脉冲计数器 (PCNT)
概述
PCNT 用于统计输入信号的上升沿和/或下降沿的数量。ESP32 集成了多个脉冲计数单元,1 每个单元都是包含多个通道的独立计数器。通道可独立配置为统计上升沿或下降沿数量的递增计数器或递减计数器。
PCNT 通道可检测 边沿 信号及 电平 信号。对于比较简单的应用,检测边沿信号就足够了。PCNT 通道可检测上升沿信号、下降沿信号,同时也能设置为递增计数,递减计数,或停止计数。电平信号就是所谓的 控制信号,可用来控制边沿信号的计数模式。通过设置电平信号与边沿信号的检测模式,PCNT 单元可用作 正交解码器。
每个 PCNT 单元还包含一个滤波器,用于滤除线路毛刺。
PCNT 模块通常用于:
对一段时间内的脉冲计数,进而计算得到周期信号的频率;
对正交信号进行解码,进而获得速度和方向信息。
功能描述
PCNT 的功能从以下几个方面进行说明:
分配资源 - 说明如何通过配置分配 PCNT 单元和通道,以及在相应操作完成之后,如何回收单元和通道。
设置通道操作 - 说明如何设置通道针对不同信号沿和电平进行操作。
配置观察点 - 说明如何配置观察点,即当计数达到某个数值时,命令 PCNT 单元触发某个事件。
注册事件回调函数 - 说明如何将您的代码挂载到观察点事件的回调函数上。
设置毛刺滤波器 - 说明如何使能毛刺滤波器并设置其时序参数。
使能和禁用单元 - 说明如何使能和关闭 PCNT 单元。
控制单元 IO - 说明 PCNT 单元的 IO 控制功能,例如使能毛刺滤波器,开启和停用 PCNT 单元,获取和清除计数。
电源管理 - 说明哪些功能会阻止芯片进入低功耗模式。
支持 IRAM 安全中断 - 说明在缓存禁用的情况下,如何执行 PCNT 中断和 IO 控制功能。
支持线程安全 - 列出线程安全的 API。
支持的 Kconfig 选项 - 列出了支持的 Kconfig 选项,这些选项可实现不同的驱动效果。
分配资源
PCNT 单元和通道分别用 pcnt_unit_handle_t
与 pcnt_channel_handle_t
表示。所有的可用单元和通道都由驱动在资源池中进行维护,无需了解底层实例 ID。
安装 PCNT 单元
安装 PCNT 单元时,需要先完成配置 pcnt_unit_config_t
:
pcnt_unit_config_t::low_limit
与pcnt_unit_config_t::high_limit
用于指定内部计数器的最小值和最大值。当计数器超过任一限值时,计数器将归零。
调用函数 pcnt_new_unit()
并将 pcnt_unit_config_t
作为其输入值,可对 PCNT 单元进行分配和初始化。该函数正常运行时,会返回一个 PCNT 单元句柄。没有可用的 PCNT 单元时(即 PCNT 单元全部被占用),该函数会返回错误 ESP_ERR_NOT_FOUND
。可用的 PCNT 单元总数记录在 SOC_PCNT_UNITS_PER_GROUP
中,以供参考。
如果不再需要之前创建的某个 PCNT 单元,建议通过调用 pcnt_del_unit()
来回收该单元,从而该单元可用于其他用途。删除某个 PCNT 单元之前,需要满足以下条件:
该单元处于初始状态,即该单元要么已经被
pcnt_unit_disable()
禁用,要么尚未使能。附属于该单元的通道已全部被
pcnt_del_channel()
删除。
#define EXAMPLE_PCNT_HIGH_LIMIT 100
#define EXAMPLE_PCNT_LOW_LIMIT -100
pcnt_unit_config_t unit_config = {
.high_limit = EXAMPLE_PCNT_HIGH_LIMIT,
.low_limit = EXAMPLE_PCNT_LOW_LIMIT,
};
pcnt_unit_handle_t pcnt_unit = NULL;
ESP_ERROR_CHECK(pcnt_new_unit(&unit_config, &pcnt_unit));
安装 PCNT 通道
安装 PCNT 通道时,需要先初始化 pcnt_chan_config_t
,然后调用 pcnt_new_channel()
。对 pcnt_chan_config_t
配置如下所示:
pcnt_chan_config_t::edge_gpio_num
与pcnt_chan_config_t::level_gpio_num
用于指定 边沿 信号和 电平 信号对应的 GPIO 编号。请注意,这两个参数未被使用时,可以设置为 -1,即成为 虚拟 IO 。对于一些简单的脉冲计数应用,电平信号或边沿信号是固定的(即不会发生改变),可将其设置为虚拟 IO,然后该信号会被连接到一个固定的高/低逻辑电平,这样就可以在通道分配时回收一个 GPIO,节省一个 GPIO 管脚资源。pcnt_chan_config_t::virt_edge_io_level
与pcnt_chan_config_t::virt_level_io_level
用于指定 边沿 信号和 电平 信号的虚拟 IO 电平,以保证这些控制信号处于确定状态。请注意,只有在pcnt_chan_config_t::edge_gpio_num
