freebsd-skq/sys/kern/subr_unit.c
Pedro F. Giffuni 8a36da99de sys/kern: adoption of SPDX licensing ID tags.
Mainly focus on files that use BSD 2-Clause license, however the tool I
was using misidentified many licenses so this was mostly a manual - error
prone - task.

The Software Package Data Exchange (SPDX) group provides a specification
to make it easier for automated tools to detect and summarize well known
opensource licenses. We are gradually adopting the specification, noting
that the tags are considered only advisory and do not, in any way,
superceed or replace the license texts.
2017-11-27 15:20:12 +00:00

1082 lines
23 KiB
C

/*-
* SPDX-License-Identifier: BSD-2-Clause-FreeBSD
*
* Copyright (c) 2004 Poul-Henning Kamp
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*
* $FreeBSD$
*
*
* Unit number allocation functions.
*
* These functions implement a mixed run-length/bitmap management of unit
* number spaces in a very memory efficient manner.
*
* Allocation policy is always lowest free number first.
*
* A return value of -1 signals that no more unit numbers are available.
*
* There is no cost associated with the range of unitnumbers, so unless
* the resource really is finite, specify INT_MAX to new_unrhdr() and
* forget about checking the return value.
*
* If a mutex is not provided when the unit number space is created, a
* default global mutex is used. The advantage to passing a mutex in, is
* that the alloc_unrl() function can be called with the mutex already
* held (it will not be released by alloc_unrl()).
*
* The allocation function alloc_unr{l}() never sleeps (but it may block on
* the mutex of course).
*
* Freeing a unit number may require allocating memory, and can therefore
* sleep so the free_unr() function does not come in a pre-locked variant.
*
* A userland test program is included.
*
* Memory usage is a very complex function of the exact allocation
* pattern, but always very compact:
* * For the very typical case where a single unbroken run of unit
* numbers are allocated 44 bytes are used on i386.
* * For a unit number space of 1000 units and the random pattern
* in the usermode test program included, the worst case usage
* was 252 bytes on i386 for 500 allocated and 500 free units.
* * For a unit number space of 10000 units and the random pattern
* in the usermode test program included, the worst case usage
* was 798 bytes on i386 for 5000 allocated and 5000 free units.
* * The worst case is where every other unit number is allocated and
* the rest are free. In that case 44 + N/4 bytes are used where
* N is the number of the highest unit allocated.
*/
#include <sys/param.h>
#include <sys/types.h>
#include <sys/_unrhdr.h>
#ifdef _KERNEL
#include <sys/bitstring.h>
#include <sys/malloc.h>
#include <sys/kernel.h>
#include <sys/systm.h>
#include <sys/limits.h>
#include <sys/lock.h>
#include <sys/mutex.h>
/*
* In theory it would be smarter to allocate the individual blocks
* with the zone allocator, but at this time the expectation is that
* there will typically not even be enough allocations to fill a single
* page, so we stick with malloc for now.
*/
static MALLOC_DEFINE(M_UNIT, "Unitno", "Unit number allocation");
#define Malloc(foo) malloc(foo, M_UNIT, M_WAITOK | M_ZERO)
#define Free(foo) free(foo, M_UNIT)
static struct mtx unitmtx;
MTX_SYSINIT(unit, &unitmtx, "unit# allocation", MTX_DEF);
#else /* ...USERLAND */
#include <bitstring.h>
#include <err.h>
#include <errno.h>
#include <getopt.h>
#include <stdbool.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#define KASSERT(cond, arg) \
do { \
if (!(cond)) { \
printf arg; \
abort(); \
} \
} while (0)
static int no_alloc;
#define Malloc(foo) _Malloc(foo, __LINE__)
static void *
_Malloc(size_t foo, int line)
{
KASSERT(no_alloc == 0, ("malloc in wrong place() line %d", line));
return (calloc(foo, 1));
}
#define Free(foo) free(foo)
struct unrhdr;
struct mtx {
int state;
} unitmtx;
static void
mtx_lock(struct mtx *mp)
{
KASSERT(mp->state == 0, ("mutex already locked"));
mp->state = 1;
}
static void
mtx_unlock(struct mtx *mp)
{
KASSERT(mp->state == 1, ("mutex not locked"));
mp->state = 0;
}
#define MA_OWNED 9
static void
mtx_assert(struct mtx *mp, int flag)
{
if (flag == MA_OWNED) {
KASSERT(mp->state == 1, ("mtx_assert(MA_OWNED) not true"));
}
}
#define CTASSERT(foo)
#define WITNESS_WARN(flags, lock, fmt, ...) (void)0
#endif /* USERLAND */
/*
* This is our basic building block.
