android_hardware_qcom_display/liboverlay/overlayLib.cpp
Naseer Ahmed 3d3e9400aa overlay: Continue when one of the framebuffer fd's fail to open
Change-Id: I4b1f071ebcf04a189bab612dd0d3def1a660105c
2012-05-22 17:03:46 -05:00

2264 lines
71 KiB
C++
Executable File

/*
* Copyright (C) 2008 The Android Open Source Project
* Copyright (c) 2010-2012, Code Aurora Forum. All rights reserved.
*
* 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.
*/
#include "overlayLib.h"
#include "gralloc_priv.h"
#define INTERLACE_MASK 0x80
#define DEBUG_OVERLAY true
/* Helper functions */
static inline size_t ALIGN(size_t x, size_t align) {
return (x + align-1) & ~(align-1);
}
using namespace overlay;
using android::sp;
using gralloc::IMemAlloc;
using gralloc::IonController;
using gralloc::alloc_data;
#ifdef HDMI_AS_PRIMARY
bool Overlay::sHDMIAsPrimary = true;
#else
bool Overlay::sHDMIAsPrimary = false;
#endif
template <class Type>
void swapWidthHeight(Type& width, Type& height) {
Type tmp = width;
width = height;
height = tmp;
}
int overlay::get_mdp_format(int format) {
switch (format) {
case HAL_PIXEL_FORMAT_RGBA_8888 :
return MDP_RGBA_8888;
case HAL_PIXEL_FORMAT_BGRA_8888:
return MDP_BGRA_8888;
case HAL_PIXEL_FORMAT_RGB_565:
return MDP_RGB_565;
case HAL_PIXEL_FORMAT_RGBX_8888:
return MDP_RGBX_8888;
case HAL_PIXEL_FORMAT_YCbCr_422_SP:
return MDP_Y_CBCR_H2V1;
case HAL_PIXEL_FORMAT_YCbCr_420_SP:
return MDP_Y_CBCR_H2V2;
case HAL_PIXEL_FORMAT_YCrCb_420_SP:
return MDP_Y_CRCB_H2V2;
case HAL_PIXEL_FORMAT_YCbCr_420_SP_TILED:
return MDP_Y_CBCR_H2V2_TILE;
case HAL_PIXEL_FORMAT_YV12:
return MDP_Y_CR_CB_GH2V2;
default:
LOGE("%s: unknown color format [0x%x]", __FUNCTION__, format);
return -1;
}
return -1;
}
int overlay::get_mdp_orientation(int value) {
switch(value) {
case 0: return 0;
case HAL_TRANSFORM_FLIP_V: return MDP_FLIP_UD;
case HAL_TRANSFORM_FLIP_H: return MDP_FLIP_LR;
case HAL_TRANSFORM_ROT_90: return MDP_ROT_90;
case HAL_TRANSFORM_ROT_90|HAL_TRANSFORM_FLIP_V:
return MDP_ROT_90|MDP_FLIP_LR;
case HAL_TRANSFORM_ROT_90|HAL_TRANSFORM_FLIP_H:
return MDP_ROT_90|MDP_FLIP_UD;
case HAL_TRANSFORM_ROT_180: return MDP_ROT_180;
case HAL_TRANSFORM_ROT_270: return MDP_ROT_270;
default:
LOGE("%s: invalid rotation value (value = 0x%x",
__FUNCTION__, value);
return -1;
}
return -1;
}
// This function normalizes the crop values to be all even
void overlay::normalize_crop(uint32_t& xy, uint32_t& wh) {
if (xy & 0x0001) {
// x or y is odd, increment it's value
xy += 1;
// Since we've incremented x(y), we need to decrement
// w(h) accordingly
if (wh & 0x0001) {
// w or h is odd, decrement it by 1, to make it even
EVEN_OUT(wh);
} else {
// w(h) is already even, hence we decrement by 2
wh -=2;
}
} else {
EVEN_OUT(wh);
}
}
#define LOG_TAG "OverlayLIB"
static void reportError(const char* message) {
LOGE( "%s", message);
}
void overlay::dump(mdp_overlay& mOVInfo) {
if (!DEBUG_OVERLAY)
return;
LOGE("mOVInfo:");
LOGE("src: width %d height %d format %s user_data[0] %d", mOVInfo.src.width,
mOVInfo.src.height, getFormatString(mOVInfo.src.format),
mOVInfo.user_data[0]);
LOGE("src_rect: x %d y %d w %d h %d", mOVInfo.src_rect.x,
mOVInfo.src_rect.y, mOVInfo.src_rect.w, mOVInfo.src_rect.h);
LOGE("dst_rect: x %d y %d w %d h %d", mOVInfo.dst_rect.x,
mOVInfo.dst_rect.y, mOVInfo.dst_rect.w, mOVInfo.dst_rect.h);
LOGE("z_order %d is_fg %d alpha %d transp_mask %d flags %x id %d",
mOVInfo.z_order, mOVInfo.is_fg, mOVInfo.alpha, mOVInfo.transp_mask,
mOVInfo.flags, mOVInfo.id);
}
void overlay::dump(msm_rotator_img_info& mRotInfo) {
if (!DEBUG_OVERLAY)
return;
LOGE("mRotInfo:");
LOGE("session_id %d dst_x %d dst_y %d rotations %d enable %d",
mRotInfo.session_id, mRotInfo.dst_x, mRotInfo.dst_y,
mRotInfo.rotations, mRotInfo.enable);
LOGE("src: width %d height %d format %s", mRotInfo.src.width,
mRotInfo.src.height, getFormatString(mRotInfo.src.format));
LOGE("dst: width %d height %d format %s", mRotInfo.dst.width,
mRotInfo.dst.height, getFormatString(mRotInfo.src.format));
LOGE("src_rect: x %d y %d w %d h %d", mRotInfo.src_rect.x,
mRotInfo.src_rect.y, mRotInfo.src_rect.w, mRotInfo.src_rect.h);
}
const char* overlay::getFormatString(int format){
static const char* formats[] = {
"MDP_RGB_565",
"MDP_XRGB_8888",
"MDP_Y_CBCR_H2V2",
"MDP_ARGB_8888",
"MDP_RGB_888",
"MDP_Y_CRCB_H2V2",
"MDP_YCRYCB_H2V1",
"MDP_Y_CRCB_H2V1",
"MDP_Y_CBCR_H2V1",
"MDP_RGBA_8888",
"MDP_BGRA_8888",
"MDP_RGBX_8888",
"MDP_Y_CRCB_H2V2_TILE",
"MDP_Y_CBCR_H2V2_TILE",
"MDP_Y_CR_CB_H2V2",
"MDP_Y_CR_CB_GH2V2",
"MDP_Y_CB_CR_H2V2",
"MDP_Y_CRCB_H1V1",
"MDP_Y_CBCR_H1V1",
"MDP_IMGTYPE_LIMIT",
"MDP_BGR_565",
"MDP_FB_FORMAT",
"MDP_IMGTYPE_LIMIT2"
};
return formats[format];
}
ZOrderManager* ZOrderManager::sInstance = 0;
FrameBufferInfo* FrameBufferInfo::sFBInfoInstance = 0;
int ZOrderManager::getZ(int fbnum){
int zorder = NO_PIPE;;
Mutex::Autolock objLock(mObjMutex);
if(mPipesInuse == mMaxPipes) {
LOGE("No free pipes available.. inUse = %d ", mPipesInuse);
return NO_PIPE;
}
switch(fbnum) {
case FRAMEBUFFER_0:
for (int i = 0;i < NUM_CHANNELS; i++) {
if(mFB0Pipes[i] == false) {
mFB0Pipes[i]= true;
zorder = i;
break;
}
}
break;
case FRAMEBUFFER_1:
case FRAMEBUFFER_2:
for (int i = 0;i < mMaxPipes; i++) {
if(mFB1Pipes[i] == false) {
mFB1Pipes[i]= true;
zorder = i;
break;
}
}
break;
default:
LOGE("getZ: Invalid framebuffer..");
break;
}
mPipesInuse++;
LOGE("getZ: return zorder = %d for fbdev = %d, pipesinUse = %d",
zorder, fbnum, mPipesInuse);
return zorder;
}
void ZOrderManager::decZ(int fbnum, int zorder){
Mutex::Autolock objLock(mObjMutex);
switch(fbnum) {
case FRAMEBUFFER_0:
LOG_ASSERT(!mFB0Pipes[zorder],"channel with ZOrder does not exist");
LOGE("decZ: freeing the pipe with zorder = %d for fbdev = %d", zorder, fbnum);
mFB0Pipes[zorder] = false;
break;
case FRAMEBUFFER_1:
case FRAMEBUFFER_2:
LOG_ASSERT(!mFB1Pipes[zorder],"channel with ZOrder does not exist");
LOGE("decZ: freeing the pipe with zorder = %d for fbdev = %d", zorder, fbnum);
mFB1Pipes[zorder] = false;
break;
default:
LOGE("decZ: Invalid framebuffer ");
break;
}
if(mPipesInuse > 0)
mPipesInuse--;
LOGE("decZ: Pipes in use = %d", mPipesInuse);
}
bool overlay::isHDMIConnected () {
char value[PROPERTY_VALUE_MAX];
property_get("hw.hdmiON", value, "0");
int isHDMI = atoi(value);
return isHDMI ? true : false;
}
bool overlay::is3DTV() {
char is3DTV = '0';
FILE *fp = fopen(EDID_3D_INFO_FILE, "r");
if (fp) {
fread(&is3DTV, 1, 1, fp);
fclose(fp);
}
LOGI("3DTV EDID flag: %c", is3DTV);
return (is3DTV == '0') ? false : true;
}
bool overlay::isPanel3D() {
int fd = open("/dev/graphics/fb0", O_RDWR, 0);
if (fd < 0) {
