\n
address_offset : 0x0 Bytes (0x0)
size : 0x2C byte (0x0)
mem_usage : registers
protection : not protected
address_offset : 0x30 Bytes (0x0)
size : 0x8 byte (0x0)
mem_usage : registers
protection : not protected
PC I/O Mode Control
address_offset : 0x0 Bytes (0x0)
access : read-write
reset_value : 0x0
reset_Mask : 0x0
MODE0 : Port A-h I/O Pin[n] Mode Control\nDetermine each I/O mode of Px.n pins.
bits : 0 - 1 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n is in Input mode (tri-state)
#01 : 1
Px.n is in Push-pull Output mode
#10 : 2
Px.n is in Open-drain Output mode
#11 : 3
Px.n is in Quasi-bidirectional mode
End of enumeration elements list.
MODE1 : Port A-h I/O Pin[n] Mode Control\nDetermine each I/O mode of Px.n pins.
bits : 2 - 3 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n is in Input mode (tri-state)
#01 : 1
Px.n is in Push-pull Output mode
#10 : 2
Px.n is in Open-drain Output mode
#11 : 3
Px.n is in Quasi-bidirectional mode
End of enumeration elements list.
MODE2 : Port A-h I/O Pin[n] Mode Control\nDetermine each I/O mode of Px.n pins.
bits : 4 - 5 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n is in Input mode (tri-state)
#01 : 1
Px.n is in Push-pull Output mode
#10 : 2
Px.n is in Open-drain Output mode
#11 : 3
Px.n is in Quasi-bidirectional mode
End of enumeration elements list.
MODE3 : Port A-h I/O Pin[n] Mode Control\nDetermine each I/O mode of Px.n pins.
bits : 6 - 7 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n is in Input mode (tri-state)
#01 : 1
Px.n is in Push-pull Output mode
#10 : 2
Px.n is in Open-drain Output mode
#11 : 3
Px.n is in Quasi-bidirectional mode
End of enumeration elements list.
MODE4 : Port A-h I/O Pin[n] Mode Control\nDetermine each I/O mode of Px.n pins.
bits : 8 - 9 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n is in Input mode (tri-state)
#01 : 1
Px.n is in Push-pull Output mode
#10 : 2
Px.n is in Open-drain Output mode
#11 : 3
Px.n is in Quasi-bidirectional mode
End of enumeration elements list.
MODE5 : Port A-h I/O Pin[n] Mode Control\nDetermine each I/O mode of Px.n pins.
bits : 10 - 11 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n is in Input mode (tri-state)
#01 : 1
Px.n is in Push-pull Output mode
#10 : 2
Px.n is in Open-drain Output mode
#11 : 3
Px.n is in Quasi-bidirectional mode
End of enumeration elements list.
MODE6 : Port A-h I/O Pin[n] Mode Control\nDetermine each I/O mode of Px.n pins.
bits : 12 - 13 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n is in Input mode (tri-state)
#01 : 1
Px.n is in Push-pull Output mode
#10 : 2
Px.n is in Open-drain Output mode
#11 : 3
Px.n is in Quasi-bidirectional mode
End of enumeration elements list.
MODE7 : Port A-h I/O Pin[n] Mode Control\nDetermine each I/O mode of Px.n pins.
bits : 14 - 15 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n is in Input mode (tri-state)
#01 : 1
Px.n is in Push-pull Output mode
#10 : 2
Px.n is in Open-drain Output mode
#11 : 3
Px.n is in Quasi-bidirectional mode
End of enumeration elements list.
MODE8 : Port A-h I/O Pin[n] Mode Control\nDetermine each I/O mode of Px.n pins.
bits : 16 - 17 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n is in Input mode (tri-state)
#01 : 1
Px.n is in Push-pull Output mode
#10 : 2
Px.n is in Open-drain Output mode
#11 : 3
Px.n is in Quasi-bidirectional mode
End of enumeration elements list.
MODE9 : Port A-h I/O Pin[n] Mode Control\nDetermine each I/O mode of Px.n pins.
bits : 18 - 19 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n is in Input mode (tri-state)
#01 : 1
Px.n is in Push-pull Output mode
#10 : 2
Px.n is in Open-drain Output mode
#11 : 3
Px.n is in Quasi-bidirectional mode
End of enumeration elements list.
MODE10 : Port A-h I/O Pin[n] Mode Control\nDetermine each I/O mode of Px.n pins.
bits : 20 - 21 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n is in Input mode (tri-state)
#01 : 1
Px.n is in Push-pull Output mode
#10 : 2
Px.n is in Open-drain Output mode
#11 : 3
Px.n is in Quasi-bidirectional mode
End of enumeration elements list.
MODE11 : Port A-h I/O Pin[n] Mode Control\nDetermine each I/O mode of Px.n pins.
bits : 22 - 23 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n is in Input mode (tri-state)
#01 : 1
Px.n is in Push-pull Output mode
#10 : 2
Px.n is in Open-drain Output mode
#11 : 3
Px.n is in Quasi-bidirectional mode
End of enumeration elements list.
MODE12 : Port A-h I/O Pin[n] Mode Control\nDetermine each I/O mode of Px.n pins.
bits : 24 - 25 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n is in Input mode (tri-state)
#01 : 1
Px.n is in Push-pull Output mode
#10 : 2
Px.n is in Open-drain Output mode
#11 : 3
Px.n is in Quasi-bidirectional mode
End of enumeration elements list.
MODE13 : Port A-h I/O Pin[n] Mode Control\nDetermine each I/O mode of Px.n pins.
bits : 26 - 27 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n is in Input mode (tri-state)
#01 : 1
Px.n is in Push-pull Output mode
#10 : 2
Px.n is in Open-drain Output mode
#11 : 3
Px.n is in Quasi-bidirectional mode
End of enumeration elements list.
MODE14 : Port A-h I/O Pin[n] Mode Control\nDetermine each I/O mode of Px.n pins.
bits : 28 - 29 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n is in Input mode (tri-state)
#01 : 1
Px.n is in Push-pull Output mode
#10 : 2
Px.n is in Open-drain Output mode
#11 : 3
Px.n is in Quasi-bidirectional mode
End of enumeration elements list.
MODE15 : Port A-h I/O Pin[n] Mode Control\nDetermine each I/O mode of Px.n pins.
bits : 30 - 31 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n is in Input mode (tri-state)
#01 : 1
Px.n is in Push-pull Output mode
#10 : 2
Px.n is in Open-drain Output mode
#11 : 3
Px.n is in Quasi-bidirectional mode
End of enumeration elements list.
PC Pin Value
address_offset : 0x10 Bytes (0x0)
access : read-only
reset_value : 0x0
reset_Mask : 0x0
PIN0 : Port A-h Pin[n] Pin Value
Each bit of the register reflects the actual status of the respective Px.n pin. If the bit is 1, it indicates the corresponding pin status is high else the pin status is low.
Note:
bits : 0 - 0 (1 bit)
access : read-only
PIN1 : Port A-h Pin[n] Pin Value
Each bit of the register reflects the actual status of the respective Px.n pin. If the bit is 1, it indicates the corresponding pin status is high else the pin status is low.
Note:
bits : 1 - 1 (1 bit)
access : read-only
PIN2 : Port A-h Pin[n] Pin Value
Each bit of the register reflects the actual status of the respective Px.n pin. If the bit is 1, it indicates the corresponding pin status is high else the pin status is low.
Note:
bits : 2 - 2 (1 bit)
access : read-only
PIN3 : Port A-h Pin[n] Pin Value
Each bit of the register reflects the actual status of the respective Px.n pin. If the bit is 1, it indicates the corresponding pin status is high else the pin status is low.
Note:
bits : 3 - 3 (1 bit)
access : read-only
PIN4 : Port A-h Pin[n] Pin Value
Each bit of the register reflects the actual status of the respective Px.n pin. If the bit is 1, it indicates the corresponding pin status is high else the pin status is low.
Note:
bits : 4 - 4 (1 bit)
access : read-only
PIN5 : Port A-h Pin[n] Pin Value
Each bit of the register reflects the actual status of the respective Px.n pin. If the bit is 1, it indicates the corresponding pin status is high else the pin status is low.
Note:
bits : 5 - 5 (1 bit)
access : read-only
PIN6 : Port A-h Pin[n] Pin Value
Each bit of the register reflects the actual status of the respective Px.n pin. If the bit is 1, it indicates the corresponding pin status is high else the pin status is low.
Note:
bits : 6 - 6 (1 bit)
access : read-only
PIN7 : Port A-h Pin[n] Pin Value
Each bit of the register reflects the actual status of the respective Px.n pin. If the bit is 1, it indicates the corresponding pin status is high else the pin status is low.
Note:
bits : 7 - 7 (1 bit)
access : read-only
PIN8 : Port A-h Pin[n] Pin Value
Each bit of the register reflects the actual status of the respective Px.n pin. If the bit is 1, it indicates the corresponding pin status is high else the pin status is low.
Note:
bits : 8 - 8 (1 bit)
access : read-only
PIN9 : Port A-h Pin[n] Pin Value
Each bit of the register reflects the actual status of the respective Px.n pin. If the bit is 1, it indicates the corresponding pin status is high else the pin status is low.
Note:
bits : 9 - 9 (1 bit)
access : read-only
PIN10 : Port A-h Pin[n] Pin Value
Each bit of the register reflects the actual status of the respective Px.n pin. If the bit is 1, it indicates the corresponding pin status is high else the pin status is low.
Note:
bits : 10 - 10 (1 bit)
access : read-only
PIN11 : Port A-h Pin[n] Pin Value
Each bit of the register reflects the actual status of the respective Px.n pin. If the bit is 1, it indicates the corresponding pin status is high else the pin status is low.
Note:
bits : 11 - 11 (1 bit)
access : read-only
PIN12 : Port A-h Pin[n] Pin Value
Each bit of the register reflects the actual status of the respective Px.n pin. If the bit is 1, it indicates the corresponding pin status is high else the pin status is low.
Note:
bits : 12 - 12 (1 bit)
access : read-only
PIN13 : Port A-h Pin[n] Pin Value
Each bit of the register reflects the actual status of the respective Px.n pin. If the bit is 1, it indicates the corresponding pin status is high else the pin status is low.
Note:
bits : 13 - 13 (1 bit)
access : read-only
PIN14 : Port A-h Pin[n] Pin Value
Each bit of the register reflects the actual status of the respective Px.n pin. If the bit is 1, it indicates the corresponding pin status is high else the pin status is low.
Note:
bits : 14 - 14 (1 bit)
access : read-only
PIN15 : Port A-h Pin[n] Pin Value
Each bit of the register reflects the actual status of the respective Px.n pin. If the bit is 1, it indicates the corresponding pin status is high else the pin status is low.
Note:
bits : 15 - 15 (1 bit)
access : read-only
PC De-bounce Enable Control Register
address_offset : 0x14 Bytes (0x0)
access : read-write
reset_value : 0x0
reset_Mask : 0x0
DBEN0 : Port A-h Pin[n] Input Signal De-bounce Enable Bit
The DBEN[n] bit is used to enable the de-bounce function for each corresponding bit. If the input signal pulse width cannot be sampled by continuous two de-bounce sample cycle, the input signal transition is seen as the signal bounce and will not trigger the interrupt. The de-bounce clock source is controlled by DBCLKSRC (GPIO_DBCTL [4]), one de-bounce sample cycle period is controlled by DBCLKSEL (GPIO_DBCTL [3:0]).
bits : 0 - 0 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n de-bounce function Disabled
#1 : 1
Px.n de-bounce function Enabled
End of enumeration elements list.
