xref: /freebsd/sys/contrib/ncsw/etc/mm.c (revision 8ef24a0d4b28fe230e20637f56869cc4148cd2ca)
1 /* Copyright (c) 2008-2011 Freescale Semiconductor, Inc.
2  * All rights reserved.
3  *
4  * Redistribution and use in source and binary forms, with or without
5  * modification, are permitted provided that the following conditions are met:
6  *     * Redistributions of source code must retain the above copyright
7  *       notice, this list of conditions and the following disclaimer.
8  *     * Redistributions in binary form must reproduce the above copyright
9  *       notice, this list of conditions and the following disclaimer in the
10  *       documentation and/or other materials provided with the distribution.
11  *     * Neither the name of Freescale Semiconductor nor the
12  *       names of its contributors may be used to endorse or promote products
13  *       derived from this software without specific prior written permission.
14  *
15  *
16  * ALTERNATIVELY, this software may be distributed under the terms of the
17  * GNU General Public License ("GPL") as published by the Free Software
18  * Foundation, either version 2 of that License or (at your option) any
19  * later version.
20  *
21  * THIS SOFTWARE IS PROVIDED BY Freescale Semiconductor ``AS IS'' AND ANY
22  * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
23  * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
24  * DISCLAIMED. IN NO EVENT SHALL Freescale Semiconductor BE LIABLE FOR ANY
25  * DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
26  * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
27  * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
28  * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
29  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
30  * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
31  */
32 
33 #include "string_ext.h"
34 #include "error_ext.h"
35 #include "std_ext.h"
36 #include "sprint_ext.h"
37 #include "part_ext.h"
38 #include "xx_ext.h"
39 
40 #include "mm.h"
41 
42 
43 
44 
45 /**********************************************************************
46  *                     MM internal routines set                       *
47  **********************************************************************/
48 
49 /****************************************************************
50  *  Routine:   CreateBusyBlock
51  *
52  *  Description:
53  *      Initializes a new busy block of "size" bytes and started
54  *      rom "base" address. Each busy block has a name that
55  *      specified the purpose of the memory allocation.
56  *
57  *  Arguments:
58  *      base      - base address of the busy block
59  *      size      - size of the busy block
60  *      name      - name that specified the busy block
61  *
62  *  Return value:
63  *      A pointer to new created structure returned on success;
64  *      Otherwise, NULL.
65  ****************************************************************/
66 static t_BusyBlock * CreateBusyBlock(uint64_t base, uint64_t size, char *name)
67 {
68     t_BusyBlock *p_BusyBlock;
69     uint32_t    n;
70 
71     p_BusyBlock = (t_BusyBlock *)XX_Malloc(sizeof(t_BusyBlock));
72     if ( !p_BusyBlock )
73     {
74         REPORT_ERROR(MAJOR, E_NO_MEMORY, NO_MSG);
75         return NULL;
76     }
77 
78     p_BusyBlock->base = base;
79     p_BusyBlock->end = base + size;
80 
81     n = strlen(name);
82     if (n >= MM_MAX_NAME_LEN)
83         n = MM_MAX_NAME_LEN - 1;
84     strncpy(p_BusyBlock->name, name, MM_MAX_NAME_LEN-1);
85     p_BusyBlock->name[n] = '\0';
86     p_BusyBlock->p_Next = 0;
87 
88     return p_BusyBlock;
89 }
90 
91 /****************************************************************
92  *  Routine:   CreateNewBlock
93  *
94  *  Description:
95  *      Initializes a new memory block of "size" bytes and started
96  *      from "base" address.
97  *
98  *  Arguments:
99  *      base    - base address of the memory block
100  *      size    - size of the memory block
101  *
102  *  Return value:
103  *      A pointer to new created structure returned on success;
104  *      Otherwise, NULL.
105  ****************************************************************/
106 static t_MemBlock * CreateNewBlock(uint64_t base, uint64_t size)
107 {
108     t_MemBlock *p_MemBlock;
109 
110     p_MemBlock = (t_MemBlock *)XX_Malloc(sizeof(t_MemBlock));
111     if ( !p_MemBlock )
112     {
113         REPORT_ERROR(MAJOR, E_NO_MEMORY, NO_MSG);
114         return NULL;
115     }
116 
117     p_MemBlock->base = base;
118     p_MemBlock->end = base+size;
119     p_MemBlock->p_Next = 0;
120 
121     return p_MemBlock;
122 }
123 
124 /****************************************************************
125  *  Routine:   CreateFreeBlock
126  *
127  *  Description:
128  *      Initializes a new free block of of "size" bytes and
129  *      started from "base" address.
130  *
131  *  Arguments:
132  *      base      - base address of the free block
133  *      size      - size of the free block
134  *
135  *  Return value:
136  *      A pointer to new created structure returned on success;
137  *      Otherwise, NULL.
