mbed official / mbed

The official Mbed 2 C/C++ SDK provides the software platform and libraries to build your applications.

Dependents:   hello SerialTestv11 SerialTestv12 Sierpinski ... more

mbed 2

This is the mbed 2 library. If you'd like to learn about Mbed OS please see the mbed-os docs.

TARGET_LPC1347/LPC13Uxx.h@64:e3affc9e7238, 2013-08-05 (annotated)

Committer:
bogdanm
Date:
Mon Aug 05 12:28:09 2013 +0300
Revision:
64:e3affc9e7238
Child:
66:9c8f0e3462fb
New build system structure, new target (LPC1347), bug fixes (I2C read/write errors, LPC11U24 memory map and others)

Who changed what in which revision?

UserRevisionLine numberNew contents of line
bogdanm 64:e3affc9e7238 1
bogdanm 64:e3affc9e7238 2 /****************************************************************************************************//**
bogdanm 64:e3affc9e7238 3 * @file LPC13Uxx.h
bogdanm 64:e3affc9e7238 4 *
bogdanm 64:e3affc9e7238 5 *
bogdanm 64:e3affc9e7238 6 *
bogdanm 64:e3affc9e7238 7 * @brief CMSIS Cortex-M3 Core Peripheral Access Layer Header File for
bogdanm 64:e3affc9e7238 8 * default LPC13Uxx Device Series
bogdanm 64:e3affc9e7238 9 *
bogdanm 64:e3affc9e7238 10 * @version V0.1
bogdanm 64:e3affc9e7238 11 * @date 18. Jan 2012
bogdanm 64:e3affc9e7238 12 *
bogdanm 64:e3affc9e7238 13 * @note Generated with SFDGen V2.6 Build 4f on Tuesday, 17.01.2012 13:39:52
bogdanm 64:e3affc9e7238 14 *
bogdanm 64:e3affc9e7238 15 * from CMSIS SVD File 'LPC13uxx_svd_v0.1.xml' Version 0.1,
bogdanm 64:e3affc9e7238 16 * created on Thurs, 01.19.2012 15:13:15, last modified on Thurs, 01.19.2012 15:53:09
bogdanm 64:e3affc9e7238 17 *
bogdanm 64:e3affc9e7238 18 *******************************************************************************************************/
bogdanm 64:e3affc9e7238 19
bogdanm 64:e3affc9e7238 20 /** @addtogroup NXP
bogdanm 64:e3affc9e7238 21 * @{
bogdanm 64:e3affc9e7238 22 */
bogdanm 64:e3affc9e7238 23
bogdanm 64:e3affc9e7238 24 /** @addtogroup LPC13Uxx
bogdanm 64:e3affc9e7238 25 * @{
bogdanm 64:e3affc9e7238 26 */
bogdanm 64:e3affc9e7238 27
bogdanm 64:e3affc9e7238 28 #ifndef __LPC13UXX_H__
bogdanm 64:e3affc9e7238 29 #define __LPC13UXX_H__
bogdanm 64:e3affc9e7238 30
bogdanm 64:e3affc9e7238 31 #ifdef __cplusplus
bogdanm 64:e3affc9e7238 32 extern "C" {
bogdanm 64:e3affc9e7238 33 #endif
bogdanm 64:e3affc9e7238 34
bogdanm 64:e3affc9e7238 35
bogdanm 64:e3affc9e7238 36 #if defined ( __CC_ARM )
bogdanm 64:e3affc9e7238 37 #pragma anon_unions
bogdanm 64:e3affc9e7238 38 #endif
bogdanm 64:e3affc9e7238 39
bogdanm 64:e3affc9e7238 40 /* Interrupt Number Definition */
bogdanm 64:e3affc9e7238 41
bogdanm 64:e3affc9e7238 42 typedef enum {
bogdanm 64:e3affc9e7238 43 // ------------------------- Cortex-M3 Processor Exceptions Numbers -----------------------------
bogdanm 64:e3affc9e7238 44 Reset_IRQn = -15, /*!< 1 Reset Vector, invoked on Power up and warm reset */
bogdanm 64:e3affc9e7238 45 NonMaskableInt_IRQn = -14, /*!< 2 Non maskable Interrupt, cannot be stopped or preempted */
bogdanm 64:e3affc9e7238 46 HardFault_IRQn = -13, /*!< 3 Hard Fault, all classes of Fault */
bogdanm 64:e3affc9e7238 47 MemoryManagement_IRQn = -12, /*!< 4 Memory Management, MPU mismatch, including Access Violation and No Match */
bogdanm 64:e3affc9e7238 48 BusFault_IRQn = -11, /*!< 5 Bus Fault, Pre-Fetch-, Memory Access Fault, other address/memory related Fault */
bogdanm 64:e3affc9e7238 49 UsageFault_IRQn = -10, /*!< 6 Usage Fault, i.e. Undef Instruction, Illegal State Transition */
bogdanm 64:e3affc9e7238 50 SVCall_IRQn = -5, /*!< 11 System Service Call via SVC instruction */
bogdanm 64:e3affc9e7238 51 DebugMonitor_IRQn = -4, /*!< 12 Debug Monitor */
bogdanm 64:e3affc9e7238 52 PendSV_IRQn = -2, /*!< 14 Pendable request for system service */
bogdanm 64:e3affc9e7238 53 SysTick_IRQn = -1, /*!< 15 System Tick Timer */
bogdanm 64:e3affc9e7238 54 // ---------------------------- LPC13Uxx Specific Interrupt Numbers --------------------------------
bogdanm 64:e3affc9e7238 55 PIN_INT0_IRQn = 0, /*!< 0 PIN_INT0 */
bogdanm 64:e3affc9e7238 56 PIN_INT1_IRQn = 1, /*!< 1 PIN_INT1 */
bogdanm 64:e3affc9e7238 57 PIN_INT2_IRQn = 2, /*!< 2 PIN_INT2 */
bogdanm 64:e3affc9e7238 58 PIN_INT3_IRQn = 3, /*!< 3 PIN_INT3 */
bogdanm 64:e3affc9e7238 59 PIN_INT4_IRQn = 4, /*!< 4 PIN_INT4 */
bogdanm 64:e3affc9e7238 60 PIN_INT5_IRQn = 5, /*!< 5 PIN_INT5 */
bogdanm 64:e3affc9e7238 61 PIN_INT6_IRQn = 6, /*!< 6 PIN_INT6 */
bogdanm 64:e3affc9e7238 62 PIN_INT7_IRQn = 7, /*!< 7 PIN_INT7 */
bogdanm 64:e3affc9e7238 63 GINT0_IRQn = 8, /*!< 8 GINT0 */
bogdanm 64:e3affc9e7238 64 GINT1_IRQn = 9, /*!< 9 GINT1 */
bogdanm 64:e3affc9e7238 65 Reserved0_IRQn = 10, /*!< 10 Reserved Interrupt */
bogdanm 64:e3affc9e7238 66 Reserved1_IRQn = 11, /*!< 11 Reserved Interrupt */
bogdanm 64:e3affc9e7238 67 RIT_IRQn = 12, /*!< 12 Repetitive Interrupt Timer */
bogdanm 64:e3affc9e7238 68 Reserved2_IRQn = 13, /*!< 13 Reserved Interrupt */
bogdanm 64:e3affc9e7238 69 SSP1_IRQn = 14, /*!< 14 SSP1 */
bogdanm 64:e3affc9e7238 70 I2C_IRQn = 15, /*!< 15 I2C */
bogdanm 64:e3affc9e7238 71 CT16B0_IRQn = 16, /*!< 16 CT16B0 */
bogdanm 64:e3affc9e7238 72 CT16B1_IRQn = 17, /*!< 17 CT16B1 */
bogdanm 64:e3affc9e7238 73 CT32B0_IRQn = 18, /*!< 18 CT32B0 */
bogdanm 64:e3affc9e7238 74 CT32B1_IRQn = 19, /*!< 19 CT32B1 */
bogdanm 64:e3affc9e7238 75 SSP0_IRQn = 20, /*!< 20 SSP0 */
bogdanm 64:e3affc9e7238 76 USART_IRQn = 21, /*!< 21 USART */
bogdanm 64:e3affc9e7238 77 USB_IRQ_IRQn = 22, /*!< 22 USB_IRQ */
bogdanm 64:e3affc9e7238 78 USB_FIQ_IRQn = 23, /*!< 23 USB_FIQ */
bogdanm 64:e3affc9e7238 79 ADC_IRQn = 24, /*!< 24 ADC */
bogdanm 64:e3affc9e7238 80 WDT_IRQn = 25, /*!< 25 WDT */
bogdanm 64:e3affc9e7238 81 BOD_IRQn = 26, /*!< 26 BOD */
bogdanm 64:e3affc9e7238 82 FMC_IRQn = 27, /*!< 27 FMC */
bogdanm 64:e3affc9e7238 83 Reserved3_IRQn = 28, /*!< 28 Reserved Interrupt */
bogdanm 64:e3affc9e7238 84 Reserved4_IRQn = 29, /*!< 29 Reserved Interrupt */
bogdanm 64:e3affc9e7238 85 USBWAKEUP_IRQn = 30, /*!< 30 USBWAKEUP */
bogdanm 64:e3affc9e7238 86 Reserved5_IRQn = 31, /*!< 31 Reserved Interrupt */
bogdanm 64:e3affc9e7238 87 } IRQn_Type;
bogdanm 64:e3affc9e7238 88
bogdanm 64:e3affc9e7238 89
bogdanm 64:e3affc9e7238 90 /** @addtogroup Configuration_of_CMSIS
bogdanm 64:e3affc9e7238 91 * @{
bogdanm 64:e3affc9e7238 92 */
bogdanm 64:e3affc9e7238 93
bogdanm 64:e3affc9e7238 94 /* Processor and Core Peripheral Section */ /* Configuration of the Cortex-M3 Processor and Core Peripherals */
bogdanm 64:e3affc9e7238 95
bogdanm 64:e3affc9e7238 96 #define __CM3_REV 0x0000 /*!< Cortex-M3 Core Revision */
bogdanm 64:e3affc9e7238 97 #define __MPU_PRESENT 0 /*!< MPU present or not */
bogdanm 64:e3affc9e7238 98 #define __NVIC_PRIO_BITS 3 /*!< Number of Bits used for Priority Levels */
bogdanm 64:e3affc9e7238 99 #define __Vendor_SysTickConfig 0 /*!< Set to 1 if different SysTick Config is used */
bogdanm 64:e3affc9e7238 100 /** @} */ /* End of group Configuration_of_CMSIS */
bogdanm 64:e3affc9e7238 101
bogdanm 64:e3affc9e7238 102 #include <core_cm3.h> /*!< Cortex-M3 processor and core peripherals */
bogdanm 64:e3affc9e7238 103 #include "system_LPC13Uxx.h" /*!< LPC13Uxx System */
bogdanm 64:e3affc9e7238 104
bogdanm 64:e3affc9e7238 105 /** @addtogroup Device_Peripheral_Registers
bogdanm 64:e3affc9e7238 106 * @{
bogdanm 64:e3affc9e7238 107 */
bogdanm 64:e3affc9e7238 108
bogdanm 64:e3affc9e7238 109
bogdanm 64:e3affc9e7238 110 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 111 // ----- I2C -----
bogdanm 64:e3affc9e7238 112 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 113
bogdanm 64:e3affc9e7238 114
bogdanm 64:e3affc9e7238 115
bogdanm 64:e3affc9e7238 116 typedef struct { /*!< (@ 0x40000000) I2C Structure */
bogdanm 64:e3affc9e7238 117 __IO uint32_t CONSET; /*!< (@ 0x40000000) I2C Control Set Register. When a one is written to a bit of this register, the corresponding bit in the I2C control register is set. Writing a zero has no effect on the corresponding bit in the I2C control register. */
bogdanm 64:e3affc9e7238 118 __I uint32_t STAT; /*!< (@ 0x40000004) I2C Status Register. During I2C operation, this register provides detailed status codes that allow software to determine the next action needed. */
bogdanm 64:e3affc9e7238 119 __IO uint32_t DAT; /*!< (@ 0x40000008) I2C Data Register. During master or slave transmit mode, data to be transmitted is written to this register. During master or slave receive mode, data that has been received may be read from this register. */
