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|
/* Copyright (c) 2003-2004, Roger Dingledine
* Copyright (c) 2004-2006, Roger Dingledine, Nick Mathewson.
* Copyright (c) 2007-2013, The Tor Project, Inc. */
/* See LICENSE for licensing information */
/**
* \file container.c
* \brief Implements a smartlist (a resizable array) along
* with helper functions to use smartlists. Also includes
* hash table implementations of a string-to-void* map, and of
* a digest-to-void* map.
**/
#include "compat.h"
#include "util.h"
#include "torlog.h"
#include "container.h"
#include "crypto.h"
#include <stdlib.h>
#include <string.h>
#include <assert.h>
#include "ht.h"
/** All newly allocated smartlists have this capacity. */
#define SMARTLIST_DEFAULT_CAPACITY 16
/** Allocate and return an empty smartlist.
*/
smartlist_t *
smartlist_new(void)
{
smartlist_t *sl = tor_malloc(sizeof(smartlist_t));
sl->num_used = 0;
sl->capacity = SMARTLIST_DEFAULT_CAPACITY;
sl->list = tor_malloc(sizeof(void *) * sl->capacity);
return sl;
}
/** Deallocate a smartlist. Does not release storage associated with the
* list's elements.
*/
void
smartlist_free(smartlist_t *sl)
{
if (!sl)
return;
tor_free(sl->list);
tor_free(sl);
}
/** Remove all elements from the list.
*/
void
smartlist_clear(smartlist_t *sl)
{
sl->num_used = 0;
}
/** Make sure that <b>sl</b> can hold at least <b>size</b> entries. */
static INLINE void
smartlist_ensure_capacity(smartlist_t *sl, int size)
{
#if SIZEOF_SIZE_T > SIZEOF_INT
#define MAX_CAPACITY (INT_MAX)
#else
#define MAX_CAPACITY (int)((SIZE_MAX / (sizeof(void*))))
#endif
if (size > sl->capacity) {
int higher = sl->capacity;
if (PREDICT_UNLIKELY(size > MAX_CAPACITY/2)) {
tor_assert(size <= MAX_CAPACITY);
higher = MAX_CAPACITY;
} else {
while (size > higher)
higher *= 2;
}
sl->capacity = higher;
sl->list = tor_realloc(sl->list, sizeof(void*)*((size_t)sl->capacity));
}
}
/** Append element to the end of the list. */
void
smartlist_add(smartlist_t *sl, void *element)
{
smartlist_ensure_capacity(sl, sl->num_used+1);
sl->list[sl->num_used++] = element;
}
/** Append each element from S2 to the end of S1. */
void
smartlist_add_all(smartlist_t *s1, const smartlist_t *s2)
{
int new_size = s1->num_used + s2->num_used;
tor_assert(new_size >= s1->num_used); /* check for overflow. */
smartlist_ensure_capacity(s1, new_size);
memcpy(s1->list + s1->num_used, s2->list, s2->num_used*sizeof(void*));
s1->num_used = new_size;
}
/** Remove all elements E from sl such that E==element. Preserve
* the order of any elements before E, but elements after E can be
* rearranged.
*/
void
smartlist_remove(smartlist_t *sl, const void *element)
{
int i;
if (element == NULL)
return;
for (i=0; i < sl->num_used; i++)
if (sl->list[i] == element) {
sl->list[i] = sl->list[--sl->num_used]; /* swap with the end */
i--; /* so we process the new i'th element */
}
}
/** If <b>sl</b> is nonempty, remove and return the final element. Otherwise,
* return NULL. */
void *
smartlist_pop_last(smartlist_t *sl)
{
tor_assert(sl);
if (sl->num_used)
return sl->list[--sl->num_used];
else
return NULL;
}
/** Reverse the order of the items in <b>sl</b>. */
void
smartlist_reverse(smartlist_t *sl)
{
int i, j;
void *tmp;
tor_assert(sl);
for (i = 0, j = sl->num_used-1; i < j; ++i, --j) {
tmp = sl->list[i];
sl->list[i] = sl->list[j];
sl->list[j] = tmp;
}
}
/** If there are any strings in sl equal to element, remove and free them.
* Does not preserve order. */
void
smartlist_string_remove(smartlist_t *sl, const char *element)
{
int i;
tor_assert(sl);
tor_assert(element);
for (i = 0; i < sl->num_used; ++i) {
if (!strcmp(element, sl->list[i])) {
tor_free(sl->list[i]);
sl->list[i] = sl->list[--sl->num_used]; /* swap with the end */
i--; /* so we process the new i'th element */
}
}
}
/** Return true iff some element E of sl has E==element.
*/
int
smartlist_contains(const smartlist_t *sl, const void *element)
{
int i;
for (i=0; i < sl->num_used; i++)
if (sl->list[i] == element)
return 1;
return 0;
}
/** Return true iff <b>sl</b> has some element E such that
* !strcmp(E,<b>element</b>)
*/
int
smartlist_contains_string(const smartlist_t *sl, const char *element)
{
int i;
if (!sl) return 0;
for (i=0; i < sl->num_used; i++)
if (strcmp((const char*)sl->list[i],element)==0)
return 1;
return 0;
}
/** If <b>element</b> is equal to an element of <b>sl</b>, return that
* element's index. Otherwise, return -1. */
int
smartlist_string_pos(const smartlist_t *sl, const char *element)
{
int i;
if (!sl) return -1;
for (i=0; i < sl->num_used; i++)
if (strcmp((const char*)sl->list[i],element)==0)
return i;
return -1;
}
/** Return true iff <b>sl</b> has some element E such that
* !strcasecmp(E,<b>element</b>)
*/
int
smartlist_contains_string_case(const smartlist_t *sl, const char *element)
{
int i;
if (!sl) return 0;
for (i=0; i < sl->num_used; i++)
if (strcasecmp((const char*)sl->list[i],element)==0)
return 1;
return 0;
}
/** Return true iff <b>sl</b> has some element E such that E is equal
* to the decimal encoding of <b>num</b>.