或pcnt_chan_config_t::level_gpio_num
设置为 -1 时,这两个参数才有效。pcnt_chan_config_t::invert_edge_input
与pcnt_chan_config_t::invert_level_input
用于确定信号在输入 PCNT 之前是否需要被翻转,信号翻转由 GPIO 矩阵 (不是 PCNT 单元) 执行。pcnt_chan_config_t::io_loop_back
仅用于调试,它可以使能 GPIO 的输入和输出路径。这样,就可以通过调用位于同一 GPIO 上的函数gpio_set_level()
来模拟脉冲信号。
调用函数 pcnt_new_channel()
,将 pcnt_chan_config_t
作为输入值并调用 pcnt_new_unit()
返回的 PCNT 单元句柄,可对 PCNT 通道进行分配和初始化。如果该函数正常运行,会返回一个 PCNT 通道句柄。如果没有可用的 PCNT 通道(PCNT 通道资源全部被占用),该函数会返回错误 ESP_ERR_NOT_FOUND
。可用的 PCNT 通道总数记录在 SOC_PCNT_CHANNELS_PER_UNIT
,以供参考。注意,为某个单元安装 PCNT 通道时,应确保该单元处于初始状态,否则函数 pcnt_new_channel()
会返回错误 ESP_ERR_INVALID_STATE
。
如果不再需要之前创建的某个 PCNT 通道,建议通过调用 pcnt_del_channel()
回收该通道,从而该通道可用于其他用途。
#define EXAMPLE_CHAN_GPIO_A 0
#define EXAMPLE_CHAN_GPIO_B 2
pcnt_chan_config_t chan_config = {
.edge_gpio_num = EXAMPLE_CHAN_GPIO_A,
.level_gpio_num = EXAMPLE_CHAN_GPIO_B,
};
pcnt_channel_handle_t pcnt_chan = NULL;
ESP_ERROR_CHECK(pcnt_new_channel(pcnt_unit, &chan_config, &pcnt_chan));
设置通道操作
当输入脉冲信号切换时,PCNT 通道会增加,减少或停止计数。边沿信号及电平信号可设置为不同的计数器操作。
pcnt_channel_set_edge_action()
为输入到pcnt_chan_config_t::edge_gpio_num
的信号上升沿和下降沿设置操作,pcnt_channel_edge_action_t
中列出了支持的操作。pcnt_channel_set_level_action()
为输入到pcnt_chan_config_t::level_gpio_num
的信号高电平和低电平设置操作,pcnt_channel_level_action_t
中列出了支持的操作。使用pcnt_new_channel()
分配 PCNT 通道时,如果pcnt_chan_config_t::level_gpio_num
被设置为 -1,就无需对该函数进行设置了。
// decrease the counter on rising edge, increase the counter on falling edge
ESP_ERROR_CHECK(pcnt_channel_set_edge_action(pcnt_chan, PCNT_CHANNEL_EDGE_ACTION_DECREASE, PCNT_CHANNEL_EDGE_ACTION_INCREASE));
// keep the counting mode when the control signal is high level, and reverse the counting mode when the control signal is low level
ESP_ERROR_CHECK(pcnt_channel_set_level_action(pcnt_chan, PCNT_CHANNEL_LEVEL_ACTION_KEEP, PCNT_CHANNEL_LEVEL_ACTION_INVERSE));
配置观察点
PCNT 单元可被设置为观察几个特定的数值,这些被观察的数值被称为 观察点。观察点不能超过 pcnt_unit_config_t
设置的范围,最小值和最大值分别为 pcnt_unit_config_t::low_limit
和 pcnt_unit_config_t::high_limit
。当计数器到达任一观察点时,会触发一个观察事件,如果在 pcnt_unit_register_event_callbacks()
注册过事件回调函数,该事件就会通过中断通知您。关于如何注册事件回调函数,请参考 注册事件回调函数。
观察点分别可以通过 pcnt_unit_add_watch_point()
和 pcnt_unit_remove_watch_point()
进行添加和删除。常用的观察点包括 过零, 最大/最小计数 以及其他的阈值。可用的观察点是有限的,如果 pcnt_unit_add_watch_point()
无法获得空闲硬件资源来存储观察点,会返回错误 ESP_ERR_NOT_FOUND
