/** * \file * * \brief SAM TCC - Timer Counter for Control Applications Driver * * Copyright (C) 2013-2016 Atmel Corporation. All rights reserved. * * \asf_license_start * * \page License * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * * 2. Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * * 3. The name of Atmel may not be used to endorse or promote products derived * from this software without specific prior written permission. * * 4. This software may only be redistributed and used in connection with an * Atmel microcontroller product. * * THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE * EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR * ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, * STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN * ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. * * \asf_license_stop * */ /* * Support and FAQ: visit Atmel Support */ #ifndef TCC_H_INCLUDED #define TCC_H_INCLUDED /** * \defgroup asfdoc_sam0_tcc_group SAM Timer Counter for Control Applications (TCC) Driver * * This driver for Atmel® | SMART ARM®-based microcontrollers provides an interface for the configuration * and management of the TCC module within the device, for waveform * generation and timing operations. It also provides extended options for * control applications. * * The following driver API modes are covered * by this manual: * * - Polled APIs * \if TCC_CALLBACK_MODE * - Callback APIs * \endif * * The following peripheral is used by this module: * - TCC (Timer/Counter for Control Applications) * * The following devices can use this module: * - Atmel | SMART SAM D21 * - Atmel | SMART SAM R21 * - Atmel | SMART SAM D10/D11 * - Atmel | SMART SAM L21/L22 * - Atmel | SMART SAM DA1 * - Atmel | SMART SAM C20/C21 * - Atmel | SMART SAM HA1 * - Atmel | SMART SAM R30 * * The outline of this documentation is as follows: * - \ref asfdoc_sam0_tcc_prerequisites * - \ref asfdoc_sam0_tcc_module_overview * - \ref asfdoc_sam0_tcc_special_considerations * - \ref asfdoc_sam0_tcc_extra_info * - \ref asfdoc_sam0_tcc_examples * - \ref asfdoc_sam0_tcc_api_overview * * \section asfdoc_sam0_tcc_prerequisites Prerequisites * * There are no prerequisites for this module. * * \section asfdoc_sam0_tcc_module_overview Module Overview * * The Timer/Counter for Control Applications (TCC) module provides a set of * timing and counting related functionality, such as the generation of periodic * waveforms, the capturing of a periodic waveform's frequency/duty cycle, * software timekeeping for periodic operations, waveform extension control, * fault detection etc. * * The counter size of the TCC modules can be 16- or 24-bit depending on * the TCC instance. * Refer \ref asfdoc_sam0_tcc_special_considerations_tcc_d21 and * \ref asfdoc_sam0_tcc_special_considerations_tcc_d11 for details on TCC instances. * * The TCC module for the SAM includes the following functions: * * - Generation of PWM signals * - Generation of timestamps for events * - General time counting * - Waveform period capture * - Waveform frequency capture * - Additional control for generated waveform outputs * - Fault protection for waveform generation * * \ref asfdoc_sam0_tcc_block_diagram "The diagram below" shows the overview * of the TCC Module. * * \anchor asfdoc_sam0_tcc_block_diagram * \image html overview.svg "Overview of the TCC Module" * * \subsection asfdoc_sam0_tcc_module_overview_parts Functional Description * The TCC module consists of following sections: * - Base Counter * - Compare/Capture channels, with waveform generation * - Waveform extension control and fault detection * - Interface to the event system, DMAC, and the interrupt system * * The base counter can be configured to either count a prescaled generic * clock or events from the event system.(TCEx, with event action configured * to counting). * The counter value can be used by compare/capture channels which can be * set up either in compare mode or capture mode. * * In capture mode, the counter value is stored when a configurable event * occurs. This mode can be used to generate timestamps used in event capture, * or it can be used for the measurement of a periodic input signal's * frequency/duty cycle. * * In compare mode, the counter value is compared against one or more of the * configured channels' compare values. When the counter value coincides with a * compare value an action can be taken automatically by the module, such as * generating an output event or toggling a pin when used for frequency or PWM * signal generation. * * \note The connection of events between modules requires the use of the * \ref asfdoc_sam0_events_group "SAM Event System Driver (EVENTS)" * to route output event of one module to the the input event of another. * For more information on event routing, refer to the event driver * documentation. * * In compare mode, when output signal is generated, extended waveform controls * are available, to arrange the compare outputs into specific formats. * The Output matrix can change the channel output routing. Pattern generation * unit can overwrite the output signal line to specific state. * The Fault protection feature of the TCC supports recoverable and * non-recoverable faults. * * \subsection asfdoc_sam0_tcc_module_overview_tc Base Timer/Counter * * \subsubsection asfdoc_sam0_tcc_module_overview_tc_size Timer/Counter Size * Each TCC has a counter size of either 16- or 24-bits. The size of the * counter determines the maximum value it can count to before an overflow * occurs. * \ref asfdoc_sam0_tcc_count_size_vs_top "The table below" shows the * maximum values for each of the possible counter sizes. * * \anchor asfdoc_sam0_tcc_count_size_vs_top * * * * * * * * * * * * * * * * * *
Timer Counter Sizes and Their Maximum Count Values
Counter sizeMax. (hexadecimal)Max. (decimal)
16-bit0xFFFF65,535
24-bit0xFFFFFF16,777,215
* * The period/top value of the counter can be set, to define counting period. * This will allow the counter to overflow when the counter value reaches the * period/top value. * * \subsubsection asfdoc_sam0_tcc_module_overview_tc_clk Timer/Counter Clock and Prescaler * TCC is clocked asynchronously to the system clock by a GCLK * (Generic Clock) channel. The GCLK channel can be connected to any of the GCLK * generators. The GCLK generators are configured to use one of the available * clock sources in the system such as internal oscillator, external crystals, * etc. See the \ref asfdoc_sam0_system_clock_group "Generic Clock driver" for * more information. * * Each TCC module in the SAM has its own individual clock prescaler, which * can be used to divide the input clock frequency used by the counter. This * prescaler only scales the clock used to provide clock pulses for the counter * to count, and does not affect the digital register interface portion of * the module, thus the timer registers will be synchronized to the raw GCLK * frequency input to the module. * * As a result of this, when selecting a GCLK frequency and timer prescaler * value, the user application should consider both the timer resolution * required and the synchronization frequency to avoid lengthy * synchronization times of the module if a very slow GCLK frequency is fed * into the TCC module. It is preferable to use a higher module GCLK frequency * as the input to the timer, and prescale this down as much as possible to * obtain a suitable counter frequency in latency-sensitive applications. * * \subsubsection asfdoc_sam0_tcc_module_overview_tc_ctrl Timer/Counter Control Inputs (Events) * * The TCC can take several actions on the occurrence of an input event. * The event actions are listed * in \ref asfdoc_sam0_tcc_module_event_act "events action settings". * * \anchor asfdoc_sam0_tcc_module_event_act * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
TCC Module Event Actions
Event actionDescriptionApplied event
TCC_EVENT_ACTION_OFFNo action on the event inputAll
TCC_EVENT_ACTION_RETRIGGERRe-trigger Counter on eventAll
TCC_EVENT_ACTION_NON_RECOVERABLE_FAULTGenerate Non-Recoverable Fault on eventAll
TCC_EVENT_ACTION_STARTCounter start on eventEV0
TCC_EVENT_ACTION_DIR_CONTROLCounter direction controlEV0
TCC_EVENT_ACTION_DECREMENTCounter decrement on eventEV0
TCC_EVENT_ACTION_PERIOD_PULSE_WIDTH_CAPTURECapture pulse period and pulse widthEV0
TCC_EVENT_ACTION_PULSE_WIDTH_PERIOD_CAPTURECapture pulse width and pulse periodEV0
TCC_EVENT_ACTION_STOPCounter stop on eventEV1
TCC_EVENT_ACTION_COUNT_EVENTCounter count on eventEV1
TCC_EVENT_ACTION_INCREMENTCounter increment on eventEV1
TCC_EVENT_ACTION_COUNT_DURING_ACTIVECounter count during active state of asynchronous eventEV1
* * \subsubsection asfdoc_sam0_tcc_module_overview_tc_reload Timer/Counter Reloading * * The TCC also has a configurable reload action, used when a * re-trigger event occurs. Examples of a re-trigger event could be the counter * reaching the maximum value when counting up, or when an event from the event * system makes the counter to re-trigger. The reload action determines if the * prescaler should be reset, and on which clock. The counter will * always be reloaded with the value it is set to start counting. The user * can choose between three different reload actions, described in * \ref asfdoc_sam0_tcc_module_reload_act "the table below". * * \anchor asfdoc_sam0_tcc_module_reload_act * * * * * * * * * * * * * * * * * * *
TCC Module Reload Actions
Reload actionDescription
TCC_RELOAD_ACTION_GCLKReload TCC counter value on next GCLK cycle. Leave prescaler * as-is.
TCC_RELOAD_ACTION_PRESCReloads TCC counter value on next prescaler clock. Leave prescaler * as-is.
TCC_RELOAD_ACTION_RESYNCReload TCC counter value on next GCLK cycle. Clear prescaler to * zero.
