1
0
mirror of https://git.FreeBSD.org/src.git synced 2024-12-29 12:03:03 +00:00
freebsd/sys/kern/subr_rman.c
John Baldwin bb82622c3e Extend the rman(9) API to support altering an existing resource.
Specifically, these changes allow a resource to back a relocatable and
resizable resource such as the I/O window decoders in PCI-PCI bridges.
- rman_adjust_resource() can adjust the start and end address of an
  existing resource.  It only succeeds if the newly requested address
  space is already free.  It also supports shrinking a resource in
  which case the freed space will be marked unallocated in the rman.
- rman_first_free_region() and rman_last_free_region() return the
  start and end addresses for the first or last unallocated region in
  an rman, respectively.  This can be used to determine by how much
  the resource backing an rman must be adjusted to accomodate an
  allocation request that does not fit into the existing rman.

While here, document the rm_start and rm_end fields in struct rman,
rman_is_region_manager(), the bound argument to
rman_reserve_resource_bound(), and rman_init_from_resource().
2011-04-29 20:05:19 +00:00

1155 lines
28 KiB
C

/*-
* Copyright 1998 Massachusetts Institute of Technology
*
* Permission to use, copy, modify, and distribute this software and
* its documentation for any purpose and without fee is hereby
* granted, provided that both the above copyright notice and this
* permission notice appear in all copies, that both the above
* copyright notice and this permission notice appear in all
* supporting documentation, and that the name of M.I.T. not be used
* in advertising or publicity pertaining to distribution of the
* software without specific, written prior permission. M.I.T. makes
* no representations about the suitability of this software for any
* purpose. It is provided "as is" without express or implied
* warranty.
*
* THIS SOFTWARE IS PROVIDED BY M.I.T. ``AS IS''. M.I.T. DISCLAIMS
* ALL EXPRESS OR IMPLIED WARRANTIES WITH REGARD TO THIS SOFTWARE,
* INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE. IN NO EVENT
* SHALL M.I.T. 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.
*/
/*
* The kernel resource manager. This code is responsible for keeping track
* of hardware resources which are apportioned out to various drivers.
* It does not actually assign those resources, and it is not expected
* that end-device drivers will call into this code directly. Rather,
* the code which implements the buses that those devices are attached to,
* and the code which manages CPU resources, will call this code, and the
* end-device drivers will make upcalls to that code to actually perform
* the allocation.
*
* There are two sorts of resources managed by this code. The first is
* the more familiar array (RMAN_ARRAY) type; resources in this class
* consist of a sequence of individually-allocatable objects which have
* been numbered in some well-defined order. Most of the resources
* are of this type, as it is the most familiar. The second type is
* called a gauge (RMAN_GAUGE), and models fungible resources (i.e.,
* resources in which each instance is indistinguishable from every
* other instance). The principal anticipated application of gauges
* is in the context of power consumption, where a bus may have a specific
* power budget which all attached devices share. RMAN_GAUGE is not
* implemented yet.
*
* For array resources, we make one simplifying assumption: two clients
* sharing the same resource must use the same range of indices. That
* is to say, sharing of overlapping-but-not-identical regions is not
* permitted.
*/
#include "opt_ddb.h"
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/kernel.h>
#include <sys/limits.h>
#include <sys/lock.h>
#include <sys/malloc.h>
#include <sys/mutex.h>
#include <sys/bus.h> /* XXX debugging */
#include <machine/bus.h>
#include <sys/rman.h>
#include <sys/sysctl.h>
#ifdef DDB
#include <ddb/ddb.h>
#endif
/*
* We use a linked list rather than a bitmap because we need to be able to
* represent potentially huge objects (like all of a processor's physical
* address space). That is also why the indices are defined to have type
* `unsigned long' -- that being the largest integral type in ISO C (1990).
* The 1999 version of C allows `long long'; we may need to switch to that
* at some point in the future, particularly if we want to support 36-bit
* addresses on IA32 hardware.
