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hardware_samsung/exynos4/hal/libhdmi/SecHdmi/SecHdmi.cpp

1957 lines
59 KiB

/*
* Copyright@ Samsung Electronics Co. LTD
*
* 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.
*/
//#define LOG_NDEBUG 0
//#define LOG_TAG "libhdmi"
#include <cutils/log.h>
#if defined(BOARD_USE_V4L2_ION)
#include "ion.h"
#endif
#include "SecHdmi.h"
#include "SecHdmiV4L2Utils.h"
#define CHECK_GRAPHIC_LAYER_TIME (0)
namespace android {
extern unsigned int output_type;
#if defined(BOARD_USE_V4L2)
extern unsigned int g_preset_id;
#endif
extern v4l2_std_id t_std_id;
extern int g_hpd_state;
extern unsigned int g_hdcp_en;
#if !defined(BOARD_USE_V4L2)
extern int fp_tvout;
extern int fp_tvout_v;
extern int fp_tvout_g0;
extern int fp_tvout_g1;
#endif
#if defined(BOARD_USES_FIMGAPI)
extern unsigned int g2d_reserved_memory[HDMI_G2D_OUTPUT_BUF_NUM];
extern unsigned int g2d_reserved_memory_size;
extern unsigned int cur_g2d_address;
extern unsigned int g2d_buf_index;
#endif
#if defined(BOARD_USES_CEC)
SecHdmi::CECThread::~CECThread()
{
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("%s", __func__);
#endif
mFlagRunning = false;
}
bool SecHdmi::CECThread::threadLoop()
{
unsigned char buffer[CEC_MAX_FRAME_SIZE];
int size;
unsigned char lsrc, ldst, opcode;
{
Mutex::Autolock lock(mThreadLoopLock);
mFlagRunning = true;
size = CECReceiveMessage(buffer, CEC_MAX_FRAME_SIZE, 100000);
if (!size) // no data available or ctrl-c
return true;
if (size == 1)
return true; // "Polling Message"
lsrc = buffer[0] >> 4;
/* ignore messages with src address == mLaddr*/
if (lsrc == mLaddr)
return true;
opcode = buffer[1];
if (CECIgnoreMessage(opcode, lsrc)) {
LOGE("### ignore message coming from address 15 (unregistered)\n");
return true;
}
if (!CECCheckMessageSize(opcode, size)) {
LOGE("### invalid message size: %d(opcode: 0x%x) ###\n", size, opcode);
return true;
}
/* check if message broadcasted/directly addressed */
if (!CECCheckMessageMode(opcode, (buffer[0] & 0x0F) == CEC_MSG_BROADCAST ? 1 : 0)) {
LOGE("### invalid message mode (directly addressed/broadcast) ###\n");
return true;
}
ldst = lsrc;
//TODO: macroses to extract src and dst logical addresses
//TODO: macros to extract opcode
switch (opcode) {
case CEC_OPCODE_GIVE_PHYSICAL_ADDRESS:
/* responce with "Report Physical Address" */
buffer[0] = (mLaddr << 4) | CEC_MSG_BROADCAST;
buffer[1] = CEC_OPCODE_REPORT_PHYSICAL_ADDRESS;
buffer[2] = (mPaddr >> 8) & 0xFF;
buffer[3] = mPaddr & 0xFF;
buffer[4] = mDevtype;
size = 5;
break;
case CEC_OPCODE_REQUEST_ACTIVE_SOURCE:
LOGD("[CEC_OPCODE_REQUEST_ACTIVE_SOURCE]\n");
/* responce with "Active Source" */
buffer[0] = (mLaddr << 4) | CEC_MSG_BROADCAST;
buffer[1] = CEC_OPCODE_ACTIVE_SOURCE;
buffer[2] = (mPaddr >> 8) & 0xFF;
buffer[3] = mPaddr & 0xFF;
size = 4;
LOGD("Tx : [CEC_OPCODE_ACTIVE_SOURCE]\n");
break;
case CEC_OPCODE_ABORT:
case CEC_OPCODE_FEATURE_ABORT:
default:
/* send "Feature Abort" */
buffer[0] = (mLaddr << 4) | ldst;
buffer[1] = CEC_OPCODE_FEATURE_ABORT;
buffer[2] = CEC_OPCODE_ABORT;
buffer[3] = 0x04; // "refused"
size = 4;
break;
}
if (CECSendMessage(buffer, size) != size)
LOGE("CECSendMessage() failed!!!\n");
}
return true;
}
bool SecHdmi::CECThread::start()
{
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("%s", __func__);
#endif
Mutex::Autolock lock(mThreadControlLock);
if (exitPending()) {
if (requestExitAndWait() == WOULD_BLOCK) {
LOGE("mCECThread.requestExitAndWait() == WOULD_BLOCK");
return false;
}
}
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("EDIDGetCECPhysicalAddress");
#endif
/* set to not valid physical address */
mPaddr = CEC_NOT_VALID_PHYSICAL_ADDRESS;
if (!EDIDGetCECPhysicalAddress(&mPaddr)) {
LOGE("Error: EDIDGetCECPhysicalAddress() failed.\n");
return false;
}
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("CECOpen");
#endif
if (!CECOpen()) {
LOGE("CECOpen() failed!!!\n");
return false;
}
/* a logical address should only be allocated when a device \
has a valid physical address, at all other times a device \
should take the 'Unregistered' logical address (15)
*/
/* if physical address is not valid device should take \
the 'Unregistered' logical address (15)
*/
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("CECAllocLogicalAddress");
#endif
mLaddr = CECAllocLogicalAddress(mPaddr, mDevtype);
if (!mLaddr) {
LOGE("CECAllocLogicalAddress() failed!!!\n");
if (!CECClose())
LOGE("CECClose() failed!\n");
return false;
}
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("request to run CECThread");
#endif
status_t ret = run("SecHdmi::CECThread", PRIORITY_DISPLAY);
if (ret != NO_ERROR) {
LOGE("%s fail to run thread", __func__);
return false;
}
return true;
}
bool SecHdmi::CECThread::stop()
{
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("%s request Exit", __func__);
#endif
Mutex::Autolock lock(mThreadControlLock);
if (requestExitAndWait() == WOULD_BLOCK) {
LOGE("mCECThread.requestExitAndWait() == WOULD_BLOCK");
return false;
}
if (!CECClose())
LOGE("CECClose() failed!\n");
mFlagRunning = false;
return true;
}
#endif
SecHdmi::SecHdmi():
#if defined(BOARD_USES_CEC)
mCECThread(NULL),
#endif
mFlagCreate(false),
mFlagConnected(false),
mHdmiDstWidth(0),
mHdmiDstHeight(0),
mHdmiSrcYAddr(0),
mHdmiSrcCbCrAddr(0),
mHdmiOutputMode(DEFAULT_OUPUT_MODE),
mHdmiResolutionValue(DEFAULT_HDMI_RESOLUTION_VALUE), // V4L2_STD_480P_60_4_3
mCompositeStd(DEFAULT_COMPOSITE_STD),
mHdcpMode(false),
mAudioMode(2),
mUIRotVal(0),
mG2DUIRotVal(0),
mCurrentHdmiOutputMode(-1),
mCurrentHdmiResolutionValue(0), // 1080960
mCurrentHdcpMode(false),
mCurrentAudioMode(-1),
mHdmiInfoChange(true),
mFimcDstColorFormat(0),
mFimcCurrentOutBufIndex(0),
mFBaddr(NULL),
mFBsize(0),
mFBionfd(-1),
mFBIndex(0),
mDefaultFBFd(-1),
mDisplayWidth(DEFALULT_DISPLAY_WIDTH),
mDisplayHeight(DEFALULT_DISPLAY_HEIGHT)
{
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("%s", __func__);
#endif
for (int i = 0; i < HDMI_LAYER_MAX; i++) {
mFlagLayerEnable[i] = false;
mFlagHdmiStart[i] = false;
mSrcWidth [i] = 0;
mSrcHeight [i] = 0;
mSrcColorFormat[i] = 0;
mHdmiResolutionWidth [i] = 0;
mHdmiResolutionHeight [i] = 0;
mHdmiFd[i] = -1;
mDstWidth [i] = 0;
mDstHeight [i] = 0;
mPrevDstWidth [i] = 0;
mPrevDstHeight [i] = 0;
}
mHdmiPresetId = DEFAULT_HDMI_PRESET_ID;
mHdmiStdId = DEFAULT_HDMI_STD_ID;
//All layer is on
mFlagLayerEnable[HDMI_LAYER_VIDEO] = true;
mFlagLayerEnable[HDMI_LAYER_GRAPHIC_0] = true;
mFlagLayerEnable[HDMI_LAYER_GRAPHIC_1] = true;
mHdmiSizeOfResolutionValueList = 14;
mHdmiResolutionValueList[0] = 1080960;
mHdmiResolutionValueList[1] = 1080950;
mHdmiResolutionValueList[2] = 1080930;
mHdmiResolutionValueList[3] = 1080924;
mHdmiResolutionValueList[4] = 1080160;
mHdmiResolutionValueList[5] = 1080150;
mHdmiResolutionValueList[6] = 720960;
mHdmiResolutionValueList[7] = 7209601;
mHdmiResolutionValueList[8] = 720950;
mHdmiResolutionValueList[9] = 7209501;
mHdmiResolutionValueList[10] = 5769501;
mHdmiResolutionValueList[11] = 5769502;
mHdmiResolutionValueList[12] = 4809601;
mHdmiResolutionValueList[13] = 4809602;
#if defined(BOARD_USES_CEC)
mCECThread = new CECThread(this);
#endif
SecBuffer zeroBuf;
for (int i = 0; i < HDMI_FIMC_OUTPUT_BUF_NUM; i++)
mFimcReservedMem[i] = zeroBuf;
#if defined(BOARD_USE_V4L2)
for (int i = 0; i < HDMI_LAYER_MAX; i++)
for (int j = 0; j < MAX_BUFFERS_MIXER; j++)
mMixerBuffer[i][j] = zeroBuf;
#endif
memset(&mDstRect, 0 , sizeof(struct v4l2_rect));
}
SecHdmi::~SecHdmi()
{
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("%s", __func__);
#endif
if (mFlagCreate == true)
LOGE("%s::this is not Destroyed fail", __func__);
else
disconnect();
}
bool SecHdmi::create(int width, int height)
{
Mutex::Autolock lock(mLock);
unsigned int fimc_buf_size = 0;
unsigned int gralloc_buf_size = 0;
mFimcCurrentOutBufIndex = 0;
int stride;
int vstride;
int BufNum = 0;
#if defined(BOARD_USE_V4L2_ION)
int IonClient = -1;
int IonFd = -1;
void *ion_base_addr = NULL;
#endif
/*
* Video plaback (I420): output buffer size of FIMC3 is (1920 x 1088 x 1.5)
* Video plaback (NV12): FIMC3 is not used.