reportError("Can't open framebuffer 0");
return false;
}
fb_fix_screeninfo finfo;
if (ioctl(fd, FBIOGET_FSCREENINFO, &finfo) == -1) {
reportError("FBIOGET_FSCREENINFO on fb0 failed");
close(fd);
fd = -1;
return false;
}
close(fd);
return (FB_TYPE_3D_PANEL == finfo.type) ? true : false;
}
bool overlay::usePanel3D() {
if (Overlay::sHDMIAsPrimary)
return is3DTV();
if(!isPanel3D())
return false;
char value[PROPERTY_VALUE_MAX];
property_get("persist.user.panel3D", value, "0");
int usePanel3D = atoi(value);
return usePanel3D ? true : false;
}
bool overlay::send3DInfoPacket (unsigned int format3D) {
FILE *fp = fopen(FORMAT_3D_FILE, "wb");
if (fp) {
fprintf(fp, "%d", format3D);
fclose(fp);
fp = NULL;
return true;
}
LOGE("%s:no sysfs entry for setting 3d mode!", __FUNCTION__);
return false;
}
bool overlay::enableBarrier (unsigned int orientation) {
FILE *fp = fopen(BARRIER_FILE, "wb");
if (fp) {
fprintf(fp, "%d", orientation);
fclose(fp);
fp = NULL;
return true;
}
LOGE("%s:no sysfs entry for enabling barriers on 3D panel!", __FUNCTION__);
return false;
}
int overlay::getColorFormat(int format)
{
if (format == HAL_PIXEL_FORMAT_YV12)
return format;
else if (format & INTERLACE_MASK)
return format ^ HAL_PIXEL_FORMAT_INTERLACE;
else
return COLOR_FORMAT(format);
}
bool overlay::isInterlacedContent(int format)
{
if ((format != HAL_PIXEL_FORMAT_YV12) &&
(format & INTERLACE_MASK))
return true;
return false;
}
unsigned int overlay::getOverlayConfig (unsigned int format3D, bool poll,
bool isHDMI) {
bool isTV3D = false;
unsigned int curState = 0;
if (poll)
isHDMI = isHDMIConnected();
if (isHDMI) {
LOGD("%s: HDMI connected... checking the TV type", __FUNCTION__);
if (format3D) {
if (is3DTV())
curState = OV_3D_VIDEO_3D_TV;
else
curState = OV_3D_VIDEO_2D_TV;
} else
curState = OV_2D_VIDEO_ON_TV;
} else {
LOGD("%s: HDMI not connected...", __FUNCTION__);
if(format3D) {
if (usePanel3D())
curState = OV_3D_VIDEO_3D_PANEL;
else
curState = OV_3D_VIDEO_2D_PANEL;
}
else
curState = OV_2D_VIDEO_ON_PANEL;
}
return curState;
}
/* clears any VG pipes allocated to the fb devices */
int overlay::initOverlay() {
msmfb_mixer_info_req req;
mdp_mixer_info *minfo = NULL;
char name[64];
int fd = -1;
for(int i = 0; i < NUM_FB_DEVICES; i++) {
snprintf(name, 64, FB_DEVICE_TEMPLATE, i);
LOGD("initoverlay:: opening the device:: %s", name);
fd = open(name, O_RDWR, 0);
if(fd < 0) {
LOGW("cannot open framebuffer(%d)", i);
continue;
}
//Get the mixer configuration */
req.mixer_num = i;
if (ioctl(fd, MSMFB_MIXER_INFO, &req) == -1) {
LOGE("ERROR: MSMFB_MIXER_INFO ioctl failed");
close(fd);
return -1;
}
minfo = req.info;
for (int j = 0; j < req.cnt; j++) {
LOGD("ndx=%d num=%d z_order=%d", minfo->pndx, minfo->pnum,
minfo->z_order);
// except the RGB base layer with z_order of -1, clear any
// other pipes connected to mixer.
if((minfo->z_order) != -1) {
int index = minfo->pndx;
LOGD("Unset overlay with index: %d at mixer %d", index, i);
if(ioctl(fd, MSMFB_OVERLAY_UNSET, &index) == -1) {
LOGE("ERROR: MSMFB_OVERLAY_UNSET failed");
close(fd);
return -1;
}
}
minfo++;
}
close(fd);
fd = -1;
}
return 0;
}
Overlay::Overlay() : mChannelUP(false), mExternalDisplay(false),
mS3DFormat(0), mCroppedSrcWidth(0),
mCroppedSrcHeight(0), mState(-1) {
mOVBufferInfo.width = mOVBufferInfo.height = 0;
mOVBufferInfo.format = mOVBufferInfo.size = 0;
mOVBufferInfo.secure = false;
}
Overlay::~Overlay() {
closeChannel();
}
int Overlay::getFBWidth(int channel) const {
return objOvCtrlChannel[channel].getFBWidth();
}
int Overlay::getFBHeight(int channel) const {
return objOvCtrlChannel[channel].getFBHeight();
}
bool Overlay::startChannel(const overlay_buffer_info& info, int fbnum,
bool norot, bool uichannel,
unsigned int format3D, int channel,
int flags, int num_buffers) {
int zorder = 0;
int format = getColorFormat(info.format);
mCroppedSrcWidth = info.width;
mCroppedSrcHeight = info.height;
if (format3D)
zorder = channel;
if (mState == -1)
mState = OV_UI_MIRROR_TV;
mChannelUP = objOvCtrlChannel[channel].startControlChannel(info.width,
info.height, format, fbnum,
norot, uichannel,
format3D, zorder, flags);
if (!mChannelUP) {
LOGE("startChannel for fb%d failed", fbnum);
return mChannelUP;
}
objOvCtrlChannel[channel].setSize(info.size);
return objOvDataChannel[channel].startDataChannel(objOvCtrlChannel[channel], fbnum,
norot, info.secure, uichannel, num_buffers);
}
bool Overlay::closeChannel() {
if (!mChannelUP)
return true;
if(mS3DFormat) {
if (mExternalDisplay)
overlay::send3DInfoPacket(0);
else if (mState == OV_3D_VIDEO_3D_PANEL) {
if (sHDMIAsPrimary)
overlay::send3DInfoPacket(0);
else
enableBarrier(0);
}
}
for (int i = 0; i < NUM_CHANNELS; i++) {
objOvCtrlChannel[i].closeControlChannel();
objOvDataChannel[i].closeDataChannel();
}
mChannelUP = false;
mS3DFormat = 0;
mOVBufferInfo.width = 0;
mOVBufferInfo.height = 0;
mOVBufferInfo.format = 0;
mOVBufferInfo.size = 0;
mOVBufferInfo.secure = false;
mState = -1;
return true;
}
void Overlay::closeExternalChannel() {
if (objOvCtrlChannel[VG1_PIPE].isChannelUP()) {
objOvCtrlChannel[VG1_PIPE].closeControlChannel();
objOvDataChannel[VG1_PIPE].closeDataChannel();
}
}
bool Overlay::getPosition(int& x, int& y, uint32_t& w, uint32_t& h, int channel) {
return objOvCtrlChannel[channel].getPosition(x, y, w, h);
}
bool Overlay::getOrientation(int& orientation, int channel) const {
return objOvCtrlChannel[channel].getOrientation(orientation);
}
bool Overlay::setDeviceOrientation(int orientation) {
// Use this to calculate the position on HDMI
mDevOrientation = orientation;
return true;
}
bool Overlay::setPosition(int x, int y, uint32_t w, uint32_t h) {
bool ret = false;
overlay_rect secDest;
overlay_rect priDest;
int currX, currY;
uint32_t currW, currH;
// Set even destination co-ordinates
EVEN_OUT(x); EVEN_OUT(y);
EVEN_OUT(w); EVEN_OUT(h);
objOvCtrlChannel[VG0_PIPE].getPosition(currX, currY, currW, currH);
priDest.x = x, priDest.y = y;
priDest.w = w, priDest.h = h;
if(x != currX || y != currY || w != currW || h != currH) {
switch (mState) {
case OV_UI_MIRROR_TV:
case OV_2D_VIDEO_ON_PANEL:
case OV_3D_VIDEO_2D_PANEL:
return setChannelPosition(x, y, w, h, VG0_PIPE);
break;
case OV_2D_VIDEO_ON_TV:
if (FrameBufferInfo::getInstance()->canSupportTrueMirroring()) {
objOvCtrlChannel[VG1_PIPE].getAspectRatioPosition(
mCroppedSrcWidth, mCroppedSrcHeight, mDevOrientation,
&priDest, &secDest);
} else {
objOvCtrlChannel[VG1_PIPE].getAspectRatioPosition(
mCroppedSrcWidth, mCroppedSrcHeight, &secDest);
}
setChannelPosition(secDest.x, secDest.y, secDest.w, secDest.h,
VG1_PIPE);
return setChannelPosition(x, y, w, h, VG0_PIPE);
