platform_hardware_libhardware/include/hardware/hwcomposer.h
Rom Lemarchand 4c2aa4c223 HAL test: statically test the size of HAL structs
Ensure none of the HAL structs change size over time.
Issues might arise when making changes without taking the different
pointer sizes for specific architectures into account.

Change-Id: I63f00004a23f09b2f46df01e7c69296766a5d03f
2013-11-21 15:52:05 -08:00

647 lines
26 KiB
C

/*
* Copyright (C) 2010 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#ifndef ANDROID_INCLUDE_HARDWARE_HWCOMPOSER_H
#define ANDROID_INCLUDE_HARDWARE_HWCOMPOSER_H
#include <stdint.h>
#include <sys/cdefs.h>
#include <hardware/gralloc.h>
#include <hardware/hardware.h>
#include <cutils/native_handle.h>
#include <hardware/hwcomposer_defs.h>
__BEGIN_DECLS
/*****************************************************************************/
/* for compatibility */
#define HWC_MODULE_API_VERSION HWC_MODULE_API_VERSION_0_1
#define HWC_DEVICE_API_VERSION HWC_DEVICE_API_VERSION_0_1
#define HWC_API_VERSION HWC_DEVICE_API_VERSION
/*****************************************************************************/
/**
* The id of this module
*/
#define HWC_HARDWARE_MODULE_ID "hwcomposer"
/**
* Name of the sensors device to open
*/
#define HWC_HARDWARE_COMPOSER "composer"
typedef struct hwc_rect {
int left;
int top;
int right;
int bottom;
} hwc_rect_t;
typedef struct hwc_frect {
float left;
float top;
float right;
float bottom;
} hwc_frect_t;
typedef struct hwc_region {
size_t numRects;
hwc_rect_t const* rects;
} hwc_region_t;
typedef struct hwc_color {
uint8_t r;
uint8_t g;
uint8_t b;
uint8_t a;
} hwc_color_t;
typedef struct hwc_layer_1 {
/*
* compositionType is used to specify this layer's type and is set by either
* the hardware composer implementation, or by the caller (see below).
*
* This field is always reset to HWC_BACKGROUND or HWC_FRAMEBUFFER
* before (*prepare)() is called when the HWC_GEOMETRY_CHANGED flag is
* also set, otherwise, this field is preserved between (*prepare)()
* calls.
*
* HWC_BACKGROUND
* Always set by the caller before calling (*prepare)(), this value
* indicates this is a special "background" layer. The only valid field
* is backgroundColor.
* The HWC can toggle this value to HWC_FRAMEBUFFER to indicate it CANNOT
* handle the background color.
*
*
* HWC_FRAMEBUFFER_TARGET
* Always set by the caller before calling (*prepare)(), this value
* indicates this layer is the framebuffer surface used as the target of
* OpenGL ES composition. If the HWC sets all other layers to HWC_OVERLAY
* or HWC_BACKGROUND, then no OpenGL ES composition will be done, and
* this layer should be ignored during set().
*
* This flag (and the framebuffer surface layer) will only be used if the
* HWC version is HWC_DEVICE_API_VERSION_1_1 or higher. In older versions,
* the OpenGL ES target surface is communicated by the (dpy, sur) fields
* in hwc_compositor_device_1_t.
*
* This value cannot be set by the HWC implementation.
*
*
* HWC_FRAMEBUFFER
* Set by the caller before calling (*prepare)() ONLY when the
* HWC_GEOMETRY_CHANGED flag is also set.
*
* Set by the HWC implementation during (*prepare)(), this indicates
* that the layer will be drawn into the framebuffer using OpenGL ES.
* The HWC can toggle this value to HWC_OVERLAY to indicate it will
* handle the layer.
*
*
* HWC_OVERLAY
* Set by the HWC implementation during (*prepare)(), this indicates
* that the layer will be handled by the HWC (ie: it must not be
* composited with OpenGL ES).
*
*/
int32_t compositionType;
/*
* hints is bit mask set by the HWC implementation during (*prepare)().
* It is preserved between (*prepare)() calls, unless the
* HWC_GEOMETRY_CHANGED flag is set, in which case it is reset to 0.