*
* It can be used in three different ways depending on the value of the ptr
* element:
* If ptr is NULL, it represents a run of free items.
* If ptr points to the unrhdr it represents a run of allocated items.
* Otherwise it points to a bitstring of allocated items.
*
* For runs the len field is the length of the run.
* For bitmaps the len field represents the number of allocated items.
*
* The bitmap is the same size as struct unr to optimize memory management.
*/
struct unr {
TAILQ_ENTRY(unr) list;
u_int len;
void *ptr;
};
struct unrb {
bitstr_t map[sizeof(struct unr) / sizeof(bitstr_t)];
};
CTASSERT((sizeof(struct unr) % sizeof(bitstr_t)) == 0);
/* Number of bits we can store in the bitmap */
#define NBITS (8 * sizeof(((struct unrb*)NULL)->map))
/* Is the unrb empty in at least the first len bits? */
static inline bool
ub_empty(struct unrb *ub, int len) {
int first_set;
bit_ffs(ub->map, len, &first_set);
return (first_set == -1);
}
/* Is the unrb full? That is, is the number of set elements equal to len? */
static inline bool
ub_full(struct unrb *ub, int len)
{
int first_clear;
bit_ffc(ub->map, len, &first_clear);
return (first_clear == -1);
}
#if defined(DIAGNOSTIC) || !defined(_KERNEL)
/*
* Consistency check function.
*
* Checks the internal consistency as well as we can.
*
* Called at all boundaries of this API.
*/
static void
check_unrhdr(struct unrhdr *uh, int line)
{
struct unr *up;
struct unrb *ub;
int w;
u_int y, z;
y = uh->first;
z = 0;
TAILQ_FOREACH(up, &uh->head, list) {
z++;
if (up->ptr != uh && up->ptr != NULL) {
ub = up->ptr;
KASSERT (up->len <= NBITS,
("UNR inconsistency: len %u max %zd (line %d)\n",
up->len, NBITS, line));
z++;
w = 0;
bit_count(ub->map, 0, up->len, &w);
y += w;
} else if (up->ptr != NULL)
y += up->len;
}
KASSERT (y == uh->busy,
("UNR inconsistency: items %u found %u (line %d)\n",
uh->busy, y, line));
KASSERT (z == uh->alloc,
("UNR inconsistency: chunks %u found %u (line %d)\n",
uh->alloc, z, line));
}
#else
static __inline void
check_unrhdr(struct unrhdr *uh __unused, int line __unused)
{
}
#endif
/*
* Userland memory management. Just use calloc and keep track of how
* many elements we have allocated for check_unrhdr().