break;
case OV_3D_VIDEO_3D_PANEL:
for (int i = 0; i < NUM_CHANNELS; i++) {
if (sHDMIAsPrimary)
objOvCtrlChannel[i].getPositionS3D(i, mS3DFormat, &secDest);
else {
if (!objOvCtrlChannel[i].useVirtualFB()) {
LOGE("%s: failed virtual fb for channel %d", __FUNCTION__, i);
return false;
}
objOvCtrlChannel[i].getPositionS3D(i, 0x1, &secDest);
}
if(!setChannelPosition(secDest.x, secDest.y, secDest.w,
secDest.h, i)) {
LOGE("%s: failed for channel %d", __FUNCTION__, i);
return false;
}
}
break;
case OV_3D_VIDEO_2D_TV:
case OV_3D_VIDEO_3D_TV:
for (int i = 0; i < NUM_CHANNELS; i++) {
ret = objOvCtrlChannel[i].getPositionS3D(i, mS3DFormat,
&secDest);
if (!ret)
ret = setChannelPosition(x, y, w, h, i);
else
ret = setChannelPosition(secDest.x, secDest.y, secDest.w,
secDest.h, i);
if (!ret) {
LOGE("%s: failed for channel %d", __FUNCTION__, i);
return ret;
}
}
break;
default:
LOGE("%s:Unknown state %d", __FUNCTION__, mState);
break;
}
}
return true;
}
bool Overlay::setChannelPosition(int x, int y, uint32_t w, uint32_t h, int channel) {
return objOvCtrlChannel[channel].setPosition(x, y, w, h);
}
bool Overlay::updateOverlaySource(const overlay_buffer_info& info, int orientation,
int flags) {
bool ret = false;
int currentFlags = 0;
bool needUpdateFlags = false;
if (objOvCtrlChannel[0].isChannelUP()) {
needUpdateFlags = objOvCtrlChannel[0].doFlagsNeedUpdate(flags);
}
bool geometryChanged = true;
if (info.width == mOVBufferInfo.width &&
info.height == mOVBufferInfo.height &&
info.format == mOVBufferInfo.format) {
geometryChanged = false;
}
if (sHDMIAsPrimary)
needUpdateFlags = false;
if ((false == needUpdateFlags) && (false == geometryChanged)) {
return true;
}
// Disable rotation for the HDMI channels
int orientHdmi = 0;
int orientPrimary = sHDMIAsPrimary ? 0 : orientation;
int orient[2] = {orientPrimary, orientHdmi};
// disable waitForVsync on HDMI, since we call the wait ioctl
int ovFlagsExternal = 0;
int ovFlagsPrimary = sHDMIAsPrimary ? (flags |= WAIT_FOR_VSYNC): flags;
int ovFlags[2] = {flags, ovFlagsExternal};
switch(mState) {
case OV_3D_VIDEO_3D_PANEL:
orient[1] = sHDMIAsPrimary ? 0 : orientation;
break;
case OV_3D_VIDEO_3D_TV:
orient[0] = 0;
break;
default:
break;
}
int numChannelsToUpdate = NUM_CHANNELS;
if (!geometryChanged) {
// Only update the primary channel - we only need to update the
// wait/no-wait flags
if (objOvCtrlChannel[0].isChannelUP()) {
return objOvCtrlChannel[0].updateOverlayFlags(flags);
}
}
// Set the overlay source info
for (int i = 0; i < NUM_CHANNELS; i++) {
if (objOvCtrlChannel[i].isChannelUP()) {
ret = objOvCtrlChannel[i].updateOverlaySource(info, orient[i], ovFlags[i]);
if (!ret) {
LOGE("objOvCtrlChannel[%d].updateOverlaySource failed", i);
return false;
}
objOvCtrlChannel[i].setSize(info.size);
ret = objOvDataChannel[i].updateDataChannel(info.size);
}
}
if (ret) {
mOVBufferInfo = info;
} else
LOGE("update failed");
return ret;
}
bool Overlay::getAspectRatioPosition(int w, int h, overlay_rect *rect, int channel) {
return objOvCtrlChannel[channel].getAspectRatioPosition(w, h, rect);
}
int Overlay::getS3DFormat(int format) {
// The S3D is part of the HAL_PIXEL_FORMAT_YV12 value. Add
// an explicit check for the format
if (format == HAL_PIXEL_FORMAT_YV12) {
return 0;
}
int format3D = FORMAT_3D(format);
int fIn3D = FORMAT_3D_INPUT(format3D); // MSB 2 bytes are input format
int fOut3D = FORMAT_3D_OUTPUT(format3D); // LSB 2 bytes are output format
format3D = fIn3D | fOut3D;
if (!fIn3D) {
format3D |= fOut3D << SHIFT_3D; //Set the input format
}
if (!fOut3D) {
format3D |= fIn3D >> SHIFT_3D; //Set the output format
}
return format3D;
}
bool Overlay::setSource(const overlay_buffer_info& info, int orientation,
int hdmiConnected, int flags, int num_buffers) {
// Separate the color format from the 3D format.
// If there is 3D content; the effective format passed by the client is:
// effectiveFormat = 3D_IN | 3D_OUT | ColorFormat
int newState = mState;
bool stateChange = false, ret = true;
bool isHDMIStateChange = (mExternalDisplay != hdmiConnected) && (mState != -1);
unsigned int format3D = getS3DFormat(info.format);
int colorFormat = getColorFormat(info.format);
if (isHDMIStateChange || -1 == mState) {
// we were mirroring UI. Also HDMI state stored was stale
newState = getOverlayConfig (format3D, false, hdmiConnected);
stateChange = (mState == newState) ? false : true;
}
if (stateChange) {
mExternalDisplay = hdmiConnected;
mState = newState;
mS3DFormat = format3D;
if (mState == OV_3D_VIDEO_2D_PANEL || mState == OV_3D_VIDEO_2D_TV) {
LOGI("3D content on 2D display: set the output format as monoscopic");
mS3DFormat = FORMAT_3D_INPUT(format3D) | HAL_3D_OUT_MONOSCOPIC_MASK;
}
// We always enable the rotator for the primary.
bool noRot = false;
bool uiChannel = false;
int fbnum = 0;
switch(mState) {
case OV_2D_VIDEO_ON_PANEL:
if(isHDMIStateChange) {
//close HDMI Only
closeExternalChannel();
break;
}
case OV_3D_VIDEO_2D_PANEL:
closeChannel();
return startChannel(info, FRAMEBUFFER_0, noRot, false,
mS3DFormat, VG0_PIPE, flags, num_buffers);
break;
case OV_3D_VIDEO_3D_PANEL:
closeChannel();
if (sHDMIAsPrimary) {
noRot = true;
flags |= WAIT_FOR_VSYNC;
send3DInfoPacket(mS3DFormat & OUTPUT_MASK_3D);
}
for (int i=0; i<NUM_CHANNELS; i++) {
if(!startChannel(info, FRAMEBUFFER_0, noRot, uiChannel,
mS3DFormat, i, flags, num_buffers)) {
LOGE("%s:failed to open channel %d", __FUNCTION__, i);
return false;
}
}
break;
case OV_2D_VIDEO_ON_TV:
if(isHDMIStateChange) {
//start only HDMI channel
noRot = true;
bool waitForVsync = true;
// External display connected, start corresponding channel
// mExternalDisplay will hold the fbnum
if(!startChannel(info, mExternalDisplay, noRot, false, mS3DFormat,
VG1_PIPE, waitForVsync, num_buffers)) {
LOGE("%s:failed to open channel %d", __func__, VG1_PIPE);
return false;
}
int currX, currY;
uint32_t currW, currH;
overlay_rect priDest;
overlay_rect secDest;
objOvCtrlChannel[VG0_PIPE].getPosition(currX, currY, currW, currH);
priDest.x = currX, priDest.y = currY;
priDest.w = currW, priDest.h = currH;
if (FrameBufferInfo::getInstance()->canSupportTrueMirroring()) {
objOvCtrlChannel[VG1_PIPE].getAspectRatioPosition(
mCroppedSrcWidth, mCroppedSrcHeight, mDevOrientation,
&priDest, &secDest);
} else {
objOvCtrlChannel[VG1_PIPE].getAspectRatioPosition(
mCroppedSrcWidth, mCroppedSrcHeight, &secDest);
}
return setChannelPosition(secDest.x, secDest.y, secDest.w, secDest.h, VG1_PIPE);
}
case OV_3D_VIDEO_2D_TV:
closeChannel();
for (int i=0; i<NUM_CHANNELS; i++) {
fbnum = i;
//start two channels for one for primary and external.
