Apollo Register Documentation  v2.4.2
IOSLAVE - I2C/SPI Slave

IOSLAVE Register Index

  0x00000100:   FIFOPTR - Current FIFO Pointer
  0x00000104:   FIFOCFG - FIFO Configuration
  0x00000108:   FIFOTHR - FIFO Threshold Configuration
  0x0000010C:   FUPD - FIFO Update Status
  0x00000110:   FIFOCTR - Overall FIFO Counter
  0x00000114:   FIFOINC - Overall FIFO Counter Increment
  0x00000118:   CFG - I/O Slave Configuration
  0x0000011C:   PRENC - I/O Slave Interrupt Priority Encode
  0x00000120:   IOINTCTL - I/O Interrupt Control
  0x00000124:   GENADD - General Address Data
  0x00000200:   INTEN - IO Slave Interrupts: Enable
  0x00000204:   INTSTAT - IO Slave Interrupts: Status
  0x00000208:   INTCLR - IO Slave Interrupts: Clear
  0x0000020C:   INTSET - IO Slave Interrupts: Set
  0x00000210:   REGACCINTEN - Register Access Interrupts: Enable
  0x00000214:   REGACCINTSTAT - Register Access Interrupts: Status
  0x00000218:   REGACCINTCLR - Register Access Interrupts: Clear
  0x0000021C:   REGACCINTSET - Register Access Interrupts: Set

FIFOPTR - Current FIFO Pointer

Address:

  Instance 0 Address:   0x50000100

Description:

Current FIFO Pointer

Example Macro Usage:

//
// All macro-based register writes follow the same basic format. For
// single-instance modules, you may use the simpler AM_REG macro. For
// multi-instance macros, you will need to specify the instance number using
// the AM_REGn macro format.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
// AM_REGn(<MODULE>, <INSTANCE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
//
// For registers that do not have specific enumeration values, you may use this alternate format instead.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>(<NUMBER>);
//
// For example, the following three lines of code are equivalent methods of
// writing the value for 12MHZ to the CLKSEL field in the ADC_CFG register.
//
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REGn(ADC, 0, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL(0x1);

Register Fields:

31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0
RSVD
0x0
FIFOSIZ
0x0
FIFOPTR
0x0

Bits Name RW Description
31:16 RSVD RO RESERVED

15:8 FIFOSIZ RW The number of bytes currently in the hardware FIFO.

7:0 FIFOPTR RW Current FIFO pointer.


FIFOCFG - FIFO Configuration

Address:

  Instance 0 Address:   0x50000104

Description:

FIFO Configuration

Example Macro Usage:

//
// All macro-based register writes follow the same basic format. For
// single-instance modules, you may use the simpler AM_REG macro. For
// multi-instance macros, you will need to specify the instance number using
// the AM_REGn macro format.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
// AM_REGn(<MODULE>, <INSTANCE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
//
// For registers that do not have specific enumeration values, you may use this alternate format instead.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>(<NUMBER>);
//
// For example, the following three lines of code are equivalent methods of
// writing the value for 12MHZ to the CLKSEL field in the ADC_CFG register.
//
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REGn(ADC, 0, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL(0x1);

Register Fields:

31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0
RSVD
0x0
ROBASE
0x20
RSVD
0x0
RSVD
0x0
FIFOMAX
0x0
RSVD
0x0
FIFOBASE
0x0

Bits Name RW Description
31:30 RSVD RO RESERVED

29:24 ROBASE RW Defines the read-only area. The IO Slave read-only area is situated in LRAM at (ROBASE*8) to (FIFOOBASE*8-1)

23:16 RSVD RO RESERVED

15:14 RSVD RO RESERVED

13:8 FIFOMAX RW These bits hold the maximum FIFO address in 8 byte segments. It is also the beginning of the RAM area of the LRAM. Note that no RAM area is configured if FIFOMAX is set to 0x1F.

7:5 RSVD RO RESERVED

4:0 FIFOBASE RW These bits hold the base address of the I/O FIFO in 8 byte segments.The IO Slave FIFO is situated in LRAM at (FIFOBASE*8) to (FIFOMAX*8-1).