138  ****************************************************************/
139 static t_FreeBlock * CreateFreeBlock(uint64_t base, uint64_t size)
140 {
141     t_FreeBlock *p_FreeBlock;
142 
143     p_FreeBlock = (t_FreeBlock *)XX_Malloc(sizeof(t_FreeBlock));
144     if ( !p_FreeBlock )
145     {
146         REPORT_ERROR(MAJOR, E_NO_MEMORY, NO_MSG);
147         return NULL;
148     }
149 
150     p_FreeBlock->base = base;
151     p_FreeBlock->end = base + size;
152     p_FreeBlock->p_Next = 0;
153 
154     return p_FreeBlock;
155 }
156 
157 /****************************************************************
158  *  Routine:    AddFree
159  *
160  *  Description:
161  *      Adds a new free block to the free lists. It updates each
162  *      free list to include a new free block.
163  *      Note, that all free block in each free list are ordered
164  *      by their base address.
165  *
166  *  Arguments:
167  *      p_MM  - pointer to the MM object
168  *      base  - base address of a given free block
169  *      end   - end address of a given free block
170  *
171  *  Return value:
172  *
173  *
174  ****************************************************************/
175 static t_Error AddFree(t_MM *p_MM, uint64_t base, uint64_t end)
176 {
177     t_FreeBlock *p_PrevB, *p_CurrB, *p_NewB;
178     uint64_t    alignment;
179     uint64_t    alignBase;
180     int         i;
181 
182     /* Updates free lists to include  a just released block */
183     for (i=0; i <= MM_MAX_ALIGNMENT; i++)
184     {
185         p_PrevB = p_NewB = 0;
186         p_CurrB = p_MM->freeBlocks[i];
187 
188         alignment = (uint64_t)(0x1 << i);
189         alignBase = MAKE_ALIGNED(base, alignment);
190 
191         /* Goes to the next free list if there is no block to free */
192         if (alignBase >= end)
193             continue;
194 
195         /* Looks for a free block that should be updated */
196         while ( p_CurrB )
197         {
198             if ( alignBase <= p_CurrB->end )
199             {
200                 if ( end > p_CurrB->end )
201                 {
202                     t_FreeBlock *p_NextB;
203                     while ( p_CurrB->p_Next && end > p_CurrB->p_Next->end )
204                     {
205                         p_NextB = p_CurrB->p_Next;
206                         p_CurrB->p_Next = p_CurrB->p_Next->p_Next;
207                         XX_Free(p_NextB);
208                     }
209 
210                     p_NextB = p_CurrB->p_Next;
211                     if ( !p_NextB || (p_NextB && end < p_NextB->base) )
212                     {
213                         p_CurrB->end = end;
214                     }
215                     else
216                     {
217                         p_CurrB->end = p_NextB->end;
218                         p_CurrB->p_Next = p_NextB->p_Next;
219                         XX_Free(p_NextB);
220                     }
221                 }
222                 else if ( (end < p_CurrB->base) && ((end-alignBase) >= alignment) )
223                 {
224                     if ((p_NewB = CreateFreeBlock(alignBase, end-alignBase)) == NULL)
225                         RETURN_ERROR(MAJOR, E_NO_MEMORY, NO_MSG);
226 
227                     p_NewB->p_Next = p_CurrB;
228                     if (p_PrevB)
229                         p_PrevB->p_Next = p_NewB;
230                     else
231                         p_MM->freeBlocks[i] = p_NewB;
232                     break;
233                 }
234 
235                 if ((alignBase < p_CurrB->base) && (end >= p_CurrB->base))
236                 {
237                     p_CurrB->base = alignBase;
238                 }
239 
240                 /* if size of the free block is less then alignment
241                  * deletes that free block from the free list. */
242                 if ( (p_CurrB->end - p_CurrB->base) < alignment)
243                 {
244                     if ( p_PrevB )
245                         p_PrevB->p_Next = p_CurrB->p_Next;
246                     else
247                         p_MM->freeBlocks[i] = p_CurrB->p_Next;
248                     XX_Free(p_CurrB);
249                 }
250                 break;
251             }
252             else
253             {
254                 p_PrevB = p_CurrB;
255                 p_CurrB = p_CurrB->p_Next;
256             }
257         }
258 
259         /* If no free block found to be updated, insert a new free block
260          * to the end of the free list.
261          */
262         if ( !p_CurrB && ((((uint64_t)(end-base)) & ((uint64_t)(alignment-1))) == 0) )
263         {
264             if ((p_NewB = CreateFreeBlock(alignBase, end-base)) == NULL)
265                 RETURN_ERROR(MAJOR, E_NO_MEMORY, NO_MSG);
266 
267             if (p_PrevB)
268                 p_PrevB->p_Next = p_NewB;
269             else
270                 p_MM->freeBlocks[i] = p_NewB;
271         }
272 
273         /* Update boundaries of the new free block */
274         if ((alignment == 1) && !p_NewB)
275         {
276             if ( p_CurrB && base > p_CurrB->base )
277                 base = p_CurrB->base;
278             if ( p_CurrB && end < p_CurrB->end )
279                 end = p_CurrB->end;
280         }
281     }
282 
283     return (E_OK);
284 }
285 
286 /****************************************************************
287  *  Routine:      CutFree
288  *
289  *  Description:
290  *      Cuts a free block from holdBase to holdEnd from the free lists.
291  *      That is, it updates all free lists of the MM object do
292  *      not include a block of memory from holdBase to holdEnd.
