URL https://opencores.org/ocsvn/pcie_ds_dma/pcie_ds_dma/trunk

Subversion Repositories pcie_ds_dma

[/] [pcie_ds_dma/] [trunk/] [soft/] [linux/] [driver/] [pexdrv/] [memory.c] - Blame information for rev 54

Details | Compare with Previous | View Log


 
#include <linux/kernel.h>
#include <linux/version.h>
#include <linux/module.h>
#include <linux/types.h>
#include <linux/ioport.h>
#include <linux/pci.h>
#include <linux/pagemap.h>
#include <linux/interrupt.h>
#include <linux/proc_fs.h>
#include <linux/sched.h>
 
#include <asm/io.h>
 
 
#include "pexmodule.h"
#include "memory.h"
 
//--------------------------------------------------------------------
 
int lock_pages( void *va, u32 size )
{
    struct page *start_page_addr = virt_to_page(va);
    int i = 0;
 
    for (i=0; i < (size >> PAGE_SHIFT); i++) {
        SetPageReserved(start_page_addr+i);
        //dbg_msg(dbg_trace, "%s(): page_addr[%d] = 0x%x\n", __FUNCTION__, i, (int)(start_page_addr+i));
    }
 
    return i;
}
 
//--------------------------------------------------------------------
 
int unlock_pages( void *va, u32 size )
{
    struct page *start_page_addr = virt_to_page(va);
    int i = 0;
 
    for (i=0; i < (size >> PAGE_SHIFT); i++) {
        ClearPageReserved(start_page_addr+i);
        //dbg_msg(dbg_trace, "%s(): page_addr[%d] = 0x%x\n", __FUNCTION__, i, (int)(start_page_addr+i));
    }
 
    return i;
}
 
//--------------------------------------------------------------------
 
int check_address( void *pMemUserAddr )
{
        size_t addr = (size_t)pMemUserAddr;
        size_t mask = (size_t)~PAGE_MASK;
 
        printk("%s()\n", __FUNCTION__);
 
        // адрес пользовательского буфера должен быть выровнен на страницу
        if(addr & mask) {
            printk("%s(): %p - Error! Address must be aling at PAGE_SIZE border\n", __FUNCTION__, pMemUserAddr );
            return 1;
        }
 
        return 0;
    }
 
//--------------------------------------------------------------------
 
int check_size( size_t userSize )
{
        printk("%s()\n", __FUNCTION__);
 
        // размер пользовательского буфера должен быть кратен размеру страницы
        if((userSize % PAGE_SIZE) != 0) {
            printk("%s(): Invalid user memory block size - 0x%lX.\n", __FUNCTION__, userSize);
            return 1;
        }
 
        return 0;
}
 
//--------------------------------------------------------------------
 
int lock_user_memory( SHARED_MEMORY_DESCRIPTION *MemDscr, void* userSpaceAddress, size_t userSpaceSize )
{
        int i = 0;
        int requested_page_count = 0;
        int allocated_page_count = 0;
 
        printk("%s()\n", __FUNCTION__);
 
        if(!MemDscr) {
            printk("%s(): Invalid memory descriptor.\n", __FUNCTION__);
            return -EINVAL;
        }
 
        requested_page_count = (userSpaceSize >> PAGE_SHIFT);
 
        MemDscr->LockedPages = (struct page**)kmalloc(requested_page_count*sizeof(struct page*), GFP_KERNEL);
        if(!MemDscr->LockedPages) {
            printk("%s(): Cant allocate memory for locked pages pointers.\n", __FUNCTION__);
            return -ENOMEM;
        }
 
        memset(MemDscr->LockedPages,0,requested_page_count*sizeof(struct page*));
 
        down_read(&current->mm->mmap_sem);
#if LINUX_VERSION_CODE < KERNEL_VERSION(4,5,0)
        allocated_page_count = get_user_pages(current,
                                          current->mm,
                                          (size_t)userSpaceAddress,
                                          requested_page_count,
                                          1,
                                          0,
                                          MemDscr->LockedPages,
                                          0);
#endif
#if (LINUX_VERSION_CODE >= KERNEL_VERSION(4,5,0)) && (LINUX_VERSION_CODE < KERNEL_VERSION(4,9,0))
        allocated_page_count = get_user_pages((size_t)userSpaceAddress,
                                          requested_page_count,
                                          1,
                                          0,
                                          MemDscr->LockedPages,
                                          0);
#endif
#if (LINUX_VERSION_CODE >= KERNEL_VERSION(4,9,0))
        allocated_page_count = get_user_pages((size_t)userSpaceAddress,
                                          requested_page_count,
                                          1,
                                          MemDscr->LockedPages,
                                          0);
#endif
 
        up_read(&current->mm->mmap_sem);
 