DBEN1 : Port A-h Pin[n] Input Signal De-bounce Enable Bit
The DBEN[n] bit is used to enable the de-bounce function for each corresponding bit. If the input signal pulse width cannot be sampled by continuous two de-bounce sample cycle, the input signal transition is seen as the signal bounce and will not trigger the interrupt. The de-bounce clock source is controlled by DBCLKSRC (GPIO_DBCTL [4]), one de-bounce sample cycle period is controlled by DBCLKSEL (GPIO_DBCTL [3:0]).
bits : 1 - 1 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n de-bounce function Disabled
#1 : 1
Px.n de-bounce function Enabled
End of enumeration elements list.
DBEN2 : Port A-h Pin[n] Input Signal De-bounce Enable Bit
The DBEN[n] bit is used to enable the de-bounce function for each corresponding bit. If the input signal pulse width cannot be sampled by continuous two de-bounce sample cycle, the input signal transition is seen as the signal bounce and will not trigger the interrupt. The de-bounce clock source is controlled by DBCLKSRC (GPIO_DBCTL [4]), one de-bounce sample cycle period is controlled by DBCLKSEL (GPIO_DBCTL [3:0]).
bits : 2 - 2 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n de-bounce function Disabled
#1 : 1
Px.n de-bounce function Enabled
End of enumeration elements list.
DBEN3 : Port A-h Pin[n] Input Signal De-bounce Enable Bit
The DBEN[n] bit is used to enable the de-bounce function for each corresponding bit. If the input signal pulse width cannot be sampled by continuous two de-bounce sample cycle, the input signal transition is seen as the signal bounce and will not trigger the interrupt. The de-bounce clock source is controlled by DBCLKSRC (GPIO_DBCTL [4]), one de-bounce sample cycle period is controlled by DBCLKSEL (GPIO_DBCTL [3:0]).
bits : 3 - 3 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n de-bounce function Disabled
#1 : 1
Px.n de-bounce function Enabled
End of enumeration elements list.
DBEN4 : Port A-h Pin[n] Input Signal De-bounce Enable Bit
The DBEN[n] bit is used to enable the de-bounce function for each corresponding bit. If the input signal pulse width cannot be sampled by continuous two de-bounce sample cycle, the input signal transition is seen as the signal bounce and will not trigger the interrupt. The de-bounce clock source is controlled by DBCLKSRC (GPIO_DBCTL [4]), one de-bounce sample cycle period is controlled by DBCLKSEL (GPIO_DBCTL [3:0]).
bits : 4 - 4 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n de-bounce function Disabled
#1 : 1
Px.n de-bounce function Enabled
End of enumeration elements list.
DBEN5 : Port A-h Pin[n] Input Signal De-bounce Enable Bit
The DBEN[n] bit is used to enable the de-bounce function for each corresponding bit. If the input signal pulse width cannot be sampled by continuous two de-bounce sample cycle, the input signal transition is seen as the signal bounce and will not trigger the interrupt. The de-bounce clock source is controlled by DBCLKSRC (GPIO_DBCTL [4]), one de-bounce sample cycle period is controlled by DBCLKSEL (GPIO_DBCTL [3:0]).
bits : 5 - 5 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n de-bounce function Disabled
#1 : 1
Px.n de-bounce function Enabled
End of enumeration elements list.
DBEN6 : Port A-h Pin[n] Input Signal De-bounce Enable Bit
The DBEN[n] bit is used to enable the de-bounce function for each corresponding bit. If the input signal pulse width cannot be sampled by continuous two de-bounce sample cycle, the input signal transition is seen as the signal bounce and will not trigger the interrupt. The de-bounce clock source is controlled by DBCLKSRC (GPIO_DBCTL [4]), one de-bounce sample cycle period is controlled by DBCLKSEL (GPIO_DBCTL [3:0]).
bits : 6 - 6 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n de-bounce function Disabled
#1 : 1
Px.n de-bounce function Enabled
End of enumeration elements list.
DBEN7 : Port A-h Pin[n] Input Signal De-bounce Enable Bit
The DBEN[n] bit is used to enable the de-bounce function for each corresponding bit. If the input signal pulse width cannot be sampled by continuous two de-bounce sample cycle, the input signal transition is seen as the signal bounce and will not trigger the interrupt. The de-bounce clock source is controlled by DBCLKSRC (GPIO_DBCTL [4]), one de-bounce sample cycle period is controlled by DBCLKSEL (GPIO_DBCTL [3:0]).
bits : 7 - 7 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n de-bounce function Disabled
#1 : 1
Px.n de-bounce function Enabled
End of enumeration elements list.
DBEN8 : Port A-h Pin[n] Input Signal De-bounce Enable Bit
The DBEN[n] bit is used to enable the de-bounce function for each corresponding bit. If the input signal pulse width cannot be sampled by continuous two de-bounce sample cycle, the input signal transition is seen as the signal bounce and will not trigger the interrupt. The de-bounce clock source is controlled by DBCLKSRC (GPIO_DBCTL [4]), one de-bounce sample cycle period is controlled by DBCLKSEL (GPIO_DBCTL [3:0]).
bits : 8 - 8 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n de-bounce function Disabled
#1 : 1
Px.n de-bounce function Enabled
End of enumeration elements list.
DBEN9 : Port A-h Pin[n] Input Signal De-bounce Enable Bit
The DBEN[n] bit is used to enable the de-bounce function for each corresponding bit. If the input signal pulse width cannot be sampled by continuous two de-bounce sample cycle, the input signal transition is seen as the signal bounce and will not trigger the interrupt. The de-bounce clock source is controlled by DBCLKSRC (GPIO_DBCTL [4]), one de-bounce sample cycle period is controlled by DBCLKSEL (GPIO_DBCTL [3:0]).
bits : 9 - 9 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n de-bounce function Disabled
#1 : 1
Px.n de-bounce function Enabled
End of enumeration elements list.
DBEN10 : Port A-h Pin[n] Input Signal De-bounce Enable Bit
The DBEN[n] bit is used to enable the de-bounce function for each corresponding bit. If the input signal pulse width cannot be sampled by continuous two de-bounce sample cycle, the input signal transition is seen as the signal bounce and will not trigger the interrupt. The de-bounce clock source is controlled by DBCLKSRC (GPIO_DBCTL [4]), one de-bounce sample cycle period is controlled by DBCLKSEL (GPIO_DBCTL [3:0]).
bits : 10 - 10 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n de-bounce function Disabled
#1 : 1
Px.n de-bounce function Enabled
End of enumeration elements list.
DBEN11 : Port A-h Pin[n] Input Signal De-bounce Enable Bit
The DBEN[n] bit is used to enable the de-bounce function for each corresponding bit. If the input signal pulse width cannot be sampled by continuous two de-bounce sample cycle, the input signal transition is seen as the signal bounce and will not trigger the interrupt. The de-bounce clock source is controlled by DBCLKSRC (GPIO_DBCTL [4]), one de-bounce sample cycle period is controlled by DBCLKSEL (GPIO_DBCTL [3:0]).
bits : 11 - 11 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n de-bounce function Disabled
#1 : 1
Px.n de-bounce function Enabled
End of enumeration elements list.
DBEN12 : Port A-h Pin[n] Input Signal De-bounce Enable Bit
The DBEN[n] bit is used to enable the de-bounce function for each corresponding bit. If the input signal pulse width cannot be sampled by continuous two de-bounce sample cycle, the input signal transition is seen as the signal bounce and will not trigger the interrupt. The de-bounce clock source is controlled by DBCLKSRC (GPIO_DBCTL [4]), one de-bounce sample cycle period is controlled by DBCLKSEL (GPIO_DBCTL [3:0]).
bits : 12 - 12 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n de-bounce function Disabled
#1 : 1
Px.n de-bounce function Enabled
End of enumeration elements list.
DBEN13 : Port A-h Pin[n] Input Signal De-bounce Enable Bit
The DBEN[n] bit is used to enable the de-bounce function for each corresponding bit. If the input signal pulse width cannot be sampled by continuous two de-bounce sample cycle, the input signal transition is seen as the signal bounce and will not trigger the interrupt. The de-bounce clock source is controlled by DBCLKSRC (GPIO_DBCTL [4]), one de-bounce sample cycle period is controlled by DBCLKSEL (GPIO_DBCTL [3:0]).
bits : 13 - 13 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n de-bounce function Disabled
#1 : 1
Px.n de-bounce function Enabled
End of enumeration elements list.
DBEN14 : Port A-h Pin[n] Input Signal De-bounce Enable Bit
The DBEN[n] bit is used to enable the de-bounce function for each corresponding bit. If the input signal pulse width cannot be sampled by continuous two de-bounce sample cycle, the input signal transition is seen as the signal bounce and will not trigger the interrupt. The de-bounce clock source is controlled by DBCLKSRC (GPIO_DBCTL [4]), one de-bounce sample cycle period is controlled by DBCLKSEL (GPIO_DBCTL [3:0]).
bits : 14 - 14 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n de-bounce function Disabled
#1 : 1
Px.n de-bounce function Enabled
End of enumeration elements list.
DBEN15 : Port A-h Pin[n] Input Signal De-bounce Enable Bit
The DBEN[n] bit is used to enable the de-bounce function for each corresponding bit. If the input signal pulse width cannot be sampled by continuous two de-bounce sample cycle, the input signal transition is seen as the signal bounce and will not trigger the interrupt. The de-bounce clock source is controlled by DBCLKSRC (GPIO_DBCTL [4]), one de-bounce sample cycle period is controlled by DBCLKSEL (GPIO_DBCTL [3:0]).
bits : 15 - 15 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n de-bounce function Disabled
#1 : 1
Px.n de-bounce function Enabled
End of enumeration elements list.
PC Interrupt Trigger Type Control
address_offset : 0x18 Bytes (0x0)
access : read-write
reset_value : 0x0
reset_Mask : 0x0
TYPE0 : Port A-h Pin[n] Edge or Level Detection Interrupt Trigger Type Control\nTYPE (Px_INTTYPE[n]) bit is used to control the triggered interrupt is by level trigger or by edge trigger. If the interrupt is by edge trigger, the trigger source can be controlled by de-bounce. If the interrupt is by level trigger, the input source is sampled by one HCLK clock and generates the interrupt.
bits : 0 - 0 (1 bit)
access : read-write
Enumeration:
#0 : 0
Edge trigger interrupt
#1 : 1
Level trigger interrupt
End of enumeration elements list.
TYPE1 : Port A-h Pin[n] Edge or Level Detection Interrupt Trigger Type Control\nTYPE (Px_INTTYPE[n]) bit is used to control the triggered interrupt is by level trigger or by edge trigger. If the interrupt is by edge trigger, the trigger source can be controlled by de-bounce. If the interrupt is by level trigger, the input source is sampled by one HCLK clock and generates the interrupt.
bits : 1 - 1 (1 bit)
access : read-write
Enumeration:
#0 : 0
Edge trigger interrupt
#1 : 1
Level trigger interrupt
End of enumeration elements list.
TYPE2 : Port A-h Pin[n] Edge or Level Detection Interrupt Trigger Type Control\nTYPE (Px_INTTYPE[n]) bit is used to control the triggered interrupt is by level trigger or by edge trigger. If the interrupt is by edge trigger, the trigger source can be controlled by de-bounce. If the interrupt is by level trigger, the input source is sampled by one HCLK clock and generates the interrupt.
bits : 2 - 2 (1 bit)
access : read-write
Enumeration:
#0 : 0
Edge trigger interrupt
#1 : 1
Level trigger interrupt
End of enumeration elements list.
