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1 #include <tommath.h> |
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2 #ifdef BN_MP_KARATSUBA_MUL_C |
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3 /* LibTomMath, multiple-precision integer library -- Tom St Denis |
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4 * |
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5 * LibTomMath is a library that provides multiple-precision |
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6 * integer arithmetic as well as number theoretic functionality. |
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7 * |
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8 * The library was designed directly after the MPI library by |
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9 * Michael Fromberger but has been written from scratch with |
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10 * additional optimizations in place. |
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11 * |
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12 * The library is free for all purposes without any express |
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13 * guarantee it works. |
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14 * |
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15 * Tom St Denis, [email protected], http://math.libtomcrypt.org |
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16 */ |
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17 |
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18 /* c = |a| * |b| using Karatsuba Multiplication using |
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19 * three half size multiplications |
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20 * |
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21 * Let B represent the radix [e.g. 2**DIGIT_BIT] and |
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22 * let n represent half of the number of digits in |
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23 * the min(a,b) |
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24 * |
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25 * a = a1 * B**n + a0 |
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26 * b = b1 * B**n + b0 |
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27 * |
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28 * Then, a * b => |
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29 a1b1 * B**2n + ((a1 - a0)(b1 - b0) + a0b0 + a1b1) * B + a0b0 |
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30 * |
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31 * Note that a1b1 and a0b0 are used twice and only need to be |
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32 * computed once. So in total three half size (half # of |
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33 * digit) multiplications are performed, a0b0, a1b1 and |
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34 * (a1-b1)(a0-b0) |
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35 * |
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36 * Note that a multiplication of half the digits requires |
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37 * 1/4th the number of single precision multiplications so in |
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38 * total after one call 25% of the single precision multiplications |
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39 * are saved. Note also that the call to mp_mul can end up back |
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40 * in this function if the a0, a1, b0, or b1 are above the threshold. |
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41 * This is known as divide-and-conquer and leads to the famous |
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42 * O(N**lg(3)) or O(N**1.584) work which is asymptopically lower than |
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43 * the standard O(N**2) that the baseline/comba methods use. |
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44 * Generally though the overhead of this method doesn't pay off |
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45 * until a certain size (N ~ 80) is reached. |
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46 */ |
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47 int mp_karatsuba_mul (mp_int * a, mp_int * b, mp_int * c) |
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48 { |
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49 mp_int x0, x1, y0, y1, t1, x0y0, x1y1; |
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50 int B, err; |
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51 |
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52 /* default the return code to an error */ |
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53 err = MP_MEM; |
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54 |
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55 /* min # of digits */ |
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56 B = MIN (a->used, b->used); |
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57 |
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58 /* now divide in two */ |
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59 B = B >> 1; |
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60 |
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61 /* init copy all the temps */ |
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62 if (mp_init_size (&x0, B) != MP_OKAY) |
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63 goto ERR; |
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64 if (mp_init_size (&x1, a->used - B) != MP_OKAY) |
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65 goto X0; |
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66 if (mp_init_size (&y0, B) != MP_OKAY) |
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67 goto X1; |
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68 if (mp_init_size (&y1, b->used - B) != MP_OKAY) |
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69 goto Y0; |
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70 |
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71 /* init temps */ |
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72 if (mp_init_size (&t1, B * 2) != MP_OKAY) |
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73 goto Y1; |
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74 if (mp_init_size (&x0y0, B * 2) != MP_OKAY) |
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75 goto T1; |
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76 if (mp_init_size (&x1y1, B * 2) != MP_OKAY) |
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77 goto X0Y0; |
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78 |
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79 /* now shift the digits */ |
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80 x0.used = y0.used = B; |
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81 x1.used = a->used - B; |
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82 y1.used = b->used - B; |
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83 |
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84 { |
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85 register int x; |
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86 register mp_digit *tmpa, *tmpb, *tmpx, *tmpy; |
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87 |
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88 /* we copy the digits directly instead of using higher level functions |
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89 * since we also need to shift the digits |
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90 */ |
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91 tmpa = a->dp; |
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92 tmpb = b->dp; |
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93 |
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94 tmpx = x0.dp; |
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95 tmpy = y0.dp; |
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96 for (x = 0; x < B; x++) { |
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97 *tmpx++ = *tmpa++; |
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98 *tmpy++ = *tmpb++; |
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99 } |
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100 |
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101 tmpx = x1.dp; |
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102 for (x = B; x < a->used; x++) { |
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103 *tmpx++ = *tmpa++; |
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104 } |
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105 |
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106 tmpy = y1.dp; |
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107 for (x = B; x < b->used; x++) { |
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108 *tmpy++ = *tmpb++; |
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109 } |
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110 } |
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111 |
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112 /* only need to clamp the lower words since by definition the |
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113 * upper words x1/y1 must have a known number of digits |
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114 */ |
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115 mp_clamp (&x0); |
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116 mp_clamp (&y0); |
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117 |
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118 /* now calc the products x0y0 and x1y1 */ |
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119 /* after this x0 is no longer required, free temp [x0==t2]! */ |
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120 if (mp_mul (&x0, &y0, &x0y0) != MP_OKAY) |
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121 goto X1Y1; /* x0y0 = x0*y0 */ |
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122 if (mp_mul (&x1, &y1, &x1y1) != MP_OKAY) |
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123 goto X1Y1; /* x1y1 = x1*y1 */ |
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124 |
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125 /* now calc x1-x0 and y1-y0 */ |
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126 if (mp_sub (&x1, &x0, &t1) != MP_OKAY) |
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127 goto X1Y1; /* t1 = x1 - x0 */ |
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128 if (mp_sub (&y1, &y0, &x0) != MP_OKAY) |
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129 goto X1Y1; /* t2 = y1 - y0 */ |
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130 if (mp_mul (&t1, &x0, &t1) != MP_OKAY) |
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131 goto X1Y1; /* t1 = (x1 - x0) * (y1 - y0) */ |
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132 |
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133 /* add x0y0 */ |
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134 if (mp_add (&x0y0, &x1y1, &x0) != MP_OKAY) |
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135 goto X1Y1; /* t2 = x0y0 + x1y1 */ |
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136 if (mp_sub (&x0, &t1, &t1) != MP_OKAY) |
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137 goto X1Y1; /* t1 = x0y0 + x1y1 - (x1-x0)*(y1-y0) */ |
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138 |
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139 /* shift by B */ |
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140 if (mp_lshd (&t1, B) != MP_OKAY) |
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141 goto X1Y1; /* t1 = (x0y0 + x1y1 - (x1-x0)*(y1-y0))<<B */ |
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142 if (mp_lshd (&x1y1, B * 2) != MP_OKAY) |
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143 goto X1Y1; /* x1y1 = x1y1 << 2*B */ |
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144 |
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145 if (mp_add (&x0y0, &t1, &t1) != MP_OKAY) |
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146 goto X1Y1; /* t1 = x0y0 + t1 */ |
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147 if (mp_add (&t1, &x1y1, c) != MP_OKAY) |
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148 goto X1Y1; /* t1 = x0y0 + t1 + x1y1 */ |
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149 |
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150 /* Algorithm succeeded set the return code to MP_OKAY */ |
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151 err = MP_OKAY; |
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152 |
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153 X1Y1:mp_clear (&x1y1); |
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154 X0Y0:mp_clear (&x0y0); |
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155 T1:mp_clear (&t1); |
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156 Y1:mp_clear (&y1); |
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157 Y0:mp_clear (&y0); |
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158 X1:mp_clear (&x1); |
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159 X0:mp_clear (&x0); |
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160 ERR: |
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161 return err; |
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162 } |
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163 #endif |