* * The reload action to use will depend on the specific application being * implemented. One example is when an external trigger for a reload occurs; if * the TCC uses the prescaler, the counter in the prescaler should not have a * value between zero and the division factor. The counter in the TCC module * and the counter in the prescaler should both start at zero. * If the counter is set to re-trigger when it reaches the maximum value, * this is not the right option to use. In such a case it would be better if * the prescaler is left unaltered when the re-trigger happens, letting the * counter reset on the next GCLK cycle. * * \subsubsection asfdoc_sam0_tcc_module_overview_tc_oneshot One-shot Mode * * The TCC module can be configured in one-shot mode. When configured in this * manner, starting the timer will cause it to count until the next overflow * or underflow condition before automatically halting, waiting to be manually * triggered by the user application software or an event from the event * system. * * \subsection asfdoc_sam0_tcc_module_overview_capt Capture Operations * * In capture operations, any event from the event system or a pin change can * trigger a capture of the counter value. This captured counter value can be * used as timestamps for the events, or it can be used in frequency and pulse * width capture. * * \subsubsection asfdoc_sam0_tcc_module_overview_capt_ev Capture Operations - Event * * Event capture is a simple use of the capture functionality, * designed to create timestamps for specific events. When the input event * appears, the current counter value is copied into the corresponding * compare/capture register, which can then be read by the user application. * * Note that when performing any capture operation, there is a risk that the * counter reaches its top value (MAX) when counting up, or the bottom value * (zero) when counting down, before the capture event occurs. This can distort * the result, making event timestamps to appear shorter than they really are. * In this case, the user application should check for timer overflow when * reading a capture result in order to detect this situation and perform an * appropriate adjustment. * * Before checking for a new capture, \ref TCC_STATUS_COUNT_OVERFLOW * should be checked. The response to an overflow error is left to the user * application, however, it may be necessary to clear both the overflow * flag and the capture flag upon each capture reading. * * \subsubsection asfdoc_sam0_tcc_module_overview_capt_pulse Capture Operations - Pulse Width * * Pulse Width Capture mode makes it possible to measure the pulse width and * period of PWM signals. This mode uses two capture channels of the counter. * There are two modes for pulse width capture; * Pulse Width Period (PWP) and Period Pulse Width (PPW). In PWP mode, capture * channel 0 is used for storing the pulse width and capture channel 1 stores * the observed period. While in PPW mode, the roles of the two capture channels * are reversed. * * As in the above example it is necessary to poll on interrupt flags to see * if a new capture has happened and check that a capture overflow error has * not occurred. * * Refer to \ref asfdoc_sam0_tcc_module_overview_tc_ctrl to set up the input * event to perform pulse width capture. * * \subsection asfdoc_sam0_tcc_module_overview_mc Compare Match Operation * * In compare match operation, Compare/Capture registers are compared * with the counter value. When the timer's count value matches the value of a * compare channel, a user defined action can be taken. * * \subsubsection asfdoc_sam0_tcc_module_overview_mc_timer Basic Timer * * A Basic Timer is a simple application where compare match operation is used * to determine when a specific period has elapsed. In Basic Timer operations, * one or more values in the module's Compare/Capture registers are used to * specify the time (in terms of the number of prescaled GCLK cycles, or * input events) at which * an action should be taken by the microcontroller. This can be an Interrupt * Service Routine (ISR), event generation via the event system, or a software * flag that is polled from the user application. * * \subsubsection asfdoc_sam0_tcc_module_overview_mc_wave Waveform Generation * * Waveform generation enables the TCC module to generate square waves, or, if * combined with an external passive low-pass filter, analog waveforms. * * \subsubsection asfdoc_sam0_tcc_module_overview_mc_wave_pwm Waveform Generation - PWM * * Pulse width modulation is a form of waveform generation and a signalling * technique that can be useful in many applications. When PWM mode is used, * a digital pulse train with a configurable frequency and duty cycle can be * generated by the TCC module and output to a GPIO pin of the device. * * Often PWM is used to communicate a control or information parameter to an * external circuit or component. Differing impedances of the source generator * and sink receiver circuits is less of an issue when using PWM compared to * using an analog voltage value, as noise will not generally affect the * signal's integrity to a meaningful extent. * * \ref asfdoc_sam0_tcc_module_pwm_single_diag "The figure below" illustrates * operations and different states of the counter and its output when using * the timer in Normal PWM mode (Single Slope). As can be seen, the TOP/PERIOD * value is * unchanged and is set to MAX. The compare match value is changed at several * points to illustrate the resulting waveform output changes. The PWM output is * set to normal (i.e. non-inverted) output mode. * * \anchor asfdoc_sam0_tcc_module_pwm_single_diag * \image html pwm_single_ex.svg "Example Of PWM In Single-Slope Mode, and Different Counter Operations" * * Several PWM modes are supported by the TCC module, refer to * datasheet for the details on PWM waveform generation. * * \subsubsection asfdoc_sam0_tcc_module_overview_mc_wave_freq Waveform Generation - Frequency * * Normal Frequency Generation is in many ways identical to PWM generation. * However, only in Frequency Generation, a toggle occurs on the output when a * match on a compare channels occurs. * * When the Match Frequency Generation is used, the timer value is reset on * match condition, resulting in a variable frequency square wave with a * fixed 50% duty cycle. * * \subsection asfdoc_sam0_tcc_module_overview_ext Waveform Extended Controls * * \subsubsection asfdoc_sam0_tcc_module_overview_ext_pat Pattern Generation * * Pattern insertion allows the TCC module to change the actual pin output level * without modifying the compare/match settings. * * \anchor asfdoc_sam0_tcc_module_pattern_gen * * * * * * * * * * * * * * * * * * *
TCC Module Output Pattern Generation
PatternDescription
TCC_OUTPUT_PATTERN_DISABLEPattern disabled, generate output as is
TCC_OUTPUT_PATTERN_0Generate pattern 0 on output (keep the output LOW)
TCC_OUTPUT_PATTERN_1Generate pattern 1 on output (keep the output HIGH)
* * \subsubsection asfdoc_sam0_tcc_module_overview_ext_r_fault Recoverable Faults * * The recoverable faults can trigger one or several of following fault actions: * -# *Halt* action: The recoverable faults can halt the TCC timer/counter, * so that the final output wave is kept at a defined state. When the fault * state is removed it is possible to recover the counter and waveform * generation. The halt action is defined as: * \anchor asfdoc_sam0_tcc_module_fault_halt_action * * * * * * * * * * * * * * * * * * * * * * *
TCC Module Recoverable Fault Halt Actions
ActionDescription
TCC_FAULT_HALT_ACTION_DISABLEHalt action is disabled
TCC_FAULT_HALT_ACTION_HW_HALTThe timer/counter is halted as long as the corresponding fault is * present
TCC_FAULT_HALT_ACTION_SW_HALTThe timer/counter is halted until the corresponding fault is removed * and fault state cleared by software
TCC_FAULT_HALT_ACTION_NON_RECOVERABLEForce all the TCC output pins to a pre-defined level, as what * Non-Recoverable Fault do
* -# *Restart* action: When enabled, the recoverable faults can restart the TCC * timer/counter. * -# *Keep* action: When enabled, the recoverable faults can keep the * corresponding channel output to zero when the fault condition is present. * -# *Capture* action: When the recoverable fault occurs, the capture action can * time stamps the corresponding fault. The following capture mode is * supported: * \anchor asfdoc_sam0_tcc_module_fault_capt_action * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
TCC Module Recoverable Fault Capture Actions
ActionDescription
TCC_FAULT_CAPTURE_DISABLECapture action is disabled
TCC_FAULT_CAPTURE_EACHEquivalent to standard capture operation, on each fault occurrence * the time stamp is captured
TCC_FAULT_CAPTURE_MINIMUMGet the minimum time stamped value in all time stamps
TCC_FAULT_CAPTURE_MAXIMUMGet the maximum time stamped value in all time stamps
TCC_FAULT_CAPTURE_SMALLERTime stamp the fault input if the value is smaller than last one
