surfaceFlinger的启动过程还是从Zygote说起。Zygote起来后会调用SystemServer.java[frameworks/base/services/java/com/android/server]里面的main函数,然后调用本地函数init1(),然后调用的是JNI的com_android_server_SystemServer.cpp里面的android_server_SystemServer_init1函数。
static void android_server_SystemServer_init1(JNIEnv* env, jobject
clazz)
{
system_init();
}
|
然后调用
System_init.cpp[frameworks/base/cmds/system_server/library]的system_init函数,通过获取属性字段system_init.startsurfaceflinger,如果字段值为1,那么就在这里启动surfaceflinger。
char propBuf[PROPERTY_VALUE_MAX];
property_get("system_init.startsurfaceflinger", propBuf, "1");if (strcmp(propBuf, "1") == 0) {
// Start the SurfaceFlinger
SurfaceFlinger::instantiate();
} |
然而,另一方面,有一个可执行文件surfaceflinger,由目录framework/base/cmds/surfaceflinger编译产生,目录下的主要文件main_surfaceflinger.cpp里面就一个main函数:
int main(int argc, char** argv)
{
sp<ProcessState> proc(ProcessState::self());
sp<IServiceManager> sm = defaultServiceManager();
LOGI("ServiceManager: %p", sm.get());
SurfaceFlinger::instantiate();
ProcessState::self()->startThreadPool();
IPCThreadState::self()->joinThreadPool();
}
|
以上两者都会调用SurfaceFlinger.cpp文件的instantiate函数。
void SurfaceFlinger::instantiate() {
defaultServiceManager()->addService(
String16("SurfaceFlinger"), new SurfaceFlinger());
}
|
如果你想在可执行文件中启动SurfaceFlinger,那么你可以在init.rc文件中增加类似如下语句:
service surfaceflinger /system/bin/surfaceflinger
user root
onrestart restart zygote
disabled
|
当然你也必须设置属性字段system_init.startsurfaceflinger为0,这个工作可以在init.rc中完成。
setprop system_init.startsurfaceflinger 0
|
surfaceflinger构造函数调用init()函数【surfaceflinger.cpp】,init函数主要打印"SurfaceFlinger
is starting"的Log信息,并且对一些debug属性进行配置。surfaceflinger构造函数调用readyToRun函数【surfaceflinger.cpp】,至于为什么会调用readyToRun函数(并没有显式的调用语句),主要是因为surfaceflinger是一个线程类,必须实现并会调用如下两个函数:一是readyToRun(),该函数定义了线程循环前需要初始化的内容;二是threadLoop(),每个线程都必须实现,该函数定义了线程执行的内容,如果该函数返回true,线程会继续调用threadLoop(),如果返回false,线程将退出。-->选自参考文献。
关于readyToRun将在下节分析
SurfaceFlinger启动过程分析(二)
上节说到SurfaceFlinger的readyToRun函数。先来看看它的代码:
(Google Android 2.2)
SurfaceFlinger.cpp
status_t SurfaceFlinger::readyToRun()
{
LOGI( "SurfaceFlinger's main thread ready to run. "
"Initializing graphics H/W...");
// we only support one display currently
int dpy = 0;
{
// initialize the main display
GraphicPlane& plane(graphicPlane(dpy));
DisplayHardware* const hw = new DisplayHardware(this, dpy);
plane.setDisplayHardware(hw);
}
// create the shared control-block
mServerHeap = new MemoryHeapBase(4096,
MemoryHeapBase::READ_ONLY, "SurfaceFlinger read-only heap");
LOGE_IF(mServerHeap==0, "can't create shared memory dealer");
mServerCblk = static_cast<surface_flinger_cblk_t*>(mServerHeap->getBase());
LOGE_IF(mServerCblk==0, "can't get to shared control block's
address");
new(mServerCblk) surface_flinger_cblk_t;
// initialize primary screen
// (other display should be initialized in the same manner, but
// asynchronously, as they could come and go. None of this is supported
// yet).
