i1 : R = ZZ/101[a,b,c,d]/ideal{a^4,b^4,c^4,d^4}
o1 = R
o1 : QuotientRing
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i2 : M = coker matrix {{a^3*b^3*c^3*d^3}};
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i3 : S = R/ideal{a^3*b^3*c^3*d^3}
o3 = S
o3 : QuotientRing
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i4 : HB = torAlgebra(R,S,GenDegreeLimit=>4,RelDegreeLimit=>8) Computing generators in degree 1 : -- used 0.00805349 seconds Computing generators in degree 2 : -- used 0.0149932 seconds Computing generators in degree 3 : -- used 0.0488255 seconds Computing generators in degree 4 : -- used 0.0300875 seconds Finding easy relations : -- used 0.581828 seconds Computing relations in degree 1 : -- used 0.0333619 seconds Computing relations in degree 2 : -- used 0.0336419 seconds Computing relations in degree 3 : -- used 0.090239 seconds Computing relations in degree 4 : -- used 0.113071 seconds Computing relations in degree 5 : -- used 0.312471 seconds Computing relations in degree 6 : -- used 0.390466 seconds Computing relations in degree 7 : -- used 0.564359 seconds Computing relations in degree 8 : -- used 0.721618 seconds o4 = HB o4 : QuotientRing |
i5 : numgens HB o5 = 35 |
i6 : apply(5,i -> #(flatten entries getBasis(i,HB)))
o6 = {1, 1, 4, 10, 20}
o6 : List
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i7 : Mres = res(M, LengthLimit=>8)
1 1 4 10 20 35 56 84 120
o7 = R <-- R <-- R <-- R <-- R <-- R <-- R <-- R <-- R
0 1 2 3 4 5 6 7 8
o7 : ChainComplex
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Note that in this example, Tor*R(S,k) has trivial multiplication, since the map from R to S is a Golod homomorphism by a theorem of Levin and Avramov.