LCD驱动程序分析---基于framebuffer
2009-01-03 13:54
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//*******************************************************
//* 2007.6.18 //******************************************************* 在/kernel/include/asm-arm/arch-s3c2410/bitfield.h 文件中: #ifndef __ASSEMBLY__ #define UData(Data) ((unsigned long) (Data)) #else #define UData(Data) (Data) #endif 例:UData(5); = 5
/*
* MACRO: Fld * * Purpose * The macro "Fld" encodes a bit field, given its size and its shift value * with respect to bit 0. * * Note * A more intuitive way to encode bit fields would have been to use their * mask. However, extracting size and shift value information from a bit * field''''s mask is cumbersome and might break the assembler (255-character * line-size limit). * * Input * Size Size of the bit field, in number of bits. * Shft Shift value of the bit field with respect to bit 0. * * Output * Fld Encoded bit field. */ #define Fld(Size, Shft) (((Size) << 16) + (Shft))
例:Fld(2,5); = 0x20005
/*
* MACROS: FSize, FShft, FMsk, FAlnMsk, F1stBit * * Purpose * The macros "FSize", "FShft", "FMsk", "FAlnMsk", and "F1stBit" return * the size, shift value, mask, aligned mask, and first bit of a * bit field. * * Input * Field Encoded bit field (using the macro "Fld"). * * Output * FSize Size of the bit field, in number of bits. * FShft Shift value of the bit field with respect to bit 0. * FMsk Mask for the bit field. * FAlnMsk Mask for the bit field, aligned on bit 0. * F1stBit First bit of the bit field. */ #define FSize(Field) ((Field) >> 16)
例:FSize(0x20005); = 2
#define FShft(Field) ((Field) & 0x0000FFFF)
例:FShft(0x20005); = 5
/*
* MACRO: FInsrt * * Purpose * The macro "FInsrt" inserts a value into a bit field by shifting the * former appropriately. * * Input * Value Bit-field value. * Field Encoded bit field (using the macro "Fld"). * * Output * FInsrt Bit-field value positioned appropriately. */ #define FInsrt(Value, Field) / (UData (Value) << FShft (Field)) 例:FInsrt(0x3, 0x20005); = 0x3 << 0x0005 = 0x60
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在/kernel/include/asm-arm/arch-s3c2410/hardware.h 文件中: /* * S3C2410 internal I/O mappings * * We have the following mapping: * phys virt * 48000000 e8000000 */ #define VIO_BASE 0xe8000000 /* virtual start of IO space */
#define PIO_START 0x48000000 /* physical start of IO space */ #define io_p2v(x) ((x) | 0xa0000000)
#define io_v2p(x) ((x) & ~0xa0000000) # define __REG(x) io_p2v(x)
# define __PREG(x) io_v2p(x) 这里,在实际的寄存器操作中,都用__REG(x) 宏将物理地址转换为了虚拟地址,然后再对这些虚拟地址进行读写操作。
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当应用程序对设备文件进行ioctl操作时候会调用它们。对于fb_get_fix(),应用程序传入的是fb_fix_screeninfo结构,在函 数中对其成员变量赋值,主要是smem_start(缓冲区起始地址)和smem_len(缓冲区长度),最终返回给应用程序。 在/kernel/drivers/video/s3c2410fb.c 文件中的s3c2410fb_map_video_memory 函数中:
fbi->fb.fix.smem_len = fbi->max_xres * fbi->max_yres * fbi->max_bpp / 8; fbi->map_size = PAGE_ALIGN(fbi->fb.fix.smem_len + PAGE_SIZE);