FIFOTHR - FIFO Threshold Configuration

Address:

  Instance 0 Address:   0x50000108

Description:

FIFO Threshold Configuration

Example Macro Usage:

//
// All macro-based register writes follow the same basic format. For
// single-instance modules, you may use the simpler AM_REG macro. For
// multi-instance macros, you will need to specify the instance number using
// the AM_REGn macro format.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
// AM_REGn(<MODULE>, <INSTANCE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
//
// For registers that do not have specific enumeration values, you may use this alternate format instead.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>(<NUMBER>);
//
// For example, the following three lines of code are equivalent methods of
// writing the value for 12MHZ to the CLKSEL field in the ADC_CFG register.
//
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REGn(ADC, 0, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL(0x1);

Register Fields:

31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0
RSVD
0x0
FIFOTHR
0x0

Bits Name RW Description
31:8 RSVD RO RESERVED

7:0 FIFOTHR RW FIFO size interrupt threshold.


FUPD - FIFO Update Status

Address:

  Instance 0 Address:   0x5000010C

Description:

FIFO Update Status

Example Macro Usage:

//
// All macro-based register writes follow the same basic format. For
// single-instance modules, you may use the simpler AM_REG macro. For
// multi-instance macros, you will need to specify the instance number using
// the AM_REGn macro format.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
// AM_REGn(<MODULE>, <INSTANCE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
//
// For registers that do not have specific enumeration values, you may use this alternate format instead.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>(<NUMBER>);
//
// For example, the following three lines of code are equivalent methods of
// writing the value for 12MHZ to the CLKSEL field in the ADC_CFG register.
//
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REGn(ADC, 0, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL(0x1);

Register Fields:

31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0
RSVD
0x0
IOREAD
0x0
FIFOUPD
0x0

Bits Name RW Description
31:2 RSVD RO RESERVED

1 IOREAD RO This bitfield indicates an IO read is active.

0 FIFOUPD RW This bit indicates that a FIFO update is underway.


FIFOCTR - Overall FIFO Counter

Address:

  Instance 0 Address:   0x50000110

Description:

Overall FIFO Counter

Example Macro Usage:

//
// All macro-based register writes follow the same basic format. For
// single-instance modules, you may use the simpler AM_REG macro. For
// multi-instance macros, you will need to specify the instance number using
// the AM_REGn macro format.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
// AM_REGn(<MODULE>, <INSTANCE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
//
// For registers that do not have specific enumeration values, you may use this alternate format instead.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>(<NUMBER>);
//
// For example, the following three lines of code are equivalent methods of
// writing the value for 12MHZ to the CLKSEL field in the ADC_CFG register.
//
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REGn(ADC, 0, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL(0x1);

Register Fields:

31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0
RSVD
0x0
FIFOCTR
0x0

Bits Name RW Description
31:10 RSVD RO RESERVED

9:0 FIFOCTR RW Virtual FIFO byte count


FIFOINC - Overall FIFO Counter Increment

Address:

  Instance 0 Address:   0x50000114

Description:

Overall FIFO Counter Increment

Example Macro Usage:

//
// All macro-based register writes follow the same basic format. For
// single-instance modules, you may use the simpler AM_REG macro. For
// multi-instance macros, you will need to specify the instance number using
// the AM_REGn macro format.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
// AM_REGn(<MODULE>, <INSTANCE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
//
// For registers that do not have specific enumeration values, you may use this alternate format instead.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>(<NUMBER>);
//
// For example, the following three lines of code are equivalent methods of
// writing the value for 12MHZ to the CLKSEL field in the ADC_CFG register.
//
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REGn(ADC, 0, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL(0x1);

Register Fields:

31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0
RSVD
0x0
FIFOINC
0x0

Bits Name RW Description
31:10 RSVD RO RESERVED

9:0 FIFOINC WO Increment the Overall FIFO Counter by this value on a write


CFG - I/O Slave Configuration

Address:

  Instance 0 Address:   0x50000118

Description:

I/O Slave Configuration

Example Macro Usage:

//
// All macro-based register writes follow the same basic format. For
// single-instance modules, you may use the simpler AM_REG macro. For
// multi-instance macros, you will need to specify the instance number using
// the AM_REGn macro format.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
// AM_REGn(<MODULE>, <INSTANCE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
//
// For registers that do not have specific enumeration values, you may use this alternate format instead.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>(<NUMBER>);
//
// For example, the following three lines of code are equivalent methods of
// writing the value for 12MHZ to the CLKSEL field in the ADC_CFG register.
//
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REGn(ADC, 0, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL(0x1);

Register Fields:

31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0
IFCEN
0x0
RSVD
0x0
I2CADDR
0x0
RSVD
0x0
STARTRD
0x0
RSVD
0x0
LSB
0x0
SPOL
0x0
IFCSEL
0x0

Bits Name RW Description
31 IFCEN RW IOSLAVE interface enable.

DIS = 0x0 - Disable the IOSLAVE
EN = 0x1 - Enable the IOSLAVE
30:20 RSVD RO RESERVED

19:8 I2CADDR RW 7-bit or 10-bit I2C device address.

