doc.txt 15.2 KB
/**
 * @defgroup    cpu_kinetis_common NXP Kinetis MCU
 * @ingroup     cpu
 * @brief       NXP Kinetis CPU peripheral drivers
 */

/**
 * @defgroup    cpu_kinetis_common_adc Kinetis ADC
 * @ingroup     cpu_kinetis_common
 * @brief       ADC driver
 *
 *              ### ADC configuration example (for periph_conf.h) ###
 *
 *                  static const adc_conf_t adc_config[] = {
 *                      { .dev = ADC0, .pin = GPIO_UNDEF          , .chan =  0 }, // ADC0_DP0
 *                      { .dev = ADC0, .pin = GPIO_UNDEF          , .chan = 19 }, // ADC0_DM0
 *                      { .dev = ADC1, .pin = GPIO_UNDEF          , .chan =  0 }, // ADC1_DP0
 *                      { .dev = ADC1, .pin = GPIO_UNDEF          , .chan = 19 }, // ADC1_DM0
 *                      { .dev = ADC0, .pin = GPIO_PIN(PORT_B,  0), .chan =  8 }, // PTB0
 *                      { .dev = ADC0, .pin = GPIO_PIN(PORT_B,  1), .chan =  9 }, // PTB1
 *                      { .dev = ADC0, .pin = GPIO_PIN(PORT_C,  1), .chan = 15 }, // PTC1
 *                      { .dev = ADC0, .pin = GPIO_PIN(PORT_C,  2), .chan =  4 }, // PTC2
 *                  };
 *                  #define ADC_NUMOF           (sizeof(adc_config) / sizeof(adc_config[0]))
 */

/**
 * @defgroup    cpu_kinetis_common_cpuid Kinetis CPUID
 * @ingroup     cpu_kinetis_common
 * @brief       CPUID driver
 *
 *              No configuration is necessary.
 */

/**
 * @defgroup    cpu_kinetis_common_gpio Kinetis GPIO
 * @ingroup     cpu_kinetis_common
 * @brief       GPIO driver
 *
 *              The GPIO driver uses the @ref GPIO_PIN(port, pin) macro to declare pins.
 *
 *              No configuration is necessary.
 */

/**
 * @defgroup    cpu_kinetis_common_i2c Kinetis I2C
 * @ingroup     cpu_kinetis_common
 * @brief       I2C driver
 *
 *              ### I2C configuration example (for periph_conf.h) ###
 *
 *                  #define I2C_NUMOF               (1U)
 *                  #define I2C_0_EN                1
 *
 *                  / * Low (10 kHz): MUL = 4, SCL divider = 2560, total: 10240 * /
 *                  #define KINETIS_I2C_F_ICR_LOW        (0x3D)
 *                  #define KINETIS_I2C_F_MULT_LOW       (2)
 *                  / * Normal (100 kHz): MUL = 2, SCL divider = 240, total: 480 * /
 *                  #define KINETIS_I2C_F_ICR_NORMAL     (0x1F)
 *                  #define KINETIS_I2C_F_MULT_NORMAL    (1)
 *                  / * Fast (400 kHz): MUL = 1, SCL divider = 128, total: 128 * /
 *                  #define KINETIS_I2C_F_ICR_FAST       (0x17)
 *                  #define KINETIS_I2C_F_MULT_FAST      (0)
 *                  / * Fast plus (1000 kHz): MUL = 1, SCL divider = 48, total: 48 * /
 *                  #define KINETIS_I2C_F_ICR_FAST_PLUS  (0x10)
 *                  #define KINETIS_I2C_F_MULT_FAST_PLUS (0)
 *
 *                  // I2C 0 device configuration
 *                  #define I2C_0_DEV               I2C1
 *                  #define I2C_0_CLKEN()           (SIM->SCGC4 |= (SIM_SCGC4_I2C1_MASK))
 *                  #define I2C_0_CLKDIS()          (SIM->SCGC4 &= ~(SIM_SCGC4_I2C1_MASK))
 *                  #define I2C_0_IRQ               I2C1_IRQn
 *                  #define I2C_0_IRQ_HANDLER       isr_i2c1
 *                  // I2C 0 pin configuration
 *                  #define I2C_0_PORT              PORTE
 *                  #define I2C_0_PORT_CLKEN()      (SIM->SCGC5 |= (SIM_SCGC5_PORTE_MASK))
 *                  #define I2C_0_PIN_AF            6
 *                  #define I2C_0_SDA_PIN           0
 *                  #define I2C_0_SCL_PIN           1
 *                  #define I2C_0_PORT_CFG          (PORT_PCR_MUX(I2C_0_PIN_AF) | PORT_PCR_ODE_MASK)
 */

