## 32 bit multiplier scheme 1 import numpy as np from matplotlib import pyplot as plt import pandas as pd from pandas import Series import random get_bin = lambda x, n: format(x, 'b').zfill(n) x=list(range(100000)) x1=list(range(5)) yans=list(range(100000)) yans1=list(range(100000)) res = [] res1 = [] num1 = [6, 7, 8, 9, 10] mean_error_distance = [0, 0, 0, 0, 0] mean_relative_error_distance = [0., 0., 0., 0., 0.] normalized_error_distance = [0., 0., 0., 0., 0.] normailzed_relative_error_distance = [0., 0., 0., 0., 0.] acceptance_prob = [0., 0., 0., 0., 0.] for c in range(100000): res.append(random.randint(1, 4294967295)) for d in range(100000): res1.append(random.randint(1, 4294967295)) for g in range (5): mean_error_distance_1 = 0 mean_relative_error_distance_1 = 0 normalized_error_distance_1 = 0 normailzed_relative_error_distance_1 = 0 prob = 0 for f in range (100000): a=res[f] b=res1[f] y=a*b abin = get_bin(a,32) bbin = get_bin(b,32) num = num1[g] i=0 while (abin[i]=='0'): i=i+1 j=0 while (bbin[j]=='0'): j=j+1 k=i l=j sum1=32-k-num sum2=32-l-num if (sum1<0): sum1=0 if (sum2<0): sum2=0 sum3=(sum1+sum2)*-1 sum3=(sum1+sum2)*-1 if (k+num>32): k = 32-num if (l+num>32): l = 32-num amul=abin[k:k+num] bmul=bbin[l:l+num] q=int(amul,2) w=int(bmul,2) e=q*w yapp = get_bin(e,64) yapp = [int(x) for x in yapp] yapp = np.roll(yapp,sum3) yapp = ' '.join(str(e) for e in yapp) yapp = str.replace(yapp," ","") w=int(yapp,2) ans=((y-w)/y)*100 yans[f]=ans yans1[f] = (y-w) mean_error_distance[g] = (y-w) + mean_error_distance[g] mean_relative_error_distance[g] = mean_relative_error_distance[g] + ans max1 = max(yans1) max2 = max(yans) if (ans>1): prob = prob + 1 mean_error_distance[g] = mean_error_distance[g]/100000 mean_relative_error_distance[g] = mean_relative_error_distance[g]/100000 normalized_error_distance[g] = mean_error_distance[g]/max1 normailzed_relative_error_distance[g] = mean_relative_error_distance[g]/max2 acceptance_prob[g] = prob/100000 acceptance_prob[g] = 1-acceptance_prob[g] print ("*******************************") print ("latency parameter: ",num1[g]) print ("mean_error_distance : ", mean_error_distance[g]) print ("mean_relative_error_distance : ", mean_relative_error_distance[g]) print ("normalized_error_distance : ", normalized_error_distance[g]) print ("normailzed_relative_error_distance : ", normailzed_relative_error_distance[g]) print ("acceptance_probability at 1% : ", acceptance_prob[g]) plt.plot(x,yans) plt.title ('RELATIVE ERROR(%) 32 BIT MULTIPLIER SCHEME 1') plt.xlabel('Random Numbers Generated') plt.ylabel('Relative Error(%)') plt.show() p = (0,1,2,3,4) l = (6,7,8,9,10) plt.plot (x1,mean_error_distance) plt.title ('32 BIT MULTIPLIER SCHEME 1') plt.xticks(p,l) plt.xlabel('Latency Parameter') plt.ylabel('Mean Error Distance') plt.show() plt.plot (x1,mean_relative_error_distance) plt.title ('32 BIT MULTIPLIER SCHEME 1') plt.xticks(p,l) plt.xlabel('Latency Parameter') plt.ylabel('Mean Relative Error Distance') plt.show() plt.plot (x1,normalized_error_distance) plt.title ('32 BIT MULTIPLIER SCHEME 1') plt.xticks(p,l) plt.xlabel('Latency Parameter') plt.ylabel('Normalized Error Distance ') plt.show() plt.plot (x1,normailzed_relative_error_distance) plt.title ('32 BIT MULTIPLIER SCHEME 1') plt.xticks(p,l) plt.xlabel('Latency Parameter') plt.ylabel('Normailzed Relative Error Distance') plt.show() plt.plot (x1,acceptance_prob) plt.title ('32 BIT MULTIPLIER SCHEME 1') plt.xticks(p,l) plt.xlabel('Latency Parameter') plt.ylabel('Acceptance Probability(1% Relative Error)') plt.show()