mx51的三个framebuffer,mxc_ipuv3_fb.c分析
转载:http://blog.csdn.net/jack_a8/article/details/43309169
mx51支持三个framebuffer:fb0, fb1, fb2
/dev/graphics/fb0,/dev/graphics/fb1:
一个作为系统的主framebuffer,另外一个作为TVOUT输出的framebuffer,缺省情况下,fb0做primary(也就是用来在primary LCD显示UI),fb1做secondary(也就是用来在TVOUT输出上显示数据)。
根据项目中的实际物理连接情况,如果primary LCD连接到disp0,那么使用缺省设置,如果primary LCD连接到disp1,那么就要在kernel启动参数中加入di1_primary。
/dev/graphics/fb2 :
用来实现overlay叠加,显示video数据的framebuffer,仅支持bpp16,数据格式是yuv422,可以在DP(Display Process)和来自MEM_BG_SYNC的数据进行合成,再传送到DC/DI。
在mxc framebuffer probe 时,第一个注册的mxc framebuffer (fb0 或者fb1,这个framebuffer作为主LCD的framebuffer)使用MEM_BG_SYNC,第二个注册的mxc framebuffer(fb0或者fb1,这个framebuffer作为TVOUT使用的framebuffer)使用MEM_DC_SYNC,最后一个注册的framebuffer(fb2)使用MEM_FG_SYNC。
MEM_BG_SYNC 和MEM_FG_SYNC都是mx5x ipu中独一无二的资源,这意味着每个通道只能被其中一个framebuffer占用。事实上MEM_DC_SYNC这个通道并不存在,只是用来表示直接连接到DC
注意这几个framebuffer中的数据并不是直连显示设备,中间可能还有MX51 IPU的DP处理单元,DP Unit负责对fb0 fb1 fb2过来的数据进行处理,包括颜色转换,图层合并,gamma处理以及光标处理后发送给DC->DI->显示设备
fsl 在/sys/class/graphics/fbx/ 下创建了一个fsl特定的属性文件fsl_disp_property,在我的机器上显示如下
- # cat /sys/class/graphics/fb0/fsl_disp_property
- 2-layer-fb-bg
- # cat /sys/class/graphics/fb1/fsl_disp_property
- 1-layer-fb
- # cat /sys/class/graphics/fb2/fsl_disp_property
- 2-layer-fb-fg
2-layer-fb-bg,表示fb0使用MEM_BG_SYNC通道,在IPU 的Display Process模块和MEM_FG_SYNC通道来的数据合并,再送入DC
1-layer-fb,表示fb1使用MEM_DC_SYNC通道,不经过Display Process模块,DC(Display Control)直接连接到DI(Display Interface)
2-layber-fb-fg,表示fb2使用MEM_FG_SYNC通道,在IPU的Display Process模块和MEM_BG_SYNC通道来的数据合并,再送入DC
应用层还可以修改/sys/class/graphics/fb0/fsl_disp_property和/sys/class/graphics/fb1/fsl_disp_property,使用如下命令:
- echo 1-layer-fb > /sys/class/graphics/fb0/fsl_disp_property
- 或者
- echo 2-layer-fb-bg > /sys/class/graphics/fb1/fsl_disp_property
注意,二者的作用是一样的,都会导致fb0和fb1交换显示通道,fsl引入这个属性的目的,就是给上层应用提供一个接口,使得应用层可以控制fb0 fb1使用MEM_BG_SYNC还是MEM_DC_SYNC通道,说到这里可能还是让人糊涂,为什么应用层要选择fb0 fb1的通道,这要先搞清楚MEM_BG_SYNC和MEM_DC_SYNC的区别。
imx51/imx53 IPU支持三种类型的显示通道:MEM_BG_SYNC, MEM_FG_SYNC和MEM_DC_SYNC,framebuffer只能通过三者之一传送数据,这些通道在物理上是唯一的,同一时间只能被一个framebuffer使用。
- MEM_BG_SYNC:fb0 -> DP (full plane) -> DC -> DI0
- MEM_FG_SYNC:fb2 -> DP (partial plane) -> DC -> DI0
- MEM_DC_SYNC:fb1 -> DC -> DI1
MEM_BG_SYNC和MEM_FG_SYNC会在DP进行合并处理,这个功能就是所谓的overlay。
