pio.h doxygen fixes and clarifications (closes #114)

This commit is contained in:
Luke Wren 2021-02-11 13:41:55 +00:00 committed by Graham Sanderson
parent a33a7c0b2c
commit 0fbaaabe6f

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@ -148,7 +148,7 @@ static inline void sm_config_set_set_pins(pio_sm_config *c, uint set_base, uint
* Can overlap with the 'out', ''set' and 'sideset' pins * Can overlap with the 'out', ''set' and 'sideset' pins
* *
* \param c Pointer to the configuration structure to modify * \param c Pointer to the configuration structure to modify
* \param in_base 0-31 First pin to set as input * \param in_base 0-31 First pin to use as input
*/ */
static inline void sm_config_set_in_pins(pio_sm_config *c, uint in_base) { static inline void sm_config_set_in_pins(pio_sm_config *c, uint in_base) {
assert(in_base < 32); assert(in_base < 32);
@ -162,7 +162,7 @@ static inline void sm_config_set_in_pins(pio_sm_config *c, uint in_base) {
* Can overlap with the 'in', 'out' and 'set' pins * Can overlap with the 'in', 'out' and 'set' pins
* *
* \param c Pointer to the configuration structure to modify * \param c Pointer to the configuration structure to modify
* \param sideset_base base pin for 'side set' * \param sideset_base 0-31 base pin for 'side set'
*/ */
static inline void sm_config_set_sideset_pins(pio_sm_config *c, uint sideset_base) { static inline void sm_config_set_sideset_pins(pio_sm_config *c, uint sideset_base) {
assert(sideset_base < 32); assert(sideset_base < 32);
@ -191,8 +191,10 @@ static inline void sm_config_set_sideset(pio_sm_config *c, uint bit_count, bool
/*! \brief Set the state machine clock divider (from a floating point value) in a state machine configuration /*! \brief Set the state machine clock divider (from a floating point value) in a state machine configuration
* \ingroup sm_config * \ingroup sm_config
* *
* The clock divider acts on the system clock to provide a clock for the state machine. * The clock divider can slow the state machine's execution to some rate below
* See the datasheet for more details. * the system clock frequency, by enabling the state machine on some cycles
* but not on others, in a regular pattern. This can be used to generate e.g.
* a given UART baud rate. See the datasheet for further detail.
* *
* \param c Pointer to the configuration structure to modify * \param c Pointer to the configuration structure to modify
* \param div The fractional divisor to be set. 1 for full speed. An integer clock divisor of n * \param div The fractional divisor to be set. 1 for full speed. An integer clock divisor of n
@ -211,8 +213,10 @@ static inline void sm_config_set_clkdiv(pio_sm_config *c, float div) {
/*! \brief Set the state machine clock divider (from integer and fractional parts - 16:8) in a state machine configuration /*! \brief Set the state machine clock divider (from integer and fractional parts - 16:8) in a state machine configuration
* \ingroup sm_config * \ingroup sm_config
* *
* The clock divider acts on the system clock to provide a clock for the state machine. * The clock divider can slow the state machine's execution to some rate below
* See the datasheet for more details. * the system clock frequency, by enabling the state machine on some cycles
* but not on others, in a regular pattern. This can be used to generate e.g.
* a given UART baud rate. See the datasheet for further detail.
* *
* \param c Pointer to the configuration structure to modify * \param c Pointer to the configuration structure to modify
* \param div_int Integer part of the divisor * \param div_int Integer part of the divisor
@ -392,6 +396,12 @@ static inline uint pio_get_index(PIO pio) {
/*! \brief Setup the function select for a GPIO to use output from the given PIO instance /*! \brief Setup the function select for a GPIO to use output from the given PIO instance
* \ingroup hardware_pio * \ingroup hardware_pio
* *
* PIO appears as an alternate function in the GPIO muxing, just like an SPI
* or UART. This function configures that multiplexing to connect a given PIO
* instance to a GPIO. Note that this is not necessary for a state machine to
* be able to read the *input* value from a GPIO, but only for it to set the
* output value or output enable.
*
* \param pio The PIO instance; either \ref pio0 or \ref pio1 * \param pio The PIO instance; either \ref pio0 or \ref pio1
* \param pin the GPIO pin whose function select to set * \param pin the GPIO pin whose function select to set
*/ */
@ -480,13 +490,13 @@ void pio_clear_instruction_memory(PIO pio);
* \ingroup hardware_pio * \ingroup hardware_pio
* *
* This method: * This method:
* - disables the state machine (if running) * - Disables the state machine (if running)
* - clears the FIFOs * - Clears the FIFOs
* - applies the configuration * - Applies the configuration specified by 'config'
* - resets any internal state * - Resets any internal state e.g. shift counters
* - jumps to the initial program location * - Jumps to the initial program location given by 'initial_pc'
* *
* The state machine is disabled on return from this call * The state machine is left disabled on return from this call.
