/*============================================================================*/
/**
-* \brief Maximum u32_t value.
+* \brief Maximum u32 value.
*/
#ifndef MAX_U32
-#define MAX_U32 ((u32_t) (0xFFFFFFFFL))
+#define MAX_U32 ((u32) (0xFFFFFFFFL))
#endif
/* Customer configurable hardware settings, etc */
*/
#ifndef DRXJ_UCODE_MAGIC_WORD
-#define DRXJ_UCODE_MAGIC_WORD ((((u16_t)'H')<<8)+((u16_t)'L'))
+#define DRXJ_UCODE_MAGIC_WORD ((((u16)'H')<<8)+((u16)'L'))
#endif
/**
#define DUMMY_READ() \
do{ \
- u16_t dummy; \
+ u16 dummy; \
RR16( demod->myI2CDevAddr, SCU_RAM_VERSION_HI__A, &dummy ); \
} while (0)
* The macro takes care of the required byte order in a 16 bits word.
* x -> lowbyte(x), highbyte(x)
*/
-#define DRXJ_16TO8( x ) ((u8_t) (((u16_t)x) &0xFF)), \
- ((u8_t)((((u16_t)x)>>8)&0xFF))
+#define DRXJ_16TO8( x ) ((u8) (((u16)x) &0xFF)), \
+ ((u8)((((u16)x)>>8)&0xFF))
/**
* This macro is used to convert byte array to 16 bit register value for block read.
* Block read speed up I2C traffic between host and demod.
* The macro takes care of the required byte order in a 16 bits word.
*/
-#define DRXJ_8TO16( x ) ((u16_t) (x[0] | (x[1] << 8)))
+#define DRXJ_8TO16( x ) ((u16) (x[0] | (x[1] << 8)))
/*============================================================================*/
/*=== MISC DEFINES ===========================================================*/
static DRXStatus_t DRXJ_DAP_ReadBlock(struct i2c_device_addr *devAddr,
DRXaddr_t addr,
- u16_t datasize,
- pu8_t data, DRXflags_t flags);
+ u16 datasize,
+ u8 *data, DRXflags_t flags);
static DRXStatus_t DRXJ_DAP_ReadModifyWriteReg8(struct i2c_device_addr *devAddr,
DRXaddr_t waddr,
DRXaddr_t raddr,
- u8_t wdata, pu8_t rdata);
+ u8 wdata, u8 *rdata);
static DRXStatus_t DRXJ_DAP_ReadModifyWriteReg16(struct i2c_device_addr *devAddr,
DRXaddr_t waddr,
DRXaddr_t raddr,
- u16_t wdata, pu16_t rdata);
+ u16 wdata, u16 *rdata);
static DRXStatus_t DRXJ_DAP_ReadModifyWriteReg32(struct i2c_device_addr *devAddr,
DRXaddr_t waddr,
DRXaddr_t raddr,
- u32_t wdata, pu32_t rdata);
+ u32 wdata, u32 *rdata);
static DRXStatus_t DRXJ_DAP_ReadReg8(struct i2c_device_addr *devAddr,
DRXaddr_t addr,
- pu8_t data, DRXflags_t flags);
+ u8 *data, DRXflags_t flags);
static DRXStatus_t DRXJ_DAP_ReadReg16(struct i2c_device_addr *devAddr,
DRXaddr_t addr,
- pu16_t data, DRXflags_t flags);
+ u16 *data, DRXflags_t flags);
static DRXStatus_t DRXJ_DAP_ReadReg32(struct i2c_device_addr *devAddr,
DRXaddr_t addr,
- pu32_t data, DRXflags_t flags);
+ u32 *data, DRXflags_t flags);
static DRXStatus_t DRXJ_DAP_WriteBlock(struct i2c_device_addr *devAddr,
DRXaddr_t addr,
- u16_t datasize,
- pu8_t data, DRXflags_t flags);
+ u16 datasize,
+ u8 *data, DRXflags_t flags);
static DRXStatus_t DRXJ_DAP_WriteReg8(struct i2c_device_addr *devAddr,
DRXaddr_t addr,
- u8_t data, DRXflags_t flags);
+ u8 data, DRXflags_t flags);
static DRXStatus_t DRXJ_DAP_WriteReg16(struct i2c_device_addr *devAddr,
DRXaddr_t addr,
- u16_t data, DRXflags_t flags);
+ u16 data, DRXflags_t flags);
static DRXStatus_t DRXJ_DAP_WriteReg32(struct i2c_device_addr *devAddr,
DRXaddr_t addr,
- u32_t data, DRXflags_t flags);
+ u32 data, DRXflags_t flags);
/* The version structure of this protocol implementation */
char drxDapDRXJModuleName[] = "DRXJ Data Access Protocol";
/* TRUE, * flagASDRequest */
/* FALSE, * flagHDevClear */
/* FALSE, * flagHDevSet */
-/* (u16_t) 0xFFF, * rdsLastCount */
+/* (u16) 0xFFF, * rdsLastCount */
/*#ifdef DRXJ_SPLIT_UCODE_UPLOAD
FALSE, * flagAudMcUploaded */
* \brief Default common attributes of a drxj demodulator instance.
*/
DRXCommonAttr_t DRXJDefaultCommAttr_g = {
- (pu8_t) NULL, /* ucode ptr */
+ (u8 *) NULL, /* ucode ptr */
0, /* ucode size */
TRUE, /* ucode verify switch */
{0}, /* version record */
STRUCTURES
----------------------------------------------------------------------------*/
typedef struct {
- u16_t eqMSE;
- u8_t eqMode;
- u8_t eqCtrl;
- u8_t eqStat;
+ u16 eqMSE;
+ u8 eqMode;
+ u8 eqCtrl;
+ u8 eqStat;
} DRXJEQStat_t, *pDRXJEQStat_t;
/* HI command */
typedef struct {
- u16_t cmd;
- u16_t param1;
- u16_t param2;
- u16_t param3;
- u16_t param4;
- u16_t param5;
- u16_t param6;
+ u16 cmd;
+ u16 param1;
+ u16 param2;
+ u16 param3;
+ u16 param4;
+ u16 param5;
+ u16 param6;
} DRXJHiCmd_t, *pDRXJHiCmd_t;
#ifdef DRXJ_SPLIT_UCODE_UPLOAD
/*============================================================================*/
typedef struct {
- u32_t addr;
- u16_t size;
- u16_t flags; /* bit[15..2]=reserved,
+ u32 addr;
+ u16 size;
+ u16 flags; /* bit[15..2]=reserved,
bit[1]= compression on/off
bit[0]= CRC on/off */
- u16_t CRC;
+ u16 CRC;
} DRXUCodeBlockHdr_t, *pDRXUCodeBlockHdr_t;
#endif /* DRXJ_SPLIT_UCODE_UPLOAD */
/* Some prototypes */
static DRXStatus_t
HICommand(struct i2c_device_addr *devAddr,
- const pDRXJHiCmd_t cmd, pu16_t result);
+ const pDRXJHiCmd_t cmd, u16 *result);
static DRXStatus_t
CtrlLockStatus(pDRXDemodInstance_t demod, pDRXLockStatus_t lockStat);
/*============================================================================*/
/**
-* \fn void Mult32(u32_t a, u32_t b, pu32_t h, pu32_t l)
+* \fn void Mult32(u32 a, u32 b, u32 *h, u32 *l)
* \brief 32bitsx32bits signed multiplication
* \param a 32 bits multiplicant, typecast from signed to unisgned
* \param b 32 bits multiplier, typecast from signed to unisgned
*
*/
-#define DRX_IS_BOOTH_NEGATIVE(__a) (((__a) & (1 << (sizeof (u32_t) * 8 - 1))) != 0)
+#define DRX_IS_BOOTH_NEGATIVE(__a) (((__a) & (1 << (sizeof (u32) * 8 - 1))) != 0)
-static void Mult32(u32_t a, u32_t b, pu32_t h, pu32_t l)
+static void Mult32(u32 a, u32 b, u32 *h, u32 *l)
{
unsigned int i;
*h = *l = 0;
case 4:
*l -= b;
*h = *h - !DRX_IS_BOOTH_NEGATIVE(b) + !b + (*l <
- ((u32_t)
+ ((u32)
(-
- ((s32_t)
+ ((s32)
b))));
case 5:
case 6:
*l -= b;
*h = *h - !DRX_IS_BOOTH_NEGATIVE(b) + !b + (*l <
- ((u32_t)
+ ((u32)
(-
- ((s32_t)
+ ((s32)
b))));
break;
}
/*============================================================================*/
/*
-* \fn u32_t Frac28(u32_t N, u32_t D)
+* \fn u32 Frac28(u32 N, u32 D)
* \brief Compute: (1<<28)*N/D
* \param N 32 bits
* \param D 32 bits
* D: 0...(1<<28)-1
* Q: 0...(1<<32)-1
*/
-static u32_t Frac28(u32_t N, u32_t D)
+static u32 Frac28(u32 N, u32 D)
{
int i = 0;
- u32_t Q1 = 0;
- u32_t R0 = 0;
+ u32 Q1 = 0;
+ u32 R0 = 0;
R0 = (N % D) << 4; /* 32-28 == 4 shifts possible at max */
Q1 = N / D; /* integer part, only the 4 least significant bits
}
/**
-* \fn u32_t Log10Times100( u32_t x)
+* \fn u32 Log10Times100( u32 x)
* \brief Compute: 100*log10(x)
* \param x 32 bits
* \return 100*log10(x)
* where y = 2^k and 1<= (x/y) < 2
*/
-static u32_t Log10Times100(u32_t x)
+static u32 Log10Times100(u32 x)
{
- static const u8_t scale = 15;
- static const u8_t indexWidth = 5;
+ static const u8 scale = 15;
+ static const u8 indexWidth = 5;
/*
log2lut[n] = (1<<scale) * 200 * log2( 1.0 + ( (1.0/(1<<INDEXWIDTH)) * n ))
0 <= n < ((1<<INDEXWIDTH)+1)
*/
- static const u32_t log2lut[] = {
+ static const u32 log2lut[] = {
0, /* 0.000000 */
290941, /* 290941.300628 */
573196, /* 573196.476418 */
6553600, /* 6553600.000000 */
};
- u8_t i = 0;
- u32_t y = 0;
- u32_t d = 0;
- u32_t k = 0;
- u32_t r = 0;
+ u8 i = 0;
+ u32 y = 0;
+ u32 d = 0;
+ u32 k = 0;
+ u32 r = 0;
if (x == 0)
return (0);
/* Scale x (normalize) */
/* computing y in log(x/y) = log(x) - log(y) */
- if ((x & (((u32_t) (-1)) << (scale + 1))) == 0) {
+ if ((x & (((u32) (-1)) << (scale + 1))) == 0) {
for (k = scale; k > 0; k--) {
- if (x & (((u32_t) 1) << scale))
+ if (x & (((u32) 1) << scale))
break;
x <<= 1;
}
} else {
for (k = scale; k < 31; k++) {
- if ((x & (((u32_t) (-1)) << (scale + 1))) == 0)
+ if ((x & (((u32) (-1)) << (scale + 1))) == 0)
break;
x >>= 1;
}
and 1.0 <= x < 2.0 */
/* correction for divison: log(x) = log(x/y)+log(y) */
- y = k * ((((u32_t) 1) << scale) * 200);
+ y = k * ((((u32) 1) << scale) * 200);
/* remove integer part */
- x &= ((((u32_t) 1) << scale) - 1);
+ x &= ((((u32) 1) << scale) - 1);
/* get index */
- i = (u8_t) (x >> (scale - indexWidth));
+ i = (u8) (x >> (scale - indexWidth));
/* compute delta (x-a) */
- d = x & ((((u32_t) 1) << (scale - indexWidth)) - 1);
+ d = x & ((((u32) 1) << (scale - indexWidth)) - 1);
/* compute log, multiplication ( d* (.. )) must be within range ! */
y += log2lut[i] +
((d * (log2lut[i + 1] - log2lut[i])) >> (scale - indexWidth));
y /= 108853; /* (log2(10) << scale) */
r = (y >> 1);
/* rounding */
- if (y & ((u32_t) 1))
+ if (y & ((u32) 1))
r++;
return (r);
}
/**
-* \fn u32_t FracTimes1e6( u16_t N, u32_t D)
+* \fn u32 FracTimes1e6( u16 N, u32 D)
* \brief Compute: (N/D) * 1000000.
* \param N nominator 16-bits.
* \param D denominator 32-bits.
-* \return u32_t
+* \return u32
* \retval ((N/D) * 1000000), 32 bits
*
* No check on D=0!
*/
-static u32_t FracTimes1e6(u32_t N, u32_t D)
+static u32 FracTimes1e6(u32 N, u32 D)
{
- u32_t remainder = 0;
- u32_t frac = 0;
+ u32 remainder = 0;
+ u32 frac = 0;
/*
frac = (N * 1000000) / D
This would result in a problem in case D < 16 (div by 0).
So we do it more elaborate as shown below.
*/
- frac = (((u32_t) N) * (1000000 >> 4)) / D;
+ frac = (((u32) N) * (1000000 >> 4)) / D;
frac <<= 4;
- remainder = (((u32_t) N) * (1000000 >> 4)) % D;
+ remainder = (((u32) N) * (1000000 >> 4)) % D;
remainder <<= 4;
frac += remainder / D;
remainder = remainder % D;
/**
* \brief Compute: 100 * 10^( GdB / 200 ).
-* \param u32_t GdB Gain in 0.1dB
-* \return u32_t Gainfactor in 0.01 resolution
+* \param u32 GdB Gain in 0.1dB
+* \return u32 Gainfactor in 0.01 resolution
*
*/
-static u32_t dB2LinTimes100(u32_t GdB)
+static u32 dB2LinTimes100(u32 GdB)
{
- u32_t result = 0;
- u32_t nr6dBSteps = 0;
- u32_t remainder = 0;
- u32_t remainderFac = 0;
+ u32 result = 0;
+ u32 nr6dBSteps = 0;
+ u32 remainder = 0;
+ u32 remainderFac = 0;
/* start with factors 2 (6.02dB) */
nr6dBSteps = GdB * 1000UL / 60206UL;
#define FRAC_CEIL 1
#define FRAC_ROUND 2
/**
-* \fn u32_t Frac( u32_t N, u32_t D, u16_t RC )
+* \fn u32 Frac( u32 N, u32 D, u16 RC )
* \brief Compute: N/D.
* \param N nominator 32-bits.
* \param D denominator 32-bits.
* \param RC-result correction: 0-floor; 1-ceil; 2-round
-* \return u32_t
+* \return u32
* \retval N/D, 32 bits
*
* If D=0 returns 0
*/
-static u32_t Frac(u32_t N, u32_t D, u16_t RC)
+static u32 Frac(u32 N, u32 D, u16 RC)
{
- u32_t remainder = 0;
- u32_t frac = 0;
- u16_t bitCnt = 32;
+ u32 remainder = 0;
+ u32 frac = 0;
+ u16 bitCnt = 32;
if (D == 0) {
frac = 0;
/*============================================================================*/
/**
-* \fn u16_t UCodeRead16( pu8_t addr)
+* \fn u16 UCodeRead16( u8 *addr)
* \brief Read a 16 bits word, expect big endian data.
-* \return u16_t The data read.
+* \return u16 The data read.
*/
-static u16_t UCodeRead16(pu8_t addr)
+static u16 UCodeRead16(u8 *addr)
{
/* Works fo any host processor */
- u16_t word = 0;
+ u16 word = 0;
- word = ((u16_t) addr[0]);
+ word = ((u16) addr[0]);
word <<= 8;
- word |= ((u16_t) addr[1]);
+ word |= ((u16) addr[1]);
return (word);
}
/*============================================================================*/
/**
-* \fn u32_t UCodeRead32( pu8_t addr)
+* \fn u32 UCodeRead32( u8 *addr)
* \brief Read a 32 bits word, expect big endian data.
-* \return u32_t The data read.
+* \return u32 The data read.
*/
-static u32_t UCodeRead32(pu8_t addr)
+static u32 UCodeRead32(u8 *addr)
{
/* Works fo any host processor */
- u32_t word = 0;
+ u32 word = 0;
- word = ((u16_t) addr[0]);
+ word = ((u16) addr[0]);
word <<= 8;
- word |= ((u16_t) addr[1]);
+ word |= ((u16) addr[1]);
word <<= 8;
- word |= ((u16_t) addr[2]);
+ word |= ((u16) addr[2]);
word <<= 8;
- word |= ((u16_t) addr[3]);
+ word |= ((u16) addr[3]);
return (word);
}
/*============================================================================*/
/**
-* \fn u16_t UCodeComputeCRC (pu8_t blockData, u16_t nrWords)
+* \fn u16 UCodeComputeCRC (u8 *blockData, u16 nrWords)
* \brief Compute CRC of block of microcode data.
* \param blockData Pointer to microcode data.
* \param nrWords Size of microcode block (number of 16 bits words).
-* \return u16_t The computed CRC residu.
+* \return u16 The computed CRC residu.
*/
-static u16_t UCodeComputeCRC(pu8_t blockData, u16_t nrWords)
+static u16 UCodeComputeCRC(u8 *blockData, u16 nrWords)
{
- u16_t i = 0;
- u16_t j = 0;
- u32_t CRCWord = 0;
- u32_t carry = 0;
+ u16 i = 0;
+ u16 j = 0;
+ u32 CRCWord = 0;
+ u32 carry = 0;
while (i < nrWords) {
- CRCWord |= (u32_t) UCodeRead16(blockData);
+ CRCWord |= (u32) UCodeRead16(blockData);
for (j = 0; j < 16; j++) {
CRCWord <<= 1;
if (carry != 0)
carry = CRCWord & 0x80000000UL;
}
i++;
- blockData += (sizeof(u16_t));
+ blockData += (sizeof(u16));
}
- return ((u16_t) (CRCWord >> 16));
+ return ((u16) (CRCWord >> 16));
}
#endif /* DRXJ_SPLIT_UCODE_UPLOAD */
* and rounded. For calc used formula: 16*10^(prescaleGain[dB]/20).