正常情况下来自fb0的UI和来自fb2的video数据在DP合并后,送到DI0,我们就可以看到UI 浮在video上面的效果。但是当激活双屏的时候,一般希望video数据和UI 都送到后屏(也就是DI1),前屏只显示UI。这就需要fb1拥有MEM_BG_SYNC,此时需要交换fb1和fb0的显示通道如下:
- MEM_BG_SYNC: fb1 -> DP (full plane) -> DC -> DI0
- MEM_FG_SYNC: fb2 -> DP (partial plane) -> DC -> DI1
- MEM_DC_SYNC: fb0 -> DC -> DI0
通道交换代码
- swap_disp_chan
- 1673 static ssize_t swap_disp_chan(struct device *dev,
- 1674 struct device_attribute *attr,
- 1675 const char *buf, size_t count)
- 1676 {
- 1677 struct fb_info *info = dev_get_drvdata(dev);
- 1678 struct mxcfb_info *mxcfbi = (struct mxcfb_info *)info->par;
- 1679 struct mxcfb_info *fg_mxcfbi = NULL;
- 1680
- 1681 acquire_console_sem();
- 1682 /* swap only happen between DP-BG and DC, while DP-FG disable */
- 1683 if (((mxcfbi->ipu_ch == MEM_BG_SYNC) &&
- 1684 (strstr(buf, “1-layer-fb”) != NULL)) ||
- 1685 ((mxcfbi->ipu_ch == MEM_DC_SYNC) &&
- 1686 (strstr(buf, “2-layer-fb-bg”) != NULL))) {
- 1687 int i;
- 1688
- 1689 for (i = 0; i < num_registered_fb; i++) {
- 1690 fg_mxcfbi =
- 1691 (struct mxcfb_info *)mxcfb_info[i]->par;
- 1692 if (fg_mxcfbi->ipu_ch == MEM_FG_SYNC)
- 1693 break;
- 1694 else
- 1695 fg_mxcfbi = NULL;
- 1696 }
- 1697 if (!fg_mxcfbi ||
- 1698 fg_mxcfbi->cur_blank == FB_BLANK_UNBLANK) {
- 1699 dev_err(dev,
- 1700 “Can not switch while fb2(fb-fg) is on.\n”);
- 1701 release_console_sem();
- 1702 return count;
- 1703 }
- 1704
- 1705 if (swap_channels(info) < 0)
- 1706 dev_err(dev, “Swap display channel failed.\n”);
- 1707 }
- 1708
- 1709 release_console_sem();
- 1710 return count;
- 1711 }
- 1712 DEVICE_ATTR(fsl_disp_property, 644, show_disp_chan, swap_disp_chan);
1682~1686 只有fb0和fb1才会参与显示通道的交换,fb2只使用MEM_FG_SYNC
1705 调用swap_channels实现通道的切换
- swap_channels
- 545 static int swap_channels(struct fb_info *fbi)
- 546 {
- 547 int i;
- 548 int swap_mode;
- 549 ipu_channel_t ch_to;
- 550 struct mxcfb_info *mxc_fbi_from = (struct mxcfb_info *)fbi->par;
- 551 struct fb_info *fbi_to = NULL;
- 552 struct mxcfb_info *mxc_fbi_to;
- 553
- 554 /* what\’s the target channel? */
- 555 if (mxc_fbi_from->ipu_ch == MEM_BG_SYNC)
- 556 ch_to = MEM_DC_SYNC;
- 557 else
- 558 ch_to = MEM_BG_SYNC;
- 559
- 560 for (i = 0; i < num_registered_fb; i++) {
- 561 mxc_fbi_to =
- 562 (struct mxcfb_info *)mxcfb_info[i]->par;
- 563 if (mxc_fbi_to->ipu_ch == ch_to) {
- 564 fbi_to = mxcfb_info[i];
- 565 break;
- 566 }