*/
int
smartlist_contains_int_as_string(const smartlist_t *sl, int num)
{
char buf[32]; /* long enough for 64-bit int, and then some. */
tor_snprintf(buf,sizeof(buf),"%d", num);
return smartlist_contains_string(sl, buf);
}
/** Return true iff the two lists contain the same strings in the same
* order, or if they are both NULL. */
int
smartlist_strings_eq(const smartlist_t *sl1, const smartlist_t *sl2)
{
if (sl1 == NULL)
return sl2 == NULL;
if (sl2 == NULL)
return 0;
if (smartlist_len(sl1) != smartlist_len(sl2))
return 0;
SMARTLIST_FOREACH(sl1, const char *, cp1, {
const char *cp2 = smartlist_get(sl2, cp1_sl_idx);
if (strcmp(cp1, cp2))
return 0;
});
return 1;
}
/** Return true iff the two lists contain the same int pointer values in
* the same order, or if they are both NULL. */
int
smartlist_ints_eq(const smartlist_t *sl1, const smartlist_t *sl2)
{
if (sl1 == NULL)
return sl2 == NULL;
if (sl2 == NULL)
return 0;
if (smartlist_len(sl1) != smartlist_len(sl2))
return 0;
SMARTLIST_FOREACH(sl1, int *, cp1, {
int *cp2 = smartlist_get(sl2, cp1_sl_idx);
if (*cp1 != *cp2)
return 0;
});
return 1;
}
/** Return true iff <b>sl</b> has some element E such that
* tor_memeq(E,<b>element</b>,DIGEST_LEN)
*/
int
smartlist_contains_digest(const smartlist_t *sl, const char *element)
{
int i;
if (!sl) return 0;
for (i=0; i < sl->num_used; i++)
if (tor_memeq((const char*)sl->list[i],element,DIGEST_LEN))
return 1;
return 0;
}
/** Return true iff some element E of sl2 has smartlist_contains(sl1,E).
*/
int
smartlist_overlap(const smartlist_t *sl1, const smartlist_t *sl2)
{
int i;
for (i=0; i < sl2->num_used; i++)
if (smartlist_contains(sl1, sl2->list[i]))
return 1;
return 0;
}
/** Remove every element E of sl1 such that !smartlist_contains(sl2,E).
* Does not preserve the order of sl1.
*/
void
smartlist_intersect(smartlist_t *sl1, const smartlist_t *sl2)
{
int i;
for (i=0; i < sl1->num_used; i++)
if (!smartlist_contains(sl2, sl1->list[i])) {
sl1->list[i] = sl1->list[--sl1->num_used]; /* swap with the end */
i--; /* so we process the new i'th element */
}
}
/** Remove every element E of sl1 such that smartlist_contains(sl2,E).
* Does not preserve the order of sl1.
*/
void
smartlist_subtract(smartlist_t *sl1, const smartlist_t *sl2)
{
int i;
for (i=0; i < sl2->num_used; i++)
smartlist_remove(sl1, sl2->list[i]);
}
/** Remove the <b>idx</b>th element of sl; if idx is not the last
* element, swap the last element of sl into the <b>idx</b>th space.
*/
void
smartlist_del(smartlist_t *sl, int idx)
{
tor_assert(sl);
tor_assert(idx>=0);
tor_assert(idx < sl->num_used);
sl->list[idx] = sl->list[--sl->num_used];
}
/** Remove the <b>idx</b>th element of sl; if idx is not the last element,
* moving all subsequent elements back one space. Return the old value
* of the <b>idx</b>th element.
*/
void
smartlist_del_keeporder(smartlist_t *sl, int idx)
{
tor_assert(sl);
tor_assert(idx>=0);
tor_assert(idx < sl->num_used);
--sl->num_used;
if (idx < sl->num_used)
memmove(sl->list+idx, sl->list+idx+1, sizeof(void*)*(sl->num_used-idx));
}
/** Insert the value <b>val</b> as the new <b>idx</b>th element of
* <b>sl</b>, moving all items previously at <b>idx</b> or later
* forward one space.
*/
void
smartlist_insert(smartlist_t *sl, int idx, void *val)
{
tor_assert(sl);
tor_assert(idx>=0);
tor_assert(idx <= sl->num_used);
if (idx == sl->num_used) {
smartlist_add(sl, val);
} else {
smartlist_ensure_capacity(sl, sl->num_used+1);
/* Move other elements away */
if (idx < sl->num_used)
memmove(sl->list + idx + 1, sl->list + idx,
sizeof(void*)*(sl->num_used-idx));
sl->num_used++;
sl->list[idx] = val;
}
}
/**
* Split a string <b>str</b> along all occurrences of <b>sep</b>,
* appending the (newly allocated) split strings, in order, to
* <b>sl</b>. Return the number of strings added to <b>sl</b>.
*
* If <b>flags</b>&SPLIT_SKIP_SPACE is true, remove initial and
* trailing space from each entry.
* If <b>flags</b>&SPLIT_IGNORE_BLANK is true, remove any entries
* of length 0.
* If <b>flags</b>&SPLIT_STRIP_SPACE is true, strip spaces from each
* split string.
*
* If <b>max</b>\>0, divide the string into no more than <b>max</b> pieces. If
* <b>sep</b> is NULL, split on any sequence of horizontal space.