* Camera preview (YV12): output buffer size of FIMC3 is (640 x 480 x 1.5)
* UI mode (ARGB8888) : output buffer size of FIMC3 is (480 x 800 x 1.5)
*/
#ifndef SUPPORT_1080P_FIMC_OUT
setDisplaySize(width, height);
#endif
stride = ALIGN(HDMI_MAX_WIDTH, 16);
vstride = ALIGN(HDMI_MAX_HEIGHT, 16);
fimc_buf_size = stride * vstride * HDMI_FIMC_BUFFER_BPP_SIZE;
gralloc_buf_size = GRALLOC_BUF_SIZE * SIZE_1K;
#if defined(BOARD_USES_FIMGAPI)
g2d_reserved_memory_size = stride * vstride * HDMI_G2D_BUFFER_BPP_SIZE;
#endif
#ifdef DEBUG_MSG_ENABLE
LOGD("%s", __func__);
#endif
if (mFlagCreate == true) {
LOGE("%s::Already Created fail", __func__);
goto CREATE_FAIL;
}
if (mDefaultFBFd <= 0) {
if ((mDefaultFBFd = fb_open(DEFAULT_FB)) < 0) {
LOGE("%s:Failed to open default FB", __func__);
return false;
}
}
#ifdef BOARD_USE_V4L2
BufNum = HDMI_FIMC_OUTPUT_BUF_NUM;
#else
BufNum = 1;
#endif
if (mSecFimc.create(SecFimc::DEV_3, SecFimc::MODE_SINGLE_BUF, BufNum) == false) {
LOGE("%s::SecFimc create() fail", __func__);
goto CREATE_FAIL;
}
#if defined(BOARD_USE_V4L2_ION)
IonClient = ion_client_create();
if (IonClient < 0) {
LOGE("%s::ion_client_create() failed", __func__);
goto CREATE_FAIL;
}
#if defined(BOARD_USES_FIMGAPI)
IonFd = ion_alloc(IonClient, g2d_reserved_memory_size * HDMI_G2D_OUTPUT_BUF_NUM, 0, ION_HEAP_EXYNOS_MASK);
if (IonFd < 0) {
LOGE("%s::ION memory allocation failed", __func__);
} else {
ion_base_addr = ion_map(IonFd, ALIGN(g2d_reserved_memory_size * HDMI_G2D_OUTPUT_BUF_NUM, PAGE_SIZE), 0);
if (ion_base_addr == MAP_FAILED)
LOGE("%s::ION mmap failed", __func__);
}
for (int i = 0; i < HDMI_G2D_OUTPUT_BUF_NUM; i++)
g2d_reserved_memory[i] = ion_base_addr + (g2d_reserved_memory_size * i);
#endif
#else
#ifndef BOARD_USE_V4L2
for (int i = 0; i < HDMI_FIMC_OUTPUT_BUF_NUM; i++)
mFimcReservedMem[i].phys.p = mSecFimc.getMemAddr()->phys.p + gralloc_buf_size + (fimc_buf_size * i);
#endif
#if defined(BOARD_USES_FIMGAPI)
#if defined(BOARD_USES_HDMI_SUBTITLES)
for (int i = 0; i < HDMI_G2D_OUTPUT_BUF_NUM; i++)
g2d_reserved_memory[i] = mFimcReservedMem[HDMI_FIMC_OUTPUT_BUF_NUM - 1].phys.p + fimc_buf_size + (g2d_reserved_memory_size * i);
#else
for (int i = 0; i < HDMI_G2D_OUTPUT_BUF_NUM; i++)
g2d_reserved_memory[i] = mSecFimc.getMemAddr()->phys.p + gralloc_buf_size + (g2d_reserved_memory_size * i);
#endif
#endif
#endif
v4l2_std_id std_id;
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("%s::mHdmiOutputMode(%d) \n", __func__, mHdmiOutputMode);
#endif
if (mHdmiOutputMode == COMPOSITE_OUTPUT_MODE) {
std_id = composite_std_2_v4l2_std_id(mCompositeStd);
if ((int)std_id < 0) {
LOGE("%s::composite_std_2_v4l2_std_id(%d) fail\n", __func__, mCompositeStd);
goto CREATE_FAIL;
}
if (m_setCompositeResolution(mCompositeStd) == false) {
LOGE("%s::m_setCompositeResolution(%d) fail\n", __func__, mCompositeStd);
goto CREATE_FAIL;
}
} else if (mHdmiOutputMode >= HDMI_OUTPUT_MODE_YCBCR &&
mHdmiOutputMode <= HDMI_OUTPUT_MODE_DVI) {
#if defined(BOARD_USE_V4L2)
unsigned int preset_id;
if (hdmi_resolution_2_preset_id(mHdmiResolutionValue, &mHdmiDstWidth, &mHdmiDstHeight, &preset_id) < 0) {
LOGE("%s::hdmi_resolution_2_preset_id(%d) fail\n", __func__, mHdmiResolutionValue);
goto CREATE_FAIL;
}
#else
if (hdmi_resolution_2_std_id(mHdmiResolutionValue, &mHdmiDstWidth, &mHdmiDstHeight, &std_id) < 0) {
LOGE("%s::hdmi_resolution_2_std_id(%d) fail\n", __func__, mHdmiResolutionValue);
goto CREATE_FAIL;
}
#endif
}
mFlagCreate = true;
return true;
CREATE_FAIL :
if (mSecFimc.flagCreate() == true &&
mSecFimc.destroy() == false)
LOGE("%s::fimc destory fail", __func__);
return false;
}
bool SecHdmi::destroy(void)
{
#ifdef DEBUG_MSG_ENABLE
LOGD("%s", __func__);
#endif
Mutex::Autolock lock(mLock);
if (mFlagCreate == false) {
LOGE("%s::Already Destroyed fail \n", __func__);
goto DESTROY_FAIL;
}
for (int layer = HDMI_LAYER_BASE + 1; layer <= HDMI_LAYER_GRAPHIC_0; layer++) {
if (mFlagHdmiStart[layer] == true && m_stopHdmi(layer) == false) {
LOGE("%s::m_stopHdmi: layer[%d] fail \n", __func__, layer);
goto DESTROY_FAIL;
}
if (hdmi_deinit_layer(layer) < 0) {
LOGE("%s::hdmi_deinit_layer(%d) fail \n", __func__, layer);
goto DESTROY_FAIL;
}
}
#if !defined(BOARD_USE_V4L2)
tvout_deinit();
#endif
if (mSecFimc.flagCreate() == true && mSecFimc.destroy() == false) {
LOGE("%s::fimc destory fail \n", __func__);
goto DESTROY_FAIL;
}
#ifdef USE_LCD_ADDR_IN_HERE
{
if (0 < mDefaultFBFd) {
close(mDefaultFBFd);
mDefaultFBFd = -1;
}
}
#endif //USE_LCD_ADDR_IN_HERE
#if defined(BOARD_USE_V4L2_ION)
if (mFBaddr != NULL)
ion_unmap((void *)mFBaddr, ALIGN(mFBsize * 4 * 2, PAGE_SIZE));
if (mFBionfd > 0)
ion_free(mFBionfd);
mFBaddr = NULL;
mFBionfd = -1;
mFBsize = 0;
#endif
#if defined(BOARD_USE_V4L2_ION) && defined(BOARD_USES_FIMGAPI)
ion_unmap((void *)g2d_reserved_memory[0], ALIGN(g2d_reserved_memory_size * HDMI_G2D_OUTPUT_BUF_NUM, PAGE_SIZE));
#endif
mFlagCreate = false;
return true;
DESTROY_FAIL :
return false;
}
bool SecHdmi::connect(void)
{
#ifdef DEBUG_MSG_ENABLE
LOGD("%s", __func__);
#endif
{
Mutex::Autolock lock(mLock);
if (mFlagCreate == false) {
LOGE("%s::Not Yet Created \n", __func__);
return false;
}
if (mFlagConnected == true) {
LOGD("%s::Already Connected.. \n", __func__);
return true;
}
if (mHdmiOutputMode >= HDMI_OUTPUT_MODE_YCBCR &&
mHdmiOutputMode <= HDMI_OUTPUT_MODE_DVI) {
if (m_flagHWConnected() == false) {
LOGD("%s::m_flagHWConnected() fail \n", __func__);
return false;
}
#if defined(BOARD_USES_EDID)
if (!EDIDOpen())
LOGE("EDIDInit() failed!\n");
if (!EDIDRead()) {
LOGE("EDIDRead() failed!\n");
if (!EDIDClose())
LOGE("EDIDClose() failed!\n");
}
#endif
#if defined(BOARD_USES_CEC)
if (!(mCECThread->mFlagRunning))
mCECThread->start();