*/
struct resource_i {
struct resource r_r;
TAILQ_ENTRY(resource_i) r_link;
LIST_ENTRY(resource_i) r_sharelink;
LIST_HEAD(, resource_i) *r_sharehead;
u_long r_start; /* index of the first entry in this resource */
u_long r_end; /* index of the last entry (inclusive) */
u_int r_flags;
void *r_virtual; /* virtual address of this resource */
struct device *r_dev; /* device which has allocated this resource */
struct rman *r_rm; /* resource manager from whence this came */
int r_rid; /* optional rid for this resource. */
};
static int rman_debug = 0;
TUNABLE_INT("debug.rman_debug", &rman_debug);
SYSCTL_INT(_debug, OID_AUTO, rman_debug, CTLFLAG_RW,
&rman_debug, 0, "rman debug");
#define DPRINTF(params) if (rman_debug) printf params
static MALLOC_DEFINE(M_RMAN, "rman", "Resource manager");
struct rman_head rman_head;
static struct mtx rman_mtx; /* mutex to protect rman_head */
static int int_rman_activate_resource(struct rman *rm, struct resource_i *r,
struct resource_i **whohas);
static int int_rman_deactivate_resource(struct resource_i *r);
static int int_rman_release_resource(struct rman *rm, struct resource_i *r);
static __inline struct resource_i *
int_alloc_resource(int malloc_flag)
{
struct resource_i *r;
r = malloc(sizeof *r, M_RMAN, malloc_flag | M_ZERO);
if (r != NULL) {
r->r_r.__r_i = r;
}
return (r);
}
int
rman_init(struct rman *rm)
{
static int once = 0;
if (once == 0) {
once = 1;
TAILQ_INIT(&rman_head);
mtx_init(&rman_mtx, "rman head", NULL, MTX_DEF);
}
if (rm->rm_start == 0 && rm->rm_end == 0)
rm->rm_end = ~0ul;
if (rm->rm_type == RMAN_UNINIT)
panic("rman_init");
if (rm->rm_type == RMAN_GAUGE)
panic("implement RMAN_GAUGE");
TAILQ_INIT(&rm->rm_list);
rm->rm_mtx = malloc(sizeof *rm->rm_mtx, M_RMAN, M_NOWAIT | M_ZERO);
if (rm->rm_mtx == NULL)
return ENOMEM;
mtx_init(rm->rm_mtx, "rman", NULL, MTX_DEF);
mtx_lock(&rman_mtx);
TAILQ_INSERT_TAIL(&rman_head, rm, rm_link);
mtx_unlock(&rman_mtx);
return 0;
}
int
rman_manage_region(struct rman *rm, u_long start, u_long end)
{
struct resource_i *r, *s, *t;
DPRINTF(("rman_manage_region: <%s> request: start %#lx, end %#lx\n",
rm->rm_descr, start, end));
if (start < rm->rm_start || end > rm->rm_end)
return EINVAL;
r = int_alloc_resource(M_NOWAIT);
if (r == NULL)
return ENOMEM;
r->r_start = start;
r->r_end = end;
r->r_rm = rm;
mtx_lock(rm->rm_mtx);
/* Skip entries before us. */
TAILQ_FOREACH(s, &rm->rm_list, r_link) {
if (s->r_end == ULONG_MAX)
break;
if (s->r_end + 1 >= r->r_start)
break;
}
/* If we ran off the end of the list, insert at the tail. */
if (s == NULL) {
TAILQ_INSERT_TAIL(&rm->rm_list, r, r_link);
} else {
/* Check for any overlap with the current region. */
if (r->r_start <= s->r_end && r->r_end >= s->r_start)
return EBUSY;
/* Check for any overlap with the next region. */
t = TAILQ_NEXT(s, r_link);
if (t && r->r_start <= t->r_end && r->r_end >= t->r_start)
return EBUSY;
/*
* See if this region can be merged with the next region. If
* not, clear the pointer.
*/
if (t && (r->r_end + 1 != t->r_start || t->r_flags != 0))
t = NULL;
/* See if we can merge with the current region. */
if (s->r_end + 1 == r->r_start && s->r_flags == 0) {
/* Can we merge all 3 regions? */
if (t != NULL) {
s->r_end = t->r_end;
TAILQ_REMOVE(&rm->rm_list, t, r_link);
free(r, M_RMAN);
free(t, M_RMAN);
} else {
s->r_end = r->r_end;
free(r, M_RMAN);
}
} else if (t != NULL) {
/* Can we merge with just the next region? */
t->r_start = r->r_start;
free(r, M_RMAN);
} else if (s->r_end < r->r_start) {
TAILQ_INSERT_AFTER(&rm->rm_list, s, r, r_link);
} else {
TAILQ_INSERT_BEFORE(s, r, r_link);
}
}
mtx_unlock(rm->rm_mtx);
return 0;
}
int
rman_init_from_resource(struct rman *rm, struct resource *r)
{
int rv;
if ((rv = rman_init(rm)) != 0)
return (rv);
return (rman_manage_region(rm, r->__r_i->r_start, r->__r_i->r_end));
}
int
rman_fini(struct rman *rm)
{
struct resource_i *r;
mtx_lock(rm->rm_mtx);
TAILQ_FOREACH(r, &rm->rm_list, r_link) {
if (r->r_flags & RF_ALLOCATED) {
mtx_unlock(rm->rm_mtx);
return EBUSY;
}
}
/*
* There really should only be one of these if we are in this
* state and the code is working properly, but it can't hurt.