- 567 }
- 568 if (fbi_to == NULL)
- 569 return -1;
- 570
- 571 ipu_clear_irq(mxc_fbi_from->ipu_ch_irq);
- 572 ipu_clear_irq(mxc_fbi_to->ipu_ch_irq);
- 573 ipu_free_irq(mxc_fbi_from->ipu_ch_irq, fbi);
- 574 ipu_free_irq(mxc_fbi_to->ipu_ch_irq, fbi_to);
- 575
- 576 if (mxc_fbi_from->cur_blank == FB_BLANK_UNBLANK) {
- 577 if (mxc_fbi_to->cur_blank == FB_BLANK_UNBLANK)
- 578 swap_mode = BOTH_ON;
- 579 else
- 580 swap_mode = SRC_ON;
- 581 } else {
- 582 if (mxc_fbi_to->cur_blank == FB_BLANK_UNBLANK)
- 583 swap_mode = TGT_ON;
- 584 else
- 585 swap_mode = BOTH_OFF;
- 586 }
- 587
- 588 /* tvout di-1: for DC use UYVY, for DP use RGB */
- 589 if (mxc_fbi_from->ipu_di == 1 && ch_to == MEM_DC_SYNC) {
- 590 fbi->var.bits_per_pixel = 16;
- 591 fbi->var.nonstd = IPU_PIX_FMT_UYVY;
- 592 } else if (mxc_fbi_from->ipu_di == 1 && ch_to == MEM_BG_SYNC) {
- 593 fbi->var.nonstd = 0;
- 594 } else if (mxc_fbi_from->ipu_di == 0 && ch_to == MEM_DC_SYNC) {
- 595 fbi_to->var.nonstd = 0;
- 596 } else if (mxc_fbi_from->ipu_di == 0 && ch_to == MEM_BG_SYNC) {
- 597 fbi->var.bits_per_pixel = 16;
- 598 fbi->var.nonstd = IPU_PIX_FMT_UYVY;
- 599 }
- 600
- 601 switch (swap_mode) {
- 602 case BOTH_ON:
- 603 /* disable target->switch src->enable target */
- 604 _swap_channels(fbi, fbi_to, true);
- 605 break;
- 606 case SRC_ON:
- 607 /* just switch src */
- 608 _swap_channels(fbi, fbi_to, false);
- 609 break;
- 610 case TGT_ON:
- 611 /* just switch target */
- 612 _swap_channels(fbi_to, fbi, false);
- 613 break;
- 614 case BOTH_OFF:
- 615 /* switch directly, no more need to do */
- 616 mxc_fbi_to->ipu_ch = mxc_fbi_from->ipu_ch;
- 617 mxc_fbi_from->ipu_ch = ch_to;
- 618 i = mxc_fbi_from->ipu_ch_irq;
- 619 mxc_fbi_from->ipu_ch_irq = mxc_fbi_to->ipu_ch_irq;
- 620 mxc_fbi_to->ipu_ch_irq = i;
- 621 break;
- 622 default:
- 623 break;
- 624 }
- 625
- 626 if (ipu_request_irq(mxc_fbi_from->ipu_ch_irq, mxcfb_irq_handler, 0,
- 627 MXCFB_NAME, fbi) != 0) {
- 628 dev_err(fbi->device, “Error registering irq %d\n”,
- 629 mxc_fbi_from->ipu_ch_irq);
- 630 return -EBUSY;
- 631 }
- 632 ipu_disable_irq(mxc_fbi_from->ipu_ch_irq);
- 633 if (ipu_request_irq(mxc_fbi_to->ipu_ch_irq, mxcfb_irq_handler, 0,
- 634 MXCFB_NAME, fbi_to) != 0) {
- 635 dev_err(fbi_to->device, “Error registering irq %d\n”,
- 636 mxc_fbi_to->ipu_ch_irq);