#endif
}
}
if (this->setHdmiOutputMode(mHdmiOutputMode, true) == false)
LOGE("%s::setHdmiOutputMode(%d) fail \n", __func__, mHdmiOutputMode);
if (mHdmiOutputMode >= HDMI_OUTPUT_MODE_YCBCR &&
mHdmiOutputMode <= HDMI_OUTPUT_MODE_DVI) {
if (this->setHdmiResolution(mHdmiResolutionValue, true) == false)
LOGE("%s::setHdmiResolution(%d) fail \n", __func__, mHdmiResolutionValue);
if (this->setHdcpMode(mHdcpMode, false) == false)
LOGE("%s::setHdcpMode(%d) fail \n", __func__, mHdcpMode);
mHdmiInfoChange = true;
mFlagConnected = true;
#if defined(BOARD_USES_EDID)
// show display..
display_menu();
#endif
}
return true;
}
bool SecHdmi::disconnect(void)
{
#ifdef DEBUG_MSG_ENABLE
LOGD("%s", __func__);
#endif
Mutex::Autolock lock(mLock);
if (mFlagCreate == false) {
LOGE("%s::Not Yet Created \n", __func__);
return false;
}
if (mFlagConnected == false) {
LOGE("%s::Already Disconnected.. \n", __func__);
return true;
}
if (mHdmiOutputMode >= HDMI_OUTPUT_MODE_YCBCR &&
mHdmiOutputMode <= HDMI_OUTPUT_MODE_DVI) {
#if defined(BOARD_USES_CEC)
if (mCECThread->mFlagRunning)
mCECThread->stop();
#endif
#if defined(BOARD_USES_EDID)
if (!EDIDClose()) {
LOGE("EDIDClose() failed!\n");
return false;
}
#endif
}
for (int layer = SecHdmi::HDMI_LAYER_BASE + 1; layer <= SecHdmi::HDMI_LAYER_GRAPHIC_0; layer++) {
if (mFlagHdmiStart[layer] == true && m_stopHdmi(layer) == false) {
LOGE("%s::hdmiLayer(%d) layer fail \n", __func__, layer);
return false;
}
}
#if defined(BOARD_USE_V4L2)
for (int layer = HDMI_LAYER_BASE + 1; layer < HDMI_LAYER_MAX; layer++) {
if (hdmi_deinit_layer(layer) < 0)
LOGE("%s::hdmi_deinit_layer(%d) fail", __func__, layer);
}
#else
tvout_deinit();
#endif
mFlagConnected = false;
mHdmiOutputMode = DEFAULT_OUPUT_MODE;
mHdmiResolutionValue = DEFAULT_HDMI_RESOLUTION_VALUE;
#if defined(BOARD_USE_V4L2)
mHdmiPresetId = DEFAULT_HDMI_PRESET_ID;
#else
mHdmiStdId = DEFAULT_HDMI_STD_ID;
#endif
mCompositeStd = DEFAULT_COMPOSITE_STD;
mAudioMode = 2;
mCurrentHdmiOutputMode = -1;
mCurrentHdmiResolutionValue = 0;
mCurrentAudioMode = -1;
mFimcCurrentOutBufIndex = 0;
return true;
}
bool SecHdmi::flagConnected(void)
{
#ifdef DEBUG_MSG_ENABLE
LOGD("%s", __func__);
#endif
Mutex::Autolock lock(mLock);
if (mFlagCreate == false) {
LOGE("%s::Not Yet Created \n", __func__);
return false;
}
return mFlagConnected;
}
bool SecHdmi::flush(int srcW, int srcH, int srcColorFormat,
unsigned int srcYAddr, unsigned int srcCbAddr, unsigned int srcCrAddr,
int dstX, int dstY,
int hdmiLayer,
int num_of_hwc_layer)
{
#ifdef DEBUG_MSG_ENABLE
LOGD("%s [srcW=%d, srcH=%d, srcColorFormat=0x%x, srcYAddr=0x%x, srcCbAddr=0x%x, srcCrAddr=0x%x, dstX=%d, dstY=%d, hdmiLayer=%d]",
__func__, srcW, srcH, srcColorFormat, srcYAddr, srcCbAddr, srcCrAddr, dstX, dstY, hdmiLayer);
#endif
Mutex::Autolock lock(mLock);
if (mFlagCreate == false) {
LOGE("%s::Not Yet Created \n", __func__);
return false;
}
#if defined(BOARD_USE_V4L2)
if (hdmiLayer == HDMI_LAYER_VIDEO) {
mDstWidth[hdmiLayer] = mHdmiDstWidth;
mDstHeight[hdmiLayer] = mHdmiDstHeight;
} else {
if (num_of_hwc_layer == 0) {
struct v4l2_rect rect;
int tempSrcW, tempSrcH;
if (mG2DUIRotVal == 0 || mG2DUIRotVal == 180) {
tempSrcW = srcW;
tempSrcH = srcH;
} else {
tempSrcW = srcH;
tempSrcH = srcW;
}
hdmi_cal_rect(tempSrcW, tempSrcH, mHdmiDstWidth, mHdmiDstHeight, &rect);
mDstWidth[hdmiLayer] = rect.width;
mDstHeight[hdmiLayer] = rect.height;
mDstWidth[HDMI_LAYER_VIDEO] = 0;
mDstHeight[HDMI_LAYER_VIDEO] = 0;
} else {
mDstWidth[hdmiLayer] = mHdmiDstWidth;
mDstHeight[hdmiLayer] = mHdmiDstHeight;
}
}
#ifdef DEBUG_MSG_ENABLE
LOGE("m_reset param(%d, %d, %d, %d)",
mDstWidth[hdmiLayer], mDstHeight[hdmiLayer], \
mPrevDstWidth[hdmiLayer], mPrevDstHeight[hdmiLayer]);
#endif
#endif
if (srcW != mSrcWidth[hdmiLayer] ||
srcH != mSrcHeight[hdmiLayer] ||
srcColorFormat != mSrcColorFormat[hdmiLayer] ||
mHdmiDstWidth != mHdmiResolutionWidth[hdmiLayer] ||
mHdmiDstHeight != mHdmiResolutionHeight[hdmiLayer] ||
#if defined(BOARD_USE_V4L2)
mDstWidth[hdmiLayer] != mPrevDstWidth[hdmiLayer] ||
mDstHeight[hdmiLayer] != mPrevDstHeight[hdmiLayer] ||
#endif
mHdmiInfoChange == true) {
#ifdef DEBUG_MSG_ENABLE
LOGD("m_reset param(%d, %d, %d, %d, %d, %d, %d)",
srcW, mSrcWidth[hdmiLayer], \
srcH, mSrcHeight[hdmiLayer], \
srcColorFormat,mSrcColorFormat[hdmiLayer], \
hdmiLayer);
#endif
if (m_reset(srcW, srcH, srcColorFormat, hdmiLayer, num_of_hwc_layer) == false) {
LOGE("%s::m_reset(%d, %d, %d, %d, %d) fail", __func__, srcW, srcH, srcColorFormat, hdmiLayer, num_of_hwc_layer);
return false;
}
}
if (srcYAddr == 0) {
#if defined(BOARD_USE_V4L2_ION)
unsigned int FB_size = ALIGN(srcW, 16) * ALIGN(srcH, 16) * HDMI_FB_BPP_SIZE;
void *virFBAddr = 0;
struct s3c_fb_user_ion_client ion_handle;
if (mFBaddr != NULL) {
ion_unmap((void *)mFBaddr, ALIGN(mFBsize * 2, PAGE_SIZE));
ion_free(mFBionfd);
}
// get framebuffer virtual address for LCD
if (ioctl(mDefaultFBFd, S3CFB_GET_ION_USER_HANDLE, &ion_handle) < 0) {
LOGE("%s:ioctl(S3CFB_GET_ION_USER_HANDLE) fail", __func__);
return false;
}
virFBAddr = ion_map(ion_handle.fd, ALIGN(FB_size * 2, PAGE_SIZE), 0);
if (virFBAddr == MAP_FAILED) {
LOGE("%s::ion_map fail", __func__);
ion_free(ion_handle.fd);
mFBaddr = NULL;
return false;
}
if ((mFBIndex % 2) == 0)
srcYAddr = (unsigned int)virFBAddr;
else
srcYAddr = (unsigned int)virFBAddr + FB_size;
srcCbAddr = srcYAddr;
mFBIndex++;
mFBaddr = virFBAddr;
mFBsize = FB_size;
mFBionfd = ion_handle.fd;
#else
unsigned int phyFBAddr = 0;
// get physical framebuffer address for LCD
if (ioctl(mDefaultFBFd, S3CFB_GET_FB_PHY_ADDR, &phyFBAddr) == -1) {
LOGE("%s:ioctl(S3CFB_GET_FB_PHY__ADDR) fail", __func__);
return false;
}
/*
* when early suspend, FIMD IP off.