293  *      For each free lists it seek for a free block that holds
294  *      either holdBase or holdEnd. If such block is found it updates it.
295  *
296  *  Arguments:
297  *      p_MM            - pointer to the MM object
298  *      holdBase        - base address of the allocated block
299  *      holdEnd         - end address of the allocated block
300  *
301  *  Return value:
302  *      E_OK is returned on success,
303  *      otherwise returns an error code.
304  *
305  ****************************************************************/
306 static t_Error CutFree(t_MM *p_MM, uint64_t holdBase, uint64_t holdEnd)
307 {
308     t_FreeBlock *p_PrevB, *p_CurrB, *p_NewB;
309     uint64_t    alignBase, base, end;
310     uint64_t    alignment;
311     int         i;
312 
313     for (i=0; i <= MM_MAX_ALIGNMENT; i++)
314     {
315         p_PrevB = p_NewB = 0;
316         p_CurrB = p_MM->freeBlocks[i];
317 
318         alignment = (uint64_t)(0x1 << i);
319         alignBase = MAKE_ALIGNED(holdEnd, alignment);
320 
321         while ( p_CurrB )
322         {
323             base = p_CurrB->base;
324             end = p_CurrB->end;
325 
326             if ( (holdBase <= base) && (holdEnd <= end) && (holdEnd > base) )
327             {
328                 if ( alignBase >= end ||
329                      (alignBase < end && ((end-alignBase) < alignment)) )
330                 {
331                     if (p_PrevB)
332                         p_PrevB->p_Next = p_CurrB->p_Next;
333                     else
334                         p_MM->freeBlocks[i] = p_CurrB->p_Next;
335                     XX_Free(p_CurrB);
336                 }
337                 else
338                 {
339                     p_CurrB->base = alignBase;
340                 }
341                 break;
342             }
343             else if ( (holdBase > base) && (holdEnd <= end) )
344             {
345                 if ( (holdBase-base) >= alignment )
346                 {
347                     if ( (alignBase < end) && ((end-alignBase) >= alignment) )
348                     {
349                         if ((p_NewB = CreateFreeBlock(alignBase, end-alignBase)) == NULL)
350                             RETURN_ERROR(MAJOR, E_NO_MEMORY, NO_MSG);
351                         p_NewB->p_Next = p_CurrB->p_Next;
352                         p_CurrB->p_Next = p_NewB;
353                     }
354                     p_CurrB->end = holdBase;
355                 }
356                 else if ( (alignBase < end) && ((end-alignBase) >= alignment) )
357                 {
358                     p_CurrB->base = alignBase;
359                 }
360                 else
361                 {
362                     if (p_PrevB)
363                         p_PrevB->p_Next = p_CurrB->p_Next;
364                     else
365                         p_MM->freeBlocks[i] = p_CurrB->p_Next;
366                     XX_Free(p_CurrB);
367                 }
368                 break;
369             }
370             else
371             {
372                 p_PrevB = p_CurrB;
373                 p_CurrB = p_CurrB->p_Next;
374             }
375         }
376     }
377 
378     return (E_OK);
379 }
380 
381 /****************************************************************
382  *  Routine:     AddBusy
383  *
384  *  Description:
385  *      Adds a new busy block to the list of busy blocks. Note,
386  *      that all busy blocks are ordered by their base address in
387  *      the busy list.
388  *
389  *  Arguments:
390  *      MM              - handler to the MM object
391  *      p_NewBusyB      - pointer to the a busy block
392  *
393  *  Return value:
394  *      None.
395  *
396  ****************************************************************/
397 static void AddBusy(t_MM *p_MM, t_BusyBlock *p_NewBusyB)
398 {
399     t_BusyBlock *p_CurrBusyB, *p_PrevBusyB;
400 
401     /* finds a place of a new busy block in the list of busy blocks */
402     p_PrevBusyB = 0;
403     p_CurrBusyB = p_MM->busyBlocks;
404 
405     while ( p_CurrBusyB && p_NewBusyB->base > p_CurrBusyB->base )
406     {
407         p_PrevBusyB = p_CurrBusyB;
408         p_CurrBusyB = p_CurrBusyB->p_Next;
409     }
410 
411     /* insert the new busy block into the list of busy blocks */
412     if ( p_CurrBusyB )
413         p_NewBusyB->p_Next = p_CurrBusyB;
414     if ( p_PrevBusyB )
415         p_PrevBusyB->p_Next = p_NewBusyB;
416     else
417         p_MM->busyBlocks = p_NewBusyB;
418 }
419 
420 /****************************************************************
421  *  Routine:    CutBusy
422  *
423  *  Description:
424  *      Cuts a block from base to end from the list of busy blocks.
425  *      This is done by updating the list of busy blocks do not
426  *      include a given block, that block is going to be free. If a
427  *      given block is a part of some other busy block, so that
428  *      busy block is updated. If there are number of busy blocks
429  *      included in the given block, so all that blocks are removed
430  *      from the busy list and the end blocks are updated.
431  *      If the given block devides some block into two parts, a new
432  *      busy block is added to the busy list.