*
*/
-static const u16_t NicamPrescTableVal[43] =
+static const u16 NicamPrescTableVal[43] =
{ 1, 1, 1, 1, 2, 2, 2, 2, 3, 3, 3, 4, 4,
5, 5, 6, 6, 7, 8, 9, 10, 11, 13, 14, 16,
18, 20, 23, 25, 28, 32, 36, 40, 45,
static DRXStatus_t DRXJ_DAP_ReadBlock(struct i2c_device_addr *devAddr,
DRXaddr_t addr,
- u16_t datasize,
- pu8_t data, DRXflags_t flags)
+ u16 datasize,
+ u8 *data, DRXflags_t flags)
{
return drxDapFASIFunct_g.readBlockFunc(devAddr,
addr, datasize, data, flags);
static DRXStatus_t DRXJ_DAP_ReadModifyWriteReg8(struct i2c_device_addr *devAddr,
DRXaddr_t waddr,
DRXaddr_t raddr,
- u8_t wdata, pu8_t rdata)
+ u8 wdata, u8 *rdata)
{
return drxDapFASIFunct_g.readModifyWriteReg8Func(devAddr,
waddr,
static DRXStatus_t DRXJ_DAP_RMWriteReg16Short(struct i2c_device_addr *devAddr,
DRXaddr_t waddr,
DRXaddr_t raddr,
- u16_t wdata, pu16_t rdata)
+ u16 wdata, u16 *rdata)
{
DRXStatus_t rc;
static DRXStatus_t DRXJ_DAP_ReadModifyWriteReg16(struct i2c_device_addr *devAddr,
DRXaddr_t waddr,
DRXaddr_t raddr,
- u16_t wdata, pu16_t rdata)
+ u16 wdata, u16 *rdata)
{
/* TODO: correct short/long addressing format decision,
now long format has higher prio then short because short also
static DRXStatus_t DRXJ_DAP_ReadModifyWriteReg32(struct i2c_device_addr *devAddr,
DRXaddr_t waddr,
DRXaddr_t raddr,
- u32_t wdata, pu32_t rdata)
+ u32 wdata, u32 *rdata)
{
return drxDapFASIFunct_g.readModifyWriteReg32Func(devAddr,
waddr,
static DRXStatus_t DRXJ_DAP_ReadReg8(struct i2c_device_addr *devAddr,
DRXaddr_t addr,
- pu8_t data, DRXflags_t flags)
+ u8 *data, DRXflags_t flags)
{
return drxDapFASIFunct_g.readReg8Func(devAddr, addr, data, flags);
}
*
*/
static DRXStatus_t DRXJ_DAP_ReadAudReg16(struct i2c_device_addr *devAddr,
- DRXaddr_t addr, pu16_t data)
+ DRXaddr_t addr, u16 *data)
{
- u32_t startTimer = 0;
- u32_t currentTimer = 0;
- u32_t deltaTimer = 0;
- u16_t trStatus = 0;
+ u32 startTimer = 0;
+ u32 currentTimer = 0;
+ u32 deltaTimer = 0;
+ u16 trStatus = 0;
DRXStatus_t stat = DRX_STS_ERROR;
/* No read possible for bank 3, return with error */
static DRXStatus_t DRXJ_DAP_ReadReg16(struct i2c_device_addr *devAddr,
DRXaddr_t addr,
- pu16_t data, DRXflags_t flags)
+ u16 *data, DRXflags_t flags)
{
DRXStatus_t stat = DRX_STS_ERROR;
static DRXStatus_t DRXJ_DAP_ReadReg32(struct i2c_device_addr *devAddr,
DRXaddr_t addr,
- pu32_t data, DRXflags_t flags)
+ u32 *data, DRXflags_t flags)
{
return drxDapFASIFunct_g.readReg32Func(devAddr, addr, data, flags);
}
static DRXStatus_t DRXJ_DAP_WriteBlock(struct i2c_device_addr *devAddr,
DRXaddr_t addr,
- u16_t datasize,
- pu8_t data, DRXflags_t flags)
+ u16 datasize,
+ u8 *data, DRXflags_t flags)
{
return drxDapFASIFunct_g.writeBlockFunc(devAddr,
addr, datasize, data, flags);
static DRXStatus_t DRXJ_DAP_WriteReg8(struct i2c_device_addr *devAddr,
DRXaddr_t addr,
- u8_t data, DRXflags_t flags)
+ u8 data, DRXflags_t flags)
{
return drxDapFASIFunct_g.writeReg8Func(devAddr, addr, data, flags);
}
*
*/
static DRXStatus_t DRXJ_DAP_WriteAudReg16(struct i2c_device_addr *devAddr,
- DRXaddr_t addr, u16_t data)
+ DRXaddr_t addr, u16 data)
{
DRXStatus_t stat = DRX_STS_ERROR;
if (DRXDAP_FASI_ADDR2BANK(addr) == 2) {
stat = DRX_STS_INVALID_ARG;
} else {
- u32_t startTimer = 0;
- u32_t currentTimer = 0;
- u32_t deltaTimer = 0;
- u16_t trStatus = 0;
+ u32 startTimer = 0;
+ u32 currentTimer = 0;
+ u32 deltaTimer = 0;
+ u16 trStatus = 0;
const DRXaddr_t writeBit = ((DRXaddr_t) 1) << 16;
/* Force write bit */
static DRXStatus_t DRXJ_DAP_WriteReg16(struct i2c_device_addr *devAddr,
DRXaddr_t addr,
- u16_t data, DRXflags_t flags)
+ u16 data, DRXflags_t flags)
{
DRXStatus_t stat = DRX_STS_ERROR;
static DRXStatus_t DRXJ_DAP_WriteReg32(struct i2c_device_addr *devAddr,
DRXaddr_t addr,
- u32_t data, DRXflags_t flags)
+ u32 data, DRXflags_t flags)
{
return drxDapFASIFunct_g.writeReg32Func(devAddr, addr, data, flags);
}
static
DRXStatus_t DRXJ_DAP_AtomicReadWriteBlock(struct i2c_device_addr *devAddr,
DRXaddr_t addr,
- u16_t datasize,
- pu8_t data, Bool_t readFlag)
+ u16 datasize,
+ u8 *data, Bool_t readFlag)
{
DRXJHiCmd_t hiCmd;
- u16_t word;
- u16_t dummy = 0;
- u16_t i = 0;
+ u16 word;
+ u16 dummy = 0;
+ u16 i = 0;
/* Parameter check */
if ((data == NULL) ||
/* Set up HI parameters to read or write n bytes */
hiCmd.cmd = SIO_HI_RA_RAM_CMD_ATOMIC_COPY;
hiCmd.param1 =
- (u16_t) ((DRXDAP_FASI_ADDR2BLOCK(DRXJ_HI_ATOMIC_BUF_START) << 6) +
+ (u16) ((DRXDAP_FASI_ADDR2BLOCK(DRXJ_HI_ATOMIC_BUF_START) << 6) +
DRXDAP_FASI_ADDR2BANK(DRXJ_HI_ATOMIC_BUF_START));
hiCmd.param2 =
- (u16_t) DRXDAP_FASI_ADDR2OFFSET(DRXJ_HI_ATOMIC_BUF_START);
- hiCmd.param3 = (u16_t) ((datasize / 2) - 1);
+ (u16) DRXDAP_FASI_ADDR2OFFSET(DRXJ_HI_ATOMIC_BUF_START);
+ hiCmd.param3 = (u16) ((datasize / 2) - 1);
if (readFlag == FALSE) {
hiCmd.param3 |= DRXJ_HI_ATOMIC_WRITE;
} else {
hiCmd.param3 |= DRXJ_HI_ATOMIC_READ;
}
- hiCmd.param4 = (u16_t) ((DRXDAP_FASI_ADDR2BLOCK(addr) << 6) +
+ hiCmd.param4 = (u16) ((DRXDAP_FASI_ADDR2BLOCK(addr) << 6) +
DRXDAP_FASI_ADDR2BANK(addr));
- hiCmd.param5 = (u16_t) DRXDAP_FASI_ADDR2OFFSET(addr);
+ hiCmd.param5 = (u16) DRXDAP_FASI_ADDR2OFFSET(addr);
if (readFlag == FALSE) {
/* write data to buffer */
for (i = 0; i < (datasize / 2); i++) {
- word = ((u16_t) data[2 * i]);
- word += (((u16_t) data[(2 * i) + 1]) << 8);
+ word = ((u16) data[2 * i]);
+ word += (((u16) data[(2 * i) + 1]) << 8);
DRXJ_DAP_WriteReg16(devAddr,
(DRXJ_HI_ATOMIC_BUF_START + i),
word, 0);
DRXJ_DAP_ReadReg16(devAddr,
(DRXJ_HI_ATOMIC_BUF_START + i),
&word, 0);
- data[2 * i] = (u8_t) (word & 0xFF);
- data[(2 * i) + 1] = (u8_t) (word >> 8);
+ data[2 * i] = (u8) (word & 0xFF);
+ data[(2 * i) + 1] = (u8) (word >> 8);
}
}
static
DRXStatus_t DRXJ_DAP_AtomicReadReg32(struct i2c_device_addr *devAddr,
DRXaddr_t addr,
- pu32_t data, DRXflags_t flags)
+ u32 *data, DRXflags_t flags)
{
- u8_t buf[sizeof(*data)];
+ u8 buf[sizeof(*data)];
DRXStatus_t rc = DRX_STS_ERROR;
- u32_t word = 0;
+ u32 word = 0;
if (!data) {
return DRX_STS_INVALID_ARG;
rc = DRXJ_DAP_AtomicReadWriteBlock(devAddr, addr,
sizeof(*data), buf, TRUE);
- word = (u32_t) buf[3];
+ word = (u32) buf[3];
word <<= 8;
- word |= (u32_t) buf[2];
+ word |= (u32) buf[2];
word <<= 8;
- word |= (u32_t) buf[1];
+ word |= (u32) buf[1];
word <<= 8;
- word |= (u32_t) buf[0];
+ word |= (u32) buf[0];
*data = word;
{
pDRXJData_t extAttr = (pDRXJData_t) (NULL);
DRXJHiCmd_t hiCmd;
- u16_t result = 0;
+ u16 result = 0;
extAttr = (pDRXJData_t) demod->myExtAttr;
*
*/
static DRXStatus_t
-HICommand(struct i2c_device_addr *devAddr, const pDRXJHiCmd_t cmd, pu16_t result)
+HICommand(struct i2c_device_addr *devAddr, const pDRXJHiCmd_t cmd, u16 *result)
{
- u16_t waitCmd = 0;
- u16_t nrRetries = 0;
+ u16 waitCmd = 0;
+ u16 nrRetries = 0;
Bool_t powerdown_cmd = FALSE;
/* Write parameters */
/* Timing div, 250ns/Psys */
/* Timing div, = ( delay (nano seconds) * sysclk (kHz) )/ 1000 */
extAttr->HICfgTimingDiv =
- (u16_t) ((commonAttr->sysClockFreq / 1000) * HI_I2C_DELAY) / 1000;
+ (u16) ((commonAttr->sysClockFreq / 1000) * HI_I2C_DELAY) / 1000;
/* Clipping */
if ((extAttr->HICfgTimingDiv) > SIO_HI_RA_RAM_PAR_2_CFG_DIV__M) {
extAttr->HICfgTimingDiv = SIO_HI_RA_RAM_PAR_2_CFG_DIV__M;
/* Delay = ( delay (nano seconds) * oscclk (kHz) )/ 1000 */
/* SDA brdige delay */
extAttr->HICfgBridgeDelay =
- (u16_t) ((commonAttr->oscClockFreq / 1000) * HI_I2C_BRIDGE_DELAY) /
+ (u16) ((commonAttr->oscClockFreq / 1000) * HI_I2C_BRIDGE_DELAY) /
1000;
/* Clipping */
if ((extAttr->HICfgBridgeDelay) > SIO_HI_RA_RAM_PAR_3_CFG_DBL_SDA__M) {
pDRXCommonAttr_t commonAttr = (pDRXCommonAttr_t) (NULL);
pDRXJData_t extAttr = (pDRXJData_t) NULL;
struct i2c_device_addr *devAddr = (struct i2c_device_addr *) (NULL);
- u16_t sioPdrOhwCfg = 0;
- u32_t sioTopJtagidLo = 0;
- u16_t bid = 0;
+ u16 sioPdrOhwCfg = 0;
+ u32 sioTopJtagidLo = 0;
+ u16 bid = 0;
commonAttr = (pDRXCommonAttr_t) demod->myCommonAttr;
extAttr = (pDRXJData_t) demod->myExtAttr;
Based on pinning v47
*/
RR32(devAddr, SIO_TOP_JTAGID_LO__A, &sioTopJtagidLo);
- extAttr->mfx = (u8_t) ((sioTopJtagidLo >> 29) & 0xF);
+ extAttr->mfx = (u8) ((sioTopJtagidLo >> 29) & 0xF);
switch ((sioTopJtagidLo >> 12) & 0xFF) {
case 0x31:
static DRXStatus_t PowerUpDevice(pDRXDemodInstance_t demod)
{
struct i2c_device_addr *devAddr = (struct i2c_device_addr *) (NULL);
- u8_t data = 0;
- u16_t retryCount = 0;
+ u8 data = 0;
+ u16 retryCount = 0;
struct i2c_device_addr wakeUpAddr;
devAddr = demod->myI2CDevAddr;
data = 0;
DRXBSP_I2C_WriteRead(&wakeUpAddr, 1, &data,
(struct i2c_device_addr *) (NULL), 0,
- (pu8_t) (NULL));
+ (u8 *) (NULL));
DRXBSP_HST_Sleep(10);
retryCount++;
} while ((DRXBSP_I2C_WriteRead
- ((struct i2c_device_addr *) (NULL), 0, (pu8_t) (NULL), devAddr, 1,
+ ((struct i2c_device_addr *) (NULL), 0, (u8 *) (NULL), devAddr, 1,
&data)
!= DRX_STS_OK) && (retryCount < DRXJ_MAX_RETRIES_POWERUP));
struct i2c_device_addr *devAddr = (struct i2c_device_addr *) (NULL);
pDRXJData_t extAttr = (pDRXJData_t) (NULL);
pDRXCommonAttr_t commonAttr = (pDRXCommonAttr_t) (NULL);
- u16_t fecOcRegMode = 0;
- u16_t fecOcRegIprMode = 0;
- u16_t fecOcRegIprInvert = 0;
- u32_t maxBitRate = 0;
- u32_t rcnRate = 0;
- u32_t nrBits = 0;
- u16_t sioPdrMdCfg = 0;
+ u16 fecOcRegMode = 0;
+ u16 fecOcRegIprMode = 0;
+ u16 fecOcRegIprInvert = 0;
+ u32 maxBitRate = 0;
+ u32 rcnRate = 0;
+ u32 nrBits = 0;
+ u16 sioPdrMdCfg = 0;
/* data mask for the output data byte */
- u16_t InvertDataMask =
+ u16 InvertDataMask =
FEC_OC_IPR_INVERT_MD7__M | FEC_OC_IPR_INVERT_MD6__M |
FEC_OC_IPR_INVERT_MD5__M | FEC_OC_IPR_INVERT_MD4__M |
FEC_OC_IPR_INVERT_MD3__M | FEC_OC_IPR_INVERT_MD2__M |
rcnRate =
(Frac28
(maxBitRate,
- (u32_t) (commonAttr->sysClockFreq / 8))) /
+ (u32) (commonAttr->sysClockFreq / 8))) /
188;
break;
default:
rcnRate =
(Frac28
(maxBitRate,
- (u32_t) (commonAttr->sysClockFreq / 8))) /
+ (u32) (commonAttr->sysClockFreq / 8))) /
204;
break;
default:
}
if (cfgData->staticCLK == TRUE) { /* Static mode */
- u32_t dtoRate = 0;
- u32_t bitRate = 0;
- u16_t fecOcDtoBurstLen = 0;
- u16_t fecOcDtoPeriod = 0;
+ u32 dtoRate = 0;
+ u32 bitRate = 0;
+ u16 fecOcDtoBurstLen = 0;
+ u16 fecOcDtoPeriod = 0;
fecOcDtoBurstLen = FEC_OC_DTO_BURST_LEN__PRE;
break;
case DRX_STANDARD_ITU_A:
{
- u32_t symbolRateTh = 6400000;
+ u32 symbolRateTh = 6400000;
if (cfgData->insertRSByte == TRUE) {
fecOcDtoBurstLen = 204;
symbolRateTh = 5900000;
Frac28(bitRate, commonAttr->sysClockFreq * 1000);
dtoRate >>= 3;
WR16(devAddr, FEC_OC_DTO_RATE_HI__A,
- (u16_t) ((dtoRate >> 16) & FEC_OC_DTO_RATE_HI__M));
+ (u16) ((dtoRate >> 16) & FEC_OC_DTO_RATE_HI__M));
WR16(devAddr, FEC_OC_DTO_RATE_LO__A,
- (u16_t) (dtoRate & FEC_OC_DTO_RATE_LO_RATE_LO__M));
+ (u16) (dtoRate & FEC_OC_DTO_RATE_LO_RATE_LO__M));
WR16(devAddr, FEC_OC_DTO_MODE__A,
FEC_OC_DTO_MODE_DYNAMIC__M |
FEC_OC_DTO_MODE_OFFSET_ENABLE__M);
struct i2c_device_addr *devAddr = (struct i2c_device_addr *) (NULL);
pDRXCommonAttr_t commonAttr = (pDRXCommonAttr_t) (NULL);
DRXLockStatus_t lockStatus = DRX_NOT_LOCKED;
- u32_t rateReg = 0;
- u32_t data64Hi = 0;
- u32_t data64Lo = 0;
+ u32 rateReg = 0;
+ u32 data64Hi = 0;
+ u32 data64Lo = 0;
if (cfgData == NULL) {
return (DRX_STS_INVALID_ARG);
{
pDRXJData_t extAttr = (pDRXJData_t) (NULL);
struct i2c_device_addr *devAddr = (struct i2c_device_addr *) (NULL);
- u16_t fecOcDprMode = 0;
- u16_t fecOcSncMode = 0;
- u16_t fecOcEmsMode = 0;
+ u16 fecOcDprMode = 0;
+ u16 fecOcSncMode = 0;
+ u16 fecOcEmsMode = 0;
devAddr = demod->myI2CDevAddr;
extAttr = (pDRXJData_t) demod->myExtAttr;
{
pDRXJData_t extAttr = (pDRXJData_t) (NULL);
struct i2c_device_addr *devAddr = (struct i2c_device_addr *) (NULL);
- u16_t fecOcIprMode = 0;
+ u16 fecOcIprMode = 0;
devAddr = demod->myI2CDevAddr;
extAttr = (pDRXJData_t) demod->myExtAttr;
{
pDRXJData_t extAttr = (pDRXJData_t) (NULL);
struct i2c_device_addr *devAddr = (struct i2c_device_addr *) (NULL);
- u16_t fecOcCommMb = 0;
+ u16 fecOcCommMb = 0;
pDRXCommonAttr_t commonAttr = (pDRXCommonAttr_t) NULL;
devAddr = demod->myI2CDevAddr;
pDRXJCfgMpegOutputMisc_t cfgData)
{
pDRXJData_t extAttr = (pDRXJData_t) (NULL);
- u16_t data = 0;
+ u16 data = 0;
if (cfgData == NULL) {
return (DRX_STS_INVALID_ARG);
static DRXStatus_t
CtrlGetCfgHwCfg(pDRXDemodInstance_t demod, pDRXJCfgHwCfg_t cfgData)
{
- u16_t data = 0;
+ u16 data = 0;
pDRXJData_t extAttr = (pDRXJData_t) (NULL);
if (cfgData == NULL) {
CtrlUIOWrite(pDRXDemodInstance_t demod, pDRXUIOData_t UIOData)
{
pDRXJData_t extAttr = (pDRXJData_t) (NULL);
- u16_t pinCfgValue = 0;
- u16_t value = 0;
+ u16 pinCfgValue = 0;
+ u16 value = 0;
if ((UIOData == NULL) || (demod == NULL)) {
return DRX_STS_INVALID_ARG;
static DRXStatus_t CtrlUIORead(pDRXDemodInstance_t demod, pDRXUIOData_t UIOData)
{
pDRXJData_t extAttr = (pDRXJData_t) (NULL);
- u16_t pinCfgValue = 0;
- u16_t value = 0;
+ u16 pinCfgValue = 0;
+ u16 value = 0;
if ((UIOData == NULL) || (demod == NULL)) {
return DRX_STS_INVALID_ARG;
CtrlI2CBridge(pDRXDemodInstance_t demod, pBool_t bridgeClosed)
{
DRXJHiCmd_t hiCmd;
- u16_t result = 0;
+ u16 result = 0;
/* check arguments */
if (bridgeClosed == NULL) {
*/
static DRXStatus_t SmartAntInit(pDRXDemodInstance_t demod)
{
- u16_t data = 0;
+ u16 data = 0;
pDRXJData_t extAttr = NULL;
struct i2c_device_addr *devAddr = NULL;
DRXUIOCfg_t UIOCfg = { DRX_UIO1, DRX_UIO_MODE_FIRMWARE_SMA };
{
pDRXJData_t extAttr = NULL;
struct i2c_device_addr *devAddr = NULL;
- u16_t data = 0;
- u32_t startTime = 0;
+ u16 data = 0;
+ u32 startTime = 0;
static Bool_t bitInverted = FALSE;
devAddr = demod->myI2CDevAddr;
static DRXStatus_t SCUCommand(struct i2c_device_addr *devAddr, pDRXJSCUCmd_t cmd)
{
- u16_t curCmd = 0;
- u32_t startTime = 0;
+ u16 curCmd = 0;
+ u32 startTime = 0;
/* Check param */
if (cmd == NULL)
/* read results */
if ((cmd->resultLen > 0) && (cmd->result != NULL)) {
- s16_t err;
+ s16 err;
switch (cmd->resultLen) {
case 4:
err = cmd->result[0];
/* check a few fixed error codes */
- if ((err == (s16_t) SCU_RAM_PARAM_0_RESULT_UNKSTD)
- || (err == (s16_t) SCU_RAM_PARAM_0_RESULT_UNKCMD)
- || (err == (s16_t) SCU_RAM_PARAM_0_RESULT_INVPAR)
- || (err == (s16_t) SCU_RAM_PARAM_0_RESULT_SIZE)
+ if ((err == (s16) SCU_RAM_PARAM_0_RESULT_UNKSTD)
+ || (err == (s16) SCU_RAM_PARAM_0_RESULT_UNKCMD)
+ || (err == (s16) SCU_RAM_PARAM_0_RESULT_INVPAR)
+ || (err == (s16) SCU_RAM_PARAM_0_RESULT_SIZE)
) {
return DRX_STS_INVALID_ARG;
}
*/
#define ADDR_AT_SCU_SPACE(x) ((x - 0x82E000) * 2)
static
-DRXStatus_t DRXJ_DAP_SCU_AtomicReadWriteBlock(struct i2c_device_addr *devAddr, DRXaddr_t addr, u16_t datasize, /* max 30 bytes because the limit of SCU parameter */
- pu8_t data, Bool_t readFlag)
+DRXStatus_t DRXJ_DAP_SCU_AtomicReadWriteBlock(struct i2c_device_addr *devAddr, DRXaddr_t addr, u16 datasize, /* max 30 bytes because the limit of SCU parameter */
+ u8 *data, Bool_t readFlag)
{
DRXJSCUCmd_t scuCmd;
- u16_t setParamParameters[15];
- u16_t cmdResult[15];
+ u16 setParamParameters[15];
+ u16 cmdResult[15];
/* Parameter check */
if ((data == NULL) ||
return (DRX_STS_INVALID_ARG);
}
- setParamParameters[1] = (u16_t) ADDR_AT_SCU_SPACE(addr);
+ setParamParameters[1] = (u16) ADDR_AT_SCU_SPACE(addr);
if (readFlag) { /* read */
setParamParameters[0] = ((~(0x0080)) & datasize);
scuCmd.parameterLen = 2;
int i = 0;
/* read data from buffer */
for (i = 0; i < (datasize / 2); i++) {
- data[2 * i] = (u8_t) (scuCmd.result[i + 2] & 0xFF);
- data[(2 * i) + 1] = (u8_t) (scuCmd.result[i + 2] >> 8);
+ data[2 * i] = (u8) (scuCmd.result[i + 2] & 0xFF);
+ data[(2 * i) + 1] = (u8) (scuCmd.result[i + 2] >> 8);
}
}
static
DRXStatus_t DRXJ_DAP_SCU_AtomicReadReg16(struct i2c_device_addr *devAddr,
DRXaddr_t addr,
- pu16_t data, DRXflags_t flags)
+ u16 *data, DRXflags_t flags)
{
- u8_t buf[2];
+ u8 buf[2];
DRXStatus_t rc = DRX_STS_ERROR;
- u16_t word = 0;
+ u16 word = 0;
if (!data) {
return DRX_STS_INVALID_ARG;
rc = DRXJ_DAP_SCU_AtomicReadWriteBlock(devAddr, addr, 2, buf, TRUE);
- word = (u16_t) (buf[0] + (buf[1] << 8));
+ word = (u16) (buf[0] + (buf[1] << 8));
*data = word;
static
DRXStatus_t DRXJ_DAP_SCU_AtomicWriteReg16(struct i2c_device_addr *devAddr,
DRXaddr_t addr,
- u16_t data, DRXflags_t flags)
+ u16 data, DRXflags_t flags)
{
- u8_t buf[2];
+ u8 buf[2];
DRXStatus_t rc = DRX_STS_ERROR;
- buf[0] = (u8_t) (data & 0xff);
- buf[1] = (u8_t) ((data >> 8) & 0xff);
+ buf[0] = (u8) (data & 0xff);
+ buf[1] = (u8) ((data >> 8) & 0xff);
rc = DRXJ_DAP_SCU_AtomicReadWriteBlock(devAddr, addr, 2, buf, FALSE);
DRXStatus_t
TunerI2CWriteRead(pTUNERInstance_t tuner,
struct i2c_device_addr *wDevAddr,
- u16_t wCount,
- pu8_t wData,
- struct i2c_device_addr *rDevAddr, u16_t rCount, pu8_t rData)
+ u16 wCount,
+ u8 *wData,
+ struct i2c_device_addr *rDevAddr, u16 rCount, u8 *rData)
{
pDRXDemodInstance_t demod;
DRXI2CData_t i2cData =
* \retval DRX_STS_ERROR Failure: I2C error
*
*/
-static DRXStatus_t ADCSyncMeasurement(pDRXDemodInstance_t demod, pu16_t count)
+static DRXStatus_t ADCSyncMeasurement(pDRXDemodInstance_t demod, u16 *count)
{
- u16_t data = 0;
+ u16 data = 0;
struct i2c_device_addr *devAddr = NULL;
devAddr = demod->myI2CDevAddr;
static DRXStatus_t ADCSynchronization(pDRXDemodInstance_t demod)
{
- u16_t count = 0;
+ u16 count = 0;
struct i2c_device_addr *devAddr = NULL;
devAddr = demod->myI2CDevAddr;
if (count == 1) {
/* Try sampling on a diffrent edge */
- u16_t clkNeg = 0;
+ u16 clkNeg = 0;
RR16(devAddr, IQM_AF_CLKNEG__A, &clkNeg);
*/
static DRXStatus_t IQMSetAf(pDRXDemodInstance_t demod, Bool_t active)
{
- u16_t data = 0;
+ u16 data = 0;
struct i2c_device_addr *devAddr = NULL;
pDRXJData_t extAttr = NULL;
*/
static DRXStatus_t CtrlValidateUCode(pDRXDemodInstance_t demod)
{
- u32_t mcDev, mcPatch;
- u16_t verType;
+ u32 mcDev, mcPatch;
+ u16 verType;
/* Check device.