* so physical framebuffer address for LCD is 0x00000000
* so JUST RETURN.
*/
if (phyFBAddr == 0) {
LOGE("%s::S3CFB_GET_FB_PHY_ADDR fail", __func__);
return true;
}
srcYAddr = phyFBAddr;
srcCbAddr = srcYAddr;
#endif
}
if (hdmiLayer == HDMI_LAYER_VIDEO) {
if (srcColorFormat == HAL_PIXEL_FORMAT_YCbCr_420_SP ||
srcColorFormat == HAL_PIXEL_FORMAT_CUSTOM_YCbCr_420_SP) {
#if defined(BOARD_USE_V4L2)
mMixerBuffer[hdmiLayer][0].virt.extP[0] = (char *)srcYAddr;
mMixerBuffer[hdmiLayer][0].virt.extP[1] = (char *)srcCbAddr;
#else
hdmi_set_v_param(hdmiLayer,
srcW, srcH, V4L2_PIX_FMT_NV12,
srcYAddr, srcCbAddr,
mHdmiDstWidth, mHdmiDstHeight);
#endif
} else if (srcColorFormat == HAL_PIXEL_FORMAT_CUSTOM_YCbCr_420_SP_TILED) {
#if defined(BOARD_USE_V4L2)
mMixerBuffer[hdmiLayer][0].virt.extP[0] = (char *)srcYAddr;
mMixerBuffer[hdmiLayer][0].virt.extP[1] = (char *)srcCbAddr;
#else
hdmi_set_v_param(hdmiLayer,
srcW, srcH, V4L2_PIX_FMT_NV12T,
srcYAddr, srcCbAddr,
mHdmiDstWidth, mHdmiDstHeight);
#endif
} else if (srcColorFormat == HAL_PIXEL_FORMAT_YCrCb_420_SP ||
srcColorFormat == HAL_PIXEL_FORMAT_CUSTOM_YCrCb_420_SP) {
#if defined(BOARD_USE_V4L2)
mMixerBuffer[hdmiLayer][0].virt.extP[0] = (char *)srcYAddr;
mMixerBuffer[hdmiLayer][0].virt.extP[1] = (char *)srcCbAddr;
#else
hdmi_set_v_param(hdmiLayer,
srcW, srcH, V4L2_PIX_FMT_NV21,
srcYAddr, srcCbAddr,
mHdmiDstWidth, mHdmiDstHeight);
#endif
} else {
if (mSecFimc.setSrcAddr(srcYAddr, srcCbAddr, srcCrAddr, srcColorFormat) == false) {
LOGE("%s::setSrcAddr(%d, %d, %d) fail",
__func__, srcYAddr, srcCbAddr, srcCrAddr);
return false;
}
int y_size = 0;
if (mUIRotVal == 0 || mUIRotVal == 180)
y_size = ALIGN(ALIGN(srcW,128) * ALIGN(srcH, 32), SZ_8K);
else
y_size = ALIGN(ALIGN(srcH,128) * ALIGN(srcW, 32), SZ_8K);
mHdmiSrcYAddr = mFimcReservedMem[mFimcCurrentOutBufIndex].phys.extP[0];
#ifdef BOARD_USE_V4L2
mHdmiSrcCbCrAddr = mFimcReservedMem[mFimcCurrentOutBufIndex].phys.extP[1];
#else
mHdmiSrcCbCrAddr = mFimcReservedMem[mFimcCurrentOutBufIndex].phys.extP[0] + y_size;
#endif
if (mSecFimc.setDstAddr(mHdmiSrcYAddr, mHdmiSrcCbCrAddr, 0, mFimcCurrentOutBufIndex) == false) {
LOGE("%s::mSecFimc.setDstAddr(%d, %d) fail \n",
__func__, mHdmiSrcYAddr, mHdmiSrcCbCrAddr);
return false;
}
if (mSecFimc.draw(0, mFimcCurrentOutBufIndex) == false) {
LOGE("%s::mSecFimc.draw() fail \n", __func__);
return false;
}
#if defined(BOARD_USE_V4L2)
mMixerBuffer[hdmiLayer][0].virt.extP[0] = (char *)mHdmiSrcYAddr;
mMixerBuffer[hdmiLayer][0].virt.extP[1] = (char *)mHdmiSrcCbCrAddr;
#else
if (mUIRotVal == 0 || mUIRotVal == 180)
hdmi_set_v_param(hdmiLayer,
srcW, srcH, V4L2_PIX_FMT_NV12T,
mHdmiSrcYAddr, mHdmiSrcCbCrAddr,
mHdmiDstWidth, mHdmiDstHeight);
else
hdmi_set_v_param(hdmiLayer,
srcH, srcW, V4L2_PIX_FMT_NV12T,
mHdmiSrcYAddr, mHdmiSrcCbCrAddr,
mHdmiDstWidth, mHdmiDstHeight);
#endif
mFimcCurrentOutBufIndex++;
if (mFimcCurrentOutBufIndex >= HDMI_FIMC_OUTPUT_BUF_NUM)
mFimcCurrentOutBufIndex = 0;
}
} else {
if (srcColorFormat != HAL_PIXEL_FORMAT_BGRA_8888 &&
srcColorFormat != HAL_PIXEL_FORMAT_RGBA_8888 &&
srcColorFormat != HAL_PIXEL_FORMAT_RGB_565) {
if (mSecFimc.setSrcAddr(srcYAddr, srcCbAddr, srcCrAddr, srcColorFormat) == false) {
LOGE("%s::setSrcAddr(%d, %d, %d) fail",
__func__, srcYAddr, srcCbAddr, srcCrAddr);
return false;
}
if (mSecFimc.draw(0, mFimcCurrentOutBufIndex) == false) {
LOGE("%s::mSecFimc.draw() failed", __func__);
return false;
}
#if defined(BOARD_USE_V4L2)
if (hdmi_set_g_scaling(hdmiLayer,
HAL_PIXEL_FORMAT_BGRA_8888,
mDstRect.width, mDstRect.height,
mHdmiSrcYAddr, &mMixerBuffer[hdmiLayer][0],
mDstRect.left , mDstRect.top,
mHdmiDstWidth, mHdmiDstHeight,
mG2DUIRotVal,
num_of_hwc_layer) < 0)
return false;
#else
if (hdmi_gl_set_param(hdmiLayer,
HAL_PIXEL_FORMAT_BGRA_8888,
mDstRect.width, mDstRect.height,
mHdmiSrcYAddr, mHdmiSrcCbCrAddr,
mDstRect.left , mDstRect.top,
mHdmiDstWidth, mHdmiDstHeight,
mG2DUIRotVal) < 0)
#endif
return false;
} else {
#if CHECK_GRAPHIC_LAYER_TIME
nsecs_t start, end;
start = systemTime();
#endif
if (num_of_hwc_layer == 0) { /* UI only mode */
struct v4l2_rect rect;
if (mG2DUIRotVal == 0 || mG2DUIRotVal == 180)
hdmi_cal_rect(srcW, srcH, mHdmiDstWidth, mHdmiDstHeight, &rect);
else
hdmi_cal_rect(srcH, srcW, mHdmiDstWidth, mHdmiDstHeight, &rect);
rect.left = ALIGN(rect.left, 16);
#if defined(BOARD_USE_V4L2)
if (hdmi_set_g_scaling(hdmiLayer,
srcColorFormat,
srcW, srcH,
srcYAddr, &mMixerBuffer[hdmiLayer][0],
rect.left, rect.top,
rect.width, rect.height,
mG2DUIRotVal,
num_of_hwc_layer) < 0)
return false;
#else
if (hdmi_gl_set_param(hdmiLayer,
srcColorFormat,
srcW, srcH,
srcYAddr, srcCbAddr,
rect.left, rect.top,
rect.width, rect.height,
mG2DUIRotVal) < 0)
return false;
#endif
} else { /* Video Playback Mode */
#if defined(BOARD_USE_V4L2)
if (hdmi_set_g_scaling(hdmiLayer,
srcColorFormat,
srcW, srcH,
srcYAddr, &mMixerBuffer[hdmiLayer][0],
dstX, dstY,
mHdmiDstWidth, mHdmiDstHeight,
mG2DUIRotVal,
num_of_hwc_layer) < 0)
return false;
#else
if (hdmi_gl_set_param(hdmiLayer,
srcColorFormat,
srcW, srcH,
srcYAddr, srcCbAddr,
dstX, dstY,
mHdmiDstWidth, mHdmiDstHeight,
mG2DUIRotVal) < 0)
return false;
#endif
}
#if CHECK_GRAPHIC_LAYER_TIME
end = systemTime();
LOGD("[UI] hdmi_gl_set_param[end-start] = %ld ms", long(ns2ms(end)) - long(ns2ms(start)));
#endif
}
}
if (mFlagConnected) {
#if defined(BOARD_USE_V4L2)
unsigned int num_of_plane;
if (hdmi_get_src_plane(srcColorFormat, &num_of_plane) < 0) {
LOGE("%s::hdmi_get_src_plane(%d) fail", __func__, srcColorFormat);
return false;
}
if (mFlagHdmiStart[hdmiLayer] == false && m_startHdmi(hdmiLayer, num_of_plane) == false) {
LOGE("%s::hdmiLayer(%d) fail", __func__, hdmiLayer);
return false;
}
#else
if (mFlagHdmiStart[hdmiLayer] == false && m_startHdmi(hdmiLayer) == false) {
LOGE("%s::hdmiLayer(%d) fail", __func__, hdmiLayer);
return false;
}
#endif
}
return true;
}
bool SecHdmi::clear(int hdmiLayer)
{
#ifdef DEBUG_MSG_ENABLE
LOGD("%s || hdmiLayer = %d", __func__, hdmiLayer);
#endif
Mutex::Autolock lock(mLock);
if (mFlagCreate == false) {
LOGE("%s::Not Yet Created \n", __func__);
return false;
}
if (mFlagHdmiStart[hdmiLayer] == true && m_stopHdmi(hdmiLayer) == false) {