*/
int
smartlist_split_string(smartlist_t *sl, const char *str, const char *sep,
int flags, int max)
{
const char *cp, *end, *next;
int n = 0;
tor_assert(sl);
tor_assert(str);
cp = str;
while (1) {
if (flags&SPLIT_SKIP_SPACE) {
while (TOR_ISSPACE(*cp)) ++cp;
}
if (max>0 && n == max-1) {
end = strchr(cp,'\0');
} else if (sep) {
end = strstr(cp,sep);
if (!end)
end = strchr(cp,'\0');
} else {
for (end = cp; *end && *end != '\t' && *end != ' '; ++end)
;
}
tor_assert(end);
if (!*end) {
next = NULL;
} else if (sep) {
next = end+strlen(sep);
} else {
next = end+1;
while (*next == '\t' || *next == ' ')
++next;
}
if (flags&SPLIT_SKIP_SPACE) {
while (end > cp && TOR_ISSPACE(*(end-1)))
--end;
}
if (end != cp || !(flags&SPLIT_IGNORE_BLANK)) {
char *string = tor_strndup(cp, end-cp);
if (flags&SPLIT_STRIP_SPACE)
tor_strstrip(string, " ");
smartlist_add(sl, string);
++n;
}
if (!next)
break;
cp = next;
}
return n;
}
/** Allocate and return a new string containing the concatenation of
* the elements of <b>sl</b>, in order, separated by <b>join</b>. If
* <b>terminate</b> is true, also terminate the string with <b>join</b>.
* If <b>len_out</b> is not NULL, set <b>len_out</b> to the length of
* the returned string. Requires that every element of <b>sl</b> is
* NUL-terminated string.
*/
char *
smartlist_join_strings(smartlist_t *sl, const char *join,
int terminate, size_t *len_out)
{
return smartlist_join_strings2(sl,join,strlen(join),terminate,len_out);
}
/** As smartlist_join_strings, but instead of separating/terminated with a
* NUL-terminated string <b>join</b>, uses the <b>join_len</b>-byte sequence
* at <b>join</b>. (Useful for generating a sequence of NUL-terminated
* strings.)
*/
char *
smartlist_join_strings2(smartlist_t *sl, const char *join,
size_t join_len, int terminate, size_t *len_out)
{
int i;
size_t n = 0;
char *r = NULL, *dst, *src;
tor_assert(sl);
tor_assert(join);
if (terminate)
n = join_len;
for (i = 0; i < sl->num_used; ++i) {
n += strlen(sl->list[i]);
if (i+1 < sl->num_used) /* avoid double-counting the last one */
n += join_len;
}
dst = r = tor_malloc(n+1);
for (i = 0; i < sl->num_used; ) {
for (src = sl->list[i]; *src; )
*dst++ = *src++;
if (++i < sl->num_used) {
memcpy(dst, join, join_len);
dst += join_len;
}
}
if (terminate) {
memcpy(dst, join, join_len);
dst += join_len;
}
*dst = '\0';
if (len_out)
*len_out = dst-r;
return r;
}
/** Sort the members of <b>sl</b> into an order defined by
* the ordering function <b>compare</b>, which returns less then 0 if a
* precedes b, greater than 0 if b precedes a, and 0 if a 'equals' b.
*/
void
smartlist_sort(smartlist_t *sl, int (*compare)(const void **a, const void **b))
{
if (!sl->num_used)
return;
qsort(sl->list, sl->num_used, sizeof(void*),
(int (*)(const void *,const void*))compare);
}
/** Given a smartlist <b>sl</b> sorted with the function <b>compare</b>,
* return the most frequent member in the list. Break ties in favor of
* later elements. If the list is empty, return NULL.
*/
void *
smartlist_get_most_frequent(const smartlist_t *sl,
int (*compare)(const void **a, const void **b))
{
const void *most_frequent = NULL;
int most_frequent_count = 0;
const void *cur = NULL;
int i, count=0;
if (!sl->num_used)
return NULL;
for (i = 0; i < sl->num_used; ++i) {
const void *item = sl->list[i];
if (cur && 0 == compare(&cur, &item)) {
++count;
} else {
if (cur && count >= most_frequent_count) {
most_frequent = cur;
most_frequent_count = count;
}
cur = item;
count = 1;
}
}
if (cur && count >= most_frequent_count) {
most_frequent = cur;
most_frequent_count = count;
}
return (void*)most_frequent;
}
/** Given a sorted smartlist <b>sl</b> and the comparison function used to
* sort it, remove all duplicate members. If free_fn is provided, calls
* free_fn on each duplicate. Otherwise, just removes them. Preserves order.
*/
void
smartlist_uniq(smartlist_t *sl,
int (*compare)(const void **a, const void **b),
void (*free_fn)(void *a))
{
int i;
for (i=1; i < sl->num_used; ++i) {
if (compare((const void **)&(sl->list[i-1]),
(const void **)&(sl->list[i])) == 0) {
if (free_fn)
free_fn(sl->list[i]);
smartlist_del_keeporder(sl, i--);
}
}
}
/** Assuming the members of <b>sl</b> are in order, return a pointer to the
* member that matches <b>key</b>. Ordering and matching are defined by a
* <b>compare</b> function that returns 0 on a match; less than 0 if key is
* less than member, and greater than 0 if key is greater then member.
*/
void *
smartlist_bsearch(smartlist_t *sl, const void *key,
int (*compare)(const void *key, const void **member))
{
int found, idx;
idx = smartlist_bsearch_idx(sl, key, compare, &found);
return found ? smartlist_get(sl, idx) : NULL;
}
/** Assuming the members of <b>sl</b> are in order, return the index of the
* member that matches <b>key</b>. If no member matches, return the index of
* the first member greater than <b>key</b>, or smartlist_len(sl) if no member
* is greater than <b>key</b>. Set <b>found_out</b> to true on a match, to
* false otherwise. Ordering and matching are defined by a <b>compare</b>
* function that returns 0 on a match; less than 0 if key is less than member,
* and greater than 0 if key is greater then member.