bogdanm 64:e3affc9e7238 120 __IO uint32_t ADR0; /*!< (@ 0x4000000C) I2C Slave Address Register 0. Contains the 7-bit slave address for operation of the I2C interface in slave mode, and is not used in master mode. The least significant bit determines whether a slave responds to the General Call address. */
bogdanm 64:e3affc9e7238 121 __IO uint32_t SCLH; /*!< (@ 0x40000010) SCH Duty Cycle Register High Half Word. Determines the high time of the I2C clock. */
bogdanm 64:e3affc9e7238 122 __IO uint32_t SCLL; /*!< (@ 0x40000014) SCL Duty Cycle Register Low Half Word. Determines the low time of the I2C clock. I2nSCLL and I2nSCLH together determine the clock frequency generated by an I2C master and certain times used in slave mode. */
bogdanm 64:e3affc9e7238 123 __O uint32_t CONCLR; /*!< (@ 0x40000018) I2C Control Clear Register. When a one is written to a bit of this register, the corresponding bit in the I2C control register is cleared. Writing a zero has no effect on the corresponding bit in the I2C control register. */
bogdanm 64:e3affc9e7238 124 __IO uint32_t MMCTRL; /*!< (@ 0x4000001C) Monitor mode control register. */
bogdanm 64:e3affc9e7238 125 union{
bogdanm 64:e3affc9e7238 126 __IO uint32_t ADR[3]; /*!< (@ 0x40000020) I2C Slave Address Register. Contains the 7-bit slave address for operation of the I2C interface in slave mode, and is not used in master mode. The least significant bit determines whether a slave responds to the General Call address. */
bogdanm 64:e3affc9e7238 127 struct{
bogdanm 64:e3affc9e7238 128 __IO uint32_t ADR1;
bogdanm 64:e3affc9e7238 129 __IO uint32_t ADR2;
bogdanm 64:e3affc9e7238 130 __IO uint32_t ADR3;
bogdanm 64:e3affc9e7238 131 };
bogdanm 64:e3affc9e7238 132 };
bogdanm 64:e3affc9e7238 133 __I uint32_t DATA_BUFFER; /*!< (@ 0x4000002C) Data buffer register. The contents of the 8 MSBs of the I2DAT shift register will be transferred to the DATA_BUFFER automatically after every nine bits (8 bits of data plus ACK or NACK) has been received on the bus. */
bogdanm 64:e3affc9e7238 134 union{
bogdanm 64:e3affc9e7238 135 __IO uint32_t MASK[4]; /*!< (@ 0x40000030) I2C Slave address mask register. This mask register is associated with I2ADR0 to determine an address match. The mask register has no effect when comparing to the General Call address (0000000). */
bogdanm 64:e3affc9e7238 136 struct{
bogdanm 64:e3affc9e7238 137 __IO uint32_t MASK0;
bogdanm 64:e3affc9e7238 138 __IO uint32_t MASK1;
bogdanm 64:e3affc9e7238 139 __IO uint32_t MASK2;
bogdanm 64:e3affc9e7238 140 __IO uint32_t MASK3;
bogdanm 64:e3affc9e7238 141 };
bogdanm 64:e3affc9e7238 142 };
bogdanm 64:e3affc9e7238 143 } LPC_I2C_Type;
bogdanm 64:e3affc9e7238 144
bogdanm 64:e3affc9e7238 145
bogdanm 64:e3affc9e7238 146 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 147 // ----- WWDT -----
bogdanm 64:e3affc9e7238 148 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 149
bogdanm 64:e3affc9e7238 150
bogdanm 64:e3affc9e7238 151 typedef struct { /*!< (@ 0x40004000) WWDT Structure */
bogdanm 64:e3affc9e7238 152 __IO uint32_t MOD; /*!< (@ 0x40004000) Watchdog mode register. This register contains the basic mode and status of the Watchdog Timer. */
bogdanm 64:e3affc9e7238 153 __IO uint32_t TC; /*!< (@ 0x40004004) Watchdog timer constant register. This 24-bit register determines the time-out value. */
bogdanm 64:e3affc9e7238 154 __O uint32_t FEED; /*!< (@ 0x40004008) Watchdog feed sequence register. Writing 0xAA followed by 0x55 to this register reloads the Watchdog timer with the value contained in WDTC. */
bogdanm 64:e3affc9e7238 155 __I uint32_t TV; /*!< (@ 0x4000400C) Watchdog timer value register. This 24-bit register reads out the current value of the Watchdog timer. */
bogdanm 64:e3affc9e7238 156 __IO uint32_t CLKSEL; /*!< (@ 0x40004010) Watchdog clock select register. */
bogdanm 64:e3affc9e7238 157 __IO uint32_t WARNINT; /*!< (@ 0x40004014) Watchdog Warning Interrupt compare value. */
bogdanm 64:e3affc9e7238 158 __IO uint32_t WINDOW; /*!< (@ 0x40004018) Watchdog Window compare value. */
bogdanm 64:e3affc9e7238 159 } LPC_WWDT_Type;
bogdanm 64:e3affc9e7238 160
bogdanm 64:e3affc9e7238 161
bogdanm 64:e3affc9e7238 162 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 163 // ----- USART -----
bogdanm 64:e3affc9e7238 164 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 165
bogdanm 64:e3affc9e7238 166
bogdanm 64:e3affc9e7238 167 typedef struct { /*!< (@ 0x40008000) USART Structure */
bogdanm 64:e3affc9e7238 168
bogdanm 64:e3affc9e7238 169 union {
bogdanm 64:e3affc9e7238 170 __IO uint32_t DLL; /*!< (@ 0x40008000) Divisor Latch LSB. Least significant byte of the baud rate divisor value. The full divisor is used to generate a baud rate from the fractional rate divider. (DLAB=1) */
bogdanm 64:e3affc9e7238 171 __O uint32_t THR; /*!< (@ 0x40008000) Transmit Holding Register. The next character to be transmitted is written here. (DLAB=0) */
bogdanm 64:e3affc9e7238 172 __I uint32_t RBR; /*!< (@ 0x40008000) Receiver Buffer Register. Contains the next received character to be read. (DLAB=0) */
bogdanm 64:e3affc9e7238 173 };
bogdanm 64:e3affc9e7238 174
bogdanm 64:e3affc9e7238 175 union {
bogdanm 64:e3affc9e7238 176 __IO uint32_t IER; /*!< (@ 0x40008004) Interrupt Enable Register. Contains individual interrupt enable bits for the 7 potential USART interrupts. (DLAB=0) */
bogdanm 64:e3affc9e7238 177 __IO uint32_t DLM; /*!< (@ 0x40008004) Divisor Latch MSB. Most significant byte of the baud rate divisor value. The full divisor is used to generate a baud rate from the fractional rate divider. (DLAB=1) */
bogdanm 64:e3affc9e7238 178 };
bogdanm 64:e3affc9e7238 179
bogdanm 64:e3affc9e7238 180 union {
bogdanm 64:e3affc9e7238 181 __O uint32_t FCR; /*!< (@ 0x40008008) FIFO Control Register. Controls USART FIFO usage and modes. */
bogdanm 64:e3affc9e7238 182 __I uint32_t IIR; /*!< (@ 0x40008008) Interrupt ID Register. Identifies which interrupt(s) are pending. */
bogdanm 64:e3affc9e7238 183 };
bogdanm 64:e3affc9e7238 184 __IO uint32_t LCR; /*!< (@ 0x4000800C) Line Control Register. Contains controls for frame formatting and break generation. */
bogdanm 64:e3affc9e7238 185 __IO uint32_t MCR; /*!< (@ 0x40008010) Modem Control Register. */
bogdanm 64:e3affc9e7238 186 __I uint32_t LSR; /*!< (@ 0x40008014) Line Status Register. Contains flags for transmit and receive status, including line errors. */
bogdanm 64:e3affc9e7238 187 __I uint32_t MSR; /*!< (@ 0x40008018) Modem Status Register. */
bogdanm 64:e3affc9e7238 188 __IO uint32_t SCR; /*!< (@ 0x4000801C) Scratch Pad Register. Eight-bit temporary storage for software. */
bogdanm 64:e3affc9e7238 189 __IO uint32_t ACR; /*!< (@ 0x40008020) Auto-baud Control Register. Contains controls for the auto-baud feature. */
bogdanm 64:e3affc9e7238 190 __IO uint32_t ICR; /*!< (@ 0x40008024) IrDA Control Register. Enables and configures the IrDA (remote control) mode. */
bogdanm 64:e3affc9e7238 191 __IO uint32_t FDR; /*!< (@ 0x40008028) Fractional Divider Register. Generates a clock input for the baud rate divider. */
bogdanm 64:e3affc9e7238 192 __IO uint32_t OSR; /*!< (@ 0x4000802C) Oversampling Register. Controls the degree of oversampling during each bit time. */
bogdanm 64:e3affc9e7238 193 __IO uint32_t TER; /*!< (@ 0x40008030) Transmit Enable Register. Turns off USART transmitter for use with software flow control. */
bogdanm 64:e3affc9e7238 194 __I uint32_t RESERVED0[3];
bogdanm 64:e3affc9e7238 195 __IO uint32_t HDEN; /*!< (@ 0x40008040) Half duplex enable register. */
bogdanm 64:e3affc9e7238 196 __I uint32_t RESERVED1;
bogdanm 64:e3affc9e7238 197 __IO uint32_t SCICTRL; /*!< (@ 0x40008048) Smart Card Interface Control register. Enables and configures the Smart Card Interface feature. */
bogdanm 64:e3affc9e7238 198 __IO uint32_t RS485CTRL; /*!< (@ 0x4000804C) RS-485/EIA-485 Control. Contains controls to configure various aspects of RS-485/EIA-485 modes. */
bogdanm 64:e3affc9e7238 199 __IO uint32_t RS485ADRMATCH; /*!< (@ 0x40008050) RS-485/EIA-485 address match. Contains the address match value for RS-485/EIA-485 mode. */
bogdanm 64:e3affc9e7238 200 __IO uint32_t RS485DLY; /*!< (@ 0x40008054) RS-485/EIA-485 direction control delay. */
bogdanm 64:e3affc9e7238 201 __IO uint32_t SYNCCTRL; /*!< (@ 0x40008058) Synchronous mode control register. */
bogdanm 64:e3affc9e7238 202 } LPC_USART_Type;
bogdanm 64:e3affc9e7238 203
bogdanm 64:e3affc9e7238 204
bogdanm 64:e3affc9e7238 205 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 206 // ----- CT16B0 -----
bogdanm 64:e3affc9e7238 207 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 208