TCC_FAULT_CAPTURE_BIGGERTime stamp the fault input if the value is bigger than last one
TCC_FAULT_CAPTURE_CHANGETime stamp the fault input if the time stamps changes its increment * direction
* * In TCC module, only the first two compare channels (CC0 and CC1) can work * with recoverable fault inputs. The corresponding event inputs (TCCx MC0 * and TCCx MC1) are then used as fault inputs respectively. * The faults are called Fault A and Fault B. * * The recoverable fault can be filtered or effected by corresponding channel * output. On fault condition there are many other settings that can be chosen. * Refer to data sheet for more details about the recoverable fault * operations. * * \subsubsection asfdoc_sam0_tcc_module_overview_ext_n_fault Non-Recoverable Faults * * The non-recoverable faults force all the TCC output pins to a pre-defined * level (can be forced to 0 or 1). The input control signal of non-recoverable * fault is from timer/counter event (TCCx EV0 and TCCx EV1). * To enable non-recoverable fault, * corresponding TCEx event action must be set to non-recoverable fault action * (\ref TCC_EVENT_ACTION_NON_RECOVERABLE_FAULT). * Refer to \ref asfdoc_sam0_tcc_module_overview_tc_ctrl to see the available * event input action. * * \subsection asfdoc_sam0_tcc_module_overview_buffering Double and Circular Buffering * * The pattern, period, and the compare channels registers are double buffered. * For these options there are effective registers (PATT, PER, and CCx) and * buffer registers (PATTB, PERB, and CCx). When writing to the buffer * registers, the values are buffered and will be committed to effective * registers on UPDATE condition. * * Usually the buffered value is cleared after it is committed, but there is also * an option to circular the register buffers. The period (PER) and four lowest * compare channels register (CCx, x is 0 ~ 3) support this function. When * circular buffer is used, on UPDATE the previous period or compare values are * copied back into the corresponding period buffer and compare buffers. * This way, the register value and its buffer register value is actually * switched on UPDATE condition, and will be switched back on next UPDATE * condition. * * For input capture, the buffer register (CCBx) and the corresponding capture * channel register (CCx) act like a FIFO. When regular register (CCx) is empty * or read, any content in the buffer register is passed to regular one. * * In TCC module driver, when the double buffering write is enabled, any * write through \ref tcc_set_top_value(), \ref tcc_set_compare_value(), and * \ref tcc_set_pattern() will be done to the corresponding buffer register. * Then the value in the buffer register will be transferred to the regular * register on the next UPDATE condition or by a force UPDATE using * \ref tcc_force_double_buffer_update(). * * \subsection asfdoc_sam0_tcc_module_overview_sleep Sleep Mode * * TCC modules can be configured to operate in any sleep mode, with its "run * in standby" function enabled. It can wake up the device using interrupts or * perform internal actions with the help of the Event System. * * \section asfdoc_sam0_tcc_special_considerations Special Considerations * * \subsection asfdoc_sam0_tcc_special_considerations_specific_features Driver Feature Macro Definition * \ref asfdoc_sam0_tcc_feature_table "The table below" shows some specific features * of the TCC Module. * * \anchor asfdoc_sam0_tcc_feature_table * * * * * * * * * * *
TCC Module Specific Features
Driver Feature MacroSupported devices
FEATURE_TCC_GENERATE_DMA_TRIGGERSAM L21/L22/R30
* * \note The specific features are only available in the driver when the * selected device supports those features. * * \subsection asfdoc_sam0_tcc_special_considerations_tcc_feature Module Features * * The features of TCC, such as timer/counter size, number of compare capture * channels, and number of outputs, are dependent on the TCC module instance being * used. * * \subsubsection asfdoc_sam0_tcc_special_considerations_tcc_d21 SAM TCC Feature List * For SAM D21/R21/L21/L22/DA1/C21/R30, the TCC features are: * \anchor asfdoc_sam0_tcc_features_d21 * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
TCC module features for SAM D21/R21/L21/L22/DA1/C21/R30
TCC#Match/Capture channelsWave outputsCounter size [bits]FaultDitheringOutput matrixDead-Time insertionSWAPPattern
04824YYYYYY
12424YYY
22216Y
* * \subsubsection asfdoc_sam0_tcc_special_considerations_tcc_d11 SAM D10/D11 TCC Feature List * For SAM D10/D11, the TCC features are: * \anchor asfdoc_sam0_tcc_features_d11 * * * * * * * * * * * * * * * * * * * * * * * * * * *
TCC Module Features For SAM D10/D11
TCC#Match/Capture channelsWave outputsCounter size [bits]FaultDitheringOutput matrixDead-Time insertionSWAPPattern
04824YYYYYY
* * \subsection asfdoc_sam0_tcc_special_considerations_tcc_pin Channels vs. Pinouts * * As the TCC module may have more waveform output pins than the number of * compare/capture channels, the free pins (with number higher than number of * channels) will reuse the waveform generated by channels subsequently. E.g., * if the number of channels is four and the number of wave output pins is eight, channel * 0 output will be available on out pin 0 and 4, channel 1 output * on wave out pin 1 and 5, and so on. * * \section asfdoc_sam0_tcc_extra_info Extra Information * * For extra information, see \ref asfdoc_sam0_tcc_extra. This includes: * - \ref asfdoc_sam0_tcc_extra_acronyms * - \ref asfdoc_sam0_tcc_extra_dependencies * - \ref asfdoc_sam0_tcc_extra_errata * - \ref asfdoc_sam0_tcc_extra_history * * * \section asfdoc_sam0_tcc_examples Examples * * For a list of examples related to this driver, see * \ref asfdoc_sam0_tcc_exqsg. * * \section asfdoc_sam0_tcc_api_overview API Overview * @{ */ #include #include #include #include /** Maximum number of channels supported by the driver * (Channel index from 0 to \c TCC_NUM_CHANNELS - 1). */ #define TCC_NUM_CHANNELS 4 /** Maximum number of wave outputs lines supported by the driver * (Output line index from 0 to \c TCC_NUM_WAVE_OUTPUTS - 1). */ #define TCC_NUM_WAVE_OUTPUTS 8 /** Maximum number of (recoverable) faults supported by the driver. */ #define TCC_NUM_FAULTS 2 #if TCC_ASYNC == true # include #endif /** * \name Driver Feature Definition * Define port features set according to different device family. * @{ */ #if (SAML21) || (SAML22) || (SAMR30) || defined(__DOXYGEN__) /** Generate DMA triggers */ # define FEATURE_TCC_GENERATE_DMA_TRIGGER #endif /*@}*/ #ifdef __cplusplus extern "C" { #endif /** Generates a table enum list entry for a given type and index (e.g. "TCC_CALLBACK_MC_CHANNEL_0,"). */ #define _TCC_ENUM(n, type) TCC_##type##_##n, /** Generates table enum list entries for all channels of a given type and channel number on TCC module. */ #define _TCC_CHANNEL_ENUM_LIST(type) \ MREPEAT(TCC_NUM_CHANNELS, _TCC_ENUM, type##_CHANNEL) /** Generates table enum list entries for all output of a given type and waveform output number on TCC module. */ #define _TCC_WO_ENUM_LIST(type) \ MREPEAT(TCC_NUM_WAVE_OUTPUTS, _TCC_ENUM, type) #if TCC_ASYNC == true /** Enum for the possible callback types for the TCC module. */ enum tcc_callback { /** Callback for TCC overflow */ TCC_CALLBACK_OVERFLOW, /** Callback for TCC Retrigger */ TCC_CALLBACK_RETRIGGER, /** Callback for TCC counter event */ TCC_CALLBACK_COUNTER_EVENT, /** Callback for capture overflow error */ TCC_CALLBACK_ERROR, /** Callback for Recoverable Fault A */ TCC_CALLBACK_FAULTA, /** Callback for Recoverable Fault B */ TCC_CALLBACK_FAULTB, /** Callback for Non-Recoverable Fault 0 */ TCC_CALLBACK_FAULT0, /** Callback for Non-Recoverable Fault 1 */ TCC_CALLBACK_FAULT1, # if defined(__DOXYGEN__) /** Channel callback type table for TCC * * Each TCC module may contain several callback types for channels; each * channel will have its own callback type in the table, with the channel * index number substituted for "n" in the channel callback type * (e.g. \c TCC_MATCH_CAPTURE_CHANNEL_0). */ TCC_CALLBACK_CHANNEL_n = n, # else /** Callbacks for Match/Capture channels, e.g., TCC_CALLBACK_CHANNEL_0 */ _TCC_CHANNEL_ENUM_LIST(CALLBACK) # endif # if !defined(__DOXYGEN__) /** Number of available callbacks */ TCC_CALLBACK_N # endif }; #endif /* #if TCC_ASYNC == true */ /** * \name Module Status Flags * * TCC status flags, returned by \ref tcc_get_status() and cleared by * \ref tcc_clear_status(). * * @{ */ /** Timer channel \c ch (0 ~ 3) has matched against its compare value, * or has captured a new value. */ #define TCC_STATUS_CHANNEL_MATCH_CAPTURE(ch) (1UL << (ch)) /** Timer channel \c ch (0 ~ 3) match/compare output state. */ #define TCC_STATUS_CHANNEL_OUTPUT(ch) (1UL << ((ch)+8)) /** A Non-Recoverable Fault \c x (0 ~ 1) has occurred. */ #define TCC_STATUS_NON_RECOVERABLE_FAULT_OCCUR(x) (1UL << ((x)+16)) /** A Recoverable Fault \c n (0 ~ 1 representing A ~ B) has occured. */ #define TCC_STATUS_RECOVERABLE_FAULT_OCCUR(n) (1UL << ((n)+18)) /** The Non-Recoverable Fault \c x (0 ~ 1) input is