const GraphicPlane& plane(graphicPlane(dpy));
const DisplayHardware& hw = plane.displayHardware();
const uint32_t w = hw.getWidth();
const uint32_t h = hw.getHeight();
const uint32_t f = hw.getFormat();
hw.makeCurrent();
// initialize the shared control block
mServerCblk->connected |= 1<<dpy;
display_cblk_t* dcblk = mServerCblk->displays + dpy;
memset(dcblk, 0, sizeof(display_cblk_t));
dcblk->w = plane.getWidth();
dcblk->h = plane.getHeight();
dcblk->format = f;
dcblk->orientation = ISurfaceComposer::eOrientationDefault;
dcblk->xdpi = hw.getDpiX();
dcblk->ydpi = hw.getDpiY();
dcblk->fps = hw.getRefreshRate();
dcblk->density = hw.getDensity();
asm volatile ("":::"memory");
// Initialize OpenGL|ES
glActiveTexture(GL_TEXTURE0);
glBindTexture(GL_TEXTURE_2D, 0);
glTexParameterx(GL_TEXTURE_2D, GL_TEXTURE_WRAP_S, GL_CLAMP_TO_EDGE);
glTexParameterx(GL_TEXTURE_2D, GL_TEXTURE_WRAP_T, GL_CLAMP_TO_EDGE);
glTexParameterx(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_NEAREST);
glTexParameterx(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_NEAREST);
glTexEnvx(GL_TEXTURE_ENV, GL_TEXTURE_ENV_MODE, GL_REPLACE);
glPixelStorei(GL_UNPACK_ALIGNMENT, 4);
glPixelStorei(GL_PACK_ALIGNMENT, 4);
glEnableClientState(GL_VERTEX_ARRAY);
glEnable(GL_SCISSOR_TEST);
glShadeModel(GL_FLAT);
glDisable(GL_DITHER);
glDisable(GL_CULL_FACE);
const uint16_t g0 = pack565(0x0F,0x1F,0x0F);
const uint16_t g1 = pack565(0x17,0x2f,0x17);
const uint16_t textureData[4] = { g0, g1, g1, g0 };
glGenTextures(1, &mWormholeTexName);
glBindTexture(GL_TEXTURE_2D, mWormholeTexName);
glTexParameterx(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_NEAREST);
glTexParameterx(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_NEAREST);
glTexParameterx(GL_TEXTURE_2D, GL_TEXTURE_WRAP_S, GL_REPEAT);
glTexParameterx(GL_TEXTURE_2D, GL_TEXTURE_WRAP_T, GL_REPEAT);
glTexImage2D(GL_TEXTURE_2D, 0, GL_RGB, 2, 2, 0,
GL_RGB, GL_UNSIGNED_SHORT_5_6_5, textureData);
glViewport(0, 0, w, h);
glMatrixMode(GL_PROJECTION);
glLoadIdentity();
glOrthof(0, w, h, 0, 0, 1);
LayerDim::initDimmer(this, w, h);
mReadyToRunBarrier.open();
/*
* We're now ready to accept clients...
*/
// start boot animation
property_set("ctl.start", "bootanim");
return NO_ERROR;
}
|
调用readyToRun函数用于初始化整个显示系统。readyToRun()调用过程如下[这部分摘自网上资料]:(1)执行new DisplayHardware(this,dpy),通过DisplayHardware初始化Framebuffer、EGL并获取OpenGL
ES信息。
(2)创建共享的内存控制块。
(3)将EGL与当前屏幕绑定。
(4)初始化共享内存控制块。
(5)初始化OpenGL ES。
(6)显示开机动画。
上面的六点作为阅读代码的提纲及参考,下面对照代码进行分析:
(1)创建一个DisplayHardware,通过它的init函数去初始化Framebuffer、EGL并获取OpenGL
ES信息。
DisplayHardware.cpp[frameworks/base/libs/surfaceflinger/displayhardware]
DisplayHardware::DisplayHardware(
const sp<SurfaceFlinger>& flinger,
uint32_t dpy)
: DisplayHardwareBase(flinger, dpy)
{
init(dpy);
}
|
init函数的代码狠长,我们一块一块,一句一句地分析:
void DisplayHardware::init(uint32_t dpy)
{
mNativeWindow = new FramebufferNativeWindow();...