TYPE3 : Port A-h Pin[n] Edge or Level Detection Interrupt Trigger Type Control\nTYPE (Px_INTTYPE[n]) bit is used to control the triggered interrupt is by level trigger or by edge trigger. If the interrupt is by edge trigger, the trigger source can be controlled by de-bounce. If the interrupt is by level trigger, the input source is sampled by one HCLK clock and generates the interrupt.
bits : 3 - 3 (1 bit)
access : read-write
Enumeration:
#0 : 0
Edge trigger interrupt
#1 : 1
Level trigger interrupt
End of enumeration elements list.
TYPE4 : Port A-h Pin[n] Edge or Level Detection Interrupt Trigger Type Control\nTYPE (Px_INTTYPE[n]) bit is used to control the triggered interrupt is by level trigger or by edge trigger. If the interrupt is by edge trigger, the trigger source can be controlled by de-bounce. If the interrupt is by level trigger, the input source is sampled by one HCLK clock and generates the interrupt.
bits : 4 - 4 (1 bit)
access : read-write
Enumeration:
#0 : 0
Edge trigger interrupt
#1 : 1
Level trigger interrupt
End of enumeration elements list.
TYPE5 : Port A-h Pin[n] Edge or Level Detection Interrupt Trigger Type Control\nTYPE (Px_INTTYPE[n]) bit is used to control the triggered interrupt is by level trigger or by edge trigger. If the interrupt is by edge trigger, the trigger source can be controlled by de-bounce. If the interrupt is by level trigger, the input source is sampled by one HCLK clock and generates the interrupt.
bits : 5 - 5 (1 bit)
access : read-write
Enumeration:
#0 : 0
Edge trigger interrupt
#1 : 1
Level trigger interrupt
End of enumeration elements list.
TYPE6 : Port A-h Pin[n] Edge or Level Detection Interrupt Trigger Type Control\nTYPE (Px_INTTYPE[n]) bit is used to control the triggered interrupt is by level trigger or by edge trigger. If the interrupt is by edge trigger, the trigger source can be controlled by de-bounce. If the interrupt is by level trigger, the input source is sampled by one HCLK clock and generates the interrupt.
bits : 6 - 6 (1 bit)
access : read-write
Enumeration:
#0 : 0
Edge trigger interrupt
#1 : 1
Level trigger interrupt
End of enumeration elements list.
TYPE7 : Port A-h Pin[n] Edge or Level Detection Interrupt Trigger Type Control\nTYPE (Px_INTTYPE[n]) bit is used to control the triggered interrupt is by level trigger or by edge trigger. If the interrupt is by edge trigger, the trigger source can be controlled by de-bounce. If the interrupt is by level trigger, the input source is sampled by one HCLK clock and generates the interrupt.
bits : 7 - 7 (1 bit)
access : read-write
Enumeration:
#0 : 0
Edge trigger interrupt
#1 : 1
Level trigger interrupt
End of enumeration elements list.
TYPE8 : Port A-h Pin[n] Edge or Level Detection Interrupt Trigger Type Control\nTYPE (Px_INTTYPE[n]) bit is used to control the triggered interrupt is by level trigger or by edge trigger. If the interrupt is by edge trigger, the trigger source can be controlled by de-bounce. If the interrupt is by level trigger, the input source is sampled by one HCLK clock and generates the interrupt.
bits : 8 - 8 (1 bit)
access : read-write
Enumeration:
#0 : 0
Edge trigger interrupt
#1 : 1
Level trigger interrupt
End of enumeration elements list.
TYPE9 : Port A-h Pin[n] Edge or Level Detection Interrupt Trigger Type Control\nTYPE (Px_INTTYPE[n]) bit is used to control the triggered interrupt is by level trigger or by edge trigger. If the interrupt is by edge trigger, the trigger source can be controlled by de-bounce. If the interrupt is by level trigger, the input source is sampled by one HCLK clock and generates the interrupt.
bits : 9 - 9 (1 bit)
access : read-write
Enumeration:
#0 : 0
Edge trigger interrupt
#1 : 1
Level trigger interrupt
End of enumeration elements list.
TYPE10 : Port A-h Pin[n] Edge or Level Detection Interrupt Trigger Type Control\nTYPE (Px_INTTYPE[n]) bit is used to control the triggered interrupt is by level trigger or by edge trigger. If the interrupt is by edge trigger, the trigger source can be controlled by de-bounce. If the interrupt is by level trigger, the input source is sampled by one HCLK clock and generates the interrupt.
bits : 10 - 10 (1 bit)
access : read-write
Enumeration:
#0 : 0
Edge trigger interrupt
#1 : 1
Level trigger interrupt
End of enumeration elements list.
TYPE11 : Port A-h Pin[n] Edge or Level Detection Interrupt Trigger Type Control\nTYPE (Px_INTTYPE[n]) bit is used to control the triggered interrupt is by level trigger or by edge trigger. If the interrupt is by edge trigger, the trigger source can be controlled by de-bounce. If the interrupt is by level trigger, the input source is sampled by one HCLK clock and generates the interrupt.
bits : 11 - 11 (1 bit)
access : read-write
Enumeration:
#0 : 0
Edge trigger interrupt
#1 : 1
Level trigger interrupt
End of enumeration elements list.
TYPE12 : Port A-h Pin[n] Edge or Level Detection Interrupt Trigger Type Control\nTYPE (Px_INTTYPE[n]) bit is used to control the triggered interrupt is by level trigger or by edge trigger. If the interrupt is by edge trigger, the trigger source can be controlled by de-bounce. If the interrupt is by level trigger, the input source is sampled by one HCLK clock and generates the interrupt.
bits : 12 - 12 (1 bit)
access : read-write
Enumeration:
#0 : 0
Edge trigger interrupt
#1 : 1
Level trigger interrupt
End of enumeration elements list.
TYPE13 : Port A-h Pin[n] Edge or Level Detection Interrupt Trigger Type Control\nTYPE (Px_INTTYPE[n]) bit is used to control the triggered interrupt is by level trigger or by edge trigger. If the interrupt is by edge trigger, the trigger source can be controlled by de-bounce. If the interrupt is by level trigger, the input source is sampled by one HCLK clock and generates the interrupt.
bits : 13 - 13 (1 bit)
access : read-write
Enumeration:
#0 : 0
Edge trigger interrupt
#1 : 1
Level trigger interrupt
End of enumeration elements list.
TYPE14 : Port A-h Pin[n] Edge or Level Detection Interrupt Trigger Type Control\nTYPE (Px_INTTYPE[n]) bit is used to control the triggered interrupt is by level trigger or by edge trigger. If the interrupt is by edge trigger, the trigger source can be controlled by de-bounce. If the interrupt is by level trigger, the input source is sampled by one HCLK clock and generates the interrupt.
bits : 14 - 14 (1 bit)
access : read-write
Enumeration:
#0 : 0
Edge trigger interrupt
#1 : 1
Level trigger interrupt
End of enumeration elements list.
TYPE15 : Port A-h Pin[n] Edge or Level Detection Interrupt Trigger Type Control\nTYPE (Px_INTTYPE[n]) bit is used to control the triggered interrupt is by level trigger or by edge trigger. If the interrupt is by edge trigger, the trigger source can be controlled by de-bounce. If the interrupt is by level trigger, the input source is sampled by one HCLK clock and generates the interrupt.
bits : 15 - 15 (1 bit)
access : read-write
Enumeration:
#0 : 0
Edge trigger interrupt
#1 : 1
Level trigger interrupt
End of enumeration elements list.
PC Interrupt Enable Control Register
address_offset : 0x1C Bytes (0x0)
access : read-write
reset_value : 0x0
reset_Mask : 0x0
FLIEN0 : Port A-h Pin[n] Falling Edge or Low Level Interrupt Trigger Type Enable Bit\nThe FLIEN (Px_INTEN[n]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function.\nWhen setting the FLIEN (Px_INTEN[n]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at low level.\nIf the interrupt is edge trigger(TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from high to low.
bits : 0 - 0 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level low or high to low interrupt Disabled
#1 : 1
Px.n level low or high to low interrupt Enabled
End of enumeration elements list.
FLIEN1 : Port A-h Pin[n] Falling Edge or Low Level Interrupt Trigger Type Enable Bit\nThe FLIEN (Px_INTEN[n]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function.\nWhen setting the FLIEN (Px_INTEN[n]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at low level.\nIf the interrupt is edge trigger(TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from high to low.
bits : 1 - 1 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level low or high to low interrupt Disabled
#1 : 1
Px.n level low or high to low interrupt Enabled
End of enumeration elements list.
FLIEN2 : Port A-h Pin[n] Falling Edge or Low Level Interrupt Trigger Type Enable Bit\nThe FLIEN (Px_INTEN[n]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function.\nWhen setting the FLIEN (Px_INTEN[n]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at low level.\nIf the interrupt is edge trigger(TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from high to low.
bits : 2 - 2 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level low or high to low interrupt Disabled
#1 : 1
Px.n level low or high to low interrupt Enabled
End of enumeration elements list.
FLIEN3 : Port A-h Pin[n] Falling Edge or Low Level Interrupt Trigger Type Enable Bit\nThe FLIEN (Px_INTEN[n]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function.\nWhen setting the FLIEN (Px_INTEN[n]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at low level.\nIf the interrupt is edge trigger(TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from high to low.
bits : 3 - 3 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level low or high to low interrupt Disabled
#1 : 1
Px.n level low or high to low interrupt Enabled
End of enumeration elements list.
FLIEN4 : Port A-h Pin[n] Falling Edge or Low Level Interrupt Trigger Type Enable Bit\nThe FLIEN (Px_INTEN[n]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function.\nWhen setting the FLIEN (Px_INTEN[n]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at low level.\nIf the interrupt is edge trigger(TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from high to low.
bits : 4 - 4 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level low or high to low interrupt Disabled
#1 : 1
Px.n level low or high to low interrupt Enabled
End of enumeration elements list.
FLIEN5 : Port A-h Pin[n] Falling Edge or Low Level Interrupt Trigger Type Enable Bit\nThe FLIEN (Px_INTEN[n]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function.\nWhen setting the FLIEN (Px_INTEN[n]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at low level.\nIf the interrupt is edge trigger(TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from high to low.
bits : 5 - 5 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level low or high to low interrupt Disabled
#1 : 1
Px.n level low or high to low interrupt Enabled
End of enumeration elements list.
FLIEN6 : Port A-h Pin[n] Falling Edge or Low Level Interrupt Trigger Type Enable Bit\nThe FLIEN (Px_INTEN[n]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function.\nWhen setting the FLIEN (Px_INTEN[n]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at low level.\nIf the interrupt is edge trigger(TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from high to low.
bits : 6 - 6 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level low or high to low interrupt Disabled
#1 : 1
Px.n level low or high to low interrupt Enabled
End of enumeration elements list.
FLIEN7 : Port A-h Pin[n] Falling Edge or Low Level Interrupt Trigger Type Enable Bit\nThe FLIEN (Px_INTEN[n]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function.\nWhen setting the FLIEN (Px_INTEN[n]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at low level.\nIf the interrupt is edge trigger(TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from high to low.
bits : 7 - 7 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level low or high to low interrupt Disabled
#1 : 1
Px.n level low or high to low interrupt Enabled
End of enumeration elements list.
FLIEN8 : Port A-h Pin[n] Falling Edge or Low Level Interrupt Trigger Type Enable Bit\nThe FLIEN (Px_INTEN[n]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function.\nWhen setting the FLIEN (Px_INTEN[n]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at low level.\nIf the interrupt is edge trigger(TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from high to low.
bits : 8 - 8 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level low or high to low interrupt Disabled
#1 : 1
Px.n level low or high to low interrupt Enabled
End of enumeration elements list.