* Disallow microcode if:
pDRXJData_t extAttr = NULL;
pDRXJCfgAgc_t pAgcRfSettings = NULL;
pDRXJCfgAgc_t pAgcIfSettings = NULL;
- u16_t IngainTgtMax = 0;
- u16_t clpDirTo = 0;
- u16_t snsSumMax = 0;
- u16_t clpSumMax = 0;
- u16_t snsDirTo = 0;
- u16_t kiInnergainMin = 0;
- u16_t agcKi = 0;
- u16_t kiMax = 0;
- u16_t ifIaccuHiTgtMin = 0;
- u16_t data = 0;
- u16_t agcKiDgain = 0;
- u16_t kiMin = 0;
- u16_t clpCtrlMode = 0;
- u16_t agcRf = 0;
- u16_t agcIf = 0;
+ u16 IngainTgtMax = 0;
+ u16 clpDirTo = 0;
+ u16 snsSumMax = 0;
+ u16 clpSumMax = 0;
+ u16 snsDirTo = 0;
+ u16 kiInnergainMin = 0;
+ u16 agcKi = 0;
+ u16 kiMax = 0;
+ u16 ifIaccuHiTgtMin = 0;
+ u16 data = 0;
+ u16 agcKiDgain = 0;
+ u16 kiMin = 0;
+ u16 clpCtrlMode = 0;
+ u16 agcRf = 0;
+ u16 agcIf = 0;
devAddr = demod->myI2CDevAddr;
commonAttr = (pDRXCommonAttr_t) demod->myCommonAttr;
extAttr = (pDRXJData_t) demod->myExtAttr;
switch (extAttr->standard) {
case DRX_STANDARD_8VSB:
clpSumMax = 1023;
- clpDirTo = (u16_t) (-9);
+ clpDirTo = (u16) (-9);
snsSumMax = 1023;
- snsDirTo = (u16_t) (-9);
- kiInnergainMin = (u16_t) (-32768);
+ snsDirTo = (u16) (-9);
+ kiInnergainMin = (u16) (-32768);
kiMax = 0x032C;
agcKiDgain = 0xC;
ifIaccuHiTgtMin = 2047;
case DRX_STANDARD_ITU_B:
IngainTgtMax = 5119;
clpSumMax = 1023;
- clpDirTo = (u16_t) (-5);
+ clpDirTo = (u16) (-5);
snsSumMax = 127;
- snsDirTo = (u16_t) (-3);
+ snsDirTo = (u16) (-3);
kiInnergainMin = 0;
kiMax = 0x0657;
ifIaccuHiTgtMin = 2047;
case DRX_STANDARD_FM:
clpSumMax = 1023;
snsSumMax = 1023;
- kiInnergainMin = (u16_t) (-32768);
+ kiInnergainMin = (u16) (-32768);
ifIaccuHiTgtMin = 2047;
agcKiDgain = 0x7;
kiMin = 0x0225;
kiMax = 0x0547;
- clpDirTo = (u16_t) (-9);
- snsDirTo = (u16_t) (-9);
+ clpDirTo = (u16) (-9);
+ snsDirTo = (u16) (-9);
IngainTgtMax = 9000;
clpCtrlMode = 1;
pAgcIfSettings = &(extAttr->atvIfAgcCfg);
case DRX_STANDARD_PAL_SECAM_I:
clpSumMax = 1023;
snsSumMax = 1023;
- kiInnergainMin = (u16_t) (-32768);
+ kiInnergainMin = (u16) (-32768);
ifIaccuHiTgtMin = 2047;
agcKiDgain = 0x7;
kiMin = 0x0225;
kiMax = 0x0547;
- clpDirTo = (u16_t) (-9);
+ clpDirTo = (u16) (-9);
IngainTgtMax = 9000;
pAgcIfSettings = &(extAttr->atvIfAgcCfg);
pAgcRfSettings = &(extAttr->atvRfAgcCfg);
- snsDirTo = (u16_t) (-9);
+ snsDirTo = (u16) (-9);
clpCtrlMode = 1;
WR16(devAddr, SCU_RAM_AGC_INGAIN_TGT__A, pAgcIfSettings->top);
break;
case DRX_STANDARD_PAL_SECAM_LP:
clpSumMax = 1023;
snsSumMax = 1023;
- kiInnergainMin = (u16_t) (-32768);
+ kiInnergainMin = (u16) (-32768);
ifIaccuHiTgtMin = 2047;
agcKiDgain = 0x7;
kiMin = 0x0225;
kiMax = 0x0547;
- clpDirTo = (u16_t) (-9);
- snsDirTo = (u16_t) (-9);
+ clpDirTo = (u16) (-9);
+ snsDirTo = (u16) (-9);
IngainTgtMax = 9000;
clpCtrlMode = 1;
pAgcIfSettings = &(extAttr->atvIfAgcCfg);
DRXFrequency_t rfFreqResidual = 0;
DRXFrequency_t adcFreq = 0;
DRXFrequency_t intermediateFreq = 0;
- u32_t iqmFsRateOfs = 0;
+ u32 iqmFsRateOfs = 0;
pDRXJData_t extAttr = NULL;
Bool_t adcFlip = TRUE;
Bool_t selectPosImage = FALSE;
#define DRXJ_RFAGC_MAX 0x3fff
#define DRXJ_RFAGC_MIN 0x800
-static DRXStatus_t GetSigStrength(pDRXDemodInstance_t demod, pu16_t sigStrength)
+static DRXStatus_t GetSigStrength(pDRXDemodInstance_t demod, u16 *sigStrength)
{
- u16_t rfGain = 0;
- u16_t ifGain = 0;
- u16_t ifAgcSns = 0;
- u16_t ifAgcTop = 0;
- u16_t rfAgcMax = 0;
- u16_t rfAgcMin = 0;
+ u16 rfGain = 0;
+ u16 ifGain = 0;
+ u16 ifAgcSns = 0;
+ u16 ifAgcTop = 0;
+ u16 rfAgcMax = 0;
+ u16 rfAgcMin = 0;
pDRXJData_t extAttr = NULL;
struct i2c_device_addr *devAddr = NULL;
* \retval DRX_STS_ERROR Erroneous data, sigStrength contains invalid data.
*/
#ifdef DRXJ_SIGNAL_ACCUM_ERR
-static DRXStatus_t GetAccPktErr(pDRXDemodInstance_t demod, pu16_t packetErr)
+static DRXStatus_t GetAccPktErr(pDRXDemodInstance_t demod, u16 *packetErr)
{
- static u16_t pktErr = 0;
- static u16_t lastPktErr = 0;
- u16_t data = 0;
+ static u16 pktErr = 0;
+ static u16 lastPktErr = 0;
+ u16 data = 0;
pDRXJData_t extAttr = NULL;
struct i2c_device_addr *devAddr = NULL;
{
#ifdef DRXJ_SIGNAL_ACCUM_ERR
pDRXJData_t extAttr = NULL;
- u16_t packetError = 0;
+ u16 packetError = 0;
extAttr = (pDRXJData_t) demod->myExtAttr;
extAttr->resetPktErrAcc = TRUE;
* \brief Get symbol rate offset in QAM & 8VSB mode
* \return Error code
*/
-static DRXStatus_t GetSTRFreqOffset(pDRXDemodInstance_t demod, s32_t * STRFreq)
+static DRXStatus_t GetSTRFreqOffset(pDRXDemodInstance_t demod, s32 *STRFreq)
{
- u32_t symbolFrequencyRatio = 0;
- u32_t symbolNomFrequencyRatio = 0;
+ u32 symbolFrequencyRatio = 0;
+ u32 symbolNomFrequencyRatio = 0;
DRXStandard_t standard = DRX_STANDARD_UNKNOWN;
struct i2c_device_addr *devAddr = NULL;
* \brief Get the value of CTLFreq in QAM & ATSC mode
* \return Error code
*/
-static DRXStatus_t GetCTLFreqOffset(pDRXDemodInstance_t demod, s32_t * CTLFreq)
+static DRXStatus_t GetCTLFreqOffset(pDRXDemodInstance_t demod, s32 *CTLFreq)
{
DRXFrequency_t samplingFrequency = 0;
- s32_t currentFrequency = 0;
- s32_t nominalFrequency = 0;
- s32_t carrierFrequencyShift = 0;
- s32_t sign = 1;
- u32_t data64Hi = 0;
- u32_t data64Lo = 0;
+ s32 currentFrequency = 0;
+ s32 nominalFrequency = 0;
+ s32 carrierFrequencyShift = 0;
+ s32 sign = 1;
+ u32 data64Hi = 0;
+ u32 data64Lo = 0;
pDRXJData_t extAttr = NULL;
pDRXCommonAttr_t commonAttr = NULL;
struct i2c_device_addr *devAddr = NULL;
/* both registers are sign extended */
nominalFrequency = extAttr->iqmFsRateOfs;
- ARR32(devAddr, IQM_FS_RATE_LO__A, (pu32_t) & currentFrequency);
+ ARR32(devAddr, IQM_FS_RATE_LO__A, (u32 *) & currentFrequency);
if (extAttr->posImage == TRUE) {
/* negative image */
/* *CTLFreq = carrierFrequencyShift * 50.625e6 / (1 << 28); */
Mult32(carrierFrequencyShift, samplingFrequency, &data64Hi, &data64Lo);
*CTLFreq =
- (s32_t) ((((data64Lo >> 28) & 0xf) | (data64Hi << 4)) * sign);
+ (s32) ((((data64Lo >> 28) & 0xf) | (data64Hi << 4)) * sign);
return (DRX_STS_OK);
rw_error:
DRXJ_ISQAMSTD(agcSettings->standard)) ||
(DRXJ_ISATVSTD(extAttr->standard) &&
DRXJ_ISATVSTD(agcSettings->standard))) {
- u16_t data = 0;
+ u16 data = 0;
switch (agcSettings->ctrlMode) {
case DRX_AGC_CTRL_AUTO:
DRXJ_ISQAMSTD(agcSettings->standard)) ||
(DRXJ_ISATVSTD(extAttr->standard) &&
DRXJ_ISATVSTD(agcSettings->standard))) {
- u16_t data = 0;
+ u16 data = 0;
switch (agcSettings->ctrlMode) {
case DRX_AGC_CTRL_AUTO:
*/
static DRXStatus_t SetIqmAf(pDRXDemodInstance_t demod, Bool_t active)
{
- u16_t data = 0;
+ u16 data = 0;
struct i2c_device_addr *devAddr = NULL;
devAddr = demod->myI2CDevAddr;
/* *parameter */ NULL,
/* *result */ NULL
};
- u16_t cmdResult = 0;
+ u16 cmdResult = 0;
pDRXJData_t extAttr = NULL;
DRXCfgMPEGOutput_t cfgMPEGOutput;
{
struct i2c_device_addr *devAddr = NULL;
- const u8_t vsb_ffe_leak_gain_ram0[] = {
+ const u8 vsb_ffe_leak_gain_ram0[] = {
DRXJ_16TO8(0x8), /* FFETRAINLKRATIO1 */
DRXJ_16TO8(0x8), /* FFETRAINLKRATIO2 */
DRXJ_16TO8(0x8), /* FFETRAINLKRATIO3 */
DRXJ_16TO8(0x1010) /* FIRRCA1GAIN8 */
};
- const u8_t vsb_ffe_leak_gain_ram1[] = {
+ const u8 vsb_ffe_leak_gain_ram1[] = {
DRXJ_16TO8(0x1010), /* FIRRCA1GAIN9 */
DRXJ_16TO8(0x0808), /* FIRRCA1GAIN10 */
DRXJ_16TO8(0x0808), /* FIRRCA1GAIN11 */
devAddr = demod->myI2CDevAddr;
WRB(devAddr, VSB_SYSCTRL_RAM0_FFETRAINLKRATIO1__A,
- sizeof(vsb_ffe_leak_gain_ram0), ((pu8_t) vsb_ffe_leak_gain_ram0));
+ sizeof(vsb_ffe_leak_gain_ram0), ((u8 *) vsb_ffe_leak_gain_ram0));
WRB(devAddr, VSB_SYSCTRL_RAM1_FIRRCA1GAIN9__A,
- sizeof(vsb_ffe_leak_gain_ram1), ((pu8_t) vsb_ffe_leak_gain_ram1));
+ sizeof(vsb_ffe_leak_gain_ram1), ((u8 *) vsb_ffe_leak_gain_ram1));
return (DRX_STS_OK);
rw_error:
static DRXStatus_t SetVSB(pDRXDemodInstance_t demod)
{
struct i2c_device_addr *devAddr = NULL;
- u16_t cmdResult = 0;
- u16_t cmdParam = 0;
+ u16 cmdResult = 0;
+ u16 cmdParam = 0;
pDRXCommonAttr_t commonAttr = NULL;
DRXJSCUCmd_t cmdSCU;
pDRXJData_t extAttr = NULL;
- const u8_t vsb_taps_re[] = {
+ const u8 vsb_taps_re[] = {
DRXJ_16TO8(-2), /* re0 */
DRXJ_16TO8(4), /* re1 */
DRXJ_16TO8(1), /* re2 */
WR16(devAddr, IQM_CF_POW_MEAS_LEN__A, 1);
WRB(devAddr, IQM_CF_TAP_RE0__A, sizeof(vsb_taps_re),
- ((pu8_t) vsb_taps_re));
+ ((u8 *) vsb_taps_re));
WRB(devAddr, IQM_CF_TAP_IM0__A, sizeof(vsb_taps_re),
- ((pu8_t) vsb_taps_re));
+ ((u8 *) vsb_taps_re));
WR16(devAddr, VSB_TOP_BNTHRESH__A, 330); /* set higher threshold */
WR16(devAddr, VSB_TOP_CLPLASTNUM__A, 90); /* burst detection on */
/* Initialize the FEC Subsystem */
WR16(devAddr, FEC_TOP_ANNEX__A, FEC_TOP_ANNEX_D);
{
- u16_t fecOcSncMode = 0;
+ u16 fecOcSncMode = 0;
RR16(devAddr, FEC_OC_SNC_MODE__A, &fecOcSncMode);
/* output data even when not locked */
WR16(devAddr, FEC_OC_SNC_MODE__A,
WR16(devAddr, VSB_TOP_SNRTH_PT__A, 0xD4);
/* no transparent, no A&C framing; parity is set in mpegoutput */
{
- u16_t fecOcRegMode = 0;
+ u16 fecOcRegMode = 0;
RR16(devAddr, FEC_OC_MODE__A, &fecOcRegMode);
WR16(devAddr, FEC_OC_MODE__A, fecOcRegMode &
(~(FEC_OC_MODE_TRANSPARENT__M
}
/**
-* \fn static short GetVSBPostRSPckErr(struct i2c_device_addr * devAddr, pu16_t PckErrs)
+* \fn static short GetVSBPostRSPckErr(struct i2c_device_addr * devAddr, u16 *PckErrs)
* \brief Get the values of packet error in 8VSB mode
* \return Error code
*/
-static DRXStatus_t GetVSBPostRSPckErr(struct i2c_device_addr *devAddr, pu16_t pckErrs)
+static DRXStatus_t GetVSBPostRSPckErr(struct i2c_device_addr *devAddr, u16 *pckErrs)
{
- u16_t data = 0;
- u16_t period = 0;
- u16_t prescale = 0;
- u16_t packetErrorsMant = 0;
- u16_t packetErrorsExp = 0;
+ u16 data = 0;
+ u16 period = 0;
+ u16 prescale = 0;
+ u16 packetErrorsMant = 0;
+ u16 packetErrorsExp = 0;
RR16(devAddr, FEC_RS_NR_FAILURES__A, &data);
packetErrorsMant = data & FEC_RS_NR_FAILURES_FIXED_MANT__M;
/* 77.3 us is time for per packet */
CHK_ZERO(period * prescale);
*pckErrs =
- (u16_t) FracTimes1e6(packetErrorsMant * (1 << packetErrorsExp),
+ (u16) FracTimes1e6(packetErrorsMant * (1 << packetErrorsExp),
(period * prescale * 77));
return (DRX_STS_OK);
}
/**
-* \fn static short GetVSBBer(struct i2c_device_addr * devAddr, pu32_t ber)
+* \fn static short GetVSBBer(struct i2c_device_addr * devAddr, u32 *ber)
* \brief Get the values of ber in VSB mode
* \return Error code
*/
-static DRXStatus_t GetVSBpostViterbiBer(struct i2c_device_addr *devAddr, pu32_t ber)
+static DRXStatus_t GetVSBpostViterbiBer(struct i2c_device_addr *devAddr, u32 *ber)
{
- u16_t data = 0;
- u16_t period = 0;
- u16_t prescale = 0;
- u16_t bitErrorsMant = 0;
- u16_t bitErrorsExp = 0;
+ u16 data = 0;
+ u16 period = 0;
+ u16 prescale = 0;
+ u16 bitErrorsMant = 0;
+ u16 bitErrorsExp = 0;
RR16(devAddr, FEC_RS_NR_BIT_ERRORS__A, &data);
period = FEC_RS_MEASUREMENT_PERIOD;
}
/**
-* \fn static short GetVSBpreViterbiBer(struct i2c_device_addr * devAddr, pu32_t ber)
+* \fn static short GetVSBpreViterbiBer(struct i2c_device_addr * devAddr, u32 *ber)
* \brief Get the values of ber in VSB mode
* \return Error code
*/
-static DRXStatus_t GetVSBpreViterbiBer(struct i2c_device_addr *devAddr, pu32_t ber)
+static DRXStatus_t GetVSBpreViterbiBer(struct i2c_device_addr *devAddr, u32 *ber)
{
- u16_t data = 0;
+ u16 data = 0;
RR16(devAddr, VSB_TOP_NR_SYM_ERRS__A, &data);
*ber =
}
/**
-* \fn static short GetVSBSymbErr(struct i2c_device_addr * devAddr, pu32_t ber)
+* \fn static short GetVSBSymbErr(struct i2c_device_addr * devAddr, u32 *ber)
* \brief Get the values of ber in VSB mode
* \return Error code
*/
-static DRXStatus_t GetVSBSymbErr(struct i2c_device_addr *devAddr, pu32_t ser)
+static DRXStatus_t GetVSBSymbErr(struct i2c_device_addr *devAddr, u32 *ser)
{
- u16_t data = 0;
- u16_t period = 0;
- u16_t prescale = 0;
- u16_t symbErrorsMant = 0;
- u16_t symbErrorsExp = 0;
+ u16 data = 0;
+ u16 period = 0;
+ u16 prescale = 0;
+ u16 symbErrorsMant = 0;
+ u16 symbErrorsExp = 0;
RR16(devAddr, FEC_RS_NR_SYMBOL_ERRORS__A, &data);
period = FEC_RS_MEASUREMENT_PERIOD;
>> FEC_RS_NR_SYMBOL_ERRORS_EXP__B;
CHK_ZERO(period * prescale);
- *ser = (u32_t) FracTimes1e6((symbErrorsMant << symbErrorsExp) * 1000,
+ *ser = (u32) FracTimes1e6((symbErrorsMant << symbErrorsExp) * 1000,
(period * prescale * 77318));
return (DRX_STS_OK);
}
/**
-* \fn static DRXStatus_t GetVSBMER(struct i2c_device_addr * devAddr, pu16_t mer)
+* \fn static DRXStatus_t GetVSBMER(struct i2c_device_addr * devAddr, u16 *mer)
* \brief Get the values of MER
* \return Error code
*/
-static DRXStatus_t GetVSBMER(struct i2c_device_addr *devAddr, pu16_t mer)
+static DRXStatus_t GetVSBMER(struct i2c_device_addr *devAddr, u16 *mer)
{
- u16_t dataHi = 0;
+ u16 dataHi = 0;
RR16(devAddr, VSB_TOP_ERR_ENERGY_H__A, &dataHi);
*mer =
- (u16_t) (Log10Times100(21504) - Log10Times100((dataHi << 6) / 52));
+ (u16) (Log10Times100(21504) - Log10Times100((dataHi << 6) / 52));
return (DRX_STS_OK);
rw_error:
{
struct i2c_device_addr *devAddr = NULL;
/**< device address */
- u16_t vsbTopCommMb = 0; /**< VSB SL MB configuration */
- u16_t vsbTopCommMbInit = 0; /**< VSB SL MB intial configuration */
- u16_t re = 0; /**< constellation Re part */
- u32_t data = 0;
+ u16 vsbTopCommMb = 0; /**< VSB SL MB configuration */
+ u16 vsbTopCommMbInit = 0; /**< VSB SL MB intial configuration */
+ u16 re = 0; /**< constellation Re part */
+ u32 data = 0;
/* read device info */
devAddr = demod->myI2CDevAddr;
/* read data */
RR32(devAddr, FEC_OC_OCR_GRAB_RD1__A, &data);
- re = (u16_t) (((data >> 10) & 0x300) | ((data >> 2) & 0xff));
+ re = (u16) (((data >> 10) & 0x300) | ((data >> 2) & 0xff));
if (re & 0x0200) {
re |= 0xfc00;
}
/* *parameter */ NULL,
/* *result */ NULL
};
- u16_t cmdResult = 0;
+ u16 cmdResult = 0;
struct i2c_device_addr *devAddr = NULL;
pDRXJData_t extAttr = NULL;
DRXCfgMPEGOutput_t cfgMPEGOutput;
#ifndef DRXJ_VSB_ONLY
static DRXStatus_t
SetQAMMeasurement(pDRXDemodInstance_t demod,
- DRXConstellation_t constellation, u32_t symbolRate)
+ DRXConstellation_t constellation, u32 symbolRate)
{
struct i2c_device_addr *devAddr = NULL; /* device address for I2C writes */
pDRXJData_t extAttr = NULL; /* Global data container for DRXJ specif data */
- u32_t fecBitsDesired = 0; /* BER accounting period */
- u16_t fecRsPlen = 0; /* defines RS BER measurement period */
- u16_t fecRsPrescale = 0; /* ReedSolomon Measurement Prescale */
- u32_t fecRsPeriod = 0; /* Value for corresponding I2C register */
- u32_t fecRsBitCnt = 0; /* Actual precise amount of bits */
- u32_t fecOcSncFailPeriod = 0; /* Value for corresponding I2C register */