*/
while (!TAILQ_EMPTY(&rm->rm_list)) {
r = TAILQ_FIRST(&rm->rm_list);
TAILQ_REMOVE(&rm->rm_list, r, r_link);
free(r, M_RMAN);
}
mtx_unlock(rm->rm_mtx);
mtx_lock(&rman_mtx);
TAILQ_REMOVE(&rman_head, rm, rm_link);
mtx_unlock(&rman_mtx);
mtx_destroy(rm->rm_mtx);
free(rm->rm_mtx, M_RMAN);
return 0;
}
int
rman_first_free_region(struct rman *rm, u_long *start, u_long *end)
{
struct resource_i *r;
mtx_lock(rm->rm_mtx);
TAILQ_FOREACH(r, &rm->rm_list, r_link) {
if (!(r->r_flags & RF_ALLOCATED)) {
*start = r->r_start;
*end = r->r_end;
mtx_unlock(rm->rm_mtx);
return (0);
}
}
mtx_unlock(rm->rm_mtx);
return (ENOENT);
}
int
rman_last_free_region(struct rman *rm, u_long *start, u_long *end)
{
struct resource_i *r;
mtx_lock(rm->rm_mtx);
TAILQ_FOREACH_REVERSE(r, &rm->rm_list, resource_head, r_link) {
if (!(r->r_flags & RF_ALLOCATED)) {
*start = r->r_start;
*end = r->r_end;
mtx_unlock(rm->rm_mtx);
return (0);
}
}
mtx_unlock(rm->rm_mtx);
return (ENOENT);
}
/* Shrink or extend one or both ends of an allocated resource. */
int
rman_adjust_resource(struct resource *rr, u_long start, u_long end)
{
struct resource_i *r, *s, *t, *new;
struct rman *rm;
/* Not supported for shared resources. */
r = rr->__r_i;
if (r->r_flags & (RF_TIMESHARE | RF_SHAREABLE))
return (EINVAL);
/*
* This does not support wholesale moving of a resource. At
* least part of the desired new range must overlap with the
* existing resource.
*/
if (end < r->r_start || r->r_end < start)
return (EINVAL);
/*
* Find the two resource regions immediately adjacent to the
* allocated resource.
*/
rm = r->r_rm;
mtx_lock(rm->rm_mtx);
#ifdef INVARIANTS
TAILQ_FOREACH(s, &rm->rm_list, r_link) {
if (s == r)
break;
}
if (s == NULL)
panic("resource not in list");
#endif
s = TAILQ_PREV(r, resource_head, r_link);
t = TAILQ_NEXT(r, r_link);
KASSERT(s == NULL || s->r_end + 1 == r->r_start,
("prev resource mismatch"));
KASSERT(t == NULL || r->r_end + 1 == t->r_start,
("next resource mismatch"));
/*
* See if the changes are permitted. Shrinking is always allowed,
* but growing requires sufficient room in the adjacent region.
*/
if (start < r->r_start && (s == NULL || (s->r_flags & RF_ALLOCATED) ||
s->r_start > start)) {
mtx_unlock(rm->rm_mtx);
return (EBUSY);
}
if (end > r->r_end && (t == NULL || (t->r_flags & RF_ALLOCATED) ||
t->r_end < end)) {
mtx_unlock(rm->rm_mtx);
return (EBUSY);
}
/*
* While holding the lock, grow either end of the resource as
* needed and shrink either end if the shrinking does not require
* allocating a new resource. We can safely drop the lock and then
* insert a new range to handle the shrinking case afterwards.