。不能多次添加同一个观察点,否则将返回错误 ESP_ERR_INVALID_STATE
。
建议通过 pcnt_unit_remove_watch_point()
删除未使用的观察点来回收资源。
// add zero across watch point
ESP_ERROR_CHECK(pcnt_unit_add_watch_point(pcnt_unit, 0));
// add high limit watch point
ESP_ERROR_CHECK(pcnt_unit_add_watch_point(pcnt_unit, EXAMPLE_PCNT_HIGH_LIMIT));
注册事件回调函数
当 PCNT 单元的数值达到任一使能的观察点的数值时,会触发相应的事件并通过中断通知 CPU。如果您想在事件触发时执行相关函数,可通过调用 pcnt_unit_register_event_callbacks()
将函数挂载到中断服务程序 (ISR) 上。pcnt_event_callbacks_t
列出了所有支持的事件回调函数:
pcnt_event_callbacks_t::on_reach
用于为观察点事件设置回调函数。由于该回调函数是在 ISR 的上下文中被调用的,必须确保该函数不会阻塞调用的任务,(例如,可确保只有以ISR
为后缀的 FreeRTOS API 才能在函数中调用)。pcnt_watch_cb_t
中声明了该回调函数的原型。
可通过 user_ctx
将函数上下文保存到 pcnt_unit_register_event_callbacks()
中,这些数据会直接传递给回调函数。
驱动程序会将特定事件的数据写入回调函数中,例如,观察点事件数据被声明为 pcnt_watch_event_data_t
:
pcnt_watch_event_data_t::watch_point_value
用于保存触发该事件的观察点数值。pcnt_watch_event_data_t::zero_cross_mode
用于保存上一次 PCNT 单元的过零模式,pcnt_unit_zero_cross_mode_t
中列出了所有可能的过零模式。通常,不同的过零模式意味着不同的 计数方向 和 计数步长。
注册回调函数会导致中断服务延迟安装,因此回调函数只能在 PCNT 单元被 pcnt_unit_enable()
使能之前调用。否则,回调函数会返回错误 ESP_ERR_INVALID_STATE
。
static bool example_pcnt_on_reach(pcnt_unit_handle_t unit, const pcnt_watch_event_data_t *edata, void *user_ctx)
{
BaseType_t high_task_wakeup;
QueueHandle_t queue = (QueueHandle_t)user_ctx;
// send watch point to queue, from this interrupt callback
xQueueSendFromISR(queue, &(edata->watch_point_value), &high_task_wakeup);
// return whether a high priority task has been waken up by this function
return (high_task_wakeup == pdTRUE);
}
pcnt_event_callbacks_t cbs = {
.on_reach = example_pcnt_on_reach,
};
QueueHandle_t queue = xQueueCreate(10, sizeof(int));
ESP_ERROR_CHECK(pcnt_unit_register_event_callbacks(pcnt_unit, &cbs, queue));
设置毛刺滤波器
PCNT 单元的滤波器可滤除信号中的短时毛刺,pcnt_glitch_filter_config_t
中列出了毛刺滤波器的配置参数:
pcnt_glitch_filter_config_t::max_glitch_ns
设置了最大的毛刺宽度,单位为纳秒。如果一个信号脉冲的宽度小于该数值,则该信号会被认定为噪声而不会触发计数器操作。
可通过调用 pcnt_unit_set_glitch_filter()
来使能毛刺滤波器,并对上述参数进行配置。之后,还可通过调用 pcnt_unit_set_glitch_filter()
来关闭毛刺滤波器,并将上述参数设置为 NULL。
调用该函数时,PCNT 单元应处于初始状态。否则,函数将返回错误 ESP_ERR_INVALID_STATE
。
备注
毛刺滤波器的时钟信息来自 APB。为确保 PCNT 单元不会滤除脉冲信号,最大毛刺宽度应大于一个 APB_CLK 周期(如果 APB 的频率为 80 MHz,则最大毛刺宽度为 12.5 ns)。使能动态频率缩放 (DFS) 后,APB 的频率会发生变化,从而最大毛刺宽度也会发生变化,这会导致计数器无法正常工作。因此,第一次使能毛刺滤波器时,驱动会为 PCNT 单元安装 PM 锁。关于 PCNT 驱动的电源管理的更多信息,请参考 电源管理。