- u32_t qamVdPeriod = 0; /* Value for corresponding I2C register */
- u32_t qamVdBitCnt = 0; /* Actual precise amount of bits */
- u16_t fecVdPlen = 0; /* no of trellis symbols: VD SER measur period */
- u16_t qamVdPrescale = 0; /* Viterbi Measurement Prescale */
+ u32 fecBitsDesired = 0; /* BER accounting period */
+ u16 fecRsPlen = 0; /* defines RS BER measurement period */
+ u16 fecRsPrescale = 0; /* ReedSolomon Measurement Prescale */
+ u32 fecRsPeriod = 0; /* Value for corresponding I2C register */
+ u32 fecRsBitCnt = 0; /* Actual precise amount of bits */
+ u32 fecOcSncFailPeriod = 0; /* Value for corresponding I2C register */
+ u32 qamVdPeriod = 0; /* Value for corresponding I2C register */
+ u32 qamVdBitCnt = 0; /* Actual precise amount of bits */
+ u16 fecVdPlen = 0; /* no of trellis symbols: VD SER measur period */
+ u16 qamVdPrescale = 0; /* Viterbi Measurement Prescale */
devAddr = demod->myI2CDevAddr;
extAttr = (pDRXJData_t) demod->myExtAttr;
return (DRX_STS_INVALID_ARG);
}
- WR16(devAddr, FEC_OC_SNC_FAIL_PERIOD__A, (u16_t) fecOcSncFailPeriod);
- WR16(devAddr, FEC_RS_MEASUREMENT_PERIOD__A, (u16_t) fecRsPeriod);
+ WR16(devAddr, FEC_OC_SNC_FAIL_PERIOD__A, (u16) fecOcSncFailPeriod);
+ WR16(devAddr, FEC_RS_MEASUREMENT_PERIOD__A, (u16) fecRsPeriod);
WR16(devAddr, FEC_RS_MEASUREMENT_PRESCALE__A, fecRsPrescale);
- extAttr->fecRsPeriod = (u16_t) fecRsPeriod;
+ extAttr->fecRsPeriod = (u16) fecRsPeriod;
extAttr->fecRsPrescale = fecRsPrescale;
WR32(devAddr, SCU_RAM_FEC_ACCUM_CW_CORRECTED_LO__A, 0);
WR16(devAddr, SCU_RAM_FEC_MEAS_COUNT__A, 0);
qamVdBitCnt *= qamVdPeriod;
WR16(devAddr, QAM_VD_MEASUREMENT_PERIOD__A,
- (u16_t) qamVdPeriod);
+ (u16) qamVdPeriod);
WR16(devAddr, QAM_VD_MEASUREMENT_PRESCALE__A, qamVdPrescale);
- extAttr->qamVdPeriod = (u16_t) qamVdPeriod;
+ extAttr->qamVdPeriod = (u16) qamVdPeriod;
extAttr->qamVdPrescale = qamVdPrescale;
}
static DRXStatus_t SetQAM16(pDRXDemodInstance_t demod)
{
struct i2c_device_addr *devAddr = demod->myI2CDevAddr;
- const u8_t qamDqQualFun[] = {
+ const u8 qamDqQualFun[] = {
DRXJ_16TO8(2), /* fun0 */
DRXJ_16TO8(2), /* fun1 */
DRXJ_16TO8(2), /* fun2 */
DRXJ_16TO8(3), /* fun4 */
DRXJ_16TO8(3), /* fun5 */
};
- const u8_t qamEqCmaRad[] = {
+ const u8 qamEqCmaRad[] = {
DRXJ_16TO8(13517), /* RAD0 */
DRXJ_16TO8(13517), /* RAD1 */
DRXJ_16TO8(13517), /* RAD2 */
};
WRB(devAddr, QAM_DQ_QUAL_FUN0__A, sizeof(qamDqQualFun),
- ((pu8_t) qamDqQualFun));
+ ((u8 *) qamDqQualFun));
WRB(devAddr, SCU_RAM_QAM_EQ_CMA_RAD0__A, sizeof(qamEqCmaRad),
- ((pu8_t) qamEqCmaRad));
+ ((u8 *) qamEqCmaRad));
WR16(devAddr, SCU_RAM_QAM_FSM_RTH__A, 140);
WR16(devAddr, SCU_RAM_QAM_FSM_FTH__A, 50);
WR16(devAddr, SCU_RAM_QAM_FSM_RADIUS_AV_LIMIT__A, 220);
WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET1__A, 25);
WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET2__A, 6);
- WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET3__A, (u16_t) (-24));
- WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET4__A, (u16_t) (-65));
- WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET5__A, (u16_t) (-127));
+ WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET3__A, (u16) (-24));
+ WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET4__A, (u16) (-65));
+ WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET5__A, (u16) (-127));
WR16(devAddr, SCU_RAM_QAM_LC_CA_FINE__A, 15);
WR16(devAddr, SCU_RAM_QAM_LC_CA_COARSE__A, 40);
static DRXStatus_t SetQAM32(pDRXDemodInstance_t demod)
{
struct i2c_device_addr *devAddr = demod->myI2CDevAddr;
- const u8_t qamDqQualFun[] = {
+ const u8 qamDqQualFun[] = {
DRXJ_16TO8(3), /* fun0 */
DRXJ_16TO8(3), /* fun1 */
DRXJ_16TO8(3), /* fun2 */
DRXJ_16TO8(4), /* fun4 */
DRXJ_16TO8(4), /* fun5 */
};
- const u8_t qamEqCmaRad[] = {
+ const u8 qamEqCmaRad[] = {
DRXJ_16TO8(6707), /* RAD0 */
DRXJ_16TO8(6707), /* RAD1 */
DRXJ_16TO8(6707), /* RAD2 */
};
WRB(devAddr, QAM_DQ_QUAL_FUN0__A, sizeof(qamDqQualFun),
- ((pu8_t) qamDqQualFun));
+ ((u8 *) qamDqQualFun));
WRB(devAddr, SCU_RAM_QAM_EQ_CMA_RAD0__A, sizeof(qamEqCmaRad),
- ((pu8_t) qamEqCmaRad));
+ ((u8 *) qamEqCmaRad));
WR16(devAddr, SCU_RAM_QAM_FSM_RTH__A, 90);
WR16(devAddr, SCU_RAM_QAM_FSM_FTH__A, 50);
WR16(devAddr, SCU_RAM_QAM_FSM_MEDIAN_AV_MULT__A, 12);
WR16(devAddr, SCU_RAM_QAM_FSM_RADIUS_AV_LIMIT__A, 140);
- WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET1__A, (u16_t) (-8));
- WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET2__A, (u16_t) (-16));
- WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET3__A, (u16_t) (-26));
- WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET4__A, (u16_t) (-56));
- WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET5__A, (u16_t) (-86));
+ WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET1__A, (u16) (-8));
+ WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET2__A, (u16) (-16));
+ WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET3__A, (u16) (-26));
+ WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET4__A, (u16) (-56));
+ WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET5__A, (u16) (-86));
WR16(devAddr, SCU_RAM_QAM_LC_CA_FINE__A, 15);
WR16(devAddr, SCU_RAM_QAM_LC_CA_COARSE__A, 40);
static DRXStatus_t SetQAM64(pDRXDemodInstance_t demod)
{
struct i2c_device_addr *devAddr = demod->myI2CDevAddr;
- const u8_t qamDqQualFun[] = { /* this is hw reset value. no necessary to re-write */
+ const u8 qamDqQualFun[] = { /* this is hw reset value. no necessary to re-write */
DRXJ_16TO8(4), /* fun0 */
DRXJ_16TO8(4), /* fun1 */
DRXJ_16TO8(4), /* fun2 */
DRXJ_16TO8(6), /* fun4 */
DRXJ_16TO8(6), /* fun5 */
};
- const u8_t qamEqCmaRad[] = {
+ const u8 qamEqCmaRad[] = {
DRXJ_16TO8(13336), /* RAD0 */
DRXJ_16TO8(12618), /* RAD1 */
DRXJ_16TO8(11988), /* RAD2 */
};
WRB(devAddr, QAM_DQ_QUAL_FUN0__A, sizeof(qamDqQualFun),
- ((pu8_t) qamDqQualFun));
+ ((u8 *) qamDqQualFun));
WRB(devAddr, SCU_RAM_QAM_EQ_CMA_RAD0__A, sizeof(qamEqCmaRad),
- ((pu8_t) qamEqCmaRad));
+ ((u8 *) qamEqCmaRad));
WR16(devAddr, SCU_RAM_QAM_FSM_RTH__A, 105);
WR16(devAddr, SCU_RAM_QAM_FSM_FTH__A, 60);
WR16(devAddr, SCU_RAM_QAM_FSM_RADIUS_AV_LIMIT__A, 141);
WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET1__A, 7);
WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET2__A, 0);
- WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET3__A, (u16_t) (-15));
- WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET4__A, (u16_t) (-45));
- WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET5__A, (u16_t) (-80));
+ WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET3__A, (u16) (-15));
+ WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET4__A, (u16) (-45));
+ WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET5__A, (u16) (-80));
WR16(devAddr, SCU_RAM_QAM_LC_CA_FINE__A, 15);
WR16(devAddr, SCU_RAM_QAM_LC_CA_COARSE__A, 40);
static DRXStatus_t SetQAM128(pDRXDemodInstance_t demod)
{
struct i2c_device_addr *devAddr = demod->myI2CDevAddr;
- const u8_t qamDqQualFun[] = {
+ const u8 qamDqQualFun[] = {
DRXJ_16TO8(6), /* fun0 */
DRXJ_16TO8(6), /* fun1 */
DRXJ_16TO8(6), /* fun2 */
DRXJ_16TO8(9), /* fun4 */
DRXJ_16TO8(9), /* fun5 */
};
- const u8_t qamEqCmaRad[] = {
+ const u8 qamEqCmaRad[] = {
DRXJ_16TO8(6164), /* RAD0 */
DRXJ_16TO8(6598), /* RAD1 */
DRXJ_16TO8(6394), /* RAD2 */
};
WRB(devAddr, QAM_DQ_QUAL_FUN0__A, sizeof(qamDqQualFun),
- ((pu8_t) qamDqQualFun));
+ ((u8 *) qamDqQualFun));
WRB(devAddr, SCU_RAM_QAM_EQ_CMA_RAD0__A, sizeof(qamEqCmaRad),
- ((pu8_t) qamEqCmaRad));
+ ((u8 *) qamEqCmaRad));
WR16(devAddr, SCU_RAM_QAM_FSM_RTH__A, 50);
WR16(devAddr, SCU_RAM_QAM_FSM_FTH__A, 60);
WR16(devAddr, SCU_RAM_QAM_FSM_RADIUS_AV_LIMIT__A, 65);
WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET1__A, 5);
WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET2__A, 3);
- WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET3__A, (u16_t) (-1));
+ WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET3__A, (u16) (-1));
WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET4__A, 12);
- WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET5__A, (u16_t) (-23));
+ WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET5__A, (u16) (-23));
WR16(devAddr, SCU_RAM_QAM_LC_CA_FINE__A, 15);
WR16(devAddr, SCU_RAM_QAM_LC_CA_COARSE__A, 40);
static DRXStatus_t SetQAM256(pDRXDemodInstance_t demod)
{
struct i2c_device_addr *devAddr = demod->myI2CDevAddr;
- const u8_t qamDqQualFun[] = {
+ const u8 qamDqQualFun[] = {
DRXJ_16TO8(8), /* fun0 */
DRXJ_16TO8(8), /* fun1 */
DRXJ_16TO8(8), /* fun2 */
DRXJ_16TO8(12), /* fun4 */
DRXJ_16TO8(12), /* fun5 */
};
- const u8_t qamEqCmaRad[] = {
+ const u8 qamEqCmaRad[] = {
DRXJ_16TO8(12345), /* RAD0 */
DRXJ_16TO8(12345), /* RAD1 */
DRXJ_16TO8(13626), /* RAD2 */
};
WRB(devAddr, QAM_DQ_QUAL_FUN0__A, sizeof(qamDqQualFun),
- ((pu8_t) qamDqQualFun));
+ ((u8 *) qamDqQualFun));
WRB(devAddr, SCU_RAM_QAM_EQ_CMA_RAD0__A, sizeof(qamEqCmaRad),
- ((pu8_t) qamEqCmaRad));
+ ((u8 *) qamEqCmaRad));
WR16(devAddr, SCU_RAM_QAM_FSM_RTH__A, 50);
WR16(devAddr, SCU_RAM_QAM_FSM_FTH__A, 60);
WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET2__A, 13);
WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET3__A, 7);
WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET4__A, 0);
- WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET5__A, (u16_t) (-8));
+ WR16(devAddr, SCU_RAM_QAM_FSM_LCAVG_OFFSET5__A, (u16) (-8));
WR16(devAddr, SCU_RAM_QAM_LC_CA_FINE__A, 15);
WR16(devAddr, SCU_RAM_QAM_LC_CA_COARSE__A, 40);
*/
static DRXStatus_t
SetQAM(pDRXDemodInstance_t demod,
- pDRXChannel_t channel, DRXFrequency_t tunerFreqOffset, u32_t op)
+ pDRXChannel_t channel, DRXFrequency_t tunerFreqOffset, u32 op)
{
struct i2c_device_addr *devAddr = NULL;
pDRXJData_t extAttr = NULL;
pDRXCommonAttr_t commonAttr = NULL;
- u16_t cmdResult = 0;
- u32_t adcFrequency = 0;
- u32_t iqmRcRate = 0;
- u16_t lcSymbolFreq = 0;
- u16_t iqmRcStretch = 0;
- u16_t setEnvParameters = 0;
- u16_t setParamParameters[2] = { 0 };
+ u16 cmdResult = 0;
+ u32 adcFrequency = 0;
+ u32 iqmRcRate = 0;
+ u16 lcSymbolFreq = 0;
+ u16 iqmRcStretch = 0;
+ u16 setEnvParameters = 0;
+ u16 setParamParameters[2] = { 0 };
DRXJSCUCmd_t cmdSCU = { /* command */ 0,
/* parameterLen */ 0,
/* resultLen */ 0,
/* parameter */ NULL,
/* result */ NULL
};
- const u8_t qamA_taps[] = {
+ const u8 qamA_taps[] = {
DRXJ_16TO8(-1), /* re0 */
DRXJ_16TO8(1), /* re1 */
DRXJ_16TO8(1), /* re2 */
DRXJ_16TO8(-40), /* re26 */
DRXJ_16TO8(619) /* re27 */
};
- const u8_t qamB64_taps[] = {
+ const u8 qamB64_taps[] = {
DRXJ_16TO8(0), /* re0 */
DRXJ_16TO8(-2), /* re1 */
DRXJ_16TO8(1), /* re2 */
DRXJ_16TO8(-46), /* re26 */
DRXJ_16TO8(614) /* re27 */
};
- const u8_t qamB256_taps[] = {
+ const u8 qamB256_taps[] = {
DRXJ_16TO8(-2), /* re0 */
DRXJ_16TO8(4), /* re1 */
DRXJ_16TO8(1), /* re2 */
DRXJ_16TO8(-32), /* re26 */
DRXJ_16TO8(628) /* re27 */
};
- const u8_t qamC_taps[] = {
+ const u8 qamC_taps[] = {
DRXJ_16TO8(-3), /* re0 */
DRXJ_16TO8(3), /* re1 */
DRXJ_16TO8(2), /* re2 */
((adcFrequency % channel->symbolrate),
channel->symbolrate) >> 7) - (1 << 23);
lcSymbolFreq =
- (u16_t) (Frac28
+ (u16) (Frac28
(channel->symbolrate +
(adcFrequency >> 13),
adcFrequency) >> 16);
if ((op & QAM_SET_OP_ALL) || (op & QAM_SET_OP_CONSTELLATION)) {
if (extAttr->standard == DRX_STANDARD_ITU_A) {
WRB(devAddr, IQM_CF_TAP_RE0__A, sizeof(qamA_taps),
- ((pu8_t) qamA_taps));
+ ((u8 *) qamA_taps));
WRB(devAddr, IQM_CF_TAP_IM0__A, sizeof(qamA_taps),
- ((pu8_t) qamA_taps));
+ ((u8 *) qamA_taps));
} else if (extAttr->standard == DRX_STANDARD_ITU_B) {
switch (channel->constellation) {
case DRX_CONSTELLATION_QAM64:
WRB(devAddr, IQM_CF_TAP_RE0__A,
- sizeof(qamB64_taps), ((pu8_t) qamB64_taps));
+ sizeof(qamB64_taps), ((u8 *) qamB64_taps));
WRB(devAddr, IQM_CF_TAP_IM0__A,
- sizeof(qamB64_taps), ((pu8_t) qamB64_taps));
+ sizeof(qamB64_taps), ((u8 *) qamB64_taps));
break;
case DRX_CONSTELLATION_QAM256:
WRB(devAddr, IQM_CF_TAP_RE0__A,
sizeof(qamB256_taps),
- ((pu8_t) qamB256_taps));
+ ((u8 *) qamB256_taps));
WRB(devAddr, IQM_CF_TAP_IM0__A,
sizeof(qamB256_taps),
- ((pu8_t) qamB256_taps));
+ ((u8 *) qamB256_taps));
break;
default:
return (DRX_STS_ERROR);
}
} else if (extAttr->standard == DRX_STANDARD_ITU_C) {
WRB(devAddr, IQM_CF_TAP_RE0__A, sizeof(qamC_taps),
- ((pu8_t) qamC_taps));
+ ((u8 *) qamC_taps));
WRB(devAddr, IQM_CF_TAP_IM0__A, sizeof(qamC_taps),
- ((pu8_t) qamC_taps));
+ ((u8 *) qamC_taps));
}
/* SETP 4: constellation specific setup */
CtrlGetQAMSigQuality(pDRXDemodInstance_t demod, pDRXSigQuality_t sigQuality);
static DRXStatus_t qamFlipSpec(pDRXDemodInstance_t demod, pDRXChannel_t channel)
{
- u32_t iqmFsRateOfs = 0;
- u32_t iqmFsRateLo = 0;
- u16_t qamCtlEna = 0;
- u16_t data = 0;
- u16_t equMode = 0;
- u16_t fsmState = 0;
+ u32 iqmFsRateOfs = 0;
+ u32 iqmFsRateLo = 0;
+ u16 qamCtlEna = 0;
+ u16 data = 0;
+ u16 equMode = 0;
+ u16 fsmState = 0;
int i = 0;
int ofsofs = 0;
struct i2c_device_addr *devAddr = NULL;
DRXFrequency_t tunerFreqOffset, pDRXLockStatus_t lockStatus)
{
DRXSigQuality_t sigQuality;
- u16_t data = 0;
- u32_t state = NO_LOCK;
- u32_t startTime = 0;
- u32_t dLockedTime = 0;
+ u16 data = 0;
+ u32 state = NO_LOCK;
+ u32 startTime = 0;
+ u32 dLockedTime = 0;
pDRXJData_t extAttr = NULL;
- u32_t timeoutOfs = 0;
+ u32 timeoutOfs = 0;
/* external attributes for storing aquired channel constellation */
extAttr = (pDRXJData_t) demod->myExtAttr;
DRXFrequency_t tunerFreqOffset, pDRXLockStatus_t lockStatus)
{
DRXSigQuality_t sigQuality;
- u32_t state = NO_LOCK;
- u32_t startTime = 0;
- u32_t dLockedTime = 0;
+ u32 state = NO_LOCK;
+ u32 startTime = 0;
+ u32 dLockedTime = 0;
pDRXJData_t extAttr = NULL;
- u32_t timeoutOfs = DRXJ_QAM_DEMOD_LOCK_EXT_WAITTIME;
+ u32 timeoutOfs = DRXJ_QAM_DEMOD_LOCK_EXT_WAITTIME;
/* external attributes for storing aquired channel constellation */
extAttr = (pDRXJData_t) demod->myExtAttr;
extAttr->mirror = channel->mirror;
}
{
- u16_t qamCtlEna = 0;
+ u16 qamCtlEna = 0;
RR16(demod->myI2CDevAddr,
SCU_RAM_QAM_CTL_ENA__A,
&qamCtlEna);
extAttr->mirror = channel->mirror;
}
{
- u16_t qamCtlEna = 0;
+ u16 qamCtlEna = 0;
RR16(demod->myI2CDevAddr,
SCU_RAM_QAM_CTL_ENA__A, &qamCtlEna);
WR16(demod->myI2CDevAddr,
static DRXStatus_t
GetQAMRSErrCount(struct i2c_device_addr *devAddr, pDRXJRSErrors_t RSErrors)
{
- u16_t nrBitErrors = 0,
+ u16 nrBitErrors = 0,
nrSymbolErrors = 0,
nrPacketErrors = 0, nrFailures = 0, nrSncParFailCount = 0;
DRXConstellation_t constellation = DRX_CONSTELLATION_UNKNOWN;