*
* see hwc_layer_t::hints
*/
uint32_t hints;
/* see hwc_layer_t::flags */
uint32_t flags;
union {
/* color of the background. hwc_color_t.a is ignored */
hwc_color_t backgroundColor;
struct {
/* handle of buffer to compose. This handle is guaranteed to have been
* allocated from gralloc using the GRALLOC_USAGE_HW_COMPOSER usage flag. If
* the layer's handle is unchanged across two consecutive prepare calls and
* the HWC_GEOMETRY_CHANGED flag is not set for the second call then the
* HWComposer implementation may assume that the contents of the buffer have
* not changed. */
buffer_handle_t handle;
/* transformation to apply to the buffer during composition */
uint32_t transform;
/* blending to apply during composition */
int32_t blending;
/* area of the source to consider, the origin is the top-left corner of
* the buffer. As of HWC_DEVICE_API_VERSION_1_3, sourceRect uses floats.
* If the h/w can't support a non-integer source crop rectangle, it should
* punt to OpenGL ES composition.
*/
union {
// crop rectangle in integer (pre HWC_DEVICE_API_VERSION_1_3)
hwc_rect_t sourceCropi;
hwc_rect_t sourceCrop; // just for source compatibility
// crop rectangle in floats (as of HWC_DEVICE_API_VERSION_1_3)
hwc_frect_t sourceCropf;
};
/* where to composite the sourceCrop onto the display. The sourceCrop
* is scaled using linear filtering to the displayFrame. The origin is the
* top-left corner of the screen.
*/
hwc_rect_t displayFrame;
/* visible region in screen space. The origin is the
* top-left corner of the screen.
* The visible region INCLUDES areas overlapped by a translucent layer.
*/
hwc_region_t visibleRegionScreen;
/* Sync fence object that will be signaled when the buffer's
* contents are available. May be -1 if the contents are already
* available. This field is only valid during set(), and should be
* ignored during prepare(). The set() call must not wait for the
* fence to be signaled before returning, but the HWC must wait for
* all buffers to be signaled before reading from them.
*
* HWC_FRAMEBUFFER layers will never have an acquire fence, since
* reads from them are complete before the framebuffer is ready for
* display.
*
* The HWC takes ownership of the acquireFenceFd and is responsible
* for closing it when no longer needed.
*/
int acquireFenceFd;
/* During set() the HWC must set this field to a file descriptor for
* a sync fence object that will signal after the HWC has finished
* reading from the buffer. The field is ignored by prepare(). Each
* layer should have a unique file descriptor, even if more than one
* refer to the same underlying fence object; this allows each to be
* closed independently.
*
* If buffer reads can complete at significantly different times,
* then using independent fences is preferred. For example, if the
* HWC handles some layers with a blit engine and others with
* overlays, then the blit layers can be reused immediately after
* the blit completes, but the overlay layers can't be reused until
* a subsequent frame has been displayed.
*
* Since HWC doesn't read from HWC_FRAMEBUFFER layers, it shouldn't
* produce a release fence for them. The releaseFenceFd will be -1
* for these layers when set() is called.
*
* The HWC client taks ownership of the releaseFenceFd and is
* responsible for closing it when no longer needed.
*/
int releaseFenceFd;
/*
* Availability: HWC_DEVICE_API_VERSION_1_2
*
* Alpha value applied to the whole layer. The effective
* value of each pixel is computed as:
*
* if (blending == HWC_BLENDING_PREMULT)
* pixel.rgb = pixel.rgb * planeAlpha / 255
* pixel.a = pixel.a * planeAlpha / 255
*
* Then blending proceeds as usual according to the "blending"
* field above.
*
* NOTE: planeAlpha applies to YUV layers as well:
*
* pixel.rgb = yuv_to_rgb(pixel.yuv)
* if (blending == HWC_BLENDING_PREMULT)
* pixel.rgb = pixel.rgb * planeAlpha / 255
* pixel.a = planeAlpha
*
*
* IMPLEMENTATION NOTE:
*
* If the source image doesn't have an alpha channel, then
* the h/w can use the HWC_BLENDING_COVERAGE equations instead of
* HWC_BLENDING_PREMULT and simply set the alpha channel to
* planeAlpha.
*
* e.g.:
*
* if (blending == HWC_BLENDING_PREMULT)
* blending = HWC_BLENDING_COVERAGE;
* pixel.a = planeAlpha;
*
*/
uint8_t planeAlpha;
/* reserved for future use */
uint8_t _pad[3];
};
};
/* Allow for expansion w/o breaking binary compatibility.
* Pad layer to 96 bytes.
*/
int32_t reserved[24 - 19];
} hwc_layer_1_t;
/* This represents a display, typically an EGLDisplay object */
typedef void* hwc_display_t;
/* This represents a surface, typically an EGLSurface object */
typedef void* hwc_surface_t;
/*
* hwc_display_contents_1_t::flags values
*/
enum {
/*
* HWC_GEOMETRY_CHANGED is set by SurfaceFlinger to indicate that the list
* passed to (*prepare)() has changed by more than just the buffer handles
* and acquire fences.