if (fbnum) {
// Disable rotation for external
noRot = true;
//set fbnum to hdmiConnected, which holds the ext display
fbnum = hdmiConnected;
flags &= ~WAIT_FOR_VSYNC;
}
if(!startChannel(info, fbnum, noRot, false, mS3DFormat,
i, flags, num_buffers)) {
LOGE("%s:failed to open channel %d", __FUNCTION__, i);
return false;
}
}
return true;
break;
case OV_3D_VIDEO_3D_TV:
closeChannel();
for (int i=0; i<NUM_CHANNELS; i++) {
if(!startChannel(info, FRAMEBUFFER_1, true, false,
mS3DFormat, i, flags, num_buffers)) {
LOGE("%s:failed to open channel %d", __FUNCTION__, i);
return false;
}
send3DInfoPacket(mS3DFormat & OUTPUT_MASK_3D);
}
break;
default:
LOGE("%s:Unknown state %d", __FUNCTION__, mState);
break;
}
} else {
ret = updateOverlaySource(info, orientation, flags);
}
return true;
}
bool Overlay::setCrop(uint32_t x, uint32_t y, uint32_t w, uint32_t h) {
if (!mChannelUP) {
LOGE("%s: channel not set", __FUNCTION__);
return false;
}
overlay_rect rect, inRect;
inRect.x = x; inRect.y = y; inRect.w = w; inRect.h = h;
mCroppedSrcWidth = w;
mCroppedSrcHeight = h;
switch (mState) {
case OV_UI_MIRROR_TV:
case OV_2D_VIDEO_ON_PANEL:
return setChannelCrop(x, y, w, h, VG0_PIPE);
break;
case OV_3D_VIDEO_2D_PANEL:
objOvDataChannel[VG0_PIPE].getCropS3D(&inRect, VG0_PIPE, mS3DFormat, &rect);
return setChannelCrop(rect.x, rect.y, rect.w, rect.h, VG0_PIPE);
break;
case OV_2D_VIDEO_ON_TV:
for (int i=0; i<NUM_CHANNELS; i++) {
if(!setChannelCrop(x, y, w, h, i)) {
LOGE("%s: failed for pipe %d", __FUNCTION__, i);
return false;
}
}
break;
case OV_3D_VIDEO_3D_PANEL:
case OV_3D_VIDEO_2D_TV:
case OV_3D_VIDEO_3D_TV:
for (int i=0; i<NUM_CHANNELS; i++) {
objOvDataChannel[i].getCropS3D(&inRect, i, mS3DFormat, &rect);
if(!setChannelCrop(rect.x, rect.y, rect.w, rect.h, i)) {
LOGE("%s: failed for pipe %d", __FUNCTION__, i);
return false;
}
}
break;
default:
LOGE("%s:Unknown state %d", __FUNCTION__, mState);
break;
}
return true;
}
bool Overlay::setChannelCrop(uint32_t x, uint32_t y, uint32_t w, uint32_t h, int channel) {
return objOvDataChannel[channel].setCrop(x, y, w, h);
}
bool Overlay::updateOverlayFlags(int flags) {
return objOvCtrlChannel[VG0_PIPE].updateOverlayFlags(flags);
}
bool Overlay::setTransform(int value) {
int barrier = 0;
switch (mState) {
case OV_UI_MIRROR_TV:
case OV_2D_VIDEO_ON_PANEL:
case OV_3D_VIDEO_2D_PANEL:
return objOvCtrlChannel[VG0_PIPE].setTransform(value);
break;
case OV_2D_VIDEO_ON_TV:
case OV_3D_VIDEO_2D_TV:
case OV_3D_VIDEO_3D_TV:
for (int i=0; i<NUM_CHANNELS; i++) {
if(!objOvCtrlChannel[i].setTransform(value)) {
LOGE("%s:failed for channel %d", __FUNCTION__, i);
return false;
}
}
break;
case OV_3D_VIDEO_3D_PANEL:
switch (value) {
case HAL_TRANSFORM_ROT_90:
case HAL_TRANSFORM_ROT_270:
barrier = BARRIER_LANDSCAPE;
break;
default:
barrier = BARRIER_PORTRAIT;
break;
if(!enableBarrier(barrier))
LOGE("%s:failed to enable barriers for 3D video", __FUNCTION__);
}
for (int i=0; i<NUM_CHANNELS; i++) {
if(!objOvCtrlChannel[i].setTransform(value)) {
LOGE("%s:failed for channel %d", __FUNCTION__, i);
return false;
}
}
break;
default:
LOGE("%s:Unknown state %d", __FUNCTION__, mState);
break;
}
return true;
}
bool Overlay::setFd(int fd, int channel) {
return objOvDataChannel[channel].setFd(fd);
}
bool Overlay::queueBuffer(uint32_t offset, int channel) {
return objOvDataChannel[channel].queueBuffer(offset);
}
bool Overlay::waitForHdmiVsync(int channel) {
return objOvDataChannel[channel].waitForHdmiVsync();
}
bool Overlay::queueBuffer(buffer_handle_t buffer) {
private_handle_t const* hnd = reinterpret_cast
<private_handle_t const*>(buffer);
if (!hnd) {
LOGE("Overlay::queueBuffer invalid handle");
return false;
}
const size_t offset = hnd->offset;
const int fd = hnd->fd;
switch (mState) {
case OV_UI_MIRROR_TV:
case OV_2D_VIDEO_ON_PANEL:
case OV_3D_VIDEO_2D_PANEL:
if(!queueBuffer(fd, offset, VG0_PIPE)) {
LOGE("%s:failed for channel 0", __FUNCTION__);
return false;
}
break;
case OV_2D_VIDEO_ON_TV:
case OV_3D_VIDEO_3D_PANEL:
case OV_3D_VIDEO_2D_TV:
case OV_3D_VIDEO_3D_TV:
for (int i=NUM_CHANNELS-1; i>=0; i--) {
if(!queueBuffer(fd, offset, i)) {
LOGE("%s:failed for channel %d", __FUNCTION__, i);
return false;
}
}
//Wait for HDMI done..
if(!waitForHdmiVsync(VG1_PIPE)) {
LOGE("%s: waitforHdmiVsync failed", __FUNCTION__);
return false;
}
break;
default:
LOGE("%s:Unknown state %d", __FUNCTION__, mState);
break;
}
return true;
}
bool Overlay::queueBuffer(int fd, uint32_t offset, int channel) {
bool ret = false;
ret = setFd(fd, channel);
if(!ret) {
LOGE("Overlay::queueBuffer channel %d setFd failed", channel);
return false;
}
ret = queueBuffer(offset, channel);
if(!ret) {
LOGE("Overlay::queueBuffer channel %d queueBuffer failed", channel);
return false;
}
return ret;
}
OverlayControlChannel::OverlayControlChannel() : mNoRot(false), mFD(-1), mRotFD(-1),
mFormat3D(0), mIsChannelUpdated(true) {
memset(&mOVInfo, 0, sizeof(mOVInfo));
memset(&m3DOVInfo, 0, sizeof(m3DOVInfo));
memset(&mRotInfo, 0, sizeof(mRotInfo));
}
OverlayControlChannel::~OverlayControlChannel() {
closeControlChannel();
}
bool OverlayControlChannel::getAspectRatioPosition(int w, int h, overlay_rect *rect)
{
int width = w, height = h, x, y;
int fbWidth = getFBWidth();
int fbHeight = getFBHeight();
// width and height for YUV TILE format
int tempWidth = w, tempHeight = h;
/* Calculate the width and height if it is YUV TILE format*/
if(getFormat() == HAL_PIXEL_FORMAT_YCbCr_420_SP_TILED) {
tempWidth = w - ( (((w-1)/64 +1)*64) - w);
tempHeight = h - ((((h-1)/32 +1)*32) - h);
}
if (width * fbHeight > fbWidth * height) {
height = fbWidth * height / width;
EVEN_OUT(height);
width = fbWidth;
} else if (width * fbHeight < fbWidth * height) {
width = fbHeight * width / height;
EVEN_OUT(width);
height = fbHeight;
} else {
width = fbWidth;
height = fbHeight;
}
/* Scaling of upto a max of 8 times supported */
if(width >(tempWidth * HW_OVERLAY_MAGNIFICATION_LIMIT)){
width = HW_OVERLAY_MAGNIFICATION_LIMIT * tempWidth;
}
if(height >(tempHeight*HW_OVERLAY_MAGNIFICATION_LIMIT)) {
height = HW_OVERLAY_MAGNIFICATION_LIMIT * tempHeight;
}
if (width > fbWidth) width = fbWidth;
if (height > fbHeight) height = fbHeight;
char value[PROPERTY_VALUE_MAX];
property_get("hw.actionsafe.width", value, "0");
float asWidth = atof(value);
property_get("hw.actionsafe.height", value, "0");
float asHeight = atof(value);
width = width * (1.0f - asWidth / 100.0f);
height = height * (1.0f - asHeight / 100.0f);
x = (fbWidth - width) / 2;
y = (fbHeight - height) / 2;
rect->x = x;
rect->y = y;
rect->w = width;
rect->h = height;
return true;
}
// This function gets the destination position for Seconday display
// based on the position and aspect ratio of the primary
bool OverlayControlChannel::getAspectRatioPosition(int w, int h, int orientation,
overlay_rect *inRect, overlay_rect *outRect) {
float priWidth = FrameBufferInfo::getInstance()->getWidth();
float priHeight = FrameBufferInfo::getInstance()->getHeight();
float fbWidth = getFBWidth();
float fbHeight = getFBHeight();
float wRatio = 1.0;
float hRatio = 1.0;
float xRatio = 1.0;
float yRatio = 1.0;
int xPos = 0;
int yPos = 0;
int tmp = 0;
overlay_rect rect;
switch(orientation) {
case MDP_ROT_NOP:
case MDP_ROT_180:
getAspectRatioPosition((int)priWidth, (int)priHeight, &rect);
xPos = rect.x;
yPos = rect.y;
fbWidth = rect.w;
fbHeight = rect.h;
if(orientation == MDP_ROT_180) {
inRect->x = priWidth - (inRect->x + inRect->w);
inRect->y = priHeight - (inRect->y + inRect->h);
}
break;
case MDP_ROT_90:
case MDP_ROT_270:
if(orientation == MDP_ROT_90) {
tmp = inRect->y;
inRect->y = priWidth - (inRect->x + inRect->w);
inRect->x = tmp;
}
else if(orientation == MDP_ROT_270) {
tmp = inRect->x;
inRect->x = priHeight - (inRect->y + inRect->h);
inRect->y = tmp;
}
//Swap the destination width/height
swapWidthHeight(inRect->w, inRect->h);
// Swap width/height for primary
swapWidthHeight(priWidth, priHeight);
getAspectRatioPosition((int)priWidth, (int)priHeight, &rect);
xPos = rect.x;
yPos = rect.y;
fbWidth = rect.w;
fbHeight = rect.h;
break;
default:
LOGE("In %s: Unknown Orientation", __FUNCTION__);
break;
}
//Calculate the position...