        // если все ok то result содержит число страниц в массиве struct page *pages
        if(MemDscr->PageCount <= 0) {
            printk("%s(): Error to lock memory pages.\n", __FUNCTION__);
            kfree(MemDscr->LockedPages);
            MemDscr->LockedPages = NULL;
            MemDscr->PageCount = 0;
            return -ENOMEM;
        }
 
        printk("%s(): MemDscr->PageCount = %ld\n", __FUNCTION__, MemDscr->PageCount);
        printk("%s(): MemDscr->LockedPages = %p\n", __FUNCTION__, MemDscr->LockedPages);
 
        for(i=0; i<MemDscr->PageCount; i++) {
 
            printk("%s(): LockedPages[%d] = %p\n", __FUNCTION__, i, MemDscr->LockedPages[i]);
            printk("%s(): PhysicalAddress = %p\n", __FUNCTION__, (void*)page_to_phys(MemDscr->LockedPages[i]));
 
            if(!PageReserved(MemDscr->LockedPages[i])) {
                SetPageReserved(MemDscr->LockedPages[i]);
            }
        }
 
        printk("%s(): Lock %ld memory pages\n", __FUNCTION__, MemDscr->PageCount);
 
        return 0;
}
 
//--------------------------------------------------------------------
 
int unlock_user_memory( SHARED_MEMORY_DESCRIPTION *MemDscr )
{
        int i = 0;
 
        printk("%s()\n", __FUNCTION__);
 
        if(!MemDscr) {
            printk("%s(): Invalid parameter MemDscr = %p\n", __FUNCTION__, MemDscr);
            return -EINVAL;
        }
 
        printk("%s(): MemDscr = %p\n", __FUNCTION__, MemDscr);
 
        if(MemDscr->LockedPages)
            printk("%s(): MemDscr->LockedPages = %p\n", __FUNCTION__, MemDscr->LockedPages);
 
        for(i=0; i<MemDscr->PageCount; i++) {
            if(MemDscr->LockedPages[i]) {
                ClearPageReserved(MemDscr->LockedPages[i]);
                //page_cache_release(MemDscr->LockedPages[i]);
                printk("%s(): Unlock page %p\n", __FUNCTION__, MemDscr->LockedPages[i]);
            }
        }
 
        if(MemDscr->LockedPages)
            kfree(MemDscr->LockedPages);
 
        return 0;
}
 
//--------------------------------------------------------------------
 
void* allocate_memory_block(struct pex_device *brd, size_t block_size, dma_addr_t *dma_addr)
{
    struct mem_t *m = NULL;
    void *cpu_addr = NULL;
    dma_addr_t dma_handle = {0};
    int locked = 0;
 
    spin_lock(&brd->m_MemListLock);
 
    m = (struct mem_t*)kzalloc(sizeof(struct mem_t), GFP_KERNEL);
    if(!m) {
        err_msg(err_trace, "%s(): Error allocate memory for mem_t descriptor\n", __FUNCTION__);
        goto do_exit;
    }
 
    cpu_addr = dma_alloc_coherent(&brd->m_pci->dev, block_size, &dma_handle, GFP_KERNEL);
    if(!cpu_addr) {
        err_msg(err_trace, "%s(): Error allocate physical memory block.\n", __FUNCTION__);
        goto do_free_mem;
    }
 
    *dma_addr = dma_handle;
    m->dma_handle = dma_handle;
    m->cpu_addr = cpu_addr;
    m->size = block_size;
 
    locked = lock_pages(m->cpu_addr, m->size);
 
    list_add_tail(&m->list, &brd->m_MemList);
 
    atomic_inc(&brd->m_MemListCount);
 
    dbg_msg(dbg_trace, "%s(): %d: PA = 0x%zx, VA = %p, SZ = 0x%zx, PAGES = %d\n",
            __FUNCTION__, atomic_read(&brd->m_MemListCount), (size_t)m->dma_handle, m->cpu_addr, m->size, locked );
 
    spin_unlock(&brd->m_MemListLock);
 
    return cpu_addr;
 
do_free_mem:
    kfree(m);
 
do_exit:
    spin_unlock(&brd->m_MemListLock);
 