FLIEN9 : Port A-h Pin[n] Falling Edge or Low Level Interrupt Trigger Type Enable Bit\nThe FLIEN (Px_INTEN[n]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function.\nWhen setting the FLIEN (Px_INTEN[n]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at low level.\nIf the interrupt is edge trigger(TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from high to low.
bits : 9 - 9 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level low or high to low interrupt Disabled
#1 : 1
Px.n level low or high to low interrupt Enabled
End of enumeration elements list.
FLIEN10 : Port A-h Pin[n] Falling Edge or Low Level Interrupt Trigger Type Enable Bit\nThe FLIEN (Px_INTEN[n]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function.\nWhen setting the FLIEN (Px_INTEN[n]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at low level.\nIf the interrupt is edge trigger(TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from high to low.
bits : 10 - 10 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level low or high to low interrupt Disabled
#1 : 1
Px.n level low or high to low interrupt Enabled
End of enumeration elements list.
FLIEN11 : Port A-h Pin[n] Falling Edge or Low Level Interrupt Trigger Type Enable Bit\nThe FLIEN (Px_INTEN[n]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function.\nWhen setting the FLIEN (Px_INTEN[n]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at low level.\nIf the interrupt is edge trigger(TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from high to low.
bits : 11 - 11 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level low or high to low interrupt Disabled
#1 : 1
Px.n level low or high to low interrupt Enabled
End of enumeration elements list.
FLIEN12 : Port A-h Pin[n] Falling Edge or Low Level Interrupt Trigger Type Enable Bit\nThe FLIEN (Px_INTEN[n]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function.\nWhen setting the FLIEN (Px_INTEN[n]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at low level.\nIf the interrupt is edge trigger(TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from high to low.
bits : 12 - 12 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level low or high to low interrupt Disabled
#1 : 1
Px.n level low or high to low interrupt Enabled
End of enumeration elements list.
FLIEN13 : Port A-h Pin[n] Falling Edge or Low Level Interrupt Trigger Type Enable Bit\nThe FLIEN (Px_INTEN[n]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function.\nWhen setting the FLIEN (Px_INTEN[n]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at low level.\nIf the interrupt is edge trigger(TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from high to low.
bits : 13 - 13 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level low or high to low interrupt Disabled
#1 : 1
Px.n level low or high to low interrupt Enabled
End of enumeration elements list.
FLIEN14 : Port A-h Pin[n] Falling Edge or Low Level Interrupt Trigger Type Enable Bit\nThe FLIEN (Px_INTEN[n]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function.\nWhen setting the FLIEN (Px_INTEN[n]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at low level.\nIf the interrupt is edge trigger(TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from high to low.
bits : 14 - 14 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level low or high to low interrupt Disabled
#1 : 1
Px.n level low or high to low interrupt Enabled
End of enumeration elements list.
FLIEN15 : Port A-h Pin[n] Falling Edge or Low Level Interrupt Trigger Type Enable Bit\nThe FLIEN (Px_INTEN[n]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function.\nWhen setting the FLIEN (Px_INTEN[n]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at low level.\nIf the interrupt is edge trigger(TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from high to low.
bits : 15 - 15 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level low or high to low interrupt Disabled
#1 : 1
Px.n level low or high to low interrupt Enabled
End of enumeration elements list.
RHIEN0 : Port A-h Pin[n] Rising Edge or High Level Interrupt Trigger Type Enable Bit\nThe RHIEN (Px_INTEN[n+16]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function. \nWhen setting the RHIEN (Px_INTEN[n+16]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at high level.\nIf the interrupt is edge trigger (TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from low to high.
bits : 16 - 16 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level high or low to high interrupt Disabled
#1 : 1
Px.n level high or low to high interrupt Enabled
End of enumeration elements list.
RHIEN1 : Port A-h Pin[n] Rising Edge or High Level Interrupt Trigger Type Enable Bit\nThe RHIEN (Px_INTEN[n+16]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function. \nWhen setting the RHIEN (Px_INTEN[n+16]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at high level.\nIf the interrupt is edge trigger (TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from low to high.
bits : 17 - 17 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level high or low to high interrupt Disabled
#1 : 1
Px.n level high or low to high interrupt Enabled
End of enumeration elements list.
RHIEN2 : Port A-h Pin[n] Rising Edge or High Level Interrupt Trigger Type Enable Bit\nThe RHIEN (Px_INTEN[n+16]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function. \nWhen setting the RHIEN (Px_INTEN[n+16]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at high level.\nIf the interrupt is edge trigger (TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from low to high.
bits : 18 - 18 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level high or low to high interrupt Disabled
#1 : 1
Px.n level high or low to high interrupt Enabled
End of enumeration elements list.
RHIEN3 : Port A-h Pin[n] Rising Edge or High Level Interrupt Trigger Type Enable Bit\nThe RHIEN (Px_INTEN[n+16]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function. \nWhen setting the RHIEN (Px_INTEN[n+16]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at high level.\nIf the interrupt is edge trigger (TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from low to high.
bits : 19 - 19 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level high or low to high interrupt Disabled
#1 : 1
Px.n level high or low to high interrupt Enabled
End of enumeration elements list.
RHIEN4 : Port A-h Pin[n] Rising Edge or High Level Interrupt Trigger Type Enable Bit\nThe RHIEN (Px_INTEN[n+16]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function. \nWhen setting the RHIEN (Px_INTEN[n+16]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at high level.\nIf the interrupt is edge trigger (TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from low to high.
bits : 20 - 20 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level high or low to high interrupt Disabled
#1 : 1
Px.n level high or low to high interrupt Enabled
End of enumeration elements list.
RHIEN5 : Port A-h Pin[n] Rising Edge or High Level Interrupt Trigger Type Enable Bit\nThe RHIEN (Px_INTEN[n+16]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function. \nWhen setting the RHIEN (Px_INTEN[n+16]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at high level.\nIf the interrupt is edge trigger (TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from low to high.
bits : 21 - 21 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level high or low to high interrupt Disabled
#1 : 1
Px.n level high or low to high interrupt Enabled
End of enumeration elements list.
RHIEN6 : Port A-h Pin[n] Rising Edge or High Level Interrupt Trigger Type Enable Bit\nThe RHIEN (Px_INTEN[n+16]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function. \nWhen setting the RHIEN (Px_INTEN[n+16]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at high level.\nIf the interrupt is edge trigger (TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from low to high.
bits : 22 - 22 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level high or low to high interrupt Disabled
#1 : 1
Px.n level high or low to high interrupt Enabled
End of enumeration elements list.
RHIEN7 : Port A-h Pin[n] Rising Edge or High Level Interrupt Trigger Type Enable Bit\nThe RHIEN (Px_INTEN[n+16]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function. \nWhen setting the RHIEN (Px_INTEN[n+16]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at high level.\nIf the interrupt is edge trigger (TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from low to high.
bits : 23 - 23 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level high or low to high interrupt Disabled
#1 : 1
Px.n level high or low to high interrupt Enabled
End of enumeration elements list.
RHIEN8 : Port A-h Pin[n] Rising Edge or High Level Interrupt Trigger Type Enable Bit\nThe RHIEN (Px_INTEN[n+16]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function. \nWhen setting the RHIEN (Px_INTEN[n+16]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at high level.\nIf the interrupt is edge trigger (TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from low to high.
bits : 24 - 24 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level high or low to high interrupt Disabled
#1 : 1
Px.n level high or low to high interrupt Enabled
End of enumeration elements list.
RHIEN9 : Port A-h Pin[n] Rising Edge or High Level Interrupt Trigger Type Enable Bit\nThe RHIEN (Px_INTEN[n+16]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function. \nWhen setting the RHIEN (Px_INTEN[n+16]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at high level.\nIf the interrupt is edge trigger (TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from low to high.
bits : 25 - 25 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level high or low to high interrupt Disabled
#1 : 1
Px.n level high or low to high interrupt Enabled
End of enumeration elements list.
RHIEN10 : Port A-h Pin[n] Rising Edge or High Level Interrupt Trigger Type Enable Bit\nThe RHIEN (Px_INTEN[n+16]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function. \nWhen setting the RHIEN (Px_INTEN[n+16]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at high level.\nIf the interrupt is edge trigger (TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from low to high.
bits : 26 - 26 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level high or low to high interrupt Disabled
#1 : 1
Px.n level high or low to high interrupt Enabled
End of enumeration elements list.
RHIEN11 : Port A-h Pin[n] Rising Edge or High Level Interrupt Trigger Type Enable Bit\nThe RHIEN (Px_INTEN[n+16]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function. \nWhen setting the RHIEN (Px_INTEN[n+16]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at high level.\nIf the interrupt is edge trigger (TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from low to high.
bits : 27 - 27 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level high or low to high interrupt Disabled
#1 : 1
Px.n level high or low to high interrupt Enabled
End of enumeration elements list.
RHIEN12 : Port A-h Pin[n] Rising Edge or High Level Interrupt Trigger Type Enable Bit\nThe RHIEN (Px_INTEN[n+16]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function. \nWhen setting the RHIEN (Px_INTEN[n+16]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at high level.\nIf the interrupt is edge trigger (TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from low to high.
bits : 28 - 28 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level high or low to high interrupt Disabled
#1 : 1
Px.n level high or low to high interrupt Enabled
End of enumeration elements list.
RHIEN13 : Port A-h Pin[n] Rising Edge or High Level Interrupt Trigger Type Enable Bit\nThe RHIEN (Px_INTEN[n+16]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function. \nWhen setting the RHIEN (Px_INTEN[n+16]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at high level.\nIf the interrupt is edge trigger (TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from low to high.
bits : 29 - 29 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level high or low to high interrupt Disabled
#1 : 1
Px.n level high or low to high interrupt Enabled
End of enumeration elements list.
RHIEN14 : Port A-h Pin[n] Rising Edge or High Level Interrupt Trigger Type Enable Bit\nThe RHIEN (Px_INTEN[n+16]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function. \nWhen setting the RHIEN (Px_INTEN[n+16]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at high level.\nIf the interrupt is edge trigger (TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from low to high.
bits : 30 - 30 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level high or low to high interrupt Disabled
#1 : 1
Px.n level high or low to high interrupt Enabled
End of enumeration elements list.
RHIEN15 : Port A-h Pin[n] Rising Edge or High Level Interrupt Trigger Type Enable Bit\nThe RHIEN (Px_INTEN[n+16]) bit is used to enable the interrupt for each of the corresponding input Px.n pin. Set bit to 1 also enable the pin wake-up function. \nWhen setting the RHIEN (Px_INTEN[n+16]) bit to 1 :\nIf the interrupt is level trigger (TYPE (Px_INTTYPE[n]) bit is set to 1), the input Px.n pin will generate the interrupt while this pin state is at high level.\nIf the interrupt is edge trigger (TYPE (Px_INTTYPE[n]) bit is set to 0), the input Px.n pin will generate the interrupt while this pin state changed from low to high.
bits : 31 - 31 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n level high or low to high interrupt Disabled
#1 : 1
Px.n level high or low to high interrupt Enabled
End of enumeration elements list.
PC Interrupt Source Flag
address_offset : 0x20 Bytes (0x0)
access : read-write
reset_value : 0x0
reset_Mask : 0x0
INTSRC0 : Port A-h Pin[n] Interrupt Source Flag\nWrite Operation:
bits : 0 - 0 (1 bit)
access : read-write
Enumeration:
#0 : 0
No action.\nNo interrupt at Px.n
#1 : 1
Clear the corresponding pending interrupt.\nPx.n generates an interrupt
End of enumeration elements list.
INTSRC1 : Port A-h Pin[n] Interrupt Source Flag\nWrite Operation:
bits : 1 - 1 (1 bit)
access : read-write
Enumeration:
#0 : 0
No action.\nNo interrupt at Px.n
#1 : 1
Clear the corresponding pending interrupt.\nPx.n generates an interrupt
End of enumeration elements list.
