import sys

import numpy as np


def read_int(): return int(input())
def read_int_tuple(): return map(int, sys.stdin.readline().rstrip().split())
def read_int_list(): return list(map(int, input().split()))


def convolute(As, Bs, MOD=10 ** 9 + 7, fft_len=2 ** 20):
    """ As, Bs, np.array([..], dtype=np.int64) """
    def _convolute8(aa, bb):
        return np.round(np.real(np.fft.irfft(np.fft.rfft(aa, fft_len) *
                                             np.fft.rfft(bb, fft_len),
                                             fft_len))).astype(np.int64)

    def _convolute16(aa, bb):
        mask = (1 << 8) - 1
        uAs = aa >> 8
        uBs = bb >> 8
        dAs = aa & mask
        dBs = bb & mask
        uCs = _convolute8(uAs, uBs) % MOD
        dCs = _convolute8(dAs, dBs) % MOD
        mCs = (_convolute8((uAs + dAs), (uBs + dBs)) - uCs - dCs) % MOD
        return (uCs * pow(2, 8 * 2, MOD) + mCs * pow(2, 8, MOD) + dCs) % MOD
    mask = (1 << 16) - 1
    uAs = As >> 16
    uBs = Bs >> 16
    dAs = As & mask
    dBs = Bs & mask

    uCs = _convolute16(uAs, uBs) % MOD
    dCs = _convolute16(dAs, dBs) % MOD
    mCs = (_convolute16((uAs + dAs), (uBs + dBs)) - uCs - dCs) % MOD
    return (uCs * pow(2, 16 * 2, MOD) + mCs * pow(2, 16, MOD) + dCs) % MOD


L, M, N = read_int_tuple()
A = read_int_list()
B = read_int_list()
Q = read_int()
C = [0] * (N + 1)
D = [0] * (N + 1)
for a in A:
    C[a] = 1
for b in B:
    D[N - b] = 1
ans = convolute(np.array(C, dtype=np.int64), np.array(D, dtype=np.int64))
for i in range(Q):
    print(ans[N + i])