*/
int
smartlist_bsearch_idx(const smartlist_t *sl, const void *key,
int (*compare)(const void *key, const void **member),
int *found_out)
{
int hi, lo, cmp, mid, len, diff;
tor_assert(sl);
tor_assert(compare);
tor_assert(found_out);
len = smartlist_len(sl);
/* Check for the trivial case of a zero-length list */
if (len == 0) {
*found_out = 0;
/* We already know smartlist_len(sl) is 0 in this case */
return 0;
}
/* Okay, we have a real search to do */
tor_assert(len > 0);
lo = 0;
hi = len - 1;
/*
* These invariants are always true:
*
* For all i such that 0 <= i < lo, sl[i] < key
* For all i such that hi < i <= len, sl[i] > key
*/
while (lo <= hi) {
diff = hi - lo;
/*
* We want mid = (lo + hi) / 2, but that could lead to overflow, so
* instead diff = hi - lo (non-negative because of loop condition), and
* then hi = lo + diff, mid = (lo + lo + diff) / 2 = lo + (diff / 2).
*/
mid = lo + (diff / 2);
cmp = compare(key, (const void**) &(sl->list[mid]));
if (cmp == 0) {
/* sl[mid] == key; we found it */
*found_out = 1;
return mid;
} else if (cmp > 0) {
/*
* key > sl[mid] and an index i such that sl[i] == key must
* have i > mid if it exists.
*/
/*
* Since lo <= mid <= hi, hi can only decrease on each iteration (by
* being set to mid - 1) and hi is initially len - 1, mid < len should
* always hold, and this is not symmetric with the left end of list
* mid > 0 test below. A key greater than the right end of the list
* should eventually lead to lo == hi == mid == len - 1, and then
* we set lo to len below and fall out to the same exit we hit for
* a key in the middle of the list but not matching. Thus, we just
* assert for consistency here rather than handle a mid == len case.
*/
tor_assert(mid < len);
/* Move lo to the element immediately after sl[mid] */
lo = mid + 1;
} else {
/* This should always be true in this case */
tor_assert(cmp < 0);
/*
* key < sl[mid] and an index i such that sl[i] == key must
* have i < mid if it exists.
*/
if (mid > 0) {
/* Normal case, move hi to the element immediately before sl[mid] */
hi = mid - 1;
} else {
/* These should always be true in this case */
tor_assert(mid == lo);
tor_assert(mid == 0);
/*
* We were at the beginning of the list and concluded that every
* element e compares e > key.
*/
*found_out = 0;
return 0;
}
}
}
/*
* lo > hi; we have no element matching key but we have elements falling
* on both sides of it. The lo index points to the first element > key.
*/
tor_assert(lo == hi + 1); /* All other cases should have been handled */
tor_assert(lo >= 0);
tor_assert(lo <= len);
tor_assert(hi >= 0);
tor_assert(hi <= len);
if (lo < len) {
cmp = compare(key, (const void **) &(sl->list[lo]));
tor_assert(cmp < 0);
} else {
cmp = compare(key, (const void **) &(sl->list[len-1]));
tor_assert(cmp > 0);
}
*found_out = 0;
return lo;
}
/** Helper: compare two const char **s. */
static int
compare_string_ptrs_(const void **_a, const void **_b)
{
return strcmp((const char*)*_a, (const char*)*_b);
}
/** Sort a smartlist <b>sl</b> containing strings into lexically ascending
* order. */
void
smartlist_sort_strings(smartlist_t *sl)
{
smartlist_sort(sl, compare_string_ptrs_);
}
/** Return the most frequent string in the sorted list <b>sl</b> */
char *
smartlist_get_most_frequent_string(smartlist_t *sl)
{
return smartlist_get_most_frequent(sl, compare_string_ptrs_);
}
/** Remove duplicate strings from a sorted list, and free them with tor_free().
*/
void
smartlist_uniq_strings(smartlist_t *sl)
{
smartlist_uniq(sl, compare_string_ptrs_, tor_free_);
}
/** Helper: compare two pointers. */
static int
compare_ptrs_(const void **_a, const void **_b)
{
const void *a = *_a, *b = *_b;
if (a<b)
return -1;
else if (a==b)
return 0;
else
return 1;
}
/** Sort <b>sl</b> in ascending order of the pointers it contains. */
void
smartlist_sort_pointers(smartlist_t *sl)
{
smartlist_sort(sl, compare_ptrs_);
}
/* Heap-based priority queue implementation for O(lg N) insert and remove.
* Recall that the heap property is that, for every index I, h[I] <
* H[LEFT_CHILD[I]] and h[I] < H[RIGHT_CHILD[I]].
*
* For us to remove items other than the topmost item, each item must store
* its own index within the heap. When calling the pqueue functions, tell
* them about the offset of the field that stores the index within the item.
*
* Example:
*
* typedef struct timer_t {
* struct timeval tv;
* int heap_index;
* } timer_t;
*
* static int compare(const void *p1, const void *p2) {
* const timer_t *t1 = p1, *t2 = p2;
* if (t1->tv.tv_sec < t2->tv.tv_sec) {
* return -1;
* } else if (t1->tv.tv_sec > t2->tv.tv_sec) {
* return 1;
* } else {
* return t1->tv.tv_usec - t2->tv_usec;
* }
* }
*
* void timer_heap_insert(smartlist_t *heap, timer_t *timer) {
* smartlist_pqueue_add(heap, compare, STRUCT_OFFSET(timer_t, heap_index),
* timer);
* }
*
* void timer_heap_pop(smartlist_t *heap) {
* return smartlist_pqueue_pop(heap, compare,
* STRUCT_OFFSET(timer_t, heap_index));
* }
*/
/** @{ */
/** Functions to manipulate heap indices to find a node's parent and children.
*
* For a 1-indexed array, we would use LEFT_CHILD[x] = 2*x and RIGHT_CHILD[x]
* = 2*x + 1. But this is C, so we have to adjust a little. */
//#define LEFT_CHILD(i) ( ((i)+1)*2 - 1)
//#define RIGHT_CHILD(i) ( ((i)+1)*2 )
//#define PARENT(i) ( ((i)+1)/2 - 1)
#define LEFT_CHILD(i) ( 2*(i) + 1 )
#define RIGHT_CHILD(i) ( 2*(i) + 2 )
#define PARENT(i) ( ((i)-1) / 2 )
/** }@ */
/** @{ */
/** Helper macros for heaps: Given a local variable <b>idx_field_offset</b>
* set to the offset of an integer index within the heap element structure,
* IDX_OF_ITEM(p) gives you the index of p, and IDXP(p) gives you a pointer to
* where p's index is stored. Given additionally a local smartlist <b>sl</b>,
* UPDATE_IDX(i) sets the index of the element at <b>i</b> to the correct
* value (that is, to <b>i</b>).
