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# precomputes a set of collocations by advancing over the text.
# warning: nasty C code
from libc.stdio cimport FILE, fopen, fread, fwrite, fclose
from libc.stdlib cimport malloc, realloc, free
from libc.string cimport memset, memcpy
cdef struct _Trie_Node # forward decl
cdef struct _Trie_Edge:
int val
_Trie_Node* node
_Trie_Edge* bigger
_Trie_Edge* smaller
cdef struct _Trie_Node:
_Trie_Edge* root
int* arr
int arr_len
cdef _Trie_Node* new_trie_node():
cdef _Trie_Node* node
node = <_Trie_Node*> malloc(sizeof(_Trie_Node))
node.root = NULL
node.arr_len = 0
node.arr = <int*> malloc(sizeof(0*sizeof(int)))
return node
cdef _Trie_Edge* new_trie_edge(int val):
cdef _Trie_Edge* edge
edge = <_Trie_Edge*> malloc(sizeof(_Trie_Edge))
edge.node = new_trie_node()
edge.bigger = NULL
edge.smaller = NULL
edge.val = val
return edge
cdef free_trie_node(_Trie_Node* node):
if node != NULL:
free_trie_edge(node.root)
free(node.arr)
cdef free_trie_edge(_Trie_Edge* edge):
if edge != NULL:
free_trie_node(edge.node)
free_trie_edge(edge.bigger)
free_trie_edge(edge.smaller)
cdef _Trie_Node* trie_find(_Trie_Node* node, int val):
cdef _Trie_Edge* cur
cur = node.root
while cur != NULL and cur.val != val:
if val > cur.val:
cur = cur.bigger
elif val < cur.val:
cur = cur.smaller
if cur == NULL:
return NULL
else:
return cur.node
cdef trie_node_data_append(_Trie_Node* node, int val):
cdef int new_len
new_len = node.arr_len + 1
node.arr = <int*> realloc(node.arr, new_len*sizeof(int))
node.arr[node.arr_len] = val
node.arr_len = new_len
cdef trie_node_data_extend(_Trie_Node* node, int* vals, int num_vals):
cdef int new_len
new_len = node.arr_len + num_vals
node.arr = <int*> realloc(node.arr, new_len*sizeof(int))
memcpy(node.arr + node.arr_len, vals, num_vals*sizeof(int))
node.arr_len = new_len
cdef _Trie_Node* trie_insert(_Trie_Node* node, int val):
cdef _Trie_Edge** cur
cur = &node.root
while cur[0] != NULL and cur[0].val != val:
if val > cur[0].val:
cur = &cur[0].bigger
elif val < cur[0].val:
cur = &cur[0].smaller
if cur[0] == NULL:
cur[0] = new_trie_edge(val)
return cur[0].node
cdef trie_node_to_map(_Trie_Node* node, result, prefix, int include_zeros):
cdef IntList arr
if include_zeros or node.arr_len > 0:
arr = IntList()
free(arr.arr)
arr.arr = <int*> malloc(node.arr_len * sizeof(int))
memcpy(arr.arr, node.arr, node.arr_len * sizeof(int))
arr.len = node.arr_len
arr.size = node.arr_len
result[prefix] = arr
trie_edge_to_map(node.root, result, prefix, include_zeros)
cdef trie_edge_to_map(_Trie_Edge* edge, result, prefix, int include_zeros):
if edge != NULL:
trie_edge_to_map(edge.smaller, result, prefix, include_zeros)
trie_edge_to_map(edge.bigger, result, prefix, include_zeros)
prefix = prefix + (edge.val,)
trie_node_to_map(edge.node, result, prefix, include_zeros)
cdef class TrieMap:
cdef _Trie_Node** root
cdef int V
def __cinit__(self, int alphabet_size):
self.V = alphabet_size
self.root = <_Trie_Node**> malloc(self.V * sizeof(_Trie_Node*))
memset(self.root, 0, self.V * sizeof(_Trie_Node*))
