufreverse(hash) hash = wordreverse(hash) hash_str = hexlify(hash).decode('utf-8') return hash_str def get_blk_dt(blk_hdr): members = struct.unpack(" self.maxOutSz): self.outF.close() if self.setFileTime: os.utime(self.outFname, (int(time.time()), self.highTS)) self.outF = None self.outFname = None self.outFn = self.outFn + 1 self.outsz = 0 (blkDate, blkTS) = get_blk_dt(blk_hdr) if self.timestampSplit and (blkDate > self.lastDate): print("New month " + blkDate.strftime("%Y-%m") + " @ " + self.hash_str) self.lastDate = blkDate if self.outF: self.outF.close() if self.setFileTime: os.utime(self.outFname, (int(time.time()), self.highTS)) self.outF = None self.outFname = None self.outFn = self.outFn + 1 self.outsz = 0 if not self.outF: if self.fileOutput: self.outFname = self.settings['output_file'] else: self.outFname = os.path.join( self.settings['output'], "blk{:05d}.dat".format(self.outFn)) print("Output file " + self.outFname) self.outF = open(self.outFname, "wb") self.outF.write(inhdr) self.outF.write(blk_hdr) self.outF.write(rawblock) self.outsz = self.outsz + len(inhdr) + len(blk_hdr) + len(rawblock) self.blkCountOut = self.blkCountOut + 1 if blkTS > self.highTS: self.highTS = blkTS if (self.blkCountOut % 1000) == 0: print('{} blocks scanned, {} blocks written (of {}, {:.1f}% complete)'.format( self.blkCountIn, self.blkCountOut, len(self.blkindex), 100.0 * self.blkCountOut / len(self.blkindex))) def inFileName(self, fn): return os.path.join(self.settings['input'], "blk{:05d}.dat".format(fn)) def fetchBlock(self, extent): '''Fetch block contents from disk given extents''' with open(self.inFileName(extent.fn), "rb") as f: f.seek(extent.offset) return f.read(extent.size) def copyOneBlock(self): '''Find the next block to be written in the input, and copy it to the output.''' extent = self.blockExtents.pop(self.blkCountOut) if self.blkCountOut in self.outOfOrderData: # If the data is cached, use it from memory and remove from the cache rawblock = self.outOfOrderData.pop(self.blkCountOut) self.outOfOrderSize -= len(rawblock) else: # Otherwise look up data on disk rawblock = self.fetchBlock(extent) self.writeBlock(extent.inhdr, extent.blkhdr, rawblock) def run(self): while self.blkCountOut < len(self.blkindex): if not self.inF: fname = self.inFileName(self.inFn) print("Input file " + fname) try: self.inF = open(fname, "rb") except IOError: print("Premature end of block data") return inhdr = self.inF.read(8) if (not inhdr or (inhdr[0] == "\0")): self.inF.close() self.inF = None self.inFn = self.inFn + 1 continue inMagic = inhdr[:4] if (inMagic != self.settings['netmagic']): print("Invalid magic: " + hexlify(inMagic).decode('utf-8')) return inLenLE = inhdr[4:] su = struct.unpack("