i2c-eg20t: change timeout value 50msec to 1000msec
[zen-stable.git] / drivers / staging / tidspbridge / pmgr / cmm.c
blobe6b2c8962f810548cec70c42baef47b508695cde
1 /*
2 * cmm.c
4 * DSP-BIOS Bridge driver support functions for TI OMAP processors.
6 * The Communication(Shared) Memory Management(CMM) module provides
7 * shared memory management services for DSP/BIOS Bridge data streaming
8 * and messaging.
10 * Multiple shared memory segments can be registered with CMM.
11 * Each registered SM segment is represented by a SM "allocator" that
12 * describes a block of physically contiguous shared memory used for
13 * future allocations by CMM.
15 * Memory is coalesced back to the appropriate heap when a buffer is
16 * freed.
18 * Notes:
19 * Va: Virtual address.
20 * Pa: Physical or kernel system address.
22 * Copyright (C) 2005-2006 Texas Instruments, Inc.
24 * This package is free software; you can redistribute it and/or modify
25 * it under the terms of the GNU General Public License version 2 as
26 * published by the Free Software Foundation.
28 * THIS PACKAGE IS PROVIDED ``AS IS'' AND WITHOUT ANY EXPRESS OR
29 * IMPLIED WARRANTIES, INCLUDING, WITHOUT LIMITATION, THE IMPLIED
30 * WARRANTIES OF MERCHANTIBILITY AND FITNESS FOR A PARTICULAR PURPOSE.
32 #include <linux/types.h>
33 #include <linux/list.h>
35 /* ----------------------------------- DSP/BIOS Bridge */
36 #include <dspbridge/dbdefs.h>
38 /* ----------------------------------- Trace & Debug */
39 #include <dspbridge/dbc.h>
41 /* ----------------------------------- OS Adaptation Layer */
42 #include <dspbridge/sync.h>
44 /* ----------------------------------- Platform Manager */
45 #include <dspbridge/dev.h>
46 #include <dspbridge/proc.h>
48 /* ----------------------------------- This */
49 #include <dspbridge/cmm.h>
51 /* ----------------------------------- Defines, Data Structures, Typedefs */
52 #define NEXT_PA(pnode) (pnode->pa + pnode->size)
54 /* Other bus/platform translations */
55 #define DSPPA2GPPPA(base, x, y) ((x)+(y))
56 #define GPPPA2DSPPA(base, x, y) ((x)-(y))
59 * Allocators define a block of contiguous memory used for future allocations.
61 * sma - shared memory allocator.
62 * vma - virtual memory allocator.(not used).
64 struct cmm_allocator { /* sma */
65 unsigned int shm_base; /* Start of physical SM block */
66 u32 sm_size; /* Size of SM block in bytes */
67 unsigned int vm_base; /* Start of VM block. (Dev driver
68 * context for 'sma') */
69 u32 dsp_phys_addr_offset; /* DSP PA to GPP PA offset for this
70 * SM space */
71 s8 c_factor; /* DSPPa to GPPPa Conversion Factor */
72 unsigned int dsp_base; /* DSP virt base byte address */
73 u32 dsp_size; /* DSP seg size in bytes */
74 struct cmm_object *cmm_mgr; /* back ref to parent mgr */
75 /* node list of available memory */
76 struct list_head free_list;
77 /* node list of memory in use */
78 struct list_head in_use_list;
81 struct cmm_xlator { /* Pa<->Va translator object */
82 /* CMM object this translator associated */
83 struct cmm_object *cmm_mgr;
85 * Client process virtual base address that corresponds to phys SM
86 * base address for translator's seg_id.
87 * Only 1 segment ID currently supported.
89 unsigned int virt_base; /* virtual base address */
90 u32 virt_size; /* size of virt space in bytes */
91 u32 seg_id; /* Segment Id */
94 /* CMM Mgr */
95 struct cmm_object {
97 * Cmm Lock is used to serialize access mem manager for multi-threads.