def __dealloc__(self):
cdef int i
for i from 0 <= i < self.V:
if self.root[i] != NULL:
free_trie_node(self.root[i])
free(self.root)
def insert(self, pattern):
cdef int* p
cdef int i, l
l = len(pattern)
p = <int*> malloc(l*sizeof(int))
for i from 0 <= i < l:
p[i] = pattern[i]
self._insert(p,l)
free(p)
cdef _Trie_Node* _insert(self, int* pattern, int pattern_len):
cdef int i
cdef _Trie_Node* node
if self.root[pattern[0]] == NULL:
self.root[pattern[0]] = new_trie_node()
node = self.root[pattern[0]]
for i from 1 <= i < pattern_len:
node = trie_insert(node, pattern[i])
return node
def contains(self, pattern):
cdef int* p
cdef int i, l
cdef _Trie_Node* node
l = len(pattern)
p = <int*> malloc(l*sizeof(int))
for i from 0 <= i < l:
p[i] = pattern[i]
node = self._contains(p,l)
free(p)
if node == NULL:
return False
else:
return True
cdef _Trie_Node* _contains(self, int* pattern, int pattern_len):
cdef int i
cdef _Trie_Node* node
node = self.root[pattern[0]]
i = 1
while node != NULL and i < pattern_len:
node = trie_find(node, pattern[i])
i = i+1
return node
def toMap(self, flag):
cdef int i, include_zeros
if flag:
include_zeros=1
else:
include_zeros=0
result = {}
for i from 0 <= i < self.V:
if self.root[i] != NULL:
trie_node_to_map(self.root[i], result, (i,), include_zeros)
return result
cdef class Precomputation:
cdef int precompute_rank
cdef int precompute_secondary_rank
cdef int max_length
cdef int max_nonterminals
cdef int train_max_initial_size
cdef int train_min_gap_size
cdef precomputed_index
cdef precomputed_collocations
cdef read_map(self, FILE* f)
cdef write_map(self, m, FILE* f)
def __cinit__(self, fsarray=None, from_stats=None, from_binary=None,
precompute_rank=1000, precompute_secondary_rank=20,
max_length=5, max_nonterminals=2,
train_max_initial_size=10, train_min_gap_size=2):
self.precompute_rank = precompute_rank
self.precompute_secondary_rank = precompute_secondary_rank
self.max_length = max_length
self.max_nonterminals = max_nonterminals
self.train_max_initial_size = train_max_initial_size
self.train_min_gap_size = train_min_gap_size
if from_binary:
self.read_binary(from_binary)
elif from_stats:
self.precompute(from_stats, fsarray)
def read_binary(self, char* filename):
cdef FILE* f
f = fopen(filename, "r")
fread(&(self.precompute_rank), sizeof(int), 1, f)
fread(&(self.precompute_secondary_rank), sizeof(int), 1, f)
fread(&(self.max_length), sizeof(int), 1, f)
fread(&(self.max_nonterminals), sizeof(int), 1, f)
fread(&(self.train_max_initial_size), sizeof(int), 1, f)
fread(&(self.train_min_gap_size), sizeof(int), 1, f)
self.precomputed_index = self.read_map(f)
self.precomputed_collocations = self.read_map(f)
fclose(f)
def write_binary(self, char* filename):
cdef FILE* f
f = fopen(filename, "w")
fwrite(&(self.precompute_rank), sizeof(int), 1, f)
fwrite(&(self.precompute_secondary_rank), sizeof(int), 1, f)
fwrite(&(self.max_length), sizeof(int), 1, f)
fwrite(&(self.max_nonterminals), sizeof(int), 1, f)
fwrite(&(self.train_max_initial_size), sizeof(int), 1, f)