DRXJRSErrors_t measuredRSErrors = { 0, 0, 0, 0, 0 };
- u32_t preBitErrRS = 0; /* pre RedSolomon Bit Error Rate */
- u32_t postBitErrRS = 0; /* post RedSolomon Bit Error Rate */
- u32_t pktErrs = 0; /* no of packet errors in RS */
- u16_t qamSlErrPower = 0; /* accumulated error between raw and sliced symbols */
- u16_t qsymErrVD = 0; /* quadrature symbol errors in QAM_VD */
- u16_t fecOcPeriod = 0; /* SNC sync failure measurement period */
- u16_t fecRsPrescale = 0; /* ReedSolomon Measurement Prescale */
- u16_t fecRsPeriod = 0; /* Value for corresponding I2C register */
+ u32 preBitErrRS = 0; /* pre RedSolomon Bit Error Rate */
+ u32 postBitErrRS = 0; /* post RedSolomon Bit Error Rate */
+ u32 pktErrs = 0; /* no of packet errors in RS */
+ u16 qamSlErrPower = 0; /* accumulated error between raw and sliced symbols */
+ u16 qsymErrVD = 0; /* quadrature symbol errors in QAM_VD */
+ u16 fecOcPeriod = 0; /* SNC sync failure measurement period */
+ u16 fecRsPrescale = 0; /* ReedSolomon Measurement Prescale */
+ u16 fecRsPeriod = 0; /* Value for corresponding I2C register */
/* calculation constants */
- u32_t rsBitCnt = 0; /* RedSolomon Bit Count */
- u32_t qamSlSigPower = 0; /* used for MER, depends of QAM constellation */
+ u32 rsBitCnt = 0; /* RedSolomon Bit Count */
+ u32 qamSlSigPower = 0; /* used for MER, depends of QAM constellation */
/* intermediate results */
- u32_t e = 0; /* exponent value used for QAM BER/SER */
- u32_t m = 0; /* mantisa value used for QAM BER/SER */
- u32_t berCnt = 0; /* BER count */
+ u32 e = 0; /* exponent value used for QAM BER/SER */
+ u32 m = 0; /* mantisa value used for QAM BER/SER */
+ u32 berCnt = 0; /* BER count */
/* signal quality info */
- u32_t qamSlMer = 0; /* QAM MER */
- u32_t qamPreRSBer = 0; /* Pre RedSolomon BER */
- u32_t qamPostRSBer = 0; /* Post RedSolomon BER */
- u32_t qamVDSer = 0; /* ViterbiDecoder SER */
- u16_t qamVdPrescale = 0; /* Viterbi Measurement Prescale */
- u16_t qamVdPeriod = 0; /* Viterbi Measurement period */
- u32_t vdBitCnt = 0; /* ViterbiDecoder Bit Count */
+ u32 qamSlMer = 0; /* QAM MER */
+ u32 qamPreRSBer = 0; /* Pre RedSolomon BER */
+ u32 qamPostRSBer = 0; /* Post RedSolomon BER */
+ u32 qamVDSer = 0; /* ViterbiDecoder SER */
+ u16 qamVdPrescale = 0; /* Viterbi Measurement Prescale */
+ u16 qamVdPeriod = 0; /* Viterbi Measurement period */
+ u32 vdBitCnt = 0; /* ViterbiDecoder Bit Count */
/* get device basic information */
devAddr = demod->myI2CDevAddr;
else
qamSlMer =
Log10Times100(qamSlSigPower) -
- Log10Times100((u32_t) qamSlErrPower);
+ Log10Times100((u32) qamSlErrPower);
/* ----------------------------------------- */
/* Pre Viterbi Symbol Error Rate Calculation */
/* pre RS BER is good if it is below 3.5e-4 */
/* get the register values */
- preBitErrRS = (u32_t) measuredRSErrors.nrBitErrors;
- pktErrs = postBitErrRS = (u32_t) measuredRSErrors.nrSncParFailCount;
+ preBitErrRS = (u32) measuredRSErrors.nrBitErrors;
+ pktErrs = postBitErrRS = (u32) measuredRSErrors.nrSncParFailCount;
/* Extract the Exponent and the Mantisa of the */
/* pre Reed-Solomon bit error count */
qamPostRSBer = e / m;
/* fill signal quality data structure */
- sigQuality->MER = ((u16_t) qamSlMer);
+ sigQuality->MER = ((u16) qamSlMer);
if (extAttr->standard == DRX_STANDARD_ITU_B) {
sigQuality->preViterbiBER = qamVDSer;
} else {
}
sigQuality->postViterbiBER = qamPreRSBer;
sigQuality->postReedSolomonBER = qamPostRSBer;
- sigQuality->scaleFactorBER = ((u32_t) 1000000);
+ sigQuality->scaleFactorBER = ((u32) 1000000);
#ifdef DRXJ_SIGNAL_ACCUM_ERR
CHK_ERROR(GetAccPktErr(demod, &sigQuality->packetError));
#else
- sigQuality->packetError = ((u16_t) pktErrs);
+ sigQuality->packetError = ((u16) pktErrs);
#endif
return (DRX_STS_OK);
static DRXStatus_t
CtrlGetQAMConstel(pDRXDemodInstance_t demod, pDRXComplex_t complexNr)
{
- u16_t fecOcOcrMode = 0;
+ u16 fecOcOcrMode = 0;
/**< FEC OCR grabber configuration */
- u16_t qamSlCommMb = 0;/**< QAM SL MB configuration */
- u16_t qamSlCommMbInit = 0;
+ u16 qamSlCommMb = 0;/**< QAM SL MB configuration */
+ u16 qamSlCommMbInit = 0;
/**< QAM SL MB intial configuration */
- u16_t im = 0; /**< constellation Im part */
- u16_t re = 0; /**< constellation Re part */
- u32_t data = 0;
+ u16 im = 0; /**< constellation Im part */
+ u16 re = 0; /**< constellation Re part */
+ u32 data = 0;
struct i2c_device_addr *devAddr = NULL;
/**< device address */
/* read data */
RR32(devAddr, FEC_OC_OCR_GRAB_RD0__A, &data);
- re = (u16_t) (data & FEC_OC_OCR_GRAB_RD0__M);
- im = (u16_t) ((data >> 16) & FEC_OC_OCR_GRAB_RD1__M);
+ re = (u16) (data & FEC_OC_OCR_GRAB_RD0__M);
+ im = (u16) ((data >> 16) & FEC_OC_OCR_GRAB_RD1__M);
/* TODO: */
/* interpret data (re & im) according to the Monitor bus mapping ?? */
if ((im & 0x0200) == 0x0200) {
im |= 0xFC00;
}
- complexNr->re = ((s16_t) re);
- complexNr->im = ((s16_t) im);
+ complexNr->re = ((s16) re);
+ complexNr->im = ((s16) im);
/* Restore MB (Monitor bus) */
WR16(devAddr, QAM_SL_COMM_MB__A, qamSlCommMbInit);
/* bypass fast carrier recovery */
if (forceUpdate) {
- u16_t data = 0;
+ u16 data = 0;
RR16(devAddr, IQM_RT_ROT_BP__A, &data);
- data &= (~((u16_t) IQM_RT_ROT_BP_ROT_OFF__M));
+ data &= (~((u16) IQM_RT_ROT_BP_ROT_OFF__M));
if (extAttr->phaseCorrectionBypass) {
data |= IQM_RT_ROT_BP_ROT_OFF_OFF;
} else {
/* SIF attenuation */
if (forceUpdate ||
((extAttr->atvCfgChangedFlags & DRXJ_ATV_CHANGED_SIF_ATT) != 0)) {
- u16_t attenuation = 0;
+ u16 attenuation = 0;
switch (extAttr->sifAttenuation) {
case DRXJ_SIF_ATTENUATION_0DB:
/* SIF & CVBS enable */
if (forceUpdate ||
((extAttr->atvCfgChangedFlags & DRXJ_ATV_CHANGED_OUTPUT) != 0)) {
- u16_t data = 0;
+ u16 data = 0;
RR16(devAddr, ATV_TOP_STDBY__A, &data);
if (extAttr->enableCVBSOutput) {
(coef->coef1 > (ATV_TOP_EQU1_EQU_C1__M / 2)) ||
(coef->coef2 > (ATV_TOP_EQU2_EQU_C2__M / 2)) ||
(coef->coef3 > (ATV_TOP_EQU3_EQU_C3__M / 2)) ||
- (coef->coef0 < ((s16_t) ~ (ATV_TOP_EQU0_EQU_C0__M >> 1))) ||
- (coef->coef1 < ((s16_t) ~ (ATV_TOP_EQU1_EQU_C1__M >> 1))) ||
- (coef->coef2 < ((s16_t) ~ (ATV_TOP_EQU2_EQU_C2__M >> 1))) ||
- (coef->coef3 < ((s16_t) ~ (ATV_TOP_EQU3_EQU_C3__M >> 1)))) {
+ (coef->coef0 < ((s16) ~ (ATV_TOP_EQU0_EQU_C0__M >> 1))) ||
+ (coef->coef1 < ((s16) ~ (ATV_TOP_EQU1_EQU_C1__M >> 1))) ||
+ (coef->coef2 < ((s16) ~ (ATV_TOP_EQU2_EQU_C2__M >> 1))) ||
+ (coef->coef3 < ((s16) ~ (ATV_TOP_EQU3_EQU_C3__M >> 1)))) {
return (DRX_STS_INVALID_ARG);
}
/* Check arguments */
if ((settings == NULL) ||
- ((settings->peakFilter) < (s16_t) (-8)) ||
- ((settings->peakFilter) > (s16_t) (15)) ||
+ ((settings->peakFilter) < (s16) (-8)) ||
+ ((settings->peakFilter) > (s16) (15)) ||
((settings->noiseFilter) > 15)) {
return (DRX_STS_INVALID_ARG);
}
static DRXStatus_t
CtrlGetCfgAtvOutput(pDRXDemodInstance_t demod, pDRXJCfgAtvOutput_t outputCfg)
{
- u16_t data = 0;
+ u16 data = 0;
/* Check arguments */
if (outputCfg == NULL) {
{
struct i2c_device_addr *devAddr = NULL;
pDRXJData_t extAttr = NULL;
- u16_t data = 0;
- u32_t tmp = 0;
+ u16 data = 0;
+ u32 tmp = 0;
/* Check arguments */
if (agcStatus == NULL) {
IQM_AF_AGC_RF__A * 27 is 20 bits worst case.
*/
RR16(devAddr, IQM_AF_AGC_RF__A, &data);
- tmp = ((u32_t) data) * 27 - ((u32_t) (data >> 2)); /* nA */
- agcStatus->rfAgcGain = (u16_t) (tmp / 1000); /* uA */
+ tmp = ((u32) data) * 27 - ((u32) (data >> 2)); /* nA */
+ agcStatus->rfAgcGain = (u16) (tmp / 1000); /* uA */
/* rounding */
if (tmp % 1000 >= 500) {
(agcStatus->rfAgcGain)++;
IQM_AF_AGC_IF__A * 27 is 20 bits worst case.
*/
RR16(devAddr, IQM_AF_AGC_IF__A, &data);
- tmp = ((u32_t) data) * 27 - ((u32_t) (data >> 2)); /* nA */
- agcStatus->ifAgcGain = (u16_t) (tmp / 1000); /* uA */
+ tmp = ((u32) data) * 27 - ((u32) (data >> 2)); /* nA */
+ agcStatus->ifAgcGain = (u16) (tmp / 1000); /* uA */
/* rounding */
if (tmp % 1000 >= 500) {
(agcStatus->ifAgcGain)++;
data++;
}
data >>= 1;
- agcStatus->videoAgcGain = ((s16_t) data) - 75; /* 0.1 dB */
+ agcStatus->videoAgcGain = ((s16) data) - 75; /* 0.1 dB */
/*
audioGain = (SCU_RAM_ATV_SIF_GAIN__A -8)* 0.05 (dB)
data++;
}
data >>= 1;
- agcStatus->audioAgcGain = ((s16_t) data) - 4; /* 0.1 dB */
+ agcStatus->audioAgcGain = ((s16) data) - 4; /* 0.1 dB */
/* Loop gain's */
SARR16(devAddr, SCU_RAM_AGC_KI__A, &data);
/* *parameter */ NULL,
/* *result */ NULL
};
- u16_t cmdResult = 0;
+ u16 cmdResult = 0;
pDRXJData_t extAttr = NULL;
devAddr = demod->myI2CDevAddr;
Still to check if this will work; DRXJ_16TO8 macro may cause
trouble ?
*/
- const u8_t ntsc_taps_re[] = {
+ const u8 ntsc_taps_re[] = {
DRXJ_16TO8(-12), /* re0 */
DRXJ_16TO8(-9), /* re1 */
DRXJ_16TO8(9), /* re2 */
DRXJ_16TO8(50), /* re26 */
DRXJ_16TO8(679) /* re27 */
};
- const u8_t ntsc_taps_im[] = {
+ const u8 ntsc_taps_im[] = {
DRXJ_16TO8(11), /* im0 */
DRXJ_16TO8(1), /* im1 */
DRXJ_16TO8(-10), /* im2 */
DRXJ_16TO8(553), /* im26 */
DRXJ_16TO8(302) /* im27 */
};
- const u8_t bg_taps_re[] = {
+ const u8 bg_taps_re[] = {
DRXJ_16TO8(-18), /* re0 */
DRXJ_16TO8(18), /* re1 */
DRXJ_16TO8(19), /* re2 */
DRXJ_16TO8(172), /* re26 */
DRXJ_16TO8(801) /* re27 */
};
- const u8_t bg_taps_im[] = {
+ const u8 bg_taps_im[] = {
DRXJ_16TO8(-24), /* im0 */
DRXJ_16TO8(-10), /* im1 */
DRXJ_16TO8(9), /* im2 */
DRXJ_16TO8(687), /* im26 */
DRXJ_16TO8(877) /* im27 */
};
- const u8_t dk_i_l_lp_taps_re[] = {
+ const u8 dk_i_l_lp_taps_re[] = {
DRXJ_16TO8(-23), /* re0 */
DRXJ_16TO8(9), /* re1 */
DRXJ_16TO8(16), /* re2 */
DRXJ_16TO8(206), /* re26 */
DRXJ_16TO8(894) /* re27 */
};
- const u8_t dk_i_l_lp_taps_im[] = {
+ const u8 dk_i_l_lp_taps_im[] = {
DRXJ_16TO8(-8), /* im0 */
DRXJ_16TO8(-20), /* im1 */
DRXJ_16TO8(17), /* im2 */
DRXJ_16TO8(657), /* im26 */
DRXJ_16TO8(1023) /* im27 */
};
- const u8_t fm_taps_re[] = {
+ const u8 fm_taps_re[] = {
DRXJ_16TO8(0), /* re0 */
DRXJ_16TO8(0), /* re1 */
DRXJ_16TO8(0), /* re2 */
DRXJ_16TO8(0), /* re26 */
DRXJ_16TO8(0) /* re27 */
};
- const u8_t fm_taps_im[] = {
+ const u8 fm_taps_im[] = {
DRXJ_16TO8(-6), /* im0 */
DRXJ_16TO8(2), /* im1 */
DRXJ_16TO8(14), /* im2 */
/* *parameter */ NULL,
/* *result */ NULL
};
- u16_t cmdResult = 0;
- u16_t cmdParam = 0;
+ u16 cmdResult = 0;
+ u16 cmdParam = 0;
#ifdef DRXJ_SPLIT_UCODE_UPLOAD
DRXUCodeInfo_t ucodeInfo;
pDRXCommonAttr_t commonAttr = NULL;
WR16(devAddr, IQM_RT_LO_INCR__A, IQM_RT_LO_INCR_MN);
WR16(devAddr, IQM_CF_MIDTAP__A, IQM_CF_MIDTAP_RE__M);
WRB(devAddr, IQM_CF_TAP_RE0__A, sizeof(ntsc_taps_re),
- ((pu8_t) ntsc_taps_re));
+ ((u8 *) ntsc_taps_re));
WRB(devAddr, IQM_CF_TAP_IM0__A, sizeof(ntsc_taps_im),
- ((pu8_t) ntsc_taps_im));
+ ((u8 *) ntsc_taps_im));
WR16(devAddr, ATV_TOP_CR_AMP_TH__A, ATV_TOP_CR_AMP_TH_MN);
WR16(devAddr, ATV_TOP_CR_CONT__A,
WR16(devAddr, IQM_RT_LO_INCR__A, 2994);
WR16(devAddr, IQM_CF_MIDTAP__A, 0);
WRB(devAddr, IQM_CF_TAP_RE0__A, sizeof(fm_taps_re),
- ((pu8_t) fm_taps_re));
+ ((u8 *) fm_taps_re));
WRB(devAddr, IQM_CF_TAP_IM0__A, sizeof(fm_taps_im),
- ((pu8_t) fm_taps_im));
+ ((u8 *) fm_taps_im));
WR16(devAddr, ATV_TOP_STD__A, (ATV_TOP_STD_MODE_FM |
ATV_TOP_STD_VID_POL_FM));
WR16(devAddr, ATV_TOP_MOD_CONTROL__A, 0);
WR16(devAddr, IQM_RT_LO_INCR__A, 1820); /* TODO check with IS */
WR16(devAddr, IQM_CF_MIDTAP__A, IQM_CF_MIDTAP_RE__M);
WRB(devAddr, IQM_CF_TAP_RE0__A, sizeof(bg_taps_re),
- ((pu8_t) bg_taps_re));
+ ((u8 *) bg_taps_re));
WRB(devAddr, IQM_CF_TAP_IM0__A, sizeof(bg_taps_im),
- ((pu8_t) bg_taps_im));
+ ((u8 *) bg_taps_im));
WR16(devAddr, ATV_TOP_VID_AMP__A, ATV_TOP_VID_AMP_BG);
WR16(devAddr, ATV_TOP_CR_AMP_TH__A, ATV_TOP_CR_AMP_TH_BG);
WR16(devAddr, ATV_TOP_CR_CONT__A,
WR16(devAddr, IQM_RT_LO_INCR__A, 2225); /* TODO check with IS */
WR16(devAddr, IQM_CF_MIDTAP__A, IQM_CF_MIDTAP_RE__M);
WRB(devAddr, IQM_CF_TAP_RE0__A, sizeof(dk_i_l_lp_taps_re),
- ((pu8_t) dk_i_l_lp_taps_re));
+ ((u8 *) dk_i_l_lp_taps_re));
WRB(devAddr, IQM_CF_TAP_IM0__A, sizeof(dk_i_l_lp_taps_im),
- ((pu8_t) dk_i_l_lp_taps_im));
+ ((u8 *) dk_i_l_lp_taps_im));
WR16(devAddr, ATV_TOP_CR_AMP_TH__A, ATV_TOP_CR_AMP_TH_DK);
WR16(devAddr, ATV_TOP_VID_AMP__A, ATV_TOP_VID_AMP_DK);
WR16(devAddr, ATV_TOP_CR_CONT__A,
WR16(devAddr, IQM_RT_LO_INCR__A, 2225); /* TODO check with IS */
WR16(devAddr, IQM_CF_MIDTAP__A, IQM_CF_MIDTAP_RE__M);
WRB(devAddr, IQM_CF_TAP_RE0__A, sizeof(dk_i_l_lp_taps_re),
- ((pu8_t) dk_i_l_lp_taps_re));
+ ((u8 *) dk_i_l_lp_taps_re));
WRB(devAddr, IQM_CF_TAP_IM0__A, sizeof(dk_i_l_lp_taps_im),
- ((pu8_t) dk_i_l_lp_taps_im));
+ ((u8 *) dk_i_l_lp_taps_im));
WR16(devAddr, ATV_TOP_CR_AMP_TH__A, ATV_TOP_CR_AMP_TH_I);
WR16(devAddr, ATV_TOP_VID_AMP__A, ATV_TOP_VID_AMP_I);
WR16(devAddr, ATV_TOP_CR_CONT__A,
WR16(devAddr, ATV_TOP_VID_AMP__A, ATV_TOP_VID_AMP_L);
WR16(devAddr, IQM_CF_MIDTAP__A, IQM_CF_MIDTAP_RE__M);
WRB(devAddr, IQM_CF_TAP_RE0__A, sizeof(dk_i_l_lp_taps_re),
- ((pu8_t) dk_i_l_lp_taps_re));
+ ((u8 *) dk_i_l_lp_taps_re));
WRB(devAddr, IQM_CF_TAP_IM0__A, sizeof(dk_i_l_lp_taps_im),
- ((pu8_t) dk_i_l_lp_taps_im));
+ ((u8 *) dk_i_l_lp_taps_im));
WR16(devAddr, ATV_TOP_CR_AMP_TH__A, 0x2); /* TODO check with IS */
WR16(devAddr, ATV_TOP_CR_CONT__A,
(ATV_TOP_CR_CONT_CR_P_L |
WR16(devAddr, IQM_RT_LO_INCR__A, 2225); /* TODO check with IS */
WR16(devAddr, IQM_CF_MIDTAP__A, IQM_CF_MIDTAP_RE__M);
WRB(devAddr, IQM_CF_TAP_RE0__A, sizeof(dk_i_l_lp_taps_re),
- ((pu8_t) dk_i_l_lp_taps_re));
+ ((u8 *) dk_i_l_lp_taps_re));
WRB(devAddr, IQM_CF_TAP_IM0__A, sizeof(dk_i_l_lp_taps_im),
- ((pu8_t) dk_i_l_lp_taps_im));
+ ((u8 *) dk_i_l_lp_taps_im));
WR16(devAddr, ATV_TOP_CR_AMP_TH__A, 0x2); /* TODO check with IS */
WR16(devAddr, ATV_TOP_CR_CONT__A,
(ATV_TOP_CR_CONT_CR_P_LP |
/* parameter */ NULL,
/* result */ NULL
};
- u16_t cmdResult = 0;
+ u16 cmdResult = 0;
pDRXJData_t extAttr = NULL;
struct i2c_device_addr *devAddr = NULL;
case DRX_STANDARD_PAL_SECAM_I:
case DRX_STANDARD_PAL_SECAM_L:
{
- u16_t measuredOffset = 0;
+ u16 measuredOffset = 0;
/* get measured frequency offset */
RR16(devAddr, ATV_TOP_CR_FREQ__A, &measuredOffset);
measuredOffset |= 0xFF80;
}
offset +=
- (DRXFrequency_t) (((s16_t) measuredOffset) * 10);
+ (DRXFrequency_t) (((s16) measuredOffset) * 10);
break;
}
case DRX_STANDARD_PAL_SECAM_LP:
{
- u16_t measuredOffset = 0;
+ u16 measuredOffset = 0;
/* get measured frequency offset */
RR16(devAddr, ATV_TOP_CR_FREQ__A, &measuredOffset);
measuredOffset |= 0xFF80;
}
offset -=
- (DRXFrequency_t) (((s16_t) measuredOffset) * 10);
+ (DRXFrequency_t) (((s16) measuredOffset) * 10);
}
break;
case DRX_STANDARD_FM:
* is not used ?
