Annotation of OpenXM/src/kan96xx/Kan/usage.sm1, Revision 1.8
1.8 ! takayama 1: %% $OpenXM: OpenXM/src/kan96xx/Kan/usage.sm1,v 1.7 2003/06/26 13:00:11 takayama Exp $
1.1 maekawa 2: %% usage.sm1
3: %% [(key word)
4: %% [( )
5: %% ( )
6: %% ]
7: %% ] putUsages
8: [(putUsages)
9: [$[(key word) [(explanation line 1) (explanation line 2) ... ]] putUsages$ ]
10: ] putUsages
11:
12: [(;)
13: [(Output the prompt sm1>)]
14: ] putUsages
15:
16: [(::)
17: [(Pop the top of the stack and print it.)]
18: ] putUsages
19:
20: [(Libraries)
21: [
22: (Doc/appell.sm1 : It generates Appell differential equations.)
23: (Doc/bfunction.sm1: Computing the b-function of a given polynomial)
24: ( by using Groebner basis. Written by T.Oaku.)
25: (Doc/factor-a.sm1: A sample interface to factor polynomials by risa/asir.)
26: (Doc/gkz.sm1 : It generates GKZ systems for given A and b.)
27: (Doc/hol.sm1 : Basic package for holonomic systems. Holonomic rank,)
28: ( characteristic ideal, singular locus.)
29: (Doc/resol0.sm1 : Constructing Schreyer resolutions. tower.sm1, tower-sugar.sm1)
30: (Doc/rest0.sm1 : Computing the restriction (inverse image) as a complex.)
31: ( This package is under developement by T.Oaku.)
32: ( cf. restall_s.sm1, resol0.sm1)
33: ]
34: ] putUsages
35: /Loadall {
36: [(parse) (bfunction.sm1) pushfile] extension
37: [(parse) (hol.sm1) pushfile] extension
38: [(parse) (gkz.sm1) pushfile] extension
39: [(parse) (appell.sm1)pushfile] extension
40: [(parse) (resol0.sm1)pushfile] extension
41: } def
42: [(Loadall)
43: [(Loadall loads the packages bfunction.sm1, hol.sm1, gkz.sm1, appell.sm1,)
44: (resol0.sm1)
45: ]] putUsages
46:
47: [(Version)
48: [(Packages must be loaded in a proper version of kan/sm1.)
49: (It can be checked as follows.)
50: (Example: )
51: ( /factor-a.version (2.981101) def)
52: ( factor-a.version [(Version)] system_variable gt )
53: $ { (This package requires the latest version of kan/sm1) message$
54: $ (Please get it from http://www.math.kobe-u.ac.jp/KAN) message$
55: $ error$
56: $ } { } ifelse$
57: ]]putUsages
58:
59:
60: [(bugs)
61: [(All known bugs are fixed.)
62: ]
63: ] putUsages
64:
65: [(factor)
66: [(Load Doc/factor-a.sm1, then factorization can be computed by invoking )
67: (asir, of which ftp cite is at http://www.math.kobe-u.ac.jp)
68: ]
69: ] putUsages
70:
71:
72: [(message)
73: [ (string message)
74: (Output the string to the screen with the newline.)
75: (cf. messagen.)
76: $Example: (Hello world) message$
77: ]
78: ] putUsages
79:
80: [(messagen)
81: [ (string messagen)
82: (Output the string to the screen without the newline.)
83: (cf. message.)
84: $Example: (Hello world) messagen$
85: ]
86: ] putUsages
87:
88: [(ring_of_polynomials)
89: [ (string ring_of_polynomials)
90: (This command is used to define a ring of polynomials with the macros)
91: (define_ring, weight_vector and elimination_order.)
92: (The user cannot use the variable names h, e, H and E.)
93: (cf. show_ring, system_variable --- CurrentRing)
94: ( print_switch_status, switch_function)
95: (Example: [(x,y,z) ring_of_polynomials (x,y) elimination_order 0] define_ring)
96: ]
97: ] putUsages
98:
99: [(ring_of_differential_operators)
100: [ (string ring_of_differential_operators)
101: (This command is used to define a ring of differential operators )
102: (with the macros define_ring, weight_vector and elimination_order.)
103: (The user cannot use the variable names h, e, H and E.)