7:5 RSVD RO RESERVED

4 STARTRD RW This bit holds the cycle to initiate an I/O RAM read.

LATE = 0x0 - Initiate I/O RAM read late in each transferred byte.
EARLY = 0x1 - Initiate I/O RAM read early in each transferred byte.
3 RSVD RO RESERVED

2 LSB RW This bit selects the transfer bit ordering.

MSB_FIRST = 0x0 - Data is assumed to be sent and received with MSB first.
LSB_FIRST = 0x1 - Data is assumed to be sent and received with LSB first.
1 SPOL RW This bit selects SPI polarity.

SPI_MODES_0_3 = 0x0 - Polarity 0, handles SPI modes 0 and 3.
SPI_MODES_1_2 = 0x1 - Polarity 1, handles SPI modes 1 and 2.
0 IFCSEL RW This bit selects the I/O interface.

I2C = 0x0 - Selects I2C interface for the IO Slave.
SPI = 0x1 - Selects SPI interface for the IO Slave.

PRENC - I/O Slave Interrupt Priority Encode

Address:

  Instance 0 Address:   0x5000011C

Description:

I/O Slave Interrupt Priority Encode

Example Macro Usage:

//
// All macro-based register writes follow the same basic format. For
// single-instance modules, you may use the simpler AM_REG macro. For
// multi-instance macros, you will need to specify the instance number using
// the AM_REGn macro format.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
// AM_REGn(<MODULE>, <INSTANCE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
//
// For registers that do not have specific enumeration values, you may use this alternate format instead.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>(<NUMBER>);
//
// For example, the following three lines of code are equivalent methods of
// writing the value for 12MHZ to the CLKSEL field in the ADC_CFG register.
//
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REGn(ADC, 0, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL(0x1);

Register Fields:

31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0
RSVD
0x0
PRENC
0x0

Bits Name RW Description
31:5 RSVD RO RESERVED

4:0 PRENC RO These bits hold the priority encode of the REGACC interrupts.


IOINTCTL - I/O Interrupt Control

Address:

  Instance 0 Address:   0x50000120

Description:

I/O Interrupt Control

Example Macro Usage:

//
// All macro-based register writes follow the same basic format. For
// single-instance modules, you may use the simpler AM_REG macro. For
// multi-instance macros, you will need to specify the instance number using
// the AM_REGn macro format.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
// AM_REGn(<MODULE>, <INSTANCE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
//
// For registers that do not have specific enumeration values, you may use this alternate format instead.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>(<NUMBER>);
//
// For example, the following three lines of code are equivalent methods of
// writing the value for 12MHZ to the CLKSEL field in the ADC_CFG register.
//
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REGn(ADC, 0, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL(0x1);

Register Fields:

31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0
IOINTSET
0x0
RSVD
0x0
IOINTCLR
0x0
IOINT
0x0
IOINTEN
0x0

Bits Name RW Description
31:24 IOINTSET WO These bits set the IOINT interrupts when written with a 1.

23:17 RSVD RO RESERVED

16 IOINTCLR WO This bit clears all of the IOINT interrupts when written with a 1.

15:8 IOINT RO These bits read the IOINT interrupts.

7:0 IOINTEN RO These bits setread the IOINT interrupt enables.


GENADD - General Address Data

Address:

  Instance 0 Address:   0x50000124

Description:

General Address Data

Example Macro Usage:

//
// All macro-based register writes follow the same basic format. For
// single-instance modules, you may use the simpler AM_REG macro. For
// multi-instance macros, you will need to specify the instance number using
// the AM_REGn macro format.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
// AM_REGn(<MODULE>, <INSTANCE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
//
// For registers that do not have specific enumeration values, you may use this alternate format instead.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>(<NUMBER>);
//
// For example, the following three lines of code are equivalent methods of
// writing the value for 12MHZ to the CLKSEL field in the ADC_CFG register.
//
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REGn(ADC, 0, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL(0x1);

Register Fields:

31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0
RSVD
0x0
GADATA
0x0

Bits Name RW Description
31:8 RSVD RO RESERVED

7:0 GADATA RO The data supplied on the last General Address reference.


INTEN - IO Slave Interrupts: Enable

Address:

  Instance 0 Address:   0x50000200

Description:

Set bits in this register to allow this module to generate the corresponding interrupt.