pcnt_glitch_filter_config_t filter_config = {
.max_glitch_ns = 1000,
};
ESP_ERROR_CHECK(pcnt_unit_set_glitch_filter(pcnt_unit, &filter_config));
使能和禁用单元
在对 PCNT 单元进行 IO 控制之前,需要通过调用函数 pcnt_unit_enable()
来使能该 PCNT 单元。该函数将完成以下操作:
将 PCNT 单元的驱动状态从 初始 切换到 使能 。
如果中断服务已经在
pcnt_unit_register_event_callbacks()
延迟安装,使能中断服务。如果电源管理锁已经在
pcnt_unit_set_glitch_filter()
延迟安装,获取该电源管理锁。请参考 电源管理 获取更多信息。
调用函数 pcnt_unit_disable()
会进行相反的操作,即将 PCNT 单元的驱动状态切换回 初始 状态,禁用中断服务并释放电源管理锁。
控制单元 IO
启用/停用及清零
通过调用 pcnt_unit_start()
可启用 PCNT 单元,根据不同脉冲信号进行递增或递减计数;通过调用 pcnt_unit_stop()
可停用 PCNT 单元,当前的计数值会保留;通过调用 pcnt_unit_clear_count()
可将计数器清零。
注意 pcnt_unit_start()
和 pcnt_unit_stop()
应该在 PCNT 单元被 pcnt_unit_enable()
使能后调用,否则将返回错误 ESP_ERR_INVALID_STATE
。
获取计数器数值
通过调用 pcnt_unit_get_count()
可随时获取当前计数器的数值。
备注
返回的计数器数值是一个 带符号 的整数,符号代表计数方向。计数器的数值大于等于最大值或小于等于最小值时,计数器会溢出。
int pulse_count = 0;
ESP_ERROR_CHECK(pcnt_unit_get_count(pcnt_unit, &pulse_count));
电源管理
使能电源管理 (即 CONFIG_PM_ENABLE 开启) 后,在进入 Light-sleep 模式之前,系统会调整 APB 的频率。这会改变 PCNT 毛刺滤波器的参数,从而可能导致有效信号被滤除。
驱动通过获取 ESP_PM_APB_FREQ_MAX
类型的电源管理锁来防止系统修改 APB 频率。每当通过 pcnt_unit_set_glitch_filter()
使能毛刺滤波器时,驱动可以保证系统在 pcnt_unit_enable()
使能 PCNT 单元后获取电源管理锁。而系统调用 pcnt_unit_disable()
之后,驱动会释放电源管理锁。
支持 IRAM 安全中断
当缓存由于写入/擦除 flash 等原因被禁用时,PCNT 中断会默认被延迟。这会导致报警中断无法及时执行,从而无法满足实时性应用的要求。
Konfig 选项 CONFIG_PCNT_ISR_IRAM_SAFE 可以实现以下功能:
即使缓存被禁用也可以使能中断服务
将 ISR 使用的所有函数都放入 IRAM 中 2
将驱动对象放入 DRAM (防止驱动对象被意外映射到 PSRAM 中)
这样,在缓存被禁用时,中断也可运行,但是这也会增加 IRAM 的消耗。
另外一个 Konfig 选项 CONFIG_PCNT_CTRL_FUNC_IN_IRAM 也可以把常用的 IO 控制函数放在 IRAM 中。这样,当缓存禁用时,这些函数仍然可以执行。这些 IO 控制函数如下所示:
支持线程安全
驱动保证工厂函数 pcnt_new_unit()
与 pcnt_new_channel()
是线程安全的,因此您可以从 RTOS 任务中调用这些函数而无需使用额外的电源管理锁。
以下函数可以在 ISR 上下文中运行,驱动可以防止这些函数在任务和 ISR 中同时被调用。
其他以 pcnt_unit_handle_t
和 pcnt_channel_handle_t
作为第一个参数的函数被视为线程不安全函数,在多任务场景下应避免调用这些函数。
支持的 Kconfig 选项
CONFIG_PCNT_CTRL_FUNC_IN_IRAM 用于确定 PCNT 控制函数的位置 (放在 IRAM 还是 flash 中),请参考 支持 IRAM 安全中断 获取更多信息。
CONFIG_PCNT_ISR_IRAM_SAFE 用于控制当缓存禁用时,默认的 ISR 句柄是否可以工作,请参考 支持 IRAM 安全中断 获取更多信息。
CONFIG_PCNT_ENABLE_DEBUG_LOG 用于使能调试日志输出,而这会增大固件二进制文件。
应用实例
对旋转编码器的正交信号进行解码的实例请参考:peripherals/pcnt/rotary_encoder。
API 参考
Header File
Functions
-
esp_err_t pcnt_new_unit(const pcnt_unit_config_t *config, pcnt_unit_handle_t *ret_unit)
Create a new PCNT unit, and return the handle.