433  *
434  *  Arguments:
435  *      p_MM  - pointer to the MM object
436  *      base  - base address of a given busy block
437  *      end   - end address of a given busy block
438  *
439  *  Return value:
440  *      E_OK on success, E_NOMEMORY otherwise.
441  *
442  ****************************************************************/
443 static t_Error CutBusy(t_MM *p_MM, uint64_t base, uint64_t end)
444 {
445     t_BusyBlock  *p_CurrB, *p_PrevB, *p_NewB;
446 
447     p_CurrB = p_MM->busyBlocks;
448     p_PrevB = p_NewB = 0;
449 
450     while ( p_CurrB )
451     {
452         if ( base < p_CurrB->end )
453         {
454             if ( end > p_CurrB->end )
455             {
456                 t_BusyBlock *p_NextB;
457                 while ( p_CurrB->p_Next && end >= p_CurrB->p_Next->end )
458                 {
459                     p_NextB = p_CurrB->p_Next;
460                     p_CurrB->p_Next = p_CurrB->p_Next->p_Next;
461                     XX_Free(p_NextB);
462                 }
463 
464                 p_NextB = p_CurrB->p_Next;
465                 if ( p_NextB && end > p_NextB->base )
466                 {
467                     p_NextB->base = end;
468                 }
469             }
470 
471             if ( base <= p_CurrB->base )
472             {
473                 if ( end < p_CurrB->end && end > p_CurrB->base )
474                 {
475                     p_CurrB->base = end;
476                 }
477                 else if ( end >= p_CurrB->end )
478                 {
479                     if ( p_PrevB )
480                         p_PrevB->p_Next = p_CurrB->p_Next;
481                     else
482                         p_MM->busyBlocks = p_CurrB->p_Next;
483                     XX_Free(p_CurrB);
484                 }
485             }
486             else
487             {
488                 if ( end < p_CurrB->end && end > p_CurrB->base )
489                 {
490                     if ((p_NewB = CreateBusyBlock(end,
491                                                   p_CurrB->end-end,
492                                                   p_CurrB->name)) == NULL)
493                         RETURN_ERROR(MAJOR, E_NO_MEMORY, NO_MSG);
494                     p_NewB->p_Next = p_CurrB->p_Next;
495                     p_CurrB->p_Next = p_NewB;
496                 }
497                 p_CurrB->end = base;
498             }
499             break;
500         }
501         else
502         {
503             p_PrevB = p_CurrB;
504             p_CurrB = p_CurrB->p_Next;
505         }
506     }
507 
508     return (E_OK);
509 }
510 
511 /****************************************************************
512  *  Routine:     MmGetGreaterAlignment
513  *
514  *  Description:
515  *      Allocates a block of memory according to the given size
516  *      and the alignment. That routine is called from the MM_Get
517  *      routine if the required alignment is greater then MM_MAX_ALIGNMENT.
518  *      In that case, it goes over free blocks of 64 byte align list
519  *      and checks if it has the required size of bytes of the required
520  *      alignment. If no blocks found returns ILLEGAL_BASE.
521  *      After the block is found and data is allocated, it calls
522  *      the internal CutFree routine to update all free lists
523  *      do not include a just allocated block. Of course, each
524  *      free list contains a free blocks with the same alignment.
525  *      It is also creates a busy block that holds
526  *      information about an allocated block.
527  *
528  *  Arguments:
529  *      MM              - handle to the MM object
530  *      size            - size of the MM
531  *      alignment       - index as a power of two defines
532  *                        a required alignment that is greater then 64.
533  *      name            - the name that specifies an allocated block.
534  *
535  *  Return value:
536  *      base address of an allocated block.
