xref: /freebsd/contrib/bc/manuals/algorithms.md (revision e32fecd0c2c3ee37c47ee100f169e7eb0282a873)
1# Algorithms
2
3This `bc` uses the math algorithms below:
4
5### Addition
6
7This `bc` uses brute force addition, which is linear (`O(n)`) in the number of
8digits.
9
10### Subtraction
11
12This `bc` uses brute force subtraction, which is linear (`O(n)`) in the number
13of digits.
14
15### Multiplication
16
17This `bc` uses two algorithms: [Karatsuba][1] and brute force.
18
19Karatsuba is used for "large" numbers. ("Large" numbers are defined as any
20number with `BC_NUM_KARATSUBA_LEN` digits or larger. `BC_NUM_KARATSUBA_LEN` has
21a sane default, but may be configured by the user.) Karatsuba, as implemented in
22this `bc`, is superlinear but subpolynomial (bounded by `O(n^log_2(3))`).
23
24Brute force multiplication is used below `BC_NUM_KARATSUBA_LEN` digits. It is
25polynomial (`O(n^2)`), but since Karatsuba requires both more intermediate
26values (which translate to memory allocations) and a few more additions, there
27is a "break even" point in the number of digits where brute force multiplication
28is faster than Karatsuba. There is a script (`$ROOT/scripts/karatsuba.py`) that
29will find the break even point on a particular machine.
30
31***WARNING: The Karatsuba script requires Python 3.***
32
33### Division
34
35This `bc` uses Algorithm D ([long division][2]). Long division is polynomial
36(`O(n^2)`), but unlike Karatsuba, any division "divide and conquer" algorithm
37reaches its "break even" point with significantly larger numbers. "Fast"
38algorithms become less attractive with division as this operation typically
39reduces the problem size.
40
41While the implementation of long division may appear to use the subtractive
42chunking method, it only uses subtraction to find a quotient digit. It avoids
43unnecessary work by aligning digits prior to performing subtraction and finding
44a starting guess for the quotient.
45
46Subtraction was used instead of multiplication for two reasons:
47
481.	Division and subtraction can share code (one of the less important goals of
49	this `bc` is small code).
502.	It minimizes algorithmic complexity.
51
52Using multiplication would make division have the even worse algorithmic
53complexity of `O(n^(2*log_2(3)))` (best case) and `O(n^3)` (worst case).
54
55### Power
56
57This `bc` implements [Exponentiation by Squaring][3], which (via Karatsuba) has
58a complexity of `O((n*log(n))^log_2(3))` which is favorable to the
59`O((n*log(n))^2)` without Karatsuba.
60
61### Square Root
62
63This `bc` implements the fast algorithm [Newton's Method][4] (also known as the
64Newton-Raphson Method, or the [Babylonian Method][5]) to perform the square root
65operation.
66
67Its complexity is `O(log(n)*n^2)` as it requires one division per iteration, and
68it doubles the amount of correct digits per iteration.
69
70### Sine and Cosine (`bc` Math Library Only)
71
72This `bc` uses the series
73
74```
75x - x^3/3! + x^5/5! - x^7/7! + ...
76```
77
78to calculate `sin(x)` and `cos(x)`. It also uses the relation
79
80```
81cos(x) = sin(x + pi/2)
82```
83
84to calculate `cos(x)`. It has a complexity of `O(n^3)`.
85
86**Note**: this series has a tendency to *occasionally* produce an error of 1
87[ULP][6]. (It is an unfortunate side effect of the algorithm, and there isn't
88any way around it; [this article][7] explains why calculating sine and cosine,
89and the other transcendental functions below, within less than 1 ULP is nearly
90impossible and unnecessary.) Therefore, I recommend that users do their
91calculations with the precision (`scale`) set to at least 1 greater than is
92needed.
93
94### Exponentiation (`bc` Math Library Only)
95
96This `bc` uses the series
97
98```
991 + x + x^2/2! + x^3/3! + ...