fbi->map_cpu = consistent_alloc(GFP_KERNEL, fbi->map_size, &fbi->map_dma); if (fbi->map_cpu) { fbi->screen_cpu = fbi->map_cpu + PAGE_SIZE; fbi->screen_dma = fbi->map_dma + PAGE_SIZE; fbi->fb.fix.smem_start = fbi->screen_dma; } 在/kernel/include/asm-arm/proc-armo/page.h 文件中: /* PAGE_SHIFT determines the page size. This is configurable. */ #if defined(CONFIG_PAGESIZE_16) #define PAGE_SHIFT 14 /* 16K */ #else /* default */ #define PAGE_SHIFT 15 /* 32K */ #endif 在/kernel/include/asm-arm/page.h 文件中:
#define PAGE_SIZE (1UL << PAGE_SHIFT) #define PAGE_MASK (~(PAGE_SIZE-1)) /* to align the pointer to the (next) page boundary */
#define PAGE_ALIGN(addr) (((addr)+PAGE_SIZE-1)&PAGE_MASK) 在/kernel/arch/arm/mm/consistent.c 文件中:
/* * This allocates one page of cache-coherent memory space and returns * both the virtual and a "dma" address to that space. It is not clear * whether this could be called from an interrupt context or not. For * now, we expressly forbid it, especially as some of the stuff we do * here is not interrupt context safe. * * Note that this does *not* zero the allocated area! */ void *consistent_alloc(int gfp, size_t size, dma_addr_t *dma_handle) 这里首先计算出需要视频缓冲区的大小(LCD屏的宽度 * LCD屏的高度 * 每像素的位数 / 每字节的位数) fbi->fb.fix.smem_len = 240*320*16/8 = 0x25800 =150K(9.375个PAGE) PAGE_SHIFT = 14 PAGE_SIZE = 1<<14 = 0x4000 = 16K (1个PAGE) PAGE_MASK = 0xFFFFC000 fbi->map_size = PAGE_ALIGN(fbi->fb.fix.smem_len + PAGE_SIZE) = PAGE_ALIGN(150K + 16K) = PAGE_ALIGN(166K) = (166K + 16K - 1) & 0xFFFFC000 = 0x2D7FF & 0xFFFFC000 = 0x2C000 =176K consistent_alloc(GFP_KERNEL, 176K, &fbi->map_dma); 最后得到: framebuffer(物理地址)
|---------------| | ... | -------|---------------| <-- fbi->map_dma | 16K | 分配了 |---------------| <-- fbi->screen_dma = fbi->fb.fix.smem_start 176K | | 共11个 | | 160K = 10个PAGE PAGE | 160K | 可以容下所需的150K 视频缓冲区大小 (16K) | | | | -------|---------------|------- | ... | |---------------| //******************************************************* //* 2007.6.19 //******************************************************* 在/kernel/drivers/video/s3c2410fb.c 文件中的s3c2410fb_activate_var 函数中: unsigned long VideoPhysicalTemp = fbi->screen_dma; 这里已经得到了framebuffer 在内存中的起始地址为VideoPhysicalTemp,地址数据位为A[30:0]。 new_regs.lcdcon1 = fbi->reg.lcdcon1 & ~LCD1_ENVID;
new_regs.lcdcon2 = (fbi->reg.lcdcon2 & ~LCD2_LINEVAL_MSK)
| LCD2_LINEVAL(var->yres - 1); /* TFT LCD only ! */
new_regs.lcdcon3 = (fbi->reg.lcdcon3 & ~LCD3_HOZVAL_MSK) | LCD3_HOZVAL(var->xres - 1); new_regs.lcdcon4 = fbi->reg.lcdcon4;
new_regs.lcdcon5 = fbi->reg.lcdcon5; LCDCON1 首先需要禁止视频输出才能进行寄存器的设置,然后对LCDCON2,LCDCON3 进行设置,主要是增加LINEVAL 和HOZVAL 这两个显示尺寸的参数。LCDCON4,LCDCON5 按原来配置设置。
LCDBANK[29:21] 为系统内存中视频缓冲区在系统存储器内的段地址的A[30:22] LCDBASEU[20:0] 为LCD framebuffer 的起始地址的A[21:1] LCDBASEL[20:0] 为LCD framebuffer 的结束地址的A[21:1] OFFSIZE[21:11] 为某一行的第一个半字与前一行最后一个半字之间的距离(单位:半字数,即2个字节) PAGEWIDTH[10:0] 为显示存储区的可见帧宽度(单位:半字数,即2个字节) new_regs.lcdsaddr1 = LCDADDR_BANK(((unsigned long)VideoPhysicalTemp >> 22)) | LCDADDR_BASEU(((unsigned long)VideoPhysicalTemp >> 1)); new_regs.lcdsaddr2 = LCDADDR_BASEL(