99 struct mutex cmm_lock; /* Lock to access cmm mgr */
100 struct list_head node_free_list; /* Free list of memory nodes */
101 u32 min_block_size; /* Min SM block; default 16 bytes */
102 u32 page_size; /* Memory Page size (1k/4k) */
103 /* GPP SM segment ptrs */
104 struct cmm_allocator *pa_gppsm_seg_tab[CMM_MAXGPPSEGS];
107 /* Default CMM Mgr attributes */
108 static struct cmm_mgrattrs cmm_dfltmgrattrs = {
109 /* min_block_size, min block size(bytes) allocated by cmm mgr */
113 /* Default allocation attributes */
114 static struct cmm_attrs cmm_dfltalctattrs = {
115 1 /* seg_id, default segment Id for allocator */
118 /* Address translator default attrs */
119 static struct cmm_xlatorattrs cmm_dfltxlatorattrs = {
120 /* seg_id, does not have to match cmm_dfltalctattrs ul_seg_id */
122 0, /* dsp_bufs */
123 0, /* dsp_buf_size */
124 NULL, /* vm_base */
125 0, /* vm_size */
128 /* SM node representing a block of memory. */
129 struct cmm_mnode {
130 struct list_head link; /* must be 1st element */
131 u32 pa; /* Phys addr */
132 u32 va; /* Virtual address in device process context */
133 u32 size; /* SM block size in bytes */
134 u32 client_proc; /* Process that allocated this mem block */
137 /* ----------------------------------- Globals */
138 static u32 refs; /* module reference count */
140 /* ----------------------------------- Function Prototypes */
141 static void add_to_free_list(struct cmm_allocator *allocator,
142 struct cmm_mnode *pnode);
143 static struct cmm_allocator *get_allocator(struct cmm_object *cmm_mgr_obj,
144 u32 ul_seg_id);
145 static struct cmm_mnode *get_free_block(struct cmm_allocator *allocator,
146 u32 usize);
147 static struct cmm_mnode *get_node(struct cmm_object *cmm_mgr_obj, u32 dw_pa,
148 u32 dw_va, u32 ul_size);
149 /* get available slot for new allocator */
150 static s32 get_slot(struct cmm_object *cmm_mgr_obj);
151 static void un_register_gppsm_seg(struct cmm_allocator *psma);
154 * ======== cmm_calloc_buf ========
155 * Purpose:
156 * Allocate a SM buffer, zero contents, and return the physical address
157 * and optional driver context virtual address(pp_buf_va).
159 * The freelist is sorted in increasing size order. Get the first
160 * block that satifies the request and sort the remaining back on
161 * the freelist; if large enough. The kept block is placed on the
162 * inUseList.
164 void *cmm_calloc_buf(struct cmm_object *hcmm_mgr, u32 usize,
165 struct cmm_attrs *pattrs, void **pp_buf_va)
167 struct cmm_object *cmm_mgr_obj = (struct cmm_object *)hcmm_mgr;
168 void *buf_pa = NULL;
169 struct cmm_mnode *pnode = NULL;
170 struct cmm_mnode *new_node = NULL;
171 struct cmm_allocator *allocator = NULL;
172 u32 delta_size;
173 u8 *pbyte = NULL;
174 s32 cnt;
176 if (pattrs == NULL)
177 pattrs = &cmm_dfltalctattrs;
179 if (pp_buf_va != NULL)
180 *pp_buf_va = NULL;
182 if (cmm_mgr_obj && (usize != 0)) {
183 if (pattrs->seg_id > 0) {
184 /* SegId > 0 is SM */
185 /* get the allocator object for this segment id */
186 allocator =
187 get_allocator(cmm_mgr_obj, pattrs->seg_id);
188 /* keep block size a multiple of min_block_size */
189 usize =
190 ((usize - 1) & ~(cmm_mgr_obj->min_block_size -
192 + cmm_mgr_obj->min_block_size;
193 mutex_lock(&cmm_mgr_obj->cmm_lock);
194 pnode = get_free_block(allocator, usize);
196 if (pnode) {
197 delta_size = (pnode->size - usize);
198 if (delta_size >= cmm_mgr_obj->min_block_size) {
199 /* create a new block with the leftovers and
200 * add to freelist */
201 new_node =
202 get_node(cmm_mgr_obj, pnode->pa + usize,
203 pnode->va + usize,
204 (u32) delta_size);
205 /* leftovers go free */
206 add_to_free_list(allocator, new_node);
207 /* adjust our node's size */
208 pnode->size = usize;
210 /* Tag node with client process requesting allocation
211 * We'll need to free up a process's alloc'd SM if the
212 * client process goes away.
214 /* Return TGID instead of process handle */
215 pnode->client_proc = current->tgid;
217 /* put our node on InUse list */
218 list_add_tail(&pnode->link, &allocator->in_use_list);
219 buf_pa = (void *)pnode->pa; /* physical address */
220 /* clear mem */
221 pbyte = (u8 *) pnode->va;
222 for (cnt = 0; cnt < (s32) usize; cnt++, pbyte++)
223 *pbyte = 0;
225 if (pp_buf_va != NULL) {
226 /* Virtual address */
227 *pp_buf_va = (void *)pnode->va;
230 mutex_unlock(&cmm_mgr_obj->cmm_lock);
232 return buf_pa;
236 * ======== cmm_create ========
237 * Purpose:
238 * Create a communication memory manager object.
