/*
  This code can be loaded, or copied and paste using cpaste, into Sage.
  It will load the data associated to the HMF, including
  the field, level, and Hecke and Atkin-Lehner eigenvalue data.
*/

P.<x> = PolynomialRing(QQ)
g = P([9, 6, -7, -2, 1])
F.<w> = NumberField(g)
ZF = F.ring_of_integers()

NN = ZF.ideal([4, 2, -1/3*w^3 + 2/3*w^2 + 4/3*w - 1])

primes_array = [
[4, 2, -1/3*w^3 + 2/3*w^2 + 4/3*w - 1],\
[7, 7, 1/3*w^3 - 2/3*w^2 - 7/3*w + 1],\
[7, 7, w - 2],\
[7, 7, w - 1],\
[9, 3, w],\
[9, 3, -1/3*w^3 + 2/3*w^2 + 7/3*w - 2],\
[23, 23, -1/3*w^3 + 2/3*w^2 + 1/3*w - 2],\
[23, 23, -2/3*w^3 + 4/3*w^2 + 11/3*w - 4],\
[31, 31, -2/3*w^3 + 1/3*w^2 + 14/3*w + 2],\
[41, 41, -1/3*w^3 + 5/3*w^2 + 4/3*w - 7],\
[41, 41, -1/3*w^3 + 5/3*w^2 + 4/3*w - 4],\
[47, 47, 1/3*w^3 - 5/3*w^2 - 1/3*w + 5],\
[47, 47, w^2 - w - 4],\
[73, 73, -w^3 + 3*w^2 + 4*w - 8],\
[73, 73, -2/3*w^3 + 7/3*w^2 - 1/3*w - 4],\
[73, 73, -w^3 + w^2 + 7*w + 1],\
[73, 73, 2/3*w^3 - 4/3*w^2 - 14/3*w + 5],\
[79, 79, w^2 - 5],\
[79, 79, -2/3*w^3 + 7/3*w^2 + 8/3*w - 6],\
[97, 97, -2/3*w^3 + 7/3*w^2 + 5/3*w - 4],\
[97, 97, 1/3*w^3 + 1/3*w^2 - 7/3*w - 5],\
[103, 103, w^3 - 3*w^2 - 2*w + 5],\
[103, 103, -4/3*w^3 + 11/3*w^2 + 13/3*w - 10],\
[113, 113, -1/3*w^3 + 5/3*w^2 + 4/3*w - 3],\
[113, 113, w^3 - 2*w^2 - 5*w + 1],\
[113, 113, -1/3*w^3 + 5/3*w^2 + 4/3*w - 1],\
[113, 113, -1/3*w^3 + 5/3*w^2 + 4/3*w - 10],\
[127, 127, -2/3*w^3 + 1/3*w^2 + 14/3*w + 1],\
[127, 127, -2/3*w^3 + 7/3*w^2 + 2/3*w - 6],\
[137, 137, -1/3*w^3 + 5/3*w^2 - 2/3*w - 6],\
[137, 137, 1/3*w^3 + 1/3*w^2 - 10/3*w - 1],\
[151, 151, -w^3 + 2*w^2 + 3*w - 5],\
[151, 151, 1/3*w^3 + 1/3*w^2 - 10/3*w - 7],\
[169, 13, -2/3*w^3 + 7/3*w^2 + 5/3*w - 2],\
[169, 13, 1/3*w^3 + 1/3*w^2 - 7/3*w - 7],\
[191, 191, 1/3*w^3 - 2/3*w^2 + 2/3*w - 2],\
[191, 191, 2*w - 5],\
[191, 191, -w^3 + 2*w^2 + 6*w - 2],\
[191, 191, 2/3*w^3 - 4/3*w^2 - 14/3*w - 1],\
[239, 239, 1/3*w^3 - 2/3*w^2 - 7/3*w - 3],\
[239, 239, w - 5],\
[241, 241, 1/3*w^3 + 1/3*w^2 - 10/3*w],\
[241, 241, 4/3*w^3 - 17/3*w^2 + 2/3*w + 9],\
[241, 241, -1/3*w^3 + 5/3*w^2 - 2/3*w - 7],\