LOGE("%s::m_stopHdmi: layer[%d] fail \n", __func__, hdmiLayer);
return false;
}
return true;
}
bool SecHdmi::setHdmiOutputMode(int hdmiOutputMode, bool forceRun)
{
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("%s::hdmiOutputMode = %d, forceRun = %d", __func__, hdmiOutputMode, forceRun);
#endif
Mutex::Autolock lock(mLock);
if (mFlagCreate == false) {
LOGE("%s::Not Yet Created \n", __func__);
return false;
}
if (forceRun == false && mHdmiOutputMode == hdmiOutputMode) {
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("%s::same hdmiOutputMode(%d) \n", __func__, hdmiOutputMode);
#endif
return true;
}
int newHdmiOutputMode = hdmiOutputMode;
int v4l2OutputType = hdmi_outputmode_2_v4l2_output_type(hdmiOutputMode);
if (v4l2OutputType < 0) {
LOGD("%s::hdmi_outputmode_2_v4l2_output_type(%d) fail\n", __func__, hdmiOutputMode);
return false;
}
#if defined(BOARD_USES_EDID)
int newV4l2OutputType = hdmi_check_output_mode(v4l2OutputType);
if (newV4l2OutputType != v4l2OutputType) {
newHdmiOutputMode = hdmi_v4l2_output_type_2_outputmode(newV4l2OutputType);
if (newHdmiOutputMode < 0) {
LOGD("%s::hdmi_v4l2_output_type_2_outputmode(%d) fail\n", __func__, newV4l2OutputType);
return false;
}
LOGD("%s::calibration mode(%d -> %d)... \n", __func__, hdmiOutputMode, newHdmiOutputMode);
mHdmiInfoChange = true;
}
#endif
if (mHdmiOutputMode != newHdmiOutputMode) {
mHdmiOutputMode = newHdmiOutputMode;
mHdmiInfoChange = true;
}
return true;
}
bool SecHdmi::setHdmiResolution(unsigned int hdmiResolutionValue, bool forceRun)
{
#ifdef DEBUG_MSG_ENABLE
LOGD("%s:: hdmiResolutionValue = %d, forceRun = %d", __func__, hdmiResolutionValue, forceRun);
#endif
Mutex::Autolock lock(mLock);
if (mFlagCreate == false) {
LOGE("%s::Not Yet Created \n", __func__);
return false;
}
if (forceRun == false && mHdmiResolutionValue == hdmiResolutionValue) {
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("%s::same hdmiResolutionValue(%d) \n", __func__, hdmiResolutionValue);
#endif
return true;
}
unsigned int newHdmiResolutionValue = hdmiResolutionValue;
int w = 0;
int h = 0;
#if defined(BOARD_USES_EDID)
// find perfect resolutions..
#if defined(BOARD_USE_V4L2)
unsigned int preset_id;
if (hdmi_resolution_2_preset_id(newHdmiResolutionValue, &w, &h, &preset_id) < 0 ||
hdmi_check_resolution(preset_id) < 0) {
bool flagFoundIndex = false;
int resolutionValueIndex = m_resolutionValueIndex(newHdmiResolutionValue);
for (int i = resolutionValueIndex + 1; i < mHdmiSizeOfResolutionValueList; i++) {
if (hdmi_resolution_2_preset_id(mHdmiResolutionValueList[i], &w, &h, &preset_id) == 0 &&
hdmi_check_resolution(preset_id) == 0) {
newHdmiResolutionValue = mHdmiResolutionValueList[i];
flagFoundIndex = true;
break;
}
}
if (flagFoundIndex == false) {
LOGE("%s::hdmi cannot control this resolution(%d) fail \n", __func__, hdmiResolutionValue);
// Set resolution to 480P
newHdmiResolutionValue = mHdmiResolutionValueList[mHdmiSizeOfResolutionValueList-2];
} else {
LOGD("%s::HDMI resolutions size is calibrated(%d -> %d)..\n", __func__, hdmiResolutionValue, newHdmiResolutionValue);
}
}
#else
v4l2_std_id std_id;
if (hdmi_resolution_2_std_id(newHdmiResolutionValue, &w, &h, &std_id) < 0 ||
hdmi_check_resolution(std_id) < 0) {
bool flagFoundIndex = false;
int resolutionValueIndex = m_resolutionValueIndex(newHdmiResolutionValue);
for (int i = resolutionValueIndex + 1; i < mHdmiSizeOfResolutionValueList; i++) {
if (hdmi_resolution_2_std_id(mHdmiResolutionValueList[i], &w, &h, &std_id) == 0 &&
hdmi_check_resolution(std_id) == 0) {
newHdmiResolutionValue = mHdmiResolutionValueList[i];
flagFoundIndex = true;
break;
}
}
if (flagFoundIndex == false) {
LOGE("%s::hdmi cannot control this resolution(%d) fail \n", __func__, hdmiResolutionValue);
// Set resolution to 480P
newHdmiResolutionValue = mHdmiResolutionValueList[mHdmiSizeOfResolutionValueList-2];
} else {
LOGD("%s::HDMI resolutions size is calibrated(%d -> %d)..\n", __func__, hdmiResolutionValue, newHdmiResolutionValue);
}
}
#endif
else {
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("%s::find resolutions(%d) at once\n", __func__, hdmiResolutionValue);
#endif
}
#endif
if (mHdmiResolutionValue != newHdmiResolutionValue) {
mHdmiResolutionValue = newHdmiResolutionValue;
mHdmiInfoChange = true;
}
return true;
}
bool SecHdmi::setHdcpMode(bool hdcpMode, bool forceRun)
{
#ifdef DEBUG_MSG_ENABLE
LOGD("%s", __func__);
#endif
Mutex::Autolock lock(mLock);
if (mFlagCreate == false) {
LOGE("%s::Not Yet Created \n", __func__);
return false;
}
if (forceRun == false && mHdcpMode == hdcpMode) {
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("%s::same hdcpMode(%d) \n", __func__, hdcpMode);
#endif
return true;
}
mHdcpMode = hdcpMode;
mHdmiInfoChange = true;
return true;
}
bool SecHdmi::setUIRotation(unsigned int rotVal, unsigned int hwcLayer)
{
#ifdef DEBUG_MSG_ENABLE
LOGD("%s", __func__);
#endif
Mutex::Autolock lock(mLock);
if (mFlagCreate == false) {
LOGE("%s::Not Yet Created \n", __func__);
return false;
}
if (rotVal % 90 != 0) {
LOGE("%s::Invalid rotation value(%d)", __func__, rotVal);
return false;
}
/* G2D rotation */
if (rotVal != mG2DUIRotVal) {
mG2DUIRotVal = rotVal;
mHdmiInfoChange = true;
}
/* FIMC rotation */
if (hwcLayer == 0) { /* Rotate in UI only mode */
if (rotVal != mUIRotVal) {
mSecFimc.setRotVal(rotVal);
mUIRotVal = rotVal;
mHdmiInfoChange = true;
}
} else { /* Don't rotate video layer when video is played. */
rotVal = 0;
if (rotVal != mUIRotVal) {
mSecFimc.setRotVal(rotVal);
mUIRotVal = rotVal;
mHdmiInfoChange = true;
}
}
return true;
}
bool SecHdmi::setDisplaySize(int width, int height)
{
mDisplayWidth = width;
mDisplayHeight = height;
return true;
}
bool SecHdmi::m_reset(int w, int h, int colorFormat, int hdmiLayer, int hwcLayer)
{
#ifdef DEBUG_MSG_ENABLE
LOGD("%s", __func__);
#endif
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("### %s called", __func__);
#endif
v4l2_std_id std_id = 0;
mFimcCurrentOutBufIndex = 0;
int srcW = w;
int srcH = h;
#if defined(BOARD_USE_V4L2)
if (mFlagHdmiStart[hdmiLayer] == true && m_stopHdmi(hdmiLayer) == false) {
LOGE("%s::m_stopHdmi: layer[%d] fail", __func__, hdmiLayer);
return false;
}
#else
// stop all..