*/
static DRXStatus_t
-GetAtvSigStrength(pDRXDemodInstance_t demod, pu16_t sigStrength)
+GetAtvSigStrength(pDRXDemodInstance_t demod, u16 *sigStrength)
{
struct i2c_device_addr *devAddr = NULL;
pDRXJData_t extAttr = NULL;
/* All weights must add up to 100 (%)
TODO: change weights when IF ctrl is available */
- u32_t digitalWeight = 50; /* 0 .. 100 */
- u32_t rfWeight = 50; /* 0 .. 100 */
- u32_t ifWeight = 0; /* 0 .. 100 */
-
- u16_t digitalCurrGain = 0;
- u32_t digitalMaxGain = 0;
- u32_t digitalMinGain = 0;
- u16_t rfCurrGain = 0;
- u32_t rfMaxGain = 0x800; /* taken from ucode */
- u32_t rfMinGain = 0x7fff;
- u16_t ifCurrGain = 0;
- u32_t ifMaxGain = 0x800; /* taken from ucode */
- u32_t ifMinGain = 0x7fff;
-
- u32_t digitalStrength = 0; /* 0.. 100 */
- u32_t rfStrength = 0; /* 0.. 100 */
- u32_t ifStrength = 0; /* 0.. 100 */
+ u32 digitalWeight = 50; /* 0 .. 100 */
+ u32 rfWeight = 50; /* 0 .. 100 */
+ u32 ifWeight = 0; /* 0 .. 100 */
+
+ u16 digitalCurrGain = 0;
+ u32 digitalMaxGain = 0;
+ u32 digitalMinGain = 0;
+ u16 rfCurrGain = 0;
+ u32 rfMaxGain = 0x800; /* taken from ucode */
+ u32 rfMinGain = 0x7fff;
+ u16 ifCurrGain = 0;
+ u32 ifMaxGain = 0x800; /* taken from ucode */
+ u32 ifMinGain = 0x7fff;
+
+ u32 digitalStrength = 0; /* 0.. 100 */
+ u32 rfStrength = 0; /* 0.. 100 */
+ u32 ifStrength = 0; /* 0.. 100 */
devAddr = demod->myI2CDevAddr;
extAttr = (pDRXJData_t) demod->myExtAttr;
/* clipping */
if (digitalCurrGain >= digitalMaxGain)
- digitalCurrGain = (u16_t) digitalMaxGain;
+ digitalCurrGain = (u16) digitalMaxGain;
if (digitalCurrGain <= digitalMinGain)
- digitalCurrGain = (u16_t) digitalMinGain;
+ digitalCurrGain = (u16) digitalMinGain;
if (ifCurrGain <= ifMaxGain)
- ifCurrGain = (u16_t) ifMaxGain;
+ ifCurrGain = (u16) ifMaxGain;
if (ifCurrGain >= ifMinGain)
- ifCurrGain = (u16_t) ifMinGain;
+ ifCurrGain = (u16) ifMinGain;
if (rfCurrGain <= rfMaxGain)
- rfCurrGain = (u16_t) rfMaxGain;
+ rfCurrGain = (u16) rfMaxGain;
if (rfCurrGain >= rfMinGain)
- rfCurrGain = (u16_t) rfMinGain;
+ rfCurrGain = (u16) rfMinGain;
/* TODO: use SCU_RAM_ATV_RAGC_HR__A to shift max and min in case
of clipping at ADC */
/* Digital gain */
/* TODO: ADC clipping not handled */
- digitalStrength = (100 * (digitalMaxGain - (u32_t) digitalCurrGain)) /
+ digitalStrength = (100 * (digitalMaxGain - (u32) digitalCurrGain)) /
(digitalMaxGain - digitalMinGain);
/* TODO: IF gain not implemented yet in microcode, check after impl. */
- ifStrength = (100 * ((u32_t) ifCurrGain - ifMaxGain)) /
+ ifStrength = (100 * ((u32) ifCurrGain - ifMaxGain)) /
(ifMinGain - ifMaxGain);
/* Rf gain */
/* TODO: ADC clipping not handled */
- rfStrength = (100 * ((u32_t) rfCurrGain - rfMaxGain)) /
+ rfStrength = (100 * ((u32) rfCurrGain - rfMaxGain)) /
(rfMinGain - rfMaxGain);
/* Compute a weighted signal strength (in %) */
- *sigStrength = (u16_t) (digitalWeight * digitalStrength +
+ *sigStrength = (u16) (digitalWeight * digitalStrength +
rfWeight * rfStrength + ifWeight * ifStrength);
*sigStrength /= 100;
AtvSigQuality(pDRXDemodInstance_t demod, pDRXSigQuality_t sigQuality)
{
struct i2c_device_addr *devAddr = NULL;
- u16_t qualityIndicator = 0;
+ u16 qualityIndicator = 0;
devAddr = demod->myI2CDevAddr;
* \return DRXStatus_t.
*
*/
-static DRXStatus_t AUDGetModus(pDRXDemodInstance_t demod, pu16_t modus)
+static DRXStatus_t AUDGetModus(pDRXDemodInstance_t demod, u16 *modus)
{
struct i2c_device_addr *devAddr = NULL;
pDRXJData_t extAttr = NULL;
- u16_t rModus = 0;
- u16_t rModusHi = 0;
- u16_t rModusLo = 0;
+ u16 rModus = 0;
+ u16 rModusHi = 0;
+ u16 rModusLo = 0;
if (modus == NULL) {
return DRX_STS_INVALID_ARG;
struct i2c_device_addr *addr = NULL;
pDRXJData_t extAttr = NULL;
- u16_t rRDSArrayCntInit = 0;
- u16_t rRDSArrayCntCheck = 0;
- u16_t rRDSData = 0;
- u16_t RDSDataCnt = 0;
+ u16 rRDSArrayCntInit = 0;
+ u16 rRDSArrayCntCheck = 0;
+ u16 rRDSData = 0;
+ u16 RDSDataCnt = 0;
addr = (struct i2c_device_addr *) demod->myI2CDevAddr;
extAttr = (pDRXJData_t) demod->myExtAttr;
pDRXJData_t extAttr = NULL;
struct i2c_device_addr *devAddr = NULL;
- u16_t rData = 0;
+ u16 rData = 0;
if (status == NULL) {
return DRX_STS_INVALID_ARG;
pDRXJData_t extAttr = NULL;
struct i2c_device_addr *devAddr = NULL;
DRXCfgAudRDS_t rds = { FALSE, {0} };
- u16_t rData = 0;
+ u16 rData = 0;
if (status == NULL) {
return DRX_STS_INVALID_ARG;
/* fmIdent */
RR16(devAddr, AUD_DSP_RD_FM_IDENT_VALUE__A, &rData);
rData >>= AUD_DSP_RD_FM_IDENT_VALUE_FM_IDENT__B;
- status->fmIdent = (s8_t) rData;
+ status->fmIdent = (s8) rData;
return DRX_STS_OK;
rw_error:
struct i2c_device_addr *devAddr = NULL;
pDRXJData_t extAttr = NULL;
- u16_t rVolume = 0;
- u16_t rAVC = 0;
- u16_t rStrengthLeft = 0;
- u16_t rStrengthRight = 0;
+ u16 rVolume = 0;
+ u16 rAVC = 0;
+ u16 rStrengthLeft = 0;
+ u16 rStrengthRight = 0;
if (volume == NULL) {
return DRX_STS_INVALID_ARG;
}
/* reference level */
- volume->avcRefLevel = (u16_t) ((rAVC & AUD_DSP_WR_AVC_AVC_REF_LEV__M) >>
+ volume->avcRefLevel = (u16) ((rAVC & AUD_DSP_WR_AVC_AVC_REF_LEV__M) >>
AUD_DSP_WR_AVC_AVC_REF_LEV__B);
/* read qpeak registers and calculate strength of left and right carrier */
/* QP vaues */
/* left carrier */
RR16(devAddr, AUD_DSP_RD_QPEAK_L__A, &rStrengthLeft);
- volume->strengthLeft = (((s16_t) Log10Times100(rStrengthLeft)) -
+ volume->strengthLeft = (((s16) Log10Times100(rStrengthLeft)) -
AUD_CARRIER_STRENGTH_QP_0DB_LOG10T100) / 5;
/* right carrier */
RR16(devAddr, AUD_DSP_RD_QPEAK_R__A, &rStrengthRight);
- volume->strengthRight = (((s16_t) Log10Times100(rStrengthRight)) -
+ volume->strengthRight = (((s16) Log10Times100(rStrengthRight)) -
AUD_CARRIER_STRENGTH_QP_0DB_LOG10T100) / 5;
return DRX_STS_OK;
struct i2c_device_addr *devAddr = NULL;
pDRXJData_t extAttr = NULL;
- u16_t wVolume = 0;
- u16_t wAVC = 0;
+ u16 wVolume = 0;
+ u16 wAVC = 0;
if (volume == NULL) {
return DRX_STS_INVALID_ARG;
RR16(devAddr, AUD_DSP_WR_VOLUME__A, &wVolume);
/* clear the volume mask */
- wVolume &= (u16_t) ~ AUD_DSP_WR_VOLUME_VOL_MAIN__M;
+ wVolume &= (u16) ~ AUD_DSP_WR_VOLUME_VOL_MAIN__M;
if (volume->mute == TRUE) {
/* mute */
/* mute overrules volume */
- wVolume |= (u16_t) (0);
+ wVolume |= (u16) (0);
} else {
- wVolume |= (u16_t) ((volume->volume + AUD_VOLUME_ZERO_DB) <<
+ wVolume |= (u16) ((volume->volume + AUD_VOLUME_ZERO_DB) <<
AUD_DSP_WR_VOLUME_VOL_MAIN__B);
}
RR16(devAddr, AUD_DSP_WR_AVC__A, &wAVC);
/* clear masks that require writing */
- wAVC &= (u16_t) ~ AUD_DSP_WR_AVC_AVC_ON__M;
- wAVC &= (u16_t) ~ AUD_DSP_WR_AVC_AVC_DECAY__M;
+ wAVC &= (u16) ~ AUD_DSP_WR_AVC_AVC_ON__M;
+ wAVC &= (u16) ~ AUD_DSP_WR_AVC_AVC_DECAY__M;
if (volume->avcMode == DRX_AUD_AVC_OFF) {
wAVC |= (AUD_DSP_WR_AVC_AVC_ON_OFF);
}
/* max attenuation */
- wAVC &= (u16_t) ~ AUD_DSP_WR_AVC_AVC_MAX_ATT__M;
+ wAVC &= (u16) ~ AUD_DSP_WR_AVC_AVC_MAX_ATT__M;
switch (volume->avcMaxAtten) {
case DRX_AUD_AVC_MAX_ATTEN_12DB:
wAVC |= AUD_DSP_WR_AVC_AVC_MAX_ATT_12DB;
}
/* max gain */
- wAVC &= (u16_t) ~ AUD_DSP_WR_AVC_AVC_MAX_GAIN__M;
+ wAVC &= (u16) ~ AUD_DSP_WR_AVC_AVC_MAX_GAIN__M;
switch (volume->avcMaxGain) {
case DRX_AUD_AVC_MAX_GAIN_0DB:
wAVC |= AUD_DSP_WR_AVC_AVC_MAX_GAIN_0DB;
return DRX_STS_INVALID_ARG;
}
- wAVC &= (u16_t) ~ AUD_DSP_WR_AVC_AVC_REF_LEV__M;
- wAVC |= (u16_t) (volume->avcRefLevel << AUD_DSP_WR_AVC_AVC_REF_LEV__B);
+ wAVC &= (u16) ~ AUD_DSP_WR_AVC_AVC_REF_LEV__M;
+ wAVC |= (u16) (volume->avcRefLevel << AUD_DSP_WR_AVC_AVC_REF_LEV__B);
WR16(devAddr, AUD_DSP_WR_AVC__A, wAVC);
struct i2c_device_addr *devAddr = NULL;
pDRXJData_t extAttr = NULL;
- u16_t wI2SConfig = 0;
- u16_t rI2SFreq = 0;
+ u16 wI2SConfig = 0;
+ u16 rI2SFreq = 0;
if (output == NULL) {
return DRX_STS_INVALID_ARG;
struct i2c_device_addr *devAddr = NULL;
pDRXJData_t extAttr = NULL;
- u16_t wI2SConfig = 0;
- u16_t wI2SPadsDataDa = 0;
- u16_t wI2SPadsDataCl = 0;
- u16_t wI2SPadsDataWs = 0;
- u32_t wI2SFreq = 0;
+ u16 wI2SConfig = 0;
+ u16 wI2SPadsDataDa = 0;
+ u16 wI2SPadsDataCl = 0;
+ u16 wI2SPadsDataWs = 0;
+ u32 wI2SFreq = 0;
if (output == NULL) {
return DRX_STS_INVALID_ARG;
RR16(devAddr, AUD_DEM_RAM_I2S_CONFIG2__A, &wI2SConfig);
/* I2S mode */
- wI2SConfig &= (u16_t) ~ AUD_DEM_WR_I2S_CONFIG2_I2S_SLV_MST__M;
+ wI2SConfig &= (u16) ~ AUD_DEM_WR_I2S_CONFIG2_I2S_SLV_MST__M;
switch (output->mode) {
case DRX_I2S_MODE_MASTER:
}
/* I2S format */
- wI2SConfig &= (u16_t) ~ AUD_DEM_WR_I2S_CONFIG2_I2S_WS_MODE__M;
+ wI2SConfig &= (u16) ~ AUD_DEM_WR_I2S_CONFIG2_I2S_WS_MODE__M;
switch (output->format) {
case DRX_I2S_FORMAT_WS_ADVANCED:
}
/* I2S word length */
- wI2SConfig &= (u16_t) ~ AUD_DEM_WR_I2S_CONFIG2_I2S_WORD_LEN__M;
+ wI2SConfig &= (u16) ~ AUD_DEM_WR_I2S_CONFIG2_I2S_WORD_LEN__M;
switch (output->wordLength) {
case DRX_I2S_WORDLENGTH_16:
}
/* I2S polarity */
- wI2SConfig &= (u16_t) ~ AUD_DEM_WR_I2S_CONFIG2_I2S_WS_POL__M;
+ wI2SConfig &= (u16) ~ AUD_DEM_WR_I2S_CONFIG2_I2S_WS_POL__M;
switch (output->polarity) {
case DRX_I2S_POLARITY_LEFT:
wI2SConfig |= AUD_DEM_WR_I2S_CONFIG2_I2S_WS_POL_LEFT_HIGH;
}
/* I2S output enabled */
- wI2SConfig &= (u16_t) ~ AUD_DEM_WR_I2S_CONFIG2_I2S_ENABLE__M;
+ wI2SConfig &= (u16) ~ AUD_DEM_WR_I2S_CONFIG2_I2S_ENABLE__M;
if (output->outputEnable == TRUE) {
wI2SConfig |= AUD_DEM_WR_I2S_CONFIG2_I2S_ENABLE_ENABLE;
} else {
}
WR16(devAddr, AUD_DEM_WR_I2S_CONFIG2__A, wI2SConfig);
- WR16(devAddr, AUD_DSP_WR_I2S_OUT_FS__A, (u16_t) wI2SFreq);
+ WR16(devAddr, AUD_DSP_WR_I2S_OUT_FS__A, (u16) wI2SFreq);
/* configure I2S output pads for master or slave mode */
WR16(devAddr, SIO_TOP_COMM_KEY__A, SIO_TOP_COMM_KEY_KEY);
struct i2c_device_addr *devAddr = (struct i2c_device_addr *) NULL;
pDRXJData_t extAttr = (pDRXJData_t) NULL;
- u16_t rModus = 0;
+ u16 rModus = 0;
if (autoSound == NULL) {
return DRX_STS_INVALID_ARG;
struct i2c_device_addr *devAddr = (struct i2c_device_addr *) NULL;
pDRXJData_t extAttr = (pDRXJData_t) NULL;
- u16_t rModus = 0;
- u16_t wModus = 0;
+ u16 rModus = 0;
+ u16 wModus = 0;
if (autoSound == NULL) {
return DRX_STS_INVALID_ARG;
wModus = rModus;
/* clear ASS & ASC bits */
- wModus &= (u16_t) ~ AUD_DEM_WR_MODUS_MOD_ASS__M;
- wModus &= (u16_t) ~ AUD_DEM_WR_MODUS_MOD_DIS_STD_CHG__M;
+ wModus &= (u16) ~ AUD_DEM_WR_MODUS_MOD_ASS__M;
+ wModus &= (u16) ~ AUD_DEM_WR_MODUS_MOD_DIS_STD_CHG__M;
switch (*autoSound) {
case DRX_AUD_AUTO_SOUND_OFF:
struct i2c_device_addr *devAddr = (struct i2c_device_addr *) NULL;
pDRXJData_t extAttr = (pDRXJData_t) NULL;
- u16_t thresA2 = 0;
- u16_t thresBtsc = 0;
- u16_t thresNicam = 0;
+ u16 thresA2 = 0;
+ u16 thresBtsc = 0;
+ u16 thresNicam = 0;
if (thres == NULL) {
return DRX_STS_INVALID_ARG;
struct i2c_device_addr *devAddr = (struct i2c_device_addr *) NULL;
pDRXJData_t extAttr = (pDRXJData_t) NULL;
- u16_t wModus = 0;
+ u16 wModus = 0;
- u16_t dcoAHi = 0;
- u16_t dcoALo = 0;
- u16_t dcoBHi = 0;
- u16_t dcoBLo = 0;
+ u16 dcoAHi = 0;
+ u16 dcoALo = 0;
+ u16 dcoBHi = 0;
+ u16 dcoBLo = 0;
- u32_t valA = 0;
- u32_t valB = 0;
+ u32 valA = 0;
+ u32 valB = 0;
- u16_t dcLvlA = 0;
- u16_t dcLvlB = 0;
+ u16 dcLvlA = 0;
+ u16 dcLvlB = 0;
- u16_t cmThesA = 0;
- u16_t cmThesB = 0;
+ u16 cmThesA = 0;
+ u16 cmThesB = 0;
if (carriers == NULL) {
return DRX_STS_INVALID_ARG;
RR16(devAddr, AUD_DEM_RAM_DCO_B_HI__A, &dcoBHi);
RR16(devAddr, AUD_DEM_RAM_DCO_B_LO__A, &dcoBLo);
- valA = (((u32_t) dcoAHi) << 12) | ((u32_t) dcoALo & 0xFFF);
- valB = (((u32_t) dcoBHi) << 12) | ((u32_t) dcoBLo & 0xFFF);
+ valA = (((u32) dcoAHi) << 12) | ((u32) dcoALo & 0xFFF);
+ valB = (((u32) dcoBHi) << 12) | ((u32) dcoBLo & 0xFFF);
/* Multiply by 20250 * 1>>24 ~= 2 / 1657 */
carriers->a.dco = DRX_S24TODRXFREQ(valA) * 2L / 1657L;
struct i2c_device_addr *devAddr = (struct i2c_device_addr *) NULL;
pDRXJData_t extAttr = (pDRXJData_t) NULL;
- u16_t wModus = 0;
- u16_t rModus = 0;
+ u16 wModus = 0;
+ u16 rModus = 0;
- u16_t dcoAHi = 0;
- u16_t dcoALo = 0;
- u16_t dcoBHi = 0;
- u16_t dcoBLo = 0;
+ u16 dcoAHi = 0;
+ u16 dcoALo = 0;
+ u16 dcoBHi = 0;
+ u16 dcoBLo = 0;
- s32_t valA = 0;
- s32_t valB = 0;
+ s32 valA = 0;
+ s32 valB = 0;
if (carriers == NULL) {
return DRX_STS_INVALID_ARG;
CHK_ERROR(AUDGetModus(demod, &rModus));
wModus = rModus;
- wModus &= (u16_t) ~ AUD_DEM_WR_MODUS_MOD_CM_A__M;
+ wModus &= (u16) ~ AUD_DEM_WR_MODUS_MOD_CM_A__M;
/* Behaviour of primary audio channel */
switch (carriers->a.opt) {
case DRX_NO_CARRIER_MUTE:
}
/* Behaviour of secondary audio channel */
- wModus &= (u16_t) ~ AUD_DEM_WR_MODUS_MOD_CM_B__M;
+ wModus &= (u16) ~ AUD_DEM_WR_MODUS_MOD_CM_B__M;
switch (carriers->b.opt) {
case DRX_NO_CARRIER_MUTE:
wModus |= AUD_DEM_WR_MODUS_MOD_CM_B_MUTE;
}
/* frequency adjustment for primary & secondary audio channel */
- valA = (s32_t) ((carriers->a.dco) * 1657L / 2);
- valB = (s32_t) ((carriers->b.dco) * 1657L / 2);
+ valA = (s32) ((carriers->a.dco) * 1657L / 2);
+ valB = (s32) ((carriers->b.dco) * 1657L / 2);
- dcoAHi = (u16_t) ((valA >> 12) & 0xFFF);
- dcoALo = (u16_t) (valA & 0xFFF);
- dcoBHi = (u16_t) ((valB >> 12) & 0xFFF);
- dcoBLo = (u16_t) (valB & 0xFFF);
+ dcoAHi = (u16) ((valA >> 12) & 0xFFF);
+ dcoALo = (u16) (valA & 0xFFF);
+ dcoBHi = (u16) ((valB >> 12) & 0xFFF);
+ dcoBLo = (u16) (valB & 0xFFF);
WR16(devAddr, AUD_DEM_WR_DCO_A_HI__A, dcoAHi);
WR16(devAddr, AUD_DEM_WR_DCO_A_LO__A, dcoALo);
struct i2c_device_addr *devAddr = (struct i2c_device_addr *) NULL;
pDRXJData_t extAttr = (pDRXJData_t) NULL;
- u16_t srcI2SMatr = 0;
- u16_t fmMatr = 0;
+ u16 srcI2SMatr = 0;
+ u16 fmMatr = 0;
if (mixer == NULL) {
return DRX_STS_INVALID_ARG;
struct i2c_device_addr *devAddr = (struct i2c_device_addr *) NULL;
pDRXJData_t extAttr = (pDRXJData_t) NULL;
- u16_t srcI2SMatr = 0;
- u16_t fmMatr = 0;
+ u16 srcI2SMatr = 0;
+ u16 fmMatr = 0;
if (mixer == NULL) {
return DRX_STS_INVALID_ARG;
/* Source Selctor */
RR16(devAddr, AUD_DSP_WR_SRC_I2S_MATR__A, &srcI2SMatr);
- srcI2SMatr &= (u16_t) ~ AUD_DSP_WR_SRC_I2S_MATR_SRC_I2S__M;
+ srcI2SMatr &= (u16) ~ AUD_DSP_WR_SRC_I2S_MATR_SRC_I2S__M;
switch (mixer->sourceI2S) {
case DRX_AUD_SRC_MONO:
}
/* Matrix */
- srcI2SMatr &= (u16_t) ~ AUD_DSP_WR_SRC_I2S_MATR_MAT_I2S__M;
+ srcI2SMatr &= (u16) ~ AUD_DSP_WR_SRC_I2S_MATR_MAT_I2S__M;
switch (mixer->matrixI2S) {
case DRX_AUD_I2S_MATRIX_MONO:
srcI2SMatr |= AUD_DSP_WR_SRC_I2S_MATR_MAT_I2S_MONO;
/* FM Matrix */
RR16(devAddr, AUD_DEM_WR_FM_MATRIX__A, &fmMatr);
- fmMatr &= (u16_t) ~ AUD_DEM_WR_FM_MATRIX__M;
+ fmMatr &= (u16) ~ AUD_DEM_WR_FM_MATRIX__M;
switch (mixer->matrixFm) {
case DRX_AUD_FM_MATRIX_NO_MATRIX:
fmMatr |= AUD_DEM_WR_FM_MATRIX_NO_MATRIX;
struct i2c_device_addr *devAddr = (struct i2c_device_addr *) NULL;
pDRXJData_t extAttr = (pDRXJData_t) NULL;
- u16_t wAudVidSync = 0;
+ u16 wAudVidSync = 0;
if (avSync == NULL) {
return DRX_STS_INVALID_ARG;
/* audio/video synchronisation */
RR16(devAddr, AUD_DSP_WR_AV_SYNC__A, &wAudVidSync);
- wAudVidSync &= (u16_t) ~ AUD_DSP_WR_AV_SYNC_AV_ON__M;
+ wAudVidSync &= (u16) ~ AUD_DSP_WR_AV_SYNC_AV_ON__M;
if (*avSync == DRX_AUD_AVSYNC_OFF) {
wAudVidSync |= AUD_DSP_WR_AV_SYNC_AV_ON_DISABLE;
wAudVidSync |= AUD_DSP_WR_AV_SYNC_AV_ON_ENABLE;
}
- wAudVidSync &= (u16_t) ~ AUD_DSP_WR_AV_SYNC_AV_STD_SEL__M;
+ wAudVidSync &= (u16) ~ AUD_DSP_WR_AV_SYNC_AV_STD_SEL__M;
switch (*avSync) {
case DRX_AUD_AVSYNC_NTSC:
struct i2c_device_addr *devAddr = (struct i2c_device_addr *) NULL;
pDRXJData_t extAttr = (pDRXJData_t) NULL;
- u16_t wAudVidSync = 0;
+ u16 wAudVidSync = 0;
if (avSync == NULL) {
return DRX_STS_INVALID_ARG;