*/
static __inline void *
new_unr(struct unrhdr *uh, void **p1, void **p2)
{
void *p;
uh->alloc++;
KASSERT(*p1 != NULL || *p2 != NULL, ("Out of cached memory"));
if (*p1 != NULL) {
p = *p1;
*p1 = NULL;
return (p);
} else {
p = *p2;
*p2 = NULL;
return (p);
}
}
static __inline void
delete_unr(struct unrhdr *uh, void *ptr)
{
struct unr *up;
uh->alloc--;
up = ptr;
TAILQ_INSERT_TAIL(&uh->ppfree, up, list);
}
void
clean_unrhdrl(struct unrhdr *uh)
{
struct unr *up;
mtx_assert(uh->mtx, MA_OWNED);
while ((up = TAILQ_FIRST(&uh->ppfree)) != NULL) {
TAILQ_REMOVE(&uh->ppfree, up, list);
mtx_unlock(uh->mtx);
Free(up);
mtx_lock(uh->mtx);
}
}
void
clean_unrhdr(struct unrhdr *uh)
{
mtx_lock(uh->mtx);
clean_unrhdrl(uh);
mtx_unlock(uh->mtx);
}
void
init_unrhdr(struct unrhdr *uh, int low, int high, struct mtx *mutex)
{
KASSERT(low >= 0 && low <= high,
("UNR: use error: new_unrhdr(%d, %d)", low, high));
if (mutex != NULL)
uh->mtx = mutex;
else
uh->mtx = &unitmtx;
TAILQ_INIT(&uh->head);
TAILQ_INIT(&uh->ppfree);
uh->low = low;
uh->high = high;
uh->first = 0;
uh->last = 1 + (high - low);
check_unrhdr(uh, __LINE__);
}
/*
* Allocate a new unrheader set.
*
* Highest and lowest valid values given as parameters.
*/
struct unrhdr *
new_unrhdr(int low, int high, struct mtx *mutex)
{
struct unrhdr *uh;
uh = Malloc(sizeof *uh);
init_unrhdr(uh, low, high, mutex);
return (uh);
}
void
delete_unrhdr(struct unrhdr *uh)
{
check_unrhdr(uh, __LINE__);
KASSERT(uh->busy == 0, ("unrhdr has %u allocations", uh->busy));
KASSERT(uh->alloc == 0, ("UNR memory leak in delete_unrhdr"));
KASSERT(TAILQ_FIRST(&uh->ppfree) == NULL,
("unrhdr has postponed item for free"));
Free(uh);
}
void
clear_unrhdr(struct unrhdr *uh)
{
struct unr *up, *uq;
KASSERT(TAILQ_EMPTY(&uh->ppfree),
("unrhdr has postponed item for free"));
TAILQ_FOREACH_SAFE(up, &uh->head, list, uq) {
if (up->ptr != uh) {
Free(up->ptr);
}
Free(up);
}
uh->busy = 0;
uh->alloc = 0;
init_unrhdr(uh, uh->low, uh->high, uh->mtx);
check_unrhdr(uh, __LINE__);
}
static __inline int
is_bitmap(struct unrhdr *uh, struct unr *up)
{
return (up->ptr != uh && up->ptr != NULL);
}
/*
* Look for sequence of items which can be combined into a bitmap, if
* multiple are present, take the one which saves most memory.
*
* Return (1) if a sequence was found to indicate that another call
* might be able to do more. Return (0) if we found no suitable sequence.
*
* NB: called from alloc_unr(), no new memory allocation allowed.
*/
static int
optimize_unr(struct unrhdr *uh)
{
struct unr *up, *uf, *us;
struct unrb *ub, *ubf;
u_int a, l, ba;
/*
* Look for the run of items (if any) which when collapsed into
* a bitmap would save most memory.
*/
us = NULL;
ba = 0;
TAILQ_FOREACH(uf, &uh->head, list) {
if (uf->len >= NBITS)
continue;
a = 1;
if (is_bitmap(uh, uf))
a++;
l = uf->len;
up = uf;
while (1) {
up = TAILQ_NEXT(up, list);
if (up == NULL)
break;
if ((up->len + l) > NBITS)
break;
a++;
if (is_bitmap(uh, up))
a++;
l += up->len;
}
if (a > ba) {
ba = a;
us = uf;
}
}
if (ba < 3)
return (0);
/*
* If the first element is not a bitmap, make it one.