*/
if (start < r->r_start ||
(start > r->r_start && s != NULL && !(s->r_flags & RF_ALLOCATED))) {
KASSERT(s->r_flags == 0, ("prev is busy"));
r->r_start = start;
if (s->r_start == start) {
TAILQ_REMOVE(&rm->rm_list, s, r_link);
free(s, M_RMAN);
} else
s->r_end = start - 1;
}
if (end > r->r_end ||
(end < r->r_end && t != NULL && !(t->r_flags & RF_ALLOCATED))) {
KASSERT(t->r_flags == 0, ("next is busy"));
r->r_end = end;
if (t->r_end == end) {
TAILQ_REMOVE(&rm->rm_list, t, r_link);
free(t, M_RMAN);
} else
t->r_start = end + 1;
}
mtx_unlock(rm->rm_mtx);
/*
* Handle the shrinking cases that require allocating a new
* resource to hold the newly-free region. We have to recheck
* if we still need this new region after acquiring the lock.
*/
if (start > r->r_start) {
new = int_alloc_resource(M_WAITOK);
new->r_start = r->r_start;
new->r_end = start - 1;
new->r_rm = rm;
mtx_lock(rm->rm_mtx);
r->r_start = start;
s = TAILQ_PREV(r, resource_head, r_link);
if (s != NULL && !(s->r_flags & RF_ALLOCATED)) {
s->r_end = start - 1;
free(new, M_RMAN);
} else
TAILQ_INSERT_BEFORE(r, new, r_link);
mtx_unlock(rm->rm_mtx);
}
if (end < r->r_end) {
new = int_alloc_resource(M_WAITOK);
new->r_start = end + 1;
new->r_end = r->r_end;
new->r_rm = rm;
mtx_lock(rm->rm_mtx);
r->r_end = end;
t = TAILQ_NEXT(r, r_link);
if (t != NULL && !(t->r_flags & RF_ALLOCATED)) {
t->r_start = end + 1;
free(new, M_RMAN);
} else
TAILQ_INSERT_AFTER(&rm->rm_list, r, new, r_link);
mtx_unlock(rm->rm_mtx);
}
return (0);
}
struct resource *
rman_reserve_resource_bound(struct rman *rm, u_long start, u_long end,
u_long count, u_long bound, u_int flags,
struct device *dev)
{
u_int want_activate;
struct resource_i *r, *s, *rv;
u_long rstart, rend, amask, bmask;
rv = NULL;
DPRINTF(("rman_reserve_resource_bound: <%s> request: [%#lx, %#lx], "
"length %#lx, flags %u, device %s\n", rm->rm_descr, start, end,
count, flags,
dev == NULL ? "<null>" : device_get_nameunit(dev)));
want_activate = (flags & RF_ACTIVE);
flags &= ~RF_ACTIVE;
mtx_lock(rm->rm_mtx);
for (r = TAILQ_FIRST(&rm->rm_list);
r && r->r_end < start;
r = TAILQ_NEXT(r, r_link))
;
if (r == NULL) {
DPRINTF(("could not find a region\n"));
goto out;
}
amask = (1ul << RF_ALIGNMENT(flags)) - 1;
/* If bound is 0, bmask will also be 0 */
bmask = ~(bound - 1);
/*
* First try to find an acceptable totally-unshared region.
*/
for (s = r; s; s = TAILQ_NEXT(s, r_link)) {
DPRINTF(("considering [%#lx, %#lx]\n", s->r_start, s->r_end));
if (s->r_start + count - 1 > end) {
DPRINTF(("s->r_start (%#lx) + count - 1> end (%#lx)\n",
s->r_start, end));
break;
}
if (s->r_flags & RF_ALLOCATED) {
DPRINTF(("region is allocated\n"));
continue;
}
rstart = ulmax(s->r_start, start);
/*
* Try to find a region by adjusting to boundary and alignment
* until both conditions are satisfied. This is not an optimal
* algorithm, but in most cases it isn't really bad, either.
*/
do {
rstart = (rstart + amask) & ~amask;
if (((rstart ^ (rstart + count - 1)) & bmask) != 0)
rstart += bound - (rstart & ~bmask);
} while ((rstart & amask) != 0 && rstart < end &&
rstart < s->r_end);
rend = ulmin(s->r_end, ulmax(rstart + count - 1, end));
if (rstart > rend) {
DPRINTF(("adjusted start exceeds end\n"));
continue;
}
DPRINTF(("truncated region: [%#lx, %#lx]; size %#lx (requested %#lx)\n",
rstart, rend, (rend - rstart + 1), count));
if ((rend - rstart + 1) >= count) {
DPRINTF(("candidate region: [%#lx, %#lx], size %#lx\n",
rstart, rend, (rend - rstart + 1)));
if ((s->r_end - s->r_start + 1) == count) {
DPRINTF(("candidate region is entire chunk\n"));
rv = s;
rv->r_flags |= RF_ALLOCATED | flags;
rv->r_dev = dev;
goto out;
}
/*
* If s->r_start < rstart and
* s->r_end > rstart + count - 1, then
* we need to split the region into three pieces
* (the middle one will get returned to the user).