fwrite(&(self.train_min_gap_size), sizeof(int), 1, f)
self.write_map(self.precomputed_index, f)
self.write_map(self.precomputed_collocations, f)
fclose(f)
cdef write_map(self, m, FILE* f):
cdef int i, N
cdef IntList arr
N = len(m)
fwrite(&(N), sizeof(int), 1, f)
for pattern, val in m.iteritems():
N = len(pattern)
fwrite(&(N), sizeof(int), 1, f)
for word_id in pattern:
i = word_id
fwrite(&(i), sizeof(int), 1, f)
arr = val
arr.write_handle(f)
cdef read_map(self, FILE* f):
cdef int i, j, k, word_id, N
cdef IntList arr
m = {}
fread(&(N), sizeof(int), 1, f)
for j from 0 <= j < N:
fread(&(i), sizeof(int), 1, f)
key = ()
for k from 0 <= k < i:
fread(&(word_id), sizeof(int), 1, f)
key = key + (word_id,)
arr = IntList()
arr.read_handle(f)
m[key] = arr
return m
def precompute(self, stats, SuffixArray sarray):
cdef int i, l, N, max_pattern_len, i1, l1, i2, l2, i3, l3, ptr1, ptr2, ptr3, is_super, sent_count, max_rank
cdef DataArray darray = sarray.darray
cdef IntList data, queue, cost_by_rank, count_by_rank
cdef TrieMap frequent_patterns, super_frequent_patterns, collocations
cdef _Trie_Node* node
data = darray.data
frequent_patterns = TrieMap(len(darray.id2word))
super_frequent_patterns = TrieMap(len(darray.id2word))
collocations = TrieMap(len(darray.id2word))
I_set = set()
J_set = set()
J2_set = set()
IJ_set = set()
pattern_rank = {}
logger.info("Precomputing frequent intersections")
cdef float start_time = monitor_cpu()
max_pattern_len = 0
for rank, (_, _, phrase) in enumerate(stats):
if rank >= self.precompute_rank:
break
max_pattern_len = max(max_pattern_len, len(phrase))
frequent_patterns.insert(phrase)
I_set.add(phrase)
pattern_rank[phrase] = rank
if rank < self.precompute_secondary_rank:
super_frequent_patterns.insert(phrase)
J_set.add(phrase)
queue = IntList(increment=1000)
logger.info(" Computing inverted indexes...")
N = len(data)
for i from 0 <= i < N:
sa_word_id = data.arr[i]
if sa_word_id == 1:
queue._append(-1)
else:
for l from 1 <= l <= max_pattern_len:
node = frequent_patterns._contains(data.arr+i, l)
if node == NULL:
break
queue._append(i)
queue._append(l)
trie_node_data_append(node, i)
logger.info(" Computing collocations...")
N = len(queue)
ptr1 = 0
sent_count = 0
while ptr1 < N: # main loop
i1 = queue.arr[ptr1]
if i1 > -1:
l1 = queue.arr[ptr1+1]
ptr2 = ptr1 + 2
while ptr2 < N:
i2 = queue.arr[ptr2]
if i2 == -1 or i2 - i1 >= self.train_max_initial_size:
break
l2 = queue.arr[ptr2+1]
if (i2 - i1 - l1 >= self.train_min_gap_size and
i2 + l2 - i1 <= self.train_max_initial_size and
l1+l2+1 <= self.max_length):
node = collocations._insert(data.arr+i1, l1)
node = trie_insert(node, -1)
for i from i2 <= i < i2+l2:
node = trie_insert(node, data.arr[i])
trie_node_data_append(node, i1)
trie_node_data_append(node, i2)
if super_frequent_patterns._contains(data.arr+i2, l2) != NULL:
if super_frequent_patterns._contains(data.arr+i1, l1) != NULL:
is_super = 1
else:
is_super = 0
ptr3 = ptr2 + 2
while ptr3 < N:
i3 = queue.arr[ptr3]
if i3 == -1 or i3 - i1 >= self.train_max_initial_size:
break
l3 = queue.arr[ptr3+1]