*/
#define IDXP(p) ((int*)STRUCT_VAR_P(p, idx_field_offset))
#define UPDATE_IDX(i) do { \
void *updated = sl->list[i]; \
*IDXP(updated) = i; \
} while (0)
#define IDX_OF_ITEM(p) (*IDXP(p))
/** @} */
/** Helper. <b>sl</b> may have at most one violation of the heap property:
* the item at <b>idx</b> may be greater than one or both of its children.
* Restore the heap property. */
static INLINE void
smartlist_heapify(smartlist_t *sl,
int (*compare)(const void *a, const void *b),
int idx_field_offset,
int idx)
{
while (1) {
int left_idx = LEFT_CHILD(idx);
int best_idx;
if (left_idx >= sl->num_used)
return;
if (compare(sl->list[idx],sl->list[left_idx]) < 0)
best_idx = idx;
else
best_idx = left_idx;
if (left_idx+1 < sl->num_used &&
compare(sl->list[left_idx+1],sl->list[best_idx]) < 0)
best_idx = left_idx + 1;
if (best_idx == idx) {
return;
} else {
void *tmp = sl->list[idx];
sl->list[idx] = sl->list[best_idx];
sl->list[best_idx] = tmp;
UPDATE_IDX(idx);
UPDATE_IDX(best_idx);
idx = best_idx;
}
}
}
/** Insert <b>item</b> into the heap stored in <b>sl</b>, where order is
* determined by <b>compare</b> and the offset of the item in the heap is
* stored in an int-typed field at position <b>idx_field_offset</b> within
* item.
*/
void
smartlist_pqueue_add(smartlist_t *sl,
int (*compare)(const void *a, const void *b),
int idx_field_offset,
void *item)
{
int idx;
smartlist_add(sl,item);
UPDATE_IDX(sl->num_used-1);
for (idx = sl->num_used - 1; idx; ) {
int parent = PARENT(idx);
if (compare(sl->list[idx], sl->list[parent]) < 0) {
void *tmp = sl->list[parent];
sl->list[parent] = sl->list[idx];
sl->list[idx] = tmp;
UPDATE_IDX(parent);
UPDATE_IDX(idx);
idx = parent;
} else {
return;
}
}
}
/** Remove and return the top-priority item from the heap stored in <b>sl</b>,
* where order is determined by <b>compare</b> and the item's position is
* stored at position <b>idx_field_offset</b> within the item. <b>sl</b> must
* not be empty. */
void *
smartlist_pqueue_pop(smartlist_t *sl,
int (*compare)(const void *a, const void *b),
int idx_field_offset)
{
void *top;
tor_assert(sl->num_used);
top = sl->list[0];
*IDXP(top)=-1;
if (--sl->num_used) {
sl->list[0] = sl->list[sl->num_used];
UPDATE_IDX(0);
smartlist_heapify(sl, compare, idx_field_offset, 0);
}
return top;
}
/** Remove the item <b>item</b> from the heap stored in <b>sl</b>,
* where order is determined by <b>compare</b> and the item's position is
* stored at position <b>idx_field_offset</b> within the item. <b>sl</b> must
* not be empty. */
void
smartlist_pqueue_remove(smartlist_t *sl,
int (*compare)(const void *a, const void *b),
int idx_field_offset,
void *item)
{
int idx = IDX_OF_ITEM(item);
tor_assert(idx >= 0);
tor_assert(sl->list[idx] == item);
--sl->num_used;
*IDXP(item) = -1;
if (idx == sl->num_used) {
return;
} else {
sl->list[idx] = sl->list[sl->num_used];
UPDATE_IDX(idx);
smartlist_heapify(sl, compare, idx_field_offset, idx);
}
}
/** Assert that the heap property is correctly maintained by the heap stored
* in <b>sl</b>, where order is determined by <b>compare</b>. */
void
smartlist_pqueue_assert_ok(smartlist_t *sl,
int (*compare)(const void *a, const void *b),
int idx_field_offset)
{
int i;
for (i = sl->num_used - 1; i >= 0; --i) {
if (i>0)
tor_assert(compare(sl->list[PARENT(i)], sl->list[i]) <= 0);
tor_assert(IDX_OF_ITEM(sl->list[i]) == i);
}
}
/** Helper: compare two DIGEST_LEN digests. */
static int
compare_digests_(const void **_a, const void **_b)
{
return tor_memcmp((const char*)*_a, (const char*)*_b, DIGEST_LEN);
}
/** Sort the list of DIGEST_LEN-byte digests into ascending order. */
void
smartlist_sort_digests(smartlist_t *sl)
{
smartlist_sort(sl, compare_digests_);
}
/** Remove duplicate digests from a sorted list, and free them with tor_free().
*/
void
smartlist_uniq_digests(smartlist_t *sl)
{
smartlist_uniq(sl, compare_digests_, tor_free_);
}
/** Helper: compare two DIGEST256_LEN digests. */
static int
compare_digests256_(const void **_a, const void **_b)
{
return tor_memcmp((const char*)*_a, (const char*)*_b, DIGEST256_LEN);
}
/** Sort the list of DIGEST256_LEN-byte digests into ascending order. */
void
smartlist_sort_digests256(smartlist_t *sl)
{
smartlist_sort(sl, compare_digests256_);
}
/** Return the most frequent member of the sorted list of DIGEST256_LEN
* digests in <b>sl</b> */
char *
smartlist_get_most_frequent_digest256(smartlist_t *sl)
{
return smartlist_get_most_frequent(sl, compare_digests256_);
}
/** Remove duplicate 256-bit digests from a sorted list, and free them with
* tor_free().