|
首先亮相的是第一句(如上),new一个FramebufferNativeWindow。
FramebufferNativeWindow构造函数的代码也不少,我们去掉一些次要的代码,挑重要的关键的说:
FramebufferNativeWindow::FramebufferNativeWindow()
: BASE(), fbDev(0), grDev(0), mUpdateOnDemand(false)
{
hw_module_t const* module;
if (hw_get_module(GRALLOC_HARDWARE_MODULE_ID, &module) == 0) {
int stride;
int err;
err = framebuffer_open(module, &fbDev);
LOGE_IF(err, "couldn't open framebuffer HAL (%s)", strerror(-err));
err = gralloc_open(module, &grDev);
LOGE_IF(err, "couldn't open gralloc HAL (%s)", strerror(-err));
// bail out if we can't initialize the modules
if (!fbDev || !grDev)
return;
mUpdateOnDemand = (fbDev->setUpdateRect != 0);
// initialize the buffer FIFO
mNumBuffers = 2;
mNumFreeBuffers = 2;
mBufferHead = mNumBuffers-1;
buffers[0] = new NativeBuffer(
fbDev->width, fbDev->height, fbDev->format, GRALLOC_USAGE_HW_FB);
buffers[1] = new NativeBuffer(
fbDev->width, fbDev->height, fbDev->format, GRALLOC_USAGE_HW_FB);err = grDev->alloc(grDev,
fbDev->width, fbDev->height, fbDev->format,
GRALLOC_USAGE_HW_FB, &buffers[0]->handle, &buffers[0]->stride);
LOGE_IF(err, "fb buffer 0 allocation failed w=%d, h=%d, err=%s",fbDev->width,fbDev->height, strerror(-err));
err = grDev->alloc(grDev,
fbDev->width, fbDev->height, fbDev->format,
GRALLOC_USAGE_HW_FB, &buffers[1]->handle, &buffers[1]->stride);
LOGE_IF(err, "fb buffer 1 allocation failed w=%d, h=%d, err=%s",fbDev->width,fbDev->height, strerror(-err));
...
} else {
LOGE("Couldn't get gralloc module");
}... }
|
关键的代码都被我高亮了,从最后一行的else的LOGE中可以看出这里主要是获得gralloc这个模块。模块ID定义在:gralloc.h[hardware/libhardware/include/hardware]
#define GRALLOC_HARDWARE_MODULE_ID "gralloc"
|
ps:有时候代码中的log狠有用,可以帮助我们读懂代码,而且logcat也是我们调试代码的好东西。
首先打开framebuffer和gralloc这两个模块
framebuffer_open和gralloc_open这两个接口在gralloc.h里面定义
static inline int framebuffer_open(const struct hw_module_t* module,
struct framebuffer_device_t** device) {
return module->methods->open(module,
GRALLOC_HARDWARE_FB0, (struct hw_device_t**)device);
}
static inline int gralloc_open(const struct hw_module_t* module,
struct alloc_device_t** device) {
return module->methods->open(module,
GRALLOC_HARDWARE_GPU0, (struct hw_device_t**)device);
}
|
两者指定的是gralloc.cpp中同一个函数gralloc_device_open,但是用的是不同的设备名,函数名和设备名分别在gralloc.cpp和gralloc.h中定义。
gralloc.h[hardware/libhardware/include/hardware] #define GRALLOC_HARDWARE_FB0 "fb0"
#define GRALLOC_HARDWARE_GPU0 "gpu0" gralloc.cpp[hardware/libhardware/modules/gralloc]
static struct hw_module_methods_t gralloc_module_methods = {
open: gralloc_device_open
};
|
gralloc.cpp[hardware/libhardware/modules/gralloc]
int gralloc_device_open(const hw_module_t* module, const char* name,
hw_device_t** device)
{
int status = -EINVAL;
if (!strcmp(name, GRALLOC_HARDWARE_GPU0)) {
gralloc_context_t *dev;
dev = (gralloc_context_t*)malloc(sizeof(*dev));
/* initialize our state here */
memset(dev, 0, sizeof(*dev));
/* initialize the procs */
dev->device.common.tag = HARDWARE_DEVICE_TAG;
dev->device.common.version = 0;
dev->device.common.module = const_cast<hw_module_t*>(module);
dev->device.common.close = gralloc_close;
dev->device.alloc = gralloc_alloc;
dev->device.free = gralloc_free;
*device = &dev->device.common;
status = 0;
} else {
status = fb_device_open(module, name, device);
}
return status;
}
|
gralloc_device_open函数通过设备名字来进行相关的初始化工作。打开framebuffer则调用fb_device_open函数。fb_device_open函数定义在framebuffer.cpp中。
int fb_device_open(hw_module_t const* module, const char* name,
hw_device_t** device)
{
int status = -EINVAL;
if (!strcmp(name, GRALLOC_HARDWARE_FB0)) {
alloc_device_t* gralloc_device;
status = gralloc_open(module, &gralloc_device);
if (status < 0)
return status;
/* initialize our state here */
fb_context_t *dev = (fb_context_t*)malloc(sizeof(*dev));
memset(dev, 0, sizeof(*dev));
/* initialize the procs */
dev->device.common.tag = HARDWARE_DEVICE_TAG;
dev->device.common.version = 0;
dev->device.common.module = const_cast<hw_module_t*>(module);
dev->device.common.close = fb_close;
dev->device.setSwapInterval = fb_setSwapInterval;
dev->device.post = fb_post;
dev->device.setUpdateRect = 0;
private_module_t* m = (private_module_t*)module;
status = mapFrameBuffer(m);
if (status >= 0) {
...