100```
101
102to calculate `e^x`. Since this only works when `x` is small, it uses
103
104```
105e^x = (e^(x/2))^2
106```
107
108to reduce `x`.
109
110It has a complexity of `O(n^3)`.
111
112**Note**: this series can also produce errors of 1 ULP, so I recommend users do
113their calculations with the precision (`scale`) set to at least 1 greater than
114is needed.
115
116### Natural Logarithm (`bc` Math Library Only)
117
118This `bc` uses the series
119
120```
121a + a^3/3 + a^5/5 + ...
122```
123
124(where `a` is equal to `(x - 1)/(x + 1)`) to calculate `ln(x)` when `x` is small
125and uses the relation
126
127```
128ln(x^2) = 2 * ln(x)
129```
130
131to sufficiently reduce `x`.
132
133It has a complexity of `O(n^3)`.
134
135**Note**: this series can also produce errors of 1 ULP, so I recommend users do
136their calculations with the precision (`scale`) set to at least 1 greater than
137is needed.
138
139### Arctangent (`bc` Math Library Only)
140
141This `bc` uses the series
142
143```
144x - x^3/3 + x^5/5 - x^7/7 + ...
145```
146
147to calculate `atan(x)` for small `x` and the relation
148
149```
150atan(x) = atan(c) + atan((x - c)/(1 + x * c))
151```
152
153to reduce `x` to small enough. It has a complexity of `O(n^3)`.
154
155**Note**: this series can also produce errors of 1 ULP, so I recommend users do
156their calculations with the precision (`scale`) set to at least 1 greater than
157is needed.
158
159### Bessel (`bc` Math Library Only)
160
161This `bc` uses the series
162
163```
164x^n/(2^n * n!) * (1 - x^2 * 2 * 1! * (n + 1)) + x^4/(2^4 * 2! * (n + 1) * (n + 2)) - ...
165```
166
167to calculate the bessel function (integer order only).
168
169It also uses the relation
170
171```
172j(-n,x) = (-1)^n * j(n,x)
173```
174
175to calculate the bessel when `x < 0`, It has a complexity of `O(n^3)`.
176
177**Note**: this series can also produce errors of 1 ULP, so I recommend users do
178their calculations with the precision (`scale`) set to at least 1 greater than
179is needed.
180
181### Modular Exponentiation
182
183This `dc` uses the [Memory-efficient method][8] to compute modular
184exponentiation. The complexity is `O(e*n^2)`, which may initially seem
185inefficient, but `n` is kept small by maintaining small numbers. In practice, it
186is extremely fast.
187
188### Non-Integer Exponentiation (`bc` Math Library 2 Only)
189
190This is implemented in the function `p(x,y)`.
191
192The algorithm used is to use the formula `e(y*l(x))`.
193
194It has a complexity of `O(n^3)` because both `e()` and `l()` do.
195
196### Rounding (`bc` Math Library 2 Only)
197
198This is implemented in the function `r(x,p)`.
199
200The algorithm is a simple method to check if rounding away from zero is
201necessary, and if so, adds `1e10^p`.
202
203It has a complexity of `O(n)` because of add.
204
205### Ceiling (`bc` Math Library 2 Only)
206
207This is implemented in the function `ceil(x,p)`.
208
209The algorithm is a simple add of one less decimal place than `p`.
210
211It has a complexity of `O(n)` because of add.
212
213### Factorial (`bc` Math Library 2 Only)
214
215This is implemented in the function `f(n)`.
216
217The algorithm is a simple multiplication loop.
218
219It has a complexity of `O(n^3)` because of linear amount of `O(n^2)`
220multiplications.
221
222### Permutations (`bc` Math Library 2 Only)
223
224This is implemented in the function `perm(n,k)`.
225
226The algorithm is to use the formula `n!/(n-k)!`.
227
228It has a complexity of `O(n^3)` because of the division and factorials.