    return NULL;
}
 
//--------------------------------------------------------------------
 
int free_memory_block(struct pex_device *brd, struct memory_block mb)
{
    struct list_head *pos, *n;
    struct mem_t *m = NULL;
    int unlocked = 0;
 
    spin_lock(&brd->m_MemListLock);
 
    list_for_each_safe(pos, n, &brd->m_MemList) {
 
        m = list_entry(pos, struct mem_t, list);
 
        if(m->dma_handle != mb.phys)
            continue;
 
        unlocked = unlock_pages(m->cpu_addr, m->size);
 
        dma_free_coherent(&brd->m_pci->dev, m->size, m->cpu_addr, m->dma_handle);
 
        dbg_msg(dbg_trace, "%s(): %d: PA = 0x%zx, VA = %p, SZ = 0x%zx, PAGES = %d\n",
                __FUNCTION__, atomic_read(&brd->m_MemListCount), (size_t)m->dma_handle, m->cpu_addr, m->size, unlocked );
 
        list_del(pos);
 
        atomic_dec(&brd->m_MemListCount);
 
        kfree(m);
    }
 
    spin_unlock(&brd->m_MemListLock);
 
    return 0;
}
 
//--------------------------------------------------------------------
 

Line No.	Rev	Author	Line
1	7	v.karak
2			`#include <linux/kernel.h>`
3	54	v.karak	`#include <linux/version.h>`
4	7	v.karak	`#include <linux/module.h>`
5			`#include <linux/types.h>`
6			`#include <linux/ioport.h>`
7			`#include <linux/pci.h>`
8			`#include <linux/pagemap.h>`
9			`#include <linux/interrupt.h>`
10			`#include <linux/proc_fs.h>`
11	54	v.karak	`#include <linux/sched.h>`
12
13	7	v.karak	`#include <asm/io.h>`
14
15	54	v.karak
16			`#include "pexmodule.h"`
17	7	v.karak	`#include "memory.h"`
18
19			`//--------------------------------------------------------------------`
20
21			`int lock_pages( void *va, u32 size )`
22			`{`
23			`struct page *start_page_addr = virt_to_page(va);`
24			`int i = 0;`
25
26	54	v.karak	`for (i=0; i < (size >> PAGE_SHIFT); i++) {`
27	7	v.karak	`SetPageReserved(start_page_addr+i);`
28			`//dbg_msg(dbg_trace, "%s(): page_addr[%d] = 0x%x\n", __FUNCTION__, i, (int)(start_page_addr+i));`
29			`}`
30
31			`return i;`
32			`}`
33
34			`//--------------------------------------------------------------------`
35
36			`int unlock_pages( void *va, u32 size )`
37			`{`
38			`struct page *start_page_addr = virt_to_page(va);`
39			`int i = 0;`
40
41	54	v.karak	`for (i=0; i < (size >> PAGE_SHIFT); i++) {`
42	7	v.karak	`ClearPageReserved(start_page_addr+i);`
43			`//dbg_msg(dbg_trace, "%s(): page_addr[%d] = 0x%x\n", __FUNCTION__, i, (int)(start_page_addr+i));`
44			`}`
45
46			`return i;`
47			`}`
48
49			`//--------------------------------------------------------------------`
50
51	54	v.karak	`int check_address( void *pMemUserAddr )`
52	7	v.karak	`{`
53	54	v.karak	`size_t addr = (size_t)pMemUserAddr;`
54			`size_t mask = (size_t)~PAGE_MASK;`
55	7	v.karak
56	54	v.karak	`printk("%s()\n", __FUNCTION__);`
57	7	v.karak
58	54	v.karak	`// адрес пользовательского буфера должен быть выровнен на страницу`
59			`if(addr & mask) {`
60			`printk("%s(): %p - Error! Address must be aling at PAGE_SIZE border\n", __FUNCTION__, pMemUserAddr );`
61			`return 1;`
62			`}`
63	7	v.karak
64	54	v.karak	`return 0;`
65	7	v.karak	`}`
66
67	54	v.karak	`//--------------------------------------------------------------------`
68	7	v.karak
69	54	v.karak	`int check_size( size_t userSize )`
70			`{`
71			`printk("%s()\n", __FUNCTION__);`
72	7	v.karak
73	54	v.karak	`// размер пользовательского буфера должен быть кратен размеру страницы`