*device = &dev->device.common;
}
}
return status;
}
|
fb_device_open函数是framebuffer.cpp里面的函数它会再次调用gralloc_open函数,调用gralloc_open并没有什么实际的用途,只是检测模块的正确性,感觉这句话没有必要,还是我哪里理解错了???因为gralloc_device这个变量在后面都没有用到啊。
哈哈,经过测试,把以下几句注释掉,然后make,烧到手机上,手机基本功能仍旧正常,看来这几句代码狠有可能是没有什么特别用处的。
alloc_device_t* gralloc_device;
status = gralloc_open(module, &gralloc_device);
if (status < 0)
return status;
|
然后调用mapFrameBuffer函数,就是将显示缓冲区映射到用户空间,这样在用户空间就可以直接对显示缓冲区进行读写操作。mapFrameBuffer函数的主体功能是在mapFrameBufferLocked函数里面完成的。
关于mapFrameBuffer函数,在下节讲解。
SurfaceFlinger启动过程分析(三)
内存映射对于framebuffer来说非常重要,因为通常用户是不能直接操作物理地址空间的(也就是物理内存?),然而通过mmap映射之后,将framebuffer的物理地址空间映射到用户空间的一段虚拟地址中,用户就可以通过操作这段虚拟内存而间接操作framebuffer了,你在那段虚拟内存中画了图,相应的图就会显示到屏幕上。
——这段是自己的理解,有错必究!
下面是framebuffer.cpp中的mapFrameBufferLocked函数。
int mapFrameBufferLocked(struct private_module_t* module)
{
// already initialized...
if (module->framebuffer) {
return 0;
}
char const * const device_template[] = {
"/dev/graphics/fb%u",
"/dev/fb%u",
0 };
int fd = -1;
int i=0;
char name[64];
while ((fd==-1) && device_template[i]) {
snprintf(name, 64, device_template[i], 0);
fd = open(name, O_RDWR, 0);
i++;
}
if (fd < 0)
return -errno;
struct fb_fix_screeninfo finfo;
if (ioctl(fd, FBIOGET_FSCREENINFO, &finfo) == -1)
return -errno;
struct fb_var_screeninfo info;
if (ioctl(fd, FBIOGET_VSCREENINFO, &info) == -1)
return -errno;
info.reserved[0] = 0;
info.reserved[1] = 0;
info.reserved[2] = 0;
info.xoffset = 0;
info.yoffset = 0;
info.activate = FB_ACTIVATE_NOW;
/*
* Explicitly request 5/6/5
*/
info.bits_per_pixel = 16;
info.red.offset = 11;
info.red.length = 5;
info.green.offset = 5;
info.green.length = 6;
info.blue.offset = 0;
info.blue.length = 5;
info.transp.offset = 0;
info.transp.length = 0;
/*
* Request NUM_BUFFERS screens (at lest 2 for page flipping)
*/
info.yres_virtual = info.yres * NUM_BUFFERS;
uint32_t flags = PAGE_FLIP;
if (ioctl(fd, FBIOPUT_VSCREENINFO, &info) == -1) {
info.yres_virtual = info.yres;
flags &= ~PAGE_FLIP;
LOGW("FBIOPUT_VSCREENINFO failed, page flipping not supported");
}
if (info.yres_virtual < info.yres * 2) {
// we need at least 2 for page-flipping
info.yres_virtual = info.yres;
flags &= ~PAGE_FLIP;
LOGW("page flipping not supported (yres_virtual=%d, requested=%d)",
info.yres_virtual, info.yres*2);
}
if (ioctl(fd, FBIOGET_VSCREENINFO, &info) == -1)
return -errno;
int refreshRate = 1000000000000000LLU /
(
uint64_t( info.upper_margin + info.lower_margin + info.yres )
* ( info.left_margin + info.right_margin + info.xres )
* info.pixclock
);
if (refreshRate == 0) {
// bleagh, bad info from the driver
refreshRate = 60*1000; // 60 Hz
}
if (int(info.width) <= 0 || int(info.height) <= 0) {
// the driver doesn't return that information