[241, 241, -4/3*w^3 + 14/3*w^2 + 13/3*w - 14],\
[257, 257, -w - 4],\
[257, 257, -1/3*w^3 + 2/3*w^2 + 7/3*w - 6],\
[263, 263, -4/3*w^3 + 11/3*w^2 + 16/3*w - 8],\
[263, 263, 2/3*w^3 - 1/3*w^2 - 8/3*w - 3],\
[281, 281, -1/3*w^3 - 1/3*w^2 + 10/3*w - 2],\
[281, 281, -1/3*w^3 + 5/3*w^2 - 5/3*w - 5],\
[281, 281, -1/3*w^3 + 5/3*w^2 - 2/3*w - 9],\
[281, 281, -2/3*w^3 + 1/3*w^2 + 17/3*w],\
[289, 17, -w^3 + 2*w^2 + 4*w - 4],\
[289, 17, w^3 - 2*w^2 - 4*w + 2],\
[311, 311, -2/3*w^3 + 10/3*w^2 - 4/3*w - 9],\
[311, 311, -2/3*w^3 - 2/3*w^2 + 20/3*w + 5],\
[313, 313, -1/3*w^3 + 5/3*w^2 - 2/3*w - 8],\
[313, 313, -1/3*w^3 - 1/3*w^2 + 10/3*w - 1],\
[313, 313, w^3 - 4*w^2 - 2*w + 10],\
[313, 313, 1/3*w^3 + 4/3*w^2 - 10/3*w - 8],\
[337, 337, -4/3*w^3 + 5/3*w^2 + 19/3*w + 4],\
[337, 337, 5/3*w^3 - 13/3*w^2 - 17/3*w + 5],\
[353, 353, -4/3*w^3 + 8/3*w^2 + 25/3*w - 3],\
[353, 353, -1/3*w^3 - 1/3*w^2 + 16/3*w + 6],\
[353, 353, -2/3*w^3 + 10/3*w^2 + 2/3*w - 13],\
[353, 353, -5/3*w^3 + 7/3*w^2 + 29/3*w - 3],\
[367, 367, -5/3*w^3 + 4/3*w^2 + 35/3*w + 4],\
[367, 367, 2/3*w^3 - 7/3*w^2 - 8/3*w + 4],\
[367, 367, -4/3*w^3 + 14/3*w^2 + 1/3*w - 8],\
[367, 367, w^2 - 7],\
[383, 383, 4/3*w^3 - 14/3*w^2 - 10/3*w + 15],\
[383, 383, -5/3*w^3 + 13/3*w^2 + 20/3*w - 12],\
[383, 383, 2*w^2 - 2*w - 13],\
[383, 383, w^3 - w^2 - 8*w - 1],\
[401, 401, -4/3*w^3 + 11/3*w^2 + 22/3*w - 11],\
[401, 401, 5/3*w^3 - 10/3*w^2 - 29/3*w + 5],\
[409, 409, -w^3 + 2*w^2 + 3*w - 2],\
[409, 409, -1/3*w^3 + 8/3*w^2 - 2/3*w - 6],\
[409, 409, 1/3*w^3 - 8/3*w^2 + 2/3*w + 12],\
[409, 409, 4/3*w^3 - 8/3*w^2 - 19/3*w + 4],\
[433, 433, -w^3 + 3*w^2 - 1],\
[433, 433, -1/3*w^3 + 5/3*w^2 - 8/3*w - 5],\
[433, 433, -w^3 + w^2 + 8*w - 2],\
[433, 433, 5/3*w^3 - 7/3*w^2 - 32/3*w - 2],\
[439, 439, w^2 - 10],\
[439, 439, -2/3*w^3 + 4/3*w^2 + 17/3*w - 7],\
[449, 449, -2/3*w^3 + 4/3*w^2 + 11/3*w - 8],\
[449, 449, -4/3*w^3 + 5/3*w^2 + 22/3*w + 2],\
[457, 457, 2/3*w^3 - 7/3*w^2 - 14/3*w + 6],\
[457, 457, 2/3*w^3 - 7/3*w^2 - 14/3*w + 9],\
[463, 463, w^3 - 3*w^2 - 6*w + 11],\
[463, 463, -1/3*w^3 + 5/3*w^2 + 10/3*w - 4],\
[479, 479, -1/3*w^3 + 5/3*w^2 - 2/3*w + 1],\