((unsigned long)VideoPhysicalTemp + (var->xres * 2 * (var>yres))) >> 1); 这里LCDADDR_BASEL 的计算方法为用framebuffer 在内存中的起始地址VideoPhysicalTemp,加上framebuffer 的大小(LCD屏的宽度 * LCD屏的高度 * 每像素的位数 / 每字节的位数),得到framebuffer 在内存中的结束地址,然后右移1位。
new_regs.lcdsaddr3 = LCDADDR_OFFSET(0) | (LCDADDR_PAGE(var->xres));
这里PAGEWIDTH 的计算方法为:LCD屏的宽度*每像素的位数/16位 (半字)。
问题:以上这些操作是否已经对DMA 控制器进行了设置? 我认为这里将framebuffer 在内存中的起始地址为VideoPhysicalTemp 变换后载入LCDADDR1,LCDADDR2,LCDADDR3 中就已经完成了对LCDCDMA 控制器的源数据的基地址设置,当打开LCDCON1 |= LCD1_ENVID; 后就可以由LCDCDMA 控制器自动从framebuffer 中传数据到LCD 屏幕了。 ------------------------------------------------------------------------ 在/kernel/drivers/video/s3c2410fb.c 文件中的xxx_stn_info 结构体初始化中: lcdcon5 : LCD5_FRM565 | LCD5_INVVLINE | LCD5_INVVFRAME | LCD5_HWSWP | LCD5_PWREN, INVVCLK , INVLINE , INVFRAME , INVVD :通过前面的时序图,我们知道,CPU的LCD控制器输出的时序默认是正脉冲,而LCD需要VSYNC(VFRAME)、VLINE(HSYNC)均为负 脉冲,因此 INVLINE 和 INVFRAME 必须设为“1 ”,即选择反相输出。 INVVDEN , INVPWREN , INVLEND 的功能同前面的类似。
PWREN 为LCD电源使能控制。在CPU LCD控制器的输出信号中,有一个电源使能管脚LCD_PWREN,用来做为LCD屏电源的开关信号。
其中LCD5_HWSWP 一项,设置了LCD从内存中显示数据时,经过了半字交换。
16BPP Display
(BSWP = 0, HWSWP = 0) D[31:16] D[15:0] 000H P1 P2 004H P3 P4 008H P5 P6 ... (BSWP = 0, HWSWP = 1)
D[31:16] D[15:0] 000H P2 P1 004H P4 P3 008H P6 P5 ... 像素显示顺序如下:
P1 P2 P3 P4 P5 ... 例如:内存地址的数据为:0x11223344 (32位)
系统存储器采用Big-Endian(大端模式)存储格式,地址数据格式如下: D[31:16] D[15:0] 00 01 02 03 00H 0x11 0x22 0x33 0x44 (0x1122) (0x3344) 04H ... 08H ... 则首先显示0x3344 的数据到第一个像素,然后再显示0x1122 到第二个像素。
系统存储器采用Little-Endian(小端模式)存储格式,地址数据格式如下:
D[31:16] D[15:0] 03 02 01 00 00H 0x11 0x22 0x33 0x44 (0x1122) (0x3344) 04H ... 08H ... 则首先显示0x3344 的数据到第一个像素,然后再显示0x1122 到第二个像素。
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//* 2007.6.20 //******************************************************* 在/kernel/arch/arm/mm/consistent.c 文件中的consistent_alloc 函数中: void *consistent_alloc(int gfp, size_t size, dma_addr_t *dma_handle) { ... virt = page_address(page); *dma_handle = virt_to_bus(virt); ret = __ioremap(virt_to_phys(virt), size, 0); ... } 这里调用该函数来分配一段内存空间有两个返回值,一个返回值返回给了ret 指针,另一个返回值返回给了dma_handle 指针。virt_to_bus 和virt_to_phys 函数的调用可以参考下面的分析。经过分析这两个函数作用一样,都是将virt 这个虚拟地址转换为物理地址。所以返回给指针dma_handle 的是所分配内存的起始地址(物理地址)。__ioremap 函数的调用也可以参考下面的说明,该函数也返回所分配内存的起始地址(虚拟地址),不过是经过I/O 内存映射的,把物理地址转换为了虚拟地址。
这样一来就很清楚了,返回的framebuffer 的物理地址给了指针dma_handle,也就是fbi->map_dma,到fbi->screen_dma,再到fbi-> fb.fix.smem_start,最后到了指针VideoPhysicalTemp,这样写入到LCDADDR1,LCDADDR2 寄存器中的framebuffer 的地址其实都是物理地址。
而返回的framebuffer 的虚拟地址给了指针ret,也就是fbi->map_cpu,到fbi->screen_cpu,最后到了display-> screen_base(见/kernel/drivers/video/s3c2410fb.c 文件中的s3c2410fb_set_var 函数)。 ------------------------------------------------------------------------ 在/kernel/drivers/video/fbmem.c 文件中: /** * register_framebuffer - registers a frame buffer device * @fb_info: frame buffer info structure * * Registers a frame buffer device @fb_info. * * Returns negative errno on error, or zero for success. * */ int