*/
HWC_GEOMETRY_CHANGED = 0x00000001,
};
/*
* Description of the contents to output on a display.
*
* This is the top-level structure passed to the prepare and set calls to
* negotiate and commit the composition of a display image.
*/
typedef struct hwc_display_contents_1 {
/* File descriptor referring to a Sync HAL fence object which will signal
* when this composition is retired. For a physical display, a composition
* is retired when it has been replaced on-screen by a subsequent set. For
* a virtual display, the composition is retired when the writes to
* outputBuffer are complete and can be read. The fence object is created
* and returned by the set call; this field will be -1 on entry to prepare
* and set. SurfaceFlinger will close the returned file descriptor.
*/
int retireFenceFd;
union {
/* Fields only relevant for HWC_DEVICE_VERSION_1_0. */
struct {
/* (dpy, sur) is the target of SurfaceFlinger's OpenGL ES
* composition for HWC_DEVICE_VERSION_1_0. They aren't relevant to
* prepare. The set call should commit this surface atomically to
* the display along with any overlay layers.
*/
hwc_display_t dpy;
hwc_surface_t sur;
};
/* These fields are used for virtual displays when the h/w composer
* version is at least HWC_DEVICE_VERSION_1_3. */
struct {
/* outbuf is the buffer that receives the composed image for
* virtual displays. Writes to the outbuf must wait until
* outbufAcquireFenceFd signals. A fence that will signal when
* writes to outbuf are complete should be returned in
* retireFenceFd.
*
* This field is set before prepare(), so properties of the buffer
* can be used to decide which layers can be handled by h/w
* composer.
*
* If prepare() sets all layers to FRAMEBUFFER, then GLES
* composition will happen directly to the output buffer. In this
* case, both outbuf and the FRAMEBUFFER_TARGET layer's buffer will
* be the same, and set() has no work to do besides managing fences.
*
* If the TARGET_FORCE_HWC_FOR_VIRTUAL_DISPLAYS board config
* variable is defined (not the default), then this behavior is
* changed: if all layers are marked for FRAMEBUFFER, GLES
* composition will take place to a scratch framebuffer, and
* h/w composer must copy it to the output buffer. This allows the
* h/w composer to do format conversion if there are cases where
* that is more desirable than doing it in the GLES driver or at the
* virtual display consumer.
*
* If some or all layers are marked OVERLAY, then the framebuffer
* and output buffer will be different. As with physical displays,
* the framebuffer handle will not change between frames if all
* layers are marked for OVERLAY.
*/
buffer_handle_t outbuf;
/* File descriptor for a fence that will signal when outbuf is
* ready to be written. The h/w composer is responsible for closing
* this when no longer needed.
*
* Will be -1 whenever outbuf is NULL, or when the outbuf can be
* written immediately.
*/
int outbufAcquireFenceFd;
};
};
/* List of layers that will be composed on the display. The buffer handles
* in the list will be unique. If numHwLayers is 0, all composition will be
* performed by SurfaceFlinger.
*/
uint32_t flags;
size_t numHwLayers;
hwc_layer_1_t hwLayers[0];
} hwc_display_contents_1_t;
/* see hwc_composer_device::registerProcs()
* All of the callbacks are required and non-NULL unless otherwise noted.
*/
typedef struct hwc_procs {
/*
* (*invalidate)() triggers a screen refresh, in particular prepare and set
* will be called shortly after this call is made. Note that there is
* NO GUARANTEE that the screen refresh will happen after invalidate()
* returns (in particular, it could happen before).
* invalidate() is GUARANTEED TO NOT CALL BACK into the h/w composer HAL and
* it is safe to call invalidate() from any of hwc_composer_device
* hooks, unless noted otherwise.
*/
void (*invalidate)(const struct hwc_procs* procs);
/*
* (*vsync)() is called by the h/w composer HAL when a vsync event is
* received and HWC_EVENT_VSYNC is enabled on a display
* (see: hwc_event_control).
*
* the "disp" parameter indicates which display the vsync event is for.
* the "timestamp" parameter is the system monotonic clock timestamp in
* nanosecond of when the vsync event happened.
*
* vsync() is GUARANTEED TO NOT CALL BACK into the h/w composer HAL.
*
* It is expected that vsync() is called from a thread of at least
* HAL_PRIORITY_URGENT_DISPLAY with as little latency as possible,
* typically less than 0.5 ms.