537  *      ILLEGAL_BASE if can't allocate a block
538  *
539  ****************************************************************/
540 static uint64_t MmGetGreaterAlignment(t_MM *p_MM, uint64_t size, uint64_t alignment, char* name)
541 {
542     t_FreeBlock *p_FreeB;
543     t_BusyBlock *p_NewBusyB;
544     uint64_t    holdBase, holdEnd, alignBase = 0;
545 
546     /* goes over free blocks of the 64 byte alignment list
547        and look for a block of the suitable size and
548        base address according to the alignment. */
549     p_FreeB = p_MM->freeBlocks[MM_MAX_ALIGNMENT];
550 
551     while ( p_FreeB )
552     {
553         alignBase = MAKE_ALIGNED(p_FreeB->base, alignment);
554 
555         /* the block is found if the aligned base inside the block
556          * and has the anough size. */
557         if ( alignBase >= p_FreeB->base &&
558              alignBase < p_FreeB->end &&
559              size <= (p_FreeB->end - alignBase) )
560             break;
561         else
562             p_FreeB = p_FreeB->p_Next;
563     }
564 
565     /* If such block isn't found */
566     if ( !p_FreeB )
567         return (uint64_t)(ILLEGAL_BASE);
568 
569     holdBase = alignBase;
570     holdEnd = alignBase + size;
571 
572     /* init a new busy block */
573     if ((p_NewBusyB = CreateBusyBlock(holdBase, size, name)) == NULL)
574         return (uint64_t)(ILLEGAL_BASE);
575 
576     /* calls Update routine to update a lists of free blocks */
577     if ( CutFree ( p_MM, holdBase, holdEnd ) != E_OK )
578         return (uint64_t)(ILLEGAL_BASE);
579 
580     /* insert the new busy block into the list of busy blocks */
581     AddBusy ( p_MM, p_NewBusyB );
582 
583     return (holdBase);
584 }
585 
586 
587 /**********************************************************************
588  *                     MM API routines set                            *
589  **********************************************************************/
590 
591 /*****************************************************************************/
592 t_Error MM_Init(t_Handle *h_MM, uint64_t base, uint64_t size)
593 {
594     t_MM        *p_MM;
595     uint64_t    newBase, newSize;
596     int         i;
597 
598     if (!size)
599     {
600         RETURN_ERROR(MAJOR, E_INVALID_VALUE, ("Size (should be positive)"));
601     }
602 
603     /* Initializes a new MM object */
604     p_MM = (t_MM *)XX_Malloc(sizeof(t_MM));
605     if (!p_MM)
606     {
607         RETURN_ERROR(MAJOR, E_NO_MEMORY, NO_MSG);
608     }
609 
610     p_MM->h_Spinlock = XX_InitSpinlock();
611     if (!p_MM->h_Spinlock)
612     {
613         XX_Free(p_MM);
614         RETURN_ERROR(MAJOR, E_NO_MEMORY, ("MM spinlock!"));
615     }
616 
617     /* initializes a new memory block */
618     if ((p_MM->memBlocks = CreateNewBlock(base, size)) == NULL)
619         RETURN_ERROR(MAJOR, E_NO_MEMORY, NO_MSG);
620 
621     /* A busy list is empty */
622     p_MM->busyBlocks = 0;
623 
624     /*Initializes a new free block for each free list*/
625     for (i=0; i <= MM_MAX_ALIGNMENT; i++)
626     {
627         newBase = MAKE_ALIGNED( base, (0x1 << i) );
628         newSize = size - (newBase - base);
629 
630         if ((p_MM->freeBlocks[i] = CreateFreeBlock(newBase, newSize)) == NULL)
631             RETURN_ERROR(MAJOR, E_NO_MEMORY, NO_MSG);
632     }
633 
634     *h_MM = p_MM;
635 
636     return (E_OK);
637 }
638 
639 /*****************************************************************************/
640 void MM_Free(t_Handle h_MM)
641 {
642     t_MM        *p_MM = (t_MM *)h_MM;
643     t_MemBlock  *p_MemBlock;
644     t_BusyBlock *p_BusyBlock;
645     t_FreeBlock *p_FreeBlock;
646     void        *p_Block;
647     int         i;
648 
649     ASSERT_COND(p_MM);
650 
651     /* release memory allocated for busy blocks */
652     p_BusyBlock = p_MM->busyBlocks;
653     while ( p_BusyBlock )
654     {
655         p_Block = p_BusyBlock;
656         p_BusyBlock = p_BusyBlock->p_Next;
657         XX_Free(p_Block);
658     }
659 
660     /* release memory allocated for free blocks */
661     for (i=0; i <= MM_MAX_ALIGNMENT; i++)
662     {
663         p_FreeBlock = p_MM->freeBlocks[i];
664         while ( p_FreeBlock )
665         {
666             p_Block = p_FreeBlock;
667             p_FreeBlock = p_FreeBlock->p_Next;
668             XX_Free(p_Block);
669         }
670     }
671 
672     /* release memory allocated for memory blocks */
673     p_MemBlock = p_MM->memBlocks;
674     while ( p_MemBlock )
675     {
676         p_Block = p_MemBlock;
677         p_MemBlock = p_MemBlock->p_Next;
678         XX_Free(p_Block);