register_framebuffer(struct fb_info *fb_info) /**
* unregister_framebuffer - releases a frame buffer device * @fb_info: frame buffer info structure * * Unregisters a frame buffer device @fb_info. * * Returns negative errno on error, or zero for success. * */ int
unregister_framebuffer(struct fb_info *fb_info) static int
fb_open(struct inode *inode, struct file *file) static int
fb_release(struct inode *inode, struct file *file) static ssize_t
fb_read(struct file *file, char *buf, size_t count, loff_t *ppos) static ssize_t
fb_write(struct file *file, const char *buf, size_t count, loff_t *ppos) static int
fb_ioctl(struct inode *inode, struct file *file, unsigned int cmd, unsigned long arg) static int
fb_mmap(struct file *file, struct vm_area_struct * vma) 在该文件中包含了所有驱动LCD 的函数。在fb_read 和fb_write 这两个函数中,都对framebuffer 进行了操作。
fb_read 函数中: char *base_addr; base_addr = info->disp->screen_base; count -= copy_to_user(buf, base_addr+p, count); fb_write 函数中:
char *base_addr; base_addr = info->disp->screen_base; count -= copy_from_user(base_addr+p, buf, count); 所读写的framebuffer 的基地址就是disp->screen_base,也就是fbi->screen_cpu 所指的framebuffer 的虚拟地址。 从而得到:
framebuffer(虚拟地址)
|---------------| | ... | -------|---------------| <-- fbi->map_cpu | 16K | 分配了 |---------------| <-- fbi->screen_cpu = display->screen_base 176K | | 共11个 | | 160K = 10个PAGE PAGE | 160K | 可以容下所需的150K 视频缓冲区大小 (16K) | | | | -------|---------------|------- | ... | |---------------| 其中display->screen_base 结构在/kernel/include/video/fbcon.h 文件中定义。
得出结论,在分配framebuffer 时一共返回两个指针,虽然是同一块内存空间,但一个返回的是实际的物理地址,另一个返回的是经过地址转换的虚拟地址。在设置LCD 控制器中framebuffer 起始地址寄存器时,用的是所分配内存的物理地址;而当要对framebuffer 进行读写操作时,用的是同一块内存的物理地址所转换后的虚拟地址。由此可以知道,内核在对每个I/O 地址进行读写操作时用的都是经过转换的虚拟地址。
------------------------------------------------------------------------ ------------------------------------------------------------------------ 在/kernel/include/asm-arm/arch-s3c2410/memory.h 文件中: /* * Page offset: 3GB */ #define PAGE_OFFSET (0xc0000000UL) #define PHYS_OFFSET (0x30000000UL)
/* * We take advantage of the fact that physical and virtual address can be the * saem. Thu NUMA code is handling the large holes that might exist between * all memory banks. */ #define __virt_to_phys__is_a_macro #define __phys_to_virt__is_a_macro #define __virt_to_phys(x) ((x) - PAGE_OFFSET + PHYS_OFFSET) #define __phys_to_virt(x) ((x) - PHYS_OFFSET + PAGE_OFFSET) 由此可见: 起始点地址 PHYS_OFFSET PAGE_OFFSET | | |--0x30000000--|------间隔------| PHYS_OFFSET(物理地址起始点): |--------------|........................... | |-----------0xc0000000----------| PAGE_OFFSET(虚拟地址起始点): |-------------------------------|.......... 物理地址与虚拟地址的间隔为:PAGE_OFFSET - PHYS_OFFSET。这样一来,以上对物理地址和虚拟地址之间转换的宏定义就很好理解了。 虚拟地址转为物理地址宏:__virt_to_phys(x) = (x) - (PAGE_OFFSET - PHYS_OFFSET) = (x) - PAGE_OFFSET + PHYS_OFFSET 物理地址转为虚拟地址宏:__phys_to_virt(x) = (x) + (PAGE_OFFSET - PHYS_OFFSET) = (x) + PAGE_OFFSET - PHYS_OFFSET 内核虚拟地址和实际物理地址仅仅是相差一个偏移量(PAGE_OFFSET),可以很方便的将其转化为物理内存地址,同时内核也提供了virt_to_phys() 函数将内核虚拟空间中的物理影射区地址转化为物理地址。
