1d96e5996SHans Petter Selasky /*-
2d96e5996SHans Petter Selasky * Copyright (c) 2020 Mellanox Technologies, Ltd.
3d96e5996SHans Petter Selasky * All rights reserved.
4d96e5996SHans Petter Selasky *
5d96e5996SHans Petter Selasky * Redistribution and use in source and binary forms, with or without
6d96e5996SHans Petter Selasky * modification, are permitted provided that the following conditions
7d96e5996SHans Petter Selasky * are met:
8d96e5996SHans Petter Selasky * 1. Redistributions of source code must retain the above copyright
9d96e5996SHans Petter Selasky * notice unmodified, this list of conditions, and the following
10d96e5996SHans Petter Selasky * disclaimer.
11d96e5996SHans Petter Selasky * 2. Redistributions in binary form must reproduce the above copyright
12d96e5996SHans Petter Selasky * notice, this list of conditions and the following disclaimer in the
13d96e5996SHans Petter Selasky * documentation and/or other materials provided with the distribution.
14d96e5996SHans Petter Selasky *
15d96e5996SHans Petter Selasky * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
16d96e5996SHans Petter Selasky * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
17d96e5996SHans Petter Selasky * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
18d96e5996SHans Petter Selasky * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
19d96e5996SHans Petter Selasky * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
20d96e5996SHans Petter Selasky * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
21d96e5996SHans Petter Selasky * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
22d96e5996SHans Petter Selasky * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
23d96e5996SHans Petter Selasky * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
24d96e5996SHans Petter Selasky * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
25d96e5996SHans Petter Selasky */
26d96e5996SHans Petter Selasky
27d96e5996SHans Petter Selasky #include <sys/cdefs.h>
28d96e5996SHans Petter Selasky __FBSDID("$FreeBSD$");
29d96e5996SHans Petter Selasky
30d96e5996SHans Petter Selasky #include <linux/xarray.h>
31d96e5996SHans Petter Selasky
32d96e5996SHans Petter Selasky #include <vm/vm_pageout.h>
33d96e5996SHans Petter Selasky
34d96e5996SHans Petter Selasky /*
35d96e5996SHans Petter Selasky * This function removes the element at the given index and returns
36d96e5996SHans Petter Selasky * the pointer to the removed element, if any.
37d96e5996SHans Petter Selasky */
38d96e5996SHans Petter Selasky void *
__xa_erase(struct xarray * xa,uint32_t index)39d96e5996SHans Petter Selasky __xa_erase(struct xarray *xa, uint32_t index)
40d96e5996SHans Petter Selasky {
41d96e5996SHans Petter Selasky XA_ASSERT_LOCKED(xa);
42d96e5996SHans Petter Selasky
43d96e5996SHans Petter Selasky return (radix_tree_delete(&xa->root, index));
44d96e5996SHans Petter Selasky }
45d96e5996SHans Petter Selasky
46d96e5996SHans Petter Selasky void *
xa_erase(struct xarray * xa,uint32_t index)47d96e5996SHans Petter Selasky xa_erase(struct xarray *xa, uint32_t index)
48d96e5996SHans Petter Selasky {
49d96e5996SHans Petter Selasky void *retval;
50d96e5996SHans Petter Selasky
51d96e5996SHans Petter Selasky xa_lock(xa);
52d96e5996SHans Petter Selasky retval = __xa_erase(xa, index);
53d96e5996SHans Petter Selasky xa_unlock(xa);
54d96e5996SHans Petter Selasky
55d96e5996SHans Petter Selasky return (retval);
56d96e5996SHans Petter Selasky }
57d96e5996SHans Petter Selasky
58d96e5996SHans Petter Selasky /*
59d96e5996SHans Petter Selasky * This function returns the element pointer at the given index. A
60d96e5996SHans Petter Selasky * value of NULL is returned if the element does not exist.