*/
void
smartlist_uniq_digests256(smartlist_t *sl)
{
smartlist_uniq(sl, compare_digests256_, tor_free_);
}
/** Helper: Declare an entry type and a map type to implement a mapping using
* ht.h. The map type will be called <b>maptype</b>. The key part of each
* entry is declared using the C declaration <b>keydecl</b>. All functions
* and types associated with the map get prefixed with <b>prefix</b> */
#define DEFINE_MAP_STRUCTS(maptype, keydecl, prefix) \
typedef struct prefix ## entry_t { \
HT_ENTRY(prefix ## entry_t) node; \
void *val; \
keydecl; \
} prefix ## entry_t; \
struct maptype { \
HT_HEAD(prefix ## impl, prefix ## entry_t) head; \
}
DEFINE_MAP_STRUCTS(strmap_t, char *key, strmap_);
DEFINE_MAP_STRUCTS(digestmap_t, char key[DIGEST_LEN], digestmap_);
/** Helper: compare strmap_entry_t objects by key value. */
static INLINE int
strmap_entries_eq(const strmap_entry_t *a, const strmap_entry_t *b)
{
return !strcmp(a->key, b->key);
}
/** Helper: return a hash value for a strmap_entry_t. */
static INLINE unsigned int
strmap_entry_hash(const strmap_entry_t *a)
{
return (unsigned) siphash24g(a->key, strlen(a->key));
}
/** Helper: compare digestmap_entry_t objects by key value. */
static INLINE int
digestmap_entries_eq(const digestmap_entry_t *a, const digestmap_entry_t *b)
{
return tor_memeq(a->key, b->key, DIGEST_LEN);
}
/** Helper: return a hash value for a digest_map_t. */
static INLINE unsigned int
digestmap_entry_hash(const digestmap_entry_t *a)
{
return (unsigned) siphash24g(a->key, DIGEST_LEN);
}
HT_PROTOTYPE(strmap_impl, strmap_entry_t, node, strmap_entry_hash,
strmap_entries_eq)
HT_GENERATE(strmap_impl, strmap_entry_t, node, strmap_entry_hash,
strmap_entries_eq, 0.6, malloc, realloc, free)
HT_PROTOTYPE(digestmap_impl, digestmap_entry_t, node, digestmap_entry_hash,
digestmap_entries_eq)
HT_GENERATE(digestmap_impl, digestmap_entry_t, node, digestmap_entry_hash,
digestmap_entries_eq, 0.6, malloc, realloc, free)
/** Constructor to create a new empty map from strings to void*'s.
*/
strmap_t *
strmap_new(void)
{
strmap_t *result;
result = tor_malloc(sizeof(strmap_t));
HT_INIT(strmap_impl, &result->head);
return result;
}
/** Constructor to create a new empty map from digests to void*'s.
*/
digestmap_t *
digestmap_new(void)
{
digestmap_t *result;
result = tor_malloc(sizeof(digestmap_t));
HT_INIT(digestmap_impl, &result->head);
return result;
}
/** Set the current value for <b>key</b> to <b>val</b>. Returns the previous
* value for <b>key</b> if one was set, or NULL if one was not.
*
* This function makes a copy of <b>key</b> if necessary, but not of
* <b>val</b>.
*/
void *
strmap_set(strmap_t *map, const char *key, void *val)
{
strmap_entry_t *resolve;
strmap_entry_t search;
void *oldval;
tor_assert(map);
tor_assert(key);
tor_assert(val);
search.key = (char*)key;
resolve = HT_FIND(strmap_impl, &map->head, &search);
if (resolve) {
oldval = resolve->val;
resolve->val = val;
return oldval;
} else {
resolve = tor_malloc_zero(sizeof(strmap_entry_t));
resolve->key = tor_strdup(key);
resolve->val = val;
tor_assert(!HT_FIND(strmap_impl, &map->head, resolve));
HT_INSERT(strmap_impl, &map->head, resolve);
return NULL;
}
}
#define OPTIMIZED_DIGESTMAP_SET
/** Like strmap_set() above but for digestmaps. */
void *
digestmap_set(digestmap_t *map, const char *key, void *val)
{
#ifndef OPTIMIZED_DIGESTMAP_SET
digestmap_entry_t *resolve;
#endif
digestmap_entry_t search;
void *oldval;
tor_assert(map);
tor_assert(key);
tor_assert(val);
memcpy(&search.key, key, DIGEST_LEN);
#ifndef OPTIMIZED_DIGESTMAP_SET
resolve = HT_FIND(digestmap_impl, &map->head, &search);
if (resolve) {
oldval = resolve->val;
resolve->val = val;
return oldval;
} else {
resolve = tor_malloc_zero(sizeof(digestmap_entry_t));
memcpy(resolve->key, key, DIGEST_LEN);
resolve->val = val;
HT_INSERT(digestmap_impl, &map->head, resolve);
return NULL;
}
#else
/* We spend up to 5% of our time in this function, so the code below is
* meant to optimize the check/alloc/set cycle by avoiding the two trips to
* the hash table that we do in the unoptimized code above. (Each of
* HT_INSERT and HT_FIND calls HT_SET_HASH and HT_FIND_P.)
*/
HT_FIND_OR_INSERT_(digestmap_impl, node, digestmap_entry_hash, &(map->head),
digestmap_entry_t, &search, ptr,
{
/* we found an entry. */
oldval = (*ptr)->val;
(*ptr)->val = val;
return oldval;
},
{
/* We didn't find the entry. */
digestmap_entry_t *newent =
tor_malloc_zero(sizeof(digestmap_entry_t));
memcpy(newent->key, key, DIGEST_LEN);
newent->val = val;
HT_FOI_INSERT_(node, &(map->head), &search, newent, ptr);
return NULL;
});
#endif
}
/** Return the current value associated with <b>key</b>, or NULL if no
* value is set.