present. */ #define TCC_STATUS_NON_RECOVERABLE_FAULT_PRESENT(x) (1UL << ((x)+20)) /** A Recoverable Fault \c n (0 ~ 1 representing A ~ B) is present. */ #define TCC_STATUS_RECOVERABLE_FAULT_PRESENT(n) (1UL << ((n)+22)) /** Timer registers synchronization has completed, and the synchronized count * value may be read. */ #define TCC_STATUS_SYNC_READY (1UL << 23) /** A new value was captured before the previous value was read, resulting in * lost data. */ #define TCC_STATUS_CAPTURE_OVERFLOW (1UL << 24) /** A counter event occurred. */ #define TCC_STATUS_COUNTER_EVENT (1UL << 25) /** A counter retrigger occurred. */ #define TCC_STATUS_COUNTER_RETRIGGERED (1UL << 26) /** The timer count value has overflowed from its maximum value to its minimum * when counting upward, or from its minimum value to its maximum when * counting downward. */ #define TCC_STATUS_COUNT_OVERFLOW (1UL << 27) /** Ramp period cycle index. * In ramp operation, each two period cycles are marked as cycle A and B, * the index 0 represents cycle A and 1 represents cycle B. */ #define TCC_STATUS_RAMP_CYCLE_INDEX (1UL << 28) /** The counter has been stopped (due to disable, stop command, or one-shot). */ #define TCC_STATUS_STOPPED (1UL << 29) /** @} */ /** * \brief Index of the match capture channels * * This enum is used to specify which capture/match channel to do * operations on. */ enum tcc_match_capture_channel { # if defined(__DOXYGEN__) /** Match capture channel index table for TCC * * Each TCC module may contain several match capture channels; each channel * will have its own index in the table, with the index number substituted * for "n" in the index name (e.g. \c TCC_MATCH_CAPTURE_CHANNEL_0). */ TCC_MATCH_CAPTURE_CHANNEL_n = n, # else /** Indexes of match capture channels, e.g., TCC_MATCH_CAPTURE_CHANNEL_0 */ _TCC_CHANNEL_ENUM_LIST(MATCH_CAPTURE) # endif # if !defined(__DOXYGEN__) /** Number of supported channels */ TCC_MATCH_CAPTURE_CHANNEL_N # endif }; /** * \brief Index of the wave outputs * * This enum is used to specify which wave output to do * operations on. */ enum tcc_wave_output { # if defined(__DOXYGEN__) /** Waveform output index table for TCC * * Each TCC module may contain several wave outputs; each output * will have its own index in the table, with the index number substituted * for "n" in the index name (e.g. \c TCC_WAVE_OUTPUT_0). */ TCC_WAVE_OUTPUT_n = n, # else /** Indexes of match capture channels, e.g., TCC_WAVEFORM_OUTPUT_0 */ _TCC_WO_ENUM_LIST(WAVE_OUTPUT) # endif # if !defined(__DOXYGEN__) /** Number of supported channels */ TCC_WAVE_OUTPUT_N # endif }; /** * \brief TCC wave generation mode enum * * This enum is used to specify the waveform generation mode. * */ enum tcc_wave_generation { /** Normal Frequency: Top is the PER register, output toggled on each * compare match */ TCC_WAVE_GENERATION_NORMAL_FREQ = 0, /** Match Frequency: Top is CC0 register, output toggles on each update * condition */ TCC_WAVE_GENERATION_MATCH_FREQ = 1, /** Single-Slope PWM: Top is the PER register, CCx controls duty cycle * (output active when count is greater than CCx) */ TCC_WAVE_GENERATION_SINGLE_SLOPE_PWM = 2, /** Double-slope (count up and down), non centre-aligned: Top is the PER * register, CC[x] controls duty cycle while counting up and CC[x+N/2] * controls it while counting down */ TCC_WAVE_GENERATION_DOUBLE_SLOPE_CRITICAL = 4, /** Double-slope (count up and down), interrupt/event at Bottom (Top is the * PER register, output active when count is greater than CCx) */ TCC_WAVE_GENERATION_DOUBLE_SLOPE_BOTTOM = 5, /** Double-slope (count up and down), interrupt/event at Bottom and Top: (Top is the * PER register, output active when count is lower than CCx) */ TCC_WAVE_GENERATION_DOUBLE_SLOPE_BOTH = 6, /** Double-slope (count up and down), interrupt/event at Top (Top is the * PER register, output active when count is greater than CCx) */ TCC_WAVE_GENERATION_DOUBLE_SLOPE_TOP = 7, }; /** * \brief Polarity of TCC wave generation on channels * * Specifies whether the wave output needs to be inverted or not. */ enum tcc_wave_polarity { /** Wave output is not inverted */ TCC_WAVE_POLARITY_0, /** Wave output is inverted */ TCC_WAVE_POLARITY_1 }; /** * \brief TCC pattern generator for outputs * * Used when disabling output pattern or when selecting a specific pattern. */ enum tcc_output_pattern { /** SWAP output pattern is not used */ TCC_OUTPUT_PATTERN_DISABLE, /** Pattern 0 is applied to SWAP output */ TCC_OUTPUT_PATTERN_0, /** Pattern 1 is applied to SWAP output */ TCC_OUTPUT_PATTERN_1 }; /** * \brief Ramp Operations which are supported in single-slope PWM generation * * Ramp operations which are supported in single-slope PWM generation. */ enum tcc_ramp { /** Default timer/counter PWM operation */ TCC_RAMP_RAMP1 = 0, /** Uses a single channel (CC0) to control both CC0/CC1 compare outputs. * In cycle A, the channel 0 output is disabled, and * in cycle B, the channel 1 output is disabled. */ TCC_RAMP_RAMP2A, /** Uses channels CC0 and CC1 to control compare outputs. * In cycle A, the channel 0 output is disabled, and * in cycle B, the channel 1 output is disabled.*/ TCC_RAMP_RAMP2 }; /** * \brief Ramp Index for TCC wave generation * * In ramp operation, each two period cycles are marked as cycle A and B, * the index 0 represents cycle A and 1 represents cycle B. */ enum tcc_ramp_index { /** Default, cycle index toggles. */ TCC_RAMP_INDEX_DEFAULT, /** Force next cycle to be cycle B (set to 1) */ TCC_RAMP_INDEX_FORCE_B, /** Force next cycle to be cycle A (clear to 0) */ TCC_RAMP_INDEX_FORCE_A, /** Force next cycle keeping the same as current */ TCC_RAMP_INDEX_FORCE_KEEP }; /** * \brief TCC output inversion * * Used when enabling or disabling output inversion. */ enum tcc_output_invertion { /** Output inversion not to be enabled */ TCC_OUTPUT_INVERTION_DISABLE, /** Invert the output from WO[x] */ TCC_OUTPUT_INVERTION_ENABLE }; /** * \brief TCC Counter reload action enum * * This enum specify how the counter is reloaded and whether the prescaler * should be restarted. */ enum tcc_reload_action { /** The counter is reloaded/reset on the next GCLK and starts * counting on the prescaler clock */ TCC_RELOAD_ACTION_GCLK, /** The counter is reloaded/reset on the next prescaler clock */ TCC_RELOAD_ACTION_PRESC, /** The counter is reloaded/reset on the next GCLK, and the * prescaler is restarted as well */ TCC_RELOAD_ACTION_RESYNC }; /** * \brief TCC clock prescaler values * * This enum is used to choose the clock prescaler * configuration. The prescaler divides the clock frequency of the TCC * module to operate TCC at a slower clock rate. */ enum tcc_clock_prescaler { /** Divide clock by 1 */ TCC_CLOCK_PRESCALER_DIV1, /** Divide clock by 2 */ TCC_CLOCK_PRESCALER_DIV2, /** Divide clock by 4 */ TCC_CLOCK_PRESCALER_DIV4, /** Divide clock by 8 */ TCC_CLOCK_PRESCALER_DIV8, /** Divide clock by 16 */ TCC_CLOCK_PRESCALER_DIV16, /** Divide clock by 64 */ TCC_CLOCK_PRESCALER_DIV64, /** Divide clock by 256 */ TCC_CLOCK_PRESCALER_DIV256, /** Divide clock by 1024 */ TCC_CLOCK_PRESCALER_DIV1024 }; /** * \brief TCC module count direction * * Used when selecting the Timer/Counter count direction. */ enum tcc_count_direction { /** Timer should count upward */ TCC_COUNT_DIRECTION_UP, /** Timer should count downward */ TCC_COUNT_DIRECTION_DOWN, }; #ifdef FEATURE_TCC_GENERATE_DMA_TRIGGER /** * \brief TCC module counter overflow DMA request mode * * Used when selecting the Timer/Counter overflow DMA request mode. */ enum tcc_count_overflow_dma_trigger_mode { /** TCC generates a DMA request on each cycle when an update condition * is detected */ TCC_COUNT_OVERFLOW_DMA_TRIGGER_MODE_CONTINUE, /** When an update condition is detected, the TCC generates a DMA trigger * on the cycle following the DMA One-Shot Command written to the Control * B register */ TCC_COUNT_OVERFLOW_DMA_TRIGGER_MODE_ONE_SHOT, }; #endif /** * \brief Action to perform when the TCC module is triggered by events * * Event action to perform when the module is triggered by events. */ enum tcc_event_action { /** No event action */ TCC_EVENT_ACTION_OFF, /** Stop counting, the counter will maintain its current value, waveforms * are set to a defined Non-Recoverable State output * (\ref tcc_non_recoverable_state_output). */ TCC_EVENT_ACTION_STOP, /** Re-trigger counter on event, may generate an event if the re-trigger * event output is enabled. * \note When re-trigger event action is enabled, enabling the counter * will not start until the next incoming event appears. */ TCC_EVENT_ACTION_RETRIGGER, /** Start counter when previously stopped. * Start counting on the event rising edge. Further events will not * restart the counter; * the counter keeps on counting using prescaled GCLK_TCCx, until it * reaches TOP or Zero * depending on the direction. */ TCC_EVENT_ACTION_START, /** Count events; i.e. Increment or decrement depending on count * direction. */ TCC_EVENT_ACTION_COUNT_EVENT, /** The event source must be an asynchronous event, input value