xRatio = inRect->x/priWidth;
yRatio = inRect->y/priHeight;
wRatio = inRect->w/priWidth;
hRatio = inRect->h/priHeight;
outRect->x = (xRatio * fbWidth) + xPos;
outRect->y = (yRatio * fbHeight) + yPos;
outRect->w = (wRatio * fbWidth);
outRect->h = hRatio * fbHeight;
LOGD("Calculated AS Position for HDMI: X= %d, y = %d w = %d h = %d",
outRect->x, outRect->y,outRect->w, outRect->h);
return true;
}
bool OverlayControlChannel::getPositionS3D(int channel, int format, overlay_rect *rect) {
int wDisp = getFBWidth();
int hDisp = getFBHeight();
switch (format & OUTPUT_MASK_3D) {
case HAL_3D_OUT_SIDE_BY_SIDE_MASK:
if (channel == VG0_PIPE) {
rect->x = 0;
rect->y = 0;
rect->w = wDisp/2;
rect->h = hDisp;
} else {
rect->x = wDisp/2;
rect->y = 0;
rect->w = wDisp/2;
rect->h = hDisp;
}
break;
case HAL_3D_OUT_TOP_BOTTOM_MASK:
if (channel == VG0_PIPE) {
rect->x = 0;
rect->y = 0;
rect->w = wDisp;
rect->h = hDisp/2;
} else {
rect->x = 0;
rect->y = hDisp/2;
rect->w = wDisp;
rect->h = hDisp/2;
}
break;
case HAL_3D_OUT_MONOSCOPIC_MASK:
if (channel == VG1_PIPE) {
rect->x = 0;
rect->y = 0;
rect->w = wDisp;
rect->h = hDisp;
}
else
return false;
break;
case HAL_3D_OUT_INTERLEAVE_MASK:
break;
default:
reportError("Unsupported 3D output format");
break;
}
return true;
}
bool OverlayControlChannel::openDevices(int fbnum) {
if (fbnum < 0)
return false;
char dev_name[64];
snprintf(dev_name, 64, FB_DEVICE_TEMPLATE, fbnum);
mFD = open(dev_name, O_RDWR, 0);
if (mFD < 0) {
reportError("Cant open framebuffer ");
return false;
}
fb_fix_screeninfo finfo;
if (ioctl(mFD, FBIOGET_FSCREENINFO, &finfo) == -1) {
reportError("FBIOGET_FSCREENINFO on fb1 failed");
close(mFD);
mFD = -1;
return false;
}
fb_var_screeninfo vinfo;
if (ioctl(mFD, FBIOGET_VSCREENINFO, &vinfo) == -1) {
reportError("FBIOGET_VSCREENINFO on fb1 failed");
close(mFD);
mFD = -1;
return false;
}
mFBWidth = vinfo.xres;
mFBHeight = vinfo.yres;
mFBbpp = vinfo.bits_per_pixel;
mFBystride = finfo.line_length;
if (!mNoRot) {
mRotFD = open("/dev/msm_rotator", O_RDWR, 0);
if (mRotFD < 0) {
reportError("Cant open rotator device");
close(mFD);
mFD = -1;
return false;
}
}
return true;
}
bool OverlayControlChannel::setOverlayInformation(const overlay_buffer_info& info,
int zorder, int flags, int requestType) {
int w = info.width;
int h = info.height;
int format = info.format;
mOVInfo.src.width = w;
mOVInfo.src.height = h;
mOVInfo.src_rect.x = 0;
mOVInfo.src_rect.y = 0;
mOVInfo.dst_rect.x = 0;
mOVInfo.dst_rect.y = 0;
mOVInfo.dst_rect.w = w;
mOVInfo.dst_rect.h = h;
if(format == MDP_Y_CRCB_H2V2_TILE || format == MDP_Y_CBCR_H2V2_TILE) {
if (mNoRot) {
mOVInfo.src_rect.w = w - ((((w-1)/64 +1)*64) - w);
mOVInfo.src_rect.h = h - ((((h-1)/32 +1)*32) - h);
} else {
mOVInfo.src_rect.w = w;
mOVInfo.src_rect.h = h;
mOVInfo.src.width = (((w-1)/64 +1)*64);
mOVInfo.src.height = (((h-1)/32 +1)*32);
mOVInfo.src_rect.x = mOVInfo.src.width - w;
mOVInfo.src_rect.y = mOVInfo.src.height - h;
}
} else {
mOVInfo.src_rect.w = w;
mOVInfo.src_rect.h = h;
}
mOVInfo.src.format = format;
int dst_w = w;
int dst_h = h;
if (dst_w > mFBWidth) {
dst_w = mFBWidth;
dst_h = dst_h * mFBWidth / w;
}
if (dst_h > mFBHeight) {
dst_h = mFBHeight;
dst_w = dst_w * mFBHeight / h;
}
mOVInfo.dst_rect.w = dst_w;
mOVInfo.dst_rect.h = dst_h;
mOVInfo.user_data[0] = 0;
if (requestType == NEW_REQUEST) {
mOVInfo.id = MSMFB_NEW_REQUEST;
mOVInfo.z_order = zorder;
mOVInfo.alpha = 0xff;
mOVInfo.transp_mask = 0xffffffff;
}
mOVInfo.flags = 0;
if (info.secure) {
flags |= SECURE_OVERLAY_SESSION;
} else {
flags &= ~SECURE_OVERLAY_SESSION;
}
setInformationFromFlags(flags, mOVInfo);
mOVInfo.dpp.sharp_strength = 0;
return true;
}
void OverlayControlChannel::setInformationFromFlags(int flags, mdp_overlay& ov)
{
if (flags & INTERLACED_CONTENT) {
mOVInfo.flags |= MDP_DEINTERLACE;
} else {
mOVInfo.flags &= ~MDP_DEINTERLACE;
}
if ((flags & WAIT_FOR_VSYNC) == 0)
mOVInfo.flags |= MDP_OV_PLAY_NOWAIT;
else
mOVInfo.flags &= ~MDP_OV_PLAY_NOWAIT;
if(flags & SECURE_OVERLAY_SESSION)
mOVInfo.flags |= MDP_SECURE_OVERLAY_SESSION;
else
mOVInfo.flags &= ~MDP_SECURE_OVERLAY_SESSION;
//set the default sharpening settings
mOVInfo.flags |= MDP_SHARPENING;
if (flags & DISABLE_FRAMEBUFFER_FETCH)
mOVInfo.is_fg = 1;
else
mOVInfo.is_fg = 0;
if (flags & OVERLAY_PIPE_SHARE) {
mOVInfo.flags |= MDP_OV_PIPE_SHARE;
} else {
mOVInfo.flags &= ~MDP_OV_PIPE_SHARE;
}
}
bool OverlayControlChannel::doFlagsNeedUpdate(int flags) {
bool needUpdate = false;
if ((flags & WAIT_FOR_VSYNC) == 0) {
if (!(mOVInfo.flags & MDP_OV_PLAY_NOWAIT)) {
needUpdate = true;
}
}
if (flags & WAIT_FOR_VSYNC) {
if (mOVInfo.flags & MDP_OV_PLAY_NOWAIT) {
needUpdate = true;
}
}
if ((flags & DISABLE_FRAMEBUFFER_FETCH) == 0) {
if (mOVInfo.is_fg == 1) {
needUpdate = true;
}
}
if (flags & DISABLE_FRAMEBUFFER_FETCH) {
if (mOVInfo.is_fg == 0) {
needUpdate = true;
}
}
return needUpdate;
}
bool OverlayControlChannel::startOVRotatorSessions(
const overlay_buffer_info& info,
int requestType) {
bool ret = true;
int w = info.width;
int h = info.height;
int format = info.format;
if (!mNoRot) {
mRotInfo.src.format = format;
mRotInfo.src.width = w;
mRotInfo.src.height = h;
mRotInfo.src_rect.w = w;
mRotInfo.src_rect.h = h;
mRotInfo.dst.width = w;
mRotInfo.dst.height = h;
if(format == MDP_Y_CRCB_H2V2_TILE || format == MDP_Y_CBCR_H2V2_TILE) {
mRotInfo.src.width = (((w-1)/64 +1)*64);
mRotInfo.src.height = (((h-1)/32 +1)*32);
mRotInfo.src_rect.w = (((w-1)/64 +1)*64);
mRotInfo.src_rect.h = (((h-1)/32 +1)*32);
mRotInfo.dst.width = (((w-1)/64 +1)*64);
mRotInfo.dst.height = (((h-1)/32 +1)*32);
}
mRotInfo.dst_x = 0;
mRotInfo.dst_y = 0;
mRotInfo.src_rect.x = 0;
mRotInfo.src_rect.y = 0;
mRotInfo.rotations = 0;
if (requestType == NEW_REQUEST) {
mRotInfo.enable = 0;
if(mUIChannel)
mRotInfo.enable = 1;
mRotInfo.session_id = 0;
} else
mRotInfo.enable = 1;
int result = ioctl(mRotFD, MSM_ROTATOR_IOCTL_START, &mRotInfo);
if (result) {
reportError("Rotator session failed");
dump(mRotInfo);
ret = false;
}
}
if (ret && ioctl(mFD, MSMFB_OVERLAY_SET, &mOVInfo)) {
reportError("startOVRotatorSessions, Overlay set failed");
dump(mOVInfo);
ret = false;
}
if (!ret)
closeControlChannel();
else
mIsChannelUpdated = true;
return ret;
}
bool OverlayControlChannel::updateOverlaySource(const overlay_buffer_info& info,
int orientation, int flags)
{
int colorFormat = getColorFormat(info.format);
int hw_format = get_mdp_format(colorFormat);
overlay_buffer_info ovBufInfo;
ovBufInfo.width = info.width;
ovBufInfo.height = info.height;
ovBufInfo.format = hw_format;
if (isInterlacedContent(info.format)) {
flags |= INTERLACED_CONTENT;
}
if (!setOverlayInformation(ovBufInfo, 0, flags,
UPDATE_REQUEST))
return false;
return startOVRotatorSessions(ovBufInfo, UPDATE_REQUEST);
}
bool OverlayControlChannel::startControlChannel(int w, int h,
int format, int fbnum, bool norot,