240 int cmm_create(struct cmm_object **ph_cmm_mgr,
241 struct dev_object *hdev_obj,
242 const struct cmm_mgrattrs *mgr_attrts)
244 struct cmm_object *cmm_obj = NULL;
245 int status = 0;
247 DBC_REQUIRE(refs > 0);
248 DBC_REQUIRE(ph_cmm_mgr != NULL);
250 *ph_cmm_mgr = NULL;
251 /* create, zero, and tag a cmm mgr object */
252 cmm_obj = kzalloc(sizeof(struct cmm_object), GFP_KERNEL);
253 if (!cmm_obj)
254 return -ENOMEM;
256 if (mgr_attrts == NULL)
257 mgr_attrts = &cmm_dfltmgrattrs; /* set defaults */
259 /* 4 bytes minimum */
260 DBC_ASSERT(mgr_attrts->min_block_size >= 4);
261 /* save away smallest block allocation for this cmm mgr */
262 cmm_obj->min_block_size = mgr_attrts->min_block_size;
263 cmm_obj->page_size = PAGE_SIZE;
265 /* create node free list */
266 INIT_LIST_HEAD(&cmm_obj->node_free_list);
267 mutex_init(&cmm_obj->cmm_lock);
268 *ph_cmm_mgr = cmm_obj;
270 return status;
274 * ======== cmm_destroy ========
275 * Purpose:
276 * Release the communication memory manager resources.
278 int cmm_destroy(struct cmm_object *hcmm_mgr, bool force)
280 struct cmm_object *cmm_mgr_obj = (struct cmm_object *)hcmm_mgr;
281 struct cmm_info temp_info;
282 int status = 0;
283 s32 slot_seg;
284 struct cmm_mnode *node, *tmp;
286 DBC_REQUIRE(refs > 0);
287 if (!hcmm_mgr) {
288 status = -EFAULT;
289 return status;
291 mutex_lock(&cmm_mgr_obj->cmm_lock);
292 /* If not force then fail if outstanding allocations exist */
293 if (!force) {
294 /* Check for outstanding memory allocations */
295 status = cmm_get_info(hcmm_mgr, &temp_info);
296 if (!status) {
297 if (temp_info.total_in_use_cnt > 0) {
298 /* outstanding allocations */
299 status = -EPERM;
303 if (!status) {
304 /* UnRegister SM allocator */
305 for (slot_seg = 0; slot_seg < CMM_MAXGPPSEGS; slot_seg++) {
306 if (cmm_mgr_obj->pa_gppsm_seg_tab[slot_seg] != NULL) {
307 un_register_gppsm_seg
308 (cmm_mgr_obj->pa_gppsm_seg_tab[slot_seg]);
309 /* Set slot to NULL for future reuse */
310 cmm_mgr_obj->pa_gppsm_seg_tab[slot_seg] = NULL;
314 list_for_each_entry_safe(node, tmp, &cmm_mgr_obj->node_free_list,
315 link) {
316 list_del(&node->link);
317 kfree(node);
319 mutex_unlock(&cmm_mgr_obj->cmm_lock);
320 if (!status) {
321 /* delete CS & cmm mgr object */
322 mutex_destroy(&cmm_mgr_obj->cmm_lock);
323 kfree(cmm_mgr_obj);
325 return status;
329 * ======== cmm_exit ========
330 * Purpose:
331 * Discontinue usage of module; free resources when reference count
332 * reaches 0.
334 void cmm_exit(void)
336 DBC_REQUIRE(refs > 0);
338 refs--;
342 * ======== cmm_free_buf ========
343 * Purpose:
344 * Free the given buffer.
346 int cmm_free_buf(struct cmm_object *hcmm_mgr, void *buf_pa, u32 ul_seg_id)
348 struct cmm_object *cmm_mgr_obj = (struct cmm_object *)hcmm_mgr;
349 int status = -EFAULT;
350 struct cmm_mnode *curr, *tmp;
351 struct cmm_allocator *allocator;
352 struct cmm_attrs *pattrs;
354 DBC_REQUIRE(refs > 0);
355 DBC_REQUIRE(buf_pa != NULL);
357 if (ul_seg_id == 0) {
358 pattrs = &cmm_dfltalctattrs;
359 ul_seg_id = pattrs->seg_id;
361 if (!hcmm_mgr || !(ul_seg_id > 0)) {
362 status = -EFAULT;
363 return status;
366 allocator = get_allocator(cmm_mgr_obj, ul_seg_id);
367 if (!allocator)
368 return status;
370 mutex_lock(&cmm_mgr_obj->cmm_lock);
371 list_for_each_entry_safe(curr, tmp, &allocator->in_use_list, link) {
372 if (curr->pa == (u32) buf_pa) {
373 list_del(&curr->link);
374 add_to_free_list(allocator, curr);
375 status = 0;
376 break;
379 mutex_unlock(&cmm_mgr_obj->cmm_lock);
381 return status;
385 * ======== cmm_get_handle ========
386 * Purpose:
387 * Return the communication memory manager object for this device.
