int edid_Initialize(u16 baseAddr, u16 sfrClock)
{
#ifdef CONFIG_HDMI_JZ4780_DEBUG
printk("hdmi %s: sfrClock = %u\n", __func__, sfrClock);
#endif
LOG_TRACE2(baseAddr, sfrClock);
/* mask interrupts */
halEdid_MaskInterrupts(baseAddr + I2CM_BASE_ADDR, TRUE);
edid_Reset(baseAddr);
/* set clock division */
halEdid_MasterClockDivision(baseAddr + I2CM_BASE_ADDR, 0x05);
halEdid_FastSpeedHighCounter(baseAddr + I2CM_BASE_ADDR, edid_i2c_count(sfrClock, I2C_MIN_FS_SCL_HIGH_TIME ));
halEdid_FastSpeedLowCounter(baseAddr + I2CM_BASE_ADDR, edid_i2c_count(sfrClock, I2C_MIN_FS_SCL_LOW_TIME));
halEdid_StandardSpeedLowCounter(baseAddr + I2CM_BASE_ADDR,edid_i2c_count(sfrClock, I2C_MIN_SS_SCL_LOW_TIME));
halEdid_StandardSpeedHighCounter(baseAddr + I2CM_BASE_ADDR, edid_i2c_count(sfrClock, I2C_MIN_SS_SCL_HIGH_TIME));
/* set address to EDID address -see spec */
halEdid_SlaveAddress(baseAddr + I2CM_BASE_ADDR, 0x50); /* HW deals with LSB (alternating the address between 0xA0 & 0xA1) */
halEdid_SegmentAddr(baseAddr + I2CM_BASE_ADDR, 0x30); /* HW deals with LSB (making the segment address go to 60) */
/* start reading E-EDID */
edid_mStatus = EDID_READING;
LOG_NOTICE("reading EDID");
halEdid_MaskInterrupts(baseAddr + I2CM_BASE_ADDR, FALSE); /* enable interrupts */
edid_ReadRequest(baseAddr, 0, 0);
return TRUE;
}
VOID Task_Start(Task *pThis)
{
LOG_TRACE2("\ninside Task_Start name: %d, Handle:%d .",pThis->hPriority,pThis->Handle);
//TSK_setpri(pThis->Handle, pThis->hPriority);
Task_setPri(pThis->Handle, pThis->hPriority);
LOG_TRACE0("\n After Task_setpri");
}
void halFrameComposerAudio_UserLeft(u16 baseAddr, u8 bit, unsigned channel)
{
LOG_TRACE2(bit, channel);
if (channel < 4)
access_CoreWrite(bit, baseAddr + FC_AUDSU, channel, 1);
else
LOG_ERROR2("invalid channel number: ", channel);
}
void halFrameComposerAudio_ValidityRight(u16 baseAddr, u8 bit, unsigned channel)
{
LOG_TRACE2(bit, channel);
if (channel < 4)
access_CoreWrite(bit, baseAddr + FC_AUDSV, 4 + channel, 1);
else
LOG_ERROR("invalid channel number");
}
void halFrameComposerAudio_IecChannelLeft(u16 baseAddr, u8 value,
unsigned channel)
{
LOG_TRACE2(value, channel);
if (channel == 0)
access_CoreWrite(value, baseAddr + FC_AUDSCHNLS5, 0, 4);
else if (channel == 1)
access_CoreWrite(value, baseAddr + FC_AUDSCHNLS5, 4, 4);
else if (channel == 2)
access_CoreWrite(value, baseAddr + FC_AUDSCHNLS6, 0, 4);
else if (channel == 3)
access_CoreWrite(value, baseAddr + FC_AUDSCHNLS6, 4, 4);
else
LOG_ERROR2("invalid channel number: ", channel);
}
int edid_ReadRequest(u16 baseAddr, u8 address, u8 blockNo)
{
/*to incorporate extensions we have to include the following - see VESA E-DDC spec. P 11 */
u8 sPointer = blockNo / 2;
u8 edidAddress = ((blockNo % 2) * 0x80) + address;
LOG_TRACE2(sPointer, edidAddress);
halEdid_RequestAddr(baseAddr + I2CM_BASE_ADDR, edidAddress);
halEdid_SegmentPointer(baseAddr + I2CM_BASE_ADDR, sPointer);
if (sPointer == 0)
{
halEdid_RequestRead(baseAddr + I2CM_BASE_ADDR);
}
else
{
halEdid_RequestExtRead(baseAddr + I2CM_BASE_ADDR);
}
return TRUE;
}
void halSourcePhy_InterruptPolarity(u16 baseAddr, u8 bitShift, u8 value)
{
LOG_TRACE2(bitShift, value);
access_CoreWrite(value, (baseAddr + PHY_POL0), bitShift, 1);
}
u8 edid_EventHandler(u16 baseAddr, int hpd, u8 state)
{
LOG_TRACE2(hpd, state);
if (edid_mStatus != EDID_READING)
{
return EDID_IDLE;
}
else if (!hpd)
{ /* hot plug detected without cable disconnection */
error_Set(ERR_HPD_LOST);
LOG_WARNING("hpd");
edid_mStatus = EDID_ERROR;
}
else if ((state & BIT(0)) != 0) /* error */
{
LOG_WARNING("error");
edid_mStatus = EDID_ERROR;
}
else if ((state & BIT(1)) != 0) /* done */
{
if (edid_mCurrAddress >= sizeof(edid_mBuffer))
{
error_Set(ERR_OVERFLOW);
LOG_WARNING("overflow");
edid_mStatus = EDID_ERROR;
}
else
{
edid_mBuffer[edid_mCurrAddress] = halEdid_ReadData(baseAddr
+ I2CM_BASE_ADDR);
edid_mBlockSum += edid_mBuffer[edid_mCurrAddress++];
if (edid_mCurrAddress >= sizeof(edid_mBuffer))
{
/*check if checksum is correct (CEA-861 D Spec p108) */
if (edid_mBlockSum % 0x100 == 0)
{
LOG_NOTICE("block checksum correct");
edid_ParseBlock(baseAddr, edid_mBuffer);
edid_mCurrAddress = 0;
edid_mCurrBlockNo++;
edid_mBlockSum = 0;
if (edid_mCurrBlockNo >= edid_mBlocksNo)
{
edid_mStatus = EDID_DONE;
}
}
else
{
error_Set(ERR_BLOCK_CHECKSUM_INVALID);
LOG_WARNING("block checksum invalid");
edid_mStatus = EDID_ERROR;
}
}
}
}
if (edid_mStatus == EDID_READING)
{
edid_ReadRequest(baseAddr, edid_mCurrAddress, edid_mCurrBlockNo);
}
else if (edid_mStatus == EDID_DONE)
{
edid_mBlocksNo = 1;
edid_mCurrBlockNo = 0;
edid_mCurrAddress = 0;
edid_mBlockSum = 0;
}
return edid_mStatus;
}
void halAudioGenerator_ChannelSelect(IM_UINT16 baseAddress, IM_UINT8 enable, IM_UINT8 channel)
{
LOG_TRACE2(channel, enable);
access_CoreWrite(enable, baseAddress + AG_GPA_CONF1, channel, 1);
}