* Trying to do so without allocating more memory complicates things
* a bit
*/
if (!is_bitmap(uh, us)) {
uf = TAILQ_NEXT(us, list);
TAILQ_REMOVE(&uh->head, us, list);
a = us->len;
l = us->ptr == uh ? 1 : 0;
ub = (void *)us;
bit_nclear(ub->map, 0, NBITS - 1);
if (l)
bit_nset(ub->map, 0, a);
if (!is_bitmap(uh, uf)) {
if (uf->ptr == NULL)
bit_nclear(ub->map, a, a + uf->len - 1);
else
bit_nset(ub->map, a, a + uf->len - 1);
uf->ptr = ub;
uf->len += a;
us = uf;
} else {
ubf = uf->ptr;
for (l = 0; l < uf->len; l++, a++) {
if (bit_test(ubf->map, l))
bit_set(ub->map, a);
else
bit_clear(ub->map, a);
}
uf->len = a;
delete_unr(uh, uf->ptr);
uf->ptr = ub;
us = uf;
}
}
ub = us->ptr;
while (1) {
uf = TAILQ_NEXT(us, list);
if (uf == NULL)
return (1);
if (uf->len + us->len > NBITS)
return (1);
if (uf->ptr == NULL) {
bit_nclear(ub->map, us->len, us->len + uf->len - 1);
us->len += uf->len;
TAILQ_REMOVE(&uh->head, uf, list);
delete_unr(uh, uf);
} else if (uf->ptr == uh) {
bit_nset(ub->map, us->len, us->len + uf->len - 1);
us->len += uf->len;
TAILQ_REMOVE(&uh->head, uf, list);
delete_unr(uh, uf);
} else {
ubf = uf->ptr;
for (l = 0; l < uf->len; l++, us->len++) {
if (bit_test(ubf->map, l))
bit_set(ub->map, us->len);
else
bit_clear(ub->map, us->len);
}
TAILQ_REMOVE(&uh->head, uf, list);
delete_unr(uh, ubf);
delete_unr(uh, uf);
}
}
}
/*
* See if a given unr should be collapsed with a neighbor.
*
* NB: called from alloc_unr(), no new memory allocation allowed.
*/
static void
collapse_unr(struct unrhdr *uh, struct unr *up)
{
struct unr *upp;
struct unrb *ub;
/* If bitmap is all set or clear, change it to runlength */
if (is_bitmap(uh, up)) {
ub = up->ptr;
if (ub_full(ub, up->len)) {
delete_unr(uh, up->ptr);
up->ptr = uh;
} else if (ub_empty(ub, up->len)) {
delete_unr(uh, up->ptr);
up->ptr = NULL;
}
}
/* If nothing left in runlength, delete it */
if (up->len == 0) {
upp = TAILQ_PREV(up, unrhd, list);
if (upp == NULL)
upp = TAILQ_NEXT(up, list);
TAILQ_REMOVE(&uh->head, up, list);
delete_unr(uh, up);
up = upp;
}
/* If we have "hot-spot" still, merge with neighbor if possible */
if (up != NULL) {
upp = TAILQ_PREV(up, unrhd, list);
if (upp != NULL && up->ptr == upp->ptr) {
up->len += upp->len;
TAILQ_REMOVE(&uh->head, upp, list);
delete_unr(uh, upp);
}
upp = TAILQ_NEXT(up, list);
if (upp != NULL && up->ptr == upp->ptr) {
up->len += upp->len;
TAILQ_REMOVE(&uh->head, upp, list);
delete_unr(uh, upp);
}
}
/* Merge into ->first if possible */
upp = TAILQ_FIRST(&uh->head);
if (upp != NULL && upp->ptr == uh) {
uh->first += upp->len;
TAILQ_REMOVE(&uh->head, upp, list);
delete_unr(uh, upp);
if (up == upp)
up = NULL;
}
/* Merge into ->last if possible */
upp = TAILQ_LAST(&uh->head, unrhd);
if (upp != NULL && upp->ptr == NULL) {
uh->last += upp->len;
TAILQ_REMOVE(&uh->head, upp, list);
delete_unr(uh, upp);
if (up == upp)
up = NULL;
}
/* Try to make bitmaps */
while (optimize_unr(uh))
continue;
}
/*
* Allocate a free unr.