// default to 160 dpi
info.width = ((info.xres * 25.4f)/160.0f + 0.5f);
info.height = ((info.yres * 25.4f)/160.0f + 0.5f);
}
float xdpi = (info.xres * 25.4f) / info.width;
float ydpi = (info.yres * 25.4f) / info.height;
float fps = refreshRate / 1000.0f;
LOGI( "using (fd=%d)/n"
"id = %s/n"
"xres = %d px/n"
"yres = %d px/n"
"xres_virtual = %d px/n"
"yres_virtual = %d px/n"
"bpp = %d/n"
"r = %2u:%u/n"
"g = %2u:%u/n"
"b = %2u:%u/n",
fd,
finfo.id,
info.xres,
info.yres,
info.xres_virtual,
info.yres_virtual,
info.bits_per_pixel,
info.red.offset, info.red.length,
info.green.offset, info.green.length,
info.blue.offset, info.blue.length
);
LOGI( "width = %d mm (%f dpi)/n"
"height = %d mm (%f dpi)/n"
"refresh rate = %.2f Hz/n",
info.width, xdpi,
info.height, ydpi,
fps
);
if (ioctl(fd, FBIOGET_FSCREENINFO, &finfo) == -1)
return -errno;
if (finfo.smem_len <= 0)
return -errno;
module->flags = flags;
module->info = info;
module->finfo = finfo;
module->xdpi = xdpi;
module->ydpi = ydpi;
module->fps = fps;
/*
* map the framebuffer
*/
int err;
size_t fbSize = roundUpToPageSize(finfo.line_length * info.yres_virtual);//对齐页
module->framebuffer = new private_handle_t(dup(fd), fbSize, 0);
module->numBuffers = info.yres_virtual / info.yres;
module->bufferMask = 0;
void* vaddr = mmap(0, fbSize, PROT_READ|PROT_WRITE, MAP_SHARED, fd, 0);
if (vaddr == MAP_FAILED) {
LOGE("Error mapping the framebuffer (%s)", strerror(errno));
return -errno;
}
module->framebuffer->base = intptr_t(vaddr);
memset(vaddr, 0, fbSize);
return 0;
}
|
这个函数就是和驱动相关的调用,其实结合驱动去看代码是很有意思的,把一路都打通了。
该函数首先通过open函数打开设备结点。
"/dev/graphics/fb%u"和"/dev/fb%u",如果前一个顺利打开的话,那么就不打开第二个。我的Log显示打开的是第一个设备结点/dev/graphics/fb%u。
然后通过ioctl读取设备的固定参数(FBIOGET_FSCREENINFO)和可变参数(FBIOGET_VSCREENINFO)。
【kernel部分的代码在drivers/video/fbmem.c中。】然后对可变参数进行修改,通过ioctl设置(FBIOPUT_VSCREENINFO)显示屏的可变参数。
设置好以后再ioctl-FBIOGET_VSCREENINFO获得可变参数,然后在log上打出显示屏的各个参数设置,也就是我们开机看到的一长串log。
I/gralloc ( 1620): using (fd=8)
I/gralloc ( 1620): id = truly-ILI9327
I/gralloc ( 1620): xres = 240 px
I/gralloc ( 1620): yres = 400 px
I/gralloc ( 1620): xres_virtual = 240 px
I/gralloc ( 1620): yres_virtual = 800 px
I/gralloc ( 1620): bpp = 16
I/gralloc ( 1620): r = 11:5
I/gralloc ( 1620): g = 5:6
I/gralloc ( 1620): b = 0:5
I/gralloc ( 1620): width = 38 mm (160.421051
dpi)
I/gralloc ( 1620): height = 64 mm (158.750000
dpi)
I/gralloc ( 1620): refresh rate = 60.00 Hz
|
然后通过mmap完成对显示缓存区的映射。这样mapFrameBufferLocked函数的任务算是完成了。
好了,以上所讲的只是(1)中的第一句话而已
Displayhardware.cpp中的init函数。
mNativeWindow = new FramebufferNativeWindow();
|
SurfaceFlinger启动过程分析(四)
在加载完framebuffer和gralloc模块之后,我们来看FramebufferNativeWindow构造函数中的代码:
buffers[0] = new NativeBuffer(
fbDev->width, fbDev->height, fbDev->format, GRALLOC_USAGE_HW_FB);