[479, 479, 5/3*w^3 - 10/3*w^2 - 23/3*w + 9],\
[487, 487, -2/3*w^3 + 7/3*w^2 + 2/3*w - 8],\
[487, 487, -2/3*w^3 + 1/3*w^2 + 14/3*w - 1],\
[503, 503, w^3 - 4*w^2 - 2*w + 16],\
[503, 503, -1/3*w^3 + 5/3*w^2 - 2/3*w - 11],\
[521, 521, -4/3*w^3 + 11/3*w^2 + 10/3*w - 7],\
[521, 521, 4/3*w^3 - 5/3*w^2 - 22/3*w],\
[529, 23, -1/3*w^3 + 2/3*w^2 + 4/3*w - 6],\
[569, 569, -1/3*w^3 + 8/3*w^2 + 1/3*w - 10],\
[569, 569, -2/3*w^3 + 10/3*w^2 + 5/3*w - 10],\
[577, 577, -2/3*w^3 + 10/3*w^2 + 5/3*w - 12],\
[577, 577, -1/3*w^3 + 8/3*w^2 + 1/3*w - 8],\
[593, 593, w^3 - w^2 - 5*w - 5],\
[593, 593, 4/3*w^3 - 11/3*w^2 - 13/3*w + 4],\
[599, 599, 2*w^2 - 3*w - 7],\
[599, 599, 2/3*w^3 - 1/3*w^2 - 8/3*w - 4],\
[599, 599, -1/3*w^3 + 8/3*w^2 - 5/3*w - 9],\
[599, 599, -4/3*w^3 + 11/3*w^2 + 16/3*w - 7],\
[607, 607, 4/3*w^3 - 8/3*w^2 - 22/3*w + 9],\
[607, 607, -2/3*w^3 + 4/3*w^2 + 2/3*w - 5],\
[625, 5, -5],\
[631, 631, -1/3*w^3 + 2/3*w^2 + 13/3*w - 5],\
[631, 631, -2/3*w^3 + 4/3*w^2 + 17/3*w - 1],\
[641, 641, -2/3*w^3 + 7/3*w^2 + 14/3*w - 7],\
[641, 641, 2/3*w^3 - 7/3*w^2 - 14/3*w + 8],\
[647, 647, -2/3*w^3 - 5/3*w^2 + 26/3*w + 8],\
[647, 647, -1/3*w^3 + 8/3*w^2 + 1/3*w - 9],\
[647, 647, -2/3*w^3 + 10/3*w^2 + 5/3*w - 11],\
[647, 647, -2/3*w^3 + 13/3*w^2 - 10/3*w - 13],\
[673, 673, -4/3*w^3 + 5/3*w^2 + 25/3*w - 2],\
[673, 673, -w^3 + 3*w^2 + w - 7],\
[727, 727, -2/3*w^3 + 7/3*w^2 + 2/3*w - 11],\
[727, 727, -2/3*w^3 + 1/3*w^2 + 14/3*w - 4],\
[743, 743, w^2 - w - 10],\
[743, 743, 1/3*w^3 - 5/3*w^2 - 1/3*w - 1],\
[769, 769, -w^3 + 2*w^2 + 7*w - 4],\
[769, 769, 3*w - 2],\
[809, 809, -1/3*w^3 + 8/3*w^2 - 2/3*w - 8],\
[809, 809, -1/3*w^3 + 8/3*w^2 - 2/3*w - 10],\
[823, 823, -w^3 + 2*w^2 + 7*w - 5],\
[823, 823, 3*w - 1],\
[839, 839, 4/3*w^3 - 2/3*w^2 - 25/3*w - 8],\
[839, 839, 2/3*w^3 - 7/3*w^2 - 14/3*w + 12],\
[857, 857, -1/3*w^3 + 5/3*w^2 - 5/3*w - 7],\
[857, 857, -2/3*w^3 + 1/3*w^2 + 17/3*w - 2],\
[863, 863, -2/3*w^3 + 7/3*w^2 - 7/3*w - 2],\
[863, 863, 5/3*w^3 - 7/3*w^2 - 35/3*w + 1],\
[881, 881, -2/3*w^3 + 1/3*w^2 + 14/3*w + 8],\
[881, 881, -2/3*w^3 + 13/3*w^2 - 4/3*w - 18],\
