#include #include #include #include "ozf.h" #define OZF2_MAGIC 0x7778 #define OZF3_MAGIC 0x7780 static const quint8 XKEY[] = { 0x2D, 0x4A, 0x43, 0xF1, 0x27, 0x9B, 0x69, 0x4F, 0x36, 0x52, 0x87, 0xEC, 0x5F, 0x42, 0x53, 0x22, 0x9E, 0x8B, 0x2D, 0x83, 0x3D, 0xD2, 0x84, 0xBA, 0xD8, 0x5B }; static void decrypt(void *data, size_t size, quint8 init) { for (size_t i = 0; i < size; i++) reinterpret_cast(data)[i] ^= XKEY[i % sizeof(XKEY)] + init; } template bool OZF::readValue(T &val) { T data; if (_file.read((char*)&data, sizeof(T)) < (qint64)sizeof(T)) return false; if (_decrypt) decrypt(&data, sizeof(T), _key); if (sizeof(T) > 1) val = qFromLittleEndian(data); else val = data; return true; } bool OZF::read(void *data, size_t size, size_t decryptSize) { if (_file.read((char*)data, size) < (qint64)size) return false; if (_decrypt) decrypt(data, decryptSize ? qMin(decryptSize, size) : size, _key); return true; } bool OZF::initOZF3() { quint8 randomNumber, initial; quint8 h1[8]; quint8 h2[16], h2d[16]; if (!_file.seek(14)) return false; if (!readValue(randomNumber)) return false; if (!_file.seek(162)) return false; if (!readValue(initial)) return false; _decrypt = true; _key = initial; if (!_file.seek(0)) return false; if (!read(h1, sizeof(h1))) return false; _tileSize = *(h1 + 6); if (!_file.seek(15 + randomNumber + 4)) return false; if (_file.read((char*)h2, sizeof(h2)) != (qint64)sizeof(h2)) return false; for (int i = 0; i < 256; i++) { memcpy(h2d, h2, sizeof(h2d)); decrypt(h2d, sizeof(h2d), (quint8)i); if ((quint32)*h2d == 40 && (quint16)*(h2d + 12) == 1 && (quint16)*(h2d + 14) == 8) { _key = (quint8)i; return true; } } return false; } bool OZF::initOZF2() { if (!_file.seek(6)) return false; if (!readValue(_tileSize)) return false; return true; } bool OZF::readHeaders() { quint16 magic; if (!readValue(magic)) return false; if (magic == OZF2_MAGIC) { if (!initOZF2()) return false; } else if (magic == OZF3_MAGIC) { if (!initOZF3()) return false; } else { qWarning("%s: not a OZF2/OZF3 file", qPrintable(_file.fileName())); return false; } return true; } bool OZF::readTileTable() { quint32 tableOffset, headerOffset, bgr0, w, h; quint16 x, y; int zooms; if (!_file.seek(_file.size() - sizeof(tableOffset))) return false; if (!readValue(tableOffset)) return false; zooms = (int)((_file.size() - tableOffset - sizeof(quint32)) / sizeof(quint32)); for (int i = 0; i < zooms - 2; i++) { if (!_file.seek(tableOffset + i * sizeof(quint32))) return false; if (!readValue(headerOffset)) return false; if (!_file.seek(headerOffset)) return false; if (!readValue(w)) return false; if (!readValue(h)) return false; if (!readValue(x)) return false; if (!readValue(y)) return false; Zoom zoom; zoom.size = QSize(w, h); zoom.dim = QSize(x, y); zoom.palette = QVector(256); if (!read(&(zoom.palette[0]), sizeof(quint32) * 256)) return false; for (int i = 0; i < zoom.palette.size(); i++) { bgr0 = qFromLittleEndian(zoom.palette.at(i)); quint32 b = (bgr0 & 0x000000FF); quint32 g = (bgr0 & 0x0000FF00) >> 8; quint32 r = (bgr0 & 0x00FF0000) >> 16; zoom.palette[i] = 0xFF000000 | r << 16 | g << 8 | b; } zoom.tiles = QVector(zoom.dim.width() * zoom.dim.height() + 1); for (int i = 0; i < zoom.tiles.size(); i++) if (!readValue(zoom.tiles[i])) return false; _zooms.append(zoom); } return _zooms.isEmpty() ? false : true; } bool OZF::load(const QString &path) { if (_file.isOpen()) _file.close(); _file.setFileName(path); if (!_file.open(QIODevice::ReadOnly)) return false; if (!readHeaders()) { qWarning("%s: Invalid header", qPrintable(_file.fileName())); _file.close(); return false; } if (!readTileTable()) { qWarning("%s: Invalid tile table", qPrintable(_file.fileName())); _file.close(); return false; } return true; } QPixmap OZF::tile(int zoom, int x, int y) { Q_ASSERT(_file.isOpen()); Q_ASSERT(0 <= zoom && zoom < _zooms.count()); const Zoom &z = _zooms.at(zoom); int i = (y/tileSize().height()) * z.dim.width() + (x/tileSize().width()); if (i >= z.tiles.size() - 1 || i < 0) return QPixmap(); int size = z.tiles.at(i+1) - z.tiles.at(i); if (!_file.seek(z.tiles.at(i))) return QPixmap(); quint32 bes = qToBigEndian(tileSize().width() * tileSize().height()); QByteArray ba; ba.resize(sizeof(bes) + size); *(ba.data()) = bes; if (!read(ba.data() + sizeof(bes), size, 16)) return QPixmap(); QByteArray uba = qUncompress(ba); if (uba.size() != tileSize().width() * tileSize().height()) return QPixmap(); QImage img((const uchar*)uba.constData(), tileSize().width(), tileSize().height(), QImage::Format_Indexed8); img.setColorTable(z.palette); return QPixmap::fromImage(img.mirrored()); } QSize OZF::size(int zoom) const { Q_ASSERT(_file.isOpen()); Q_ASSERT(0 <= zoom && zoom < _zooms.count()); return _zooms.at(zoom).size; } bool OZF::isOZF(const QString &path) { QFile file(path); quint16 magic; if (!file.open(QIODevice::ReadOnly)) return false; if (file.read((char*)&magic, sizeof(magic)) < (qint64)sizeof(magic)) return false; magic = qFromLittleEndian(magic); if (magic == OZF2_MAGIC || magic == OZF3_MAGIC) return true; return false; }