*/
int
alloc_unrl(struct unrhdr *uh)
{
struct unr *up;
struct unrb *ub;
u_int x;
int y;
mtx_assert(uh->mtx, MA_OWNED);
check_unrhdr(uh, __LINE__);
x = uh->low + uh->first;
up = TAILQ_FIRST(&uh->head);
/*
* If we have an ideal split, just adjust the first+last
*/
if (up == NULL && uh->last > 0) {
uh->first++;
uh->last--;
uh->busy++;
return (x);
}
/*
* We can always allocate from the first list element, so if we have
* nothing on the list, we must have run out of unit numbers.
*/
if (up == NULL)
return (-1);
KASSERT(up->ptr != uh, ("UNR first element is allocated"));
if (up->ptr == NULL) { /* free run */
uh->first++;
up->len--;
} else { /* bitmap */
ub = up->ptr;
bit_ffc(ub->map, up->len, &y);
KASSERT(y != -1, ("UNR corruption: No clear bit in bitmap."));
bit_set(ub->map, y);
x += y;
}
uh->busy++;
collapse_unr(uh, up);
return (x);
}
int
alloc_unr(struct unrhdr *uh)
{
int i;
mtx_lock(uh->mtx);
i = alloc_unrl(uh);
clean_unrhdrl(uh);
mtx_unlock(uh->mtx);
return (i);
}
static int
alloc_unr_specificl(struct unrhdr *uh, u_int item, void **p1, void **p2)
{
struct unr *up, *upn;
struct unrb *ub;
u_int i, last, tl;
mtx_assert(uh->mtx, MA_OWNED);
if (item < uh->low + uh->first || item > uh->high)
return (-1);
up = TAILQ_FIRST(&uh->head);
/* Ideal split. */
if (up == NULL && item - uh->low == uh->first) {
uh->first++;
uh->last--;
uh->busy++;
check_unrhdr(uh, __LINE__);
return (item);
}
i = item - uh->low - uh->first;
if (up == NULL) {
up = new_unr(uh, p1, p2);
up->ptr = NULL;
up->len = i;
TAILQ_INSERT_TAIL(&uh->head, up, list);
up = new_unr(uh, p1, p2);
up->ptr = uh;
up->len = 1;
TAILQ_INSERT_TAIL(&uh->head, up, list);
uh->last = uh->high - uh->low - i;
uh->busy++;
check_unrhdr(uh, __LINE__);
return (item);
} else {
/* Find the item which contains the unit we want to allocate. */
TAILQ_FOREACH(up, &uh->head, list) {
if (up->len > i)
break;
i -= up->len;
}
}
if (up == NULL) {
if (i > 0) {
up = new_unr(uh, p1, p2);
up->ptr = NULL;
up->len = i;
TAILQ_INSERT_TAIL(&uh->head, up, list);
}
up = new_unr(uh, p1, p2);
up->ptr = uh;
up->len = 1;
TAILQ_INSERT_TAIL(&uh->head, up, list);
goto done;
}
if (is_bitmap(uh, up)) {
ub = up->ptr;
if (bit_test(ub->map, i) == 0) {
bit_set(ub->map, i);
goto done;
} else
return (-1);
} else if (up->ptr == uh)
return (-1);
KASSERT(up->ptr == NULL,
("alloc_unr_specificl: up->ptr != NULL (up=%p)", up));
/* Split off the tail end, if any. */
tl = up->len - (1 + i);
if (tl > 0) {
upn = new_unr(uh, p1, p2);
upn->ptr = NULL;
upn->len = tl;
TAILQ_INSERT_AFTER(&uh->head, up, upn, list);
}
/* Split off head end, if any */
if (i > 0) {
upn = new_unr(uh, p1, p2);
upn->len = i;
upn->ptr = NULL;
TAILQ_INSERT_BEFORE(up, upn, list);
}
up->len = 1;
up->ptr = uh;
done:
last = uh->high - uh->low - (item - uh->low);
if (uh->last > last)
uh->last = last;
uh->busy++;
collapse_unr(uh, up);
check_unrhdr(uh, __LINE__);
return (item);
}
int
alloc_unr_specific(struct unrhdr *uh, u_int item)
{
void *p1, *p2;
int i;
WITNESS_WARN(WARN_GIANTOK | WARN_SLEEPOK, NULL, "alloc_unr_specific");
p1 = Malloc(sizeof(struct unr));
p2 = Malloc(sizeof(struct unr));
mtx_lock(uh->mtx);
i = alloc_unr_specificl(uh, item, &p1, &p2);
mtx_unlock(uh->mtx);
if (p1 != NULL)
Free(p1);
if (p2 != NULL)
Free(p2);
return (i);
}
/*
* Free a unr.