* Otherwise, we are allocating at either the
* beginning or the end of s, so we only need to
* split it in two. The first case requires
* two new allocations; the second requires but one.
*/
rv = int_alloc_resource(M_NOWAIT);
if (rv == NULL)
goto out;
rv->r_start = rstart;
rv->r_end = rstart + count - 1;
rv->r_flags = flags | RF_ALLOCATED;
rv->r_dev = dev;
rv->r_rm = rm;
if (s->r_start < rv->r_start && s->r_end > rv->r_end) {
DPRINTF(("splitting region in three parts: "
"[%#lx, %#lx]; [%#lx, %#lx]; [%#lx, %#lx]\n",
s->r_start, rv->r_start - 1,
rv->r_start, rv->r_end,
rv->r_end + 1, s->r_end));
/*
* We are allocating in the middle.
*/
r = int_alloc_resource(M_NOWAIT);
if (r == NULL) {
free(rv, M_RMAN);
rv = NULL;
goto out;
}
r->r_start = rv->r_end + 1;
r->r_end = s->r_end;
r->r_flags = s->r_flags;
r->r_rm = rm;
s->r_end = rv->r_start - 1;
TAILQ_INSERT_AFTER(&rm->rm_list, s, rv,
r_link);
TAILQ_INSERT_AFTER(&rm->rm_list, rv, r,
r_link);
} else if (s->r_start == rv->r_start) {
DPRINTF(("allocating from the beginning\n"));
/*
* We are allocating at the beginning.
*/
s->r_start = rv->r_end + 1;
TAILQ_INSERT_BEFORE(s, rv, r_link);
} else {
DPRINTF(("allocating at the end\n"));
/*
* We are allocating at the end.
*/
s->r_end = rv->r_start - 1;
TAILQ_INSERT_AFTER(&rm->rm_list, s, rv,
r_link);
}
goto out;
}
}
/*
* Now find an acceptable shared region, if the client's requirements
* allow sharing. By our implementation restriction, a candidate
* region must match exactly by both size and sharing type in order
* to be considered compatible with the client's request. (The
* former restriction could probably be lifted without too much
* additional work, but this does not seem warranted.)
*/
DPRINTF(("no unshared regions found\n"));
if ((flags & (RF_SHAREABLE | RF_TIMESHARE)) == 0)
goto out;
for (s = r; s; s = TAILQ_NEXT(s, r_link)) {
if (s->r_start > end)
break;
if ((s->r_flags & flags) != flags)
continue;
rstart = ulmax(s->r_start, start);
rend = ulmin(s->r_end, ulmax(start + count - 1, end));
if (s->r_start >= start && s->r_end <= end
&& (s->r_end - s->r_start + 1) == count &&
(s->r_start & amask) == 0 &&
((s->r_start ^ s->r_end) & bmask) == 0) {
rv = int_alloc_resource(M_NOWAIT);
if (rv == NULL)
goto out;
rv->r_start = s->r_start;
rv->r_end = s->r_end;
rv->r_flags = s->r_flags &
(RF_ALLOCATED | RF_SHAREABLE | RF_TIMESHARE);
rv->r_dev = dev;
rv->r_rm = rm;
if (s->r_sharehead == NULL) {
s->r_sharehead = malloc(sizeof *s->r_sharehead,
M_RMAN, M_NOWAIT | M_ZERO);
if (s->r_sharehead == NULL) {
free(rv, M_RMAN);
rv = NULL;
goto out;
}
LIST_INIT(s->r_sharehead);
LIST_INSERT_HEAD(s->r_sharehead, s,
r_sharelink);
s->r_flags |= RF_FIRSTSHARE;
}
rv->r_sharehead = s->r_sharehead;
LIST_INSERT_HEAD(s->r_sharehead, rv, r_sharelink);
goto out;
}
}
/*
* We couldn't find anything.