104: (cf. show_ring, system_variable --- CurrentRing)
105: ( print_switch_status, switch_function)
1.5 takayama 106: (Example: [(x,y) ring_of_differential_operators [[(Dx) 1 (Dy) 1]])
107: ( weight_vector 0] define_ring)
108: ( Define the ring of differential operators Q<x,y,Dx,Dy> with the order)
109: ( obtained by refining the partial order defined by the weight vector)
110: ( [x,y,Dx,Dy] = [0,0,1,1] )
111: (Example: [(x,y) ring_of_differential_operators 0 [(weightedHomogenization) 1]])
1.6 takayama 112: ( define_ring )
113: (Example: [(x,y) ring_of_differential_operators [[(x) -1 (Dx) 1]] weight_vector)
1.7 takayama 114: ( 0 [(degreeShift) [[1 0 1]]] ])
1.5 takayama 115: ( define_ring )
1.1 maekawa 116: (Example: [(x,y,z) ring_of_differential_operators (Dx,Dy) elimination_order 0] define_ring)
117: ( Dx,Dy, and Dz are corresponding differential operators to the )
118: ( space variables x, y and z.)
119: ]
120: ] putUsages
121:
122: [(ring_of_difference_operators)
123: [ (string ring_of_difference_operators)
1.4 takayama 124: (!!! OBSOLETE !!!)
1.1 maekawa 125: ( )
126: (This command has not been maintained since 1996. So, there may be)
127: (troubles if it is used with new features of kan/sm1.)
128: ( )
129: (This command is used to define a ring of difference operators )
130: (with the macros define_ring, weight_vector and elimination_order.)
131: (The user cannot use the variable names h, e, H and E.)
132: (cf. show_ring, system_variable --- CurrentRing)
133: ( print_switch_status, switch_function)
134: (Example: [(x,y,z) ring_of_difference_operators (Ex,Ey) elimination_order 0] define_ring)
135: ( Ex,Ey, and Ez are corresponding difference operators to the )
136: ( space variables x, y and z ( Ex x = (x+1) Ex).)
137: ]
138: ] putUsages
139:
140:
141: [(ring_of_q_difference_operators)
142: [ (string ring_of_q_difference_operators)
143: ( )
144: (This command has not been maintained since 1996. So, there may be)
145: (troubles if it is used with new features of kan/sm1.)
146: ( )
147: (This command is used to define a ring of q-difference operators )
148: (with the macros define_qring, weight_vector and elimination_order.)
149: (Note that you should use this macro with define_qring instead of)
150: (define_ring.)
151: (The user cannot use the variable names h, e, q and E.)
152: (cf. show_ring, system_variable --- CurrentRing)
153: ( print_switch_status, switch_function)
154: (Example: [(x,y,z) ring_of_q_difference_operators (Qx,Qy) elimination_order 0] define_qring)
155: ( Qx,Qy, and Qz are corresponding q-difference operators to the )
156: ( space variables x, y and z ( Qx x = (q) x Q).)
157: ]
158: ] putUsages
159:
1.4 takayama 160: [(ring_of_differential_difference_operators)
161: [ ([string1 string2] ring_of_differential_difference operators)
162: (This command is used to define a ring of differential-difference operators )
163: (with the macros define_ring, weight_vector and elimination_order.)
164: (string1 is a set of variables for differential operators.)
165: (string2 is a set of variables for difference operators.)
166: (The user cannot use the variable names h, e, H and E.)
167: (cf. show_ring, system_variable --- CurrentRing)
168: ( print_switch_status, switch_function)
169: (Example: [[(x,y) (s)] ring_of_differential_difference_operators )
170: ( [[(Es) 1] [(s) 1]] weight_vector 0] define_ring)
171: ( Dx and Dy are corresponding differential operators to the )
172: ( space variables x and y. Try show_ring to see the commutation)
173: ( relations.)
174: ]
175: ] putUsages
1.1 maekawa 176:
177: [(define_ring)
178: [( [varlist ring_of_??? order characteristic options] define_ring)
179: ( Pointer to the ring.)
180: (Example: [(x,y,z) ring_of_polynomials [[(x) 100 (y) 10 (z) 1]] weight_vector)
181: ( 11] define_qring )
182: (Example: [(x,y) ring_of_polynomials [[(x) 1]] weight_vector 0 ] define_ring)
183: ( /R set)
184: (cf. define_qring, set_up_ring@ <coefficient ring>)
185: ( <<ring_of_???>> ring_of_polynomials, ring_of_differential_operators, )
186: ( ring_of_difference_operators)
187: ( <<order>> elimination_order, weight_vector)
1.8 ! takayama 188: ( ring_def,ring , << __ >>)
1.1 maekawa 189: ]
190: ] putUsages
191:
192:
193: [(.)
194: [(string . polynomial)
195: (Parse the string as a polynomial in the current ring and put it on the stack)
196: (Example ( (x+2)^3 ) .)