229
230### Combinations (`bc` Math Library 2 Only)
231
232This is implemented in the function `comb(n,r)`.
233
234The algorithm is to use the formula `n!/r!*(n-r)!`.
235
236It has a complexity of `O(n^3)` because of the division and factorials.
237
238### Logarithm of Any Base (`bc` Math Library 2 Only)
239
240This is implemented in the function `log(x,b)`.
241
242The algorithm is to use the formula `l(x)/l(b)` with double the `scale` because
243there is no good way of knowing how many digits of precision are needed when
244switching bases.
245
246It has a complexity of `O(n^3)` because of the division and `l()`.
247
248### Logarithm of Base 2 (`bc` Math Library 2 Only)
249
250This is implemented in the function `l2(x)`.
251
252This is a convenience wrapper around `log(x,2)`.
253
254### Logarithm of Base 10 (`bc` Math Library 2 Only)
255
256This is implemented in the function `l10(x)`.
257
258This is a convenience wrapper around `log(x,10)`.
259
260### Root (`bc` Math Library 2 Only)
261
262This is implemented in the function `root(x,n)`.
263
264The algorithm is [Newton's method][9]. The initial guess is calculated as
265`10^ceil(length(x)/n)`.
266
267Like square root, its complexity is `O(log(n)*n^2)` as it requires one division
268per iteration, and it doubles the amount of correct digits per iteration.
269
270### Cube Root (`bc` Math Library 2 Only)
271
272This is implemented in the function `cbrt(x)`.
273
274This is a convenience wrapper around `root(x,3)`.
275
276### Greatest Common Divisor (`bc` Math Library 2 Only)
277
278This is implemented in the function `gcd(a,b)`.
279
280The algorithm is an iterative version of the [Euclidean Algorithm][10].
281
282It has a complexity of `O(n^4)` because it has a linear number of divisions.
283
284This function ensures that `a` is always bigger than `b` before starting the
285algorithm.
286
287### Least Common Multiple (`bc` Math Library 2 Only)
288
289This is implemented in the function `lcm(a,b)`.
290
291The algorithm uses the formula `a*b/gcd(a,b)`.
292
293It has a complexity of `O(n^4)` because of `gcd()`.
294
295### Pi (`bc` Math Library 2 Only)
296
297This is implemented in the function `pi(s)`.
298
299The algorithm uses the formula `4*a(1)`.
300
301It has a complexity of `O(n^3)` because of arctangent.
302
303### Tangent (`bc` Math Library 2 Only)
304
305This is implemented in the function `t(x)`.
306
307The algorithm uses the formula `s(x)/c(x)`.
308
309It has a complexity of `O(n^3)` because of sine, cosine, and division.
310
311### Atan2 (`bc` Math Library 2 Only)
312
313This is implemented in the function `a2(y,x)`.
314
315The algorithm uses the [standard formulas][11].
316
317It has a complexity of `O(n^3)` because of arctangent.
318
319[1]: https://en.wikipedia.org/wiki/Karatsuba_algorithm
320[2]: https://en.wikipedia.org/wiki/Long_division
321[3]: https://en.wikipedia.org/wiki/Exponentiation_by_squaring
322[4]: https://en.wikipedia.org/wiki/Newton%27s_method#Square_root_of_a_number
323[5]: https://en.wikipedia.org/wiki/Methods_of_computing_square_roots#Babylonian_method
324[6]: https://en.wikipedia.org/wiki/Unit_in_the_last_place
325[7]: https://people.eecs.berkeley.edu/~wkahan/LOG10HAF.TXT
326[8]: https://en.wikipedia.org/wiki/Modular_exponentiation#Memory-efficient_method
327[9]: https://en.wikipedia.org/wiki/Root-finding_algorithms#Newton's_method_(and_similar_derivative-based_methods)
328[10]: https://en.wikipedia.org/wiki/Euclidean_algorithm
329[11]: https://en.wikipedia.org/wiki/Atan2#Definition_and_computation
330