for (int layer = HDMI_LAYER_BASE + 1; layer < HDMI_LAYER_MAX; layer++) {
if (mFlagHdmiStart[layer] == true && m_stopHdmi(layer) == false) {
LOGE("%s::m_stopHdmi: layer[%d] fail", __func__, layer);
return false;
}
}
#endif
#if defined(BOARD_USE_V4L2)
if (hdmi_deinit_layer(hdmiLayer) < 0)
LOGE("%s::hdmi_deinit_layer(%d) fail", __func__, hdmiLayer);
mHdmiFd[hdmiLayer] = hdmi_init_layer(hdmiLayer);
if (mHdmiFd[hdmiLayer] < 0)
LOGE("%s::hdmi_init_layer(%d) fail", __func__, hdmiLayer);
if (tvout_std_v4l2_init(mHdmiFd[hdmiLayer], mHdmiPresetId) < 0)
LOGE("%s::tvout_std_v4l2_init fail", __func__);
#endif
if (w != mSrcWidth [hdmiLayer] ||
h != mSrcHeight [hdmiLayer] ||
mHdmiDstWidth != mHdmiResolutionWidth[hdmiLayer] ||
mHdmiDstHeight != mHdmiResolutionHeight[hdmiLayer] ||
#if defined(BOARD_USE_V4L2)
mDstWidth[hdmiLayer] != mPrevDstWidth[hdmiLayer] ||
mDstHeight[hdmiLayer] != mPrevDstHeight[hdmiLayer] ||
#endif
colorFormat != mSrcColorFormat[hdmiLayer]) {
int preVideoSrcColorFormat = mSrcColorFormat[hdmiLayer];
int videoSrcColorFormat = colorFormat;
if (preVideoSrcColorFormat != HAL_PIXEL_FORMAT_YCbCr_420_SP &&
preVideoSrcColorFormat != HAL_PIXEL_FORMAT_YCrCb_420_SP &&
preVideoSrcColorFormat != HAL_PIXEL_FORMAT_CUSTOM_YCbCr_420_SP &&
preVideoSrcColorFormat != HAL_PIXEL_FORMAT_CUSTOM_YCrCb_420_SP &&
preVideoSrcColorFormat != HAL_PIXEL_FORMAT_CUSTOM_YCbCr_420_SP_TILED) {
LOGI("%s: Unsupported preVideoSrcColorFormat = 0x%x\n", __func__, preVideoSrcColorFormat);
preVideoSrcColorFormat = HAL_PIXEL_FORMAT_CUSTOM_YCbCr_420_SP_TILED;
}
if (hdmiLayer == HDMI_LAYER_VIDEO) {
if (colorFormat != HAL_PIXEL_FORMAT_YCbCr_420_SP &&
colorFormat != HAL_PIXEL_FORMAT_YCrCb_420_SP &&
colorFormat != HAL_PIXEL_FORMAT_CUSTOM_YCbCr_420_SP &&
colorFormat != HAL_PIXEL_FORMAT_CUSTOM_YCrCb_420_SP &&
colorFormat != HAL_PIXEL_FORMAT_CUSTOM_YCbCr_420_SP_TILED) {
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("### %s call mSecFimc.setSrcParams\n", __func__);
#endif
unsigned int full_wdith = ALIGN(w, 16);
unsigned int full_height = ALIGN(h, 2);
if (mSecFimc.setSrcParams(full_wdith, full_height, 0, 0,
(unsigned int*)&w, (unsigned int*)&h, colorFormat, true) == false) {
LOGE("%s::mSecFimc.setSrcParams(%d, %d, %d) fail \n",
__func__, w, h, colorFormat);
return false;
}
mFimcDstColorFormat = HAL_PIXEL_FORMAT_CUSTOM_YCbCr_420_SP_TILED;
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("### %s call mSecFimc.setDstParams\n", __func__);
#endif
if (mUIRotVal == 0 || mUIRotVal == 180) {
if (mSecFimc.setDstParams((unsigned int)w, (unsigned int)h, 0, 0,
(unsigned int*)&w, (unsigned int*)&h, mFimcDstColorFormat, true) == false) {
LOGE("%s::mSecFimc.setDstParams(%d, %d, %d) fail \n",
__func__, w, h, mFimcDstColorFormat);
return false;
}
#if defined(BOARD_USE_V4L2)
hdmi_set_v_param(mHdmiFd[hdmiLayer], hdmiLayer,
mFimcDstColorFormat, srcW, srcH,
&mMixerBuffer[hdmiLayer][0],
0, 0, mHdmiDstWidth, mHdmiDstHeight);
#endif
} else {
if (mSecFimc.setDstParams((unsigned int)h, (unsigned int)w, 0, 0,
(unsigned int*)&h, (unsigned int*)&w, mFimcDstColorFormat, true) == false) {
LOGE("%s::mSecFimc.setDstParams(%d, %d, %d) fail \n",
__func__, w, h, mFimcDstColorFormat);
return false;
}
#if defined(BOARD_USE_V4L2)
hdmi_set_v_param(mHdmiFd[hdmiLayer], hdmiLayer,
mFimcDstColorFormat, srcH, srcW,
&mMixerBuffer[hdmiLayer][0],
0, 0, mHdmiDstWidth, mHdmiDstHeight);
#endif
}
}
#if defined(BOARD_USE_V4L2)
else {
hdmi_set_v_param(mHdmiFd[hdmiLayer], hdmiLayer,
colorFormat, srcW, srcH,
&mMixerBuffer[hdmiLayer][0],
0, 0, mHdmiDstWidth, mHdmiDstHeight);
}
#endif
mPrevDstWidth[hdmiLayer] = mHdmiDstWidth;
mPrevDstHeight[hdmiLayer] = mHdmiDstHeight;
} else {
#if defined(BOARD_USE_V4L2)
struct v4l2_rect rect;
int tempSrcW, tempSrcH;
if (mG2DUIRotVal == 0 || mG2DUIRotVal == 180) {
tempSrcW = srcW;
tempSrcH = srcH;
} else {
tempSrcW = srcH;
tempSrcH = srcW;
}
hdmi_cal_rect(tempSrcW, tempSrcH, mHdmiDstWidth, mHdmiDstHeight, &rect);
rect.left = ALIGN(rect.left, 16);
if (hwcLayer == 0) { /* UI only mode */
hdmi_set_g_param(mHdmiFd[hdmiLayer], hdmiLayer,
colorFormat, srcW, srcH,
&mMixerBuffer[hdmiLayer][0],
rect.left, rect.top, rect.width, rect.height);
mPrevDstWidth[hdmiLayer] = rect.width;
mPrevDstHeight[hdmiLayer] = rect.height;
mPrevDstWidth[HDMI_LAYER_VIDEO] = 0;
mPrevDstHeight[HDMI_LAYER_VIDEO] = 0;
} else { /* Video Playback + UI Mode */
hdmi_set_g_param(mHdmiFd[hdmiLayer], hdmiLayer,
colorFormat, srcW, srcH,
&mMixerBuffer[hdmiLayer][0],
0, 0, mHdmiDstWidth, mHdmiDstHeight);
mPrevDstWidth[hdmiLayer] = mHdmiDstWidth;
mPrevDstHeight[hdmiLayer] = mHdmiDstHeight;
}
#endif
}
if (preVideoSrcColorFormat != videoSrcColorFormat)
mHdmiInfoChange = true;
mSrcWidth[hdmiLayer] = srcW;
mSrcHeight[hdmiLayer] = srcH;
mSrcColorFormat[hdmiLayer] = colorFormat;
mHdmiResolutionWidth[hdmiLayer] = mHdmiDstWidth;
mHdmiResolutionHeight[hdmiLayer] = mHdmiDstHeight;
#ifdef DEBUG_MSG_ENABLE
LOGD("m_reset saved param(%d, %d, %d, %d, %d, %d, %d) \n",
srcW, mSrcWidth[hdmiLayer], \
srcH, mSrcHeight[hdmiLayer], \
colorFormat,mSrcColorFormat[hdmiLayer], \
hdmiLayer);
#endif
}
if (mHdmiInfoChange == true) {
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("mHdmiInfoChange: %d\n", mHdmiInfoChange);
#endif
// stop all..