388 * This is typically called from the client process.
390 int cmm_get_handle(void *hprocessor, struct cmm_object ** ph_cmm_mgr)
392 int status = 0;
393 struct dev_object *hdev_obj;
395 DBC_REQUIRE(refs > 0);
396 DBC_REQUIRE(ph_cmm_mgr != NULL);
397 if (hprocessor != NULL)
398 status = proc_get_dev_object(hprocessor, &hdev_obj);
399 else
400 hdev_obj = dev_get_first(); /* default */
402 if (!status)
403 status = dev_get_cmm_mgr(hdev_obj, ph_cmm_mgr);
405 return status;
409 * ======== cmm_get_info ========
410 * Purpose:
411 * Return the current memory utilization information.
413 int cmm_get_info(struct cmm_object *hcmm_mgr,
414 struct cmm_info *cmm_info_obj)
416 struct cmm_object *cmm_mgr_obj = (struct cmm_object *)hcmm_mgr;
417 u32 ul_seg;
418 int status = 0;
419 struct cmm_allocator *altr;
420 struct cmm_mnode *curr;
422 DBC_REQUIRE(cmm_info_obj != NULL);
424 if (!hcmm_mgr) {
425 status = -EFAULT;
426 return status;
428 mutex_lock(&cmm_mgr_obj->cmm_lock);
429 cmm_info_obj->num_gppsm_segs = 0; /* # of SM segments */
430 /* Total # of outstanding alloc */
431 cmm_info_obj->total_in_use_cnt = 0;
432 /* min block size */
433 cmm_info_obj->min_block_size = cmm_mgr_obj->min_block_size;
434 /* check SM memory segments */
435 for (ul_seg = 1; ul_seg <= CMM_MAXGPPSEGS; ul_seg++) {
436 /* get the allocator object for this segment id */
437 altr = get_allocator(cmm_mgr_obj, ul_seg);
438 if (!altr)
439 continue;
440 cmm_info_obj->num_gppsm_segs++;
441 cmm_info_obj->seg_info[ul_seg - 1].seg_base_pa =
442 altr->shm_base - altr->dsp_size;
443 cmm_info_obj->seg_info[ul_seg - 1].total_seg_size =
444 altr->dsp_size + altr->sm_size;
445 cmm_info_obj->seg_info[ul_seg - 1].gpp_base_pa =
446 altr->shm_base;
447 cmm_info_obj->seg_info[ul_seg - 1].gpp_size =
448 altr->sm_size;
449 cmm_info_obj->seg_info[ul_seg - 1].dsp_base_va =
450 altr->dsp_base;
451 cmm_info_obj->seg_info[ul_seg - 1].dsp_size =
452 altr->dsp_size;
453 cmm_info_obj->seg_info[ul_seg - 1].seg_base_va =
454 altr->vm_base - altr->dsp_size;
455 cmm_info_obj->seg_info[ul_seg - 1].in_use_cnt = 0;
457 list_for_each_entry(curr, &altr->in_use_list, link) {
458 cmm_info_obj->total_in_use_cnt++;
459 cmm_info_obj->seg_info[ul_seg - 1].in_use_cnt++;
462 mutex_unlock(&cmm_mgr_obj->cmm_lock);
463 return status;
467 * ======== cmm_init ========
468 * Purpose:
469 * Initializes private state of CMM module.
471 bool cmm_init(void)
473 bool ret = true;
475 DBC_REQUIRE(refs >= 0);
476 if (ret)
477 refs++;
479 DBC_ENSURE((ret && (refs > 0)) || (!ret && (refs >= 0)));
481 return ret;
485 * ======== cmm_register_gppsm_seg ========
486 * Purpose:
487 * Register a block of SM with the CMM to be used for later GPP SM
488 * allocations.