bogdanm 64:e3affc9e7238 209 typedef struct { /*!< (@ 0x4000C000) LPC_CTxxBx_Type Structure */
bogdanm 64:e3affc9e7238 210 __IO uint32_t IR; /*!< (@ 0x4000C000) Interrupt Register. The IR can be written to clear interrupts. The IR can be read to identify which of eight possible interrupt sources are pending. */
bogdanm 64:e3affc9e7238 211 __IO uint32_t TCR; /*!< (@ 0x4000C004) Timer Control Register. The TCR is used to control the Timer Counter functions. The Timer Counter can be disabled or reset through the TCR. */
bogdanm 64:e3affc9e7238 212 __IO uint32_t TC; /*!< (@ 0x4000C008) Timer Counter. The 16-bit TC is incremented every PR+1 cycles of PCLK. The TC is controlled through the TCR. */
bogdanm 64:e3affc9e7238 213 __IO uint32_t PR; /*!< (@ 0x4000C00C) Prescale Register. When the Prescale Counter (below) is equal to this value, the next clock increments the TC and clears the PC. */
bogdanm 64:e3affc9e7238 214 __IO uint32_t PC; /*!< (@ 0x4000C010) Prescale Counter. The 16-bit PC is a counter which is incremented to the value stored in PR. When the value in PR is reached, the TC is incremented and the PC is cleared. The PC is observable and controllable through the bus interface. */
bogdanm 64:e3affc9e7238 215 __IO uint32_t MCR; /*!< (@ 0x4000C014) Match Control Register. The MCR is used to control if an interrupt is generated and if the TC is reset when a Match occurs. */
bogdanm 64:e3affc9e7238 216 union {
bogdanm 64:e3affc9e7238 217 __IO uint32_t MR[4]; /*!< (@ 0x4000C018) Match Register. MR can be enabled through the MCR to reset the TC, stop both the TC and PC, and/or generate an interrupt every time MR matches the TC. */
bogdanm 64:e3affc9e7238 218 struct{
bogdanm 64:e3affc9e7238 219 __IO uint32_t MR0; /*!< (@ 0x4000C018) Match Register. MR0 */
bogdanm 64:e3affc9e7238 220 __IO uint32_t MR1; /*!< (@ 0x4000C01C) Match Register. MR1 */
bogdanm 64:e3affc9e7238 221 __IO uint32_t MR2; /*!< (@ 0x4000C020) Match Register. MR2 */
bogdanm 64:e3affc9e7238 222 __IO uint32_t MR3; /*!< (@ 0x4000C024) Match Register. MR3 */
bogdanm 64:e3affc9e7238 223 };
bogdanm 64:e3affc9e7238 224 };
bogdanm 64:e3affc9e7238 225 __IO uint32_t CCR; /*!< (@ 0x4000C028) Capture Control Register. The CCR controls which edges of the capture inputs are used to load the Capture Registers and whether or not an interrupt is generated when a capture takes place. */
bogdanm 64:e3affc9e7238 226 union{
bogdanm 64:e3affc9e7238 227 __I uint32_t CR[4]; /*!< (@ 0x4000C02C) Capture Register. CR is loaded with the value of TC when there is an event on the CT16B0_CAP input. */
bogdanm 64:e3affc9e7238 228 struct{
bogdanm 64:e3affc9e7238 229 __I uint32_t CR0; /*!< (@ 0x4000C02C) Capture Register. CR 0 */
bogdanm 64:e3affc9e7238 230 __I uint32_t CR1; /*!< (@ 0x4000C030) Capture Register. CR 1 */
bogdanm 64:e3affc9e7238 231 __I uint32_t CR2; /*!< (@ 0x4000C034) Capture Register. CR 2 */
bogdanm 64:e3affc9e7238 232 __I uint32_t CR3; /*!< (@ 0x4000C038) Capture Register. CR 3 */
bogdanm 64:e3affc9e7238 233 };
bogdanm 64:e3affc9e7238 234 };
bogdanm 64:e3affc9e7238 235 __IO uint32_t EMR; /*!< (@ 0x4000C03C) External Match Register. The EMR controls the match function and the external match pins */
bogdanm 64:e3affc9e7238 236 __I uint32_t RESERVED0[12];
bogdanm 64:e3affc9e7238 237 __IO uint32_t CTCR; /*!< (@ 0x4000C070) Count Control Register. The CTCR selects between Timer and Counter mode, and in Counter mode selects the signal and edge(s) for counting. */
bogdanm 64:e3affc9e7238 238 __IO uint32_t PWMC; /*!< (@ 0x4000C074) PWM Control Register. The PWMCON enables PWM mode for the external match pins CT16B0_MAT[1:0] and CT16B1_MAT[1:0]. */
bogdanm 64:e3affc9e7238 239 } LPC_CTxxBx_Type;
bogdanm 64:e3affc9e7238 240
bogdanm 64:e3affc9e7238 241 typedef struct { /*!< (@ 0x4000C000) CT16B0 Structure */
bogdanm 64:e3affc9e7238 242 __IO uint32_t IR; /*!< (@ 0x4000C000) Interrupt Register. The IR can be written to clear interrupts. The IR can be read to identify which of eight possible interrupt sources are pending. */
bogdanm 64:e3affc9e7238 243 __IO uint32_t TCR; /*!< (@ 0x4000C004) Timer Control Register. The TCR is used to control the Timer Counter functions. The Timer Counter can be disabled or reset through the TCR. */
bogdanm 64:e3affc9e7238 244 __IO uint32_t TC; /*!< (@ 0x4000C008) Timer Counter. The 16-bit TC is incremented every PR+1 cycles of PCLK. The TC is controlled through the TCR. */
bogdanm 64:e3affc9e7238 245 __IO uint32_t PR; /*!< (@ 0x4000C00C) Prescale Register. When the Prescale Counter (below) is equal to this value, the next clock increments the TC and clears the PC. */
bogdanm 64:e3affc9e7238 246 __IO uint32_t PC; /*!< (@ 0x4000C010) Prescale Counter. The 16-bit PC is a counter which is incremented to the value stored in PR. When the value in PR is reached, the TC is incremented and the PC is cleared. The PC is observable and controllable through the bus interface. */
bogdanm 64:e3affc9e7238 247 __IO uint32_t MCR; /*!< (@ 0x4000C014) Match Control Register. The MCR is used to control if an interrupt is generated and if the TC is reset when a Match occurs. */
bogdanm 64:e3affc9e7238 248 union {
bogdanm 64:e3affc9e7238 249 __IO uint32_t MR[4]; /*!< (@ 0x4000C018) Match Register. MR can be enabled through the MCR to reset the TC, stop both the TC and PC, and/or generate an interrupt every time MR matches the TC. */
bogdanm 64:e3affc9e7238 250 struct{
bogdanm 64:e3affc9e7238 251 __IO uint32_t MR0; /*!< (@ 0x4000C018) Match Register. MR0 */
bogdanm 64:e3affc9e7238 252 __IO uint32_t MR1; /*!< (@ 0x4000C01C) Match Register. MR1 */
bogdanm 64:e3affc9e7238 253 __IO uint32_t MR2; /*!< (@ 0x4000C020) Match Register. MR2 */
bogdanm 64:e3affc9e7238 254 __IO uint32_t MR3; /*!< (@ 0x4000C024) Match Register. MR3 */
bogdanm 64:e3affc9e7238 255 };
bogdanm 64:e3affc9e7238 256 };
bogdanm 64:e3affc9e7238 257 __IO uint32_t CCR; /*!< (@ 0x4000C028) Capture Control Register. The CCR controls which edges of the capture inputs are used to load the Capture Registers and whether or not an interrupt is generated when a capture takes place. */
bogdanm 64:e3affc9e7238 258 union{
bogdanm 64:e3affc9e7238 259 __I uint32_t CR[4]; /*!< (@ 0x4000C02C) Capture Register. CR is loaded with the value of TC when there is an event on the CT16B0_CAP input. */
bogdanm 64:e3affc9e7238 260 struct{
bogdanm 64:e3affc9e7238 261 __I uint32_t CR0; /*!< (@ 0x4000C02C) Capture Register. CR 0 */
bogdanm 64:e3affc9e7238 262 __I uint32_t CR1; /*!< (@ 0x4000C030) Capture Register. CR 1 */
bogdanm 64:e3affc9e7238 263 __I uint32_t CR2; /*!< (@ 0x4000C034) Capture Register. CR 2 */
bogdanm 64:e3affc9e7238 264 __I uint32_t CR3; /*!< (@ 0x4000C038) Capture Register. CR 3 */
bogdanm 64:e3affc9e7238 265 };
bogdanm 64:e3affc9e7238 266 };
bogdanm 64:e3affc9e7238 267 __IO uint32_t EMR; /*!< (@ 0x4000C03C) External Match Register. The EMR controls the match function and the external match pins */
bogdanm 64:e3affc9e7238 268 __I uint32_t RESERVED0[12];
bogdanm 64:e3affc9e7238 269 __IO uint32_t CTCR; /*!< (@ 0x4000C070) Count Control Register. The CTCR selects between Timer and Counter mode, and in Counter mode selects the signal and edge(s) for counting. */
bogdanm 64:e3affc9e7238 270 __IO uint32_t PWMC; /*!< (@ 0x4000C074) PWM Control Register. The PWMCON enables PWM mode for the external match pins CT16B0_MAT[1:0] and CT16B1_MAT[1:0]. */
bogdanm 64:e3affc9e7238 271 } LPC_CT16B0_Type;
bogdanm 64:e3affc9e7238 272
bogdanm 64:e3affc9e7238 273
bogdanm 64:e3affc9e7238 274 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 275 // ----- CT16B1 -----
bogdanm 64:e3affc9e7238 276 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 277
bogdanm 64:e3affc9e7238 278 typedef struct { /*!< (@ 0x40010000) CT16B1 Structure */
bogdanm 64:e3affc9e7238 279 __IO uint32_t IR; /*!< (@ 0x40010000) Interrupt Register. The IR can be written to clear interrupts. The IR can be read to identify which of eight possible interrupt sources are pending. */
bogdanm 64:e3affc9e7238 280 __IO uint32_t TCR; /*!< (@ 0x40010004) Timer Control Register. The TCR is used to control the Timer Counter functions. The Timer Counter can be disabled or reset through the TCR. */
bogdanm 64:e3affc9e7238 281 __IO uint32_t TC; /*!< (@ 0x40010008) Timer Counter. The 16-bit TC is incremented every PR+1 cycles of PCLK. The TC is controlled through the TCR. */
bogdanm 64:e3affc9e7238 282 __IO uint32_t PR; /*!< (@ 0x4001000C) Prescale Register. When the Prescale Counter (below) is equal to this value, the next clock increments the TC and clears the PC. */