#if defined(BOARD_USES_CEC)
if (mHdmiOutputMode >= HDMI_OUTPUT_MODE_YCBCR &&
mHdmiOutputMode <= HDMI_OUTPUT_MODE_DVI) {
if (mCECThread->mFlagRunning)
mCECThread->stop();
}
#endif
if (m_setHdmiOutputMode(mHdmiOutputMode) == false) {
LOGE("%s::m_setHdmiOutputMode() fail \n", __func__);
return false;
}
if (mHdmiOutputMode == COMPOSITE_OUTPUT_MODE) {
std_id = composite_std_2_v4l2_std_id(mCompositeStd);
if ((int)std_id < 0) {
LOGE("%s::composite_std_2_v4l2_std_id(%d) fail\n", __func__, mCompositeStd);
return false;
}
if (m_setCompositeResolution(mCompositeStd) == false) {
LOGE("%s::m_setCompositeRsolution() fail \n", __func__);
return false;
}
} else if (mHdmiOutputMode >= HDMI_OUTPUT_MODE_YCBCR &&
mHdmiOutputMode <= HDMI_OUTPUT_MODE_DVI) {
if (m_setHdmiResolution(mHdmiResolutionValue) == false) {
LOGE("%s::m_setHdmiResolution() fail \n", __func__);
return false;
}
if (m_setHdcpMode(mHdcpMode) == false) {
LOGE("%s::m_setHdcpMode() fail \n", __func__);
return false;
}
#if !defined(BOARD_USE_V4L2)
std_id = mHdmiStdId;
#endif
}
#if !defined(BOARD_USE_V4L2)
fp_tvout = tvout_init(std_id);
for (int layer = HDMI_LAYER_BASE + 1; layer < HDMI_LAYER_MAX; layer++) {
if (hdmi_deinit_layer(layer) < 0)
LOGE("%s::hdmi_init_layer(%d) fail \n", __func__, layer);
}
for (int layer = HDMI_LAYER_BASE + 1; layer < HDMI_LAYER_MAX; layer++) {
if (hdmi_init_layer(layer) < 0)
LOGE("%s::hdmi_init_layer(%d) fail \n", __func__, layer);
}
#endif
if (mHdmiOutputMode >= HDMI_OUTPUT_MODE_YCBCR &&
mHdmiOutputMode <= HDMI_OUTPUT_MODE_DVI) {
#if defined(BOARD_USES_CEC)
if (!(mCECThread->mFlagRunning))
mCECThread->start();
#endif
if (m_setAudioMode(mAudioMode) == false)
LOGE("%s::m_setAudioMode() fail \n", __func__);
}
mHdmiInfoChange = false;
#ifdef BOARD_USE_V4L2
for (int i = 0; i < HDMI_FIMC_OUTPUT_BUF_NUM; i++)
mFimcReservedMem[i] = *(mSecFimc.getMemAddr(i));
#endif
}
return true;
}
#if defined(BOARD_USE_V4L2)
bool SecHdmi::m_startHdmi(int hdmiLayer, unsigned int num_of_plane)
{
#ifdef DEBUG_MSG_ENABLE
LOGD("%s", __func__);
#endif
bool ret = true;
int buf_index = 0;
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("### %s: hdmiLayer(%d) called\n", __func__, hdmiLayer);
#endif
if (mFlagLayerEnable[hdmiLayer]) {
static unsigned int index = 0;
if (mFlagHdmiStart[hdmiLayer] == false) {
index = 0;
if (tvout_std_v4l2_qbuf(mHdmiFd[hdmiLayer], V4L2_BUF_TYPE_VIDEO_OUTPUT_MPLANE, V4L2_MEMORY_USERPTR,
index, num_of_plane, &mMixerBuffer[hdmiLayer][0]) < 0) {
LOGE("%s::tvout_std_v4l2_qbuf(index : %d) (mSrcBufNum : %d) failed", __func__, index, HDMI_NUM_MIXER_BUF);
return false;
}
index++;
if (tvout_std_v4l2_streamon(mHdmiFd[hdmiLayer], V4L2_BUF_TYPE_VIDEO_OUTPUT_MPLANE) < 0) {
LOGE("%s::tvout_std_v4l2_streamon() failed", __func__);
return false;
}
mFlagHdmiStart[hdmiLayer] = true;
} else {
if (tvout_std_v4l2_qbuf(mHdmiFd[hdmiLayer], V4L2_BUF_TYPE_VIDEO_OUTPUT_MPLANE, V4L2_MEMORY_USERPTR,
index, num_of_plane, &mMixerBuffer[hdmiLayer][0]) < 0) {
LOGE("%s::tvout_std_v4l2_qbuf() failed", __func__);
return false;
}
if (tvout_std_v4l2_dqbuf(mHdmiFd[hdmiLayer], V4L2_BUF_TYPE_VIDEO_OUTPUT_MPLANE, V4L2_MEMORY_USERPTR, &buf_index, num_of_plane) < 0) {
LOGE("%s::tvout_std_v4l2_dqbuf() failed", __func__);
return false;
}
index = buf_index;
}
}
return true;
}
#else
bool SecHdmi::m_startHdmi(int hdmiLayer)
{
#ifdef DEBUG_MSG_ENABLE
LOGD("%s", __func__);
#endif
bool ret = true;
int buf_index = 0;
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("### %s: hdmiLayer(%d) called\n", __func__, hdmiLayer);
#endif
switch (hdmiLayer) {
case HDMI_LAYER_VIDEO:
tvout_v4l2_start_overlay(fp_tvout_v);
mFlagHdmiStart[hdmiLayer] = true;
break;
case HDMI_LAYER_GRAPHIC_0 :
if (mFlagLayerEnable[hdmiLayer]) {
if (ioctl(fp_tvout_g0, FBIOBLANK, (void *)FB_BLANK_UNBLANK) != -1)
mFlagHdmiStart[hdmiLayer] = true;
}
break;
case HDMI_LAYER_GRAPHIC_1 :
if (mFlagLayerEnable[hdmiLayer]) {
if (ioctl(fp_tvout_g1, FBIOBLANK, (void *)FB_BLANK_UNBLANK) != -1)
mFlagHdmiStart[hdmiLayer] = true;
}
break;
default :
LOGE("%s::unmathced layer(%d) fail", __func__, hdmiLayer);
ret = false;
break;
}
return true;
}
#endif
bool SecHdmi::m_stopHdmi(int hdmiLayer)
{
#ifdef DEBUG_MSG_ENABLE
LOGD("%s", __func__);
#endif
bool ret = true;
if (mFlagHdmiStart[hdmiLayer] == false) {
LOGD("%s::already HDMI(%d layer) stopped.. \n", __func__, hdmiLayer);
return true;
}
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("### %s : layer[%d] called\n", __func__, hdmiLayer);
#endif
#if defined(BOARD_USE_V4L2)
int fd;
switch (hdmiLayer) {
case HDMI_LAYER_VIDEO:
break;
case HDMI_LAYER_GRAPHIC_0 :
break;
case HDMI_LAYER_GRAPHIC_1 :
#if defined(BOARD_USES_FIMGAPI)
cur_g2d_address = 0;
g2d_buf_index = 0;
#endif
break;
default :
LOGE("%s::unmathced layer(%d) fail", __func__, hdmiLayer);
ret = false;
break;
}
if (mFlagLayerEnable[hdmiLayer]) {
if (tvout_std_v4l2_streamoff(mHdmiFd[hdmiLayer], V4L2_BUF_TYPE_VIDEO_OUTPUT_MPLANE) < 0) {
LOGE("%s::tvout_std_v4l2_streamon layer(%d) failed", __func__, hdmiLayer);
return false;
}
/* clear buffer */
if (tvout_std_v4l2_reqbuf(mHdmiFd[hdmiLayer], V4L2_BUF_TYPE_VIDEO_OUTPUT_MPLANE, V4L2_MEMORY_USERPTR, 0) < 0) {
LOGE("%s::tvout_std_v4l2_reqbuf(buf_num=%d)[graphic layer] failed", __func__, 0);
return -1;
}
mFlagHdmiStart[hdmiLayer] = false;
}
#else
switch (hdmiLayer) {
case HDMI_LAYER_VIDEO:
tvout_v4l2_stop_overlay(fp_tvout_v);
mFlagHdmiStart[hdmiLayer] = false;
break;
case HDMI_LAYER_GRAPHIC_0 :
if (mFlagLayerEnable[hdmiLayer]) {