/**
 * @defgroup    cpu_kinetis_common_pwm Kinetis PWM
 * @ingroup     cpu_kinetis_common
 * @brief       PWM driver
 *
 *              ### PWM configuration example (for periph_conf.h) ###
 *
 *                  #define PWM_NUMOF           (1U)
 *                  #define PWM_0_EN            1
 *                  #define PWM_MAX_CHANNELS    2
 *
 *                  // PWM 0 device configuration
 *                  #define PWM_0_DEV           FTM0
 *                  #define PWM_0_CHANNELS      2
 *                  #define PWM_0_CLK           (48e6)
 *                  #define PWM_0_CLKEN()       (SIM->SCGC6 |= (SIM_SCGC6_FTM0_MASK))
 *                  #define PWM_0_CLKDIS()      (SIM->SCGC6 &= ~(SIM_SCGC6_FTM0_MASK))
 *                  // PWM 0 pin configuration
 *                  #define PWM_0_PORT_CLKEN()  (SIM->SCGC5 |= (SIM_SCGC5_PORTD_MASK | SIM_SCGC5_PORTA_MASK))
 *
 *                  #define PWM_0_PIN_CH0       4
 *                  #define PWM_0_FTMCHAN_CH0   1
 *                  #define PWM_0_PORT_CH0      PORTA
 *                  #define PWM_0_PIN_AF_CH0    3
 *
 *                  #define PWM_0_PIN_CH1       4
 *                  #define PWM_0_FTMCHAN_CH1   4
 *                  #define PWM_0_PORT_CH1      PORTD
 *                  #define PWM_0_PIN_AF_CH1    4
 */

/**
 * @defgroup    cpu_kinetis_common_rnga Kinetis RNGA
 * @ingroup     cpu_kinetis_common
 * @brief       Driver for Freescale's RNGA module. RNGA generates data that
 *              looks random. Reference Manual recommends to use the RNGA as entropy
 *              source.
 *
 *              ### RNGA configuration example (for periph_conf.h) ###
 *
 *                  #define RANDOM_NUMOF         (1U)
 *                  #define KINETIS_RNGA         RNG
 *                  #define RANDOM_CLKEN()       (SIM->SCGC6 |= (1 << 9))
 *                  #define RANDOM_CLKDIS()      (SIM->SCGC6 &= ~(1 << 9))
 */

/**
 * @defgroup    cpu_kinetis_common_rngb Kinetis RNGB
 * @ingroup     cpu_kinetis_common
 * @brief       Low-level random number generator driver implementation.
 *              Driver for Freescale's RNGB module. RNGB generates data that
 *              looks random. Reference Manual recommends to use the RNGB as entropy
 *              source.
 *
 *              ### RNGB configuration example (for periph_conf.h) ###
 *
 *                  #define RANDOM_NUMOF         (1U)
 *                  #define KINETIS_RNGB         RNG
 *                  #define RANDOM_CLKEN()       (SIM->SCGC6 |= (1 << 9))
 *                  #define RANDOM_CLKDIS()      (SIM->SCGC6 &= ~(1 << 9))
 */