61d96e5996SHans Petter Selasky */
62d96e5996SHans Petter Selasky void *
xa_load(struct xarray * xa,uint32_t index)63d96e5996SHans Petter Selasky xa_load(struct xarray *xa, uint32_t index)
64d96e5996SHans Petter Selasky {
65d96e5996SHans Petter Selasky void *retval;
66d96e5996SHans Petter Selasky
67d96e5996SHans Petter Selasky xa_lock(xa);
68d96e5996SHans Petter Selasky retval = radix_tree_lookup(&xa->root, index);
69d96e5996SHans Petter Selasky xa_unlock(xa);
70d96e5996SHans Petter Selasky
71d96e5996SHans Petter Selasky return (retval);
72d96e5996SHans Petter Selasky }
73d96e5996SHans Petter Selasky
74d96e5996SHans Petter Selasky /*
75d96e5996SHans Petter Selasky * This is an internal function used to sleep until more memory
76d96e5996SHans Petter Selasky * becomes available.
77d96e5996SHans Petter Selasky */
78d96e5996SHans Petter Selasky static void
xa_vm_wait_locked(struct xarray * xa)79d96e5996SHans Petter Selasky xa_vm_wait_locked(struct xarray *xa)
80d96e5996SHans Petter Selasky {
81d96e5996SHans Petter Selasky xa_unlock(xa);
82d96e5996SHans Petter Selasky vm_wait(NULL);
83d96e5996SHans Petter Selasky xa_lock(xa);
84d96e5996SHans Petter Selasky }
85d96e5996SHans Petter Selasky
86d96e5996SHans Petter Selasky /*
87d96e5996SHans Petter Selasky * This function iterates the xarray until it finds a free slot where
88d96e5996SHans Petter Selasky * it can insert the element pointer to by "ptr". It starts at the
89d96e5996SHans Petter Selasky * index pointed to by "pindex" and updates this value at return. The
90d96e5996SHans Petter Selasky * "mask" argument defines the maximum index allowed, inclusivly, and
91d96e5996SHans Petter Selasky * must be a power of two minus one value. The "gfp" argument
92d96e5996SHans Petter Selasky * basically tells if we can wait for more memory to become available
93d96e5996SHans Petter Selasky * or not. This function returns zero upon success or a negative error
94d96e5996SHans Petter Selasky * code on failure. A typical error code is -ENOMEM which means either
95d96e5996SHans Petter Selasky * the xarray is full, or there was not enough internal memory
96d96e5996SHans Petter Selasky * available to complete the radix tree insertion.
97d96e5996SHans Petter Selasky */
98d96e5996SHans Petter Selasky int
__xa_alloc(struct xarray * xa,uint32_t * pindex,void * ptr,uint32_t mask,gfp_t gfp)99d96e5996SHans Petter Selasky __xa_alloc(struct xarray *xa, uint32_t *pindex, void *ptr, uint32_t mask, gfp_t gfp)
100d96e5996SHans Petter Selasky {
101d96e5996SHans Petter Selasky int retval;
102d96e5996SHans Petter Selasky
103d96e5996SHans Petter Selasky XA_ASSERT_LOCKED(xa);
104d96e5996SHans Petter Selasky
105*8dc3f129SVladimir Kondratyev /* mask should allow to allocate at least one item */
106*8dc3f129SVladimir Kondratyev MPASS(mask > (xa->flags & XA_FLAGS_ALLOC1) != 0 ? 1 : 0);
107d96e5996SHans Petter Selasky
108d96e5996SHans Petter Selasky /* mask can be any power of two value minus one */
109d96e5996SHans Petter Selasky MPASS((mask & (mask + 1)) == 0);