Example Macro Usage:

//
// All macro-based register writes follow the same basic format. For
// single-instance modules, you may use the simpler AM_REG macro. For
// multi-instance macros, you will need to specify the instance number using
// the AM_REGn macro format.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
// AM_REGn(<MODULE>, <INSTANCE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
//
// For registers that do not have specific enumeration values, you may use this alternate format instead.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>(<NUMBER>);
//
// For example, the following three lines of code are equivalent methods of
// writing the value for 12MHZ to the CLKSEL field in the ADC_CFG register.
//
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REGn(ADC, 0, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL(0x1);

Register Fields:

31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0
RSVD
0x0
IOINTW
0x0
GENAD
0x0
FRDERR
0x0
FUNDFL
0x0
FOVFL
0x0
FSIZE
0x0

Bits Name RW Description
31:6 RSVD RO RESERVED

5 IOINTW RW I2C Interrupt Write interrupt.

4 GENAD RW I2C General Address interrupt.

3 FRDERR RW FIFO Read Error interrupt.

2 FUNDFL RW FIFO Underflow interrupt.

1 FOVFL RW FIFO Overflow interrupt.

0 FSIZE RW FIFO Size interrupt.


INTSTAT - IO Slave Interrupts: Status

Address:

  Instance 0 Address:   0x50000204

Description:

Read bits from this register to discover the cause of a recent interrupt.

Example Macro Usage:

//
// All macro-based register writes follow the same basic format. For
// single-instance modules, you may use the simpler AM_REG macro. For
// multi-instance macros, you will need to specify the instance number using
// the AM_REGn macro format.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
// AM_REGn(<MODULE>, <INSTANCE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
//
// For registers that do not have specific enumeration values, you may use this alternate format instead.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>(<NUMBER>);
//
// For example, the following three lines of code are equivalent methods of
// writing the value for 12MHZ to the CLKSEL field in the ADC_CFG register.
//
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REGn(ADC, 0, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL(0x1);

Register Fields:

31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0
RSVD
0x0
IOINTW
0x0
GENAD
0x0
FRDERR
0x0
FUNDFL
0x0
FOVFL
0x0
FSIZE
0x0

Bits Name RW Description
31:6 RSVD RO RESERVED

5 IOINTW RW I2C Interrupt Write interrupt.

4 GENAD RW I2C General Address interrupt.

3 FRDERR RW FIFO Read Error interrupt.

2 FUNDFL RW FIFO Underflow interrupt.

1 FOVFL RW FIFO Overflow interrupt.

0 FSIZE RW FIFO Size interrupt.


INTCLR - IO Slave Interrupts: Clear

Address:

  Instance 0 Address:   0x50000208

Description:

Write a 1 to a bit in this register to clear the interrupt status associated with that bit.

Example Macro Usage:

//
// All macro-based register writes follow the same basic format. For
// single-instance modules, you may use the simpler AM_REG macro. For
// multi-instance macros, you will need to specify the instance number using
// the AM_REGn macro format.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
// AM_REGn(<MODULE>, <INSTANCE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
//
// For registers that do not have specific enumeration values, you may use this alternate format instead.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>(<NUMBER>);
//
// For example, the following three lines of code are equivalent methods of
// writing the value for 12MHZ to the CLKSEL field in the ADC_CFG register.
//
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REGn(ADC, 0, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL(0x1);

Register Fields:

31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0
RSVD
0x0
IOINTW
0x0
GENAD
0x0
FRDERR
0x0
FUNDFL
0x0
FOVFL
0x0
FSIZE
0x0

Bits Name RW Description
31:6 RSVD RO RESERVED

5 IOINTW RW I2C Interrupt Write interrupt.

4 GENAD RW I2C General Address interrupt.

3 FRDERR RW FIFO Read Error interrupt.

2 FUNDFL RW FIFO Underflow interrupt.

1 FOVFL RW FIFO Overflow interrupt.

0 FSIZE RW FIFO Size interrupt.


INTSET - IO Slave Interrupts: Set

Address:

  Instance 0 Address:   0x5000020C

Description:

Write a 1 to a bit in this register to instantly generate an interrupt from this module. (Generally used for testing purposes).