*
* It is a (silent) error to have HWC_EVENT_VSYNC enabled when calling
* hwc_composer_device.set(..., 0, 0, 0) (screen off). The implementation
* can either stop or continue to process VSYNC events, but must not
* crash or cause other problems.
*/
void (*vsync)(const struct hwc_procs* procs, int disp, int64_t timestamp);
/*
* (*hotplug)() is called by the h/w composer HAL when a display is
* connected or disconnected. The PRIMARY display is always connected and
* the hotplug callback should not be called for it.
*
* The disp parameter indicates which display type this event is for.
* The connected parameter indicates whether the display has just been
* connected (1) or disconnected (0).
*
* The hotplug() callback may call back into the h/w composer on the same
* thread to query refresh rate and dpi for the display. Additionally,
* other threads may be calling into the h/w composer while the callback
* is in progress.
*
* The h/w composer must serialize calls to the hotplug callback; only
* one thread may call it at a time.
*
* This callback will be NULL if the h/w composer is using
* HWC_DEVICE_API_VERSION_1_0.
*/
void (*hotplug)(const struct hwc_procs* procs, int disp, int connected);
} hwc_procs_t;
/*****************************************************************************/
typedef struct hwc_module {
struct hw_module_t common;
} hwc_module_t;
typedef struct hwc_composer_device_1 {
struct hw_device_t common;
/*
* (*prepare)() is called for each frame before composition and is used by
* SurfaceFlinger to determine what composition steps the HWC can handle.
*
* (*prepare)() can be called more than once, the last call prevails.
*
* The HWC responds by setting the compositionType field in each layer to
* either HWC_FRAMEBUFFER or HWC_OVERLAY. In the former case, the
* composition for the layer is handled by SurfaceFlinger with OpenGL ES,
* in the later case, the HWC will have to handle the layer's composition.
* compositionType and hints are preserved between (*prepare)() calles
* unless the HWC_GEOMETRY_CHANGED flag is set.
*
* (*prepare)() is called with HWC_GEOMETRY_CHANGED to indicate that the
* list's geometry has changed, that is, when more than just the buffer's
* handles have been updated. Typically this happens (but is not limited to)
* when a window is added, removed, resized or moved. In this case
* compositionType and hints are reset to their default value.
*
* For HWC 1.0, numDisplays will always be one, and displays[0] will be
* non-NULL.
*
* For HWC 1.1, numDisplays will always be HWC_NUM_PHYSICAL_DISPLAY_TYPES.
* Entries for unsupported or disabled/disconnected display types will be
* NULL.
*
* In HWC 1.3, numDisplays may be up to HWC_NUM_DISPLAY_TYPES. The extra
* entries correspond to enabled virtual displays, and will be non-NULL.
*
* returns: 0 on success. An negative error code on error. If an error is
* returned, SurfaceFlinger will assume that none of the layer will be
* handled by the HWC.
*/
int (*prepare)(struct hwc_composer_device_1 *dev,
size_t numDisplays, hwc_display_contents_1_t** displays);
/*
* (*set)() is used in place of eglSwapBuffers(), and assumes the same
* functionality, except it also commits the work list atomically with
* the actual eglSwapBuffers().
*
* The layer lists are guaranteed to be the same as the ones returned from
* the last call to (*prepare)().
*
* When this call returns the caller assumes that the displays will be
* updated in the near future with the content of their work lists, without
* artifacts during the transition from the previous frame.
*
* A display with zero layers indicates that the entire composition has
* been handled by SurfaceFlinger with OpenGL ES. In this case, (*set)()
* behaves just like eglSwapBuffers().
*
* For HWC 1.0, numDisplays will always be one, and displays[0] will be
* non-NULL.
*
* For HWC 1.1, numDisplays will always be HWC_NUM_PHYSICAL_DISPLAY_TYPES.
* Entries for unsupported or disabled/disconnected display types will be
* NULL.
*
* In HWC 1.3, numDisplays may be up to HWC_NUM_DISPLAY_TYPES. The extra
* entries correspond to enabled virtual displays, and will be non-NULL.
*
* IMPORTANT NOTE: There is an implicit layer containing opaque black
* pixels behind all the layers in the list. It is the responsibility of
* the hwcomposer module to make sure black pixels are output (or blended
* from).
*
* IMPORTANT NOTE: In the event of an error this call *MUST* still cause
* any fences returned in the previous call to set to eventually become
* signaled. The caller may have already issued wait commands on these
* fences, and having set return without causing those fences to signal
* will likely result in a deadlock.