bool uichannel,
unsigned int format3D, int zorder,
int flags) {
mNoRot = norot;
mFormat = format;
mUIChannel = uichannel;
mFBNum = fbnum;
fb_fix_screeninfo finfo;
fb_var_screeninfo vinfo;
int hw_format;
int colorFormat = format;
// The interlace mask is part of the HAL_PIXEL_FORMAT_YV12 value. Add
// an explicit check for the format
if (isInterlacedContent(format)) {
flags |= MDP_DEINTERLACE;
// Get the actual format
colorFormat = format ^ HAL_PIXEL_FORMAT_INTERLACE;
}
hw_format = get_mdp_format(colorFormat);
if (hw_format < 0) {
reportError("Unsupported format");
return false;
}
mFormat3D = format3D;
if ( !mFormat3D || (mFormat3D & HAL_3D_OUT_MONOSCOPIC_MASK) ) {
// Set the share bit for sharing the VG pipe
flags |= OVERLAY_PIPE_SHARE;
}
//do not set the PIPE SHARE bit for true mirroring
if(uichannel && FrameBufferInfo::getInstance()->canSupportTrueMirroring())
flags &= ~OVERLAY_PIPE_SHARE;
if (!openDevices(fbnum))
return false;
//get Z order
zorder = ZOrderManager::getInstance()->getZ(fbnum);
if (zorder == NO_PIPE)
return false;
overlay_buffer_info ovBufInfo;
ovBufInfo.width = w;
ovBufInfo.height = h;
ovBufInfo.format = hw_format;
if (!setOverlayInformation(ovBufInfo, zorder, flags, NEW_REQUEST))
return false;
return startOVRotatorSessions(ovBufInfo, NEW_REQUEST);
}
bool OverlayControlChannel::closeControlChannel() {
if (!isChannelUP())
return true;
if (!mNoRot && mRotFD > 0) {
ioctl(mRotFD, MSM_ROTATOR_IOCTL_FINISH, &(mRotInfo.session_id));
close(mRotFD);
mRotFD = -1;
}
int ovid = mOVInfo.id;
ioctl(mFD, MSMFB_OVERLAY_UNSET, &ovid);
if (m3DOVInfo.is_3d) {
m3DOVInfo.is_3d = 0;
ioctl(mFD, MSMFB_OVERLAY_3D, &m3DOVInfo);
}
close(mFD);
if(NO_PIPE != mOVInfo.z_order){
ZOrderManager::getInstance()->decZ(mFBNum, mOVInfo.z_order);
}
memset(&mOVInfo, 0, sizeof(mOVInfo));
memset(&mRotInfo, 0, sizeof(mRotInfo));
memset(&m3DOVInfo, 0, sizeof(m3DOVInfo));
mOVInfo.z_order = NO_PIPE;
mFD = -1;
return true;
}
bool OverlayControlChannel::updateOverlayFlags(int flags) {
if ((flags & WAIT_FOR_VSYNC) == 0)
mOVInfo.flags |= MDP_OV_PLAY_NOWAIT;
else
mOVInfo.flags &= ~MDP_OV_PLAY_NOWAIT;
if (flags & DISABLE_FRAMEBUFFER_FETCH)
mOVInfo.is_fg = 1;
else
mOVInfo.is_fg = 0;
if (ioctl(mFD, MSMFB_OVERLAY_SET, &mOVInfo)) {
LOGE("%s: OVERLAY_SET failed", __FUNCTION__);
dump(mOVInfo);
return false;
}
return true;
}
bool OverlayControlChannel::setPosition(int x, int y, uint32_t w, uint32_t h) {
if (!isChannelUP() ||
(x < 0) || (y < 0) || ((x + w) > mFBWidth) ||
((y + h) > mFBHeight)) {
reportError("setPosition failed");
LOGW("x %d y %d (x+w) %d (y+h) %d FBWidth %d FBHeight %d", x, y, x+w, y+h,
mFBWidth,mFBHeight);
return false;
}
if( x != mOVInfo.dst_rect.x || y != mOVInfo.dst_rect.y ||
w != mOVInfo.dst_rect.w || h != mOVInfo.dst_rect.h ) {
mdp_overlay ov;
ov.id = mOVInfo.id;
if (ioctl(mFD, MSMFB_OVERLAY_GET, &ov)) {
reportError("setPosition, overlay GET failed");
return false;
}
/* Scaling of upto a max of 8 times supported */
if(w >(ov.src_rect.w * HW_OVERLAY_MAGNIFICATION_LIMIT)){
w = HW_OVERLAY_MAGNIFICATION_LIMIT * ov.src_rect.w;
x = (mFBWidth - w) / 2;
}
if(h >(ov.src_rect.h * HW_OVERLAY_MAGNIFICATION_LIMIT)) {
h = HW_OVERLAY_MAGNIFICATION_LIMIT * ov.src_rect.h;
y = (mFBHeight - h) / 2;
}
ov.dst_rect.x = x;
ov.dst_rect.y = y;
ov.dst_rect.w = w;
ov.dst_rect.h = h;
if (ioctl(mFD, MSMFB_OVERLAY_SET, &ov)) {
reportError("setPosition, Overlay SET failed");
dump(ov);
return false;
}
mOVInfo = ov;
}
return true;
}
void OverlayControlChannel::swapOVRotWidthHeight() {
int tmp = mOVInfo.src.width;
mOVInfo.src.width = mOVInfo.src.height;
mOVInfo.src.height = tmp;
tmp = mOVInfo.src_rect.h;
mOVInfo.src_rect.h = mOVInfo.src_rect.w;
mOVInfo.src_rect.w = tmp;
tmp = mRotInfo.dst.width;
mRotInfo.dst.width = mRotInfo.dst.height;
mRotInfo.dst.height = tmp;
}
bool OverlayControlChannel::useVirtualFB() {
if(!m3DOVInfo.is_3d) {
m3DOVInfo.is_3d = 1;
mFBWidth *= 2;
mFBHeight /= 2;
m3DOVInfo.width = mFBWidth;
m3DOVInfo.height = mFBHeight;
return ioctl(mFD, MSMFB_OVERLAY_3D, &m3DOVInfo) ? false : true;
}
return true;
}
bool OverlayControlChannel::setTransform(int value, bool fetch) {
if (!isChannelUP()) {
LOGE("%s: channel is not up", __FUNCTION__);
return false;
}
mdp_overlay ov = mOVInfo;
if (fetch && ioctl(mFD, MSMFB_OVERLAY_GET, &ov)) {
reportError("setParameter, overlay GET failed");
return false;
}
mOVInfo = ov;
if (!mIsChannelUpdated) {
int orientation = get_mdp_orientation(value);
if (orientation == mOVInfo.user_data[0]) {
return true;
}
}
mIsChannelUpdated = false;
int val = mOVInfo.user_data[0];
if (mNoRot)
return true;
int rot = value;
switch(rot) {
case 0:
case HAL_TRANSFORM_FLIP_H:
case HAL_TRANSFORM_FLIP_V:
{
if (val == MDP_ROT_90) {
int tmp = mOVInfo.src_rect.y;
mOVInfo.src_rect.y = mOVInfo.src.width -
(mOVInfo.src_rect.x + mOVInfo.src_rect.w);
mOVInfo.src_rect.x = tmp;
swapOVRotWidthHeight();
}
else if (val == MDP_ROT_270) {
int tmp = mOVInfo.src_rect.x;
mOVInfo.src_rect.x = mOVInfo.src.height - (
mOVInfo.src_rect.y + mOVInfo.src_rect.h);
mOVInfo.src_rect.y = tmp;
swapOVRotWidthHeight();
}
break;
}
case HAL_TRANSFORM_ROT_90:
case (HAL_TRANSFORM_ROT_90|HAL_TRANSFORM_FLIP_H):
case (HAL_TRANSFORM_ROT_90|HAL_TRANSFORM_FLIP_V):
{
if (val == MDP_ROT_270) {
mOVInfo.src_rect.x = mOVInfo.src.width - (
mOVInfo.src_rect.x + mOVInfo.src_rect.w);
mOVInfo.src_rect.y = mOVInfo.src.height - (
mOVInfo.src_rect.y + mOVInfo.src_rect.h);
}
else if (val == MDP_ROT_NOP || val == MDP_ROT_180) {
int tmp = mOVInfo.src_rect.x;
mOVInfo.src_rect.x = mOVInfo.src.height -
(mOVInfo.src_rect.y + mOVInfo.src_rect.h);
mOVInfo.src_rect.y = tmp;
swapOVRotWidthHeight();
}
break;
}
case HAL_TRANSFORM_ROT_180:
{
if (val == MDP_ROT_270) {
int tmp = mOVInfo.src_rect.y;
mOVInfo.src_rect.y = mOVInfo.src.width -
(mOVInfo.src_rect.x + mOVInfo.src_rect.w);
mOVInfo.src_rect.x = tmp;
swapOVRotWidthHeight();
}
else if (val == MDP_ROT_90) {
int tmp = mOVInfo.src_rect.x;
mOVInfo.src_rect.x = mOVInfo.src.height - (
mOVInfo.src_rect.y + mOVInfo.src_rect.h);
mOVInfo.src_rect.y = tmp;
swapOVRotWidthHeight();
}
break;
}
case HAL_TRANSFORM_ROT_270:
{
if (val == MDP_ROT_90) {
mOVInfo.src_rect.y = mOVInfo.src.height -
(mOVInfo.src_rect.y + mOVInfo.src_rect.h);
mOVInfo.src_rect.x = mOVInfo.src.width -
(mOVInfo.src_rect.x + mOVInfo.src_rect.w);
}
else if (val == MDP_ROT_NOP || val == MDP_ROT_180) {
int tmp = mOVInfo.src_rect.y;
mOVInfo.src_rect.y = mOVInfo.src.width - (
mOVInfo.src_rect.x + mOVInfo.src_rect.w);
mOVInfo.src_rect.x = tmp;
swapOVRotWidthHeight();
}
break;
}
default: return false;
}
int mdp_rotation = get_mdp_orientation(rot);
if (mdp_rotation == -1)
return false;
mOVInfo.user_data[0] = mdp_rotation;
mRotInfo.rotations = mOVInfo.user_data[0];
//Always enable rotation for UI mirror usecase
if (mOVInfo.user_data[0] || mUIChannel)
mRotInfo.enable = 1;
else
mRotInfo.enable = 0;