110d96e5996SHans Petter Selasky
111*8dc3f129SVladimir Kondratyev *pindex = (xa->flags & XA_FLAGS_ALLOC1) != 0 ? 1 : 0;
112d96e5996SHans Petter Selasky retry:
113d96e5996SHans Petter Selasky retval = radix_tree_insert(&xa->root, *pindex, ptr);
114d96e5996SHans Petter Selasky
115d96e5996SHans Petter Selasky switch (retval) {
116d96e5996SHans Petter Selasky case -EEXIST:
117d96e5996SHans Petter Selasky if (likely(*pindex != mask)) {
118d96e5996SHans Petter Selasky (*pindex)++;
119d96e5996SHans Petter Selasky goto retry;
120d96e5996SHans Petter Selasky }
121d96e5996SHans Petter Selasky retval = -ENOMEM;
122d96e5996SHans Petter Selasky break;
123d96e5996SHans Petter Selasky case -ENOMEM:
124d96e5996SHans Petter Selasky if (likely(gfp & M_WAITOK)) {
125d96e5996SHans Petter Selasky xa_vm_wait_locked(xa);
126d96e5996SHans Petter Selasky goto retry;
127d96e5996SHans Petter Selasky }
128d96e5996SHans Petter Selasky break;
129d96e5996SHans Petter Selasky default:
130d96e5996SHans Petter Selasky break;
131d96e5996SHans Petter Selasky }
132d96e5996SHans Petter Selasky return (retval);
133d96e5996SHans Petter Selasky }
134d96e5996SHans Petter Selasky
135d96e5996SHans Petter Selasky int
xa_alloc(struct xarray * xa,uint32_t * pindex,void * ptr,uint32_t mask,gfp_t gfp)136d96e5996SHans Petter Selasky xa_alloc(struct xarray *xa, uint32_t *pindex, void *ptr, uint32_t mask, gfp_t gfp)
137d96e5996SHans Petter Selasky {
138d96e5996SHans Petter Selasky int retval;
139d96e5996SHans Petter Selasky
140d96e5996SHans Petter Selasky xa_lock(xa);
141d96e5996SHans Petter Selasky retval = __xa_alloc(xa, pindex, ptr, mask, gfp);
142d96e5996SHans Petter Selasky xa_unlock(xa);
143d96e5996SHans Petter Selasky
144d96e5996SHans Petter Selasky return (retval);
145d96e5996SHans Petter Selasky }
146d96e5996SHans Petter Selasky
147d96e5996SHans Petter Selasky /*
148d96e5996SHans Petter Selasky * This function works the same like the "xa_alloc" function, except
149d96e5996SHans Petter Selasky * it wraps the next index value to zero when there are no entries
150d96e5996SHans Petter Selasky * left at the end of the xarray searching for a free slot from the
151d96e5996SHans Petter Selasky * beginning of the array. If the xarray is full -ENOMEM is returned.
152d96e5996SHans Petter Selasky */
153d96e5996SHans Petter Selasky int
__xa_alloc_cyclic(struct xarray * xa,uint32_t * pindex,void * ptr,uint32_t mask,uint32_t * pnext_index,gfp_t gfp)154d96e5996SHans Petter Selasky __xa_alloc_cyclic(struct xarray *xa, uint32_t *pindex, void *ptr, uint32_t mask,
155d96e5996SHans Petter Selasky uint32_t *pnext_index, gfp_t gfp)
156d96e5996SHans Petter Selasky {
157d96e5996SHans Petter Selasky int retval;
158d96e5996SHans Petter Selasky int timeout = 1;
159d96e5996SHans Petter Selasky
160d96e5996SHans Petter Selasky XA_ASSERT_LOCKED(xa);
161d96e5996SHans Petter Selasky
162*8dc3f129SVladimir Kondratyev /* mask should allow to allocate at least one item */