bogdanm 64:e3affc9e7238 283 __IO uint32_t PC; /*!< (@ 0x40010010) Prescale Counter. The 16-bit PC is a counter which is incremented to the value stored in PR. When the value in PR is reached, the TC is incremented and the PC is cleared. The PC is observable and controllable through the bus interface. */
bogdanm 64:e3affc9e7238 284 __IO uint32_t MCR; /*!< (@ 0x40010014) Match Control Register. The MCR is used to control if an interrupt is generated and if the TC is reset when a Match occurs. */
bogdanm 64:e3affc9e7238 285 union {
bogdanm 64:e3affc9e7238 286 __IO uint32_t MR[4]; /*!< (@ 0x40010018) Match Register. MR can be enabled through the MCR to reset the TC, stop both the TC and PC, and/or generate an interrupt every time MR matches the TC. */
bogdanm 64:e3affc9e7238 287 struct{
bogdanm 64:e3affc9e7238 288 __IO uint32_t MR0; /*!< (@ 0x40010018) Match Register. MR0 */
bogdanm 64:e3affc9e7238 289 __IO uint32_t MR1; /*!< (@ 0x4001001C) Match Register. MR1 */
bogdanm 64:e3affc9e7238 290 __IO uint32_t MR2; /*!< (@ 0x40010020) Match Register. MR2 */
bogdanm 64:e3affc9e7238 291 __IO uint32_t MR3; /*!< (@ 0x40010024) Match Register. MR3 */
bogdanm 64:e3affc9e7238 292 };
bogdanm 64:e3affc9e7238 293 };
bogdanm 64:e3affc9e7238 294 __IO uint32_t CCR; /*!< (@ 0x40010028) Capture Control Register. The CCR controls which edges of the capture inputs are used to load the Capture Registers and whether or not an interrupt is generated when a capture takes place. */
bogdanm 64:e3affc9e7238 295 union{
bogdanm 64:e3affc9e7238 296 __I uint32_t CR[4]; /*!< (@ 0x4001002C) Capture Register. CR is loaded with the value of TC when there is an event on the CT16B0_CAP input. */
bogdanm 64:e3affc9e7238 297 struct{
bogdanm 64:e3affc9e7238 298 __I uint32_t CR0; /*!< (@ 0x4001002C) Capture Register. CR 0 */
bogdanm 64:e3affc9e7238 299 __I uint32_t CR1; /*!< (@ 0x40010030) Capture Register. CR 1 */
bogdanm 64:e3affc9e7238 300 __I uint32_t CR2; /*!< (@ 0x40010034) Capture Register. CR 2 */
bogdanm 64:e3affc9e7238 301 __I uint32_t CR3; /*!< (@ 0x40010038) Capture Register. CR 3 */
bogdanm 64:e3affc9e7238 302 };
bogdanm 64:e3affc9e7238 303 };
bogdanm 64:e3affc9e7238 304 __IO uint32_t EMR; /*!< (@ 0x4001003C) External Match Register. The EMR controls the match function and the external match pins */
bogdanm 64:e3affc9e7238 305 __I uint32_t RESERVED0[12];
bogdanm 64:e3affc9e7238 306 __IO uint32_t CTCR; /*!< (@ 0x40010070) Count Control Register. The CTCR selects between Timer and Counter mode, and in Counter mode selects the signal and edge(s) for counting. */
bogdanm 64:e3affc9e7238 307 __IO uint32_t PWMC; /*!< (@ 0x40010074) PWM Control Register. The PWMCON enables PWM mode for the external match pins CT16B0_MAT[1:0] and CT16B1_MAT[1:0]. */
bogdanm 64:e3affc9e7238 308 } LPC_CT16B1_Type;
bogdanm 64:e3affc9e7238 309
bogdanm 64:e3affc9e7238 310
bogdanm 64:e3affc9e7238 311 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 312 // ----- CT32B0 -----
bogdanm 64:e3affc9e7238 313 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 314 typedef struct { /*!< (@ 0x40014000) CT32B0 Structure */
bogdanm 64:e3affc9e7238 315 __IO uint32_t IR; /*!< (@ 0x40014000) Interrupt Register. The IR can be written to clear interrupts. The IR can be read to identify which of eight possible interrupt sources are pending. */
bogdanm 64:e3affc9e7238 316 __IO uint32_t TCR; /*!< (@ 0x40014004) Timer Control Register. The TCR is used to control the Timer Counter functions. The Timer Counter can be disabled or reset through the TCR. */
bogdanm 64:e3affc9e7238 317 __IO uint32_t TC; /*!< (@ 0x40014008) Timer Counter. The 32-bit TC is incremented every PR+1 cycles of PCLK. The TC is controlled through the TCR. */
bogdanm 64:e3affc9e7238 318 __IO uint32_t PR; /*!< (@ 0x4001400C) Prescale Register. When the Prescale Counter (below) is equal to this value, the next clock increments the TC and clears the PC. */
bogdanm 64:e3affc9e7238 319 __IO uint32_t PC; /*!< (@ 0x40014010) Prescale Counter. The 32-bit PC is a counter which is incremented to the value stored in PR. When the value in PR is reached, the TC is incremented and the PC is cleared. The PC is observable and controllable through the bus interface. */
bogdanm 64:e3affc9e7238 320 __IO uint32_t MCR; /*!< (@ 0x40014014) Match Control Register. The MCR is used to control if an interrupt is generated and if the TC is reset when a Match occurs. */
bogdanm 64:e3affc9e7238 321 union {
bogdanm 64:e3affc9e7238 322 __IO uint32_t MR[4]; /*!< (@ 0x40014018) Match Register. MR can be enabled through the MCR to reset the TC, stop both the TC and PC, and/or generate an interrupt every time MR matches the TC. */
bogdanm 64:e3affc9e7238 323 struct{
bogdanm 64:e3affc9e7238 324 __IO uint32_t MR0; /*!< (@ 0x40014018) Match Register. MR0 */
bogdanm 64:e3affc9e7238 325 __IO uint32_t MR1; /*!< (@ 0x4001401C) Match Register. MR1 */
bogdanm 64:e3affc9e7238 326 __IO uint32_t MR2; /*!< (@ 0x40014020) Match Register. MR2 */
bogdanm 64:e3affc9e7238 327 __IO uint32_t MR3; /*!< (@ 0x40014024) Match Register. MR3 */
bogdanm 64:e3affc9e7238 328 };
bogdanm 64:e3affc9e7238 329 };
bogdanm 64:e3affc9e7238 330 __IO uint32_t CCR; /*!< (@ 0x40014028) Capture Control Register. The CCR controls which edges of the capture inputs are used to load the Capture Registers and whether or not an interrupt is generated when a capture takes place. */
bogdanm 64:e3affc9e7238 331 union{
bogdanm 64:e3affc9e7238 332 __I uint32_t CR[4]; /*!< (@ 0x4001402C) Capture Register. CR is loaded with the value of TC when there is an event on the CT32B_CAP0 input. */
bogdanm 64:e3affc9e7238 333 struct{
bogdanm 64:e3affc9e7238 334 __I uint32_t CR0; /*!< (@ 0x4001402C) Capture Register. CR 0 */
bogdanm 64:e3affc9e7238 335 __I uint32_t CR1; /*!< (@ 0x40014030) Capture Register. CR 1 */
bogdanm 64:e3affc9e7238 336 __I uint32_t CR2; /*!< (@ 0x40014034) Capture Register. CR 2 */
bogdanm 64:e3affc9e7238 337 __I uint32_t CR3; /*!< (@ 0x40014038) Capture Register. CR 3 */
bogdanm 64:e3affc9e7238 338 };
bogdanm 64:e3affc9e7238 339 };
bogdanm 64:e3affc9e7238 340 __IO uint32_t EMR; /*!< (@ 0x4001403C) External Match Register. The EMR controls the match function and the external match pins CT32Bn_MAT[3:0]. */
bogdanm 64:e3affc9e7238 341 __I uint32_t RESERVED0[12];
bogdanm 64:e3affc9e7238 342 __IO uint32_t CTCR; /*!< (@ 0x40014070) Count Control Register. The CTCR selects between Timer and Counter mode, and in Counter mode selects the signal and edge(s) for counting. */
bogdanm 64:e3affc9e7238 343 __IO uint32_t PWMC; /*!< (@ 0x40014074) PWM Control Register. The PWMCON enables PWM mode for the external match pins CT32Bn_MAT[3:0]. */
bogdanm 64:e3affc9e7238 344 } LPC_CT32B0_Type;
bogdanm 64:e3affc9e7238 345
bogdanm 64:e3affc9e7238 346
bogdanm 64:e3affc9e7238 347 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 348 // ----- CT32B1 -----
bogdanm 64:e3affc9e7238 349 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 350 typedef struct { /*!< (@ 0x40018000) CT32B1 Structure */
bogdanm 64:e3affc9e7238 351 __IO uint32_t IR; /*!< (@ 0x40018000) Interrupt Register. The IR can be written to clear interrupts. The IR can be read to identify which of eight possible interrupt sources are pending. */
bogdanm 64:e3affc9e7238 352 __IO uint32_t TCR; /*!< (@ 0x40018004) Timer Control Register. The TCR is used to control the Timer Counter functions. The Timer Counter can be disabled or reset through the TCR. */
bogdanm 64:e3affc9e7238 353 __IO uint32_t TC; /*!< (@ 0x40018008) Timer Counter. The 32-bit TC is incremented every PR+1 cycles of PCLK. The TC is controlled through the TCR. */
bogdanm 64:e3affc9e7238 354 __IO uint32_t PR; /*!< (@ 0x4001800C) Prescale Register. When the Prescale Counter (below) is equal to this value, the next clock increments the TC and clears the PC. */
bogdanm 64:e3affc9e7238 355 __IO uint32_t PC; /*!< (@ 0x40018010) Prescale Counter. The 32-bit PC is a counter which is incremented to the value stored in PR. When the value in PR is reached, the TC is incremented and the PC is cleared. The PC is observable and controllable through the bus interface. */
bogdanm 64:e3affc9e7238 356 __IO uint32_t MCR; /*!< (@ 0x40018014) Match Control Register. The MCR is used to control if an interrupt is generated and if the TC is reset when a Match occurs. */
bogdanm 64:e3affc9e7238 357 union {