*/
void *
strmap_get(const strmap_t *map, const char *key)
{
strmap_entry_t *resolve;
strmap_entry_t search;
tor_assert(map);
tor_assert(key);
search.key = (char*)key;
resolve = HT_FIND(strmap_impl, &map->head, &search);
if (resolve) {
return resolve->val;
} else {
return NULL;
}
}
/** Like strmap_get() above but for digestmaps. */
void *
digestmap_get(const digestmap_t *map, const char *key)
{
digestmap_entry_t *resolve;
digestmap_entry_t search;
tor_assert(map);
tor_assert(key);
memcpy(&search.key, key, DIGEST_LEN);
resolve = HT_FIND(digestmap_impl, &map->head, &search);
if (resolve) {
return resolve->val;
} else {
return NULL;
}
}
/** Remove the value currently associated with <b>key</b> from the map.
* Return the value if one was set, or NULL if there was no entry for
* <b>key</b>.
*
* Note: you must free any storage associated with the returned value.
*/
void *
strmap_remove(strmap_t *map, const char *key)
{
strmap_entry_t *resolve;
strmap_entry_t search;
void *oldval;
tor_assert(map);
tor_assert(key);
search.key = (char*)key;
resolve = HT_REMOVE(strmap_impl, &map->head, &search);
if (resolve) {
oldval = resolve->val;
tor_free(resolve->key);
tor_free(resolve);
return oldval;
} else {
return NULL;
}
}
/** Like strmap_remove() above but for digestmaps. */
void *
digestmap_remove(digestmap_t *map, const char *key)
{
digestmap_entry_t *resolve;
digestmap_entry_t search;
void *oldval;
tor_assert(map);
tor_assert(key);
memcpy(&search.key, key, DIGEST_LEN);
resolve = HT_REMOVE(digestmap_impl, &map->head, &search);
if (resolve) {
oldval = resolve->val;
tor_free(resolve);
return oldval;
} else {
return NULL;
}
}
/** Same as strmap_set, but first converts <b>key</b> to lowercase. */
void *
strmap_set_lc(strmap_t *map, const char *key, void *val)
{
/* We could be a little faster by using strcasecmp instead, and a separate
* type, but I don't think it matters. */
void *v;
char *lc_key = tor_strdup(key);
tor_strlower(lc_key);
v = strmap_set(map,lc_key,val);
tor_free(lc_key);
return v;
}
/** Same as strmap_get, but first converts <b>key</b> to lowercase. */
void *
strmap_get_lc(const strmap_t *map, const char *key)
{
void *v;
char *lc_key = tor_strdup(key);
tor_strlower(lc_key);
v = strmap_get(map,lc_key);
tor_free(lc_key);
return v;
}
/** Same as strmap_remove, but first converts <b>key</b> to lowercase */
void *
strmap_remove_lc(strmap_t *map, const char *key)
{
void *v;
char *lc_key = tor_strdup(key);
tor_strlower(lc_key);
v = strmap_remove(map,lc_key);
tor_free(lc_key);
return v;
}
/** return an <b>iterator</b> pointer to the front of a map.
*
* Iterator example:
*
* \code
* // uppercase values in "map", removing empty values.
*
* strmap_iter_t *iter;
* const char *key;
* void *val;
* char *cp;
*
* for (iter = strmap_iter_init(map); !strmap_iter_done(iter); ) {
* strmap_iter_get(iter, &key, &val);
* cp = (char*)val;
* if (!*cp) {
* iter = strmap_iter_next_rmv(map,iter);
* free(val);
* } else {
* for (;*cp;cp++) *cp = TOR_TOUPPER(*cp);
* iter = strmap_iter_next(map,iter);
* }
* }
* \endcode
*
*/
strmap_iter_t *
strmap_iter_init(strmap_t *map)
{
tor_assert(map);
return HT_START(strmap_impl, &map->head);
}
/** Start iterating through <b>map</b>. See strmap_iter_init() for example. */
digestmap_iter_t *
digestmap_iter_init(digestmap_t *map)
{
tor_assert(map);
return HT_START(digestmap_impl, &map->head);
}
/** Advance the iterator <b>iter</b> for <b>map</b> a single step to the next
* entry, and return its new value. */
strmap_iter_t *
strmap_iter_next(strmap_t *map, strmap_iter_t *iter)
{
tor_assert(map);
tor_assert(iter);
return HT_NEXT(strmap_impl, &map->head, iter);
}
/** Advance the iterator <b>iter</b> for map a single step to the next entry,
* and return its new value. */
digestmap_iter_t *
digestmap_iter_next(digestmap_t *map, digestmap_iter_t *iter)
{
tor_assert(map);
tor_assert(iter);
return HT_NEXT(digestmap_impl, &map->head, iter);
}
/** Advance the iterator <b>iter</b> a single step to the next entry, removing
* the current entry, and return its new value.
*/
strmap_iter_t *
strmap_iter_next_rmv(strmap_t *map, strmap_iter_t *iter)
{
strmap_entry_t *rmv;
tor_assert(map);
tor_assert(iter);
tor_assert(*iter);
rmv = *iter;
iter = HT_NEXT_RMV(strmap_impl, &map->head, iter);
tor_free(rmv->key);
tor_free(rmv);
return iter;
}
/** Advance the iterator <b>iter</b> a single step to the next entry, removing
* the current entry, and return its new value.