struct i2c_device_addr *devAddr = (struct i2c_device_addr *) NULL;
pDRXJData_t extAttr = (pDRXJData_t) NULL;
- u16_t rModus = 0;
+ u16 rModus = 0;
if (dev == NULL) {
return DRX_STS_INVALID_ARG;
struct i2c_device_addr *devAddr = (struct i2c_device_addr *) NULL;
pDRXJData_t extAttr = (pDRXJData_t) NULL;
- u16_t wModus = 0;
- u16_t rModus = 0;
+ u16 wModus = 0;
+ u16 rModus = 0;
if (dev == NULL) {
return DRX_STS_INVALID_ARG;
wModus = rModus;
- wModus &= (u16_t) ~ AUD_DEM_WR_MODUS_MOD_HDEV_A__M;
+ wModus &= (u16) ~ AUD_DEM_WR_MODUS_MOD_HDEV_A__M;
switch (*dev) {
case DRX_AUD_DEVIATION_NORMAL:
struct i2c_device_addr *devAddr = (struct i2c_device_addr *) NULL;
pDRXJData_t extAttr = (pDRXJData_t) NULL;
- u16_t rMaxFMDeviation = 0;
- u16_t rNicamPrescaler = 0;
+ u16 rMaxFMDeviation = 0;
+ u16 rNicamPrescaler = 0;
if (presc == NULL) {
return DRX_STS_INVALID_ARG;
presc->nicamGain = -241;
} else {
- presc->nicamGain = (s16_t) (((s32_t)
+ presc->nicamGain = (s16) (((s32)
(Log10Times100
(10 * rNicamPrescaler *
- rNicamPrescaler)) - (s32_t)
+ rNicamPrescaler)) - (s32)
(Log10Times100(10 * 16 * 16))));
}
struct i2c_device_addr *devAddr = (struct i2c_device_addr *) NULL;
pDRXJData_t extAttr = (pDRXJData_t) NULL;
- u16_t wMaxFMDeviation = 0;
- u16_t nicamPrescaler;
+ u16 wMaxFMDeviation = 0;
+ u16 nicamPrescaler;
if (presc == NULL) {
return DRX_STS_INVALID_ARG;
}
/* setting of max FM deviation */
- wMaxFMDeviation = (u16_t) (Frac(3600UL, presc->fmDeviation, 0));
+ wMaxFMDeviation = (u16) (Frac(3600UL, presc->fmDeviation, 0));
wMaxFMDeviation <<= AUD_DSP_WR_FM_PRESC_FM_AM_PRESC__B;
if (wMaxFMDeviation >=
AUD_DSP_WR_FM_PRESC_FM_AM_PRESC_28_KHZ_FM_DEVIATION) {
= 10^( G0.1dB + 200log10(16)) / 200 )
*/
- nicamPrescaler = (u16_t)
+ nicamPrescaler = (u16)
((dB2LinTimes100(presc->nicamGain + 241UL) + 50UL) / 100UL);
/* clip result */
struct i2c_device_addr *devAddr = (struct i2c_device_addr *) NULL;
pDRXJData_t extAttr = (pDRXJData_t) NULL;
- u16_t theBeep = 0;
- u16_t volume = 0;
- u32_t frequency = 0;
+ u16 theBeep = 0;
+ u16 volume = 0;
+ u32 frequency = 0;
if (beep == NULL) {
return DRX_STS_INVALID_ARG;
return DRX_STS_INVALID_ARG;
}
- volume = (u16_t) beep->volume + 127;
+ volume = (u16) beep->volume + 127;
theBeep |= volume << AUD_DSP_WR_BEEPER_BEEP_VOLUME__B;
- frequency = ((u32_t) beep->frequency) * 23 / 500;
+ frequency = ((u32) beep->frequency) * 23 / 500;
if (frequency > AUD_DSP_WR_BEEPER_BEEP_FREQUENCY__M) {
frequency = AUD_DSP_WR_BEEPER_BEEP_FREQUENCY__M;
}
- theBeep |= (u16_t) frequency;
+ theBeep |= (u16) frequency;
if (beep->mute == TRUE) {
theBeep = 0;
pDRXJData_t extAttr = NULL;
DRXStandard_t currentStandard = DRX_STANDARD_UNKNOWN;
- u16_t wStandard = 0;
- u16_t wModus = 0;
- u16_t rModus = 0;
+ u16 wStandard = 0;
+ u16 wModus = 0;
+ u16 rModus = 0;
Bool_t muteBuffer = FALSE;
- s16_t volumeBuffer = 0;
- u16_t wVolume = 0;
+ s16 volumeBuffer = 0;
+ u16 wVolume = 0;
if (standard == NULL) {
return DRX_STS_INVALID_ARG;
/* we need the current standard here */
currentStandard = extAttr->standard;
- wModus &= (u16_t) ~ AUD_DEM_WR_MODUS_MOD_6_5MHZ__M;
+ wModus &= (u16) ~ AUD_DEM_WR_MODUS_MOD_6_5MHZ__M;
if ((currentStandard == DRX_STANDARD_PAL_SECAM_L) ||
(currentStandard == DRX_STANDARD_PAL_SECAM_LP)) {
wModus |= (AUD_DEM_WR_MODUS_MOD_6_5MHZ_D_K);
}
- wModus &= (u16_t) ~ AUD_DEM_WR_MODUS_MOD_4_5MHZ__M;
+ wModus &= (u16) ~ AUD_DEM_WR_MODUS_MOD_4_5MHZ__M;
if (currentStandard == DRX_STANDARD_NTSC) {
wModus |= (AUD_DEM_WR_MODUS_MOD_4_5MHZ_M_BTSC);
}
- wModus &= (u16_t) ~ AUD_DEM_WR_MODUS_MOD_FMRADIO__M;
+ wModus &= (u16) ~ AUD_DEM_WR_MODUS_MOD_FMRADIO__M;
/* just get hardcoded deemphasis and activate here */
if (extAttr->audData.deemph == DRX_AUD_FM_DEEMPH_50US) {
wModus |= (AUD_DEM_WR_MODUS_MOD_FMRADIO_US_75U);
}
- wModus &= (u16_t) ~ AUD_DEM_WR_MODUS_MOD_BTSC__M;
+ wModus &= (u16) ~ AUD_DEM_WR_MODUS_MOD_BTSC__M;
if (extAttr->audData.btscDetect == DRX_BTSC_STEREO) {
wModus |= (AUD_DEM_WR_MODUS_MOD_BTSC_BTSC_STEREO);
} else { /* DRX_BTSC_MONO_AND_SAP */
/**************************************************************************/
extAttr->audData.volume.mute = muteBuffer;
if (extAttr->audData.volume.mute == FALSE) {
- wVolume |= (u16_t) ((volumeBuffer + AUD_VOLUME_ZERO_DB) <<
+ wVolume |= (u16) ((volumeBuffer + AUD_VOLUME_ZERO_DB) <<
AUD_DSP_WR_VOLUME_VOL_MAIN__B);
WR16(devAddr, AUD_DSP_WR_VOLUME__A, wVolume);
}
struct i2c_device_addr *devAddr = NULL;
pDRXJData_t extAttr = NULL;
- u16_t rData = 0;
+ u16 rData = 0;
if (standard == NULL) {
return DRX_STS_INVALID_ARG;
struct i2c_device_addr *devAddr, pDRXLockStatus_t oobLock)
{
DRXJSCUCmd_t scuCmd;
- u16_t cmdResult[2];
- u16_t OOBLockState;
+ u16 cmdResult[2];
+ u16 OOBLockState;
*oobLock = DRX_NOT_LOCKED;
*
*/
static DRXStatus_t
-GetOOBSymbolRateOffset(struct i2c_device_addr *devAddr, ps32_t SymbolRateOffset)
+GetOOBSymbolRateOffset(struct i2c_device_addr *devAddr, s32 *SymbolRateOffset)
{
/* offset = -{(timingOffset/2^19)*(symbolRate/12,656250MHz)}*10^6 [ppm] */
/* offset = -{(timingOffset/2^19)*(symbolRate/12656250)}*10^6 [ppm] */
/* trim 12656250/15625 = 810 */
/* offset = -{(timingOffset*(symbolRate * 2^-5))/(2^8*810)} [ppm] */
/* offset = -[(symbolRate * 2^-5)*(timingOffset)/(2^8)]/810 [ppm] */
- s32_t timingOffset = 0;
- u32_t unsignedTimingOffset = 0;
- s32_t divisionFactor = 810;
- u16_t data = 0;
- u32_t symbolRate = 0;
+ s32 timingOffset = 0;
+ u32 unsignedTimingOffset = 0;
+ s32 divisionFactor = 810;
+ u16 data = 0;
+ u32 symbolRate = 0;
Bool_t negative = FALSE;
*SymbolRateOffset = 0;
if (data == 0x8000)
unsignedTimingOffset = 32768;
else
- unsignedTimingOffset = 0x00007FFF & (u32_t) (-data);
+ unsignedTimingOffset = 0x00007FFF & (u32) (-data);
negative = TRUE;
} else
- unsignedTimingOffset = (u32_t) data;
+ unsignedTimingOffset = (u32) data;
symbolRate = symbolRate >> 5;
unsignedTimingOffset = (unsignedTimingOffset * symbolRate);
unsignedTimingOffset = Frac(unsignedTimingOffset,
divisionFactor, FRAC_ROUND);
if (negative)
- timingOffset = (s32_t) unsignedTimingOffset;
+ timingOffset = (s32) unsignedTimingOffset;
else
- timingOffset = -(s32_t) unsignedTimingOffset;
+ timingOffset = -(s32) unsignedTimingOffset;
*SymbolRateOffset = timingOffset;
static DRXStatus_t
GetOOBFreqOffset(pDRXDemodInstance_t demod, pDRXFrequency_t freqOffset)
{
- u16_t data = 0;
- u16_t rot = 0;
- u16_t symbolRateReg = 0;
- u32_t symbolRate = 0;
- s32_t coarseFreqOffset = 0;
- s32_t fineFreqOffset = 0;
- s32_t fineSign = 1;
- s32_t coarseSign = 1;
- u32_t data64Hi = 0;
- u32_t data64Lo = 0;
- u32_t tempFreqOffset = 0;
+ u16 data = 0;
+ u16 rot = 0;
+ u16 symbolRateReg = 0;
+ u32 symbolRate = 0;
+ s32 coarseFreqOffset = 0;
+ s32 fineFreqOffset = 0;
+ s32 fineSign = 1;
+ s32 coarseSign = 1;
+ u32 data64Hi = 0;
+ u32 data64Lo = 0;
+ u32 tempFreqOffset = 0;
pDRXCommonAttr_t commonAttr = (pDRXCommonAttr_t) (NULL);
struct i2c_device_addr *devAddr = NULL;
static DRXStatus_t
GetOOBFrequency(pDRXDemodInstance_t demod, pDRXFrequency_t frequency)
{
- u16_t data = 0;
+ u16 data = 0;
DRXFrequency_t freqOffset = 0;
DRXFrequency_t freq = 0;
struct i2c_device_addr *devAddr = NULL;
* Gets OOB MER. Table for MER is in Programming guide.
*
*/
-static DRXStatus_t GetOOBMER(struct i2c_device_addr *devAddr, pu32_t mer)
+static DRXStatus_t GetOOBMER(struct i2c_device_addr *devAddr, u32 *mer)
{
- u16_t data = 0;
+ u16 data = 0;
*mer = 0;
/* READ MER */
*/
static DRXStatus_t SetOrxNsuAox(pDRXDemodInstance_t demod, Bool_t active)
{
- u16_t data = 0;
+ u16 data = 0;
struct i2c_device_addr *devAddr = NULL;
pDRXJData_t extAttr = NULL;
DRXFrequency_t freq = 0; /* KHz */
struct i2c_device_addr *devAddr = NULL;
pDRXJData_t extAttr = NULL;
- u16_t i = 0;
+ u16 i = 0;
Bool_t mirrorFreqSpectOOB = FALSE;
- u16_t trkFilterValue = 0;
+ u16 trkFilterValue = 0;
DRXJSCUCmd_t scuCmd;
- u16_t setParamParameters[3];
- u16_t cmdResult[2] = { 0, 0 };
- s16_t NyquistCoeffs[4][(NYQFILTERLEN + 1) / 2] = {
+ u16 setParamParameters[3];
+ u16 cmdResult[2] = { 0, 0 };
+ s16 NyquistCoeffs[4][(NYQFILTERLEN + 1) / 2] = {
IMPULSE_COSINE_ALPHA_0_3, /* Target Mode 0 */
IMPULSE_COSINE_ALPHA_0_3, /* Target Mode 1 */
IMPULSE_COSINE_ALPHA_0_5, /* Target Mode 2 */
IMPULSE_COSINE_ALPHA_RO_0_5 /* Target Mode 3 */
};
- u8_t mode_val[4] = { 2, 2, 0, 1 };
- u8_t PFICoeffs[4][6] = {
+ u8 mode_val[4] = { 2, 2, 0, 1 };
+ u8 PFICoeffs[4][6] = {
{DRXJ_16TO8(-92), DRXJ_16TO8(-108), DRXJ_16TO8(100)}, /* TARGET_MODE = 0: PFI_A = -23/32; PFI_B = -54/32; PFI_C = 25/32; fg = 0.5 MHz (Att=26dB) */
{DRXJ_16TO8(-64), DRXJ_16TO8(-80), DRXJ_16TO8(80)}, /* TARGET_MODE = 1: PFI_A = -16/32; PFI_B = -40/32; PFI_C = 20/32; fg = 1.0 MHz (Att=28dB) */
{DRXJ_16TO8(-80), DRXJ_16TO8(-98), DRXJ_16TO8(92)}, /* TARGET_MODE = 2, 3: PFI_A = -20/32; PFI_B = -49/32; PFI_C = 23/32; fg = 0.8 MHz (Att=25dB) */
{DRXJ_16TO8(-80), DRXJ_16TO8(-98), DRXJ_16TO8(92)} /* TARGET_MODE = 2, 3: PFI_A = -20/32; PFI_B = -49/32; PFI_C = 23/32; fg = 0.8 MHz (Att=25dB) */
};
- u16_t mode_index;
+ u16 mode_index;
devAddr = demod->myI2CDevAddr;
extAttr = (pDRXJData_t) demod->myExtAttr;
freq = (freq - 50000) / 50;
{
- u16_t index = 0;
- u16_t remainder = 0;
- pu16_t trkFiltercfg = extAttr->oobTrkFilterCfg;
+ u16 index = 0;
+ u16 remainder = 0;
+ u16 *trkFiltercfg = extAttr->oobTrkFilterCfg;
- index = (u16_t) ((freq - 400) / 200);
- remainder = (u16_t) ((freq - 400) % 200);
+ index = (u16) ((freq - 400) / 200);
+ remainder = (u16) ((freq - 400) % 200);
trkFilterValue =
trkFiltercfg[index] - (trkFiltercfg[index] -
trkFiltercfg[index +
SCU_RAM_ORX_RF_RX_DATA_RATE_3088KBPS_REGSPEC;
break;
}
- setParamParameters[1] = (u16_t) (freq & 0xFFFF);
+ setParamParameters[1] = (u16) (freq & 0xFFFF);
setParamParameters[2] = trkFilterValue;
scuCmd.parameter = setParamParameters;
scuCmd.resultLen = 1;
/* AGN_LOCK = {2048>>3, -2048, 8, -8, 0, 1}; */
WR16(devAddr, SCU_RAM_ORX_AGN_LOCK_TH__A, 2048 >> 3);
- WR16(devAddr, SCU_RAM_ORX_AGN_LOCK_TOTH__A, (u16_t) (-2048));
+ WR16(devAddr, SCU_RAM_ORX_AGN_LOCK_TOTH__A, (u16) (-2048));
WR16(devAddr, SCU_RAM_ORX_AGN_ONLOCK_TTH__A, 8);
- WR16(devAddr, SCU_RAM_ORX_AGN_UNLOCK_TTH__A, (u16_t) (-8));
+ WR16(devAddr, SCU_RAM_ORX_AGN_UNLOCK_TTH__A, (u16) (-8));
WR16(devAddr, SCU_RAM_ORX_AGN_LOCK_MASK__A, 1);
/* DGN_LOCK = {10, -2048, 8, -8, 0, 1<<1}; */
WR16(devAddr, SCU_RAM_ORX_DGN_LOCK_TH__A, 10);
- WR16(devAddr, SCU_RAM_ORX_DGN_LOCK_TOTH__A, (u16_t) (-2048));
+ WR16(devAddr, SCU_RAM_ORX_DGN_LOCK_TOTH__A, (u16) (-2048));
WR16(devAddr, SCU_RAM_ORX_DGN_ONLOCK_TTH__A, 8);
- WR16(devAddr, SCU_RAM_ORX_DGN_UNLOCK_TTH__A, (u16_t) (-8));
+ WR16(devAddr, SCU_RAM_ORX_DGN_UNLOCK_TTH__A, (u16) (-8));
WR16(devAddr, SCU_RAM_ORX_DGN_LOCK_MASK__A, 1 << 1);
/* FRQ_LOCK = {15,-2048, 8, -8, 0, 1<<2}; */
WR16(devAddr, SCU_RAM_ORX_FRQ_LOCK_TH__A, 17);
- WR16(devAddr, SCU_RAM_ORX_FRQ_LOCK_TOTH__A, (u16_t) (-2048));
+ WR16(devAddr, SCU_RAM_ORX_FRQ_LOCK_TOTH__A, (u16) (-2048));
WR16(devAddr, SCU_RAM_ORX_FRQ_ONLOCK_TTH__A, 8);
- WR16(devAddr, SCU_RAM_ORX_FRQ_UNLOCK_TTH__A, (u16_t) (-8));
+ WR16(devAddr, SCU_RAM_ORX_FRQ_UNLOCK_TTH__A, (u16) (-8));
WR16(devAddr, SCU_RAM_ORX_FRQ_LOCK_MASK__A, 1 << 2);
/* PHA_LOCK = {5000, -2048, 8, -8, 0, 1<<3}; */
WR16(devAddr, SCU_RAM_ORX_PHA_LOCK_TH__A, 3000);
- WR16(devAddr, SCU_RAM_ORX_PHA_LOCK_TOTH__A, (u16_t) (-2048));
+ WR16(devAddr, SCU_RAM_ORX_PHA_LOCK_TOTH__A, (u16) (-2048));
WR16(devAddr, SCU_RAM_ORX_PHA_ONLOCK_TTH__A, 8);
- WR16(devAddr, SCU_RAM_ORX_PHA_UNLOCK_TTH__A, (u16_t) (-8));
+ WR16(devAddr, SCU_RAM_ORX_PHA_UNLOCK_TTH__A, (u16) (-8));
WR16(devAddr, SCU_RAM_ORX_PHA_LOCK_MASK__A, 1 << 3);
/* TIM_LOCK = {300, -2048, 8, -8, 0, 1<<4}; */
WR16(devAddr, SCU_RAM_ORX_TIM_LOCK_TH__A, 400);
- WR16(devAddr, SCU_RAM_ORX_TIM_LOCK_TOTH__A, (u16_t) (-2048));
+ WR16(devAddr, SCU_RAM_ORX_TIM_LOCK_TOTH__A, (u16) (-2048));
WR16(devAddr, SCU_RAM_ORX_TIM_ONLOCK_TTH__A, 8);
- WR16(devAddr, SCU_RAM_ORX_TIM_UNLOCK_TTH__A, (u16_t) (-8));
+ WR16(devAddr, SCU_RAM_ORX_TIM_UNLOCK_TTH__A, (u16) (-8));
WR16(devAddr, SCU_RAM_ORX_TIM_LOCK_MASK__A, 1 << 4);
/* EQU_LOCK = {20, -2048, 8, -8, 0, 1<<5}; */
WR16(devAddr, SCU_RAM_ORX_EQU_LOCK_TH__A, 20);
- WR16(devAddr, SCU_RAM_ORX_EQU_LOCK_TOTH__A, (u16_t) (-2048));
+ WR16(devAddr, SCU_RAM_ORX_EQU_LOCK_TOTH__A, (u16) (-2048));
WR16(devAddr, SCU_RAM_ORX_EQU_ONLOCK_TTH__A, 4);
- WR16(devAddr, SCU_RAM_ORX_EQU_UNLOCK_TTH__A, (u16_t) (-4));
+ WR16(devAddr, SCU_RAM_ORX_EQU_UNLOCK_TTH__A, (u16) (-4));
WR16(devAddr, SCU_RAM_ORX_EQU_LOCK_MASK__A, 1 << 5);
/* PRE-Filter coefficients (PFI) */
WRB(devAddr, ORX_FWP_PFI_A_W__A, sizeof(PFICoeffs[mode_index]),
- ((pu8_t) PFICoeffs[mode_index]));
+ ((u8 *) PFICoeffs[mode_index]));
WR16(devAddr, ORX_TOP_MDE_W__A, mode_index);
/* NYQUIST-Filter coefficients (NYQ) */
#ifndef DRXJ_DIGITAL_ONLY
struct i2c_device_addr *devAddr = NULL;
pDRXJData_t extAttr = NULL;
- u16_t data = 0;
+ u16 data = 0;
devAddr = demod->myI2CDevAddr;
extAttr = (pDRXJData_t) demod->myExtAttr;
*/
#ifndef DRXJ_DIGITAL_ONLY
static DRXStatus_t
-CtrlSetCfgOOBPreSAW(pDRXDemodInstance_t demod, pu16_t cfgData)
+CtrlSetCfgOOBPreSAW(pDRXDemodInstance_t demod, u16 *cfgData)
{
struct i2c_device_addr *devAddr = NULL;
pDRXJData_t extAttr = NULL;
*/
#ifndef DRXJ_DIGITAL_ONLY
static DRXStatus_t
-CtrlGetCfgOOBPreSAW(pDRXDemodInstance_t demod, pu16_t cfgData)
+CtrlGetCfgOOBPreSAW(pDRXDemodInstance_t demod, u16 *cfgData)
{
pDRXJData_t extAttr = NULL;
pDRXCommonAttr_t commonAttr = NULL;
Bool_t bridgeClosed = FALSE;
#ifndef DRXJ_VSB_ONLY
- u32_t minSymbolRate = 0;
- u32_t maxSymbolRate = 0;
+ u32 minSymbolRate = 0;
+ u32 maxSymbolRate = 0;
int bandwidthTemp = 0;
int bandwidth = 0;
#endif
DRXStandard_t standard = DRX_STANDARD_UNKNOWN;
pDRXCommonAttr_t commonAttr = NULL;
DRXFrequency_t intermediateFreq = 0;
- s32_t CTLFreqOffset = 0;
- u32_t iqmRcRateLo = 0;
- u32_t adcFrequency = 0;
+ s32 CTLFreqOffset = 0;
+ u32 iqmRcRateLo = 0;
+ u32 adcFrequency = 0;
#ifndef DRXJ_VSB_ONLY
int bandwidthTemp = 0;
int bandwidth = 0;
} else {
/* annex A & C */
- u32_t rollOff = 113; /* default annex C */
+ u32 rollOff = 113; /* default annex C */
if (standard == DRX_STANDARD_ITU_A) {
rollOff = 115;
/* parameter */ NULL,
/* result */ NULL
};
- u16_t cmdResult[3] = { 0, 0, 0 };
+ u16 cmdResult[3] = { 0, 0, 0 };
cmdSCU.command =
SCU_RAM_COMMAND_STANDARD_QAM |
===== SigQuality() ==========================================================
===========================================================================*/
-static u16_t
-mer2indicator(u16_t mer, u16_t minMer, u16_t thresholdMer, u16_t maxMer)
+static u16
+mer2indicator(u16 mer, u16 minMer, u16 thresholdMer, u16 maxMer)
{
- u16_t indicator = 0;
+ u16 indicator = 0;
if (mer < minMer) {
indicator = 0;
pDRXJData_t extAttr = NULL;
DRXStandard_t standard = DRX_STANDARD_UNKNOWN;
DRXLockStatus_t lockStatus = DRX_NOT_LOCKED;
- u16_t minMer = 0;
- u16_t maxMer = 0;
- u16_t thresholdMer = 0;
+ u16 minMer = 0;
+ u16 maxMer = 0;
+ u16 thresholdMer = 0;
/* Check arguments */
if ((sigQuality == NULL) || (demod == NULL)) {
/* *parameter */ NULL,
/* *result */ NULL
};
- u16_t cmdResult[2] = { 0, 0 };
- u16_t demodLock = SCU_RAM_PARAM_1_RES_DEMOD_GET_LOCK_DEMOD_LOCKED;
+ u16 cmdResult[2] = { 0, 0 };
+ u16 demodLock = SCU_RAM_PARAM_1_RES_DEMOD_GET_LOCK_DEMOD_LOCKED;
/* check arguments */
if ((demod == NULL) || (lockStat == NULL)) {
/**
* \fn DRXStatus_t CtrlGetCfgSymbolClockOffset()
* \brief Get frequency offsets of STR.