if (i3 - i2 - l2 >= self.train_min_gap_size and
i3 + l3 - i1 <= self.train_max_initial_size and
l1+l2+l3+2 <= self.max_length):
if is_super or super_frequent_patterns._contains(data.arr+i3, l3) != NULL:
node = collocations._insert(data.arr+i1, l1)
node = trie_insert(node, -1)
for i from i2 <= i < i2+l2:
node = trie_insert(node, data.arr[i])
node = trie_insert(node, -1)
for i from i3 <= i < i3+l3:
node = trie_insert(node, data.arr[i])
trie_node_data_append(node, i1)
trie_node_data_append(node, i2)
trie_node_data_append(node, i3)
ptr3 = ptr3 + 2
ptr2 = ptr2 + 2
ptr1 = ptr1 + 2
else:
sent_count = sent_count + 1
if sent_count % 10000 == 0:
logger.debug(" %d sentences", sent_count)
ptr1 = ptr1 + 1
self.precomputed_collocations = collocations.toMap(False)
self.precomputed_index = frequent_patterns.toMap(True)
x = 0
for pattern1 in J_set:
for pattern2 in J_set:
if len(pattern1) + len(pattern2) + 1 < self.max_length:
combined_pattern = pattern1 + (-1,) + pattern2
J2_set.add(combined_pattern)
for pattern1 in I_set:
for pattern2 in I_set:
x = x+1
if len(pattern1) + len(pattern2) + 1 <= self.max_length:
combined_pattern = pattern1 + (-1,) + pattern2
IJ_set.add(combined_pattern)
for pattern1 in I_set:
for pattern2 in J2_set:
x = x+2
if len(pattern1) + len(pattern2) + 1<= self.max_length:
combined_pattern = pattern1 + (-1,) + pattern2
IJ_set.add(combined_pattern)
combined_pattern = pattern2 + (-1,) + pattern1
IJ_set.add(combined_pattern)
N = len(pattern_rank)
cost_by_rank = IntList(initial_len=N)
count_by_rank = IntList(initial_len=N)
for pattern, arr in self.precomputed_collocations.iteritems():
if pattern not in IJ_set:
s = ""
for word_id in pattern:
if word_id == -1:
s = s + "X "
else:
s = s + darray.id2word[word_id] + " "
logger.warn("ERROR: unexpected pattern %s in set of precomputed collocations", s)
else:
chunk = ()
max_rank = 0
arity = 0
for word_id in pattern:
if word_id == -1:
max_rank = max(max_rank, pattern_rank[chunk])
arity = arity + 1
chunk = ()
else:
chunk = chunk + (word_id,)
max_rank = max(max_rank, pattern_rank[chunk])
cost_by_rank.arr[max_rank] = cost_by_rank.arr[max_rank] + (4*len(arr))
count_by_rank.arr[max_rank] = count_by_rank.arr[max_rank] + (len(arr)/(arity+1))
cumul_cost = 0
cumul_count = 0
for i from 0 <= i < N:
cumul_cost = cumul_cost + cost_by_rank.arr[i]
cumul_count = cumul_count + count_by_rank.arr[i]
logger.debug("RANK %d\tCOUNT, COST: %d %d\tCUMUL: %d, %d", i, count_by_rank.arr[i], cost_by_rank.arr[i], cumul_count, cumul_cost)
num_found_patterns = len(self.precomputed_collocations)
for pattern in IJ_set:
if pattern not in self.precomputed_collocations:
self.precomputed_collocations[pattern] = IntList()
cdef float stop_time = monitor_cpu()
logger.info("Precomputed collocations for %d patterns out of %d possible (upper bound %d)", num_found_patterns, len(self.precomputed_collocations), x)
logger.info("Precomputed inverted index for %d patterns ", len(self.precomputed_index))
logger.info("Precomputation took %f seconds", (stop_time - start_time))
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