buffers[1] = new NativeBuffer(
fbDev->width, fbDev->height, fbDev->format, GRALLOC_USAGE_HW_FB);
err = grDev->alloc(grDev,
fbDev->width, fbDev->height, fbDev->format,
GRALLOC_USAGE_HW_FB, &buffers[0]->handle, &buffers[0]->stride);
LOGE_IF(err, "fb buffer 0 allocation failed w=%d, h=%d, err=%s", fbDev->width,fbDev->height, strerror(-err));
err = grDev->alloc(grDev,
fbDev->width, fbDev->height, fbDev->format,
GRALLOC_USAGE_HW_FB, &buffers[1]->handle, &buffers[1]->stride);
LOGE_IF(err, "fb buffer 1 allocation failed w=%d, h=%d, err=%s",fbDev->width,fbDev->height, strerror(-err));
|
该构造函数中关键的就剩下这四句高亮代码了,这四句也是framebuffer双缓存机制的关键。
首先新建了两个NativeBuffer,然后通过grDev为它们分配内存空间。这个grDev就是上面gralloc_open的gralloc设备模块。grDev->alloc这个函数在gralloc_device_open函数里面指定了是gralloc.cpp中的gralloc_alloc函数。
dev->device.alloc = gralloc_alloc;
|
为两个缓冲区分配完内存之后,FramebufferNativeWindow构造函数的事情就算完了。下面继续看DisplayHardware.cpp中init函数接下去的代码。DisplayHardware.cpp
if (hw_get_module(OVERLAY_HARDWARE_MODULE_ID, &module) == 0) {
overlay_control_open(module, &mOverlayEngine);
}
// initialize EGL
...
|
接下去就获得overlay模块,前提是你的设备支持overlay。
然后就初始化EGL。DisplayHardware.cpp
EGLDisplay display = eglGetDisplay(EGL_DEFAULT_DISPLAY);
eglInitialize(display, NULL, NULL);
eglGetConfigs(display, NULL, 0, &numConfigs);
EGLConfig config;
status_t err = EGLUtils::selectConfigForNativeWindow(
display, attribs, mNativeWindow.get(), &config);
|
eglGetDisplay是EGL用来获取物理屏幕句柄的函数。返回的是EGLDisplay,代表一个物理显示设备。调用这个函数进入的是egl.cpp[frameworks/base/opengl/libs/egl]
EGLDisplay eglGetDisplay(NativeDisplayType display)
{
uint32_t index = uint32_t(display);
if (index >= NUM_DISPLAYS) {
return setError(EGL_BAD_PARAMETER, EGL_NO_DISPLAY);
}
if (egl_init_drivers() == EGL_FALSE) {
return setError(EGL_BAD_PARAMETER, EGL_NO_DISPLAY);
}
EGLDisplay dpy = EGLDisplay(uintptr_t(display) + 1LU);
return dpy;
}
|
它会调用egl_init_drivers去初始化设备。egl_init_drivers->egl_init_drivers_locked
下面简单贴一下egl_init_drivers_locked代码:
EGLBoolean egl_init_drivers_locked()
{
if (sEarlyInitState) {
// initialized by static ctor. should be set here.
return EGL_FALSE;
}
// get our driver loader
Loader& loader(Loader::getInstance());
cnx = &gEGLImpl[IMPL_SOFTWARE];
if (cnx->dso == 0) {
cnx->hooks[GLESv1_INDEX] = &gHooks[GLESv1_INDEX][IMPL_SOFTWARE];
cnx->hooks[GLESv2_INDEX] = &gHooks[GLESv2_INDEX][IMPL_SOFTWARE];
cnx->dso = loader.open(EGL_DEFAULT_DISPLAY, 0, cnx);
if (cnx->dso) {
EGLDisplay dpy = cnx->egl.eglGetDisplay(EGL_DEFAULT_DISPLAY);
LOGE_IF(dpy==EGL_NO_DISPLAY, "No EGLDisplay for software
EGL!");
d->disp[IMPL_SOFTWARE].dpy = dpy;
if (dpy == EGL_NO_DISPLAY) {
loader.close(cnx->dso);
cnx->dso = NULL;
}
}
}
cnx = &gEGLImpl[IMPL_HARDWARE];
if (cnx->dso == 0) {
...