* *
* \param pio The PIO instance; either \ref pio0 or \ref pio1 * \param pio The PIO instance; either \ref pio0 or \ref pio1
* \param sm State machine index (0..3) * \param sm State machine index (0..3)
@ -549,9 +559,24 @@ static inline void pio_restart_sm_mask(PIO pio, uint32_t mask) {
pio->ctrl |= (mask << PIO_CTRL_SM_RESTART_LSB) & PIO_CTRL_SM_RESTART_BITS; pio->ctrl |= (mask << PIO_CTRL_SM_RESTART_LSB) & PIO_CTRL_SM_RESTART_BITS;
} }
/*! \brief Restart a state machine's clock divider (resetting the fractional count) /*! \brief Restart a state machine's clock divider from a phase of 0
* \ingroup hardware_pio * \ingroup hardware_pio
* *
* Each state machine's clock divider is a free-running piece of hardware,
* that generates a pattern of clock enable pulses for the state machine,
* based *only* on the configured integer/fractional divisor. The pattern of
* enabled/disabled cycles slows the state machine's execution to some
* controlled rate.
*
* This function clears the divider's integer and fractional phase
* accumulators so that it restarts this pattern from the beginning. It is
* called automatically by pio_sm_init() but can also be called at a later
* time, when you enable the state machine, to ensure precisely consistent
* timing each time you load and run a given PIO program.
*
* More commonly this hardware mechanism is used to synchronise the execution
* clocks of multiple state machines -- see pio_clkdiv_restart_sm_mask().
*
* \param pio The PIO instance; either \ref pio0 or \ref pio1 * \param pio The PIO instance; either \ref pio0 or \ref pio1
* \param sm State machine index (0..3) * \param sm State machine index (0..3)
*/ */
@ -559,11 +584,31 @@ static inline void pio_sm_clkdiv_restart(PIO pio, uint sm) {
pio->ctrl |= 1u << (PIO_CTRL_CLKDIV_RESTART_LSB + sm); pio->ctrl |= 1u << (PIO_CTRL_CLKDIV_RESTART_LSB + sm);
} }
/*! \brief Restart multiple state machines' clock dividers (resetting the fractional count) /*! \brief Restart multiple state machines' clock dividers from a phase of 0.
* \ingroup hardware_pio * \ingroup hardware_pio
* *
* This method can be used to guarantee that multiple state machines with fractional clock dividers * Each state machine's clock divider is a free-running piece of hardware,
* are exactly in sync * that generates a pattern of clock enable pulses for the state machine,
* based *only* on the configured integer/fractional divisor. The pattern of
* enabled/disabled cycles slows the state machine's execution to some
* controlled rate.
*
* This function simultaneously clears the integer and fractional phase
* accumulators of multiple state machines' clock dividers. If these state
* machines all have the same integer and fractional divisors configured,
* their clock dividers will run in precise deterministic lockstep from this
* point.
*
* With their execution clocks synchronised in this way, it is then safe to
* e.g. have multiple state machines performing a 'wait irq' on the same flag,
* and all clear it on the same cycle.
*
* Also note that this function can be called whilst state machines are
* running (e.g. if you have just changed the clock divisors of some state
* machines and wish to resynchronise them), and that disabling a state
* machine does not halt its clock divider: that is, if multiple state
* machines have their clocks synchronised, you can safely disable and
* reenable one of the state machines without losing synchronisation.
* *
* \param pio The PIO instance; either \ref pio0 or \ref pio1 * \param pio The PIO instance; either \ref pio0 or \ref pio1
* \param mask bit mask of state machine indexes to modify the enabled state of * \param mask bit mask of state machine indexes to modify the enabled state of
@ -575,6 +620,11 @@ static inline void pio_clkdiv_restart_sm_mask(PIO pio, uint32_t mask) {
/*! \brief Enable multiple PIO state machines synchronizing their clock dividers /*! \brief Enable multiple PIO state machines synchronizing their clock dividers
* \ingroup hardware_pio * \ingroup hardware_pio
* *
* This is equivalent to calling both pio_set_sm_mask_enabled() and
* pio_clkdiv_restart_sm_mask() on the *same* clock cycle. All state machines
* specified by 'mask' are started simultaneously and, assuming they have the
* same clock divisors, their divided clocks will stay precisely synchronised.
