/*** * This code is a part of EvoApproxLib library (ehw.fit.vutbr.cz/approxlib) distributed under The MIT License. * When used, please cite the following article(s): V. MRAZEK. Optimization of BDD-based Approximation Error Metrics Calculations. In: IEEE Computer Society Annual Symposium on VLSI (ISVLSI '22). Paphos: Institute of Electrical and Electronics Engineers, 2022, pp. 86-91. ISBN 978-1-6654-6605-9. * This file contains a circuit from a sub-set of pareto optimal circuits with respect to the pwr and ep parameters ***/ // MAE% = 0.048 % // MAE = 3.9 // WCE% = 0.29 % // WCE = 24 // WCRE% = 66.67 % // EP% = 58.98 % // MRE% = 0.13 % // MSE = 48 // PDK45_PWR = 0.038 mW // PDK45_AREA = 96.2 um2 // PDK45_DELAY = 0.63 ns #include #include uint64_t add12u_0ZP(uint64_t a, uint64_t b) { int wa[12]; int wb[12]; uint64_t y = 0; wa[0] = (a >> 0) & 0x01; wb[0] = (b >> 0) & 0x01; wa[1] = (a >> 1) & 0x01; wb[1] = (b >> 1) & 0x01; wa[2] = (a >> 2) & 0x01; wb[2] = (b >> 2) & 0x01; wa[3] = (a >> 3) & 0x01; wb[3] = (b >> 3) & 0x01; wa[4] = (a >> 4) & 0x01; wb[4] = (b >> 4) & 0x01; wa[5] = (a >> 5) & 0x01; wb[5] = (b >> 5) & 0x01; wa[6] = (a >> 6) & 0x01; wb[6] = (b >> 6) & 0x01; wa[7] = (a >> 7) & 0x01; wb[7] = (b >> 7) & 0x01; wa[8] = (a >> 8) & 0x01; wb[8] = (b >> 8) & 0x01; wa[9] = (a >> 9) & 0x01; wb[9] = (b >> 9) & 0x01; wa[10] = (a >> 10) & 0x01; wb[10] = (b >> 10) & 0x01; wa[11] = (a >> 11) & 0x01; wb[11] = (b >> 11) & 0x01; int sig_24 = wa[0] ^ wb[0]; int sig_25 = wa[0] & wb[0]; int sig_26 = wa[1] | wb[1]; int sig_29 = sig_26 | sig_25; int sig_31 = wa[2] | wb[2]; int sig_34 = sig_31; int sig_36 = wa[3] ^ wb[3]; int sig_37 = wa[3] & wb[3]; int sig_39 = sig_36; int sig_40 = sig_37; int sig_41 = wa[4] ^ wb[4]; int sig_42 = wa[4] & wb[4]; int sig_44 = sig_41 | sig_40; int sig_45 = sig_42; int sig_46 = wa[5] ^ wb[5]; int sig_47 = wa[5] & wb[5]; int sig_48 = sig_46 & sig_45; int sig_49 = sig_46 ^ sig_45; int sig_50 = sig_47 | sig_48; int sig_51 = wa[6] ^ wb[6]; int sig_52 = wa[6] & wb[6]; int sig_53 = sig_51 & sig_50; int sig_54 = sig_51 ^ sig_50; int sig_55 = sig_52 | sig_53; int sig_56 = wa[7] ^ wb[7]; int sig_57 = wa[7] & wb[7]; int sig_58 = sig_56 & sig_55; int sig_59 = sig_56 ^ sig_55; int sig_60 = sig_57 | sig_58; int sig_61 = wa[8] ^ wb[8]; int sig_62 = wa[8] & wb[8]; int sig_63 = sig_61 & sig_60; int sig_64 = sig_61 ^ sig_60; int sig_65 = sig_62 | sig_63; int sig_66 = wa[9] ^ wb[9]; int sig_67 = wa[9] & wb[9]; int sig_68 = sig_66 & sig_65; int sig_69 = sig_66 ^ sig_65; int sig_70 = sig_67 | sig_68; int sig_71 = wa[10] ^ wb[10]; int sig_72 = wa[10] & wb[10]; int sig_73 = sig_71 & sig_70; int sig_74 = sig_71 ^ sig_70; int sig_75 = sig_72 | sig_73; int sig_76 = wa[11] ^ wb[11]; int sig_77 = wa[11] & wb[11]; int sig_78 = sig_76 & sig_75; int sig_79 = sig_76 ^ sig_75; int sig_80 = sig_77 | sig_78; y |= (sig_24 & 0x01) << 0; // default output y |= (sig_29 & 0x01) << 1; // default output y |= (sig_34 & 0x01) << 2; // default output y |= (sig_39 & 0x01) << 3; // default output y |= (sig_44 & 0x01) << 4; // default output y |= (sig_49 & 0x01) << 5; // default output y |= (sig_54 & 0x01) << 6; // default output y |= (sig_59 & 0x01) << 7; // default output y |= (sig_64 & 0x01) << 8; // default output y |= (sig_69 & 0x01) << 9; // default output y |= (sig_74 & 0x01) << 10; // default output y |= (sig_79 & 0x01) << 11; // default output y |= (sig_80 & 0x01) << 12; // default output return y; }