} else {
LOGD("3D hardware acceleration is disabled");
}
}
return EGL_TRUE;
}
|
egl_init_drivers_locked()函数的作用就是填充gEGLImpl[IMPL_SOFTWARE]和gEGLImpl[IMPL_
HARDWARE]两个数组项。达到通过gEGLImpl[IMPL_SOFTWARE]和gEGLImpl[IMPL_
HARDWARE]两个数组项就可以调用libGLES_android.so库中所有函数的目的。
cnx->hooks[GLESv1_INDEX] = &gHooks[GLESv1_INDEX][IMPL_SOFTWARE];
cnx->hooks[GLESv2_INDEX] = &gHooks[GLESv2_INDEX][IMPL_SOFTWARE];
|
上面这两句代码的作用是引用赋值,在loader.open完以后,
cnx->hooks[GLESv1_INDEX]会被赋值,而相对应的
gHooks[GLESv1_INDEX][IMPL_SOFTWARE]也会被赋值。Loader的构造函数先从/system/lib/egl/egl.cfg中读取配置,如果不存在,那就选用默认配置。
Loader::Loader(){char line[256];char tag[256];FILE* cfg = fopen("/system/lib/egl/egl.cfg", "r");if (cfg == NULL) {// default configLOGD("egl.cfg not found, using default config");gConfig.add( entry_t(0, 0, "android") );} else {while (fgets(line, 256, cfg)) {int dpy;int impl;if (sscanf(line, "%u
%u %s", &dpy, &impl, tag) == 3) {//LOGD(">>> %u %u %s", dpy, impl, tag);gConfig.add( entry_t(dpy, impl, tag) );}}fclose(cfg);}}
|
默认的配置为(0, 0, "android")并把它放在gConfig中,以备在调用Loader.open的时候使用。
void* Loader::open(EGLNativeDisplayType
display, int impl, egl_connection_t* cnx){/** TODO: if we don't find display/0, then use 0/0* (0/0 should always work)*/void* dso;char path[PATH_MAX];int index = int(display);driver_t* hnd = 0;const char* const format = "/system/lib/egl/lib%s_%s.so";char const* tag = getTag(index, impl);if (tag) {snprintf(path, PATH_MAX, format, "GLES", tag);dso = load_driver(path, cnx, EGL | GLESv1_CM | GLESv2);if (dso) {hnd = new driver_t(dso);} else {// Always load EGL firstsnprintf(path, PATH_MAX, format, "EGL", tag);dso = load_driver(path, cnx, EGL);if (dso) {hnd = new driver_t(dso);// TODO: make this more automatedsnprintf(path, PATH_MAX, format, "GLESv1_CM", tag);hnd->set( load_driver(path, cnx, GLESv1_CM), GLESv1_CM );snprintf(path, PATH_MAX, format, "GLESv2", tag);hnd->set( load_driver(path, cnx, GLESv2), GLESv2 );}}}LOG_FATAL_IF(!index && !impl && !hnd,"couldn't find the default OpenGL ES implementation ""for default display");return (void*)hnd;}
|
Loader::open这个函数首先去加载/system/lib/egl/libGLES_android.so,如果加载成功,那么对EGL
| GLESv1_CM | GLESv2三个函数库,进行初始化。如果加载不成功,那么就加载libEGL_android.so,libGLESv1_CM_android.so,libGLESv2_android.so这三个库,事实上我们的/system/lib/egl目录下面只有libGLES_android.so这一个库,所以加载libGLES_android.so库。Ps:libEGL.so ,libGLESv1_CM.so, libGLESv2.so三个库在/system/lib目录下面。
下面简单地分析下EGL的配置。首先在Loader的构造函数中获取了EGL的配置信息0,
0, "android",然后把它放在一个结构体中,这个结构体名为entry_t,定义如下
struct entry_t {entry_t() { }entry_t(int dpy, int impl, const char* tag);int dpy;int impl;String8 tag;};
|
随后在Loader::open中调用getTag(index, impl),其实为getTag(0,
0)。所以getTag返回的是字符串android。
const char* Loader::getTag(int dpy, int impl){const Vector<entry_t>& cfgs(gConfig);const size_t c = cfgs.size();for (size_t i=0 ; i<c ; i++) {if (dpy == cfgs[i].dpy)if (impl == cfgs[i].impl)return cfgs[i].tag.string();}return 0;}
|
现在有了库的路径path = /system/lib/egl/libGLES_android.so,通过load_driver函数来加载函数库。
Loader::load_driver