*/
digestmap_iter_t *
digestmap_iter_next_rmv(digestmap_t *map, digestmap_iter_t *iter)
{
digestmap_entry_t *rmv;
tor_assert(map);
tor_assert(iter);
tor_assert(*iter);
rmv = *iter;
iter = HT_NEXT_RMV(digestmap_impl, &map->head, iter);
tor_free(rmv);
return iter;
}
/** Set *<b>keyp</b> and *<b>valp</b> to the current entry pointed to by
* iter. */
void
strmap_iter_get(strmap_iter_t *iter, const char **keyp, void **valp)
{
tor_assert(iter);
tor_assert(*iter);
tor_assert(keyp);
tor_assert(valp);
*keyp = (*iter)->key;
*valp = (*iter)->val;
}
/** Set *<b>keyp</b> and *<b>valp</b> to the current entry pointed to by
* iter. */
void
digestmap_iter_get(digestmap_iter_t *iter, const char **keyp, void **valp)
{
tor_assert(iter);
tor_assert(*iter);
tor_assert(keyp);
tor_assert(valp);
*keyp = (*iter)->key;
*valp = (*iter)->val;
}
/** Return true iff <b>iter</b> has advanced past the last entry of
* <b>map</b>. */
int
strmap_iter_done(strmap_iter_t *iter)
{
return iter == NULL;
}
/** Return true iff <b>iter</b> has advanced past the last entry of
* <b>map</b>. */
int
digestmap_iter_done(digestmap_iter_t *iter)
{
return iter == NULL;
}
/** Remove all entries from <b>map</b>, and deallocate storage for those
* entries. If free_val is provided, it is invoked on every value in
* <b>map</b>.
*/
void
strmap_free(strmap_t *map, void (*free_val)(void*))
{
strmap_entry_t **ent, **next, *this;
if (!map)
return;
for (ent = HT_START(strmap_impl, &map->head); ent != NULL; ent = next) {
this = *ent;
next = HT_NEXT_RMV(strmap_impl, &map->head, ent);
tor_free(this->key);
if (free_val)
free_val(this->val);
tor_free(this);
}
tor_assert(HT_EMPTY(&map->head));
HT_CLEAR(strmap_impl, &map->head);
tor_free(map);
}
/** Remove all entries from <b>map</b>, and deallocate storage for those
* entries. If free_val is provided, it is invoked on every value in
* <b>map</b>.
*/
void
digestmap_free(digestmap_t *map, void (*free_val)(void*))
{
digestmap_entry_t **ent, **next, *this;
if (!map)
return;
for (ent = HT_START(digestmap_impl, &map->head); ent != NULL; ent = next) {
this = *ent;
next = HT_NEXT_RMV(digestmap_impl, &map->head, ent);
if (free_val)
free_val(this->val);
tor_free(this);
}
tor_assert(HT_EMPTY(&map->head));
HT_CLEAR(digestmap_impl, &map->head);
tor_free(map);
}
/** Fail with an assertion error if anything has gone wrong with the internal
* representation of <b>map</b>. */
void
strmap_assert_ok(const strmap_t *map)
{
tor_assert(!strmap_impl_HT_REP_IS_BAD_(&map->head));
}
/** Fail with an assertion error if anything has gone wrong with the internal
* representation of <b>map</b>. */
void
digestmap_assert_ok(const digestmap_t *map)
{
tor_assert(!digestmap_impl_HT_REP_IS_BAD_(&map->head));
}
/** Return true iff <b>map</b> has no entries. */
int
strmap_isempty(const strmap_t *map)
{
return HT_EMPTY(&map->head);
}
/** Return true iff <b>map</b> has no entries. */
int
digestmap_isempty(const digestmap_t *map)
{
return HT_EMPTY(&map->head);
}
/** Return the number of items in <b>map</b>. */
int
strmap_size(const strmap_t *map)
{
return HT_SIZE(&map->head);
}
/** Return the number of items in <b>map</b>. */
int
digestmap_size(const digestmap_t *map)
{
return HT_SIZE(&map->head);
}
/** Declare a function called <b>funcname</b> that acts as a find_nth_FOO
* function for an array of type <b>elt_t</b>*.
*
* NOTE: The implementation kind of sucks: It's O(n log n), whereas finding
* the kth element of an n-element list can be done in O(n). Then again, this
* implementation is not in critical path, and it is obviously correct. */
#define IMPLEMENT_ORDER_FUNC(funcname, elt_t) \
static int \
_cmp_ ## elt_t(const void *_a, const void *_b) \
{ \
const elt_t *a = _a, *b = _b; \
if (*a<*b) \
return -1; \
else if (*a>*b) \
return 1; \
else \
return 0; \
} \
elt_t \
funcname(elt_t *array, int n_elements, int nth) \
{ \
tor_assert(nth >= 0); \
tor_assert(nth < n_elements); \
qsort(array, n_elements, sizeof(elt_t), _cmp_ ##elt_t); \
return array[nth]; \
}
IMPLEMENT_ORDER_FUNC(find_nth_int, int)
IMPLEMENT_ORDER_FUNC(find_nth_time, time_t)
IMPLEMENT_ORDER_FUNC(find_nth_double, double)
IMPLEMENT_ORDER_FUNC(find_nth_uint32, uint32_t)
IMPLEMENT_ORDER_FUNC(find_nth_int32, int32_t)
IMPLEMENT_ORDER_FUNC(find_nth_long, long)
/** Return a newly allocated digestset_t, optimized to hold a total of
* <b>max_elements</b> digests with a reasonably low false positive weight. */
digestset_t *
digestset_new(int max_elements)
{
/* The probability of false positives is about P=(1 - exp(-kn/m))^k, where k
* is the number of hash functions per entry, m is the bits in the array,
* and n is the number of elements inserted. For us, k==4, n<=max_elements,
* and m==n_bits= approximately max_elements*32. This gives
* P<(1-exp(-4*n/(32*n)))^4 == (1-exp(1/-8))^4 == .00019
*
* It would be more optimal in space vs false positives to get this false
* positive rate by going for k==13, and m==18.5n, but we also want to
* conserve CPU, and k==13 is pretty big.
*/
int n_bits = 1u << (tor_log2(max_elements)+5);
digestset_t *r = tor_malloc(sizeof(digestset_t));
r->mask = n_bits - 1;
r->ba = bitarray_init_zero(n_bits);
return r;
}
/** Free all storage held in <b>set</b>. */
void
digestset_free(digestset_t *set)
{
if (!set)
return;
bitarray_free(set->ba);
tor_free(set);
}
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