*/
out:
/*
* If the user specified RF_ACTIVE in the initial flags,
* which is reflected in `want_activate', we attempt to atomically
* activate the resource. If this fails, we release the resource
* and indicate overall failure. (This behavior probably doesn't
* make sense for RF_TIMESHARE-type resources.)
*/
if (rv && want_activate) {
struct resource_i *whohas;
if (int_rman_activate_resource(rm, rv, &whohas)) {
int_rman_release_resource(rm, rv);
rv = NULL;
}
}
mtx_unlock(rm->rm_mtx);
return (rv == NULL ? NULL : &rv->r_r);
}
struct resource *
rman_reserve_resource(struct rman *rm, u_long start, u_long end, u_long count,
u_int flags, struct device *dev)
{
return (rman_reserve_resource_bound(rm, start, end, count, 0, flags,
dev));
}
static int
int_rman_activate_resource(struct rman *rm, struct resource_i *r,
struct resource_i **whohas)
{
struct resource_i *s;
int ok;
/*
* If we are not timesharing, then there is nothing much to do.
* If we already have the resource, then there is nothing at all to do.
* If we are not on a sharing list with anybody else, then there is
* little to do.
*/
if ((r->r_flags & RF_TIMESHARE) == 0
|| (r->r_flags & RF_ACTIVE) != 0
|| r->r_sharehead == NULL) {
r->r_flags |= RF_ACTIVE;
return 0;
}
ok = 1;
for (s = LIST_FIRST(r->r_sharehead); s && ok;
s = LIST_NEXT(s, r_sharelink)) {
if ((s->r_flags & RF_ACTIVE) != 0) {
ok = 0;
*whohas = s;
}
}
if (ok) {
r->r_flags |= RF_ACTIVE;
return 0;
}
return EBUSY;
}
int
rman_activate_resource(struct resource *re)
{
int rv;
struct resource_i *r, *whohas;
struct rman *rm;
r = re->__r_i;
rm = r->r_rm;
mtx_lock(rm->rm_mtx);
rv = int_rman_activate_resource(rm, r, &whohas);
mtx_unlock(rm->rm_mtx);
return rv;
}
int
rman_await_resource(struct resource *re, int pri, int timo)
{
int rv;
struct resource_i *r, *whohas;
struct rman *rm;
r = re->__r_i;
rm = r->r_rm;
mtx_lock(rm->rm_mtx);
for (;;) {
rv = int_rman_activate_resource(rm, r, &whohas);
if (rv != EBUSY)
return (rv); /* returns with mutex held */
if (r->r_sharehead == NULL)
panic("rman_await_resource");
whohas->r_flags |= RF_WANTED;
rv = msleep(r->r_sharehead, rm->rm_mtx, pri, "rmwait", timo);
if (rv) {
mtx_unlock(rm->rm_mtx);
return (rv);
}
}
}
static int
int_rman_deactivate_resource(struct resource_i *r)
{
r->r_flags &= ~RF_ACTIVE;
if (r->r_flags & RF_WANTED) {
r->r_flags &= ~RF_WANTED;
wakeup(r->r_sharehead);
}
return 0;
}
int
rman_deactivate_resource(struct resource *r)
{
struct rman *rm;
rm = r->__r_i->r_rm;
mtx_lock(rm->rm_mtx);
int_rman_deactivate_resource(r->__r_i);
mtx_unlock(rm->rm_mtx);
return 0;
}
static int
int_rman_release_resource(struct rman *rm, struct resource_i *r)
{
struct resource_i *s, *t;
if (r->r_flags & RF_ACTIVE)
int_rman_deactivate_resource(r);
/*
* Check for a sharing list first. If there is one, then we don't
* have to think as hard.
*/
if (r->r_sharehead) {
/*
* If a sharing list exists, then we know there are at
* least two sharers.
*
* If we are in the main circleq, appoint someone else.
*/
LIST_REMOVE(r, r_sharelink);
s = LIST_FIRST(r->r_sharehead);
if (r->r_flags & RF_FIRSTSHARE) {
s->r_flags |= RF_FIRSTSHARE;
TAILQ_INSERT_BEFORE(r, s, r_link);
TAILQ_REMOVE(&rm->rm_list, r, r_link);
}
/*
* Make sure that the sharing list goes away completely
* if the resource is no longer being shared at all.