if (ioctl(fp_tvout_g0, FBIOBLANK, (void *)FB_BLANK_POWERDOWN) != -1)
mFlagHdmiStart[hdmiLayer] = false;
}
break;
case HDMI_LAYER_GRAPHIC_1 :
#if defined(BOARD_USES_FIMGAPI)
cur_g2d_address = 0;
g2d_buf_index = 0;
#endif
if (mFlagLayerEnable[hdmiLayer]) {
if (ioctl(fp_tvout_g1, FBIOBLANK, (void *)FB_BLANK_POWERDOWN) != -1)
mFlagHdmiStart[hdmiLayer] = false;
}
break;
default :
LOGE("%s::unmathced layer(%d) fail", __func__, hdmiLayer);
ret = false;
break;
}
#endif
return true;
}
bool SecHdmi::m_setHdmiOutputMode(int hdmiOutputMode)
{
#ifdef DEBUG_MSG_ENABLE
LOGD("%s", __func__);
#endif
if (hdmiOutputMode == mCurrentHdmiOutputMode) {
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("%s::same hdmiOutputMode(%d) \n", __func__, hdmiOutputMode);
#endif
return true;
}
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("### %s called\n", __func__);
#endif
int v4l2OutputType = hdmi_outputmode_2_v4l2_output_type(hdmiOutputMode);
if (v4l2OutputType < 0) {
LOGE("%s::hdmi_outputmode_2_v4l2_output_type(%d) fail\n", __func__, hdmiOutputMode);
return false;
}
output_type = v4l2OutputType;
mCurrentHdmiOutputMode = hdmiOutputMode;
return true;
}
bool SecHdmi::m_setCompositeResolution(unsigned int compositeStdId)
{
#ifdef DEBUG_MSG_ENABLE
LOGD("%s", __func__);
#endif
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("### %s called\n", __func__);
#endif
int w = 0;
int h = 0;
if (mHdmiOutputMode != COMPOSITE_OUTPUT_MODE) {
LOGE("%s:: not supported output type \n", __func__);
return false;
}
switch (compositeStdId) {
case COMPOSITE_STD_NTSC_M:
case COMPOSITE_STD_NTSC_443:
w = 704;
h = 480;
break;
case COMPOSITE_STD_PAL_BDGHI:
case COMPOSITE_STD_PAL_M:
case COMPOSITE_STD_PAL_N:
case COMPOSITE_STD_PAL_Nc:
case COMPOSITE_STD_PAL_60:
w = 704;
h = 576;
break;
default:
LOGE("%s::unmathced composite_std(%d)", __func__, compositeStdId);
return false;
}
t_std_id = composite_std_2_v4l2_std_id(mCompositeStd);
mHdmiDstWidth = w;
mHdmiDstHeight = h;
mCurrentHdmiResolutionValue = -1;
return true;
}
bool SecHdmi::m_setHdmiResolution(unsigned int hdmiResolutionValue)
{
#ifdef DEBUG_MSG_ENABLE
LOGD("%s", __func__);
#endif
if (hdmiResolutionValue == mCurrentHdmiResolutionValue) {
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("%s::same hdmiResolutionValue(%d) \n", __func__, hdmiResolutionValue);
#endif
return true;
}
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("### %s called\n", __func__);
#endif
int w = 0;
int h = 0;
#if defined(BOARD_USE_V4L2)
unsigned int preset_id;
#else
v4l2_std_id std_id;
#endif
if (mHdmiOutputMode >= HDMI_OUTPUT_MODE_YCBCR &&
mHdmiOutputMode <= HDMI_OUTPUT_MODE_DVI) {
#if defined(BOARD_USE_V4L2)
if (hdmi_resolution_2_preset_id(hdmiResolutionValue, &w, &h, &preset_id) < 0) {
LOGE("%s::hdmi_resolution_2_std_id(%d) fail\n", __func__, hdmiResolutionValue);
return false;
}
mHdmiPresetId = preset_id;
#else
if (hdmi_resolution_2_std_id(hdmiResolutionValue, &w, &h, &std_id) < 0) {
LOGE("%s::hdmi_resolution_2_std_id(%d) fail\n", __func__, hdmiResolutionValue);
return false;
}
mHdmiStdId = std_id;
#endif
} else {
LOGE("%s:: not supported output type \n", __func__);
return false;
}
#if defined(BOARD_USE_V4L2)
g_preset_id = preset_id;
#else
t_std_id = std_id;
#endif
mHdmiDstWidth = w;
mHdmiDstHeight = h;
mCurrentHdmiResolutionValue = hdmiResolutionValue;
#ifdef DEBUG_HDMI_HW_LEVEL
#if defined(BOARD_USE_V4L2)
LOGD("%s:: mHdmiDstWidth = %d, mHdmiDstHeight = %d, mHdmiPresetId = 0x%x, hdmiResolutionValue = 0x%x\n",
__func__,
mHdmiDstWidth,
mHdmiDstHeight,
mHdmiPresetId,
hdmiResolutionValue);
#else
LOGD("%s:: mHdmiDstWidth = %d, mHdmiDstHeight = %d, mHdmiStdId = 0x%x, hdmiResolutionValue = 0x%x\n",
__func__,
mHdmiDstWidth,
mHdmiDstHeight,
mHdmiStdId,
hdmiResolutionValue);
#endif
#endif
return true;
}
bool SecHdmi::m_setHdcpMode(bool hdcpMode)
{
#ifdef DEBUG_MSG_ENABLE
LOGD("%s", __func__);
#endif
if (hdcpMode == mCurrentHdcpMode) {
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("%s::same hdcpMode(%d) \n", __func__, hdcpMode);
#endif
return true;
}
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("### %s called\n", __func__);
#endif
if (hdcpMode == true)
g_hdcp_en = 1;
else
g_hdcp_en = 0;
mCurrentHdcpMode = hdcpMode;
return true;
}
bool SecHdmi::m_setAudioMode(int audioMode)
{
#ifdef DEBUG_MSG_ENABLE
LOGD("%s", __func__);
#endif
if (audioMode == mCurrentAudioMode) {
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("%s::same audioMode(%d) \n", __func__, audioMode);
#endif
return true;
}
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("### %s called\n", __func__);
#endif
if (hdmi_check_audio() < 0) {
LOGE("%s::hdmi_check_audio() fail \n", __func__);
return false;
}
mCurrentAudioMode = audioMode;
return true;
}
int SecHdmi::m_resolutionValueIndex(unsigned int ResolutionValue)
{
#ifdef DEBUG_MSG_ENABLE
LOGD("%s", __func__);
#endif
int index = -1;
for (int i = 0; i < mHdmiSizeOfResolutionValueList; i++) {
if (mHdmiResolutionValueList[i] == ResolutionValue) {
index = i;
break;
}
}
return index;
}
bool SecHdmi::m_flagHWConnected(void)
{
#ifdef DEBUG_MSG_ENABLE
LOGD("%s", __func__);
#endif
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("### %s called\n", __func__);
#endif
bool ret = true;
int hdmiStatus = hdmi_cable_status();
if (hdmiStatus <= 0) {
#ifdef DEBUG_HDMI_HW_LEVEL
LOGD("%s::hdmi_cable_status() fail \n", __func__);
#endif
ret = false;
} else {
ret = true;
}
return ret;
}
}; // namespace android