490 int cmm_register_gppsm_seg(struct cmm_object *hcmm_mgr,
491 u32 dw_gpp_base_pa, u32 ul_size,
492 u32 dsp_addr_offset, s8 c_factor,
493 u32 dw_dsp_base, u32 ul_dsp_size,
494 u32 *sgmt_id, u32 gpp_base_va)
496 struct cmm_object *cmm_mgr_obj = (struct cmm_object *)hcmm_mgr;
497 struct cmm_allocator *psma = NULL;
498 int status = 0;
499 struct cmm_mnode *new_node;
500 s32 slot_seg;
502 DBC_REQUIRE(ul_size > 0);
503 DBC_REQUIRE(sgmt_id != NULL);
504 DBC_REQUIRE(dw_gpp_base_pa != 0);
505 DBC_REQUIRE(gpp_base_va != 0);
506 DBC_REQUIRE((c_factor <= CMM_ADDTODSPPA) &&
507 (c_factor >= CMM_SUBFROMDSPPA));
509 dev_dbg(bridge, "%s: dw_gpp_base_pa %x ul_size %x dsp_addr_offset %x "
510 "dw_dsp_base %x ul_dsp_size %x gpp_base_va %x\n",
511 __func__, dw_gpp_base_pa, ul_size, dsp_addr_offset,
512 dw_dsp_base, ul_dsp_size, gpp_base_va);
514 if (!hcmm_mgr)
515 return -EFAULT;
517 /* make sure we have room for another allocator */
518 mutex_lock(&cmm_mgr_obj->cmm_lock);
520 slot_seg = get_slot(cmm_mgr_obj);
521 if (slot_seg < 0) {
522 status = -EPERM;
523 goto func_end;
526 /* Check if input ul_size is big enough to alloc at least one block */
527 if (ul_size < cmm_mgr_obj->min_block_size) {
528 status = -EINVAL;
529 goto func_end;
532 /* create, zero, and tag an SM allocator object */
533 psma = kzalloc(sizeof(struct cmm_allocator), GFP_KERNEL);
534 if (!psma) {
535 status = -ENOMEM;
536 goto func_end;
539 psma->cmm_mgr = hcmm_mgr; /* ref to parent */
540 psma->shm_base = dw_gpp_base_pa; /* SM Base phys */
541 psma->sm_size = ul_size; /* SM segment size in bytes */
542 psma->vm_base = gpp_base_va;
543 psma->dsp_phys_addr_offset = dsp_addr_offset;
544 psma->c_factor = c_factor;
545 psma->dsp_base = dw_dsp_base;
546 psma->dsp_size = ul_dsp_size;
547 if (psma->vm_base == 0) {
548 status = -EPERM;
549 goto func_end;
551 /* return the actual segment identifier */
552 *sgmt_id = (u32) slot_seg + 1;
554 INIT_LIST_HEAD(&psma->free_list);
555 INIT_LIST_HEAD(&psma->in_use_list);
557 /* Get a mem node for this hunk-o-memory */
558 new_node = get_node(cmm_mgr_obj, dw_gpp_base_pa,
559 psma->vm_base, ul_size);
560 /* Place node on the SM allocator's free list */
561 if (new_node) {
562 list_add_tail(&new_node->link, &psma->free_list);
563 } else {
564 status = -ENOMEM;
565 goto func_end;
567 /* make entry */
568 cmm_mgr_obj->pa_gppsm_seg_tab[slot_seg] = psma;
570 func_end:
571 /* Cleanup allocator */
572 if (status && psma)
573 un_register_gppsm_seg(psma);
574 mutex_unlock(&cmm_mgr_obj->cmm_lock);
576 return status;
580 * ======== cmm_un_register_gppsm_seg ========
581 * Purpose:
582 * UnRegister GPP SM segments with the CMM.
584 int cmm_un_register_gppsm_seg(struct cmm_object *hcmm_mgr,
585 u32 ul_seg_id)
587 struct cmm_object *cmm_mgr_obj = (struct cmm_object *)hcmm_mgr;
588 int status = 0;
589 struct cmm_allocator *psma;
590 u32 ul_id = ul_seg_id;
592 DBC_REQUIRE(ul_seg_id > 0);
593 if (!hcmm_mgr)
594 return -EFAULT;
596 if (ul_seg_id == CMM_ALLSEGMENTS)
597 ul_id = 1;
599 if ((ul_id <= 0) || (ul_id > CMM_MAXGPPSEGS))
600 return -EINVAL;
603 * FIXME: CMM_MAXGPPSEGS == 1. why use a while cycle? Seems to me like
604 * the ul_seg_id is not needed here. It must be always 1.