74			`if((userSize % PAGE_SIZE) != 0) {`
75			`printk("%s(): Invalid user memory block size - 0x%lX.\n", __FUNCTION__, userSize);`
76			`return 1;`
77			`}`
78	7	v.karak
79	54	v.karak	`return 0;`
80			`}`
81	7	v.karak
82	54	v.karak	`//--------------------------------------------------------------------`
83	7	v.karak
84	54	v.karak	`int lock_user_memory( SHARED_MEMORY_DESCRIPTION MemDscr, void userSpaceAddress, size_t userSpaceSize )`
85			`{`
86			`int i = 0;`
87			`int requested_page_count = 0;`
88			`int allocated_page_count = 0;`
89
90			`printk("%s()\n", __FUNCTION__);`
91
92			`if(!MemDscr) {`
93			`printk("%s(): Invalid memory descriptor.\n", __FUNCTION__);`
94			`return -EINVAL;`
95			`}`
96
97			`requested_page_count = (userSpaceSize >> PAGE_SHIFT);`
98
99			`MemDscr->LockedPages = (struct page*)kmalloc(requested_page_countsizeof(struct page*), GFP_KERNEL);`
100			`if(!MemDscr->LockedPages) {`
101			`printk("%s(): Cant allocate memory for locked pages pointers.\n", __FUNCTION__);`
102			`return -ENOMEM;`
103			`}`
104
105			`memset(MemDscr->LockedPages,0,requested_page_countsizeof(struct page));`
106
107			`down_read(&current->mm->mmap_sem);`
108			`#if LINUX_VERSION_CODE < KERNEL_VERSION(4,5,0)`
109			`allocated_page_count = get_user_pages(current,`
110			`current->mm,`
111			`(size_t)userSpaceAddress,`
112			`requested_page_count,`
113			`1,`
114			`0,`
115			`MemDscr->LockedPages,`
116			`0);`
117			`#endif`
118			`#if (LINUX_VERSION_CODE >= KERNEL_VERSION(4,5,0)) && (LINUX_VERSION_CODE < KERNEL_VERSION(4,9,0))`
119			`allocated_page_count = get_user_pages((size_t)userSpaceAddress,`
120			`requested_page_count,`
121			`1,`
122			`0,`
123			`MemDscr->LockedPages,`
124			`0);`
125			`#endif`
126			`#if (LINUX_VERSION_CODE >= KERNEL_VERSION(4,9,0))`
127			`allocated_page_count = get_user_pages((size_t)userSpaceAddress,`
128			`requested_page_count,`
129			`1,`
130			`MemDscr->LockedPages,`
131			`0);`
132			`#endif`
133
134			`up_read(&current->mm->mmap_sem);`
135
136			`// если все ok то result содержит число страниц в массиве struct page *pages`
137			`if(MemDscr->PageCount <= 0) {`
138			`printk("%s(): Error to lock memory pages.\n", __FUNCTION__);`
139			`kfree(MemDscr->LockedPages);`
140			`MemDscr->LockedPages = NULL;`
141			`MemDscr->PageCount = 0;`
142			`return -ENOMEM;`
143			`}`
144
145			`printk("%s(): MemDscr->PageCount = %ld\n", __FUNCTION__, MemDscr->PageCount);`
146			`printk("%s(): MemDscr->LockedPages = %p\n", __FUNCTION__, MemDscr->LockedPages);`
147
148			`for(i=0; i<MemDscr->PageCount; i++) {`
149
150			`printk("%s(): LockedPages[%d] = %p\n", __FUNCTION__, i, MemDscr->LockedPages[i]);`
151			`printk("%s(): PhysicalAddress = %p\n", __FUNCTION__, (void*)page_to_phys(MemDscr->LockedPages[i]));`
152
153			`if(!PageReserved(MemDscr->LockedPages[i])) {`
154			`SetPageReserved(MemDscr->LockedPages[i]);`
155			`}`
156			`}`
157
158			`printk("%s(): Lock %ld memory pages\n", __FUNCTION__, MemDscr->PageCount);`
159
160			`return 0;`
161	7	v.karak	`}`
162
163	54	v.karak	`//--------------------------------------------------------------------`
164
165			`int unlock_user_memory( SHARED_MEMORY_DESCRIPTION *MemDscr )`
166	7	v.karak	`{`
167	54	v.karak	`int i = 0;`
168
169			`printk("%s()\n", __FUNCTION__);`
170
171			`if(!MemDscr) {`
172			`printk("%s(): Invalid parameter MemDscr = %p\n", __FUNCTION__, MemDscr);`
173			`return -EINVAL;`
174			`}`
175