Example Macro Usage:

//
// All macro-based register writes follow the same basic format. For
// single-instance modules, you may use the simpler AM_REG macro. For
// multi-instance macros, you will need to specify the instance number using
// the AM_REGn macro format.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
// AM_REGn(<MODULE>, <INSTANCE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
//
// For registers that do not have specific enumeration values, you may use this alternate format instead.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>(<NUMBER>);
//
// For example, the following three lines of code are equivalent methods of
// writing the value for 12MHZ to the CLKSEL field in the ADC_CFG register.
//
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REGn(ADC, 0, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL(0x1);

Register Fields:

31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0
RSVD
0x0
IOINTW
0x0
GENAD
0x0
FRDERR
0x0
FUNDFL
0x0
FOVFL
0x0
FSIZE
0x0

Bits Name RW Description
31:6 RSVD RO RESERVED

5 IOINTW RW I2C Interrupt Write interrupt.

4 GENAD RW I2C General Address interrupt.

3 FRDERR RW FIFO Read Error interrupt.

2 FUNDFL RW FIFO Underflow interrupt.

1 FOVFL RW FIFO Overflow interrupt.

0 FSIZE RW FIFO Size interrupt.


REGACCINTEN - Register Access Interrupts: Enable

Address:

  Instance 0 Address:   0x50000210

Description:

Set bits in this register to allow this module to generate the corresponding interrupt.

Example Macro Usage:

//
// All macro-based register writes follow the same basic format. For
// single-instance modules, you may use the simpler AM_REG macro. For
// multi-instance macros, you will need to specify the instance number using
// the AM_REGn macro format.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
// AM_REGn(<MODULE>, <INSTANCE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
//
// For registers that do not have specific enumeration values, you may use this alternate format instead.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>(<NUMBER>);
//
// For example, the following three lines of code are equivalent methods of
// writing the value for 12MHZ to the CLKSEL field in the ADC_CFG register.
//
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REGn(ADC, 0, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL(0x1);

Register Fields:

31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0
REGACC
0x0

Bits Name RW Description
31:0 REGACC RW Register access interrupts.


REGACCINTSTAT - Register Access Interrupts: Status

Address:

  Instance 0 Address:   0x50000214

Description:

Read bits from this register to discover the cause of a recent interrupt.

Example Macro Usage:

//
// All macro-based register writes follow the same basic format. For
// single-instance modules, you may use the simpler AM_REG macro. For
// multi-instance macros, you will need to specify the instance number using
// the AM_REGn macro format.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
// AM_REGn(<MODULE>, <INSTANCE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
//
// For registers that do not have specific enumeration values, you may use this alternate format instead.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>(<NUMBER>);
//
// For example, the following three lines of code are equivalent methods of
// writing the value for 12MHZ to the CLKSEL field in the ADC_CFG register.
//
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REGn(ADC, 0, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL(0x1);

Register Fields:

31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0
REGACC
0x0

Bits Name RW Description
31:0 REGACC RW Register access interrupts.


REGACCINTCLR - Register Access Interrupts: Clear

Address:

  Instance 0 Address:   0x50000218

Description:

Write a 1 to a bit in this register to clear the interrupt status associated with that bit.

Example Macro Usage:

//
// All macro-based register writes follow the same basic format. For
// single-instance modules, you may use the simpler AM_REG macro. For
// multi-instance macros, you will need to specify the instance number using
// the AM_REGn macro format.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
// AM_REGn(<MODULE>, <INSTANCE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
//
// For registers that do not have specific enumeration values, you may use this alternate format instead.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>(<NUMBER>);
//
// For example, the following three lines of code are equivalent methods of
// writing the value for 12MHZ to the CLKSEL field in the ADC_CFG register.
//
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REGn(ADC, 0, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL(0x1);

Register Fields:

31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0
REGACC
0x0

Bits Name RW Description
31:0 REGACC RW Register access interrupts.


REGACCINTSET - Register Access Interrupts: Set

Address:

  Instance 0 Address:   0x5000021C

Description:

Write a 1 to a bit in this register to instantly generate an interrupt from this module. (Generally used for testing purposes).

Example Macro Usage:

//
// All macro-based register writes follow the same basic format. For
// single-instance modules, you may use the simpler AM_REG macro. For
// multi-instance macros, you will need to specify the instance number using
// the AM_REGn macro format.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
// AM_REGn(<MODULE>, <INSTANCE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>_<VALUE>;
//
// For registers that do not have specific enumeration values, you may use this alternate format instead.
//
// AM_REG(<MODULE>, <REGISTER>) |= AM_REG_<MODULE>_<REGISTER>_<FIELD>(<NUMBER>);
//
// For example, the following three lines of code are equivalent methods of
// writing the value for 12MHZ to the CLKSEL field in the ADC_CFG register.
//
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REGn(ADC, 0, CFG) |= AM_REG_ADC_CFG_CLKSEL_12MHZ;
AM_REG(ADC, CFG) |= AM_REG_ADC_CFG_CLKSEL(0x1);

Register Fields:

31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0
REGACC
0x0

Bits Name RW Description
31:0 REGACC RW Register access interrupts.