*
* If we can save unrs by using a bitmap, do so.
*/
static void
free_unrl(struct unrhdr *uh, u_int item, void **p1, void **p2)
{
struct unr *up, *upp, *upn;
struct unrb *ub;
u_int pl;
KASSERT(item >= uh->low && item <= uh->high,
("UNR: free_unr(%u) out of range [%u...%u]",
item, uh->low, uh->high));
check_unrhdr(uh, __LINE__);
item -= uh->low;
upp = TAILQ_FIRST(&uh->head);
/*
* Freeing in the ideal split case
*/
if (item + 1 == uh->first && upp == NULL) {
uh->last++;
uh->first--;
uh->busy--;
check_unrhdr(uh, __LINE__);
return;
}
/*
* Freeing in the ->first section. Create a run starting at the
* freed item. The code below will subdivide it.
*/
if (item < uh->first) {
up = new_unr(uh, p1, p2);
up->ptr = uh;
up->len = uh->first - item;
TAILQ_INSERT_HEAD(&uh->head, up, list);
uh->first -= up->len;
}
item -= uh->first;
/* Find the item which contains the unit we want to free */
TAILQ_FOREACH(up, &uh->head, list) {
if (up->len > item)
break;
item -= up->len;
}
/* Handle bitmap items */
if (is_bitmap(uh, up)) {
ub = up->ptr;
KASSERT(bit_test(ub->map, item) != 0,
("UNR: Freeing free item %d (bitmap)\n", item));
bit_clear(ub->map, item);
uh->busy--;
collapse_unr(uh, up);
return;
}
KASSERT(up->ptr == uh, ("UNR Freeing free item %d (run))\n", item));
/* Just this one left, reap it */
if (up->len == 1) {
up->ptr = NULL;
uh->busy--;
collapse_unr(uh, up);
return;
}
/* Check if we can shift the item into the previous 'free' run */
upp = TAILQ_PREV(up, unrhd, list);
if (item == 0 && upp != NULL && upp->ptr == NULL) {
upp->len++;
up->len--;
uh->busy--;
collapse_unr(uh, up);
return;
}
/* Check if we can shift the item to the next 'free' run */
upn = TAILQ_NEXT(up, list);
if (item == up->len - 1 && upn != NULL && upn->ptr == NULL) {
upn->len++;
up->len--;
uh->busy--;
collapse_unr(uh, up);
return;
}
/* Split off the tail end, if any. */
pl = up->len - (1 + item);
if (pl > 0) {
upp = new_unr(uh, p1, p2);
upp->ptr = uh;
upp->len = pl;
TAILQ_INSERT_AFTER(&uh->head, up, upp, list);
}
/* Split off head end, if any */
if (item > 0) {
upp = new_unr(uh, p1, p2);
upp->len = item;
upp->ptr = uh;
TAILQ_INSERT_BEFORE(up, upp, list);
}
up->len = 1;
up->ptr = NULL;
uh->busy--;
collapse_unr(uh, up);
}
void
free_unr(struct unrhdr *uh, u_int item)
{
void *p1, *p2;
WITNESS_WARN(WARN_GIANTOK | WARN_SLEEPOK, NULL, "free_unr");
p1 = Malloc(sizeof(struct unr));
p2 = Malloc(sizeof(struct unr));
mtx_lock(uh->mtx);
free_unrl(uh, item, &p1, &p2);
clean_unrhdrl(uh);
mtx_unlock(uh->mtx);
if (p1 != NULL)
Free(p1);
if (p2 != NULL)
Free(p2);
}
#ifndef _KERNEL /* USERLAND test driver */
/*
* Simple stochastic test driver for the above functions. The code resides
* here so that it can access static functions and structures.