176			`printk("%s(): MemDscr = %p\n", __FUNCTION__, MemDscr);`
177
178			`if(MemDscr->LockedPages)`
179			`printk("%s(): MemDscr->LockedPages = %p\n", __FUNCTION__, MemDscr->LockedPages);`
180
181			`for(i=0; i<MemDscr->PageCount; i++) {`
182			`if(MemDscr->LockedPages[i]) {`
183			`ClearPageReserved(MemDscr->LockedPages[i]);`
184			`//page_cache_release(MemDscr->LockedPages[i]);`
185			`printk("%s(): Unlock page %p\n", __FUNCTION__, MemDscr->LockedPages[i]);`
186			`}`
187			`}`
188
189			`if(MemDscr->LockedPages)`
190			`kfree(MemDscr->LockedPages);`
191
192			`return 0;`
193	7	v.karak	`}`
194
195	54	v.karak	`//--------------------------------------------------------------------`
196	7	v.karak
197			`void* allocate_memory_block(struct pex_device brd, size_t block_size, dma_addr_t dma_addr)`
198			`{`
199			`struct mem_t *m = NULL;`
200			`void *cpu_addr = NULL;`
201			`dma_addr_t dma_handle = {0};`
202			`int locked = 0;`
203
204			`spin_lock(&brd->m_MemListLock);`
205
206			`m = (struct mem_t*)kzalloc(sizeof(struct mem_t), GFP_KERNEL);`
207			`if(!m) {`
208			`err_msg(err_trace, "%s(): Error allocate memory for mem_t descriptor\n", __FUNCTION__);`
209			`goto do_exit;`
210			`}`
211
212			`cpu_addr = dma_alloc_coherent(&brd->m_pci->dev, block_size, &dma_handle, GFP_KERNEL);`
213			`if(!cpu_addr) {`
214			`err_msg(err_trace, "%s(): Error allocate physical memory block.\n", __FUNCTION__);`
215			`goto do_free_mem;`
216			`}`
217
218			`*dma_addr = dma_handle;`
219			`m->dma_handle = dma_handle;`
220			`m->cpu_addr = cpu_addr;`
221			`m->size = block_size;`
222
223			`locked = lock_pages(m->cpu_addr, m->size);`
224
225			`list_add_tail(&m->list, &brd->m_MemList);`
226
227			`atomic_inc(&brd->m_MemListCount);`
228
229			`dbg_msg(dbg_trace, "%s(): %d: PA = 0x%zx, VA = %p, SZ = 0x%zx, PAGES = %d\n",`
230			`__FUNCTION__, atomic_read(&brd->m_MemListCount), (size_t)m->dma_handle, m->cpu_addr, m->size, locked );`
231
232			`spin_unlock(&brd->m_MemListLock);`
233
234			`return cpu_addr;`
235
236			`do_free_mem:`
237			`kfree(m);`
238
239			`do_exit:`
240			`spin_unlock(&brd->m_MemListLock);`
241
242			`return NULL;`
243			`}`
244
245			`//--------------------------------------------------------------------`
246
247			`int free_memory_block(struct pex_device *brd, struct memory_block mb)`
248			`{`
249			`struct list_head pos, n;`
250			`struct mem_t *m = NULL;`
251			`int unlocked = 0;`
252
253			`spin_lock(&brd->m_MemListLock);`
254
255			`list_for_each_safe(pos, n, &brd->m_MemList) {`
256
257			`m = list_entry(pos, struct mem_t, list);`
258
259			`if(m->dma_handle != mb.phys)`
260			`continue;`
261
262			`unlocked = unlock_pages(m->cpu_addr, m->size);`
263
264			`dma_free_coherent(&brd->m_pci->dev, m->size, m->cpu_addr, m->dma_handle);`
265
266			`dbg_msg(dbg_trace, "%s(): %d: PA = 0x%zx, VA = %p, SZ = 0x%zx, PAGES = %d\n",`
267			`__FUNCTION__, atomic_read(&brd->m_MemListCount), (size_t)m->dma_handle, m->cpu_addr, m->size, unlocked );`
268
269			`list_del(pos);`
270
271			`atomic_dec(&brd->m_MemListCount);`
272
273			`kfree(m);`
274			`}`
275
276			`spin_unlock(&brd->m_MemListLock);`
277
278			`return 0;`
279			`}`
280
281			`//--------------------------------------------------------------------`
282

Browse

Tools

Subversion Repositories pcie_ds_dma

[/] [pcie_ds_dma/] [trunk/] [soft/] [linux/] [driver/] [pexdrv/] [memory.c] - Blame information for rev 54