OpenXM/src/k097/lib/minimal/cohom.k - diff

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Diff for /OpenXM/src/k097/lib/minimal/cohom.k between version 1.3 and 1.4

version 1.3, 2000/09/10 20:22:45

version 1.4, 2000/11/19 05:50:30

Line 1

/* $OpenXM: OpenXM/src/k097/lib/minimal/cohom.k,v 1.2 2000/06/14 07:44:04 takayama Exp $ */

/* $OpenXM: OpenXM/src/k097/lib/minimal/cohom.k,v 1.3 2000/09/10 20:22:45 takayama Exp $ */

/* k0 interface functions for cohom.sm1 */

def Boundp(a) {

Line 27 def sm1_deRham(a,b) {

}

sm1("[", aa,bb, " ] deRham /FunctionValue set ");

}

HelpAdd(["sm1_deRham",

["sm1_deRham(f,v) computes the dimension of the deRham cohomology groups",

"of C^n - V(f)",

"This function does not use (-w,w)-minimal free resolution.",

"Example: sm1_deRham(\"x^3-y^2\",\"x,y\");"

]]);

def Weyl(v,w,p) {

Line 45 def Weyl(v,w,p) {

Line 51 def Weyl(v,w,p) {

sm1(" define_ring_variables ");

return(a);

}

HelpAdd(["Weyl",

[ "Weyl(v,w) defines the Weyl algebra (the ring of differential operators)",

"with the weight vector w.",

"Example: Weyl(\"x,y\",[[\"x\",-1,\"Dx\",1]]); "

]]);

/* ( and ) must match in HelpAdd. */

def sm1_pmat(a) {

sm1(a," pmat ");

Line 213 def GKZ(A,B) {

Line 225 def GKZ(A,B) {

HelpAdd(["GKZ.GKZ",

["GKZ(a,b) returns the GKZ systems associated to the matrix a and the vector b",

"The answer is given by strings.",

"Example: GKZ([[1,1,1,1],[0,1,3,4]],[0,2])"]]);

"Example: GKZ([[1,1,1,1],[0,1,3,4]],[0,2]);"]]);

def ToricIdeal(A) {

/* we need sm1_rat_to_p in a future. */

Line 229 def ToricIdeal(A) {

Line 241 def ToricIdeal(A) {

HelpAdd(["ToricIdeal",

["ToricIdeal(a) returns the affine toric ideal associated to the matrix a",

"The answer is given by a list of strings.",

"Example: ToricIdeal([[1,1,1,1],[0,1,3,4]]"]]);

"Example: ToricIdeal([[1,1,1,1],[0,1,3,4]]);"]]);

def Rest(a) {

sm1(a," rest /FunctionValue set ");

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