-* \param pointer to s32_t.
+* \param pointer to s32.
* \return DRXStatus_t.
*
*/
static DRXStatus_t
-CtrlGetCfgSymbolClockOffset(pDRXDemodInstance_t demod, ps32_t rateOffset)
+CtrlGetCfgSymbolClockOffset(pDRXDemodInstance_t demod, s32 *rateOffset)
{
DRXStandard_t standard = DRX_STANDARD_UNKNOWN;
struct i2c_device_addr *devAddr = NULL;
pDRXCommonAttr_t commonAttr = (pDRXCommonAttr_t) NULL;
pDRXJData_t extAttr = (pDRXJData_t) NULL;
struct i2c_device_addr *devAddr = (struct i2c_device_addr *) NULL;
- u16_t sioCcPwdMode = 0;
+ u16 sioCcPwdMode = 0;
commonAttr = (pDRXCommonAttr_t) demod->myCommonAttr;
extAttr = (pDRXJData_t) demod->myExtAttr;
pDRXJData_t extAttr = (pDRXJData_t) (NULL);
struct i2c_device_addr *devAddr = (struct i2c_device_addr *) (NULL);
pDRXCommonAttr_t commonAttr = (pDRXCommonAttr_t) (NULL);
- u16_t ucodeMajorMinor = 0; /* BCD Ma:Ma:Ma:Mi */
- u16_t ucodePatch = 0; /* BCD Pa:Pa:Pa:Pa */
- u16_t major = 0;
- u16_t minor = 0;
- u16_t patch = 0;
- u16_t idx = 0;
- u32_t jtag = 0;
- u16_t subtype = 0;
- u16_t mfx = 0;
- u16_t bid = 0;
- u16_t key = 0;
+ u16 ucodeMajorMinor = 0; /* BCD Ma:Ma:Ma:Mi */
+ u16 ucodePatch = 0; /* BCD Pa:Pa:Pa:Pa */
+ u16 major = 0;
+ u16 minor = 0;
+ u16 patch = 0;
+ u16 idx = 0;
+ u32 jtag = 0;
+ u16 subtype = 0;
+ u16 mfx = 0;
+ u16 bid = 0;
+ u16 key = 0;
static char ucodeName[] = "Microcode";
static char deviceName[] = "Device";
/* DRX39xxJ type Ax */
/* TODO semantics of mfx and spin are unclear */
- subtype = (u16_t) ((jtag >> 12) & 0xFF);
- mfx = (u16_t) (jtag >> 29);
+ subtype = (u16) ((jtag >> 12) & 0xFF);
+ mfx = (u16) (jtag >> 29);
extAttr->vVersion[1].vMinor = 1;
if (mfx == 0x03) {
extAttr->vVersion[1].vPatch = mfx + 2;
|| commonAttr->currentPowerMode != DRX_POWER_UP) {
struct i2c_device_addr *devAddr = NULL;
DRXPowerMode_t powerMode = DRX_POWER_UP;
- u32_t jtag = 0;
+ u32 jtag = 0;
devAddr = demod->myI2CDevAddr;
FALSE if MC block not Audio
* \return Bool_t.
*/
-Bool_t IsMCBlockAudio(u32_t addr)
+Bool_t IsMCBlockAudio(u32 addr)
{
if ((addr == AUD_XFP_PRAM_4K__A) || (addr == AUD_XDFP_PRAM_4K__A)) {
return (TRUE);
pDRXUCodeInfo_t mcInfo,
DRXUCodeAction_t action, Bool_t uploadAudioMC)
{
- u16_t i = 0;
- u16_t mcNrOfBlks = 0;
- u16_t mcMagicWord = 0;
- pu8_t mcData = (pu8_t) (NULL);
+ u16 i = 0;
+ u16 mcNrOfBlks = 0;
+ u16 mcMagicWord = 0;
+ u8 *mcData = (u8 *) (NULL);
struct i2c_device_addr *devAddr = (struct i2c_device_addr *) (NULL);
pDRXJData_t extAttr = (pDRXJData_t) (NULL);
/* Check data */
mcMagicWord = UCodeRead16(mcData);
- mcData += sizeof(u16_t);
+ mcData += sizeof(u16);
mcNrOfBlks = UCodeRead16(mcData);
- mcData += sizeof(u16_t);
+ mcData += sizeof(u16);
if ((mcMagicWord != DRXJ_UCODE_MAGIC_WORD) || (mcNrOfBlks == 0)) {
/* wrong endianess or wrong data ? */
/* Process microcode blocks */
for (i = 0; i < mcNrOfBlks; i++) {
DRXUCodeBlockHdr_t blockHdr;
- u16_t mcBlockNrBytes = 0;
+ u16 mcBlockNrBytes = 0;
/* Process block header */
blockHdr.addr = UCodeRead32(mcData);
- mcData += sizeof(u32_t);
+ mcData += sizeof(u32);
blockHdr.size = UCodeRead16(mcData);
- mcData += sizeof(u16_t);
+ mcData += sizeof(u16);
blockHdr.flags = UCodeRead16(mcData);
- mcData += sizeof(u16_t);
+ mcData += sizeof(u16);
blockHdr.CRC = UCodeRead16(mcData);
- mcData += sizeof(u16_t);
+ mcData += sizeof(u16);
/* Check block header on:
- no data
return DRX_STS_INVALID_ARG;
}
- mcBlockNrBytes = blockHdr.size * sizeof(u16_t);
+ mcBlockNrBytes = blockHdr.size * sizeof(u16);
/* Perform the desired action */
/* Check which part of MC need to be uploaded - Audio or not Audio */
case UCODE_VERIFY:
{
int result = 0;
- u8_t mcDataBuffer
+ u8 mcDataBuffer
[DRXJ_UCODE_MAX_BUF_SIZE];
- u32_t bytesToCompare = 0;
- u32_t bytesLeftToCompare = 0;
+ u32 bytesToCompare = 0;
+ u32 bytesLeftToCompare = 0;
DRXaddr_t currAddr = (DRXaddr_t) 0;
- pu8_t currPtr = NULL;
+ u8 *currPtr = NULL;
bytesLeftToCompare = mcBlockNrBytes;
currAddr = blockHdr.addr;
while (bytesLeftToCompare != 0) {
if (bytesLeftToCompare >
- ((u32_t)
+ ((u32)
DRXJ_UCODE_MAX_BUF_SIZE)) {
bytesToCompare =
- ((u32_t)
+ ((u32)
DRXJ_UCODE_MAX_BUF_SIZE);
} else {
bytesToCompare =
if (demod->myAccessFunct->
readBlockFunc(devAddr,
currAddr,
- (u16_t)
+ (u16)
bytesToCompare,
- (pu8_t)
+ (u8 *)
mcDataBuffer,
0x0000) !=
DRX_STS_OK) {
currPtr =
&(currPtr[bytesToCompare]);
bytesLeftToCompare -=
- ((u32_t) bytesToCompare);
+ ((u32) bytesToCompare);
} /* while( bytesToCompare > DRXJ_UCODE_MAX_BUF_SIZE ) */
};
break;
*/
static DRXStatus_t
-CtrlSigStrength(pDRXDemodInstance_t demod, pu16_t sigStrength)
+CtrlSigStrength(pDRXDemodInstance_t demod, u16 *sigStrength)
{
pDRXJData_t extAttr = NULL;
DRXStandard_t standard = DRX_STANDARD_UNKNOWN;
CtrlGetCfgOOBMisc(pDRXDemodInstance_t demod, pDRXJCfgOOBMisc_t misc)
{
struct i2c_device_addr *devAddr = NULL;
- u16_t lock = 0U;
- u16_t state = 0U;
- u16_t data = 0U;
- u16_t digitalAGCMant = 0U;
- u16_t digitalAGCExp = 0U;
+ u16 lock = 0U;
+ u16 state = 0U;
+ u16 data = 0U;
+ u16 digitalAGCMant = 0U;
+ u16 digitalAGCExp = 0U;
/* check arguments */
if (misc == NULL) {
* \fn DRXStatus_t CtrlGetCfgAgcInternal()
* \brief Retrieve internal AGC value.
* \param demod demod instance
-* \param u16_t
+* \param u16
* \return DRXStatus_t.
*
* Check arguments
*
*/
static DRXStatus_t
-CtrlGetCfgAgcInternal(pDRXDemodInstance_t demod, pu16_t agcInternal)
+CtrlGetCfgAgcInternal(pDRXDemodInstance_t demod, u16 *agcInternal)
{
struct i2c_device_addr *devAddr = NULL;
DRXLockStatus_t lockStatus = DRX_NOT_LOCKED;
pDRXJData_t extAttr = NULL;
- u16_t iqmCfScaleSh = 0;
- u16_t iqmCfPower = 0;
- u16_t iqmCfAmp = 0;
- u16_t iqmCfGain = 0;
+ u16 iqmCfScaleSh = 0;
+ u16 iqmCfPower = 0;
+ u16 iqmCfAmp = 0;
+ u16 iqmCfGain = 0;
/* check arguments */
if (agcInternal == NULL) {
-IQM_CF_Gain_dB-18+6*(27-IQM_CF_SCALE_SH*2-10)
+6*7+10*log10(1+0.115/4); */
/* PadcdB = P4dB +3 -6 +60; dBmV */
- *agcInternal = (u16_t) (Log10Times100(iqmCfPower)
+ *agcInternal = (u16) (Log10Times100(iqmCfPower)
- 2 * Log10Times100(iqmCfAmp)
- iqmCfGain - 120 * iqmCfScaleSh + 781);
* \fn DRXStatus_t CtrlSetCfgPreSaw()
* \brief Set Pre-saw reference.
* \param demod demod instance
-* \param pu16_t
+* \param u16 *
* \return DRXStatus_t.
*
* Check arguments
* \fn DRXStatus_t CtrlSetCfgAfeGain()
* \brief Set AFE Gain.
* \param demod demod instance
-* \param pu16_t
+* \param u16 *
* \return DRXStatus_t.
*
* Check arguments
{
struct i2c_device_addr *devAddr = NULL;
pDRXJData_t extAttr = NULL;
- u8_t gain = 0;
+ u8 gain = 0;
/* check arguments */
if (afeGain == NULL) {
* \fn DRXStatus_t CtrlGetCfgPreSaw()
* \brief Get Pre-saw reference setting.
* \param demod demod instance
-* \param pu16_t
+* \param u16 *
* \return DRXStatus_t.
*
* Check arguments
* \fn DRXStatus_t CtrlGetCfgAfeGain()
* \brief Get AFE Gain.
* \param demod demod instance
-* \param pu16_t
+* \param u16 *
* \return DRXStatus_t.
*
* Check arguments
* \fn DRXStatus_t CtrlGetFecMeasSeqCount()
* \brief Get FEC measurement sequnce number.
* \param demod demod instance
-* \param pu16_t
+* \param u16 *
* \return DRXStatus_t.
*
* Check arguments
*
*/
static DRXStatus_t
-CtrlGetFecMeasSeqCount(pDRXDemodInstance_t demod, pu16_t fecMeasSeqCount)
+CtrlGetFecMeasSeqCount(pDRXDemodInstance_t demod, u16 *fecMeasSeqCount)
{
/* check arguments */
if (fecMeasSeqCount == NULL) {
* \fn DRXStatus_t CtrlGetAccumCrRSCwErr()
* \brief Get accumulative corrected RS codeword number.
* \param demod demod instance
-* \param pu32_t
+* \param u32 *
* \return DRXStatus_t.
*
* Check arguments
*
*/
static DRXStatus_t
-CtrlGetAccumCrRSCwErr(pDRXDemodInstance_t demod, pu32_t accumCrRsCWErr)
+CtrlGetAccumCrRSCwErr(pDRXDemodInstance_t demod, u32 *accumCrRsCWErr)
{
if (accumCrRsCWErr == NULL) {
return (DRX_STS_INVALID_ARG);
return CtrlSetCfgResetPktErr(demod);
#ifndef DRXJ_DIGITAL_ONLY
case DRXJ_CFG_OOB_PRE_SAW:
- return CtrlSetCfgOOBPreSAW(demod, (pu16_t) (config->cfgData));
+ return CtrlSetCfgOOBPreSAW(demod, (u16 *) (config->cfgData));
case DRXJ_CFG_OOB_LO_POW:
return CtrlSetCfgOOBLoPower(demod,
(pDRXJCfgOobLoPower_t) (config->
case DRXJ_CFG_AGC_IF:
return CtrlGetCfgAgcIf(demod, (pDRXJCfgAgc_t) config->cfgData);
case DRXJ_CFG_AGC_INTERNAL:
- return CtrlGetCfgAgcInternal(demod, (pu16_t) config->cfgData);
+ return CtrlGetCfgAgcInternal(demod, (u16 *) config->cfgData);
case DRXJ_CFG_PRE_SAW:
return CtrlGetCfgPreSaw(demod,
(pDRXJCfgPreSaw_t) config->cfgData);
return CtrlGetCfgAfeGain(demod,
(pDRXJCfgAfeGain_t) config->cfgData);
case DRXJ_CFG_ACCUM_CR_RS_CW_ERR:
- return CtrlGetAccumCrRSCwErr(demod, (pu32_t) config->cfgData);
+ return CtrlGetAccumCrRSCwErr(demod, (u32 *) config->cfgData);
case DRXJ_CFG_FEC_MERS_SEQ_COUNT:
- return CtrlGetFecMeasSeqCount(demod, (pu16_t) config->cfgData);
+ return CtrlGetFecMeasSeqCount(demod, (u16 *) config->cfgData);
case DRXJ_CFG_VSB_MISC:
return CtrlGetCfgVSBMisc(demod,
(pDRXJCfgVSBMisc_t) config->cfgData);
case DRXJ_CFG_SYMBOL_CLK_OFFSET:
return CtrlGetCfgSymbolClockOffset(demod,
- (ps32_t) config->cfgData);
+ (s32 *) config->cfgData);
#ifndef DRXJ_DIGITAL_ONLY
case DRXJ_CFG_OOB_MISC:
return CtrlGetCfgOOBMisc(demod,
(pDRXJCfgOOBMisc_t) config->cfgData);
case DRXJ_CFG_OOB_PRE_SAW:
- return CtrlGetCfgOOBPreSAW(demod, (pu16_t) (config->cfgData));
+ return CtrlGetCfgOOBPreSAW(demod, (u16 *) (config->cfgData));
case DRXJ_CFG_OOB_LO_POW:
return CtrlGetCfgOOBLoPower(demod,
(pDRXJCfgOobLoPower_t) (config->
struct i2c_device_addr *devAddr = NULL;
pDRXJData_t extAttr = NULL;
pDRXCommonAttr_t commonAttr = NULL;
- u32_t driverVersion = 0;
+ u32 driverVersion = 0;
DRXUCodeInfo_t ucodeInfo;
DRXCfgMPEGOutput_t cfgMPEGOutput;
driverVersion += (VERSION_PATCH / 10) % 10;
driverVersion <<= 4;
driverVersion += (VERSION_PATCH % 10);
- WR16(devAddr, SCU_RAM_DRIVER_VER_HI__A, (u16_t) (driverVersion >> 16));
+ WR16(devAddr, SCU_RAM_DRIVER_VER_HI__A, (u16) (driverVersion >> 16));
WR16(devAddr, SCU_RAM_DRIVER_VER_LO__A,
- (u16_t) (driverVersion & 0xFFFF));
+ (u16) (driverVersion & 0xFFFF));
/* refresh the audio data structure with default */
extAttr->audData = DRXJDefaultAudData_g;
/*======================================================================*/
case DRX_CTRL_SIG_STRENGTH:
{
- return CtrlSigStrength(demod, (pu16_t) ctrlData);
+ return CtrlSigStrength(demod, (u16 *) ctrlData);
}
break;
/*======================================================================*/
projects / linux.git / commitdiff