备注
The newly created PCNT unit is put in the init state.
- 参数
config – [in] PCNT unit configuration
ret_unit – [out] Returned PCNT unit handle
- 返回
ESP_OK: Create PCNT unit successfully
ESP_ERR_INVALID_ARG: Create PCNT unit failed because of invalid argument (e.g. high/low limit value out of the range)
ESP_ERR_NO_MEM: Create PCNT unit failed because out of memory
ESP_ERR_NOT_FOUND: Create PCNT unit failed because all PCNT units are used up and no more free one
ESP_FAIL: Create PCNT unit failed because of other error
-
esp_err_t pcnt_del_unit(pcnt_unit_handle_t unit)
Delete the PCNT unit handle.
备注
A PCNT unit can’t be in the enable state when this function is invoked. See also
pcnt_unit_disable()
for how to disable a unit.- 参数
unit – [in] PCNT unit handle created by
pcnt_new_unit()
- 返回
ESP_OK: Delete the PCNT unit successfully
ESP_ERR_INVALID_ARG: Delete the PCNT unit failed because of invalid argument
ESP_ERR_INVALID_STATE: Delete the PCNT unit failed because the unit is not in init state or some PCNT channel is still in working
ESP_FAIL: Delete the PCNT unit failed because of other error
-
esp_err_t pcnt_unit_set_glitch_filter(pcnt_unit_handle_t unit, const pcnt_glitch_filter_config_t *config)
Set glitch filter for PCNT unit.
备注
The glitch filter module is clocked from APB, and APB frequency can be changed during DFS, which in return make the filter out of action. So this function will lazy-install a PM lock internally when the power management is enabled. With this lock, the APB frequency won’t be changed. The PM lock can be uninstalled in
pcnt_del_unit()
.备注
This function should be called when the PCNT unit is in the init state (i.e. before calling
pcnt_unit_enable()
)- 参数
unit – [in] PCNT unit handle created by
pcnt_new_unit()
config – [in] PCNT filter configuration, set config to NULL means disabling the filter function
- 返回
ESP_OK: Set glitch filter successfully
ESP_ERR_INVALID_ARG: Set glitch filter failed because of invalid argument (e.g. glitch width is too big)
ESP_ERR_INVALID_STATE: Set glitch filter failed because the unit is not in the init state
ESP_FAIL: Set glitch filter failed because of other error
-
esp_err_t pcnt_unit_enable(pcnt_unit_handle_t unit)
Enable the PCNT unit.
备注
This function will transit the unit state from init to enable.
备注
This function will enable the interrupt service, if it’s lazy installed in
pcnt_unit_register_event_callbacks()
.备注
This function will acquire the PM lock if it’s lazy installed in
pcnt_unit_set_glitch_filter()
.备注
Enable a PCNT unit doesn’t mean to start it. See also
pcnt_unit_start()
for how to start the PCNT counter.- 参数
unit – [in] PCNT unit handle created by
pcnt_new_unit()
- 返回
ESP_OK: Enable PCNT unit successfully
ESP_ERR_INVALID_ARG: Enable PCNT unit failed because of invalid argument
ESP_ERR_INVALID_STATE: Enable PCNT unit failed because the unit is already enabled
ESP_FAIL: Enable PCNT unit failed because of other error
-
esp_err_t pcnt_unit_disable(pcnt_unit_handle_t unit)
Disable the PCNT unit.
备注
This function will do the opposite work to the
pcnt_unit_enable()
备注
Disable a PCNT unit doesn’t mean to stop it. See also
pcnt_unit_stop()
for how to stop the PCNT counter.- 参数
unit – [in] PCNT unit handle created by
pcnt_new_unit()
- 返回
ESP_OK: Disable PCNT unit successfully
ESP_ERR_INVALID_ARG: Disable PCNT unit failed because of invalid argument
ESP_ERR_INVALID_STATE: Disable PCNT unit failed because the unit is not enabled yet
ESP_FAIL: Disable PCNT unit failed because of other error
-
esp_err_t pcnt_unit_start(pcnt_unit_handle_t unit)
Start the PCNT unit, the counter will start to count according to the edge and/or level input signals.