bogdanm 64:e3affc9e7238 358 __IO uint32_t MR[4]; /*!< (@ 0x40018018) Match Register. MR can be enabled through the MCR to reset the TC, stop both the TC and PC, and/or generate an interrupt every time MR matches the TC. */
bogdanm 64:e3affc9e7238 359 struct{
bogdanm 64:e3affc9e7238 360 __IO uint32_t MR0; /*!< (@ 0x40018018) Match Register. MR0 */
bogdanm 64:e3affc9e7238 361 __IO uint32_t MR1; /*!< (@ 0x4001801C) Match Register. MR1 */
bogdanm 64:e3affc9e7238 362 __IO uint32_t MR2; /*!< (@ 0x40018020) Match Register. MR2 */
bogdanm 64:e3affc9e7238 363 __IO uint32_t MR3; /*!< (@ 0x40018024) Match Register. MR3 */
bogdanm 64:e3affc9e7238 364 };
bogdanm 64:e3affc9e7238 365 };
bogdanm 64:e3affc9e7238 366 __IO uint32_t CCR; /*!< (@ 0x40018028) Capture Control Register. The CCR controls which edges of the capture inputs are used to load the Capture Registers and whether or not an interrupt is generated when a capture takes place. */
bogdanm 64:e3affc9e7238 367 union{
bogdanm 64:e3affc9e7238 368 __I uint32_t CR[4]; /*!< (@ 0x4001802C) Capture Register. CR is loaded with the value of TC when there is an event on the CT32B_CAP0 input. */
bogdanm 64:e3affc9e7238 369 struct{
bogdanm 64:e3affc9e7238 370 __I uint32_t CR0; /*!< (@ 0x4001802C) Capture Register. CR 0 */
bogdanm 64:e3affc9e7238 371 __I uint32_t CR1; /*!< (@ 0x40018030) Capture Register. CR 1 */
bogdanm 64:e3affc9e7238 372 __I uint32_t CR2; /*!< (@ 0x40018034) Capture Register. CR 2 */
bogdanm 64:e3affc9e7238 373 __I uint32_t CR3; /*!< (@ 0x40018038) Capture Register. CR 3 */
bogdanm 64:e3affc9e7238 374 };
bogdanm 64:e3affc9e7238 375 };
bogdanm 64:e3affc9e7238 376 __IO uint32_t EMR; /*!< (@ 0x4001803C) External Match Register. The EMR controls the match function and the external match pins CT32Bn_MAT[3:0]. */
bogdanm 64:e3affc9e7238 377 __I uint32_t RESERVED0[12];
bogdanm 64:e3affc9e7238 378 __IO uint32_t CTCR; /*!< (@ 0x40018070) Count Control Register. The CTCR selects between Timer and Counter mode, and in Counter mode selects the signal and edge(s) for counting. */
bogdanm 64:e3affc9e7238 379 __IO uint32_t PWMC; /*!< (@ 0x40018074) PWM Control Register. The PWMCON enables PWM mode for the external match pins CT32Bn_MAT[3:0]. */
bogdanm 64:e3affc9e7238 380 } LPC_CT32B1_Type;
bogdanm 64:e3affc9e7238 381
bogdanm 64:e3affc9e7238 382
bogdanm 64:e3affc9e7238 383 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 384 // ----- ADC -----
bogdanm 64:e3affc9e7238 385 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 386 typedef struct { /*!< (@ 0x4001C000) ADC Structure */
bogdanm 64:e3affc9e7238 387 __IO uint32_t CR; /*!< (@ 0x4001C000) A/D Control Register. The CR register must be written to select the operating mode before A/D conversion can occur. */
bogdanm 64:e3affc9e7238 388 __IO uint32_t GDR; /*!< (@ 0x4001C004) A/D Global Data Register. Contains the result of the most recent A/D conversion. */
bogdanm 64:e3affc9e7238 389 __I uint32_t RESERVED0[1];
bogdanm 64:e3affc9e7238 390 __IO uint32_t INTEN; /*!< (@ 0x4001C00C) A/D Interrupt Enable Register. This register contains enable bits that allow the DONE flag of each A/D channel to be included or excluded from contributing to the generation of an A/D interrupt. */
bogdanm 64:e3affc9e7238 391 union{
bogdanm 64:e3affc9e7238 392 __I uint32_t DR[8]; /*!< (@ 0x4001C010) A/D Channel Data Register*/
bogdanm 64:e3affc9e7238 393 struct{
bogdanm 64:e3affc9e7238 394 __I uint32_t DR0; /*!< (@ 0x4001C010) A/D Channel Data Register 0*/
bogdanm 64:e3affc9e7238 395 __I uint32_t DR1; /*!< (@ 0x4001C014) A/D Channel Data Register 1*/
bogdanm 64:e3affc9e7238 396 __I uint32_t DR2; /*!< (@ 0x4001C018) A/D Channel Data Register 2*/
bogdanm 64:e3affc9e7238 397 __I uint32_t DR3; /*!< (@ 0x4001C01C) A/D Channel Data Register 3*/
bogdanm 64:e3affc9e7238 398 __I uint32_t DR4; /*!< (@ 0x4001C020) A/D Channel Data Register 4*/
bogdanm 64:e3affc9e7238 399 __I uint32_t DR5; /*!< (@ 0x4001C024) A/D Channel Data Register 5*/
bogdanm 64:e3affc9e7238 400 __I uint32_t DR6; /*!< (@ 0x4001C028) A/D Channel Data Register 6*/
bogdanm 64:e3affc9e7238 401 __I uint32_t DR7; /*!< (@ 0x4001C02C) A/D Channel Data Register 7*/
bogdanm 64:e3affc9e7238 402 };
bogdanm 64:e3affc9e7238 403 };
bogdanm 64:e3affc9e7238 404 __I uint32_t STAT; /*!< (@ 0x4001C030) A/D Status Register. This register contains DONE and OVERRUN flags for all of the A/D channels, as well as the A/D interrupt flag. */
bogdanm 64:e3affc9e7238 405 } LPC_ADC_Type;
bogdanm 64:e3affc9e7238 406
bogdanm 64:e3affc9e7238 407
bogdanm 64:e3affc9e7238 408 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 409 // ----- PMU -----
bogdanm 64:e3affc9e7238 410 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 411
bogdanm 64:e3affc9e7238 412 typedef struct { /*!< (@ 0x40038000) PMU Structure */
bogdanm 64:e3affc9e7238 413 __IO uint32_t PCON; /*!< (@ 0x40038000) Power control register */
bogdanm 64:e3affc9e7238 414 union{
bogdanm 64:e3affc9e7238 415 __IO uint32_t GPREG[4]; /*!< (@ 0x40038004) General purpose register 0 */
bogdanm 64:e3affc9e7238 416 struct{
bogdanm 64:e3affc9e7238 417 __IO uint32_t GPREG0; /*!< (@ 0x40038004) General purpose register 0 */
bogdanm 64:e3affc9e7238 418 __IO uint32_t GPREG1; /*!< (@ 0x40038008) General purpose register 1 */
bogdanm 64:e3affc9e7238 419 __IO uint32_t GPREG2; /*!< (@ 0x4003800C) General purpose register 2 */
bogdanm 64:e3affc9e7238 420 __IO uint32_t GPREG3; /*!< (@ 0x40038010) General purpose register 3 */
bogdanm 64:e3affc9e7238 421 };
bogdanm 64:e3affc9e7238 422 };
bogdanm 64:e3affc9e7238 423 __IO uint32_t GPREG4; /*!< (@ 0x40038014) General purpose register 4 */
bogdanm 64:e3affc9e7238 424 } LPC_PMU_Type;
bogdanm 64:e3affc9e7238 425
bogdanm 64:e3affc9e7238 426
bogdanm 64:e3affc9e7238 427 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 428 // ----- FLASHCTRL -----
bogdanm 64:e3affc9e7238 429 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 430
bogdanm 64:e3affc9e7238 431 typedef struct { /*!< (@ 0x4003C000) FLASHCTRL Structure */
bogdanm 64:e3affc9e7238 432 __I uint32_t RESERVED0[4];
bogdanm 64:e3affc9e7238 433 __IO uint32_t FLASHCFG; /*!< (@ 0x4003C010) Flash memory access time configuration register */
bogdanm 64:e3affc9e7238 434 __I uint32_t RESERVED1[3];
bogdanm 64:e3affc9e7238 435 __IO uint32_t FMSSTART; /*!< (@ 0x4003C020) Signature start address register */
bogdanm 64:e3affc9e7238 436 __IO uint32_t FMSSTOP; /*!< (@ 0x4003C024) Signature stop-address register */
bogdanm 64:e3affc9e7238 437 __I uint32_t RESERVED2[1];
bogdanm 64:e3affc9e7238 438 __I uint32_t FMSW0; /*!< (@ 0x4003C02C) Word 0 [31:0] */
bogdanm 64:e3affc9e7238 439 __I uint32_t FMSW1; /*!< (@ 0x4003C030) Word 1 [63:32] */
bogdanm 64:e3affc9e7238 440 __I uint32_t FMSW2; /*!< (@ 0x4003C034) Word 2 [95:64] */
bogdanm 64:e3affc9e7238 441 __I uint32_t FMSW3; /*!< (@ 0x4003C038) Word 3 [127:96] */
bogdanm 64:e3affc9e7238 442 __I uint32_t RESERVED3[1001];
bogdanm 64:e3affc9e7238 443 __I uint32_t FMSTAT; /*!< (@ 0x4003CFE0) Signature generation status register */
bogdanm 64:e3affc9e7238 444 __I uint32_t RESERVED4[1];
bogdanm 64:e3affc9e7238 445 __O uint32_t FMSTATCLR; /*!< (@ 0x4003CFE8) Signature generation status clear register */
bogdanm 64:e3affc9e7238 446 } LPC_FLASHCTRL_Type;
bogdanm 64:e3affc9e7238 447
bogdanm 64:e3affc9e7238 448
bogdanm 64:e3affc9e7238 449 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 450 // ----- SSP -----
bogdanm 64:e3affc9e7238 451 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 452 typedef struct { /*!< (@ 0x40040000) SSP0 Structure */
bogdanm 64:e3affc9e7238 453 __IO uint32_t CR0; /*!< (@ 0x40040000) Control Register 0. Selects the serial clock rate, bus type, and data size. */
bogdanm 64:e3affc9e7238 454 __IO uint32_t CR1; /*!< (@ 0x40040004) Control Register 1. Selects master/slave and other modes. */
bogdanm 64:e3affc9e7238 455 __IO uint32_t DR; /*!< (@ 0x40040008) Data Register. Writes fill the transmit FIFO, and reads empty the receive FIFO. */
bogdanm 64:e3affc9e7238 456 __I uint32_t SR; /*!< (@ 0x4004000C) Status Register */
bogdanm 64:e3affc9e7238 457 __IO uint32_t CPSR; /*!< (@ 0x40040010) Clock Prescale Register */
bogdanm 64:e3affc9e7238 458 __IO uint32_t IMSC; /*!< (@ 0x40040014) Interrupt Mask Set and Clear Register */
bogdanm 64:e3affc9e7238 459 __I uint32_t RIS; /*!< (@ 0x40040018) Raw Interrupt Status Register */
bogdanm 64:e3affc9e7238 460 __I uint32_t MIS; /*!< (@ 0x4004001C) Masked Interrupt Status Register */
bogdanm 64:e3affc9e7238 461 __O uint32_t ICR; /*!< (@ 0x40040020) SSPICR Interrupt Clear Register */