*/
static bool verbose;
#define VPRINTF(...) {if (verbose) printf(__VA_ARGS__);}
static void
print_unr(struct unrhdr *uh, struct unr *up)
{
u_int x;
struct unrb *ub;
printf(" %p len = %5u ", up, up->len);
if (up->ptr == NULL)
printf("free\n");
else if (up->ptr == uh)
printf("alloc\n");
else {
ub = up->ptr;
printf("bitmap [");
for (x = 0; x < up->len; x++) {
if (bit_test(ub->map, x))
printf("#");
else
printf(" ");
}
printf("]\n");
}
}
static void
print_unrhdr(struct unrhdr *uh)
{
struct unr *up;
u_int x;
printf(
"%p low = %u high = %u first = %u last = %u busy %u chunks = %u\n",
uh, uh->low, uh->high, uh->first, uh->last, uh->busy, uh->alloc);
x = uh->low + uh->first;
TAILQ_FOREACH(up, &uh->head, list) {
printf(" from = %5u", x);
print_unr(uh, up);
if (up->ptr == NULL || up->ptr == uh)
x += up->len;
else
x += NBITS;
}
}
static void
test_alloc_unr(struct unrhdr *uh, u_int i, char a[])
{
int j;
if (a[i]) {
VPRINTF("F %u\n", i);
free_unr(uh, i);
a[i] = 0;
} else {
no_alloc = 1;
j = alloc_unr(uh);
if (j != -1) {
a[j] = 1;
VPRINTF("A %d\n", j);
}
no_alloc = 0;
}
}
static void
test_alloc_unr_specific(struct unrhdr *uh, u_int i, char a[])
{
int j;
j = alloc_unr_specific(uh, i);
if (j == -1) {
VPRINTF("F %u\n", i);
a[i] = 0;
free_unr(uh, i);
} else {
a[i] = 1;
VPRINTF("A %d\n", j);
}
}
static void
usage(char** argv)
{
printf("%s [-h] [-r REPETITIONS] [-v]\n", argv[0]);
}
int
main(int argc, char **argv)
{
struct unrhdr *uh;
char *a;
long count = 10000; /* Number of unrs to test */
long reps = 1, m;
int ch;
u_int i, j;
verbose = false;
while ((ch = getopt(argc, argv, "hr:v")) != -1) {
switch (ch) {
case 'r':
errno = 0;
reps = strtol(optarg, NULL, 0);
if (errno == ERANGE || errno == EINVAL) {
usage(argv);
exit(2);
}
break;
case 'v':
verbose = true;
break;
case 'h':
default:
usage(argv);
exit(2);
}
}
setbuf(stdout, NULL);
uh = new_unrhdr(0, count - 1, NULL);
print_unrhdr(uh);
a = calloc(count, sizeof(char));
if (a == NULL)
err(1, "calloc failed");
srandomdev();
printf("sizeof(struct unr) %zu\n", sizeof(struct unr));
printf("sizeof(struct unrb) %zu\n", sizeof(struct unrb));
printf("sizeof(struct unrhdr) %zu\n", sizeof(struct unrhdr));
printf("NBITS %lu\n", (unsigned long)NBITS);
for (m = 0; m < count * reps; m++) {
j = random();
i = (j >> 1) % count;
#if 0
if (a[i] && (j & 1))
continue;
#endif
if ((random() & 1) != 0)
test_alloc_unr(uh, i, a);
else
test_alloc_unr_specific(uh, i, a);
if (verbose)
print_unrhdr(uh);
check_unrhdr(uh, __LINE__);
}
for (i = 0; i < (u_int)count; i++) {
if (a[i]) {
if (verbose) {
printf("C %u\n", i);
print_unrhdr(uh);
}
free_unr(uh, i);
}
}
print_unrhdr(uh);
delete_unrhdr(uh);
free(a);
return (0);
}
#endif