备注
This function should be called when the unit is in the enable state (i.e. after calling
pcnt_unit_enable()
)备注
This function is allowed to run within ISR context
备注
This function will be placed into IRAM if
CONFIG_PCNT_CTRL_FUNC_IN_IRAM
is on, so that it’s allowed to be executed when Cache is disabled- 参数
unit – [in] PCNT unit handle created by
pcnt_new_unit()
- 返回
ESP_OK: Start PCNT unit successfully
ESP_ERR_INVALID_ARG: Start PCNT unit failed because of invalid argument
ESP_ERR_INVALID_STATE: Start PCNT unit failed because the unit is not enabled yet
ESP_FAIL: Start PCNT unit failed because of other error
-
esp_err_t pcnt_unit_stop(pcnt_unit_handle_t unit)
Stop PCNT from counting.
备注
This function should be called when the unit is in the enable state (i.e. after calling
pcnt_unit_enable()
)备注
The stop operation won’t clear the counter. Also see
pcnt_unit_clear_count()
for how to clear pulse count value.备注
This function is allowed to run within ISR context
备注
This function will be placed into IRAM if
CONFIG_PCNT_CTRL_FUNC_IN_IRAM
, so that it is allowed to be executed when Cache is disabled- 参数
unit – [in] PCNT unit handle created by
pcnt_new_unit()
- 返回
ESP_OK: Stop PCNT unit successfully
ESP_ERR_INVALID_ARG: Stop PCNT unit failed because of invalid argument
ESP_ERR_INVALID_STATE: Stop PCNT unit failed because the unit is not enabled yet
ESP_FAIL: Stop PCNT unit failed because of other error
-
esp_err_t pcnt_unit_clear_count(pcnt_unit_handle_t unit)
Clear PCNT pulse count value to zero.
备注
It’s recommended to call this function after adding a watch point by
pcnt_unit_add_watch_point()
, so that the newly added watch point is effective immediately.备注
This function is allowed to run within ISR context
备注
This function will be placed into IRAM if
CONFIG_PCNT_CTRL_FUNC_IN_IRAM
, so that it’s allowed to be executed when Cache is disabled- 参数
unit – [in] PCNT unit handle created by
pcnt_new_unit()
- 返回
ESP_OK: Clear PCNT pulse count successfully
ESP_ERR_INVALID_ARG: Clear PCNT pulse count failed because of invalid argument
ESP_FAIL: Clear PCNT pulse count failed because of other error
-
esp_err_t pcnt_unit_get_count(pcnt_unit_handle_t unit, int *value)
Get PCNT count value.
备注
This function is allowed to run within ISR context
备注
This function will be placed into IRAM if
CONFIG_PCNT_CTRL_FUNC_IN_IRAM
, so that it’s allowed to be executed when Cache is disabled- 参数
unit – [in] PCNT unit handle created by
pcnt_new_unit()
value – [out] Returned count value
- 返回
ESP_OK: Get PCNT pulse count successfully
ESP_ERR_INVALID_ARG: Get PCNT pulse count failed because of invalid argument
ESP_FAIL: Get PCNT pulse count failed because of other error
-
esp_err_t pcnt_unit_register_event_callbacks(pcnt_unit_handle_t unit, const pcnt_event_callbacks_t *cbs, void *user_data)
Set event callbacks for PCNT unit.
备注
User registered callbacks are expected to be runnable within ISR context
备注
The first call to this function needs to be before the call to
pcnt_unit_enable
备注
User can deregister a previously registered callback by calling this function and setting the callback member in the
cbs
structure to NULL.- 参数
unit – [in] PCNT unit handle created by
pcnt_new_unit()
cbs – [in] Group of callback functions
user_data – [in] User data, which will be passed to callback functions directly
- 返回
ESP_OK: Set event callbacks successfully
ESP_ERR_INVALID_ARG: Set event callbacks failed because of invalid argument
ESP_ERR_INVALID_STATE: Set event callbacks failed because the unit is not in init state
ESP_FAIL: Set event callbacks failed because of other error
-
esp_err_t pcnt_unit_add_watch_point(pcnt_unit_handle_t unit, int watch_point)
Add a watch point for PCNT unit, PCNT will generate an event when the counter value reaches the watch point value.