679     }
680 
681     if (p_MM->h_Spinlock)
682         XX_FreeSpinlock(p_MM->h_Spinlock);
683 
684     /* release memory allocated for MM object itself */
685     XX_Free(p_MM);
686 }
687 
688 /*****************************************************************************/
689 uint64_t MM_Get(t_Handle h_MM, uint64_t size, uint64_t alignment, char* name)
690 {
691     t_MM        *p_MM = (t_MM *)h_MM;
692     t_FreeBlock *p_FreeB;
693     t_BusyBlock *p_NewBusyB;
694     uint64_t    holdBase, holdEnd, j, i = 0;
695     uint32_t    intFlags;
696 
697     SANITY_CHECK_RETURN_VALUE(p_MM, E_INVALID_HANDLE, (uint64_t)ILLEGAL_BASE);
698 
699     /* checks that alignment value is greater then zero */
700     if (alignment == 0)
701     {
702         alignment = 1;
703     }
704 
705     j = alignment;
706 
707     /* checks if alignment is a power of two, if it correct and if the
708        required size is multiple of the given alignment. */
709     while ((j & 0x1) == 0)
710     {
711         i++;
712         j = j >> 1;
713     }
714 
715     /* if the given alignment isn't power of two, returns an error */
716     if (j != 1)
717     {
718         REPORT_ERROR(MAJOR, E_INVALID_VALUE, ("alignment (should be power of 2)"));
719         return (uint64_t)ILLEGAL_BASE;
720     }
721 
722     if (i > MM_MAX_ALIGNMENT)
723     {
724         return (MmGetGreaterAlignment(p_MM, size, alignment, name));
725     }
726 
727     intFlags = XX_LockIntrSpinlock(p_MM->h_Spinlock);
728     /* look for a block of the size greater or equal to the required size. */
729     p_FreeB = p_MM->freeBlocks[i];
730     while ( p_FreeB && (p_FreeB->end - p_FreeB->base) < size )
731         p_FreeB = p_FreeB->p_Next;
732 
733     /* If such block is found */
734     if ( !p_FreeB )
735     {
736         XX_UnlockIntrSpinlock(p_MM->h_Spinlock, intFlags);
737         return (uint64_t)(ILLEGAL_BASE);
738     }
739 
740     holdBase = p_FreeB->base;
741     holdEnd = holdBase + size;
742 
743     /* init a new busy block */
744     if ((p_NewBusyB = CreateBusyBlock(holdBase, size, name)) == NULL)
745     {
746         XX_UnlockIntrSpinlock(p_MM->h_Spinlock, intFlags);
747         return (uint64_t)(ILLEGAL_BASE);
748     }
749 
750     /* calls Update routine to update a lists of free blocks */
751     if ( CutFree ( p_MM, holdBase, holdEnd ) != E_OK )
752     {
753         XX_UnlockIntrSpinlock(p_MM->h_Spinlock, intFlags);
754         return (uint64_t)(ILLEGAL_BASE);
755     }
756 
757     /* insert the new busy block into the list of busy blocks */
758     AddBusy ( p_MM, p_NewBusyB );
759     XX_UnlockIntrSpinlock(p_MM->h_Spinlock, intFlags);
760 
761     return (holdBase);
762 }
763 
764 /*****************************************************************************/
765 uint64_t MM_GetForce(t_Handle h_MM, uint64_t base, uint64_t size, char* name)
766 {
767     t_MM        *p_MM = (t_MM *)h_MM;
768     t_FreeBlock *p_FreeB;
769     t_BusyBlock *p_NewBusyB;
770     uint32_t    intFlags;
771     bool        blockIsFree = FALSE;
772 
773     ASSERT_COND(p_MM);
774 
775     intFlags = XX_LockIntrSpinlock(p_MM->h_Spinlock);
776     p_FreeB = p_MM->freeBlocks[0]; /* The biggest free blocks are in the
777                                       free list with alignment 1 */
778 
779     while ( p_FreeB )
780     {
781         if ( base >= p_FreeB->base && (base+size) <= p_FreeB->end )
782         {
783             blockIsFree = TRUE;
784             break;
785         }
786         else
787             p_FreeB = p_FreeB->p_Next;
788     }
789 
790     if ( !blockIsFree )
791     {
792         XX_UnlockIntrSpinlock(p_MM->h_Spinlock, intFlags);
793         return (uint64_t)(ILLEGAL_BASE);
794     }
795 
796     /* init a new busy block */
797     if ((p_NewBusyB = CreateBusyBlock(base, size, name)) == NULL)
798     {
799         XX_UnlockIntrSpinlock(p_MM->h_Spinlock, intFlags);
800         return (uint64_t)(ILLEGAL_BASE);
801     }
802 
803     /* calls Update routine to update a lists of free blocks */
804     if ( CutFree ( p_MM, base, base+size ) != E_OK )
805     {
806         XX_UnlockIntrSpinlock(p_MM->h_Spinlock, intFlags);
807         return (uint64_t)(ILLEGAL_BASE);
808     }
809 
810     /* insert the new busy block into the list of busy blocks */
811     AddBusy ( p_MM, p_NewBusyB );
812     XX_UnlockIntrSpinlock(p_MM->h_Spinlock, intFlags);
813 
814     return (base);
815 }
816 
817 /*****************************************************************************/
818 uint64_t MM_GetForceMin(t_Handle h_MM, uint64_t size, uint64_t alignment, uint64_t min, char* name)
819 {