bogdanm 64:e3affc9e7238 462 } LPC_SSPx_Type;
bogdanm 64:e3affc9e7238 463
bogdanm 64:e3affc9e7238 464
bogdanm 64:e3affc9e7238 465 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 466 // ----- IOCON -----
bogdanm 64:e3affc9e7238 467 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 468 typedef struct { /*!< (@ 0x40044000) IOCON Structure */
bogdanm 64:e3affc9e7238 469 __IO uint32_t RESET_PIO0_0; /*!< (@ 0x40044000) I/O configuration for pin RESET/PIO0_0 */
bogdanm 64:e3affc9e7238 470 __IO uint32_t PIO0_1; /*!< (@ 0x40044004) I/O configuration for pin PIO0_1/CLKOUT/CT32B0_MAT2/USB_FTOGGLE */
bogdanm 64:e3affc9e7238 471 __IO uint32_t PIO0_2; /*!< (@ 0x40044008) I/O configuration for pin PIO0_2/SSEL0/CT16B0_CAP0 */
bogdanm 64:e3affc9e7238 472 __IO uint32_t PIO0_3; /*!< (@ 0x4004400C) I/O configuration for pin PIO0_3/USB_VBUS */
bogdanm 64:e3affc9e7238 473 __IO uint32_t PIO0_4; /*!< (@ 0x40044010) I/O configuration for pin PIO0_4/SCL */
bogdanm 64:e3affc9e7238 474 __IO uint32_t PIO0_5; /*!< (@ 0x40044014) I/O configuration for pin PIO0_5/SDA */
bogdanm 64:e3affc9e7238 475 __IO uint32_t PIO0_6; /*!< (@ 0x40044018) I/O configuration for pin PIO0_6/USB_CONNECT/SCK0 */
bogdanm 64:e3affc9e7238 476 __IO uint32_t PIO0_7; /*!< (@ 0x4004401C) I/O configuration for pin PIO0_7/CTS */
bogdanm 64:e3affc9e7238 477 __IO uint32_t PIO0_8; /*!< (@ 0x40044020) I/O configuration for pin PIO0_8/MISO0/CT16B0_MAT0/SWO */
bogdanm 64:e3affc9e7238 478 __IO uint32_t PIO0_9; /*!< (@ 0x40044024) I/O configuration for pin PIO0_9/MOSI0/CT16B0_MAT1/TRACECLK */
bogdanm 64:e3affc9e7238 479 __IO uint32_t SWCLK_PIO0_10; /*!< (@ 0x40044028) I/O configuration for pin SWCLK/PIO0_10/ SCK0/CT16B0_MAT2 */
bogdanm 64:e3affc9e7238 480 __IO uint32_t TDI_PIO0_11; /*!< (@ 0x4004402C) I/O configuration for pin TDI/PIO0_11/AD0/CT32B0_MAT3 */
bogdanm 64:e3affc9e7238 481 __IO uint32_t TMS_PIO0_12; /*!< (@ 0x40044030) I/O configuration for pin TMS/PIO0_12/AD1/CT32B1_CAP0 */
bogdanm 64:e3affc9e7238 482 __IO uint32_t TDO_PIO0_13; /*!< (@ 0x40044034) I/O configuration for pin TDO/PIO0_13/AD2/CT32B1_MAT0 */
bogdanm 64:e3affc9e7238 483 __IO uint32_t TRST_PIO0_14; /*!< (@ 0x40044038) I/O configuration for pin TRST/PIO0_14/AD3/CT32B1_MAT1 */
bogdanm 64:e3affc9e7238 484 __IO uint32_t SWDIO_PIO0_15; /*!< (@ 0x4004403C) I/O configuration for pin SWDIO/PIO0_15/AD4/CT32B1_MAT2 */
bogdanm 64:e3affc9e7238 485 __IO uint32_t PIO0_16; /*!< (@ 0x40044040) I/O configuration for pin PIO0_16/AD5/CT32B1_MAT3/ WAKEUP */
bogdanm 64:e3affc9e7238 486 __IO uint32_t PIO0_17; /*!< (@ 0x40044044) I/O configuration for pin PIO0_17/RTS/CT32B0_CAP0/SCLK */
bogdanm 64:e3affc9e7238 487 __IO uint32_t PIO0_18; /*!< (@ 0x40044048) I/O configuration for pin PIO0_18/RXD/CT32B0_MAT0 */
bogdanm 64:e3affc9e7238 488 __IO uint32_t PIO0_19; /*!< (@ 0x4004404C) I/O configuration for pin PIO0_19/TXD/CT32B0_MAT1 */
bogdanm 64:e3affc9e7238 489 __IO uint32_t PIO0_20; /*!< (@ 0x40044050) I/O configuration for pin PIO0_20/CT16B1_CAP0 */
bogdanm 64:e3affc9e7238 490 __IO uint32_t PIO0_21; /*!< (@ 0x40044054) I/O configuration for pin PIO0_21/CT16B1_MAT0/MOSI1 */
bogdanm 64:e3affc9e7238 491 __IO uint32_t PIO0_22; /*!< (@ 0x40044058) I/O configuration for pin PIO0_22/AD6/CT16B1_MAT1/MISO1 */
bogdanm 64:e3affc9e7238 492 __IO uint32_t PIO0_23; /*!< (@ 0x4004405C) I/O configuration for pin PIO0_23/AD7 */
bogdanm 64:e3affc9e7238 493 __IO uint32_t PIO1_0; /*!< (@ 0x40044060) I/O configuration for pin PIO1_0/CT32B1_MAT0 */
bogdanm 64:e3affc9e7238 494 __IO uint32_t PIO1_1; /*!< (@ 0x40044064) I/O configuration for pin PIO1_1/CT32B1_MAT1 */
bogdanm 64:e3affc9e7238 495 __IO uint32_t PIO1_2; /*!< (@ 0x40044068) I/O configuration for pin PIO1_2/CT32B1_MAT2 */
bogdanm 64:e3affc9e7238 496 __IO uint32_t PIO1_3; /*!< (@ 0x4004406C) I/O configuration for pin PIO1_3/CT32B1_MAT3 */
bogdanm 64:e3affc9e7238 497 __IO uint32_t PIO1_4; /*!< (@ 0x40044070) I/O configuration for pin PIO1_4/CT32B1_CAP0 */
bogdanm 64:e3affc9e7238 498 __IO uint32_t PIO1_5; /*!< (@ 0x40044074) I/O configuration for pin PIO1_5/CT32B1_CAP1 */
bogdanm 64:e3affc9e7238 499 __IO uint32_t PIO1_6; /*!< (@ 0x40044078) I/O configuration for pin PIO1_6 */
bogdanm 64:e3affc9e7238 500 __IO uint32_t PIO1_7; /*!< (@ 0x4004407C) I/O configuration for pin PIO1_7 */
bogdanm 64:e3affc9e7238 501 __IO uint32_t PIO1_8; /*!< (@ 0x40044080) I/O configuration for pin PIO1_8 */
bogdanm 64:e3affc9e7238 502 __IO uint32_t PIO1_9; /*!< (@ 0x40044084) I/O configuration for pin PIO1_9 */
bogdanm 64:e3affc9e7238 503 __IO uint32_t PIO1_10; /*!< (@ 0x40044088) I/O configuration for pin PIO1_10 */
bogdanm 64:e3affc9e7238 504 __IO uint32_t PIO1_11; /*!< (@ 0x4004408C) I/O configuration for pin PIO1_11 */
bogdanm 64:e3affc9e7238 505 __IO uint32_t PIO1_12; /*!< (@ 0x40044090) I/O configuration for pin PIO1_12 */
bogdanm 64:e3affc9e7238 506 __IO uint32_t PIO1_13; /*!< (@ 0x40044094) I/O configuration for PIO1_13/DTR/CT16B0_MAT0/TXD */
bogdanm 64:e3affc9e7238 507 __IO uint32_t PIO1_14; /*!< (@ 0x40044098) I/O configuration for PIO1_14/DSR/CT16B0_MAT1/RXD */
bogdanm 64:e3affc9e7238 508 __IO uint32_t PIO1_15; /*!< (@ 0x4004409C) I/O configuration for pin PIO1_15/DCD/ CT16B0_MAT2/SCK1 */
bogdanm 64:e3affc9e7238 509 __IO uint32_t PIO1_16; /*!< (@ 0x400440A0) I/O configuration for pin PIO1_16/RI/CT16B0_CAP0 */
bogdanm 64:e3affc9e7238 510 __IO uint32_t PIO1_17; /*!< (@ 0x400440A4) I/O configuration for PIO1_17/CT16B0_CAP1/RXD */
bogdanm 64:e3affc9e7238 511 __IO uint32_t PIO1_18; /*!< (@ 0x400440A8) I/O configuration for PIO1_18/CT16B1_CAP1/TXD */
bogdanm 64:e3affc9e7238 512 __IO uint32_t PIO1_19; /*!< (@ 0x400440AC) I/O configuration for pin PIO1_19/DTR/SSEL1 */
bogdanm 64:e3affc9e7238 513 __IO uint32_t PIO1_20; /*!< (@ 0x400440B0) I/O configuration for pin PIO1_20/DSR/SCK1 */
bogdanm 64:e3affc9e7238 514 __IO uint32_t PIO1_21; /*!< (@ 0x400440B4) I/O configuration for pin PIO1_21/DCD/MISO1 */
bogdanm 64:e3affc9e7238 515 __IO uint32_t PIO1_22; /*!< (@ 0x400440B8) I/O configuration for pin PIO1_22/RI/MOSI1 */
bogdanm 64:e3affc9e7238 516 __IO uint32_t PIO1_23; /*!< (@ 0x400440BC) I/O configuration for pin PIO1_23/CT16B1_MAT1/SSEL1 */
bogdanm 64:e3affc9e7238 517 __IO uint32_t PIO1_24; /*!< (@ 0x400440C0) I/O configuration for pin PIO1_24/ CT32B0_MAT0 */
bogdanm 64:e3affc9e7238 518 __IO uint32_t PIO1_25; /*!< (@ 0x400440C4) I/O configuration for pin PIO1_25/CT32B0_MAT1 */
bogdanm 64:e3affc9e7238 519 __IO uint32_t PIO1_26; /*!< (@ 0x400440C8) I/O configuration for pin PIO1_26/CT32B0_MAT2/ RXD */
bogdanm 64:e3affc9e7238 520 __IO uint32_t PIO1_27; /*!< (@ 0x400440CC) I/O configuration for pin PIO1_27/CT32B0_MAT3/ TXD */
bogdanm 64:e3affc9e7238 521 __IO uint32_t PIO1_28; /*!< (@ 0x400440D0) I/O configuration for pin PIO1_28/CT32B0_CAP0/ SCLK */
bogdanm 64:e3affc9e7238 522 __IO uint32_t PIO1_29; /*!< (@ 0x400440D4) I/O configuration for pin PIO1_29/SCK0/ CT32B0_CAP1 */
bogdanm 64:e3affc9e7238 523 __IO uint32_t PIO1_30; /*!< (@ 0x400440D8) I/O configuration for pin PIO1_30 */
bogdanm 64:e3affc9e7238 524 __IO uint32_t PIO1_31; /*!< (@ 0x400440DC) I/O configuration for pin PIO1_31 */
bogdanm 64:e3affc9e7238 525 } LPC_IOCON_Type;
bogdanm 64:e3affc9e7238 526
bogdanm 64:e3affc9e7238 527
bogdanm 64:e3affc9e7238 528 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 529 // ----- SYSCON -----
bogdanm 64:e3affc9e7238 530 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 531
bogdanm 64:e3affc9e7238 532 typedef struct { /*!< (@ 0x40048000) SYSCON Structure */
bogdanm 64:e3affc9e7238 533 __IO uint32_t SYSMEMREMAP; /*!< (@ 0x40048000) System memory remap */
bogdanm 64:e3affc9e7238 534 __IO uint32_t PRESETCTRL; /*!< (@ 0x40048004) Peripheral reset control */
bogdanm 64:e3affc9e7238 535 __IO uint32_t SYSPLLCTRL; /*!< (@ 0x40048008) System PLL control */
bogdanm 64:e3affc9e7238 536 __I uint32_t SYSPLLSTAT; /*!< (@ 0x4004800C) System PLL status */
bogdanm 64:e3affc9e7238 537 __IO uint32_t USBPLLCTRL; /*!< (@ 0x40048010) USB PLL control */
bogdanm 64:e3affc9e7238 538 __I uint32_t USBPLLSTAT; /*!< (@ 0x40048014) USB PLL status */
bogdanm 64:e3affc9e7238 539 __I uint32_t RESERVED0[2];
bogdanm 64:e3affc9e7238 540 __IO uint32_t SYSOSCCTRL; /*!< (@ 0x40048020) System oscillator control */
bogdanm 64:e3affc9e7238 541 __IO uint32_t WDTOSCCTRL; /*!< (@ 0x40048024) Watchdog oscillator control */
bogdanm 64:e3affc9e7238 542 __I uint32_t RESERVED1[2];
bogdanm 64:e3affc9e7238 543 __IO uint32_t SYSRSTSTAT; /*!< (@ 0x40048030) System reset status register */