/* * Virtual view <-> DMA view memory address translations * virt_to_bus: Used to translate the virtual address to an * address suitable to be passed to set_dma_addr * bus_to_virt: Used to convert an address for DMA operations * to an address that the kernel can use. */ #define __virt_to_bus__is_a_macro #define __bus_to_virt__is_a_macro #define __virt_to_bus(x) __virt_to_phys(x) #define __bus_to_virt(x) __phys_to_virt(x) 这里注意:__virt_to_bus(x) 就等于__virt_to_phys(x) ------------------------------------------------------------------------
在/kernel/include/asm-arm/memory.h 文件中: /* * These are *only* valid on the kernel direct mapped RAM memory. */ static inline unsigned long virt_to_phys(volatile void *x) { return __virt_to_phys((unsigned long)(x)); } /* * Virtual <-> DMA view memory address translations * Again, these are *only* valid on the kernel direct mapped RAM * memory. */ #define virt_to_bus(x) (__virt_to_bus((unsigned long)(x))) 由上面的分析可知:virt_to_bus(x) 和virt_to_phys(volatile void *x) 这两个函数调用的都是__virt_to_phys(x) 即((x) - PAGE_OFFSET + PHYS_OFFSET)。所以这两个调用都是将虚拟地址转换为了物理地址。 ------------------------------------------------------------------------ 在/kernel/arch/arm/mm/ioremap.c 文件中: /* * Remap an arbitrary physical address space into the kernel virtual * address space. Needed when the kernel wants to access high addresses * directly. * * NOTE! We need to allow non-page-aligned mappings too: we will obviously * have to convert them into an offset in a page-aligned mapping, but the * caller shouldn''''t need to know that small detail. * * ''''flags'''' are the extra L_PTE_ flags that you want to specify for this * mapping. See include/asm-arm/proc-armv/pgtable.h for more information. */ void * __ioremap(unsigned long phys_addr, size_t size, unsigned long flags) ioremap 函数的作用是将physical address以及bus address映射为kernel的
virtual adrress。 ioremap 的作用是把I/O 内存地址(物理地址)映射到虚拟地址空间,使用之前需要分配I/O 内存区域。但是,ioremap 函数的内部实现并不是简单的((IO的物理地址)-0x10000000 +0xE4000000)。所以,得到的虚拟地址可能是不同的。 因为linux 用的是页面映射机制,CPU 不能按物理地址来访问存储空间,而必须使用虚拟地址,所以必须反向的从物理地址出发找到一片虚存空间并建立起映射。 //******************************************************* //* 2007.6.22 //******************************************************* 在/kernel/drivers/video/fbmem.c 文件中: static struct file_operations fb_fops = { owner: THIS_MODULE, read: fb_read, write: fb_write, ioctl: fb_ioctl, mmap: fb_mmap, open: fb_open, release: fb_release, #ifdef HAVE_ARCH_FB_UNMAPPED_AREA get_unmapped_area: get_fb_unmapped_area, #endif }; 这个结构中定义了对LCD 所分配的framebuffer 进行读写操作,以及一些内存映射之类的函数,这些源函数都在该文件中。
/** * register_framebuffer - registers a frame buffer device * @fb_info: frame buffer info structure * * Registers a frame buffer device @fb_info. * * Returns negative errno on error, or zero for success. * */ int
register_framebuffer(struct fb_info *fb_info) 这个是对LCD 的framebuffer 设备进行注册时调用到的注册函数,该函数在/kernel/drivers/video/s3c2410fb.c 文件的s3c2410fb_init 函数里的最后部分被调用。