820     t_MM        *p_MM = (t_MM *)h_MM;
821     t_FreeBlock *p_FreeB;
822     t_BusyBlock *p_NewBusyB;
823     uint64_t    holdBase, holdEnd, j = alignment, i=0;
824     uint32_t    intFlags;
825 
826     ASSERT_COND(p_MM);
827 
828     /* checks if alignment is a power of two, if it correct and if the
829        required size is multiple of the given alignment. */
830     while ((j & 0x1) == 0)
831     {
832         i++;
833         j = j >> 1;
834     }
835 
836     if ( (j != 1) || (i > MM_MAX_ALIGNMENT) )
837     {
838         return (uint64_t)(ILLEGAL_BASE);
839     }
840 
841     intFlags = XX_LockIntrSpinlock(p_MM->h_Spinlock);
842     p_FreeB = p_MM->freeBlocks[i];
843 
844     /* look for the first block that contains the minimum
845        base address. If the whole required size may be fit
846        into it, use that block, otherwise look for the next
847        block of size greater or equal to the required size. */
848     while ( p_FreeB && (min >= p_FreeB->end))
849             p_FreeB = p_FreeB->p_Next;
850 
851     /* If such block is found */
852     if ( !p_FreeB )
853     {
854         XX_UnlockIntrSpinlock(p_MM->h_Spinlock, intFlags);
855         return (uint64_t)(ILLEGAL_BASE);
856     }
857 
858     /* if this block is large enough, use this block */
859     holdBase = ( min <= p_FreeB->base ) ? p_FreeB->base : min;
860     if ((holdBase + size) <= p_FreeB->end )
861     {
862         holdEnd = holdBase + size;
863     }
864     else
865     {
866         p_FreeB = p_FreeB->p_Next;
867         while ( p_FreeB && ((p_FreeB->end - p_FreeB->base) < size) )
868             p_FreeB = p_FreeB->p_Next;
869 
870         /* If such block is found */
871         if ( !p_FreeB )
872         {
873             XX_UnlockIntrSpinlock(p_MM->h_Spinlock, intFlags);
874             return (uint64_t)(ILLEGAL_BASE);
875         }
876 
877         holdBase = p_FreeB->base;
878         holdEnd = holdBase + size;
879     }
880 
881     /* init a new busy block */
882     if ((p_NewBusyB = CreateBusyBlock(holdBase, size, name)) == NULL)
883     {
884         XX_UnlockIntrSpinlock(p_MM->h_Spinlock, intFlags);
885         return (uint64_t)(ILLEGAL_BASE);
886     }
887 
888     /* calls Update routine to update a lists of free blocks */
889     if ( CutFree( p_MM, holdBase, holdEnd ) != E_OK )
890     {
891         XX_UnlockIntrSpinlock(p_MM->h_Spinlock, intFlags);
892         return (uint64_t)(ILLEGAL_BASE);
893     }
894 
895     /* insert the new busy block into the list of busy blocks */
896     AddBusy( p_MM, p_NewBusyB );
897     XX_UnlockIntrSpinlock(p_MM->h_Spinlock, intFlags);
898 
899     return (holdBase);
900 }
901 
902 /*****************************************************************************/
903 uint64_t MM_Put(t_Handle h_MM, uint64_t base)
904 {
905     t_MM        *p_MM = (t_MM *)h_MM;
906     t_BusyBlock *p_BusyB, *p_PrevBusyB;
907     uint64_t    size;
908     uint32_t    intFlags;
909 
910     ASSERT_COND(p_MM);
911 
912     /* Look for a busy block that have the given base value.
913      * That block will be returned back to the memory.
914      */
915     p_PrevBusyB = 0;
916 
917     intFlags = XX_LockIntrSpinlock(p_MM->h_Spinlock);
918     p_BusyB = p_MM->busyBlocks;
919     while ( p_BusyB && base != p_BusyB->base )
920     {
921         p_PrevBusyB = p_BusyB;
922         p_BusyB = p_BusyB->p_Next;
923     }
924 
925     if ( !p_BusyB )
926     {
927         XX_UnlockIntrSpinlock(p_MM->h_Spinlock, intFlags);
928         return (uint64_t)(0);
929     }
930 
931     if ( AddFree( p_MM, p_BusyB->base, p_BusyB->end ) != E_OK )
932     {
933         XX_UnlockIntrSpinlock(p_MM->h_Spinlock, intFlags);
934         return (uint64_t)(0);
935     }
936 
937     /* removes a busy block form the list of busy blocks */
938     if ( p_PrevBusyB )
939         p_PrevBusyB->p_Next = p_BusyB->p_Next;
940     else
941         p_MM->busyBlocks = p_BusyB->p_Next;
942 
943     size = p_BusyB->end - p_BusyB->base;
944 
945     XX_Free(p_BusyB);
946     XX_UnlockIntrSpinlock(p_MM->h_Spinlock, intFlags);
947 
948     return (size);
949 }
950 
951 /*****************************************************************************/
952 uint64_t MM_PutForce(t_Handle h_MM, uint64_t base, uint64_t size)
953 {
954     t_MM        *p_MM = (t_MM *)h_MM;
955     uint64_t    end = base + size;
956     uint32_t    intFlags;
957 
958     ASSERT_COND(p_MM);
959 
960     intFlags = XX_LockIntrSpinlock(p_MM->h_Spinlock);
961     if ( CutBusy( p_MM, base, end ) != E_OK )
962     {
963         XX_UnlockIntrSpinlock(p_MM->h_Spinlock, intFlags);
964         return (uint64_t)(0);