163*8dc3f129SVladimir Kondratyev MPASS(mask > (xa->flags & XA_FLAGS_ALLOC1) != 0 ? 1 : 0);
164d96e5996SHans Petter Selasky
165d96e5996SHans Petter Selasky /* mask can be any power of two value minus one */
166d96e5996SHans Petter Selasky MPASS((mask & (mask + 1)) == 0);
167d96e5996SHans Petter Selasky
168*8dc3f129SVladimir Kondratyev *pnext_index = (xa->flags & XA_FLAGS_ALLOC1) != 0 ? 1 : 0;
169d96e5996SHans Petter Selasky retry:
170d96e5996SHans Petter Selasky retval = radix_tree_insert(&xa->root, *pnext_index, ptr);
171d96e5996SHans Petter Selasky
172d96e5996SHans Petter Selasky switch (retval) {
173d96e5996SHans Petter Selasky case -EEXIST:
174d96e5996SHans Petter Selasky if (unlikely(*pnext_index == mask) && !timeout--) {
175d96e5996SHans Petter Selasky retval = -ENOMEM;
176d96e5996SHans Petter Selasky break;
177d96e5996SHans Petter Selasky }
178d96e5996SHans Petter Selasky (*pnext_index)++;
179d96e5996SHans Petter Selasky (*pnext_index) &= mask;
180*8dc3f129SVladimir Kondratyev if (*pnext_index == 0 && (xa->flags & XA_FLAGS_ALLOC1) != 0)
181*8dc3f129SVladimir Kondratyev (*pnext_index)++;
182d96e5996SHans Petter Selasky goto retry;
183d96e5996SHans Petter Selasky case -ENOMEM:
184d96e5996SHans Petter Selasky if (likely(gfp & M_WAITOK)) {
185d96e5996SHans Petter Selasky xa_vm_wait_locked(xa);
186d96e5996SHans Petter Selasky goto retry;
187d96e5996SHans Petter Selasky }
188d96e5996SHans Petter Selasky break;
189d96e5996SHans Petter Selasky default:
190d96e5996SHans Petter Selasky break;
191d96e5996SHans Petter Selasky }
192d96e5996SHans Petter Selasky *pindex = *pnext_index;
193d96e5996SHans Petter Selasky
194d96e5996SHans Petter Selasky return (retval);
195d96e5996SHans Petter Selasky }
196d96e5996SHans Petter Selasky
197d96e5996SHans Petter Selasky int
xa_alloc_cyclic(struct xarray * xa,uint32_t * pindex,void * ptr,uint32_t mask,uint32_t * pnext_index,gfp_t gfp)198d96e5996SHans Petter Selasky xa_alloc_cyclic(struct xarray *xa, uint32_t *pindex, void *ptr, uint32_t mask,
199d96e5996SHans Petter Selasky uint32_t *pnext_index, gfp_t gfp)
200d96e5996SHans Petter Selasky {
201d96e5996SHans Petter Selasky int retval;
202d96e5996SHans Petter Selasky
203d96e5996SHans Petter Selasky xa_lock(xa);
204d96e5996SHans Petter Selasky retval = __xa_alloc_cyclic(xa, pindex, ptr, mask, pnext_index, gfp);
205d96e5996SHans Petter Selasky xa_unlock(xa);
206d96e5996SHans Petter Selasky
207d96e5996SHans Petter Selasky return (retval);
208d96e5996SHans Petter Selasky }
209d96e5996SHans Petter Selasky
210d96e5996SHans Petter Selasky /*
211d96e5996SHans Petter Selasky * This function tries to insert an element at the given index. The
212d96e5996SHans Petter Selasky * "gfp" argument basically decides of this function can sleep or not
213d96e5996SHans Petter Selasky * trying to allocate internal memory for its radix tree. The
214d96e5996SHans Petter Selasky * function returns an error code upon failure. Typical error codes
215d96e5996SHans Petter Selasky * are element exists (-EEXIST) or out of memory (-ENOMEM).