will * overrides the direction settings (input low: counting up, input high: * counting down). */ TCC_EVENT_ACTION_DIR_CONTROL, /** Increment the counter on event, irrespective of count direction */ TCC_EVENT_ACTION_INCREMENT, /** Decrement the counter on event, irrespective of count direction */ TCC_EVENT_ACTION_DECREMENT, /** Count during active state of asynchronous event. In this case, * depending on the count direction, the count will be incremented * or decremented on each prescaled GCLK_TCCx, as long as the input * event remains active. */ TCC_EVENT_ACTION_COUNT_DURING_ACTIVE, /** Store period in capture register 0, pulse width in capture * register 1 */ TCC_EVENT_ACTION_PERIOD_PULSE_WIDTH_CAPTURE, /** Store pulse width in capture register 0, period in capture * register 1 */ TCC_EVENT_ACTION_PULSE_WIDTH_PERIOD_CAPTURE, /** Generate Non-Recoverable Fault on event */ TCC_EVENT_ACTION_NON_RECOVERABLE_FAULT, }; /** * \brief Action to be performed when the TCC module is triggered by event0 * * Event action to perform when the module is triggered by event0. */ enum tcc_event0_action { /** No event action */ TCC_EVENT0_ACTION_OFF = TCC_EVENT_ACTION_OFF, /** Re-trigger Counter on event */ TCC_EVENT0_ACTION_RETRIGGER = TCC_EVENT_ACTION_RETRIGGER, /** Count events (increment or decrement, depending on count direction) */ TCC_EVENT0_ACTION_COUNT_EVENT = TCC_EVENT_ACTION_COUNT_EVENT, /** Start counter on event */ TCC_EVENT0_ACTION_START = TCC_EVENT_ACTION_START, /** Increment counter on event */ TCC_EVENT0_ACTION_INCREMENT = TCC_EVENT_ACTION_INCREMENT, /** Count during active state of asynchronous event */ TCC_EVENT0_ACTION_COUNT_DURING_ACTIVE = TCC_EVENT_ACTION_COUNT_DURING_ACTIVE, /** Generate Non-Recoverable Fault on event */ TCC_EVENT0_ACTION_NON_RECOVERABLE_FAULT = TCC_EVENT_ACTION_NON_RECOVERABLE_FAULT }; /** * \brief Action to perform when the TCC module is triggered by event1 * * Event action to perform when the module is triggered by event1. */ enum tcc_event1_action { /** No event action */ TCC_EVENT1_ACTION_OFF = TCC_EVENT_ACTION_OFF, /** Re-trigger Counter on event */ TCC_EVENT1_ACTION_RETRIGGER = TCC_EVENT_ACTION_RETRIGGER, /** The event source must be an asynchronous event, and the input value * will override the direction settings. * If TCEINVx is 0 and input event is LOW: counter will count up. * If TCEINVx is 0 and input event is HIGH: counter will count down. */ TCC_EVENT1_ACTION_DIR_CONTROL = TCC_EVENT_ACTION_DIR_CONTROL, /** Stop counter on event */ TCC_EVENT1_ACTION_STOP = TCC_EVENT_ACTION_STOP, /** Decrement on event */ TCC_EVENT1_ACTION_DECREMENT = TCC_EVENT_ACTION_DECREMENT, /** Store period in capture register 0, pulse width in capture * register 1 */ TCC_EVENT1_ACTION_PERIOD_PULSE_WIDTH_CAPTURE = TCC_EVENT_ACTION_PERIOD_PULSE_WIDTH_CAPTURE, /** Store pulse width in capture register 0, period in capture * register 1 */ TCC_EVENT1_ACTION_PULSE_WIDTH_PERIOD_CAPTURE = TCC_EVENT_ACTION_PULSE_WIDTH_PERIOD_CAPTURE, /** Generate Non-Recoverable Fault on event */ TCC_EVENT1_ACTION_NON_RECOVERABLE_FAULT = TCC_EVENT_ACTION_NON_RECOVERABLE_FAULT }; /** * \brief On which part of the counter cycle the counter event output is generated * * This enum is used to define the point at which the counter event is generated. */ enum tcc_event_generation_selection { /** Counter Event is generated when a new counter cycle starts */ TCC_EVENT_GENERATION_SELECTION_START, /** Counter Event is generated when a counter cycle ends */ TCC_EVENT_GENERATION_SELECTION_END, /** Counter Event is generated when a counter cycle ends, except for the * first and last cycles */ TCC_EVENT_GENERATION_SELECTION_BETWEEN, /** Counter Event is generated when a new counter cycle starts or ends */ TCC_EVENT_GENERATION_SELECTION_BOUNDARY }; /** * \brief TCC channel operation modes * * To set a timer channel either in compare or in capture mode. */ enum tcc_channel_function { /** TCC channel performs compare operation */ TCC_CHANNEL_FUNCTION_COMPARE, /** TCC channel performs capture operation */ TCC_CHANNEL_FUNCTION_CAPTURE }; /** * \brief TCC (recoverable) fault Halt action */ enum tcc_fault_halt_action { /** Halt action disabled. */ TCC_FAULT_HALT_ACTION_DISABLE, /** Hardware halt action, counter is halted until restart */ TCC_FAULT_HALT_ACTION_HW_HALT, /** Software halt action, counter is halted until fault bit cleared */ TCC_FAULT_HALT_ACTION_SW_HALT, /** Non-Recoverable fault, force output to pre-defined level */ TCC_FAULT_HALT_ACTION_NON_RECOVERABLE }; /** * \brief TCC (recoverable) fault Capture action */ enum tcc_fault_capture_action { /** Capture disabled */ TCC_FAULT_CAPTURE_DISABLE, /** Capture on Fault, each value is captured */ TCC_FAULT_CAPTURE_EACH, /** Capture the minimum detection, but notify on smaller ones */ TCC_FAULT_CAPTURE_MINIMUM, /** Capture the maximum detection, but notify on bigger ones */ TCC_FAULT_CAPTURE_MAXIMUM, /** Capture if the value is smaller than last, notify event or interrupt * if previous stamp is confirmed to be "local minimum" (not bigger than * current stamp). */ TCC_FAULT_CAPTURE_SMALLER, /** Capture if the value is bigger than last, notify event or interrupt * if previous stamp is confirmed to be "local maximum" (not smaller than * current stamp). */ TCC_FAULT_CAPTURE_BIGGER, /** Capture if the time stamps changes its increment direction */ TCC_FAULT_CAPTURE_CHANGE }; /** * \brief Capture Channel triggered by TCC (recoverable) fault */ enum tcc_fault_capture_channel { /** Recoverable fault triggers channel 0 capture operation */ TCC_FAULT_CAPTURE_CHANNEL_0, /** Recoverable fault triggers channel 1 capture operation */ TCC_FAULT_CAPTURE_CHANNEL_1, /** Recoverable fault triggers channel 2 capture operation */ TCC_FAULT_CAPTURE_CHANNEL_2, /** Recoverable fault triggers channel 3 capture operation */ TCC_FAULT_CAPTURE_CHANNEL_3 }; /** * \brief TCC (recoverable) fault Input Source */ enum tcc_fault_source { /** Fault input is disabled */ TCC_FAULT_SOURCE_DISABLE, /** Match Capture Event x (x=0,1) input */ TCC_FAULT_SOURCE_ENABLE, /** Inverted MCEx (x=0,1) event input */ TCC_FAULT_SOURCE_INVERT, /** Alternate fault (A or B) state at the end of the previous period */ TCC_FAULT_SOURCE_ALTFAULT }; /** * \brief TCC (recoverable) fault Input Blanking Start Point */ enum tcc_fault_blanking { /** No blanking */ TCC_FAULT_BLANKING_DISABLE, /** Blanking applied from rising edge of the output waveform */ TCC_FAULT_BLANKING_RISING_EDGE, /** Blanking applied from falling edge of the output waveform */ TCC_FAULT_BLANKING_FALLING_EDGE, /** Blanking applied from each toggle of the output waveform */ TCC_FAULT_BLANKING_BOTH_EDGE }; /** * \brief TCC (recoverable) fault Input Qualification Action */ enum tcc_fault_qualification { /** The input is not disabled on compare condition */ TCC_FAULT_QUALIFICATION_DISABLE, /** The input is disabled when match output signal is at inactive level */ TCC_FAULT_QUALIFICATION_BY_OUTPUT }; /** * \brief TCC (recoverable) fault Output Keep Action */ enum tcc_fault_keep { /** Disable keeping, wave output released as soon as fault is released */ TCC_FAULT_KEEP_DISABLE, /** Keep wave output until end of TCC cycle */ TCC_FAULT_KEEP_TILL_END }; /** * \brief TCC Non-recoverable State Outupt */ enum tcc_fault_state_output { /** Non-recoverable fault output is tri-stated */ TCC_FAULT_STATE_OUTPUT_OFF, /** Non-recoverable fault force output 0 */ TCC_FAULT_STATE_OUTPUT_0, /** Non-recoverable fault force output 1 */ TCC_FAULT_STATE_OUTPUT_1 }; /** * \brief TCC (recoverable) fault Restart Action */ enum tcc_fault_restart { /** Restart Action disabled */ TCC_FAULT_RESTART_DISABLE, /** Restart Action enabled */ TCC_FAULT_RESTART_ENABLE }; /** * \brief Configuration struct for TCC module recoverable fault */ struct tcc_recoverable_fault_config { /** Fault filter value applied on MCEx event input line (0x0 ~ 0xF). * Must be 0 when MCEx event is used as synchronous event. * Apply to both recoverable and non-recoverable fault. */ uint8_t filter_value; /** Fault blanking value (0 ~ 255), disable input source for several TCC * clocks after the detection of the waveform edge */ uint8_t blanking_cycles; /** Set to \c true to enable restart action */ bool restart; /** Set to \c true to enable keep action (keep until end of TCC cycle) */ bool keep; /** Set to \c true to enable input qualification * (disable input when output is inactive) */ bool qualification; /** Specifies if the event input generates recoverable Fault. * The event system channel connected to MCEx event input must be * configured as asynchronous. */ enum tcc_fault_source source; /** Fault Blanking Start Point for recoverable Fault */ enum tcc_fault_blanking blanking; /** Halt action for recoverable Fault */ enum tcc_fault_halt_action halt_action; /** Capture action for recoverable Fault */ enum tcc_fault_capture_action capture_action; /** Channel triggered by recoverable Fault */ enum tcc_fault_capture_channel capture_channel; }; /** * \brief Configuration struct for TCC module