- 637 return -EBUSY;
- 638 }
- 639 ipu_disable_irq(mxc_fbi_to->ipu_ch_irq);
- 640
- 641 return 0;
- 642 }
550 mxc_fbi_from 和字面意思一样,我们想要交换哪一个fb_info,也就是交换源
555~558 交换只发生在MEM_DC_SYNC和MEM_BG_SYNC之间,如果源fb的通道是MEM_BG_SYNC,那么我们希望交换为MEM_DC_SYNC,反之亦然。
560~567 找到目标通道坐在的framebuffer
576~586 swap_mode记录下source和dest framebuffer的blank状态
571~574 先释放from和to的ipu 通道中断号,因为IPU通道中断号也会随着通道一起交换
589~599 I have no idea
601~613 _swap_channels进行交换
614~620 如果fbi_from和fbi_to都处于BLANK状态,那么直接交换通道即可,注意通道中断号也需要交换,因为通道和通道中断号是一一对应的。
626~642 重新为fbi_from和fbi_to申请ipu irq,这里disable了irq,不过不要紧,当pan_display操作时,会使能ipu irq
- swap_channels
- 504 static int _swap_channels(struct fb_info *fbi,
- 505 struct fb_info *fbi_to, bool both_on)
- 506 {
- 507 int retval, tmp;
- 508 ipu_channel_t old_ch;
- 509 struct mxcfb_info *mxc_fbi_from = (struct mxcfb_info *)fbi->par;
- 510 struct mxcfb_info *mxc_fbi_to = (struct mxcfb_info *)fbi_to->par;
- 511
- 512 if (both_on) {
- 513 ipu_disable_channel(mxc_fbi_to->ipu_ch, true);
- 514 ipu_uninit_channel(mxc_fbi_to->ipu_ch);
- 515 }
- 516
- 517 /* switch the mxc fbi parameters */
- 518 old_ch = mxc_fbi_from->ipu_ch;
- 519 mxc_fbi_from->ipu_ch = mxc_fbi_to->ipu_ch;
- 520 mxc_fbi_to->ipu_ch = old_ch;
- 521 tmp = mxc_fbi_from->ipu_ch_irq;
- 522 mxc_fbi_from->ipu_ch_irq = mxc_fbi_to->ipu_ch_irq;
- 523 mxc_fbi_to->ipu_ch_irq = tmp;
- 524
- 525 _setup_disp_channel1(fbi);
- 526 retval = _setup_disp_channel2(fbi);
- 527 if (retval)
- 528 return retval;
- 529
- 530 /* switch between dp and dc, disable old idmac, enable new idmac */
- 531 retval = ipu_swap_channel(old_ch, mxc_fbi_from->ipu_ch);
- 532 ipu_uninit_channel(old_ch);
- 533
- 534 if (both_on) {
- 535 _setup_disp_channel1(fbi_to);
- 536 retval = _setup_disp_channel2(fbi_to);
- 537 if (retval)
- 538 return retval;
- 539 ipu_enable_channel(mxc_fbi_to->ipu_ch);
- 540 }
- 541
- 542 return retval;
- 543 }
504~505 函数有三个参数,@fbi是source,@fbi_to是dest,@both_on 布尔量为true 则@fbi_to为UNBLANK状态;false,则@fbi_to为BLANK状态。这里@fbi一定为UNBLANK状态,否则不会调用这个函数。
512~515 在交换之前,先销毁掉@fbi_to的channel
518~523 交换二者的通道和通道irq
525~528 交换完成后,设置disp通道的参数。
531~532 现在,通道号已经交换完成,但是还有一件事没有完成,我们知道DC通道1,5的控制寄存器DC_WR_CH_CONF_x中,配置着这个DC通道连接到哪一个DI,我们希望交换通道,但是不希望更改到DI的配置。ipu_swap_channel交换两个DC通道的DI配置。
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