*/
if (LIST_NEXT(s, r_sharelink) == NULL) {
free(s->r_sharehead, M_RMAN);
s->r_sharehead = NULL;
s->r_flags &= ~RF_FIRSTSHARE;
}
goto out;
}
/*
* Look at the adjacent resources in the list and see if our
* segment can be merged with any of them. If either of the
* resources is allocated or is not exactly adjacent then they
* cannot be merged with our segment.
*/
s = TAILQ_PREV(r, resource_head, r_link);
if (s != NULL && ((s->r_flags & RF_ALLOCATED) != 0 ||
s->r_end + 1 != r->r_start))
s = NULL;
t = TAILQ_NEXT(r, r_link);
if (t != NULL && ((t->r_flags & RF_ALLOCATED) != 0 ||
r->r_end + 1 != t->r_start))
t = NULL;
if (s != NULL && t != NULL) {
/*
* Merge all three segments.
*/
s->r_end = t->r_end;
TAILQ_REMOVE(&rm->rm_list, r, r_link);
TAILQ_REMOVE(&rm->rm_list, t, r_link);
free(t, M_RMAN);
} else if (s != NULL) {
/*
* Merge previous segment with ours.
*/
s->r_end = r->r_end;
TAILQ_REMOVE(&rm->rm_list, r, r_link);
} else if (t != NULL) {
/*
* Merge next segment with ours.
*/
t->r_start = r->r_start;
TAILQ_REMOVE(&rm->rm_list, r, r_link);
} else {
/*
* At this point, we know there is nothing we
* can potentially merge with, because on each
* side, there is either nothing there or what is
* there is still allocated. In that case, we don't
* want to remove r from the list; we simply want to
* change it to an unallocated region and return
* without freeing anything.
*/
r->r_flags &= ~RF_ALLOCATED;
return 0;
}
out:
free(r, M_RMAN);
return 0;
}
int
rman_release_resource(struct resource *re)
{
int rv;
struct resource_i *r;
struct rman *rm;
r = re->__r_i;
rm = r->r_rm;
mtx_lock(rm->rm_mtx);
rv = int_rman_release_resource(rm, r);
mtx_unlock(rm->rm_mtx);
return (rv);
}
uint32_t
rman_make_alignment_flags(uint32_t size)
{
int i;
/*
* Find the hightest bit set, and add one if more than one bit
* set. We're effectively computing the ceil(log2(size)) here.
*/
for (i = 31; i > 0; i--)
if ((1 << i) & size)
break;
if (~(1 << i) & size)
i++;
return(RF_ALIGNMENT_LOG2(i));
}
void
rman_set_start(struct resource *r, u_long start)
{
r->__r_i->r_start = start;
}
u_long
rman_get_start(struct resource *r)
{
return (r->__r_i->r_start);
}
void
rman_set_end(struct resource *r, u_long end)
{
r->__r_i->r_end = end;
}
u_long
rman_get_end(struct resource *r)
{
return (r->__r_i->r_end);
}
u_long
rman_get_size(struct resource *r)
{
return (r->__r_i->r_end - r->__r_i->r_start + 1);
}
u_int
rman_get_flags(struct resource *r)
{
return (r->__r_i->r_flags);
}
void
rman_set_virtual(struct resource *r, void *v)
{
r->__r_i->r_virtual = v;
}
void *
rman_get_virtual(struct resource *r)
{
return (r->__r_i->r_virtual);
}
void
rman_set_bustag(struct resource *r, bus_space_tag_t t)
{
r->r_bustag = t;
}
bus_space_tag_t
rman_get_bustag(struct resource *r)
{
return (r->r_bustag);
}
void
rman_set_bushandle(struct resource *r, bus_space_handle_t h)
{
r->r_bushandle = h;
}
bus_space_handle_t
rman_get_bushandle(struct resource *r)
{
return (r->r_bushandle);
}
void
rman_set_rid(struct resource *r, int rid)
{
r->__r_i->r_rid = rid;
}
int
rman_get_rid(struct resource *r)
{
return (r->__r_i->r_rid);
}
void
rman_set_device(struct resource *r, struct device *dev)
{
r->__r_i->r_dev = dev;
}
struct device *
rman_get_device(struct resource *r)
{
return (r->__r_i->r_dev);
}
int
rman_is_region_manager(struct resource *r, struct rman *rm)
{
return (r->__r_i->r_rm == rm);
}
/*
* Sysctl interface for scanning the resource lists.
*
* We take two input parameters; the index into the list of resource
* managers, and the resource offset into the list.