if (ioctl(mRotFD, MSM_ROTATOR_IOCTL_START, &mRotInfo)) {
reportError("setTransform, rotator start failed");
return false;
}
/* set input format to overlay depending on rotator being used or not */
if (mRotInfo.enable)
mOVInfo.src.format = mRotInfo.dst.format;
else
mOVInfo.src.format = mRotInfo.src.format;
if ((mOVInfo.user_data[0] == MDP_ROT_90) ||
(mOVInfo.user_data[0] == MDP_ROT_270))
mOVInfo.flags |= MDP_SOURCE_ROTATED_90;
else
mOVInfo.flags &= ~MDP_SOURCE_ROTATED_90;
if (ioctl(mFD, MSMFB_OVERLAY_SET, &mOVInfo)) {
reportError("setTransform, overlay set failed");
dump(mOVInfo);
return false;
}
return true;
}
bool OverlayControlChannel::getPosition(int& x, int& y,
uint32_t& w, uint32_t& h) {
if (!isChannelUP())
return false;
//mOVInfo has the current Overlay Position
x = mOVInfo.dst_rect.x;
y = mOVInfo.dst_rect.y;
w = mOVInfo.dst_rect.w;
h = mOVInfo.dst_rect.h;
return true;
}
bool OverlayControlChannel::getOrientation(int& orientation) const {
if (!isChannelUP())
return false;
// mOVInfo has the current orientation
orientation = mOVInfo.user_data[0];
return true;
}
bool OverlayControlChannel::getOvSessionID(int& sessionID) const {
if (!isChannelUP())
return false;
sessionID = mOVInfo.id;
return true;
}
bool OverlayControlChannel::getRotSessionID(int& sessionID) const {
if (!isChannelUP())
return false;
sessionID = mRotInfo.session_id;
return true;
}
bool OverlayControlChannel::getSize(int& size) const {
if (!isChannelUP())
return false;
size = mSize;
return true;
}
OverlayDataChannel::OverlayDataChannel() : mNoRot(false), mFD(-1), mRotFD(-1),
mPmemFD(-1), mPmemAddr(0), mUpdateDataChannel(false)
{
//XXX: getInstance(false) implies that it should only
// use the kernel allocator. Change it to something
// more descriptive later.
mAlloc = gralloc::IAllocController::getInstance(false);
}
OverlayDataChannel::~OverlayDataChannel() {
closeDataChannel();
}
bool OverlayDataChannel::startDataChannel(
const OverlayControlChannel& objOvCtrlChannel,
int fbnum, bool norot, bool secure, bool uichannel,
int num_buffers) {
int ovid, rotid, size;
mNoRot = norot;
mSecure = secure;
memset(&mOvData, 0, sizeof(mOvData));
memset(&mOvDataRot, 0, sizeof(mOvDataRot));
memset(&mRotData, 0, sizeof(mRotData));
if (objOvCtrlChannel.getOvSessionID(ovid) &&
objOvCtrlChannel.getRotSessionID(rotid) &&
objOvCtrlChannel.getSize(size)) {
return startDataChannel(ovid, rotid, size, fbnum,
norot, uichannel, num_buffers);
}
else
return false;
}
bool OverlayDataChannel::openDevices(int fbnum, bool uichannel, int num_buffers) {
if (fbnum < 0)
return false;
char dev_name[64];
snprintf(dev_name, 64, FB_DEVICE_TEMPLATE, fbnum);
mFD = open(dev_name, O_RDWR, 0);
if (mFD < 0) {
reportError("Cant open framebuffer ");
return false;
}
if (!mNoRot) {
mRotFD = open("/dev/msm_rotator", O_RDWR, 0);
if (mRotFD < 0) {
reportError("Cant open rotator device");
close(mFD);
mFD = -1;
return false;
}
return mapRotatorMemory(num_buffers, uichannel, NEW_REQUEST);
}
return true;
}
bool OverlayDataChannel::mapRotatorMemory(int num_buffers, bool uiChannel, int requestType)
{
mPmemAddr = MAP_FAILED;
alloc_data data;
data.base = 0;
data.fd = -1;
data.offset = 0;
data.size = mPmemOffset * num_buffers;
data.align = getpagesize();
data.uncached = true;
int allocFlags = GRALLOC_USAGE_PRIVATE_MM_HEAP |
GRALLOC_USAGE_PRIVATE_WRITEBACK_HEAP|
GRALLOC_USAGE_PRIVATE_DO_NOT_MAP;
if(mSecure) {
allocFlags |= GRALLOC_USAGE_PROTECTED;
} else {
allocFlags |= GRALLOC_USAGE_PRIVATE_ADSP_HEAP |
GRALLOC_USAGE_PRIVATE_IOMMU_HEAP;
if((requestType == NEW_REQUEST) && !uiChannel)
allocFlags |= GRALLOC_USAGE_PRIVATE_SMI_HEAP;
}
int err = mAlloc->allocate(data, allocFlags, 0);
if(err) {
reportError("Cant allocate rotatory memory");
close(mFD);
mFD = -1;
close(mRotFD);
mRotFD = -1;
return false;
}
mPmemFD = data.fd;
mPmemAddr = data.base;
mBufferType = data.allocType;
// Set this flag if source memory is fb
if(uiChannel)
mRotData.src.flags |= MDP_MEMORY_ID_TYPE_FB;
mOvDataRot.data.memory_id = mPmemFD;
mRotData.dst.memory_id = mPmemFD;
mRotData.dst.offset = 0;
mNumBuffers = num_buffers;
mCurrentItem = 0;
for (int i = 0; i < num_buffers; i++)
mRotOffset[i] = i * mPmemOffset;
return true;
}
bool OverlayDataChannel::updateDataChannel(int size) {
mUpdateDataChannel = true;
mNewPmemOffset = size;
return true;
}
bool OverlayDataChannel::startDataChannel(int ovid, int rotid, int size,
int fbnum, bool norot,
bool uichannel, int num_buffers) {
memset(&mOvData, 0, sizeof(mOvData));
memset(&mOvDataRot, 0, sizeof(mOvDataRot));
memset(&mRotData, 0, sizeof(mRotData));
mNoRot = norot;
mOvData.data.memory_id = -1;
mOvData.id = ovid;
mOvDataRot = mOvData;
mPmemOffset = size;
mRotData.session_id = rotid;
mNumBuffers = 0;
mCurrentItem = 0;
return openDevices(fbnum, uichannel, num_buffers);
}
bool OverlayDataChannel::closeDataChannel() {
if (!isChannelUP())
return true;
if (!mNoRot && mRotFD > 0) {
sp<IMemAlloc> memalloc = mAlloc->getAllocator(mBufferType);
memalloc->free_buffer(mPmemAddr, mPmemOffset * mNumBuffers, 0, mPmemFD);
close(mPmemFD);
mPmemFD = -1;
close(mRotFD);
mRotFD = -1;
}
close(mFD);
mFD = -1;
memset(&mOvData, 0, sizeof(mOvData));
memset(&mOvDataRot, 0, sizeof(mOvDataRot));
memset(&mRotData, 0, sizeof(mRotData));
mNumBuffers = 0;
mCurrentItem = 0;
return true;
}
bool OverlayDataChannel::setFd(int fd) {
mOvData.data.memory_id = fd;
return true;
}
bool OverlayDataChannel::queueBuffer(uint32_t offset) {
if ((!isChannelUP()) || mOvData.data.memory_id < 0) {
reportError("QueueBuffer failed, either channel is not set or no file descriptor to read from");
return false;
}
int oldPmemFD = -1;
void* oldPmemAddr = MAP_FAILED;
uint32_t oldPmemOffset = -1;
bool result;
if (!mNoRot) {
if (mUpdateDataChannel) {
oldPmemFD = mPmemFD;
oldPmemAddr = mPmemAddr;
oldPmemOffset = mPmemOffset;
mPmemOffset = mNewPmemOffset;
mNewPmemOffset = -1;
// Map the new PMEM memory
result = mapRotatorMemory(mNumBuffers, 0, UPDATE_REQUEST);
if (!result) {
LOGE("queueBuffer: mapRotatorMemory failed");
return false;
}
mUpdateDataChannel = false;
}
}
result = queue(offset);
// Unmap the old PMEM memory after the queueBuffer has returned
if (oldPmemFD != -1 && oldPmemAddr != MAP_FAILED) {
sp<IMemAlloc> memalloc = mAlloc->getAllocator(mBufferType);
memalloc->free_buffer(oldPmemAddr, oldPmemOffset * mNumBuffers, 0, oldPmemFD);
oldPmemFD = -1;
}
return result;
}
bool OverlayDataChannel::queue(uint32_t offset) {
msmfb_overlay_data *odPtr;
mOvData.data.offset = offset;
odPtr = &mOvData;
if (!mNoRot) {
mRotData.src.memory_id = mOvData.data.memory_id;
mRotData.src.offset = offset;
mRotData.dst.offset = (mRotData.dst.offset) ? 0 : mPmemOffset;
mRotData.dst.offset = mRotOffset[mCurrentItem];
mCurrentItem = (mCurrentItem + 1) % mNumBuffers;
int result = ioctl(mRotFD,
MSM_ROTATOR_IOCTL_ROTATE, &mRotData);
if (!result) {