606 while (ul_id <= CMM_MAXGPPSEGS) {
607 mutex_lock(&cmm_mgr_obj->cmm_lock);
608 /* slot = seg_id-1 */
609 psma = cmm_mgr_obj->pa_gppsm_seg_tab[ul_id - 1];
610 if (psma != NULL) {
611 un_register_gppsm_seg(psma);
612 /* Set alctr ptr to NULL for future reuse */
613 cmm_mgr_obj->pa_gppsm_seg_tab[ul_id - 1] = NULL;
614 } else if (ul_seg_id != CMM_ALLSEGMENTS) {
615 status = -EPERM;
617 mutex_unlock(&cmm_mgr_obj->cmm_lock);
618 if (ul_seg_id != CMM_ALLSEGMENTS)
619 break;
621 ul_id++;
622 } /* end while */
623 return status;
627 * ======== un_register_gppsm_seg ========
628 * Purpose:
629 * UnRegister the SM allocator by freeing all its resources and
630 * nulling cmm mgr table entry.
631 * Note:
632 * This routine is always called within cmm lock crit sect.
634 static void un_register_gppsm_seg(struct cmm_allocator *psma)
636 struct cmm_mnode *curr, *tmp;
638 DBC_REQUIRE(psma != NULL);
640 /* free nodes on free list */
641 list_for_each_entry_safe(curr, tmp, &psma->free_list, link) {
642 list_del(&curr->link);
643 kfree(curr);
646 /* free nodes on InUse list */
647 list_for_each_entry_safe(curr, tmp, &psma->in_use_list, link) {
648 list_del(&curr->link);
649 kfree(curr);
652 if ((void *)psma->vm_base != NULL)
653 MEM_UNMAP_LINEAR_ADDRESS((void *)psma->vm_base);
655 /* Free allocator itself */
656 kfree(psma);
660 * ======== get_slot ========
661 * Purpose:
662 * An available slot # is returned. Returns negative on failure.
664 static s32 get_slot(struct cmm_object *cmm_mgr_obj)
666 s32 slot_seg = -1; /* neg on failure */
667 DBC_REQUIRE(cmm_mgr_obj != NULL);
668 /* get first available slot in cmm mgr SMSegTab[] */
669 for (slot_seg = 0; slot_seg < CMM_MAXGPPSEGS; slot_seg++) {
670 if (cmm_mgr_obj->pa_gppsm_seg_tab[slot_seg] == NULL)
671 break;
674 if (slot_seg == CMM_MAXGPPSEGS)
675 slot_seg = -1; /* failed */
677 return slot_seg;
681 * ======== get_node ========
682 * Purpose:
683 * Get a memory node from freelist or create a new one.
685 static struct cmm_mnode *get_node(struct cmm_object *cmm_mgr_obj, u32 dw_pa,
686 u32 dw_va, u32 ul_size)
688 struct cmm_mnode *pnode;
690 DBC_REQUIRE(cmm_mgr_obj != NULL);
691 DBC_REQUIRE(dw_pa != 0);
692 DBC_REQUIRE(dw_va != 0);
693 DBC_REQUIRE(ul_size != 0);
695 /* Check cmm mgr's node freelist */
696 if (list_empty(&cmm_mgr_obj->node_free_list)) {
697 pnode = kzalloc(sizeof(struct cmm_mnode), GFP_KERNEL);
698 if (!pnode)
699 return NULL;
700 } else {
701 /* surely a valid element */
702 pnode = list_first_entry(&cmm_mgr_obj->node_free_list,
703 struct cmm_mnode, link);
704 list_del_init(&pnode->link);
707 pnode->pa = dw_pa;
708 pnode->va = dw_va;
709 pnode->size = ul_size;
711 return pnode;
715 * ======== delete_node ========
716 * Purpose:
717 * Put a memory node on the cmm nodelist for later use.
718 * Doesn't actually delete the node. Heap thrashing friendly.
720 static void delete_node(struct cmm_object *cmm_mgr_obj, struct cmm_mnode *pnode)
722 DBC_REQUIRE(pnode != NULL);
723 list_add_tail(&pnode->link, &cmm_mgr_obj->node_free_list);
727 * ====== get_free_block ========
728 * Purpose:
729 * Scan the free block list and return the first block that satisfies
730 * the size.
732 static struct cmm_mnode *get_free_block(struct cmm_allocator *allocator,
733 u32 usize)
735 struct cmm_mnode *node, *tmp;
737 if (!allocator)
738 return NULL;
740 list_for_each_entry_safe(node, tmp, &allocator->free_list, link) {
741 if (usize <= node->size) {
742 list_del(&node->link);
743 return node;
747 return NULL;
751 * ======== add_to_free_list ========
752 * Purpose:
753 * Coalesce node into the freelist in ascending size order.