INTSRC2 : Port A-h Pin[n] Interrupt Source Flag\nWrite Operation:
bits : 2 - 2 (1 bit)
access : read-write
Enumeration:
#0 : 0
No action.\nNo interrupt at Px.n
#1 : 1
Clear the corresponding pending interrupt.\nPx.n generates an interrupt
End of enumeration elements list.
INTSRC3 : Port A-h Pin[n] Interrupt Source Flag\nWrite Operation:
bits : 3 - 3 (1 bit)
access : read-write
Enumeration:
#0 : 0
No action.\nNo interrupt at Px.n
#1 : 1
Clear the corresponding pending interrupt.\nPx.n generates an interrupt
End of enumeration elements list.
INTSRC4 : Port A-h Pin[n] Interrupt Source Flag\nWrite Operation:
bits : 4 - 4 (1 bit)
access : read-write
Enumeration:
#0 : 0
No action.\nNo interrupt at Px.n
#1 : 1
Clear the corresponding pending interrupt.\nPx.n generates an interrupt
End of enumeration elements list.
INTSRC5 : Port A-h Pin[n] Interrupt Source Flag\nWrite Operation:
bits : 5 - 5 (1 bit)
access : read-write
Enumeration:
#0 : 0
No action.\nNo interrupt at Px.n
#1 : 1
Clear the corresponding pending interrupt.\nPx.n generates an interrupt
End of enumeration elements list.
INTSRC6 : Port A-h Pin[n] Interrupt Source Flag\nWrite Operation:
bits : 6 - 6 (1 bit)
access : read-write
Enumeration:
#0 : 0
No action.\nNo interrupt at Px.n
#1 : 1
Clear the corresponding pending interrupt.\nPx.n generates an interrupt
End of enumeration elements list.
INTSRC7 : Port A-h Pin[n] Interrupt Source Flag\nWrite Operation:
bits : 7 - 7 (1 bit)
access : read-write
Enumeration:
#0 : 0
No action.\nNo interrupt at Px.n
#1 : 1
Clear the corresponding pending interrupt.\nPx.n generates an interrupt
End of enumeration elements list.
INTSRC8 : Port A-h Pin[n] Interrupt Source Flag\nWrite Operation:
bits : 8 - 8 (1 bit)
access : read-write
Enumeration:
#0 : 0
No action.\nNo interrupt at Px.n
#1 : 1
Clear the corresponding pending interrupt.\nPx.n generates an interrupt
End of enumeration elements list.
INTSRC9 : Port A-h Pin[n] Interrupt Source Flag\nWrite Operation:
bits : 9 - 9 (1 bit)
access : read-write
Enumeration:
#0 : 0
No action.\nNo interrupt at Px.n
#1 : 1
Clear the corresponding pending interrupt.\nPx.n generates an interrupt
End of enumeration elements list.
INTSRC10 : Port A-h Pin[n] Interrupt Source Flag\nWrite Operation:
bits : 10 - 10 (1 bit)
access : read-write
Enumeration:
#0 : 0
No action.\nNo interrupt at Px.n
#1 : 1
Clear the corresponding pending interrupt.\nPx.n generates an interrupt
End of enumeration elements list.
INTSRC11 : Port A-h Pin[n] Interrupt Source Flag\nWrite Operation:
bits : 11 - 11 (1 bit)
access : read-write
Enumeration:
#0 : 0
No action.\nNo interrupt at Px.n
#1 : 1
Clear the corresponding pending interrupt.\nPx.n generates an interrupt
End of enumeration elements list.
INTSRC12 : Port A-h Pin[n] Interrupt Source Flag\nWrite Operation:
bits : 12 - 12 (1 bit)
access : read-write
Enumeration:
#0 : 0
No action.\nNo interrupt at Px.n
#1 : 1
Clear the corresponding pending interrupt.\nPx.n generates an interrupt
End of enumeration elements list.
INTSRC13 : Port A-h Pin[n] Interrupt Source Flag\nWrite Operation:
bits : 13 - 13 (1 bit)
access : read-write
Enumeration:
#0 : 0
No action.\nNo interrupt at Px.n
#1 : 1
Clear the corresponding pending interrupt.\nPx.n generates an interrupt
End of enumeration elements list.
INTSRC14 : Port A-h Pin[n] Interrupt Source Flag\nWrite Operation:
bits : 14 - 14 (1 bit)
access : read-write
Enumeration:
#0 : 0
No action.\nNo interrupt at Px.n
#1 : 1
Clear the corresponding pending interrupt.\nPx.n generates an interrupt
End of enumeration elements list.
INTSRC15 : Port A-h Pin[n] Interrupt Source Flag\nWrite Operation:
bits : 15 - 15 (1 bit)
access : read-write
Enumeration:
#0 : 0
No action.\nNo interrupt at Px.n
#1 : 1
Clear the corresponding pending interrupt.\nPx.n generates an interrupt
End of enumeration elements list.
PC Input Schmitt Trigger Enable Register
address_offset : 0x24 Bytes (0x0)
access : read-write
reset_value : 0x0
reset_Mask : 0x0
SMTEN0 : Port A-h Pin[n] Input Schmitt Trigger Enable Bit
bits : 0 - 0 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n input schmitt trigger function Disabled
#1 : 1
Px.n input schmitt trigger function Enabled
End of enumeration elements list.
SMTEN1 : Port A-h Pin[n] Input Schmitt Trigger Enable Bit
bits : 1 - 1 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n input schmitt trigger function Disabled
#1 : 1
Px.n input schmitt trigger function Enabled
End of enumeration elements list.
SMTEN2 : Port A-h Pin[n] Input Schmitt Trigger Enable Bit
bits : 2 - 2 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n input schmitt trigger function Disabled
#1 : 1
Px.n input schmitt trigger function Enabled
End of enumeration elements list.
SMTEN3 : Port A-h Pin[n] Input Schmitt Trigger Enable Bit
bits : 3 - 3 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n input schmitt trigger function Disabled
#1 : 1
Px.n input schmitt trigger function Enabled
End of enumeration elements list.
SMTEN4 : Port A-h Pin[n] Input Schmitt Trigger Enable Bit
bits : 4 - 4 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n input schmitt trigger function Disabled
#1 : 1
Px.n input schmitt trigger function Enabled
End of enumeration elements list.
SMTEN5 : Port A-h Pin[n] Input Schmitt Trigger Enable Bit
bits : 5 - 5 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n input schmitt trigger function Disabled
#1 : 1
Px.n input schmitt trigger function Enabled
End of enumeration elements list.
SMTEN6 : Port A-h Pin[n] Input Schmitt Trigger Enable Bit
bits : 6 - 6 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n input schmitt trigger function Disabled
#1 : 1
Px.n input schmitt trigger function Enabled
End of enumeration elements list.
SMTEN7 : Port A-h Pin[n] Input Schmitt Trigger Enable Bit
bits : 7 - 7 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n input schmitt trigger function Disabled
#1 : 1
Px.n input schmitt trigger function Enabled
End of enumeration elements list.
SMTEN8 : Port A-h Pin[n] Input Schmitt Trigger Enable Bit
bits : 8 - 8 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n input schmitt trigger function Disabled
#1 : 1
Px.n input schmitt trigger function Enabled
End of enumeration elements list.
SMTEN9 : Port A-h Pin[n] Input Schmitt Trigger Enable Bit
bits : 9 - 9 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n input schmitt trigger function Disabled
#1 : 1
Px.n input schmitt trigger function Enabled
End of enumeration elements list.
SMTEN10 : Port A-h Pin[n] Input Schmitt Trigger Enable Bit
bits : 10 - 10 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n input schmitt trigger function Disabled
#1 : 1
Px.n input schmitt trigger function Enabled
End of enumeration elements list.
SMTEN11 : Port A-h Pin[n] Input Schmitt Trigger Enable Bit
bits : 11 - 11 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n input schmitt trigger function Disabled
#1 : 1
Px.n input schmitt trigger function Enabled
End of enumeration elements list.
SMTEN12 : Port A-h Pin[n] Input Schmitt Trigger Enable Bit
bits : 12 - 12 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n input schmitt trigger function Disabled
#1 : 1
Px.n input schmitt trigger function Enabled
End of enumeration elements list.
SMTEN13 : Port A-h Pin[n] Input Schmitt Trigger Enable Bit
bits : 13 - 13 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n input schmitt trigger function Disabled
#1 : 1
Px.n input schmitt trigger function Enabled
End of enumeration elements list.
SMTEN14 : Port A-h Pin[n] Input Schmitt Trigger Enable Bit
bits : 14 - 14 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n input schmitt trigger function Disabled
#1 : 1
Px.n input schmitt trigger function Enabled
End of enumeration elements list.
SMTEN15 : Port A-h Pin[n] Input Schmitt Trigger Enable Bit
bits : 15 - 15 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n input schmitt trigger function Disabled
#1 : 1
Px.n input schmitt trigger function Enabled
End of enumeration elements list.
PC High Slew Rate Control Register
address_offset : 0x28 Bytes (0x0)
access : read-write
reset_value : 0x0
reset_Mask : 0x0
HSREN0 : Port A-h Pin[n] High Slew Rate Control
bits : 0 - 1 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n output with normal slew rate mode (maximum 40 MHz at 2.7V)
#01 : 1
Px.n output with high slew rate mode (maximum 80 MHz at 2.7V)
#10 : 2
Px.n output with fast slew rate mode (maximum 100 MHz at 2.7V)
#11 : 3
Reserved.
End of enumeration elements list.
HSREN1 : Port A-h Pin[n] High Slew Rate Control
bits : 2 - 3 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n output with normal slew rate mode (maximum 40 MHz at 2.7V)
#01 : 1
Px.n output with high slew rate mode (maximum 80 MHz at 2.7V)
#10 : 2
Px.n output with fast slew rate mode (maximum 100 MHz at 2.7V)
#11 : 3
Reserved.
End of enumeration elements list.
HSREN2 : Port A-h Pin[n] High Slew Rate Control
bits : 4 - 5 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n output with normal slew rate mode (maximum 40 MHz at 2.7V)
#01 : 1
Px.n output with high slew rate mode (maximum 80 MHz at 2.7V)
#10 : 2
Px.n output with fast slew rate mode (maximum 100 MHz at 2.7V)
#11 : 3
Reserved.
End of enumeration elements list.
HSREN3 : Port A-h Pin[n] High Slew Rate Control
bits : 6 - 7 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n output with normal slew rate mode (maximum 40 MHz at 2.7V)
#01 : 1
Px.n output with high slew rate mode (maximum 80 MHz at 2.7V)
#10 : 2
Px.n output with fast slew rate mode (maximum 100 MHz at 2.7V)
#11 : 3
Reserved.
End of enumeration elements list.
HSREN4 : Port A-h Pin[n] High Slew Rate Control
bits : 8 - 9 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n output with normal slew rate mode (maximum 40 MHz at 2.7V)
#01 : 1
Px.n output with high slew rate mode (maximum 80 MHz at 2.7V)
#10 : 2
Px.n output with fast slew rate mode (maximum 100 MHz at 2.7V)
#11 : 3
Reserved.
End of enumeration elements list.
HSREN5 : Port A-h Pin[n] High Slew Rate Control
bits : 10 - 11 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n output with normal slew rate mode (maximum 40 MHz at 2.7V)
#01 : 1
Px.n output with high slew rate mode (maximum 80 MHz at 2.7V)
#10 : 2
Px.n output with fast slew rate mode (maximum 100 MHz at 2.7V)
#11 : 3
Reserved.
End of enumeration elements list.