- 参数
unit – [in] PCNT unit handle created by
pcnt_new_unit()
watch_point – [in] Value to be watched
- 返回
ESP_OK: Add watch point successfully
ESP_ERR_INVALID_ARG: Add watch point failed because of invalid argument (e.g. the value to be watched is out of the limitation set in
pcnt_unit_config_t
)ESP_ERR_INVALID_STATE: Add watch point failed because the same watch point has already been added
ESP_ERR_NOT_FOUND: Add watch point failed because no more hardware watch point can be configured
ESP_FAIL: Add watch point failed because of other error
-
esp_err_t pcnt_unit_remove_watch_point(pcnt_unit_handle_t unit, int watch_point)
Remove a watch point for PCNT unit.
- 参数
unit – [in] PCNT unit handle created by
pcnt_new_unit()
watch_point – [in] Watch point value
- 返回
ESP_OK: Remove watch point successfully
ESP_ERR_INVALID_ARG: Remove watch point failed because of invalid argument
ESP_ERR_INVALID_STATE: Remove watch point failed because the watch point was not added by
pcnt_unit_add_watch_point()
yetESP_FAIL: Remove watch point failed because of other error
-
esp_err_t pcnt_new_channel(pcnt_unit_handle_t unit, const pcnt_chan_config_t *config, pcnt_channel_handle_t *ret_chan)
Create PCNT channel for specific unit, each PCNT has several channels associated with it.
备注
This function should be called when the unit is in init state (i.e. before calling
pcnt_unit_enable()
)- 参数
unit – [in] PCNT unit handle created by
pcnt_new_unit()
config – [in] PCNT channel configuration
ret_chan – [out] Returned channel handle
- 返回
ESP_OK: Create PCNT channel successfully
ESP_ERR_INVALID_ARG: Create PCNT channel failed because of invalid argument
ESP_ERR_NO_MEM: Create PCNT channel failed because of insufficient memory
ESP_ERR_NOT_FOUND: Create PCNT channel failed because all PCNT channels are used up and no more free one
ESP_ERR_INVALID_STATE: Create PCNT channel failed because the unit is not in the init state
ESP_FAIL: Create PCNT channel failed because of other error
-
esp_err_t pcnt_del_channel(pcnt_channel_handle_t chan)
Delete the PCNT channel.
- 参数
chan – [in] PCNT channel handle created by
pcnt_new_channel()
- 返回
ESP_OK: Delete the PCNT channel successfully
ESP_ERR_INVALID_ARG: Delete the PCNT channel failed because of invalid argument
ESP_FAIL: Delete the PCNT channel failed because of other error
-
esp_err_t pcnt_channel_set_edge_action(pcnt_channel_handle_t chan, pcnt_channel_edge_action_t pos_act, pcnt_channel_edge_action_t neg_act)
Set channel actions when edge signal changes (e.g. falling or rising edge occurred). The edge signal is input from the
edge_gpio_num
configured inpcnt_chan_config_t
. We use these actions to control when and how to change the counter value.- 参数
chan – [in] PCNT channel handle created by
pcnt_new_channel()
pos_act – [in] Action on posedge signal
neg_act – [in] Action on negedge signal
- 返回
ESP_OK: Set edge action for PCNT channel successfully
ESP_ERR_INVALID_ARG: Set edge action for PCNT channel failed because of invalid argument
ESP_FAIL: Set edge action for PCNT channel failed because of other error
-
esp_err_t pcnt_channel_set_level_action(pcnt_channel_handle_t chan, pcnt_channel_level_action_t high_act, pcnt_channel_level_action_t low_act)
Set channel actions when level signal changes (e.g. signal level goes from high to low). The level signal is input from the
level_gpio_num
configured inpcnt_chan_config_t
. We use these actions to control when and how to change the counting mode.- 参数
chan – [in] PCNT channel handle created by
pcnt_new_channel()
high_act – [in] Action on high level signal
low_act – [in] Action on low level signal
- 返回
ESP_OK: Set level action for PCNT channel successfully
ESP_ERR_INVALID_ARG: Set level action for PCNT channel failed because of invalid argument
ESP_FAIL: Set level action for PCNT channel failed because of other error
Structures
-
struct pcnt_watch_event_data_t
PCNT watch event data.
Public Members
-
int watch_point_value
Watch point value that triggered the event
-
pcnt_unit_zero_cross_mode_t zero_cross_mode
Zero cross mode
-
int watch_point_value
-
struct pcnt_event_callbacks_t
Group of supported PCNT callbacks.