/**
 * @defgroup    cpu_kinetis_common_rtc Kinetis RTC
 * @ingroup     cpu_kinetis_common
 * @brief       RTC is clocked by a 32.768 kHz clock.
 *              Please note the manual of your MCU or SiP for the
 *              clock setting for the RTC module. After initialization
 *              Time Seconds Register (TSR) increments once a second.
 *              The TSR (also TAR) value will be converted to the stuct tm
 *              and back with the help of stdlib functions that are
 *              defined in time.h.
 *              The driver supports alarm, it is stored in the
 *              Time Alarm Registers (TAR) and the unit is seconds.
 *
 *              ### RTC configuration example (for periph_conf.h) ###
 *
 *                  #define RTC_NUMOF           (1U)
 *                  #define RTC_DEV             RTC
 *                  #define RTC_UNLOCK()        (SIM->SCGC6 |= (SIM_SCGC6_RTC_MASK))
 *
 *              Optional settings to configure internal load capacitors (see
 *              reference manual):
 *
 *                  #define RTC_LOAD_CAP_BITS   0
 */

/**
 * @defgroup    cpu_kinetis_common_spi Kinetis SPI
 * @ingroup     cpu_kinetis_common
 * @brief       Kinetis SPI driver for MCUs with Cortex-M4 core.
 *
 *              The SPI baud rate and other timings are generated from the bus
 *              clock via prescalers, the hardware module allows for very
 *              detailed timing configuration, but a tool exists to generate a
 *              standard timing configuration for any given module clock frequency.
 *              The timing configuration tool is found in
 *              cpu/kinetis_common/dist/calc_spi_scalers
 *
 *              Finer tuning of timings than the RIOT SPI API is capable of is
 *              supported by modifying the generated configuration. See the
 *              reference manual for your Kinetis CPU (Chapter: "SPI module,
 *              Functional description, Module baud rate and clock delay
 *              generation") for a description of each delay.
 *
 *              The SPI driver supports using GPIO pins for chip select, as an
 *              alternative to using hardware chip select.
 *              The pins specified in spi_config[x].pin_cs[y] are the hardware
 *              chip select pins, designated SPIx_PCSy in the hardware reference
 *              documentation. These pins can not be chosen arbitrarily but must
 *              be selected from the pins which support the SPIx_PCSy function
 *              in the pin multiplexing table found in the reference manual.
 *
 *              To use a hardware controlled chip select pin, use the SPI_HWCS
 *              macro instead of GPIO_PIN when calling spi_acquire() in the
 *              device driver.
 *              Software managed CS signals can use any GPIO pin, at the cost of
 *              extra delays in the transfer because of the additional overhead
 *              of calling gpio_set/clear at every transfer.
 *
 *              ### SPI configuration example (for periph_conf.h): ###
 *
 *                  static const uint32_t spi_clk_config[] = {
 *                      // Use cpu/kinetis_common/dist/calc_spi_scalers to
 *                      // generate the timing configuration
 *                  };
 *
 *                  static const spi_conf_t spi_config[] = {
 *                      {
 *                          .dev      = SPI0,
 *                          .pin_miso = GPIO_PIN(PORT_D, 3),
 *                          .pin_mosi = GPIO_PIN(PORT_D, 2),
 *                          .pin_clk  = GPIO_PIN(PORT_D, 1),
 *                          .pin_cs   = {
 *                              GPIO_PIN(PORT_D, 0),
 *                              GPIO_PIN(PORT_D, 4),
 *                              GPIO_PIN(PORT_D, 5),
 *                              GPIO_PIN(PORT_D, 6),
 *                              GPIO_UNDEF
 *                          },
 *                          .pcr      = GPIO_AF_2,
 *                          .simmask  = SIM_SCGC6_SPI0_MASK
 *                      },
 *                      {
 *                          .dev      = SPI1,
 *                          .pin_miso = GPIO_PIN(PORT_E, 3),
 *                          .pin_mosi = GPIO_PIN(PORT_E, 1),
 *                          .pin_clk  = GPIO_PIN(PORT_E, 2),
 *                          .pin_cs   = {
 *                              GPIO_PIN(PORT_E, 4),
 *                              GPIO_UNDEF,
 *                              GPIO_UNDEF,
 *                              GPIO_UNDEF,
 *                              GPIO_UNDEF
 *                          },
 *                          .pcr      = GPIO_AF_2,
 *                          .simmask  = SIM_SCGC6_SPI1_MASK
 *                      }
 *                  };
 *
 *                  #define SPI_NUMOF           (sizeof(spi_config) / sizeof(spi_config[0]))
 */

