import typing def _ceil_pow2(n: int) -> int: x = 0 while (1 << x) < n: x += 1 return x class SegTree: def __init__(self, op: typing.Callable[[typing.Any, typing.Any], typing.Any], e: typing.Any, v: typing.Union[int, typing.List[typing.Any]]) -> None: self._op = op self._e = e if isinstance(v, int): v = [e] * v self._n = len(v) self._log = _ceil_pow2(self._n) self._size = 1 << self._log self._d = [e] * (2 * self._size) for i in range(self._n): self._d[self._size + i] = v[i] for i in range(self._size - 1, 0, -1): self._update(i) def set(self, p: int, x: typing.Any) -> None: assert 0 <= p < self._n p += self._size self._d[p] = x for i in range(1, self._log + 1): self._update(p >> i) def get(self, p: int) -> typing.Any: assert 0 <= p < self._n return self._d[p + self._size] def prod(self, left: int, right: int) -> typing.Any: assert 0 <= left <= right <= self._n sml = self._e smr = self._e left += self._size right += self._size while left < right: if left & 1: sml = self._op(sml, self._d[left]) left += 1 if right & 1: right -= 1 smr = self._op(self._d[right], smr) left >>= 1 right >>= 1 return self._op(sml, smr) def all_prod(self) -> typing.Any: return self._d[1] def max_right(self, left: int, f: typing.Callable[[typing.Any], bool]) -> int: assert 0 <= left <= self._n assert f(self._e) if left == self._n: return self._n left += self._size sm = self._e first = True while first or (left & -left) != left: first = False while left % 2 == 0: left >>= 1 if not f(self._op(sm, self._d[left])): while left < self._size: left *= 2 if f(self._op(sm, self._d[left])): sm = self._op(sm, self._d[left]) left += 1 return left - self._size sm = self._op(sm, self._d[left]) left += 1 return self._n def min_left(self, right: int, f: typing.Callable[[typing.Any], bool]) -> int: assert 0 <= right <= self._n assert f(self._e) if right == 0: return 0 right += self._size sm = self._e first = True while first or (right & -right) != right: first = False right -= 1 while right > 1 and right % 2: right >>= 1 if not f(self._op(self._d[right], sm)): while right < self._size: right = 2 * right + 1 if f(self._op(self._d[right], sm)): sm = self._op(self._d[right], sm) right -= 1 return right + 1 - self._size sm = self._op(self._d[right], sm) return 0 def _update(self, k: int) -> None: self._d[k] = self._op(self._d[2 * k], self._d[2 * k + 1]) from random import randint N,L,Q = list(map(int,input().split())) MASK = randint(10**30,10**31) MOD = (1<<31) - 1 S = [] for _ in range(N): s = input() T = SegTree(lambda x,y:(x+y) % MOD, 0, [pow(MASK,num,MOD) * (ord(i) - ord("a")) % MOD for num,i in enumerate(s)]) S.append(T) for _ in range(Q): query = input().split() if(query[0] == "1"): _,k,c,d = query k = int(k) - 1 for i in range(N): if(S[i].get(k) != pow(MASK,k,MOD) * (ord(c) - ord("a")) % MOD):continue S[i].set(k, pow(MASK,k,MOD) * (ord(d) - ord("a")) % MOD) else: _,t = query t_v = 0 for i in range(len(t)): t_v += pow(MASK,i,MOD) * (ord(t[i]) - ord("a")) t_v %= MOD ans = 0 for i in range(N): v = S[i].prod(0,len(t)) ans += v == t_v print(ans)