[881, 881, -5/3*w^3 + 7/3*w^2 + 35/3*w + 3],\
[881, 881, -2/3*w^3 + 7/3*w^2 + 2/3*w + 1],\
[887, 887, -1/3*w^3 + 11/3*w^2 - 8/3*w - 7],\
[887, 887, -1/3*w^3 + 11/3*w^2 - 8/3*w - 18],\
[911, 911, 5/3*w^3 - 4/3*w^2 - 29/3*w - 3],\
[911, 911, 2*w^3 - 6*w^2 - 5*w + 13],\
[929, 929, 2*w^3 - 4*w^2 - 9*w + 2],\
[929, 929, 5/3*w^3 - 10/3*w^2 - 17/3*w],\
[929, 929, -4/3*w^3 + 14/3*w^2 + 13/3*w - 11],\
[929, 929, 1/3*w^3 + 4/3*w^2 - 7/3*w - 9],\
[937, 937, -w^3 + 4*w^2 + w - 13],\
[937, 937, 2/3*w^3 + 2/3*w^2 - 17/3*w - 3],\
[953, 953, -2*w^3 + w^2 + 15*w + 8],\
[953, 953, -5/3*w^3 + 19/3*w^2 - 1/3*w - 11],\
[961, 31, 4/3*w^3 - 8/3*w^2 - 16/3*w + 5],\
[967, 967, -4/3*w^3 + 2/3*w^2 + 31/3*w + 11],\
[967, 967, 7/3*w^3 - 5/3*w^2 - 46/3*w - 9],\
[977, 977, 2*w^3 - 5*w^2 - 8*w + 10],\
[977, 977, -w^3 + 3*w^2 + 2*w - 14],\
[977, 977, -4/3*w^3 + 8/3*w^2 + 25/3*w - 11],\
[977, 977, -w^3 + w^2 + 6*w - 7],\
[983, 983, -5/3*w^3 + 16/3*w^2 + 8/3*w - 12],\
[983, 983, -1/3*w^3 + 11/3*w^2 - 11/3*w - 15],\
[983, 983, 3*w^2 - 2*w - 16],\
[983, 983, -5/3*w^3 + 16/3*w^2 + 11/3*w - 14],\
[991, 991, 4/3*w^3 - 8/3*w^2 - 22/3*w + 1],\
[991, 991, 2/3*w^3 - 4/3*w^2 - 2/3*w - 3]]
primes = [ZF.ideal(I) for I in primes_array]

heckePol = x^4 - 34*x^2 + 200
K.<e> = NumberField(heckePol)

hecke_eigenvalues_array = [-1, 1/20*e^3 - 7/10*e, e, 1/20*e^3 - 7/10*e, 0, 0, -1/2*e^2 + 11, -1/2*e^2 + 11, -e^2 + 16, -1/5*e^3 + 29/5*e, -1/5*e^3 + 29/5*e, 1/10*e^3 - 12/5*e, 1/10*e^3 - 12/5*e, -1/5*e^3 + 24/5*e, -e^2 + 18, -e^2 + 18, -1/5*e^3 + 24/5*e, 2/5*e^3 - 43/5*e, 2/5*e^3 - 43/5*e, -3/20*e^3 + 11/10*e, -3/20*e^3 + 11/10*e, -1/2*e^2 + 11, -1/2*e^2 + 11, -2*e, -2*e, 7/20*e^3 - 89/10*e, 7/20*e^3 - 89/10*e, e^2 - 16, e^2 - 16, -e^2 + 12, -e^2 + 12, 1/2*e^2 - 5, 1/2*e^2 - 5, 1/2*e^3 - 12*e, 1/2*e^3 - 12*e, -3/10*e^3 + 46/5*e, 1/10*e^3 + 3/5*e, -3/10*e^3 + 46/5*e, 1/10*e^3 + 3/5*e, -e^2 + 14, -e^2 + 14, 3/2*e^2 - 39, -7/10*e^3 + 64/5*e, 3/2*e^2 - 39, -7/10*e^3 + 64/5*e, -1/2*e^2 - 5, -1/2*e^2 - 5, 1/4*e^3 - 21/2*e, 1/4*e^3 - 21/2*e, 2, -8, 2, -8, 30, e^2 + 6, 1/2*e^2 + 5, 1/2*e^2 + 