bogdanm 64:e3affc9e7238 544 __I uint32_t RESERVED2[3];
bogdanm 64:e3affc9e7238 545 __IO uint32_t SYSPLLCLKSEL; /*!< (@ 0x40048040) System PLL clock source select */
bogdanm 64:e3affc9e7238 546 __I uint32_t RESERVED3;
bogdanm 64:e3affc9e7238 547 __IO uint32_t USBPLLCLKSEL; /*!< (@ 0x40048048) USB PLL clock source select */
bogdanm 64:e3affc9e7238 548 __I uint32_t RESERVED4[9];
bogdanm 64:e3affc9e7238 549 __IO uint32_t MAINCLKSEL; /*!< (@ 0x40048070) Main clock source select */
bogdanm 64:e3affc9e7238 550 __I uint32_t RESERVED5;
bogdanm 64:e3affc9e7238 551 __IO uint32_t SYSAHBCLKDIV; /*!< (@ 0x40048078) System clock divider */
bogdanm 64:e3affc9e7238 552 __I uint32_t RESERVED6;
bogdanm 64:e3affc9e7238 553 __IO uint32_t SYSAHBCLKCTRL; /*!< (@ 0x40048080) System clock control */
bogdanm 64:e3affc9e7238 554 __I uint32_t RESERVED7[4];
bogdanm 64:e3affc9e7238 555 __IO uint32_t SSP0CLKDIV; /*!< (@ 0x40048094) SSP0 clock divider */
bogdanm 64:e3affc9e7238 556 __IO uint32_t UARTCLKDIV; /*!< (@ 0x40048098) UART clock divider */
bogdanm 64:e3affc9e7238 557 __IO uint32_t SSP1CLKDIV; /*!< (@ 0x4004809C) SSP1 clock divider */
bogdanm 64:e3affc9e7238 558 __I uint32_t RESERVED8[3];
bogdanm 64:e3affc9e7238 559 __IO uint32_t TRACECLKDIV; /*!< (@ 0x400480AC) ARM trace clock divider */
bogdanm 64:e3affc9e7238 560 __IO uint32_t SYSTICKCLKDIV; /*!< (@ 0x400480B0) SYSTICK clock divder */
bogdanm 64:e3affc9e7238 561 __I uint32_t RESERVED9[3];
bogdanm 64:e3affc9e7238 562 __IO uint32_t USBCLKSEL; /*!< (@ 0x400480C0) USB clock source select */
bogdanm 64:e3affc9e7238 563 __I uint32_t RESERVED10;
bogdanm 64:e3affc9e7238 564 __IO uint32_t USBCLKDIV; /*!< (@ 0x400480C8) USB clock source divider */
bogdanm 64:e3affc9e7238 565 __I uint32_t RESERVED11[5];
bogdanm 64:e3affc9e7238 566 __IO uint32_t CLKOUTSEL; /*!< (@ 0x400480E0) CLKOUT clock source select */
bogdanm 64:e3affc9e7238 567 __I uint32_t RESERVED12;
bogdanm 64:e3affc9e7238 568 __IO uint32_t CLKOUTDIV; /*!< (@ 0x400480E8) CLKOUT clock divider */
bogdanm 64:e3affc9e7238 569 __I uint32_t RESERVED13[5];
bogdanm 64:e3affc9e7238 570 __I uint32_t PIOPORCAP0; /*!< (@ 0x40048100) POR captured PIO status 0 */
bogdanm 64:e3affc9e7238 571 __I uint32_t PIOPORCAP1; /*!< (@ 0x40048104) POR captured PIO status 1 */
bogdanm 64:e3affc9e7238 572 __I uint32_t RESERVED14[18];
bogdanm 64:e3affc9e7238 573 __IO uint32_t BODCTRL; /*!< (@ 0x40048150) Brown-Out Detect */
bogdanm 64:e3affc9e7238 574 __IO uint32_t SYSTCKCAL; /*!< (@ 0x40048154) System tick counter calibration */
bogdanm 64:e3affc9e7238 575 __I uint32_t RESERVED15[6];
bogdanm 64:e3affc9e7238 576 __IO uint32_t IRQLATENCY; /*!< (@ 0x40048170) IQR delay. Allows trade-off between interrupt latency and determinism. */
bogdanm 64:e3affc9e7238 577 __IO uint32_t NMISRC; /*!< (@ 0x40048174) NMI Source Control */
bogdanm 64:e3affc9e7238 578 __IO uint32_t PINSEL[8]; /*!< (@ 0x40048178) GPIO Pin Interrupt Select register */
bogdanm 64:e3affc9e7238 579 __IO uint32_t USBCLKCTRL; /*!< (@ 0x40048198) USB clock control */
bogdanm 64:e3affc9e7238 580 __I uint32_t USBCLKST; /*!< (@ 0x4004819C) USB clock status */
bogdanm 64:e3affc9e7238 581 __I uint32_t RESERVED16[25];
bogdanm 64:e3affc9e7238 582 __IO uint32_t STARTERP0; /*!< (@ 0x40048204) Start logic 0 interrupt wake-up enable register 0 */
bogdanm 64:e3affc9e7238 583 __I uint32_t RESERVED17[3];
bogdanm 64:e3affc9e7238 584 __IO uint32_t STARTERP1; /*!< (@ 0x40048214) Start logic 1 interrupt wake-up enable register 1 */
bogdanm 64:e3affc9e7238 585 __I uint32_t RESERVED18[6];
bogdanm 64:e3affc9e7238 586 __IO uint32_t PDSLEEPCFG; /*!< (@ 0x40048230) Power-down states in deep-sleep mode */
bogdanm 64:e3affc9e7238 587 __IO uint32_t PDAWAKECFG; /*!< (@ 0x40048234) Power-down states for wake-up from deep-sleep */
bogdanm 64:e3affc9e7238 588 __IO uint32_t PDRUNCFG; /*!< (@ 0x40048238) Power configuration register */
bogdanm 64:e3affc9e7238 589 __I uint32_t RESERVED19[111];
bogdanm 64:e3affc9e7238 590 __I uint32_t DEVICE_ID; /*!< (@ 0x400483F8) Device ID */
bogdanm 64:e3affc9e7238 591 } LPC_SYSCON_Type;
bogdanm 64:e3affc9e7238 592
bogdanm 64:e3affc9e7238 593
bogdanm 64:e3affc9e7238 594 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 595 // ----- GPIO_PIN_INT -----
bogdanm 64:e3affc9e7238 596 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 597 typedef struct { /*!< (@ 0x4004C000) GPIO_PIN_INT Structure */
bogdanm 64:e3affc9e7238 598 __IO uint32_t ISEL; /*!< (@ 0x4004C000) Pin Interrupt Mode register */
bogdanm 64:e3affc9e7238 599 __IO uint32_t IENR; /*!< (@ 0x4004C004) Pin Interrupt Enable (Rising) register */
bogdanm 64:e3affc9e7238 600 __O uint32_t SIENR; /*!< (@ 0x4004C008) Set Pin Interrupt Enable (Rising) register */
bogdanm 64:e3affc9e7238 601 __O uint32_t CIENR; /*!< (@ 0x4004C00C) Clear Pin Interrupt Enable (Rising) register */
bogdanm 64:e3affc9e7238 602 __IO uint32_t IENF; /*!< (@ 0x4004C010) Pin Interrupt Enable Falling Edge / Active Level register */
bogdanm 64:e3affc9e7238 603 __O uint32_t SIENF; /*!< (@ 0x4004C014) Set Pin Interrupt Enable Falling Edge / Active Level register */
bogdanm 64:e3affc9e7238 604 __O uint32_t CIENF; /*!< (@ 0x4004C018) Clear Pin Interrupt Enable Falling Edge / Active Level address */
bogdanm 64:e3affc9e7238 605 __IO uint32_t RISE; /*!< (@ 0x4004C01C) Pin Interrupt Rising Edge register */
bogdanm 64:e3affc9e7238 606 __IO uint32_t FALL; /*!< (@ 0x4004C020) Pin Interrupt Falling Edge register */
bogdanm 64:e3affc9e7238 607 __IO uint32_t IST; /*!< (@ 0x4004C024) Pin Interrupt Status register */
bogdanm 64:e3affc9e7238 608 } LPC_GPIO_PIN_INT_Type;
bogdanm 64:e3affc9e7238 609
bogdanm 64:e3affc9e7238 610
bogdanm 64:e3affc9e7238 611 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 612 // ----- GPIO_GROUP_INT0 -----
bogdanm 64:e3affc9e7238 613 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 614 typedef struct { /*!< (@ 0x4005C000) GPIO_GROUP_INT0 Structure */
bogdanm 64:e3affc9e7238 615 __IO uint32_t CTRL; /*!< (@ 0x4005C000) GPIO grouped interrupt control register */
bogdanm 64:e3affc9e7238 616 __I uint32_t RESERVED0[7];
bogdanm 64:e3affc9e7238 617 __IO uint32_t PORT_POL[2]; /*!< (@ 0x4005C020) GPIO grouped interrupt port 0 polarity register */
bogdanm 64:e3affc9e7238 618 __I uint32_t RESERVED1[6];
bogdanm 64:e3affc9e7238 619 __IO uint32_t PORT_ENA[2]; /*!< (@ 0x4005C040) GPIO grouped interrupt port 0/1 enable register */
bogdanm 64:e3affc9e7238 620 } LPC_GPIO_GROUP_INT0_Type;
bogdanm 64:e3affc9e7238 621
bogdanm 64:e3affc9e7238 622
bogdanm 64:e3affc9e7238 623 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 624 // ----- GPIO_GROUP_INT1 -----
bogdanm 64:e3affc9e7238 625 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 626
bogdanm 64:e3affc9e7238 627 typedef struct { /*!< (@ 0x40060000) GPIO_GROUP_INT1 Structure */
bogdanm 64:e3affc9e7238 628 __IO uint32_t CTRL; /*!< (@ 0x40060000) GPIO grouped interrupt control register */
bogdanm 64:e3affc9e7238 629 __I uint32_t RESERVED0[7];
bogdanm 64:e3affc9e7238 630 __IO uint32_t PORT_POL[2]; /*!< (@ 0x40060020) GPIO grouped interrupt port 0 polarity register */
bogdanm 64:e3affc9e7238 631 __I uint32_t RESERVED1[6];
bogdanm 64:e3affc9e7238 632 __IO uint32_t PORT_ENA[2]; /*!< (@ 0x40060040) GPIO grouped interrupt port 0/1 enable register */
bogdanm 64:e3affc9e7238 633 } LPC_GPIO_GROUP_INT1_Type;
bogdanm 64:e3affc9e7238 634
bogdanm 64:e3affc9e7238 635
bogdanm 64:e3affc9e7238 636 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 637 // ----- Repetitive Interrupt Timer (RIT) -----
bogdanm 64:e3affc9e7238 638 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 639
bogdanm 64:e3affc9e7238 640 typedef struct { /*!< (@ 0x40064000) RITIMER Structure */
bogdanm 64:e3affc9e7238 641 __IO uint32_t COMPVAL; /*!< (@ 0x40064000) RITIMER compare register */
bogdanm 64:e3affc9e7238 642 __IO uint32_t MASK; /*!< (@ 0x40064004) RITIMER mask register */
bogdanm 64:e3affc9e7238 643 __IO uint32_t CTRL; /*!< (@ 0x40064008) RITIMER control register */
bogdanm 64:e3affc9e7238 644 __IO uint32_t COUNTER; /*!< (@ 0x4006400C) RITIMER counter register */
bogdanm 64:e3affc9e7238 645 __IO uint32_t COMPVAL_H; /*!< (@ 0x40064010) RITIMER compare upper register */
bogdanm 64:e3affc9e7238 646 __IO uint32_t MASK_H; /*!< (@ 0x40064014) RITIMER mask upper register */
bogdanm 64:e3affc9e7238 647 __I uint32_t RESERVED0[1];
bogdanm 64:e3affc9e7238 648 __IO uint32_t COUNTER_H; /*!< (@ 0x4006401C) RITIMER counter upper register */
bogdanm 64:e3affc9e7238 649 } LPC_RITIMER_Type;
bogdanm 64:e3affc9e7238 650