965     }
966 
967     if ( AddFree ( p_MM, base, end ) != E_OK )
968     {
969         XX_UnlockIntrSpinlock(p_MM->h_Spinlock, intFlags);
970         return (uint64_t)(0);
971     }
972     XX_UnlockIntrSpinlock(p_MM->h_Spinlock, intFlags);
973 
974     return (size);
975 }
976 
977 /*****************************************************************************/
978 t_Error MM_Add(t_Handle h_MM, uint64_t base, uint64_t size)
979 {
980     t_MM        *p_MM = (t_MM *)h_MM;
981     t_MemBlock  *p_MemB, *p_NewMemB;
982     t_Error     errCode;
983     uint32_t    intFlags;
984 
985     ASSERT_COND(p_MM);
986 
987     /* find a last block in the list of memory blocks to insert a new
988      * memory block
989      */
990     intFlags = XX_LockIntrSpinlock(p_MM->h_Spinlock);
991     p_MemB = p_MM->memBlocks;
992     while ( p_MemB->p_Next )
993     {
994         if ( base >= p_MemB->base && base < p_MemB->end )
995         {
996         XX_UnlockIntrSpinlock(p_MM->h_Spinlock, intFlags);
997             RETURN_ERROR(MAJOR, E_ALREADY_EXISTS, NO_MSG);
998         }
999         p_MemB = p_MemB->p_Next;
1000     }
1001     /* check for a last memory block */
1002     if ( base >= p_MemB->base && base < p_MemB->end )
1003     {
1004         XX_UnlockIntrSpinlock(p_MM->h_Spinlock, intFlags);
1005         RETURN_ERROR(MAJOR, E_ALREADY_EXISTS, NO_MSG);
1006     }
1007 
1008     /* create a new memory block */
1009     if ((p_NewMemB = CreateNewBlock(base, size)) == NULL)
1010     {
1011         XX_UnlockIntrSpinlock(p_MM->h_Spinlock, intFlags);
1012         RETURN_ERROR(MAJOR, E_NO_MEMORY, NO_MSG);
1013     }
1014 
1015     /* append a new memory block to the end of the list of memory blocks */
1016     p_MemB->p_Next = p_NewMemB;
1017 
1018     /* add a new free block to the free lists */
1019     errCode = AddFree(p_MM, base, base+size);
1020     if (errCode)
1021     {
1022         XX_UnlockIntrSpinlock(p_MM->h_Spinlock, intFlags);
1023         p_MemB->p_Next = 0;
1024         XX_Free(p_NewMemB);
1025         return ((t_Error)errCode);
1026     }
1027     XX_UnlockIntrSpinlock(p_MM->h_Spinlock, intFlags);
1028 
1029     return (E_OK);
1030 }
1031 
1032 /*****************************************************************************/
1033 uint64_t MM_GetMemBlock(t_Handle h_MM, int index)
1034 {
1035     t_MM       *p_MM = (t_MM*)h_MM;
1036     t_MemBlock *p_MemBlock;
1037     int         i;
1038 
1039     ASSERT_COND(p_MM);
1040 
1041     p_MemBlock = p_MM->memBlocks;
1042     for (i=0; i < index; i++)
1043         p_MemBlock = p_MemBlock->p_Next;
1044 
1045     if ( p_MemBlock )
1046         return (p_MemBlock->base);
1047     else
1048         return (uint64_t)ILLEGAL_BASE;
1049 }
1050 
1051 /*****************************************************************************/
1052 uint64_t MM_GetBase(t_Handle h_MM)
1053 {
1054     t_MM       *p_MM = (t_MM*)h_MM;
1055     t_MemBlock *p_MemBlock;
1056 
1057     ASSERT_COND(p_MM);
1058 
1059     p_MemBlock = p_MM->memBlocks;
1060     return  p_MemBlock->base;
1061 }
1062 
1063 /*****************************************************************************/
1064 bool MM_InRange(t_Handle h_MM, uint64_t addr)
1065 {
1066     t_MM       *p_MM = (t_MM*)h_MM;
1067     t_MemBlock *p_MemBlock;
1068 
1069     ASSERT_COND(p_MM);
1070 
1071     p_MemBlock = p_MM->memBlocks;
1072 
1073     if ((addr >= p_MemBlock->base) && (addr < p_MemBlock->end))
1074         return TRUE;
1075     else
1076         return FALSE;
1077 }
1078 
1079 /*****************************************************************************/
1080 void MM_Dump(t_Handle h_MM, void *buff)
1081 {
1082     t_MM        *p_MM = (t_MM *)h_MM;
1083     t_FreeBlock *p_FreeB;
1084     t_BusyBlock *p_BusyB;
1085     int          i;
1086 
1087     p_BusyB = p_MM->busyBlocks;
1088     Sprint(buff, "List of busy blocks:\n");
1089     while (p_BusyB)
1090     {
1091         Sprint(buff, "\t0x%p: (%s: b=0x%lx, e=0x%lx)\n",
1092                p_BusyB, p_BusyB->name, p_BusyB->base, p_BusyB->end );
1093         p_BusyB = p_BusyB->p_Next;
1094     }
1095 
1096     Sprint(buff, "\nLists of free blocks according to alignment:\n");
1097     for (i=0; i <= MM_MAX_ALIGNMENT; i++)
1098     {
1099         Sprint(buff, "%d alignment:\n", (0x1 << i));
1100         p_FreeB = p_MM->freeBlocks[i];
1101         while (p_FreeB)
1102         {
1103             Sprint(buff, "\t0x%p: (b=0x%lx, e=0x%lx)\n",
1104                    p_FreeB, p_FreeB->base, p_FreeB->end);
1105             p_FreeB = p_FreeB->p_Next;
1106         }
1107         Sprint(buff, "\n");
1108     }
1109 }
1110