5, -6, -6, 1/5*e^3 - 19/5*e, 1/5*e^3 - 19/5*e, -1/20*e^3 + 27/10*e, -1/20*e^3 + 27/10*e, 3/20*e^3 - 21/10*e, -1/2*e^2 - 9, 3/20*e^3 - 21/10*e, -1/2*e^2 - 9, e^2 - 6, 1/5*e^3 - 54/5*e, e^2 - 6, 1/5*e^3 - 54/5*e, 24, 24, -3/10*e^3 + 16/5*e, -3/10*e^3 + 16/5*e, 1/20*e^3 - 77/10*e, 1/20*e^3 - 77/10*e, -e^2 + 24, 1/2*e^3 - 12*e, 1/2*e^3 - 12*e, -e^2 + 24, -9/20*e^3 + 133/10*e, -1/2*e^2 + 1, -1/2*e^2 + 1, -9/20*e^3 + 133/10*e, 9/10*e^3 - 103/5*e, 9/10*e^3 - 103/5*e, 1/2*e^2 - 17, 1/2*e^2 - 17, -3/10*e^3 + 56/5*e, -3/10*e^3 + 56/5*e, -3/10*e^3 + 41/5*e, -3/10*e^3 + 41/5*e, 4*e^2 - 66, 4*e^2 - 66, -e^2 - 8, -e^2 - 8, -16, -16, 22, 22, -2*e^2 + 58, 1/5*e^3 - 9/5*e, 1/5*e^3 - 9/5*e, 2/5*e^3 - 38/5*e, 2/5*e^3 - 38/5*e, -3/4*e^3 + 37/2*e, -3/4*e^3 + 37/2*e, 1/10*e^3 - 17/5*e, -11/20*e^3 + 187/10*e, 1/10*e^3 - 17/5*e, -11/20*e^3 + 187/10*e, -3*e^2 + 70, -3*e^2 + 70, 1/2*e^2 + 19, -1/20*e^3 + 57/10*e, -1/20*e^3 + 57/10*e, -9/20*e^3 + 93/10*e, -9/20*e^3 + 93/10*e, 5/2*e^2 - 47, -13/20*e^3 + 181/10*e, -13/20*e^3 + 181/10*e, 5/2*e^2 - 47, 3/2*e^2 - 27, 3/2*e^2 - 27, -5/2*e^2 + 33, -5/2*e^2 + 33, 3/2*e^2 + 13, 3/2*e^2 + 13, -3/10*e^3 + 26/5*e, -3/10*e^3 + 26/5*e, -2/5*e^3 + 43/5*e, -2/5*e^3 + 43/5*e, 5/4*e^3 - 49/2*e, 5/4*e^3 - 49/2*e, 7/20*e^3 - 19/10*e, 7/20*e^3 - 19/10*e, -2*e^2 + 26, -2*e^2 + 26, -7/10*e^3 + 84/5*e, -7/10*e^3 + 84/5*e, -3/2*e^2 + 33, 1/5*e^3 - 14/5*e, 1/5*e^3 - 14/5*e, -3/2*e^2 + 33, -3/4*e^3 + 23/2*e, -3/4*e^3 + 23/2*e, 3*e^2 - 30, 3*e^2 - 30, 9/2*e^2 - 93, 9/2*e^2 - 93, -11/20*e^3 + 187/10*e, -11/20*e^3 + 187/10*e, 4*e^2 - 68, 4*e^2 - 68, -2*e^2 + 42, -2*e^2 + 42, -3/2*e^2 + 63, 5/2*e^2 - 37, 5/2*e^2 - 37, 5/2*e^2 - 37, 7/2*e^2 - 51, 5/2*e^2 - 37, 7/2*e^2 - 51, -2*e^2 + 12, -1/4*e^3 - 7/2*e, -1/4*e^3 - 7/2*e, -2*e^2 + 12, 17/10*e^3 - 169/5*e, 17/10*e^3 - 169/5*e]
hecke_eigenvalues = {}
for i in range(len(hecke_eigenvalues_array)):
    hecke_eigenvalues[primes[i]] = hecke_eigenvalues_array[i]

AL_eigenvalues = {}
AL_eigenvalues[ZF.ideal([4, 2, -1/3*w^3 + 2/3*w^2 + 4/3*w - 1])] = 1

# EXAMPLE:
# pp = ZF.ideal(2).factor()[0][0]
# hecke_eigenvalues[pp]