755 static void add_to_free_list(struct cmm_allocator *allocator,
756 struct cmm_mnode *node)
758 struct cmm_mnode *curr;
760 if (!node) {
761 pr_err("%s: failed - node is NULL\n", __func__);
762 return;
765 list_for_each_entry(curr, &allocator->free_list, link) {
766 if (NEXT_PA(curr) == node->pa) {
767 curr->size += node->size;
768 delete_node(allocator->cmm_mgr, node);
769 return;
771 if (curr->pa == NEXT_PA(node)) {
772 curr->pa = node->pa;
773 curr->va = node->va;
774 curr->size += node->size;
775 delete_node(allocator->cmm_mgr, node);
776 return;
779 list_for_each_entry(curr, &allocator->free_list, link) {
780 if (curr->size >= node->size) {
781 list_add_tail(&node->link, &curr->link);
782 return;
785 list_add_tail(&node->link, &allocator->free_list);
789 * ======== get_allocator ========
790 * Purpose:
791 * Return the allocator for the given SM Segid.
792 * SegIds: 1,2,3..max.
794 static struct cmm_allocator *get_allocator(struct cmm_object *cmm_mgr_obj,
795 u32 ul_seg_id)
797 DBC_REQUIRE(cmm_mgr_obj != NULL);
798 DBC_REQUIRE((ul_seg_id > 0) && (ul_seg_id <= CMM_MAXGPPSEGS));
800 return cmm_mgr_obj->pa_gppsm_seg_tab[ul_seg_id - 1];
804 * The CMM_Xlator[xxx] routines below are used by Node and Stream
805 * to perform SM address translation to the client process address space.
806 * A "translator" object is created by a node/stream for each SM seg used.
810 * ======== cmm_xlator_create ========
811 * Purpose:
812 * Create an address translator object.
814 int cmm_xlator_create(struct cmm_xlatorobject **xlator,
815 struct cmm_object *hcmm_mgr,
816 struct cmm_xlatorattrs *xlator_attrs)
818 struct cmm_xlator *xlator_object = NULL;
819 int status = 0;
821 DBC_REQUIRE(refs > 0);
822 DBC_REQUIRE(xlator != NULL);
823 DBC_REQUIRE(hcmm_mgr != NULL);
825 *xlator = NULL;
826 if (xlator_attrs == NULL)
827 xlator_attrs = &cmm_dfltxlatorattrs; /* set defaults */
829 xlator_object = kzalloc(sizeof(struct cmm_xlator), GFP_KERNEL);
830 if (xlator_object != NULL) {
831 xlator_object->cmm_mgr = hcmm_mgr; /* ref back to CMM */
832 /* SM seg_id */
833 xlator_object->seg_id = xlator_attrs->seg_id;
834 } else {
835 status = -ENOMEM;
837 if (!status)
838 *xlator = (struct cmm_xlatorobject *)xlator_object;
840 return status;
844 * ======== cmm_xlator_alloc_buf ========
846 void *cmm_xlator_alloc_buf(struct cmm_xlatorobject *xlator, void *va_buf,
847 u32 pa_size)
849 struct cmm_xlator *xlator_obj = (struct cmm_xlator *)xlator;
850 void *pbuf = NULL;
851 void *tmp_va_buff;
852 struct cmm_attrs attrs;
854 DBC_REQUIRE(refs > 0);
855 DBC_REQUIRE(xlator != NULL);
856 DBC_REQUIRE(xlator_obj->cmm_mgr != NULL);
857 DBC_REQUIRE(va_buf != NULL);
858 DBC_REQUIRE(pa_size > 0);
859 DBC_REQUIRE(xlator_obj->seg_id > 0);
861 if (xlator_obj) {
862 attrs.seg_id = xlator_obj->seg_id;
863 __raw_writel(0, va_buf);
864 /* Alloc SM */
865 pbuf =
866 cmm_calloc_buf(xlator_obj->cmm_mgr, pa_size, &attrs, NULL);
867 if (pbuf) {
868 /* convert to translator(node/strm) process Virtual
869 * address */
870 tmp_va_buff = cmm_xlator_translate(xlator,
871 pbuf, CMM_PA2VA);
872 __raw_writel((u32)tmp_va_buff, va_buf);
875 return pbuf;
879 * ======== cmm_xlator_free_buf ========
880 * Purpose:
881 * Free the given SM buffer and descriptor.
882 * Does not free virtual memory.