non-recoverable fault */ struct tcc_non_recoverable_fault_config { /** Fault filter value applied on TCEx event input line (0x0 ~ 0xF). * Must be 0 when TCEx event is used as synchronous event. */ uint8_t filter_value; /** Output */ enum tcc_fault_state_output output; }; /** * \brief TCC input event enable/disable/configure structure * * For configuring an input event. */ struct tcc_input_event_config { /** Event action on incoming event */ enum tcc_event_action action; /** Modify event action */ bool modify_action; /** Invert incoming event input line */ bool invert; }; /** * \brief TCC output event enable/disable/configure structure * * Structure used for configuring an output event. */ struct tcc_output_event_config { /** It decides which part of the counter cycle the counter event output * is generated */ enum tcc_event_generation_selection generation_selection; /** A switch to allow enable/disable of events, without modifying the * event output configuration */ bool modify_generation_selection; }; /** * \brief TCC event enable/disable structure * * Event flags for the \ref tcc_enable_events() and \ref tcc_disable_events(). */ struct tcc_events { /** Input events configuration */ struct tcc_input_event_config input_config[2]; /** Output event configuration */ struct tcc_output_event_config output_config; /** Perform the configured event action when an incoming event is * signalled */ bool on_input_event_perform_action[2]; /** Perform the configured event action when an incoming channel event is * signalled */ bool on_event_perform_channel_action[TCC_NUM_CHANNELS]; /** Generate an output event on a channel capture/match. * Specify which channels will generate events */ bool generate_event_on_channel[TCC_NUM_CHANNELS]; /** Generate an output event on counter overflow/underflow */ bool generate_event_on_counter_overflow; /** Generate an output event on counter retrigger */ bool generate_event_on_counter_retrigger; /** Generate an output event on counter boundary. * See \ref tcc_event_output_action. */ bool generate_event_on_counter_event; }; /** * \brief Configuration struct for the TCC module base counter * * Structure for configuring a TCC as a counter. */ struct tcc_counter_config { /** Value to initialize the count register */ uint32_t count; /** Period/top and period/top buffer values for counter */ uint32_t period; /** When \c true, the counter will be stopped on the next hardware or * software re-trigger event or overflow/underflow */ bool oneshot; #ifdef FEATURE_TCC_GENERATE_DMA_TRIGGER /** Counter overflow trigger a DMA request mode */ enum tcc_count_overflow_dma_trigger_mode dma_trigger_mode; #endif /** Specifies the direction for the TCC to count */ enum tcc_count_direction direction; /** GCLK generator used to clock the peripheral */ enum gclk_generator clock_source; /** Specifies the prescaler value for GCLK_TCC */ enum tcc_clock_prescaler clock_prescaler; /** Specifies the reload or reset time of the counter and prescaler * resynchronization on a re-trigger event for the TCC */ enum tcc_reload_action reload_action; }; /** * \brief Configuration struct for the TCC module capture * * Structure used when configuring TCC channels in capture mode. */ struct tcc_capture_config { /** Channel functions selection (capture/match) */ enum tcc_channel_function channel_function[TCC_NUM_CHANNELS]; }; /** * \brief Configuration struct for the TCC module match/wave generation * * The structure, which helps to configure a TCC channel for compare * operation and wave generation. */ struct tcc_match_wave_config { /** Channel functions selection (capture/match) */ enum tcc_channel_function channel_function[TCC_NUM_CHANNELS]; /** Specifies polarity for match output waveform generation */ enum tcc_wave_polarity wave_polarity[TCC_NUM_CHANNELS]; /** Specifies which waveform generation mode to use */ enum tcc_wave_generation wave_generation; /** Specifies Ramp mode for waveform generation */ enum tcc_ramp wave_ramp; /** Value to be used for compare match on each channel */ uint32_t match[TCC_NUM_CHANNELS]; }; /** * \brief Configuration struct for the TCC module waveform extension * * This structure is used to specify the waveform extension features for TCC. */ struct tcc_wave_extension_config { /** Configuration for recoverable faults */ struct tcc_recoverable_fault_config recoverable_fault[TCC_NUM_FAULTS]; /** Configuration for non-recoverable faults */ struct tcc_non_recoverable_fault_config non_recoverable_fault[TCC_NUM_WAVE_OUTPUTS]; /** Invert waveform final outputs lines */ bool invert[TCC_NUM_WAVE_OUTPUTS]; }; /** * \brief Configuration struct for the TCC module output pins * * Structure which is used when taking wave output from TCC. */ struct tcc_pins_config { /** Specifies pin output for each channel */ uint32_t wave_out_pin[TCC_NUM_WAVE_OUTPUTS]; /** Specifies MUX setting for each output channel pin */ uint32_t wave_out_pin_mux[TCC_NUM_WAVE_OUTPUTS]; /** When \c true, PWM output pin for the given channel is enabled */ bool enable_wave_out_pin[TCC_NUM_WAVE_OUTPUTS]; }; /** * \brief TCC configuration structure * * Configuration struct for a TCC instance. This structure should be * initialized by the \ref tcc_get_config_defaults function before being * modified by the user application. */ struct tcc_config { /** Structure for configuring TCC base timer/counter */ struct tcc_counter_config counter; /** TCC match/capture configurations */ union { /** Helps to configure a TCC channel in capture mode */ struct tcc_capture_config capture; /** For configuring a TCC channel in compare mode */ struct tcc_match_wave_config compare; /** Serves the same purpose as compare. Used as an alias for * compare, * when a TCC channel is configured for wave generation */ struct tcc_match_wave_config wave; }; /** Structure for configuring TCC waveform extension */ struct tcc_wave_extension_config wave_ext; /** Structure for configuring TCC output pins */ struct tcc_pins_config pins; /** Set to \c true to enable double buffering write. When enabled any write * through \ref tcc_set_top_value(), \ref tcc_set_compare_value() and * \ref tcc_set_pattern() will direct to the buffer register as buffered * value, and the buffered value will be committed to effective register * on UPDATE condition, if update is not locked. * * \note The init values in \ref tcc_config for \ref tcc_init are always * filled to effective registers, no matter if double buffering is * enabled or not. */ bool double_buffering_enabled; /** When \c true the module is enabled during standby */ bool run_in_standby; }; #if TCC_ASYNC == true /* Forward Declaration for the device instance. */ struct tcc_module; /** Type definition for the TCC callback function. */ typedef void (*tcc_callback_t)(struct tcc_module *const module); #endif /** * \brief TCC software device instance structure * * TCC software instance structure, used to retain software state information * of an associated hardware module instance. * * \note The fields of this structure should not be altered by the user * application; they are reserved only for module-internal use. */ struct tcc_module { /** Hardware module pointer of the associated Timer/Counter peripheral. */ Tcc *hw; # if TCC_ASYNC == true /** Array of callbacks */ tcc_callback_t callback[TCC_CALLBACK_N]; /** Bit mask for callbacks registered */ uint32_t register_callback_mask; /** Bit mask for callbacks enabled */ uint32_t enable_callback_mask; # endif /** Set to \c true to write to buffered registers */ bool double_buffering_enabled; }; #if !defined(__DOXYGEN__) uint8_t _tcc_get_inst_index( Tcc *const hw); #endif /** * \name Driver Initialization and Configuration * @{ */ /** * \brief Determines if the hardware module is currently synchronizing to the bus * * Checks to see if the underlying hardware peripheral module is currently * synchronizing across multiple clock domains to the hardware bus. This * function can be used to delay further operations on a module until such time * that it is ready, to prevent blocking delays for synchronization in the * user application. * * \param[in] module_inst Pointer to the software module instance struct * * \return Synchronization status of the underlying hardware module. * * \retval false If the module has completed synchronization * \retval true If the module synchronization is ongoing */ static inline bool tcc_is_syncing( const struct tcc_module *const module_inst) { /* Sanity check arguments */ Assert(module_inst); Assert(module_inst->hw); return (module_inst->hw->SYNCBUSY.reg > 0); } void tcc_get_config_defaults( struct tcc_config *const config, Tcc *const hw); enum status_code tcc_init( struct tcc_module *const module_inst, Tcc *const hw, const struct tcc_config *const config); /** @} */ /** * \name Event Management * @{ */ enum status_code tcc_enable_events( struct tcc_module *const module_inst, struct tcc_events *const events); void tcc_disable_events( struct tcc_module *const module_inst, struct tcc_events *const events); /** @} */ /** * \name Enable/Disable/Reset * @{ */ /** * \brief Enable the TCC module * * Enables a TCC module that has been previously initialized. The counter will * start when the counter is enabled. * * \note When the counter is configured to re-trigger on an event, the counter * will not start until the next incoming event appears. Then it * restarts on any following event. * * \param[in] module_inst Pointer to the software module instance struct */ static inline void tcc_enable( const struct tcc_module *const module_inst) { /* Sanity check arguments */ Assert(module_inst); Assert(module_inst->hw); /* Get a pointer to the module's hardware instance */ Tcc *const tcc_module = module_inst->hw; while (tcc_module->SYNCBUSY.reg & TCC_SYNCBUSY_ENABLE) { /* Wait for sync */ } /* Enable the TCC module */ tcc_module->CTRLA.reg |= TCC_CTRLA_ENABLE; } /** * \brief Disables the TCC module * * Disables a TCC module and stops the counter. * * \param[in] module_inst Pointer to the software module instance struct */ static inline void tcc_disable( const struct tcc_module *const module_inst) { /* Sanity check arguments */ Assert(module_inst); Assert(module_inst->hw); /* Get a pointer to the module's hardware instance */ Tcc *const tcc_module = module_inst->hw; while (tcc_module->SYNCBUSY.reg & TCC_SYNCBUSY_ENABLE) { /* Wait for sync */ } /* Disbale interrupt */ tcc_module->INTENCLR.reg = TCC_INTENCLR_MASK; /* Clear interrupt flag */ tcc_module->INTFLAG.reg = TCC_INTFLAG_MASK; /* Disable the TCC module */ tcc_module->CTRLA.reg &= ~TC_CTRLA_ENABLE; } /** * \brief Resets the TCC module * * Resets the TCC module, restoring all hardware module registers to their * default values and disabling the module. The TCC module will not be * accessible while the reset is being performed. * * \note When resetting a 32-bit counter only the master TCC module's instance * structure should be passed to the function. * * \param[in] module_inst Pointer to the software module instance struct * */ static inline void tcc_reset( const struct tcc_module *const module_inst) { /* Sanity check arguments */ Assert(module_inst); Assert(module_inst->hw); /* Get a pointer to the module hardware instance */ Tcc *const tcc_module = module_inst->hw; /* Disable this module if it is running */ if (tcc_module->CTRLA.reg & TCC_CTRLA_ENABLE) { tcc_disable(module_inst); while (tcc_is_syncing(module_inst)) { /* wait while module is disabling */ } } /* Reset this TC module */ tcc_module->CTRLA.reg |= TCC_CTRLA_SWRST; } /** @} */ /** * \name Set/Toggle Count Direction * @{ */ /** * \brief Sets the TCC module count direction * * Sets the count direction of an initialized TCC module. The * specified TCC module can remain running or stopped. * * \param[in] module_inst Pointer to the software module instance struct * \param[in] dir New timer count direction to set */ static inline void tcc_set_count_direction( const struct tcc_module *const module_inst, enum tcc_count_direction dir) { /* Sanity check arguments */ Assert(module_inst); Assert(module_inst->hw); /* Get a pointer to the module's hardware instance */ Tcc *const tcc_module = module_inst->hw; while (tcc_module->SYNCBUSY.reg & TCC_SYNCBUSY_CTRLB) { /* Wait for sync */ } /* Set count direction */ if (TCC_COUNT_DIRECTION_DOWN == dir) { tcc_module->CTRLBSET.reg = TCC_CTRLBSET_DIR; return; } tcc_module->CTRLBCLR.reg = TCC_CTRLBCLR_DIR; } /** * \brief Toggles the TCC module count direction * * Toggles the count direction of an initialized TCC module. The * specified TCC module can remain running or stopped. * * \param[in] module_inst Pointer to the software module instance struct */ static inline void tcc_toggle_count_direction( const struct tcc_module *const module_inst) { /* Sanity check arguments */ Assert(module_inst); Assert(module_inst->hw); /* Get a pointer to the module's hardware instance */ Tcc *const tcc_module = module_inst->hw; while (tcc_module->SYNCBUSY.reg & TCC_SYNCBUSY_CTRLB) { /* Wait for sync */ } bool dir_value_1 = tcc_module->CTRLBSET.bit.DIR; if (dir_value_1) { tcc_module->CTRLBCLR.reg = TCC_CTRLBCLR_DIR; } else { tcc_module->CTRLBSET.reg = TCC_CTRLBSET_DIR; } } /** @} */ /** * \name Get/Set Count Value * @{ */ uint32_t tcc_get_count_value( const struct tcc_module *const module_inst); enum status_code tcc_set_count_value( const struct tcc_module *const module_inst, const uint32_t count); /** @} */ /** * \name Stop/Restart Counter * @{ */ /** * \brief Stops the counter * * This function will stop the counter. When the counter is stopped * the value in the count register is set to 0 if the counter was * counting up, or maximum or the top value if the counter was counting * down. * * \param[in] module_inst Pointer to the software module instance struct */ static inline void tcc_stop_counter( const struct tcc_module *const module_inst) { /* Sanity check arguments */ Assert(module_inst); Assert(module_inst->hw); /* Get a pointer to the module's hardware instance */ Tcc *const tcc_module = module_inst->hw; uint32_t last_cmd; /* Wait until last command is done */ do { while (tcc_module->SYNCBUSY.reg & TCC_SYNCBUSY_CTRLB) { /* Wait for sync */ } last_cmd = tcc_module->CTRLBSET.reg & TCC_CTRLBSET_CMD_Msk; if (last_cmd == TCC_CTRLBSET_CMD_NONE) { break; } else if (last_cmd == TCC_CTRLBSET_CMD_STOP) { /* Command have been issued */ return; } else if (last_cmd == TCC_CTRLBSET_CMD_RETRIGGER) { /* Cancel RETRIGGER command and issue STOP */ tcc_module->CTRLBCLR.reg = TCC_CTRLBCLR_CMD_Msk; } } while (1); /* Write command to execute */ tcc_module->CTRLBSET.reg = TCC_CTRLBSET_CMD_STOP; } /** * \brief Starts the counter from beginning * * Restarts an initialized TCC module's counter. * * \param[in] module_inst Pointer to the software module instance struct */ static inline void tcc_restart_counter( const struct tcc_module *const module_inst) { /* Sanity check arguments */ Assert(module_inst); Assert(module_inst->hw); /* Get a pointer to the module's hardware instance */ Tcc *const tcc_module = module_inst->hw; uint32_t last_cmd; /* Wait until last command is done */ do { while (tcc_module->SYNCBUSY.reg & TCC_SYNCBUSY_CTRLB) { /* Wait for sync */ } last_cmd = tcc_module->CTRLBSET.reg & TCC_CTRLBSET_CMD_Msk; if (last_cmd == TCC_CTRLBSET_CMD_NONE) { break; } else if (last_cmd == TCC_CTRLBSET_CMD_RETRIGGER) { /* Command have been issued */ return; } else if (last_cmd == TCC_CTRLBSET_CMD_STOP) { /* Cancel STOP command and issue RETRIGGER */ tcc_module->CTRLBCLR.reg = TCC_CTRLBCLR_CMD_Msk; } } while (1); /* Write command to execute */ tcc_module->CTRLBSET.reg = TCC_CTRLBSET_CMD_RETRIGGER; } /** @} */ #ifdef FEATURE_TCC_GENERATE_DMA_TRIGGER /** * \name Generate TCC DMA Triggers Command * @{ */ /** * \brief TCC DMA Trigger. * * TCC DMA trigger command. * * \param[in] module_inst Pointer to the software module instance struct */ static inline void tcc_dma_trigger_command( const struct tcc_module *const module_inst) { /* Sanity check arguments */ Assert(module_inst); Assert(module_inst->hw); /* Get a pointer to the module's hardware instance */ Tcc *const tcc_module = module_inst->hw; while (tcc_module->SYNCBUSY.reg & TCC_SYNCBUSY_CTRLB) { /* Wait for sync */ } /* Make certain that there are no conflicting commands in the register */ tcc_module->CTRLBCLR.reg = TCC_CTRLBCLR_CMD_NONE; while (tcc_module->SYNCBUSY.reg & TCC_SYNCBUSY_CTRLB) { /* Wait for sync */ } #if !(SAML21 || SAML22 || SAMR30) /* Write command to execute */ tcc_module->CTRLBSET.reg = TCC_CTRLBSET_CMD_DMATRG; #endif #if (SAML21XXXB) || (SAML22) || (SAMR30) /* Write command to execute */ tcc_module->CTRLBSET.reg = TCC_CTRLBSET_CMD_DMAOS; #endif } /** @} */ #endif /** * \name Get/Set Compare/Capture Register * @{ */ uint32_t tcc_get_capture_value( const struct tcc_module *const module_inst, const enum tcc_match_capture_channel channel_index); enum status_code tcc_set_compare_value( const struct tcc_module *const module_inst, const enum tcc_match_capture_channel channel_index, const uint32_t compare); /** @} */ /** * \name Set Top Value * @{ */ enum status_code tcc_set_top_value( const struct tcc_module *const module_inst, const uint32_t top_value); /** @} */ /** * \name Set Output Pattern * @{ */ enum status_code tcc_set_pattern( const struct tcc_module *const module_inst, const uint32_t line_index, const enum tcc_output_pattern pattern); /** @} */ /** * \name Set Ramp Index * @{ */ /** * \brief Sets the TCC module ramp index on next cycle * * In RAMP2 and RAMP2A operation, we can force either cycle A or cycle B at * the output, on the next clock cycle. * When ramp index command is disabled, cycle A and cycle B will appear at * the output, on alternate clock cycles. * See \ref tcc_ramp. * * \param[in] module_inst Pointer to the software module instance struct * \param[in] ramp_index Ramp index (\ref tcc_ramp_index) of the next cycle */ static inline void tcc_set_ramp_index( const struct tcc_module *const module_inst, const enum tcc_ramp_index ramp_index) { /* Sanity check arguments */ Assert(module_inst); Assert(module_inst->hw); /* Get a pointer to the module's hardware instance */ Tcc *const tcc_module = module_inst->hw; uint32_t last_cmd; /* Wait until last command is done */ do { while (tcc_module->SYNCBUSY.reg & TCC_SYNCBUSY_CTRLB) { /* Wait for sync */ } if (TCC_RAMP_INDEX_DEFAULT == ramp_index) { /* Cancel pending command */ tcc_module->CTRLBCLR.reg = TCC_CTRLBSET_IDXCMD_HOLD; return; } last_cmd = tcc_module->CTRLBSET.reg & TCC_CTRLBSET_IDXCMD_Msk; if (last_cmd == TCC_CTRLBSET_IDXCMD_DISABLE) { break; } else if (last_cmd == TCC_CTRLBSET_IDXCMD(ramp_index)) { /* Command have been issued */ return; } } while (1); /* Write command to execute */ tcc_module->CTRLBSET.reg = TCC_CTRLBSET_IDXCMD(ramp_index); } /** @} */ /** * \name Status Management * @{ */ /** * \brief Checks if the timer/counter is running * * \param[in] module_inst Pointer to the TCC software instance struct * * \return Status which indicates whether the module is running. * * \retval true The timer/counter is running * \retval false The timer/counter is stopped */ static inline bool tcc_is_running( struct tcc_module *const module_inst) { /* Sanity check arguments */ Assert(module_inst); Assert(module_inst->hw); return !module_inst->hw->STATUS.bit.STOP; } uint32_t tcc_get_status( struct tcc_module *const module_inst); void tcc_clear_status( struct tcc_module *const module_inst, const uint32_t status_flags); /** @} */ /** * \name Double Buffering Management * @{ */ /** * \brief Enable TCC double buffering write * * When double buffering write is enabled, the following function will write * values to buffered registers instead of effective ones (buffered): * - PERB: through \ref tcc_set_top_value() * - CCBx(x is 0~3): through \ref tcc_set_compare_value() * - PATTB: through \ref tcc_set_pattern() * * Then, on UPDATE condition the buffered registers are committed to regular ones * to take effect. * * \param[in] module_inst Pointer to the TCC software instance struct */ static inline void tcc_enable_double_buffering( struct tcc_module *const module_inst) { /* Sanity check arguments */ Assert(module_inst); module_inst->double_buffering_enabled = true; } /** * \brief Disable TCC double buffering Write * * When double buffering write is disabled, following function will write values * to effective registers (not buffered): * - PER: through \ref tcc_set_top_value() * - CCx(x is 0~3): through \ref tcc_set_compare_value() * - PATT: through \ref tcc_set_pattern() * * \note This function does not lock double buffer update, which means on next * UPDATE condition the last written buffered values will be committed to * take effect. Invoke \ref tcc_lock_double_buffer_update() before this * function to disable double buffering update, if this change is not * expected. * * \param[in] module_inst Pointer to the TCC software instance struct */ static inline void tcc_disable_double_buffering( struct tcc_module *const module_inst) { /* Sanity check arguments */ Assert(module_inst); Assert(module_inst->hw); module_inst->double_buffering_enabled = false; } /** * \brief Lock the TCC double buffered registers updates * * Locks the double buffered registers so they will not be updated through * their buffered values on UPDATE conditions. * * \param[in] module_inst Pointer to the TCC software instance struct * */ static inline void tcc_lock_double_buffer_update( struct tcc_module *const module_inst) { /* Sanity check arguments */ Assert(module_inst); Assert(module_inst->hw); while (module_inst->hw->SYNCBUSY.reg & TCC_SYNCBUSY_CTRLB) { /* Wait for sync */ } module_inst->hw->CTRLBSET.reg = TCC_CTRLBSET_LUPD; } /** * \brief Unlock the TCC double buffered registers updates * * Unlock the double buffered registers so they will be updated through * their buffered values on UPDATE conditions. * * \param[in] module_inst Pointer to the TCC software instance struct * */ static inline void tcc_unlock_double_buffer_update( struct tcc_module *const module_inst) { /* Sanity check arguments */ Assert(module_inst); Assert(module_inst->hw); while (module_inst->hw->SYNCBUSY.reg & TCC_SYNCBUSY_CTRLB) { /* Wait for sync */ } module_inst->hw->CTRLBCLR.reg = TCC_CTRLBCLR_LUPD; } /** * \brief Force the TCC double buffered registers to update once * * \param[in] module_inst Pointer to the TCC software instance struct * */ static inline void tcc_force_double_buffer_update( struct tcc_module *const module_inst) { /* Sanity check arguments */ Assert(module_inst); Assert(module_inst->hw); /* Get a pointer to the module's hardware instance */ Tcc *const tcc_module = module_inst->hw; uint32_t last_cmd; /* Wait until last command is done */ do { while (tcc_module->SYNCBUSY.reg & TCC_SYNCBUSY_CTRLB) { /* Wait for sync */ } last_cmd = tcc_module->CTRLBSET.reg & TCC_CTRLBSET_CMD_Msk; if (last_cmd == TCC_CTRLBSET_CMD_NONE) { break; } else if (last_cmd == TCC_CTRLBSET_CMD_UPDATE) { /* Command have been issued */ return; } } while (1); /* Write command to execute */ tcc_module->CTRLBSET.reg = TCC_CTRLBSET_CMD_UPDATE; } /** * \brief Enable Circular option for double buffered Top/Period Values * * Enable circular option for the double buffered top/period values. * On each UPDATE condition, the contents of PERB and PER are switched, meaning * that the contents of PERB are transferred to PER and the contents of PER are * transferred to PERB. * * \param[in] module_inst Pointer to the TCC software instance struct */ static inline void tcc_enable_circular_buffer_top( struct tcc_module *const module_inst) { /* Sanity check arguments */ Assert(module_inst); Assert(module_inst->hw); module_inst->hw->WAVE.reg |= TCC_WAVE_CIPEREN; } /** * \brief Disable Circular option for double buffered Top/Period Values * * Stop circularing the double buffered top/period values. * * \param[in] module_inst Pointer to the TCC software instance struct */ static inline void tcc_disable_circular_buffer_top( struct tcc_module *const module_inst) { /* Sanity check arguments */ Assert(module_inst); Assert(module_inst->hw); module_inst->hw->WAVE.reg &= ~TCC_WAVE_CIPEREN; } enum status_code tcc_set_double_buffer_top_values( const struct tcc_module *const module_inst, const uint32_t top_value, const uint32_t top_buffer_value); enum status_code tcc_enable_circular_buffer_compare( struct tcc_module *const module_inst, enum tcc_match_capture_channel channel_index); enum status_code tcc_disable_circular_buffer_compare( struct tcc_module *const module_inst, enum tcc_match_capture_channel channel_index); enum status_code tcc_set_double_buffer_compare_values( struct tcc_module *const module_inst, enum tcc_match_capture_channel channel_index, const uint32_t compare, const uint32_t compare_buffer); /** @} */ /** @} */ #ifdef __cplusplus } #endif /** * \page asfdoc_sam0_tcc_extra Extra Information for TCC Driver * * \section asfdoc_sam0_tcc_extra_acronyms Acronyms * The table below presents the acronyms used in this module: * * * * * * * * * * * * * * * * * * * * * * * * * * *
AcronymDescription
DMADirect Memory Access
TCCTimer Counter for Control Applications
PWMPulse Width Modulation
PWPPulse Width Period
PPWPeriod Pulse Width
* * * \section asfdoc_sam0_tcc_extra_dependencies Dependencies * This driver has the following dependencies: * * - \ref asfdoc_sam0_system_pinmux_group "System Pin Multiplexer Driver" * * * \section asfdoc_sam0_tcc_extra_errata Errata * There are no errata related to this driver. * * * \section asfdoc_sam0_tcc_extra_history Module History * An overview of the module history is presented in the table below, with * details on the enhancements and fixes made to the module since its first * release. The current version of this corresponds to the newest version in * the table. * * * * * * * * * * * * * * *
Changelog
Add double buffering functionality
Add fault handling functionality
Initial Release
*/ /** * \page asfdoc_sam0_tcc_exqsg Examples for TCC Driver * * This is a list of the available Quick Start guides (QSGs) and example * applications for \ref asfdoc_sam0_tcc_group. QSGs are simple examples with * step-by-step instructions to configure and use this driver in a selection of * use cases. Note that QSGs can be compiled as a standalone application or be * added to the user application. * * - \subpage asfdoc_sam0_tcc_basic_use_case * - \subpage asfdoc_sam0_tcc_buffering_use_case * \if TCC_CALLBACK_MODE * - \subpage asfdoc_sam0_tcc_timer_use_case * - \subpage asfdoc_sam0_tcc_callback_use_case * - \subpage asfdoc_sam0_tcc_faultx_use_case * - \subpage asfdoc_sam0_tcc_faultn_use_case * \endif * - \subpage asfdoc_sam0_tcc_dma_use_case * * \page asfdoc_sam0_tcc_document_revision_history Document Revision History * * * * * * * * * * * * * * * * * * * * * * *
Doc. Rev.DateComments
42256C12/2015Added support for SAM L21/L22, SAM DA1, and SAM C20/C21
42256B12/2014Added fault handling functionality. * Added double buffering functionality with use case. * Added timer use case. * Added SAM R21/D10/D11 support.
42256A01/2014Initial release
*/ #endif /* TCC_H_INCLUDED */