*
* returns: 0 on success. A negative error code on error:
* HWC_EGL_ERROR: eglGetError() will provide the proper error code (only
* allowed prior to HWComposer 1.1)
* Another code for non EGL errors.
*/
int (*set)(struct hwc_composer_device_1 *dev,
size_t numDisplays, hwc_display_contents_1_t** displays);
/*
* eventControl(..., event, enabled)
* Enables or disables h/w composer events for a display.
*
* eventControl can be called from any thread and takes effect
* immediately.
*
* Supported events are:
* HWC_EVENT_VSYNC
*
* returns -EINVAL if the "event" parameter is not one of the value above
* or if the "enabled" parameter is not 0 or 1.
*/
int (*eventControl)(struct hwc_composer_device_1* dev, int disp,
int event, int enabled);
/*
* blank(..., blank)
* Blanks or unblanks a display's screen.
*
* Turns the screen off when blank is nonzero, on when blank is zero.
* Multiple sequential calls with the same blank value must be supported.
* The screen state transition must be be complete when the function
* returns.
*
* returns 0 on success, negative on error.
*/
int (*blank)(struct hwc_composer_device_1* dev, int disp, int blank);
/*
* Used to retrieve information about the h/w composer
*
* Returns 0 on success or -errno on error.
*/
int (*query)(struct hwc_composer_device_1* dev, int what, int* value);
/*
* (*registerProcs)() registers callbacks that the h/w composer HAL can
* later use. It will be called immediately after the composer device is
* opened with non-NULL procs. It is FORBIDDEN to call any of the callbacks
* from within registerProcs(). registerProcs() must save the hwc_procs_t
* pointer which is needed when calling a registered callback.
*/
void (*registerProcs)(struct hwc_composer_device_1* dev,
hwc_procs_t const* procs);
/*
* This field is OPTIONAL and can be NULL.
*
* If non NULL it will be called by SurfaceFlinger on dumpsys
*/
void (*dump)(struct hwc_composer_device_1* dev, char *buff, int buff_len);
/*
* (*getDisplayConfigs)() returns handles for the configurations available
* on the connected display. These handles must remain valid as long as the
* display is connected.
*
* Configuration handles are written to configs. The number of entries
* allocated by the caller is passed in *numConfigs; getDisplayConfigs must
* not try to write more than this number of config handles. On return, the
* total number of configurations available for the display is returned in
* *numConfigs. If *numConfigs is zero on entry, then configs may be NULL.
*
* HWC_DEVICE_API_VERSION_1_1 does not provide a way to choose a config.
* For displays that support multiple configurations, the h/w composer
* implementation should choose one and report it as the first config in
* the list. Reporting the not-chosen configs is not required.
*
* Returns 0 on success or -errno on error. If disp is a hotpluggable
* display type and no display is connected, an error should be returned.
*
* This field is REQUIRED for HWC_DEVICE_API_VERSION_1_1 and later.
* It should be NULL for previous versions.
*/
int (*getDisplayConfigs)(struct hwc_composer_device_1* dev, int disp,
uint32_t* configs, size_t* numConfigs);
/*
* (*getDisplayAttributes)() returns attributes for a specific config of a
* connected display. The config parameter is one of the config handles
* returned by getDisplayConfigs.
*
* The list of attributes to return is provided in the attributes
* parameter, terminated by HWC_DISPLAY_NO_ATTRIBUTE. The value for each
* requested attribute is written in order to the values array. The
* HWC_DISPLAY_NO_ATTRIBUTE attribute does not have a value, so the values
* array will have one less value than the attributes array.
*
* This field is REQUIRED for HWC_DEVICE_API_VERSION_1_1 and later.
* It should be NULL for previous versions.
*
* If disp is a hotpluggable display type and no display is connected,
* or if config is not a valid configuration for the display, a negative
* value should be returned.
*/
int (*getDisplayAttributes)(struct hwc_composer_device_1* dev, int disp,
uint32_t config, const uint32_t* attributes, int32_t* values);
/*
* Reserved for future use. Must be NULL.
*/
void* reserved_proc[4];
} hwc_composer_device_1_t;
/** convenience API for opening and closing a device */
static inline int hwc_open_1(const struct hw_module_t* module,
hwc_composer_device_1_t** device) {
return module->methods->open(module,
HWC_HARDWARE_COMPOSER, (struct hw_device_t**)device);
}
static inline int hwc_close_1(hwc_composer_device_1_t* device) {
return device->common.close(&device->common);
}
/*****************************************************************************/
__END_DECLS
#endif /* ANDROID_INCLUDE_HARDWARE_HWCOMPOSER_H */