#ifndef MARS_checksum #define MARS_checksum #ifndef __CINT__ #include #endif #include class Checksum { public: uint64_t buffer; void reset() { buffer = 0; } Checksum() : buffer(0) { } Checksum(const Checksum &sum) : buffer(sum.buffer) { } Checksum(uint64_t v) : buffer(((v>>16)&0xffff) | ((v&0xffff)<<32)) { } uint32_t val() const { return (((buffer&0xffff)<<16) | ((buffer>>32)&0xffff)); } bool valid() const { return buffer==0xffff0000ffff; } void HandleCarryBits() { while (1) { const uint64_t carry = ((buffer>>48)&0xffff) | ((buffer&0xffff0000)<<16); if (!carry) break; buffer = (buffer&0xffff0000ffff) + carry; } } Checksum &operator+=(const Checksum &sum) { buffer += sum.buffer; HandleCarryBits(); return *this; } Checksum operator+(Checksum sum) const { return (sum += *this); } bool add(const char *buf, size_t len, bool big_endian = true) { // Avoid overflows in carry bits if (len>262140) // 2^18-4 { add(buf, 262140); return add(buf+262140, len-262140); } if (len%4>0) { std::ostringstream sout; sout << "Length " << len << " not dividable by 4"; #ifdef __EXCEPTIONS throw std::runtime_error(sout.str()); #else gLog << ___err___ << "ERROR - " << sout.str() << std::endl; return false; #endif } const uint16_t *sbuf = reinterpret_cast(buf); uint32_t *hilo = reinterpret_cast(&buffer); const uint16_t *end = sbuf + len/2; if (big_endian) addLoopSwapping(sbuf, end, hilo); else addLoop(sbuf, end, hilo); /*const uint16_t *end = sbuf + len/2; while (1) { if (sbuf==end) break; hilo[0] += ntohs(*sbuf++); if (sbuf==end) break; hilo[1] += ntohs(*sbuf++); }*/ HandleCarryBits(); return true; } void addLoopSwapping(const uint16_t *sbuf, const uint16_t *end, uint32_t* hilo) { /* for (size_t i = 0; i < len/2; i++) { //swap the bytes of the 32 bits value. but... //the hi and lo values are stored in fits-like order. do not swap them hilo[i%2] += ntohs(sbuf[i]); //(sbuf[i]&0xff00)>>8 | (sbuf[i]&0x00ff)<<8; }*/ // This is about as twice as fast as the loop above // ntohs is CPU optimized, i%2 doesn't need to be computed while (1) { if (sbuf==end) break; hilo[0] += ntohs(*sbuf++); if (sbuf==end) break; hilo[1] += ntohs(*sbuf++); } } void addLoop(const uint16_t *sbuf, const uint16_t *end, uint32_t* hilo) { while (1) { if (sbuf==end) break; hilo[0] += ntohs(*sbuf++); if (sbuf==end) break; hilo[1] += ntohs(*sbuf++); } } bool add(const std::vector &v, bool big_endian = true) { return add(v.data(), v.size(), big_endian); } std::string str(bool complm=true) const { std::string rc(16,0); const uint8_t exclude[13] = { 0x3a, 0x3b, 0x3c, 0x3d, 0x3e, 0x3f, 0x40, 0x5b, 0x5c, 0x5d, 0x5e, 0x5f, 0x60 }; const uint32_t value = complm ? ~val() : val(); // complement each bit of the value for (int ii = 0; ii < 4; ii++) { uint8_t byte = (value >> (24 - (8 * ii))); const uint8_t quotient = byte / 4 + '0'; const uint8_t remainder = byte % 4; uint32_t ch[4] = { uint32_t(quotient+remainder), quotient, quotient, quotient }; // avoid ASCII punctuation while (1) { bool check = false; for (int kk = 0; kk < 13; kk++) { for (int jj = 0; jj < 4; jj += 2) { if (ch[jj] != exclude[kk] && ch[jj+1] != exclude[kk]) continue; ch[jj]++; ch[jj+1]--; check=true; } } if (!check) break; } for (int jj = 0; jj < 4; jj++) // assign the bytes rc[4*jj+ii] = ch[jj]; } const char lastChar = rc[15]; for (int i=15;i>0;i--) rc[i] = rc[i-1]; rc[0] = lastChar; return rc; /* uint8_t *p = reinterpret_cast(&value); //swap the bytes of the value uint8_t temp; temp = p[0]; p[0] = p[3]; p[3] = temp; temp = p[1]; p[1] = p[2]; p[2] = temp; for (int i=0; i<4; i++) { rc[i+ 0] = '0' + p[i]/4 + p[i]%4; rc[i+ 4] = '0' + p[i]/4; rc[i+ 8] = '0' + p[i]/4; rc[i+12] = '0' + p[i]/4; } while(1) { bool ok = true; for (int i=0; i<16-4; i++) { for (int j=0; j<13; j++) if (rc[i]==exclude[j] || rc[(i+4)%16]==exclude[j]) { rc[i]++; rc[(i+4)%16]--; ok = false; } } if (ok) break; } return rc; */ } }; #endif