bogdanm 64:e3affc9e7238 651
bogdanm 64:e3affc9e7238 652 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 653 // ----- USB -----
bogdanm 64:e3affc9e7238 654 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 655 typedef struct { /*!< (@ 0x40020000) USB Structure */
bogdanm 64:e3affc9e7238 656 __IO uint32_t DEVCMDSTAT; /*!< (@ 0x40020000) USB Device Command/Status register */
bogdanm 64:e3affc9e7238 657 __IO uint32_t INFO; /*!< (@ 0x40020004) USB Info register */
bogdanm 64:e3affc9e7238 658 __IO uint32_t EPLISTSTART; /*!< (@ 0x40020008) USB EP Command/Status List start address */
bogdanm 64:e3affc9e7238 659 __IO uint32_t DATABUFSTART; /*!< (@ 0x4002000C) USB Data buffer start address */
bogdanm 64:e3affc9e7238 660 __IO uint32_t LPM; /*!< (@ 0x40020010) Link Power Management register */
bogdanm 64:e3affc9e7238 661 __IO uint32_t EPSKIP; /*!< (@ 0x40020014) USB Endpoint skip */
bogdanm 64:e3affc9e7238 662 __IO uint32_t EPINUSE; /*!< (@ 0x40020018) USB Endpoint Buffer in use */
bogdanm 64:e3affc9e7238 663 __IO uint32_t EPBUFCFG; /*!< (@ 0x4002001C) USB Endpoint Buffer Configuration register */
bogdanm 64:e3affc9e7238 664 __IO uint32_t INTSTAT; /*!< (@ 0x40020020) USB interrupt status register */
bogdanm 64:e3affc9e7238 665 __IO uint32_t INTEN; /*!< (@ 0x40020024) USB interrupt enable register */
bogdanm 64:e3affc9e7238 666 __IO uint32_t INTSETSTAT; /*!< (@ 0x40020028) USB set interrupt status register */
bogdanm 64:e3affc9e7238 667 __IO uint32_t INTROUTING; /*!< (@ 0x4002002C) USB interrupt routing register */
bogdanm 64:e3affc9e7238 668 __I uint32_t RESERVED0[1];
bogdanm 64:e3affc9e7238 669 __I uint32_t EPTOGGLE; /*!< (@ 0x40020034) USB Endpoint toggle register */
bogdanm 64:e3affc9e7238 670 } LPC_USB_Type;
bogdanm 64:e3affc9e7238 671
bogdanm 64:e3affc9e7238 672
bogdanm 64:e3affc9e7238 673 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 674 // ----- GPIO_PORT -----
bogdanm 64:e3affc9e7238 675 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 676
bogdanm 64:e3affc9e7238 677 typedef struct { /*!< (@ 0x50000000) GPIO_PORT Structure */
bogdanm 64:e3affc9e7238 678 union {
bogdanm 64:e3affc9e7238 679 struct {
bogdanm 64:e3affc9e7238 680 __IO uint8_t B0[32]; /*!< (@ 0x50000000) Byte pin registers port 0; pins PIO0_0 to PIO0_31 */
bogdanm 64:e3affc9e7238 681 __IO uint8_t B1[32]; /*!< (@ 0x50000020) Byte pin registers port 1 */
bogdanm 64:e3affc9e7238 682 };
bogdanm 64:e3affc9e7238 683 __IO uint8_t B[64]; /*!< (@ 0x50000000) Byte pin registers port 0/1 */
bogdanm 64:e3affc9e7238 684 };
bogdanm 64:e3affc9e7238 685 __I uint32_t RESERVED0[1008];
bogdanm 64:e3affc9e7238 686 union {
bogdanm 64:e3affc9e7238 687 struct {
bogdanm 64:e3affc9e7238 688 __IO uint32_t W0[32]; /*!< (@ 0x50001000) Word pin registers port 0 */
bogdanm 64:e3affc9e7238 689 __IO uint32_t W1[32]; /*!< (@ 0x50001080) Word pin registers port 1 */
bogdanm 64:e3affc9e7238 690 };
bogdanm 64:e3affc9e7238 691 __IO uint32_t W[64]; /*!< (@ 0x50001000) Word pin registers port 0/1 */
bogdanm 64:e3affc9e7238 692 };
bogdanm 64:e3affc9e7238 693 __I uint32_t RESERVED1[960];
bogdanm 64:e3affc9e7238 694 __IO uint32_t DIR[2]; /*!< (@ 0x50002000) Direction registers port 0/1 */
bogdanm 64:e3affc9e7238 695 __I uint32_t RESERVED2[30];
bogdanm 64:e3affc9e7238 696 __IO uint32_t MASK[2]; /*!< (@ 0x50002080) Mask register port 0/1 */
bogdanm 64:e3affc9e7238 697 __I uint32_t RESERVED3[30];
bogdanm 64:e3affc9e7238 698 __IO uint32_t PIN[2]; /*!< (@ 0x50002100) Portpin register port 0 */
bogdanm 64:e3affc9e7238 699 __I uint32_t RESERVED4[30];
bogdanm 64:e3affc9e7238 700 __IO uint32_t MPIN[2]; /*!< (@ 0x50002180) Masked port register port 0/1 */
bogdanm 64:e3affc9e7238 701 __I uint32_t RESERVED5[30];
bogdanm 64:e3affc9e7238 702 __IO uint32_t SET[2]; /*!< (@ 0x50002200) Write: Set register for port 0/1 Read: output bits for port 0/1 */
bogdanm 64:e3affc9e7238 703 __I uint32_t RESERVED6[30];
bogdanm 64:e3affc9e7238 704 __O uint32_t CLR[2]; /*!< (@ 0x50002280) Clear port 0/1 */
bogdanm 64:e3affc9e7238 705 __I uint32_t RESERVED7[30];
bogdanm 64:e3affc9e7238 706 __O uint32_t NOT[2]; /*!< (@ 0x50002300) Toggle port 0/1 */
bogdanm 64:e3affc9e7238 707 } LPC_GPIO_Type;
bogdanm 64:e3affc9e7238 708
bogdanm 64:e3affc9e7238 709
bogdanm 64:e3affc9e7238 710 #if defined ( __CC_ARM )
bogdanm 64:e3affc9e7238 711 #pragma no_anon_unions
bogdanm 64:e3affc9e7238 712 #endif
bogdanm 64:e3affc9e7238 713
bogdanm 64:e3affc9e7238 714
bogdanm 64:e3affc9e7238 715 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 716 // ----- Peripheral memory map -----
bogdanm 64:e3affc9e7238 717 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 718
bogdanm 64:e3affc9e7238 719 #define LPC_I2C_BASE (0x40000000)
bogdanm 64:e3affc9e7238 720 #define LPC_WWDT_BASE (0x40004000)
bogdanm 64:e3affc9e7238 721 #define LPC_USART_BASE (0x40008000)
bogdanm 64:e3affc9e7238 722 #define LPC_CT16B0_BASE (0x4000C000)
bogdanm 64:e3affc9e7238 723 #define LPC_CT16B1_BASE (0x40010000)
bogdanm 64:e3affc9e7238 724 #define LPC_CT32B0_BASE (0x40014000)
bogdanm 64:e3affc9e7238 725 #define LPC_CT32B1_BASE (0x40018000)
bogdanm 64:e3affc9e7238 726 #define LPC_ADC_BASE (0x4001C000)
bogdanm 64:e3affc9e7238 727 #define LPC_PMU_BASE (0x40038000)
bogdanm 64:e3affc9e7238 728 #define LPC_FLASHCTRL_BASE (0x4003C000)
bogdanm 64:e3affc9e7238 729 #define LPC_SSP0_BASE (0x40040000)
bogdanm 64:e3affc9e7238 730 #define LPC_IOCON_BASE (0x40044000)
bogdanm 64:e3affc9e7238 731 #define LPC_SYSCON_BASE (0x40048000)
bogdanm 64:e3affc9e7238 732 #define LPC_GPIO_PIN_INT_BASE (0x4004C000)
bogdanm 64:e3affc9e7238 733 #define LPC_SSP1_BASE (0x40058000)
bogdanm 64:e3affc9e7238 734 #define LPC_GPIO_GROUP_INT0_BASE (0x4005C000)
bogdanm 64:e3affc9e7238 735 #define LPC_GPIO_GROUP_INT1_BASE (0x40060000)
bogdanm 64:e3affc9e7238 736 #define LPC_RITIMER_BASE (0x40064000)
bogdanm 64:e3affc9e7238 737 #define LPC_USB_BASE (0x40080000)
bogdanm 64:e3affc9e7238 738 #define LPC_GPIO_BASE (0x50000000)
bogdanm 64:e3affc9e7238 739
bogdanm 64:e3affc9e7238 740
bogdanm 64:e3affc9e7238 741 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 742 // ----- Peripheral declaration -----
bogdanm 64:e3affc9e7238 743 // ------------------------------------------------------------------------------------------------
bogdanm 64:e3affc9e7238 744
bogdanm 64:e3affc9e7238 745 #define LPC_I2C ((LPC_I2C_Type *) LPC_I2C_BASE)
bogdanm 64:e3affc9e7238 746 #define LPC_WWDT ((LPC_WWDT_Type *) LPC_WWDT_BASE)
bogdanm 64:e3affc9e7238 747 #define LPC_USART ((LPC_USART_Type *) LPC_USART_BASE)
bogdanm 64:e3affc9e7238 748 #define LPC_CT16B0 ((LPC_CTxxBx_Type *) LPC_CT16B0_BASE)
bogdanm 64:e3affc9e7238 749 #define LPC_CT16B1 ((LPC_CTxxBx_Type *) LPC_CT16B1_BASE)
bogdanm 64:e3affc9e7238 750 #define LPC_CT32B0 ((LPC_CTxxBx_Type *) LPC_CT32B0_BASE)
bogdanm 64:e3affc9e7238 751 #define LPC_CT32B1 ((LPC_CTxxBx_Type *) LPC_CT32B1_BASE)
bogdanm 64:e3affc9e7238 752 #define LPC_ADC ((LPC_ADC_Type *) LPC_ADC_BASE)
bogdanm 64:e3affc9e7238 753 #define LPC_PMU ((LPC_PMU_Type *) LPC_PMU_BASE)
bogdanm 64:e3affc9e7238 754 #define LPC_FLASHCTRL ((LPC_FLASHCTRL_Type *) LPC_FLASHCTRL_BASE)
bogdanm 64:e3affc9e7238 755 #define LPC_SSP0 ((LPC_SSPx_Type *) LPC_SSP0_BASE)
bogdanm 64:e3affc9e7238 756 #define LPC_SSP1 ((LPC_SSPx_Type *) LPC_SSP1_BASE)
bogdanm 64:e3affc9e7238 757 #define LPC_IOCON ((LPC_IOCON_Type *) LPC_IOCON_BASE)
bogdanm 64:e3affc9e7238 758 #define LPC_SYSCON ((LPC_SYSCON_Type *) LPC_SYSCON_BASE)
bogdanm 64:e3affc9e7238 759 #define LPC_GPIO_PIN_INT ((LPC_GPIO_PIN_INT_Type *) LPC_GPIO_PIN_INT_BASE)
bogdanm 64:e3affc9e7238 760 #define LPC_GPIO_GROUP_INT0 ((LPC_GPIO_GROUP_INT0_Type*) LPC_GPIO_GROUP_INT0_BASE)
bogdanm 64:e3affc9e7238 761 #define LPC_GPIO_GROUP_INT1 ((LPC_GPIO_GROUP_INT1_Type*) LPC_GPIO_GROUP_INT1_BASE)
bogdanm 64:e3affc9e7238 762 #define LPC_RITIMER ((LPC_RITIMER_Type *) LPC_RITIMER_BASE)
bogdanm 64:e3affc9e7238 763 #define LPC_USB ((LPC_USB_Type *) LPC_USB_BASE)
bogdanm 64:e3affc9e7238 764 #define LPC_GPIO ((LPC_GPIO_Type *) LPC_GPIO_BASE)
bogdanm 64:e3affc9e7238 765
bogdanm 64:e3affc9e7238 766
bogdanm 64:e3affc9e7238 767 /** @} */ /* End of group Device_Peripheral_Registers */
bogdanm 64:e3affc9e7238 768 /** @} */ /* End of group (null) */
bogdanm 64:e3affc9e7238 769 /** @} */ /* End of group h1usf */
bogdanm 64:e3affc9e7238 770
bogdanm 64:e3affc9e7238 771 #ifdef __cplusplus
bogdanm 64:e3affc9e7238 772 }
bogdanm 64:e3affc9e7238 773 #endif
bogdanm 64:e3affc9e7238 774
bogdanm 64:e3affc9e7238 775
bogdanm 64:e3affc9e7238 776 #endif // __LPC13UXX_H__