*
* \param pio The PIO instance; either \ref pio0 or \ref pio1 * \param pio The PIO instance; either \ref pio0 or \ref pio1
* \param mask bit mask of state machine indexes to modify the enabled state of * \param mask bit mask of state machine indexes to modify the enabled state of
*/ */
@ -704,7 +754,7 @@ static inline void pio_sm_set_set_pins(PIO pio, uint sm, uint set_base, uint set
* *
* \param pio The PIO instance; either \ref pio0 or \ref pio1 * \param pio The PIO instance; either \ref pio0 or \ref pio1
* \param sm State machine index (0..3) * \param sm State machine index (0..3)
* \param in_base 0-31 First pin to set as input * \param in_base 0-31 First pin to use as input
*/ */
static inline void pio_sm_set_in_pins(PIO pio, uint sm, uint in_base) { static inline void pio_sm_set_in_pins(PIO pio, uint sm, uint in_base) {
check_sm_param(sm); check_sm_param(sm);
@ -720,7 +770,7 @@ static inline void pio_sm_set_in_pins(PIO pio, uint sm, uint in_base) {
* *
* \param pio The PIO instance; either \ref pio0 or \ref pio1 * \param pio The PIO instance; either \ref pio0 or \ref pio1
* \param sm State machine index (0..3) * \param sm State machine index (0..3)
* \param sideset_base base pin for 'side set' * \param sideset_base 0-31 base pin for 'side set'
*/ */
static inline void pio_sm_set_sideset_pins(PIO pio, uint sm, uint sideset_base) { static inline void pio_sm_set_sideset_pins(PIO pio, uint sm, uint sideset_base) {
check_sm_param(sm); check_sm_param(sm);
@ -732,11 +782,16 @@ static inline void pio_sm_set_sideset_pins(PIO pio, uint sm, uint sideset_base)
/*! \brief Write a word of data to a state machine's TX FIFO /*! \brief Write a word of data to a state machine's TX FIFO
* \ingroup hardware_pio * \ingroup hardware_pio
* *
* If the FIFO is full, the most recent value will be overwritten * This is a raw FIFO access that does not check for fullness. If the FIFO is
* full, the FIFO contents and state are not affected by the write attempt.
* Hardware sets the TXOVER sticky flag for this FIFO in FDEBUG, to indicate
* that the system attempted to write to a full FIFO.
* *
* \param pio The PIO instance; either \ref pio0 or \ref pio1 * \param pio The PIO instance; either \ref pio0 or \ref pio1
* \param sm State machine index (0..3) * \param sm State machine index (0..3)
* \param data the 32 bit data value * \param data the 32 bit data value
*
* \sa pio_sm_put_blocking
*/ */
static inline void pio_sm_put(PIO pio, uint sm, uint32_t data) { static inline void pio_sm_put(PIO pio, uint sm, uint32_t data) {
check_sm_param(sm); check_sm_param(sm);
@ -746,10 +801,17 @@ static inline void pio_sm_put(PIO pio, uint sm, uint32_t data) {
/*! \brief Read a word of data from a state machine's RX FIFO /*! \brief Read a word of data from a state machine's RX FIFO
* \ingroup hardware_pio * \ingroup hardware_pio
* *
* If the FIFO is empty, the return value is zero. * This is a raw FIFO access that does not check for emptiness. If the FIFO is
* empty, the hardware ignores the attempt to read from the FIFO (the FIFO
* remains in an empty state following the read) and the sticky RXUNDER flag
* for this FIFO is set in FDEBUG to indicate that the system tried to read
* from this FIFO when empty. The data returned by this function is undefined
* when the FIFO is empty.
* *
* \param pio The PIO instance; either \ref pio0 or \ref pio1 * \param pio The PIO instance; either \ref pio0 or \ref pio1
* \param sm State machine index (0..3) * \param sm State machine index (0..3)
*
* \sa pio_sm_get_blocking
*/ */
static inline uint32_t pio_sm_get(PIO pio, uint sm) { static inline uint32_t pio_sm_get(PIO pio, uint sm) {
check_sm_param(sm); check_sm_param(sm);
@ -860,10 +922,15 @@ static inline uint32_t pio_sm_get_blocking(PIO pio, uint sm) {
/*! \brief Empty out a state machine's TX FIFO /*! \brief Empty out a state machine's TX FIFO
* \ingroup hardware_pio * \ingroup hardware_pio
* *
* This method executes `pull` instructions on the state machine until the TX FIFO is empty * This method executes `pull` instructions on the state machine until the TX
* FIFO is empty. This disturbs the contents of the OSR, so see also
* pio_sm_clear_fifos() which clears both FIFOs but leaves the state machine's
* internal state undisturbed.
* *
* \param pio The PIO instance; either \ref pio0 or \ref pio1 * \param pio The PIO instance; either \ref pio0 or \ref pio1
* \param sm State machine index (0..3) * \param sm State machine index (0..3)
*
* \sa pio_sm_clear_fifos
*/ */
void pio_sm_drain_tx_fifo(PIO pio, uint sm); void pio_sm_drain_tx_fifo(PIO pio, uint sm);
@ -898,7 +965,7 @@ static inline void pio_sm_set_clkdiv_int_frac(PIO pio, uint sm, uint16_t div_int
(div_int << PIO_SM0_CLKDIV_INT_LSB); (div_int << PIO_SM0_CLKDIV_INT_LSB);
} }
/*! \brief Clear a state machine's TX and RX FIFOFs /*! \brief Clear a state machine's TX and RX FIFOs
* \ingroup hardware_pio * \ingroup hardware_pio
* *
* \param pio The PIO instance; either \ref pio0 or \ref pio1 * \param pio The PIO instance; either \ref pio0 or \ref pio1