HSREN6 : Port A-h Pin[n] High Slew Rate Control
bits : 12 - 13 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n output with normal slew rate mode (maximum 40 MHz at 2.7V)
#01 : 1
Px.n output with high slew rate mode (maximum 80 MHz at 2.7V)
#10 : 2
Px.n output with fast slew rate mode (maximum 100 MHz at 2.7V)
#11 : 3
Reserved.
End of enumeration elements list.
HSREN7 : Port A-h Pin[n] High Slew Rate Control
bits : 14 - 15 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n output with normal slew rate mode (maximum 40 MHz at 2.7V)
#01 : 1
Px.n output with high slew rate mode (maximum 80 MHz at 2.7V)
#10 : 2
Px.n output with fast slew rate mode (maximum 100 MHz at 2.7V)
#11 : 3
Reserved.
End of enumeration elements list.
HSREN8 : Port A-h Pin[n] High Slew Rate Control
bits : 16 - 17 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n output with normal slew rate mode (maximum 40 MHz at 2.7V)
#01 : 1
Px.n output with high slew rate mode (maximum 80 MHz at 2.7V)
#10 : 2
Px.n output with fast slew rate mode (maximum 100 MHz at 2.7V)
#11 : 3
Reserved.
End of enumeration elements list.
HSREN9 : Port A-h Pin[n] High Slew Rate Control
bits : 18 - 19 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n output with normal slew rate mode (maximum 40 MHz at 2.7V)
#01 : 1
Px.n output with high slew rate mode (maximum 80 MHz at 2.7V)
#10 : 2
Px.n output with fast slew rate mode (maximum 100 MHz at 2.7V)
#11 : 3
Reserved.
End of enumeration elements list.
HSREN10 : Port A-h Pin[n] High Slew Rate Control
bits : 20 - 21 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n output with normal slew rate mode (maximum 40 MHz at 2.7V)
#01 : 1
Px.n output with high slew rate mode (maximum 80 MHz at 2.7V)
#10 : 2
Px.n output with fast slew rate mode (maximum 100 MHz at 2.7V)
#11 : 3
Reserved.
End of enumeration elements list.
HSREN11 : Port A-h Pin[n] High Slew Rate Control
bits : 22 - 23 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n output with normal slew rate mode (maximum 40 MHz at 2.7V)
#01 : 1
Px.n output with high slew rate mode (maximum 80 MHz at 2.7V)
#10 : 2
Px.n output with fast slew rate mode (maximum 100 MHz at 2.7V)
#11 : 3
Reserved.
End of enumeration elements list.
HSREN12 : Port A-h Pin[n] High Slew Rate Control
bits : 24 - 25 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n output with normal slew rate mode (maximum 40 MHz at 2.7V)
#01 : 1
Px.n output with high slew rate mode (maximum 80 MHz at 2.7V)
#10 : 2
Px.n output with fast slew rate mode (maximum 100 MHz at 2.7V)
#11 : 3
Reserved.
End of enumeration elements list.
HSREN13 : Port A-h Pin[n] High Slew Rate Control
bits : 26 - 27 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n output with normal slew rate mode (maximum 40 MHz at 2.7V)
#01 : 1
Px.n output with high slew rate mode (maximum 80 MHz at 2.7V)
#10 : 2
Px.n output with fast slew rate mode (maximum 100 MHz at 2.7V)
#11 : 3
Reserved.
End of enumeration elements list.
HSREN14 : Port A-h Pin[n] High Slew Rate Control
bits : 28 - 29 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n output with normal slew rate mode (maximum 40 MHz at 2.7V)
#01 : 1
Px.n output with high slew rate mode (maximum 80 MHz at 2.7V)
#10 : 2
Px.n output with fast slew rate mode (maximum 100 MHz at 2.7V)
#11 : 3
Reserved.
End of enumeration elements list.
HSREN15 : Port A-h Pin[n] High Slew Rate Control
bits : 30 - 31 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n output with normal slew rate mode (maximum 40 MHz at 2.7V)
#01 : 1
Px.n output with high slew rate mode (maximum 80 MHz at 2.7V)
#10 : 2
Px.n output with fast slew rate mode (maximum 100 MHz at 2.7V)
#11 : 3
Reserved.
End of enumeration elements list.
PC Pull-up and Pull-down Selection Register
address_offset : 0x30 Bytes (0x0)
access : read-write
reset_value : 0x0
reset_Mask : 0x0
PUSEL0 : Port A-h Pin[n] Pull-up and Pull-down Enable Register\nDetermine each I/O Pull-up/pull-down of Px.n pins.
bits : 0 - 1 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n pull-up and pull-down disable
#01 : 1
Px.n pull-up enable
#10 : 2
Px.n pull-down enable
#11 : 3
Px.n pull-up and pull-down disable
End of enumeration elements list.
PUSEL1 : Port A-h Pin[n] Pull-up and Pull-down Enable Register\nDetermine each I/O Pull-up/pull-down of Px.n pins.
bits : 2 - 3 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n pull-up and pull-down disable
#01 : 1
Px.n pull-up enable
#10 : 2
Px.n pull-down enable
#11 : 3
Px.n pull-up and pull-down disable
End of enumeration elements list.
PUSEL2 : Port A-h Pin[n] Pull-up and Pull-down Enable Register\nDetermine each I/O Pull-up/pull-down of Px.n pins.
bits : 4 - 5 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n pull-up and pull-down disable
#01 : 1
Px.n pull-up enable
#10 : 2
Px.n pull-down enable
#11 : 3
Px.n pull-up and pull-down disable
End of enumeration elements list.
PUSEL3 : Port A-h Pin[n] Pull-up and Pull-down Enable Register\nDetermine each I/O Pull-up/pull-down of Px.n pins.
bits : 6 - 7 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n pull-up and pull-down disable
#01 : 1
Px.n pull-up enable
#10 : 2
Px.n pull-down enable
#11 : 3
Px.n pull-up and pull-down disable
End of enumeration elements list.
PUSEL4 : Port A-h Pin[n] Pull-up and Pull-down Enable Register\nDetermine each I/O Pull-up/pull-down of Px.n pins.
bits : 8 - 9 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n pull-up and pull-down disable
#01 : 1
Px.n pull-up enable
#10 : 2
Px.n pull-down enable
#11 : 3
Px.n pull-up and pull-down disable
End of enumeration elements list.
PUSEL5 : Port A-h Pin[n] Pull-up and Pull-down Enable Register\nDetermine each I/O Pull-up/pull-down of Px.n pins.
bits : 10 - 11 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n pull-up and pull-down disable
#01 : 1
Px.n pull-up enable
#10 : 2
Px.n pull-down enable
#11 : 3
Px.n pull-up and pull-down disable
End of enumeration elements list.
PUSEL6 : Port A-h Pin[n] Pull-up and Pull-down Enable Register\nDetermine each I/O Pull-up/pull-down of Px.n pins.
bits : 12 - 13 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n pull-up and pull-down disable
#01 : 1
Px.n pull-up enable
#10 : 2
Px.n pull-down enable
#11 : 3
Px.n pull-up and pull-down disable
End of enumeration elements list.
PUSEL7 : Port A-h Pin[n] Pull-up and Pull-down Enable Register\nDetermine each I/O Pull-up/pull-down of Px.n pins.
bits : 14 - 15 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n pull-up and pull-down disable
#01 : 1
Px.n pull-up enable
#10 : 2
Px.n pull-down enable
#11 : 3
Px.n pull-up and pull-down disable
End of enumeration elements list.
PUSEL8 : Port A-h Pin[n] Pull-up and Pull-down Enable Register\nDetermine each I/O Pull-up/pull-down of Px.n pins.
bits : 16 - 17 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n pull-up and pull-down disable
#01 : 1
Px.n pull-up enable
#10 : 2
Px.n pull-down enable
#11 : 3
Px.n pull-up and pull-down disable
End of enumeration elements list.
PUSEL9 : Port A-h Pin[n] Pull-up and Pull-down Enable Register\nDetermine each I/O Pull-up/pull-down of Px.n pins.
bits : 18 - 19 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n pull-up and pull-down disable
#01 : 1
Px.n pull-up enable
#10 : 2
Px.n pull-down enable
#11 : 3
Px.n pull-up and pull-down disable
End of enumeration elements list.
PUSEL10 : Port A-h Pin[n] Pull-up and Pull-down Enable Register\nDetermine each I/O Pull-up/pull-down of Px.n pins.
bits : 20 - 21 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n pull-up and pull-down disable
#01 : 1
Px.n pull-up enable
#10 : 2
Px.n pull-down enable
#11 : 3
Px.n pull-up and pull-down disable
End of enumeration elements list.
PUSEL11 : Port A-h Pin[n] Pull-up and Pull-down Enable Register\nDetermine each I/O Pull-up/pull-down of Px.n pins.
bits : 22 - 23 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n pull-up and pull-down disable
#01 : 1
Px.n pull-up enable
#10 : 2
Px.n pull-down enable
#11 : 3
Px.n pull-up and pull-down disable
End of enumeration elements list.
PUSEL12 : Port A-h Pin[n] Pull-up and Pull-down Enable Register\nDetermine each I/O Pull-up/pull-down of Px.n pins.
bits : 24 - 25 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n pull-up and pull-down disable
#01 : 1
Px.n pull-up enable
#10 : 2
Px.n pull-down enable
#11 : 3
Px.n pull-up and pull-down disable
End of enumeration elements list.
PUSEL13 : Port A-h Pin[n] Pull-up and Pull-down Enable Register\nDetermine each I/O Pull-up/pull-down of Px.n pins.
bits : 26 - 27 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n pull-up and pull-down disable
#01 : 1
Px.n pull-up enable
#10 : 2
Px.n pull-down enable
#11 : 3
Px.n pull-up and pull-down disable
End of enumeration elements list.
PUSEL14 : Port A-h Pin[n] Pull-up and Pull-down Enable Register\nDetermine each I/O Pull-up/pull-down of Px.n pins.
bits : 28 - 29 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n pull-up and pull-down disable
#01 : 1
Px.n pull-up enable
#10 : 2
Px.n pull-down enable
#11 : 3
Px.n pull-up and pull-down disable
End of enumeration elements list.
PUSEL15 : Port A-h Pin[n] Pull-up and Pull-down Enable Register\nDetermine each I/O Pull-up/pull-down of Px.n pins.
bits : 30 - 31 (2 bit)
access : read-write
Enumeration:
#00 : 0
Px.n pull-up and pull-down disable
#01 : 1
Px.n pull-up enable
#10 : 2
Px.n pull-down enable
#11 : 3
Px.n pull-up and pull-down disable
End of enumeration elements list.
PC Interrupt De-bounce Control Register
address_offset : 0x34 Bytes (0x0)
size : -1 bit
access : read-write
reset_value : 0x0
reset_Mask : 0x0
DBCLKSEL : De-bounce Sampling Cycle Selection
bits : 0 - 3 (4 bit)
access : read-write
Enumeration:
#0000 : 0
Sample interrupt input once per 1 clocks
#0001 : 1
Sample interrupt input once per 2 clocks
#0010 : 2
Sample interrupt input once per 4 clocks
#0011 : 3
Sample interrupt input once per 8 clocks
#0100 : 4
Sample interrupt input once per 16 clocks
#0101 : 5
Sample interrupt input once per 32 clocks
#0110 : 6
Sample interrupt input once per 64 clocks
#0111 : 7
Sample interrupt input once per 128 clocks
#1000 : 8
Sample interrupt input once per 256 clocks
#1001 : 9
Sample interrupt input once per 2*256 clocks
#1010 : 10
Sample interrupt input once per 4*256 clocks
#1011 : 11
Sample interrupt input once per 8*256 clocks
#1100 : 12
Sample interrupt input once per 16*256 clocks
#1101 : 13
Sample interrupt input once per 32*256 clocks
#1110 : 14
Sample interrupt input once per 64*256 clocks
#1111 : 15
Sample interrupt input once per 128*256 clocks
End of enumeration elements list.