mOvDataRot.data.offset = (uint32_t) mRotData.dst.offset;
odPtr = &mOvDataRot;
}
}
if (ioctl(mFD, MSMFB_OVERLAY_PLAY, odPtr)) {
reportError("overlay play failed.");
return false;
}
return true;
}
bool OverlayDataChannel::waitForHdmiVsync() {
if (!isChannelUP()) {
LOGE("%s: channel not up", __FUNCTION__);
return false;
}
if (ioctl(mFD, MSMFB_OVERLAY_PLAY_WAIT, &mOvData)) {
LOGE("%s: MSMFB_OVERLAY_PLAY_WAIT failed", __FUNCTION__);
return false;
}
return true;
}
bool OverlayDataChannel::getCropS3D(overlay_rect *inRect, int channel, int format,
overlay_rect *rect) {
// for the 3D usecase extract channels from a frame
switch (format & INPUT_MASK_3D) {
case HAL_3D_IN_SIDE_BY_SIDE_L_R:
if(channel == 0) {
rect->x = 0;
rect->y = 0;
rect->w = inRect->w/2;
rect->h = inRect->h;
} else {
rect->x = inRect->w/2;
rect->y = 0;
rect->w = inRect->w/2;
rect->h = inRect->h;
}
break;
case HAL_3D_IN_SIDE_BY_SIDE_R_L:
if(channel == 1) {
rect->x = 0;
rect->y = 0;
rect->w = inRect->w/2;
rect->h = inRect->h;
} else {
rect->x = inRect->w/2;
rect->y = 0;
rect->w = inRect->w/2;
rect->h = inRect->h;
}
break;
case HAL_3D_IN_TOP_BOTTOM:
if(channel == 0) {
rect->x = 0;
rect->y = 0;
rect->w = inRect->w;
rect->h = inRect->h/2;
} else {
rect->x = 0;
rect->y = inRect->h/2;
rect->w = inRect->w;
rect->h = inRect->h/2;
}
break;
case HAL_3D_IN_INTERLEAVE:
break;
default:
reportError("Unsupported 3D format...");
break;
}
return true;
}
bool OverlayDataChannel::setCrop(uint32_t x, uint32_t y, uint32_t w, uint32_t h) {
if (!isChannelUP()) {
reportError("Channel not set");
return false;
}
mdp_overlay ov;
ov.id = mOvData.id;
if (ioctl(mFD, MSMFB_OVERLAY_GET, &ov)) {
reportError("setCrop, overlay GET failed");
return false;
}
if ((ov.user_data[0] == MDP_ROT_90) ||
(ov.user_data[0] == (MDP_ROT_90 | MDP_FLIP_UD)) ||
(ov.user_data[0] == (MDP_ROT_90 | MDP_FLIP_LR))){
if (ov.src.width < (y + h))
return false;
uint32_t tmp = x;
x = ov.src.width - (y + h);
y = tmp;
tmp = w;
w = h;
h = tmp;
}
else if (ov.user_data[0] == MDP_ROT_270) {
if (ov.src.height < (x + w))
return false;
uint32_t tmp = y;
y = ov.src.height - (x + w);
x = tmp;
tmp = w;
w = h;
h = tmp;
}
else if(ov.user_data[0] == MDP_ROT_180) {
if ((ov.src.height < (y + h)) || (ov.src.width < ( x + w)))
return false;
x = ov.src.width - (x + w);
y = ov.src.height - (y + h);
}
if ((ov.src_rect.x == x) &&
(ov.src_rect.y == y) &&
(ov.src_rect.w == w) &&
(ov.src_rect.h == h))
return true;
normalize_crop(x, w);
normalize_crop(y, h);
ov.src_rect.x = x;
ov.src_rect.y = y;
ov.src_rect.w = w;
ov.src_rect.h = h;
/* Scaling of upto a max of 8 times supported */
if(ov.dst_rect.w >(ov.src_rect.w * HW_OVERLAY_MAGNIFICATION_LIMIT)){
ov.dst_rect.w = HW_OVERLAY_MAGNIFICATION_LIMIT * ov.src_rect.w;
}
if(ov.dst_rect.h >(ov.src_rect.h * HW_OVERLAY_MAGNIFICATION_LIMIT)) {
ov.dst_rect.h = HW_OVERLAY_MAGNIFICATION_LIMIT * ov.src_rect.h;
}
if (ioctl(mFD, MSMFB_OVERLAY_SET, &ov)) {
reportError("setCrop, overlay set error");
return false;
}
return true;
}
/* setVisualParam can be called to set the configuration value of a post
* processing feature (HUE,SATURATION,BRIGHTNESS,CONTRAST,SMOOTHING/SHARPENING)
* for the first 4, the setting will stay set until the parameter is changed
* by another call to setVisualParam with that same paramType */
void Overlay::setVisualParam(int8_t paramType, float paramValue) {
switch (mState) {
case OV_UI_MIRROR_TV:
case OV_2D_VIDEO_ON_PANEL:
case OV_3D_VIDEO_2D_PANEL:
// set the parameter value for the given parameter type.
if(!objOvCtrlChannel[VG0_PIPE].setVisualParam(paramType, paramValue)) {
LOGE("Failed to set param %d for value %f", paramType, paramValue);
}
break;
case OV_2D_VIDEO_ON_TV:
case OV_3D_VIDEO_3D_PANEL:
case OV_3D_VIDEO_2D_TV:
case OV_3D_VIDEO_3D_TV:
for (int i=0; i<NUM_CHANNELS; i++) {
//setting the value for the given parameter on each pipe (i.e. for
//both video pipes)
if(!objOvCtrlChannel[i].setVisualParam(paramType, paramValue)) {
LOGE("Failed to set param %d for value %f", paramType, paramValue);
}
}
break;
default:
break;
}
}
/* Finalizes the parameter value in the hsic_cfg structure*/
int OverlayControlChannel::commitVisualParam(int8_t paramType, float paramValue) {
#ifdef USES_POST_PROCESSING
switch(paramType) {
case SET_HUE:
//API expects param within range -180 - 180
CAP_RANGE(paramValue, HUE_RANGE, -HUE_RANGE);
hsic_cfg.hue = (int32_t) paramValue;
break;
case SET_BRIGHTNESS:
//API expects param within range -255 - 255
CAP_RANGE(paramValue, BRIGHTNESS_RANGE, -BRIGHTNESS_RANGE);
hsic_cfg.intensity = (int32_t) paramValue;
break;
case SET_SATURATION:
//API expects param within range -1 - 1
CAP_RANGE(paramValue, CON_SAT_RANGE, -CON_SAT_RANGE);
hsic_cfg.sat = paramValue;
break;
case SET_CONTRAST:
//API expects param within range -1 - 1
CAP_RANGE(paramValue, CON_SAT_RANGE, -CON_SAT_RANGE);
hsic_cfg.contrast = paramValue;
break;
default:
return -1;
}
return 0;
#endif
return -1;
}
/* Converts paramValue to the expected range for each paramType, */
bool OverlayControlChannel::setVisualParam(int8_t paramType, float paramValue)
{
if (!isChannelUP()) {
LOGE("%s: Channel not set", __FUNCTION__);
return false;
}
bool setFlag = false;
//Sharpness values range from -128 to 127
//Integer values must be converted accordingly
int8_t value;
if (paramType == SET_SHARPNESS) {
//binding paramValue to the limits of its range.
CAP_RANGE(paramValue, SHARPNESS_RANGE, -SHARPNESS_RANGE);
value = paramValue * NUM_SHARPNESS_VALS - (NUM_SHARPNESS_VALS / 2);
}
uint32_t block = MDP_BLOCK_MAX;
//tranlate mOVInfo.id into block type for pp_conv
switch(mOVInfo.id) {
case 3:
// 3 is the pipe_ndx given when OVERLAY_PIPE_VG1 is used
block = MDP_BLOCK_VG_1;
break;
case 4:
// 4 is the pipe_ndx given when OVERLAY_PIPE_VG2 is used
block = MDP_BLOCK_VG_2;
break;
default:
LOGE("%s: Invalid HSIC overlay id",__FUNCTION__);
}
//save the paramValue to hsic_cfg
commitVisualParam(paramType, paramValue);
#ifdef USES_POST_PROCESSING
//calling our user space library to configure the post processing color
//conversion (does Hue, Saturation, Brightness, and Contrast adjustment)
display_pp_conv_set_cfg(block, &hsic_cfg);
#endif
mdp_overlay overlay;
switch(paramType) {
case SET_NONE:
return true;
case SET_SHARPNESS:
if (ioctl(mFD, MSMFB_OVERLAY_GET, &overlay)) {
reportError("setVisualParam, overlay GET failed");
return false;
}
if (overlay.dpp.sharp_strength != value) {
mOVInfo.flags |= MDP_SHARPENING;
mOVInfo.dpp.sharp_strength = value;
setFlag = true;
}
break;
case RESET_ALL:
//set all visual params to a default value
//passed in from the app
mOVInfo.flags |= MDP_SHARPENING;
mOVInfo.dpp.sharp_strength = value;
setFlag = true;
break;
default:
return false;
}
if (setFlag) {
if (ioctl(mFD, MSMFB_OVERLAY_SET, &mOVInfo)) {
reportError("setVisualParam, overlay set failed");
dump(mOVInfo);
return false;
}
}
return true;
}