void *Loader::load_driver(const char* driver_absolute_path,egl_connection_t* cnx, uint32_t mask){if (access(driver_absolute_path, R_OK)) {// this happens often, we don't want to log an errorreturn 0;}//加载libGLES_android.sovoid* dso = dlopen(driver_absolute_path, RTLD_NOW | RTLD_LOCAL);if (dso == 0) {const char* err = dlerror();LOGE("load_driver(%s): %s", driver_absolute_path, err?err:"unknown");return 0;}LOGD("loaded %s", driver_absolute_path);if (mask & EGL) {//加载EGL函数库getProcAddress = (getProcAddressType)dlsym(dso, "eglGetProcAddress");LOGE_IF(!getProcAddress,"can't find eglGetProcAddress() in %s", driver_absolute_path);egl_t* egl = &cnx->egl;//把函数赋值到cnx->egl中__eglMustCastToProperFunctionPointerType* curr =(__eglMustCastToProperFunctionPointerType*)egl;char const * const * api = egl_names;while (*api) {char const * name = *api;__eglMustCastToProperFunctionPointerType f =(__eglMustCastToProperFunctionPointerType)dlsym(dso, name);if (f == NULL) {// couldn't find the entry-point, use eglGetProcAddress()f = getProcAddress(name);if (f == NULL) {f = (__eglMustCastToProperFunctionPointerType)0;}}*curr++ = f;api++;}}if (mask & GLESv1_CM) {//加载GLESv1_CM函数库init_api(dso, gl_names,(__eglMustCastToProperFunctionPointerType*)&cnx->hooks[GLESv1_INDEX]->gl,getProcAddress);}if (mask & GLESv2) {//加载GLESv2函数库init_api(dso, gl_names,(__eglMustCastToProperFunctionPointerType*)&cnx->hooks[GLESv2_INDEX]->gl,getProcAddress);}return dso;}
|
通过系统调用dlopen打开一个动态链接库。以下是百度百科对dlopen的解释:
dlopen() 功能:打开一个动态链接库 包含头文件: #include <dlfcn.h> 函数定义: void * dlopen( const char * pathname, int mode ); 函数描述: 在dlopen的()函数以指定模式打开指定的动态连接库文件,并返回一个句柄给调用进程。使用dlclose()来卸载打开的库。
|
然后通过dlsym函数获得指向函数地址指针。以下是百度百科对dlsym的解释:
dlsym()的函数原型是 void* dlsym(void* handle,const char* symbol) 该函数在<dlfcn.h>文件中。 handle是由dlopen打开动态链接库后返回的指针,symbol就是要求获取的函数的名称,函数返回值是void*,指向函数的地址,供调用使用。
|
dlsym首先去得到eglGetProcAddress的函数指针,这个函数的原型:void (*eglGetProcAddress(const char *procname)) ();该函数的作用是返回由procname指定的扩展函数地址。
下面综述一下load_driver函数所做的工作:首先通过dlopen加载libGLES_android.so库,库所在路径为/system/lib/egl/libGLES_android.so,然后从libGLES_android.so库中提取EGL的各个API函数的地址放到cnx->egl中,从libGLES_android.so获取GLESv1_CM的API保存到cnx->hooks[GLESv1_INDEX]->gl中,从libGLES_android.so获取GLESv1_CM的API保存到cnx->hooks[GLESv2_INDEX]->gl。
提取EGLAPI地址的方法是首先通过dlsym函数获得一个获取函数地址的函数eglGetProcAddress的地址,然后遍历EGL的API所在文件frameworks/base/opengl/libs/EGL/egl_entries.in。先通过dlsym获取各个API地址,如果返回NULL再利用eglGetProcAddress去获得,如果依旧为空就把函数地址赋值为0;提取GLESv1_CM和GLESv1_CM库中函数地址方法和提取EGL差不多,只是他们的函数文件保存在frameworks/base/opengl/libs/entries.in中。还有它们把函数地址复制给了cnx->hooks[GLESv1_INDEX]->gl和cnx->hooks[GLESv2_INDEX]->gl。等加载完库以后在libs/egl/egl.cpp里面的egl_init_drivers_locked就通过cnx->egl.eglGetDisplay(EGL_DEFAULT_DISPLAY);调用eglGetDisplay函数,其实就是调用libGLES_android.so里面的eglGetDisplay函数,libGLES_android.so库是由目录frameworks/base/opengl/libagl生成的,所以libGLES_android.so里面的eglGetDisplay函数是文件libagl/egl.cpp里面的。
其实libs/egl/egl.cpp中的函数,大多是调用libGLES_android.so库里面的,是对其的一种封装,也就是说调用libagl/egl.cpp文件里面的同名函数,如eglGetDisplay,eglCreateWindowSurface,eglCreateContext等。因为libGLES_android.so库是由rameworks/base/opengl/libagl目录生成。本文转自:文章出处:http://danielwood.cublog.cn
作者:Daniel Wood