/**
 * @defgroup    cpu_kinetis_common_timer Kinetis Timer
 * @ingroup     cpu_kinetis_common
 * @brief       Periodic Interrupt Timer (PIT) and Low-Power Timer (LPTMR) driver.
 *
 *              The PIT is a count down timer, in order to use it with riot-os
 *              a count up timer will be simulated. The PIT has four channels,
 *              each two channels are cascaded. The n-1 channel is a prescaler
 *              and the n channel a down counter. In standard configuration
 *              with four channels, two simulated count up timer are possible.
 *
 *              To counteract the effects of the asynchronous operation of the
 *              LPTMR, this driver uses the RTT as a time base which the LPTMR
 *              is referenced against. This method reduces the timing jitter
 *              caused by mixing the clock domains of the bus clock used by the
 *              CPU and the 32kHz reference clock for the LPTMR counter.
 *
 *              ### Timer configuration example (for periph_conf.h) ###
 *
 *                  #define PIT_NUMOF               (2U)
 *                  #define PIT_CONFIG {                 \
 *                          {                            \
 *                              .prescaler_ch = 0,       \
 *                              .count_ch = 1,           \
 *                          },                           \
 *                          {                            \
 *                              .prescaler_ch = 2,       \
 *                              .count_ch = 3,           \
 *                          },                           \
 *                      }
 *                  #define LPTMR_NUMOF             (1U)
 *                  #define LPTMR_CONFIG { \
 *                          { \
 *                              .dev = LPTMR0, \
 *                              .irqn = LPTMR0_IRQn, \
 *                          } \
 *                      }
 *                  #define TIMER_NUMOF             ((PIT_NUMOF) + (LPTMR_NUMOF))
 *
 *                  #define PIT_BASECLOCK           (CLOCK_BUSCLOCK)
 *                  #define PIT_ISR_0               isr_pit1
 *                  #define PIT_ISR_1               isr_pit3
 *                  #define LPTMR_ISR_0             isr_lptmr0
 */

/**
 * @defgroup    cpu_kinetis_common_uart Kinetis UART
 * @ingroup     cpu_kinetis_common
 * @brief       Kinetis UART driver.
 *              There are different implementations of the UART interface.
 *              The treatment of interrupts is also slightly different.
 *              The register UARTx_BDH to UARTx_C4 look almost the same.
 *              We distinguish the type of the UART
 *              using the BRFA field in the UART C4 register.
 *              Currently, only the base TX/RX functionality is available.
 *
 *              ### UART configuration example (for periph_conf.h) ###
 *
 *                  static const uart_conf_t uart_config[] = {
 *                      {
 *                          .dev    = UART0,
 *                          .freq   = CLOCK_CORECLOCK,
 *                          .pin_rx = GPIO_PIN(PORT_A, 14),
 *                          .pin_tx = GPIO_PIN(PORT_A, 15),
 *                          .pcr_rx = PORT_PCR_MUX(3),
 *                          .pcr_tx = PORT_PCR_MUX(3),
 *                          .irqn   = UART0_RX_TX_IRQn,
 *                          .scgc_addr = &SIM->SCGC4,
 *                          .scgc_bit = SIM_SCGC4_UART0_SHIFT,
 *                          .mode   = UART_MODE_8N1,
 *                      },
 *                      {
 *                          .dev    = UART1,
 *                          .freq   = CLOCK_CORECLOCK,
 *                          .pin_rx = GPIO_PIN(PORT_C, 3),
 *                          .pin_tx = GPIO_PIN(PORT_C, 4),
 *                          .pcr_rx = PORT_PCR_MUX(3),
 *                          .pcr_tx = PORT_PCR_MUX(3),
 *                          .irqn   = UART1_RX_TX_IRQn,
 *                          .scgc_addr = &SIM->SCGC4,
 *                          .scgc_bit = SIM_SCGC4_UART1_SHIFT,
 *                          .mode   = UART_MODE_8N1,
 *                      },
 *                  };
 *                  #define UART_NUMOF          (sizeof(uart_config) / sizeof(uart_config[0]))
 */