884 int cmm_xlator_free_buf(struct cmm_xlatorobject *xlator, void *buf_va)
886 struct cmm_xlator *xlator_obj = (struct cmm_xlator *)xlator;
887 int status = -EPERM;
888 void *buf_pa = NULL;
890 DBC_REQUIRE(refs > 0);
891 DBC_REQUIRE(buf_va != NULL);
892 DBC_REQUIRE(xlator_obj->seg_id > 0);
894 if (xlator_obj) {
895 /* convert Va to Pa so we can free it. */
896 buf_pa = cmm_xlator_translate(xlator, buf_va, CMM_VA2PA);
897 if (buf_pa) {
898 status = cmm_free_buf(xlator_obj->cmm_mgr, buf_pa,
899 xlator_obj->seg_id);
900 if (status) {
901 /* Uh oh, this shouldn't happen. Descriptor
902 * gone! */
903 DBC_ASSERT(false); /* CMM is leaking mem */
907 return status;
911 * ======== cmm_xlator_info ========
912 * Purpose:
913 * Set/Get translator info.
915 int cmm_xlator_info(struct cmm_xlatorobject *xlator, u8 ** paddr,
916 u32 ul_size, u32 segm_id, bool set_info)
918 struct cmm_xlator *xlator_obj = (struct cmm_xlator *)xlator;
919 int status = 0;
921 DBC_REQUIRE(refs > 0);
922 DBC_REQUIRE(paddr != NULL);
923 DBC_REQUIRE((segm_id > 0) && (segm_id <= CMM_MAXGPPSEGS));
925 if (xlator_obj) {
926 if (set_info) {
927 /* set translators virtual address range */
928 xlator_obj->virt_base = (u32) *paddr;
929 xlator_obj->virt_size = ul_size;
930 } else { /* return virt base address */
931 *paddr = (u8 *) xlator_obj->virt_base;
933 } else {
934 status = -EFAULT;
936 return status;
940 * ======== cmm_xlator_translate ========
942 void *cmm_xlator_translate(struct cmm_xlatorobject *xlator, void *paddr,
943 enum cmm_xlatetype xtype)
945 u32 dw_addr_xlate = 0;
946 struct cmm_xlator *xlator_obj = (struct cmm_xlator *)xlator;
947 struct cmm_object *cmm_mgr_obj = NULL;
948 struct cmm_allocator *allocator = NULL;
949 u32 dw_offset = 0;
951 DBC_REQUIRE(refs > 0);
952 DBC_REQUIRE(paddr != NULL);
953 DBC_REQUIRE((xtype >= CMM_VA2PA) && (xtype <= CMM_DSPPA2PA));
955 if (!xlator_obj)
956 goto loop_cont;
958 cmm_mgr_obj = (struct cmm_object *)xlator_obj->cmm_mgr;
959 /* get this translator's default SM allocator */
960 DBC_ASSERT(xlator_obj->seg_id > 0);
961 allocator = cmm_mgr_obj->pa_gppsm_seg_tab[xlator_obj->seg_id - 1];
962 if (!allocator)
963 goto loop_cont;
965 if ((xtype == CMM_VA2DSPPA) || (xtype == CMM_VA2PA) ||
966 (xtype == CMM_PA2VA)) {
967 if (xtype == CMM_PA2VA) {
968 /* Gpp Va = Va Base + offset */
969 dw_offset = (u8 *) paddr - (u8 *) (allocator->shm_base -
970 allocator->
971 dsp_size);
972 dw_addr_xlate = xlator_obj->virt_base + dw_offset;
973 /* Check if translated Va base is in range */
974 if ((dw_addr_xlate < xlator_obj->virt_base) ||
975 (dw_addr_xlate >=
976 (xlator_obj->virt_base +
977 xlator_obj->virt_size))) {
978 dw_addr_xlate = 0; /* bad address */
980 } else {
981 /* Gpp PA = Gpp Base + offset */
982 dw_offset =
983 (u8 *) paddr - (u8 *) xlator_obj->virt_base;
984 dw_addr_xlate =
985 allocator->shm_base - allocator->dsp_size +
986 dw_offset;
988 } else {
989 dw_addr_xlate = (u32) paddr;
991 /*Now convert address to proper target physical address if needed */
992 if ((xtype == CMM_VA2DSPPA) || (xtype == CMM_PA2DSPPA)) {
993 /* Got Gpp Pa now, convert to DSP Pa */
994 dw_addr_xlate =
995 GPPPA2DSPPA((allocator->shm_base - allocator->dsp_size),
996 dw_addr_xlate,
997 allocator->dsp_phys_addr_offset *
998 allocator->c_factor);
999 } else if (xtype == CMM_DSPPA2PA) {
1000 /* Got DSP Pa, convert to GPP Pa */
1001 dw_addr_xlate =
1002 DSPPA2GPPPA(allocator->shm_base - allocator->dsp_size,
1003 dw_addr_xlate,
1004 allocator->dsp_phys_addr_offset *
1005 allocator->c_factor);
1007 loop_cont:
1008 return (void *)dw_addr_xlate;