DBCLKSRC : De-bounce Counter Clock Source Selection
bits : 4 - 4 (1 bit)
access : read-write
Enumeration:
#0 : 0
De-bounce counter clock source is the HCLK
#1 : 1
De-bounce counter clock source is the 10 kHz internal low speed RC oscillator (LIRC)
End of enumeration elements list.
ICLKON : Interrupt Clock on Mode\nNote: It is recommended to disable this bit to save system power if no special application concern.
bits : 5 - 5 (1 bit)
access : read-write
Enumeration:
#0 : 0
Edge detection circuit is active only if I/O pin corresponding RHIEN (Px_INTEN[n+16])/FLIEN (Px_INTEN[n]) bit is set to 1
#1 : 1
All I/O pins edge detection circuit is always active after reset
End of enumeration elements list.
PC Digital Input Path Disable Control
address_offset : 0x4 Bytes (0x0)
access : read-write
reset_value : 0x0
reset_Mask : 0x0
DINOFF0 : Port A-h Pin[n] Digital Input Path Disable Bit\nEach of these bits is used to control if the digital input path of corresponding Px.n pin is disabled. If input is analog signal, users can disable Px.n digital input path to avoid input current leakage.
bits : 16 - 16 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n digital input path Enabled
#1 : 1
Px.n digital input path Disabled (digital input tied to low)
End of enumeration elements list.
DINOFF1 : Port A-h Pin[n] Digital Input Path Disable Bit\nEach of these bits is used to control if the digital input path of corresponding Px.n pin is disabled. If input is analog signal, users can disable Px.n digital input path to avoid input current leakage.
bits : 17 - 17 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n digital input path Enabled
#1 : 1
Px.n digital input path Disabled (digital input tied to low)
End of enumeration elements list.
DINOFF2 : Port A-h Pin[n] Digital Input Path Disable Bit\nEach of these bits is used to control if the digital input path of corresponding Px.n pin is disabled. If input is analog signal, users can disable Px.n digital input path to avoid input current leakage.
bits : 18 - 18 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n digital input path Enabled
#1 : 1
Px.n digital input path Disabled (digital input tied to low)
End of enumeration elements list.
DINOFF3 : Port A-h Pin[n] Digital Input Path Disable Bit\nEach of these bits is used to control if the digital input path of corresponding Px.n pin is disabled. If input is analog signal, users can disable Px.n digital input path to avoid input current leakage.
bits : 19 - 19 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n digital input path Enabled
#1 : 1
Px.n digital input path Disabled (digital input tied to low)
End of enumeration elements list.
DINOFF4 : Port A-h Pin[n] Digital Input Path Disable Bit\nEach of these bits is used to control if the digital input path of corresponding Px.n pin is disabled. If input is analog signal, users can disable Px.n digital input path to avoid input current leakage.
bits : 20 - 20 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n digital input path Enabled
#1 : 1
Px.n digital input path Disabled (digital input tied to low)
End of enumeration elements list.
DINOFF5 : Port A-h Pin[n] Digital Input Path Disable Bit\nEach of these bits is used to control if the digital input path of corresponding Px.n pin is disabled. If input is analog signal, users can disable Px.n digital input path to avoid input current leakage.
bits : 21 - 21 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n digital input path Enabled
#1 : 1
Px.n digital input path Disabled (digital input tied to low)
End of enumeration elements list.
DINOFF6 : Port A-h Pin[n] Digital Input Path Disable Bit\nEach of these bits is used to control if the digital input path of corresponding Px.n pin is disabled. If input is analog signal, users can disable Px.n digital input path to avoid input current leakage.
bits : 22 - 22 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n digital input path Enabled
#1 : 1
Px.n digital input path Disabled (digital input tied to low)
End of enumeration elements list.
DINOFF7 : Port A-h Pin[n] Digital Input Path Disable Bit\nEach of these bits is used to control if the digital input path of corresponding Px.n pin is disabled. If input is analog signal, users can disable Px.n digital input path to avoid input current leakage.
bits : 23 - 23 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n digital input path Enabled
#1 : 1
Px.n digital input path Disabled (digital input tied to low)
End of enumeration elements list.
DINOFF8 : Port A-h Pin[n] Digital Input Path Disable Bit\nEach of these bits is used to control if the digital input path of corresponding Px.n pin is disabled. If input is analog signal, users can disable Px.n digital input path to avoid input current leakage.
bits : 24 - 24 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n digital input path Enabled
#1 : 1
Px.n digital input path Disabled (digital input tied to low)
End of enumeration elements list.
DINOFF9 : Port A-h Pin[n] Digital Input Path Disable Bit\nEach of these bits is used to control if the digital input path of corresponding Px.n pin is disabled. If input is analog signal, users can disable Px.n digital input path to avoid input current leakage.
bits : 25 - 25 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n digital input path Enabled
#1 : 1
Px.n digital input path Disabled (digital input tied to low)
End of enumeration elements list.
DINOFF10 : Port A-h Pin[n] Digital Input Path Disable Bit\nEach of these bits is used to control if the digital input path of corresponding Px.n pin is disabled. If input is analog signal, users can disable Px.n digital input path to avoid input current leakage.
bits : 26 - 26 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n digital input path Enabled
#1 : 1
Px.n digital input path Disabled (digital input tied to low)
End of enumeration elements list.
DINOFF11 : Port A-h Pin[n] Digital Input Path Disable Bit\nEach of these bits is used to control if the digital input path of corresponding Px.n pin is disabled. If input is analog signal, users can disable Px.n digital input path to avoid input current leakage.
bits : 27 - 27 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n digital input path Enabled
#1 : 1
Px.n digital input path Disabled (digital input tied to low)
End of enumeration elements list.
DINOFF12 : Port A-h Pin[n] Digital Input Path Disable Bit\nEach of these bits is used to control if the digital input path of corresponding Px.n pin is disabled. If input is analog signal, users can disable Px.n digital input path to avoid input current leakage.
bits : 28 - 28 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n digital input path Enabled
#1 : 1
Px.n digital input path Disabled (digital input tied to low)
End of enumeration elements list.
DINOFF13 : Port A-h Pin[n] Digital Input Path Disable Bit\nEach of these bits is used to control if the digital input path of corresponding Px.n pin is disabled. If input is analog signal, users can disable Px.n digital input path to avoid input current leakage.
bits : 29 - 29 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n digital input path Enabled
#1 : 1
Px.n digital input path Disabled (digital input tied to low)
End of enumeration elements list.
DINOFF14 : Port A-h Pin[n] Digital Input Path Disable Bit\nEach of these bits is used to control if the digital input path of corresponding Px.n pin is disabled. If input is analog signal, users can disable Px.n digital input path to avoid input current leakage.
bits : 30 - 30 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n digital input path Enabled
#1 : 1
Px.n digital input path Disabled (digital input tied to low)
End of enumeration elements list.
DINOFF15 : Port A-h Pin[n] Digital Input Path Disable Bit\nEach of these bits is used to control if the digital input path of corresponding Px.n pin is disabled. If input is analog signal, users can disable Px.n digital input path to avoid input current leakage.
bits : 31 - 31 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n digital input path Enabled
#1 : 1
Px.n digital input path Disabled (digital input tied to low)
End of enumeration elements list.
PC Data Output Value
address_offset : 0x8 Bytes (0x0)
size : -1 bit
access : read-write
reset_value : 0x0
reset_Mask : 0x0
DOUT0 : Port A-h Pin[n] Output Value\nEach of these bits controls the status of a Px.n pin when the Px.n is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode.
bits : 0 - 0 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n will drive Low if the Px.n pin is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode
#1 : 1
Px.n will drive High if the Px.n pin is configured as Push-pull output or Quasi-bidirectional mode
End of enumeration elements list.
DOUT1 : Port A-h Pin[n] Output Value\nEach of these bits controls the status of a Px.n pin when the Px.n is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode.
bits : 1 - 1 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n will drive Low if the Px.n pin is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode
#1 : 1
Px.n will drive High if the Px.n pin is configured as Push-pull output or Quasi-bidirectional mode
End of enumeration elements list.
DOUT2 : Port A-h Pin[n] Output Value\nEach of these bits controls the status of a Px.n pin when the Px.n is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode.
bits : 2 - 2 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n will drive Low if the Px.n pin is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode
#1 : 1
Px.n will drive High if the Px.n pin is configured as Push-pull output or Quasi-bidirectional mode
End of enumeration elements list.
DOUT3 : Port A-h Pin[n] Output Value\nEach of these bits controls the status of a Px.n pin when the Px.n is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode.
bits : 3 - 3 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n will drive Low if the Px.n pin is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode
#1 : 1
Px.n will drive High if the Px.n pin is configured as Push-pull output or Quasi-bidirectional mode
End of enumeration elements list.
DOUT4 : Port A-h Pin[n] Output Value\nEach of these bits controls the status of a Px.n pin when the Px.n is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode.
bits : 4 - 4 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n will drive Low if the Px.n pin is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode
#1 : 1
Px.n will drive High if the Px.n pin is configured as Push-pull output or Quasi-bidirectional mode
End of enumeration elements list.
DOUT5 : Port A-h Pin[n] Output Value\nEach of these bits controls the status of a Px.n pin when the Px.n is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode.
bits : 5 - 5 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n will drive Low if the Px.n pin is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode
#1 : 1
Px.n will drive High if the Px.n pin is configured as Push-pull output or Quasi-bidirectional mode
End of enumeration elements list.
DOUT6 : Port A-h Pin[n] Output Value\nEach of these bits controls the status of a Px.n pin when the Px.n is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode.
bits : 6 - 6 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n will drive Low if the Px.n pin is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode
#1 : 1
Px.n will drive High if the Px.n pin is configured as Push-pull output or Quasi-bidirectional mode
End of enumeration elements list.
DOUT7 : Port A-h Pin[n] Output Value\nEach of these bits controls the status of a Px.n pin when the Px.n is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode.
bits : 7 - 7 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n will drive Low if the Px.n pin is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode
#1 : 1
Px.n will drive High if the Px.n pin is configured as Push-pull output or Quasi-bidirectional mode
End of enumeration elements list.
DOUT8 : Port A-h Pin[n] Output Value\nEach of these bits controls the status of a Px.n pin when the Px.n is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode.
bits : 8 - 8 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n will drive Low if the Px.n pin is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode
#1 : 1
Px.n will drive High if the Px.n pin is configured as Push-pull output or Quasi-bidirectional mode
End of enumeration elements list.
DOUT9 : Port A-h Pin[n] Output Value\nEach of these bits controls the status of a Px.n pin when the Px.n is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode.
bits : 9 - 9 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n will drive Low if the Px.n pin is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode
#1 : 1
Px.n will drive High if the Px.n pin is configured as Push-pull output or Quasi-bidirectional mode
End of enumeration elements list.
DOUT10 : Port A-h Pin[n] Output Value\nEach of these bits controls the status of a Px.n pin when the Px.n is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode.
bits : 10 - 10 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n will drive Low if the Px.n pin is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode
#1 : 1
Px.n will drive High if the Px.n pin is configured as Push-pull output or Quasi-bidirectional mode
End of enumeration elements list.
DOUT11 : Port A-h Pin[n] Output Value\nEach of these bits controls the status of a Px.n pin when the Px.n is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode.
bits : 11 - 11 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n will drive Low if the Px.n pin is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode
#1 : 1
Px.n will drive High if the Px.n pin is configured as Push-pull output or Quasi-bidirectional mode
End of enumeration elements list.