备注
The callbacks are all running under ISR environment
备注
When CONFIG_PCNT_ISR_IRAM_SAFE is enabled, the callback itself and functions callbed by it should be placed in IRAM.
Public Members
-
pcnt_watch_cb_t on_reach
Called when PCNT unit counter reaches any watch point
-
pcnt_watch_cb_t on_reach
-
struct pcnt_unit_config_t
PCNT unit configuration.
-
struct pcnt_chan_config_t
PCNT channel configuration.
Public Members
-
int edge_gpio_num
GPIO number used by the edge signal, input mode with pull up enabled. Set to -1 if unused
-
int level_gpio_num
GPIO number used by the level signal, input mode with pull up enabled. Set to -1 if unused
-
uint32_t invert_edge_input
Invert the input edge signal
-
uint32_t invert_level_input
Invert the input level signal
-
uint32_t virt_edge_io_level
Virtual edge IO level, 0: low, 1: high. Only valid when edge_gpio_num is set to -1
-
uint32_t virt_level_io_level
Virtual level IO level, 0: low, 1: high. Only valid when level_gpio_num is set to -1
-
uint32_t io_loop_back
For debug/test, the signal output from the GPIO will be fed to the input path as well
-
struct pcnt_chan_config_t::[anonymous] flags
Channel config flags
-
int edge_gpio_num
Type Definitions
-
typedef struct pcnt_unit_t *pcnt_unit_handle_t
Type of PCNT unit handle.
-
typedef struct pcnt_chan_t *pcnt_channel_handle_t
Type of PCNT channel handle.
-
typedef bool (*pcnt_watch_cb_t)(pcnt_unit_handle_t unit, const pcnt_watch_event_data_t *edata, void *user_ctx)
PCNT watch event callback prototype.
备注
The callback function is invoked from an ISR context, so it should meet the restrictions of not calling any blocking APIs when implementing the callback. e.g. must use ISR version of FreeRTOS APIs.
- Param unit
[in] PCNT unit handle
- Param edata
[in] PCNT event data, fed by the driver
- Param user_ctx
[in] User data, passed from
pcnt_unit_register_event_callbacks()
- Return
Whether a high priority task has been woken up by this function
Header File
Enumerations
-
enum pcnt_channel_level_action_t
PCNT channel action on control level.
Values:
-
enumerator PCNT_CHANNEL_LEVEL_ACTION_KEEP
Keep current count mode
-
enumerator PCNT_CHANNEL_LEVEL_ACTION_INVERSE
Invert current count mode (increase -> decrease, decrease -> increase)
-
enumerator PCNT_CHANNEL_LEVEL_ACTION_HOLD
Hold current count value
-
enumerator PCNT_CHANNEL_LEVEL_ACTION_KEEP
-
enum pcnt_channel_edge_action_t
PCNT channel action on signal edge.
Values:
-
enumerator PCNT_CHANNEL_EDGE_ACTION_HOLD
Hold current count value
-
enumerator PCNT_CHANNEL_EDGE_ACTION_INCREASE
Increase count value
-
enumerator PCNT_CHANNEL_EDGE_ACTION_DECREASE
Decrease count value
-
enumerator PCNT_CHANNEL_EDGE_ACTION_HOLD
-
enum pcnt_unit_zero_cross_mode_t
PCNT unit zero cross mode.
Values:
-
enumerator PCNT_UNIT_ZERO_CROSS_POS_ZERO
start from positive value, end to zero, i.e. +N->0
-
enumerator PCNT_UNIT_ZERO_CROSS_NEG_ZERO
start from negative value, end to zero, i.e. -N->0
-
enumerator PCNT_UNIT_ZERO_CROSS_NEG_POS
start from negative value, end to positive value, i.e. -N->+M
-
enumerator PCNT_UNIT_ZERO_CROSS_POS_NEG
start from positive value, end to negative value, i.e. +N->-M
-
enumerator PCNT_UNIT_ZERO_CROSS_POS_ZERO
- 1
在不同的 ESP 芯片系列中,PCNT 单元和通道的数量可能会有差异,具体信息请参考 [TRM]。驱动不会禁止用户申请更多的 PCNT 单元和通道,但是当单元和通道资源全部被占用时,再调用单元和通道会返回错误。因此分配资源时,应注意检查返回值,如
pcnt_new_unit()
。- 2
pcnt_event_callbacks_t::on_reach
回调函数和其调用的函数也应该放在 IRAM 中。