197: ]
198: ] putUsages
199:
200: [(evenQ)
201: [ (number evenQ bool)
202: ]
203: ] putUsages
204:
205: [(reverse)
206: [ (array reverse reversed_array)
207: ]
208: ] putUsages
209:
210: [(memberQ)
211: [(element array(list) memberQ bool)
212: ]
213: ] putUsages
214:
215: [(transpose)
216: [( matrix transpose transposed_matrix)
217: ]
218: ] putUsages
219:
220: [(timer)
221: [( { codes } timer )
222: (It outputs the execution time to execute << codes >>.)
223: (If you type in ctrl-C while you are executing this macro,)
224: (you need to type in set_timer after you type in ctrl-C to reset)
225: (the timer.)
226: ]] putUsages
227:
228: [(complement)
229: [( set universal_set complement complement_set)
230: (Example: [1 2] [3 4 1 2 5] complement ::)
231: ]
232: ] putUsages
233:
234: [(pushVariables)
235: [ (varlist pushVariables pushed-variables)
236: (The macro is used to define local variables in a macro.)
237: (Example : /foo { )
238: ( /arg1 set )
239: ( [/abc /cd] pushVariables )
240: ( [ /abc arg1 def )
241: ( /cd abc 1 add def )
242: ( /arg1 cd def )
243: ( ] pop )
244: ( popVariables)
245: ( arg1 )
246: ( } def )
247: ( 10 foo :: returns 11 )
248: ( In the example, abc and cd are local variables.)
249: ]
250: ] putUsages
251:
252:
253:
254: /@@@.global.usage1
255: [(@@@. is the prefix for the global control variables and global functions.)
256: (@@@.quiet : 1 ---> quiet mode, 0 ---> not. cf. sm1 -q)
257: (@@@.esymbol : (e_) is the standard value. It is used to express)
258: ( vectors internally. cf. fromVectors, toVectors)
259: (@@@.Dsymbol : (D) is the standard value for differential operator.)
260: ( cf. ring_of_differential_operators)
261: (@@@.diffEsymbol : (E) is the standard value for difference operator.)
262: ( cf. ring_of_difference_operators)
263: (@@@.Qsymbol : (Q) is the standard value for q-difference operator.)
264: ( cf. ring_of_qdifference_operators)
265: ]
266: def
267: [(@@@.quiet) @@@.global.usage1] putUsages
268: [(@@@.Dsymbol) @@@.global.usage1] putUsages
269: [(@@@.diffEsymbol) @@@.global.usage1] putUsages
270: [(@@@.Qsymbol) @@@.global.usage1] putUsages
271: [(@@@.esymbol) @@@.global.usage1] putUsages
272:
273: [(join)
274: [(list1 list2 join list3)
275: (Ex. [1 2] [3 [4 (ab)]] join [1 2 3 [4 (ab)]])
276: ]
277: ] putUsages
278:
279: [(not)
280: [(int not int)
281: (1 not 0)
282: (0 not 1)
283: ]
284: ] putUsages
285:
286: [(append)
287: [(list1 obj2 append list3)
288: (Ex. [1 2] 3 append [1 2 3])
289: ]
290: ] putUsages
291:
292: [(null)
293: [(<<null>> returns null object)]
294: ] putUsages
295:
296: [(oxasir)
297: [(ox_asir is an asir server which is complient to open xxx protocol.)
298: (This module is necessary for efficient execution factorization )
299: (of b-functions in annfs, deRham. cf. lib/oxasir.sm1)
300: (ox_asir has not yet been put on the ftp cite. 12/17, 1998.)
301: ]
302: ] putUsages
303:
304: [(toVectors)
305: [(obj toVectors vec)
306: (Convert the internal expression of vector into the array <<vec>>.)
307: (obj can be [n [g1 ... gm]] where n is the length of the vector.)
1.3 takayama 308: $cf. [(toe_) array_of_poly] gbext $
1.1 maekawa 309: $Example 1: [(x) ring_of_polynomials 0] define_ring $
310: $ (e_ + 2). toVectors :: $
311: ( ---> [2 , 1] )
312: (Example 2: [3 (e_ +2).] toVectors ::)
313: ( ---> [2 , 1 , 0 ])
314: (Example 3: [(e_+2). (e_^2+1).] toVectors ::)
315: ( ---> [[2 , 1] [1 , 0 , 1]] )
316: (Example 4: [2 [(e x + 1). (x+1).]] toVectors )
317: ( ===> [ [1 , x] [x+1 , 0] ] )
318: ]] putUsages
319: [(toVectors2)
320: [(Remained for the compatibility. cf. toVectors)
321: ]] putUsages
322:
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