216d96e5996SHans Petter Selasky */
217d96e5996SHans Petter Selasky int
__xa_insert(struct xarray * xa,uint32_t index,void * ptr,gfp_t gfp)218d96e5996SHans Petter Selasky __xa_insert(struct xarray *xa, uint32_t index, void *ptr, gfp_t gfp)
219d96e5996SHans Petter Selasky {
220d96e5996SHans Petter Selasky int retval;
221d96e5996SHans Petter Selasky
222d96e5996SHans Petter Selasky XA_ASSERT_LOCKED(xa);
223d96e5996SHans Petter Selasky retry:
224d96e5996SHans Petter Selasky retval = radix_tree_insert(&xa->root, index, ptr);
225d96e5996SHans Petter Selasky
226d96e5996SHans Petter Selasky switch (retval) {
227d96e5996SHans Petter Selasky case -ENOMEM:
228d96e5996SHans Petter Selasky if (likely(gfp & M_WAITOK)) {
229d96e5996SHans Petter Selasky xa_vm_wait_locked(xa);
230d96e5996SHans Petter Selasky goto retry;
231d96e5996SHans Petter Selasky }
232d96e5996SHans Petter Selasky break;
233d96e5996SHans Petter Selasky default:
234d96e5996SHans Petter Selasky break;
235d96e5996SHans Petter Selasky }
236d96e5996SHans Petter Selasky return (retval);
237d96e5996SHans Petter Selasky }
238d96e5996SHans Petter Selasky
239d96e5996SHans Petter Selasky int
xa_insert(struct xarray * xa,uint32_t index,void * ptr,gfp_t gfp)240d96e5996SHans Petter Selasky xa_insert(struct xarray *xa, uint32_t index, void *ptr, gfp_t gfp)
241d96e5996SHans Petter Selasky {
242d96e5996SHans Petter Selasky int retval;
243d96e5996SHans Petter Selasky
244d96e5996SHans Petter Selasky xa_lock(xa);
245d96e5996SHans Petter Selasky retval = __xa_insert(xa, index, ptr, gfp);
246d96e5996SHans Petter Selasky xa_unlock(xa);
247d96e5996SHans Petter Selasky
248d96e5996SHans Petter Selasky return (retval);
249d96e5996SHans Petter Selasky }
250d96e5996SHans Petter Selasky
251d96e5996SHans Petter Selasky /*
252d96e5996SHans Petter Selasky * This function updates the element at the given index and returns a
253d96e5996SHans Petter Selasky * pointer to the old element. The "gfp" argument basically decides of
254d96e5996SHans Petter Selasky * this function can sleep or not trying to allocate internal memory
255d96e5996SHans Petter Selasky * for its radix tree. The function returns an XA_ERROR() pointer code
256d96e5996SHans Petter Selasky * upon failure. Code using this function must always check if the
257d96e5996SHans Petter Selasky * return value is an XA_ERROR() code before using the returned value.
258d96e5996SHans Petter Selasky */
259d96e5996SHans Petter Selasky void *
__xa_store(struct xarray * xa,uint32_t index,void * ptr,gfp_t gfp)260d96e5996SHans Petter Selasky __xa_store(struct xarray *xa, uint32_t index, void *ptr, gfp_t gfp)
261d96e5996SHans Petter Selasky {
262d96e5996SHans Petter Selasky int retval;
263d96e5996SHans Petter Selasky
264d96e5996SHans Petter Selasky XA_ASSERT_LOCKED(xa);
265d96e5996SHans Petter Selasky retry:
266d96e5996SHans Petter Selasky retval = radix_tree_store(&xa->root, index, &ptr);
267d96e5996SHans Petter Selasky
268d96e5996SHans Petter Selasky switch (retval) {
269d96e5996SHans Petter Selasky case 0:
270d96e5996SHans Petter Selasky break;
271d96e5996SHans Petter Selasky case -ENOMEM:
272d96e5996SHans Petter Selasky if (likely(gfp & M_WAITOK)) {
273d96e5996SHans Petter Selasky xa_vm_wait_locked(xa);
274d96e5996SHans Petter Selasky goto retry;
275d96e5996SHans Petter Selasky }
276d96e5996SHans Petter Selasky ptr = XA_ERROR(retval);
277d96e5996SHans Petter Selasky break;
278d96e5996SHans Petter Selasky default:
279d96e5996SHans Petter Selasky ptr = XA_ERROR(retval);
280d96e5996SHans Petter Selasky break;
281d96e5996SHans Petter Selasky }
282d96e5996SHans Petter Selasky return (ptr);
283d96e5996SHans Petter Selasky }
284d96e5996SHans Petter Selasky
285d96e5996SHans Petter Selasky void *
xa_store(struct xarray * xa,uint32_t index,void * ptr,gfp_t gfp)286d96e5996SHans Petter Selasky xa_store(struct xarray *xa, uint32_t index, void *ptr, gfp_t gfp)
287d96e5996SHans Petter Selasky {
288d96e5996SHans Petter Selasky void *retval;
289d96e5996SHans Petter Selasky
290d96e5996SHans Petter Selasky xa_lock(xa);
291d96e5996SHans Petter Selasky retval = __xa_store(xa, index, ptr, gfp);
292d96e5996SHans Petter Selasky xa_unlock(xa);
293d96e5996SHans Petter Selasky
294d96e5996SHans Petter Selasky return (retval);
295d96e5996SHans Petter Selasky }
296d96e5996SHans Petter Selasky
297d96e5996SHans Petter Selasky /*
298d96e5996SHans Petter Selasky * This function initialize an xarray structure.
299d96e5996SHans Petter Selasky */
300d96e5996SHans Petter Selasky void
xa_init_flags(struct xarray * xa,uint32_t flags)301d96e5996SHans Petter Selasky xa_init_flags(struct xarray *xa, uint32_t flags)
302d96e5996SHans Petter Selasky {
303d96e5996SHans Petter Selasky memset(xa, 0, sizeof(*xa));
304d96e5996SHans Petter Selasky
305d96e5996SHans Petter Selasky mtx_init(&xa->mtx, "lkpi-xarray", NULL, MTX_DEF | MTX_RECURSE);
306d96e5996SHans Petter Selasky xa->root.gfp_mask = GFP_NOWAIT;
307*8dc3f129SVladimir Kondratyev xa->flags = flags;
308d96e5996SHans Petter Selasky }
309d96e5996SHans Petter Selasky
310d96e5996SHans Petter Selasky /*
311d96e5996SHans Petter Selasky * This function destroys an xarray structure and all its internal
312d96e5996SHans Petter Selasky * memory and locks.
313d96e5996SHans Petter Selasky */
314d96e5996SHans Petter Selasky void
xa_destroy(struct xarray * xa)315d96e5996SHans Petter Selasky xa_destroy(struct xarray *xa)
316d96e5996SHans Petter Selasky {
317d96e5996SHans Petter Selasky struct radix_tree_iter iter;
318d96e5996SHans Petter Selasky void **ppslot;
319d96e5996SHans Petter Selasky
320d96e5996SHans Petter Selasky radix_tree_for_each_slot(ppslot, &xa->root, &iter, 0)
321d96e5996SHans Petter Selasky radix_tree_iter_delete(&xa->root, &iter, ppslot);
322d96e5996SHans Petter Selasky mtx_destroy(&xa->mtx);
323d96e5996SHans Petter Selasky }
324d96e5996SHans Petter Selasky
325d96e5996SHans Petter Selasky /*
326d96e5996SHans Petter Selasky * This function checks if an xarray is empty or not.
327d96e5996SHans Petter Selasky * It returns true if empty, else false.