DOUT12 : Port A-h Pin[n] Output Value\nEach of these bits controls the status of a Px.n pin when the Px.n is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode.
bits : 12 - 12 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n will drive Low if the Px.n pin is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode
#1 : 1
Px.n will drive High if the Px.n pin is configured as Push-pull output or Quasi-bidirectional mode
End of enumeration elements list.
DOUT13 : Port A-h Pin[n] Output Value\nEach of these bits controls the status of a Px.n pin when the Px.n is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode.
bits : 13 - 13 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n will drive Low if the Px.n pin is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode
#1 : 1
Px.n will drive High if the Px.n pin is configured as Push-pull output or Quasi-bidirectional mode
End of enumeration elements list.
DOUT14 : Port A-h Pin[n] Output Value\nEach of these bits controls the status of a Px.n pin when the Px.n is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode.
bits : 14 - 14 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n will drive Low if the Px.n pin is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode
#1 : 1
Px.n will drive High if the Px.n pin is configured as Push-pull output or Quasi-bidirectional mode
End of enumeration elements list.
DOUT15 : Port A-h Pin[n] Output Value\nEach of these bits controls the status of a Px.n pin when the Px.n is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode.
bits : 15 - 15 (1 bit)
access : read-write
Enumeration:
#0 : 0
Px.n will drive Low if the Px.n pin is configured as Push-pull output, Open-drain output or Quasi-bidirectional mode
#1 : 1
Px.n will drive High if the Px.n pin is configured as Push-pull output or Quasi-bidirectional mode
End of enumeration elements list.
PC Data Output Write Mask
address_offset : 0xC Bytes (0x0)
access : read-write
reset_value : 0x0
reset_Mask : 0x0
DATMSK0 : Port A-h Pin[n] Data Output Write Mask\nThese bits are used to protect the corresponding DOUT (Px_DOUT[n]) bit. When the DATMSK (Px_DATMSK[n]) bit is set to 1, the corresponding DOUT (Px_DOUT[n]) bit is protected. If the write signal is masked, writing data to the protect bit is ineffective.
bits : 0 - 0 (1 bit)
access : read-write
Enumeration:
#0 : 0
Corresponding DOUT (Px_DOUT[n]) bit can be updated
#1 : 1
Corresponding DOUT (Px_DOUT[n]) bit protected
End of enumeration elements list.
DATMSK1 : Port A-h Pin[n] Data Output Write Mask\nThese bits are used to protect the corresponding DOUT (Px_DOUT[n]) bit. When the DATMSK (Px_DATMSK[n]) bit is set to 1, the corresponding DOUT (Px_DOUT[n]) bit is protected. If the write signal is masked, writing data to the protect bit is ineffective.
bits : 1 - 1 (1 bit)
access : read-write
Enumeration:
#0 : 0
Corresponding DOUT (Px_DOUT[n]) bit can be updated
#1 : 1
Corresponding DOUT (Px_DOUT[n]) bit protected
End of enumeration elements list.
DATMSK2 : Port A-h Pin[n] Data Output Write Mask\nThese bits are used to protect the corresponding DOUT (Px_DOUT[n]) bit. When the DATMSK (Px_DATMSK[n]) bit is set to 1, the corresponding DOUT (Px_DOUT[n]) bit is protected. If the write signal is masked, writing data to the protect bit is ineffective.
bits : 2 - 2 (1 bit)
access : read-write
Enumeration:
#0 : 0
Corresponding DOUT (Px_DOUT[n]) bit can be updated
#1 : 1
Corresponding DOUT (Px_DOUT[n]) bit protected
End of enumeration elements list.
DATMSK3 : Port A-h Pin[n] Data Output Write Mask\nThese bits are used to protect the corresponding DOUT (Px_DOUT[n]) bit. When the DATMSK (Px_DATMSK[n]) bit is set to 1, the corresponding DOUT (Px_DOUT[n]) bit is protected. If the write signal is masked, writing data to the protect bit is ineffective.
bits : 3 - 3 (1 bit)
access : read-write
Enumeration:
#0 : 0
Corresponding DOUT (Px_DOUT[n]) bit can be updated
#1 : 1
Corresponding DOUT (Px_DOUT[n]) bit protected
End of enumeration elements list.
DATMSK4 : Port A-h Pin[n] Data Output Write Mask\nThese bits are used to protect the corresponding DOUT (Px_DOUT[n]) bit. When the DATMSK (Px_DATMSK[n]) bit is set to 1, the corresponding DOUT (Px_DOUT[n]) bit is protected. If the write signal is masked, writing data to the protect bit is ineffective.
bits : 4 - 4 (1 bit)
access : read-write
Enumeration:
#0 : 0
Corresponding DOUT (Px_DOUT[n]) bit can be updated
#1 : 1
Corresponding DOUT (Px_DOUT[n]) bit protected
End of enumeration elements list.
DATMSK5 : Port A-h Pin[n] Data Output Write Mask\nThese bits are used to protect the corresponding DOUT (Px_DOUT[n]) bit. When the DATMSK (Px_DATMSK[n]) bit is set to 1, the corresponding DOUT (Px_DOUT[n]) bit is protected. If the write signal is masked, writing data to the protect bit is ineffective.
bits : 5 - 5 (1 bit)
access : read-write
Enumeration:
#0 : 0
Corresponding DOUT (Px_DOUT[n]) bit can be updated
#1 : 1
Corresponding DOUT (Px_DOUT[n]) bit protected
End of enumeration elements list.
DATMSK6 : Port A-h Pin[n] Data Output Write Mask\nThese bits are used to protect the corresponding DOUT (Px_DOUT[n]) bit. When the DATMSK (Px_DATMSK[n]) bit is set to 1, the corresponding DOUT (Px_DOUT[n]) bit is protected. If the write signal is masked, writing data to the protect bit is ineffective.
bits : 6 - 6 (1 bit)
access : read-write
Enumeration:
#0 : 0
Corresponding DOUT (Px_DOUT[n]) bit can be updated
#1 : 1
Corresponding DOUT (Px_DOUT[n]) bit protected
End of enumeration elements list.
DATMSK7 : Port A-h Pin[n] Data Output Write Mask\nThese bits are used to protect the corresponding DOUT (Px_DOUT[n]) bit. When the DATMSK (Px_DATMSK[n]) bit is set to 1, the corresponding DOUT (Px_DOUT[n]) bit is protected. If the write signal is masked, writing data to the protect bit is ineffective.
bits : 7 - 7 (1 bit)
access : read-write
Enumeration:
#0 : 0
Corresponding DOUT (Px_DOUT[n]) bit can be updated
#1 : 1
Corresponding DOUT (Px_DOUT[n]) bit protected
End of enumeration elements list.
DATMSK8 : Port A-h Pin[n] Data Output Write Mask\nThese bits are used to protect the corresponding DOUT (Px_DOUT[n]) bit. When the DATMSK (Px_DATMSK[n]) bit is set to 1, the corresponding DOUT (Px_DOUT[n]) bit is protected. If the write signal is masked, writing data to the protect bit is ineffective.
bits : 8 - 8 (1 bit)
access : read-write
Enumeration:
#0 : 0
Corresponding DOUT (Px_DOUT[n]) bit can be updated
#1 : 1
Corresponding DOUT (Px_DOUT[n]) bit protected
End of enumeration elements list.
DATMSK9 : Port A-h Pin[n] Data Output Write Mask\nThese bits are used to protect the corresponding DOUT (Px_DOUT[n]) bit. When the DATMSK (Px_DATMSK[n]) bit is set to 1, the corresponding DOUT (Px_DOUT[n]) bit is protected. If the write signal is masked, writing data to the protect bit is ineffective.
bits : 9 - 9 (1 bit)
access : read-write
Enumeration:
#0 : 0
Corresponding DOUT (Px_DOUT[n]) bit can be updated
#1 : 1
Corresponding DOUT (Px_DOUT[n]) bit protected
End of enumeration elements list.
DATMSK10 : Port A-h Pin[n] Data Output Write Mask\nThese bits are used to protect the corresponding DOUT (Px_DOUT[n]) bit. When the DATMSK (Px_DATMSK[n]) bit is set to 1, the corresponding DOUT (Px_DOUT[n]) bit is protected. If the write signal is masked, writing data to the protect bit is ineffective.
bits : 10 - 10 (1 bit)
access : read-write
Enumeration:
#0 : 0
Corresponding DOUT (Px_DOUT[n]) bit can be updated
#1 : 1
Corresponding DOUT (Px_DOUT[n]) bit protected
End of enumeration elements list.
DATMSK11 : Port A-h Pin[n] Data Output Write Mask\nThese bits are used to protect the corresponding DOUT (Px_DOUT[n]) bit. When the DATMSK (Px_DATMSK[n]) bit is set to 1, the corresponding DOUT (Px_DOUT[n]) bit is protected. If the write signal is masked, writing data to the protect bit is ineffective.
bits : 11 - 11 (1 bit)
access : read-write
Enumeration:
#0 : 0
Corresponding DOUT (Px_DOUT[n]) bit can be updated
#1 : 1
Corresponding DOUT (Px_DOUT[n]) bit protected
End of enumeration elements list.
DATMSK12 : Port A-h Pin[n] Data Output Write Mask\nThese bits are used to protect the corresponding DOUT (Px_DOUT[n]) bit. When the DATMSK (Px_DATMSK[n]) bit is set to 1, the corresponding DOUT (Px_DOUT[n]) bit is protected. If the write signal is masked, writing data to the protect bit is ineffective.
bits : 12 - 12 (1 bit)
access : read-write
Enumeration:
#0 : 0
Corresponding DOUT (Px_DOUT[n]) bit can be updated
#1 : 1
Corresponding DOUT (Px_DOUT[n]) bit protected
End of enumeration elements list.
DATMSK13 : Port A-h Pin[n] Data Output Write Mask\nThese bits are used to protect the corresponding DOUT (Px_DOUT[n]) bit. When the DATMSK (Px_DATMSK[n]) bit is set to 1, the corresponding DOUT (Px_DOUT[n]) bit is protected. If the write signal is masked, writing data to the protect bit is ineffective.
bits : 13 - 13 (1 bit)
access : read-write
Enumeration:
#0 : 0
Corresponding DOUT (Px_DOUT[n]) bit can be updated
#1 : 1
Corresponding DOUT (Px_DOUT[n]) bit protected
End of enumeration elements list.
DATMSK14 : Port A-h Pin[n] Data Output Write Mask\nThese bits are used to protect the corresponding DOUT (Px_DOUT[n]) bit. When the DATMSK (Px_DATMSK[n]) bit is set to 1, the corresponding DOUT (Px_DOUT[n]) bit is protected. If the write signal is masked, writing data to the protect bit is ineffective.
bits : 14 - 14 (1 bit)
access : read-write
Enumeration:
#0 : 0
Corresponding DOUT (Px_DOUT[n]) bit can be updated
#1 : 1
Corresponding DOUT (Px_DOUT[n]) bit protected
End of enumeration elements list.
DATMSK15 : Port A-h Pin[n] Data Output Write Mask\nThese bits are used to protect the corresponding DOUT (Px_DOUT[n]) bit. When the DATMSK (Px_DATMSK[n]) bit is set to 1, the corresponding DOUT (Px_DOUT[n]) bit is protected. If the write signal is masked, writing data to the protect bit is ineffective.
bits : 15 - 15 (1 bit)
access : read-write
Enumeration:
#0 : 0
Corresponding DOUT (Px_DOUT[n]) bit can be updated
#1 : 1
Corresponding DOUT (Px_DOUT[n]) bit protected
End of enumeration elements list.
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