*/
static int
sysctl_rman(SYSCTL_HANDLER_ARGS)
{
int *name = (int *)arg1;
u_int namelen = arg2;
int rman_idx, res_idx;
struct rman *rm;
struct resource_i *res;
struct resource_i *sres;
struct u_rman urm;
struct u_resource ures;
int error;
if (namelen != 3)
return (EINVAL);
if (bus_data_generation_check(name[0]))
return (EINVAL);
rman_idx = name[1];
res_idx = name[2];
/*
* Find the indexed resource manager
*/
mtx_lock(&rman_mtx);
TAILQ_FOREACH(rm, &rman_head, rm_link) {
if (rman_idx-- == 0)
break;
}
mtx_unlock(&rman_mtx);
if (rm == NULL)
return (ENOENT);
/*
* If the resource index is -1, we want details on the
* resource manager.
*/
if (res_idx == -1) {
bzero(&urm, sizeof(urm));
urm.rm_handle = (uintptr_t)rm;
if (rm->rm_descr != NULL)
strlcpy(urm.rm_descr, rm->rm_descr, RM_TEXTLEN);
urm.rm_start = rm->rm_start;
urm.rm_size = rm->rm_end - rm->rm_start + 1;
urm.rm_type = rm->rm_type;
error = SYSCTL_OUT(req, &urm, sizeof(urm));
return (error);
}
/*
* Find the indexed resource and return it.
*/
mtx_lock(rm->rm_mtx);
TAILQ_FOREACH(res, &rm->rm_list, r_link) {
if (res->r_sharehead != NULL) {
LIST_FOREACH(sres, res->r_sharehead, r_sharelink)
if (res_idx-- == 0) {
res = sres;
goto found;
}
}
else if (res_idx-- == 0)
goto found;
}
mtx_unlock(rm->rm_mtx);
return (ENOENT);
found:
bzero(&ures, sizeof(ures));
ures.r_handle = (uintptr_t)res;
ures.r_parent = (uintptr_t)res->r_rm;
ures.r_device = (uintptr_t)res->r_dev;
if (res->r_dev != NULL) {
if (device_get_name(res->r_dev) != NULL) {
snprintf(ures.r_devname, RM_TEXTLEN,
"%s%d",
device_get_name(res->r_dev),
device_get_unit(res->r_dev));
} else {
strlcpy(ures.r_devname, "nomatch",
RM_TEXTLEN);
}
} else {
ures.r_devname[0] = '\0';
}
ures.r_start = res->r_start;
ures.r_size = res->r_end - res->r_start + 1;
ures.r_flags = res->r_flags;
mtx_unlock(rm->rm_mtx);
error = SYSCTL_OUT(req, &ures, sizeof(ures));
return (error);
}
SYSCTL_NODE(_hw_bus, OID_AUTO, rman, CTLFLAG_RD, sysctl_rman,
"kernel resource manager");
#ifdef DDB
static void
dump_rman_header(struct rman *rm)
{
if (db_pager_quit)
return;
db_printf("rman %p: %s (0x%lx-0x%lx full range)\n",
rm, rm->rm_descr, rm->rm_start, rm->rm_end);
}
static void
dump_rman(struct rman *rm)
{
struct resource_i *r;
const char *devname;
if (db_pager_quit)
return;
TAILQ_FOREACH(r, &rm->rm_list, r_link) {
if (r->r_dev != NULL) {
devname = device_get_nameunit(r->r_dev);
if (devname == NULL)
devname = "nomatch";
} else
devname = NULL;
db_printf(" 0x%lx-0x%lx ", r->r_start, r->r_end);
if (devname != NULL)
db_printf("(%s)\n", devname);
else
db_printf("----\n");
if (db_pager_quit)
return;
}
}
DB_SHOW_COMMAND(rman, db_show_rman)
{
if (have_addr) {
dump_rman_header((struct rman *)addr);
dump_rman((struct rman *)addr);
}
}
DB_SHOW_COMMAND(rmans, db_show_rmans)
{
struct rman *rm;
TAILQ_FOREACH(rm, &rman_head, rm_link) {
dump_rman_header(rm);
}
}
DB_SHOW_ALL_COMMAND(rman, db_show_all_rman)
{
struct rman *rm;
TAILQ_FOREACH(rm, &rman_head, rm_link) {
dump_rman_header(rm);
dump_rman(rm);
}
}
DB_SHOW_ALIAS(allrman, db_show_all_rman);
#endif