328d96e5996SHans Petter Selasky */
329d96e5996SHans Petter Selasky bool
__xa_empty(struct xarray * xa)330d96e5996SHans Petter Selasky __xa_empty(struct xarray *xa)
331d96e5996SHans Petter Selasky {
332d96e5996SHans Petter Selasky struct radix_tree_iter iter = {};
333d96e5996SHans Petter Selasky void **temp;
334d96e5996SHans Petter Selasky
335d96e5996SHans Petter Selasky XA_ASSERT_LOCKED(xa);
336d96e5996SHans Petter Selasky
337d96e5996SHans Petter Selasky return (!radix_tree_iter_find(&xa->root, &iter, &temp));
338d96e5996SHans Petter Selasky }
339d96e5996SHans Petter Selasky
340d96e5996SHans Petter Selasky bool
xa_empty(struct xarray * xa)341d96e5996SHans Petter Selasky xa_empty(struct xarray *xa)
342d96e5996SHans Petter Selasky {
343d96e5996SHans Petter Selasky bool retval;
344d96e5996SHans Petter Selasky
345d96e5996SHans Petter Selasky xa_lock(xa);
346d96e5996SHans Petter Selasky retval = __xa_empty(xa);
347d96e5996SHans Petter Selasky xa_unlock(xa);
348d96e5996SHans Petter Selasky
349d96e5996SHans Petter Selasky return (retval);
350d96e5996SHans Petter Selasky }
351d96e5996SHans Petter Selasky
352d96e5996SHans Petter Selasky /*
353d96e5996SHans Petter Selasky * This function returns the next valid xarray entry based on the
354d96e5996SHans Petter Selasky * index given by "pindex". The valued pointed to by "pindex" is
355d96e5996SHans Petter Selasky * updated before return.
356d96e5996SHans Petter Selasky */
357d96e5996SHans Petter Selasky void *
__xa_next(struct xarray * xa,unsigned long * pindex,bool not_first)358d96e5996SHans Petter Selasky __xa_next(struct xarray *xa, unsigned long *pindex, bool not_first)
359d96e5996SHans Petter Selasky {
360d96e5996SHans Petter Selasky struct radix_tree_iter iter = { .index = *pindex };
361d96e5996SHans Petter Selasky void **ppslot;
362d96e5996SHans Petter Selasky void *retval;
363d96e5996SHans Petter Selasky bool found;
364d96e5996SHans Petter Selasky
365d96e5996SHans Petter Selasky XA_ASSERT_LOCKED(xa);
366d96e5996SHans Petter Selasky
367d96e5996SHans Petter Selasky if (not_first) {
368d96e5996SHans Petter Selasky /* advance to next index, if any */
369d96e5996SHans Petter Selasky iter.index++;
370d96e5996SHans Petter Selasky if (iter.index == 0)
371d96e5996SHans Petter Selasky return (NULL);
372d96e5996SHans Petter Selasky }
373d96e5996SHans Petter Selasky
374d96e5996SHans Petter Selasky found = radix_tree_iter_find(&xa->root, &iter, &ppslot);
375d96e5996SHans Petter Selasky if (likely(found)) {
376d96e5996SHans Petter Selasky retval = *ppslot;
377d96e5996SHans Petter Selasky *pindex = iter.index;
378d96e5996SHans Petter Selasky } else {
379d96e5996SHans Petter Selasky retval = NULL;
380d96e5996SHans Petter Selasky }
381d96e5996SHans Petter Selasky return (retval);
382d96e5996SHans Petter Selasky }
383d96e5996SHans Petter Selasky
384d96e5996SHans Petter Selasky void *
xa_next(struct xarray * xa,unsigned long * pindex,bool not_first)385d96e5996SHans Petter Selasky xa_next(struct xarray *xa, unsigned long *pindex, bool not_first)
386d96e5996SHans Petter Selasky {
387d96e5996SHans Petter Selasky void *retval;
388d96e5996SHans Petter Selasky
389d96e5996SHans Petter Selasky xa_lock(xa);
390d96e5996SHans Petter Selasky retval = __xa_next(xa, pindex, not_first);
391d96e5996SHans Petter Selasky xa_unlock(xa);
392d96e5996SHans Petter Selasky
393d96e5996SHans Petter Selasky return (retval);
394d96e5996SHans Petter Selasky }
395