fb_info->devfs_handle =
devfs_register (devfs_handle, name_buf, DEVFS_FL_DEFAULT, FB_MAJOR, i, S_IFCHR | S_IRUGO | S_IWUGO, &fb_fops, NULL); 在注册函数的最后部分,将前面的fb_fops 结构里的各个驱动函数的入口点传入到devfs_register()设备注册函数中。
//******************************************************* //* 2007.6.26 //******************************************************* 上面这个devfs_register 函数(原型在/kernel/fs/devfs/base.c 文件中)执行前,在fbmem_init 函数中调用了函数: devfs_handle = devfs_mk_dir (NULL, "fb", NULL);
在/kernel/fs/devfs/base.c 文件中: /** * devfs_mk_dir - Create a directory in the devfs namespace. * @dir: The handle to the parent devfs directory entry. If this is %NULL the * new name is relative to the root of the devfs. * @name: The name of the entry. * @info: An arbitrary pointer which will be associated with the entry. * * Use of this function is optional. The devfs_register() function * will automatically create intermediate directories as needed. This function * is provided for efficiency reasons, as it provides a handle to a directory. * Returns a handle which may later be used in a call to devfs_unregister(). * On failure %NULL is returned. */ devfs_handle_t devfs_mk_dir (devfs_handle_t dir, const char *name, void *info)
这个devfs_mk_dir 函数会在设备文件系统中创建一个名为fb 的目录,并返回一个带有devfs 设备文件系统目录结构的数据结构变量devfs_handle。然后把这个数据结构作为下一步调用devfs_register 函数时的参数,该参数在调用设备文件系统注册清除函数devfs_unregister 时也要作为参数传入。 /** * devfs_register - Register a device entry. * @dir: The handle to the parent devfs directory entry. If this is %NULL the * new name is relative to the root of the devfs. * @name: The name of the entry. * @flags: A set of bitwise-ORed flags (DEVFS_FL_*). * @major: The major number. Not needed for regular files. * @minor: The minor number. Not needed for regular files. * @mode: The default file mode. * @ops: The &file_operations or &block_device_operations structure. * This must not be externally deallocated. * @info: An arbitrary pointer which will be written to the @private_data * field of the &file structure passed to the device driver. You can set * this to whatever you like, and change it once the file is opened (the next * file opened will not see this change). * * Returns a handle which may later be used in a call to devfs_unregister(). * On failure %NULL is returned. */ devfs_handle_t devfs_register (devfs_handle_t dir, const char *name,
unsigned int flags, unsigned int major, unsigned int minor, umode_t mode, void *ops, void *info) 函数devfs_register 是设备文件系统的主册函数,会在刚才创建的目录下再创建一个名为name 的设备文件节点。返回的devfs_handle_t 数据结构变量会在调用设备文件系统注册清除函数devfs_unregister 时作为参数传入。
fb_info->devfs_handle = devfs_register (devfs_handle, name_buf, DEVFS_FL_DEFAULT, FB_MAJOR, i, S_IFCHR | S_IRUGO | S_IWUGO, &fb_fops, NULL); 调用该函数后,会在刚才创建的fb 目录下再创建一个名为0 (name_buf)的设备文件节点,并赋予相应的权限,以及主次设备号和file_operations 结构的函数入口。 这样一来,Linux 设备文件的创建,删除和目录层次等都由各设备驱动程序管理,再也不用手工创建设备文件节点了,再也不需要mknod 时查找对应的主设备号了,也不用依靠复杂的脚本来管理设备文件了。 |