faf6cc4f84
This commit implements a workaround that allows ESP32-C5 to run at 240MHz CPU frequency normally, while automatically reducing CPU frequency during encrypted flash writes to ensure correct operation. The frequency limit is chip revision dependent: - v1.2 and above: limited to 160MHz during encrypted writes - v1.0 and below: limited to 80MHz during encrypted writes Key implementation details: - Frequency limiting is triggered automatically when esp_flash_write_encrypted() is called - Uses start() flags (ESP_FLASH_START_FLAG_LIMIT_CPU_FREQ) to integrate with OS layer - Works with both PM enabled and disabled configurations - Frequency is automatically restored after encrypted write completes - For ESP32-C5 with 120MHz flash, Flash clock and timing registers are adjusted when CPU frequency is reduced to 80MHz - SPI1 timing registers are configured during frequency switching since encrypted writes use SPI1 and must work correctly at reduced CPU frequencies Code improvements: - Use SOC_MSPI_FREQ_AXI_CONSTRAINED capability macro instead of hardcoded chip checks - Control workaround via Kconfig (CONFIG_PM_WORKAROUND_FREQ_LIMIT_ENABLED) instead of hardcoded macros - Add comprehensive test cases covering various PM configurations and edge cases This workaround enables ESP32-C5 applications to benefit from 240MHz CPU performance while maintaining reliable encrypted flash write functionality.
esp_hw_support (G1 component)
This component contains hardware-related operations for supporting the system. These operations are one level above that of hal in that:
- it uses system services such as memory allocation, logging, scheduling
- it may be multi-step operations involving/affecting multiple parts of the SoC
- it offers a service for other components vary from multiple layers (G1, G2 and G3) of ESP-IDF
Implementations that don't fit other components cleanly, but are not worth creating a new component for (yet) may also be placed here as long as they don't pull dependencies other than the core system components.
Event-Task Service (esp_etm)
esp_etm driver design
esp_etm driver is divided into two parts:
- The core driver, which focuses on ETM channel allocation and offers APIs to connect the channel with ETM tasks and ETM events that come from other peripherals.
- Peripheral side extensions, e.g. GPTimer support generating different kinds of ETM events, and accept multiple ETM tasks. These extensions are implemented in the peripheral driver, and can be located in different components. Usually, the task and event extensions will simply inherit the interface that defined in the core driver.
See the following class diagram, we take the GPIO and GPTimer as the example to illustrate the architecture of esp_etm driver.
classDiagram
esp_etm_channel_t "1" --> "1" esp_etm_event_t : Has
esp_etm_channel_t "1" --> "1" esp_etm_task_t : Has
class esp_etm_channel_t {
-int chan_id
-esp_etm_event_t event
-esp_etm_task_t task
+enable() esp_err_t
+disable() esp_err_t
+connect(event, task) esp_err_t
+dump() esp_err_t
}
class esp_etm_event_t {
<<interface>>
#int event_id
#etm_trigger_peripheral_t trig_periph
#del() esp_err_t
}
class esp_etm_task_t {
<<interface>>
#int task_id
#etm_trigger_peripheral_t trig_periph
#del() esp_err_t
}
gpio_etm_event_t --|> esp_etm_event_t : Inheritance
class gpio_etm_event_t {
-int chan_id
+bind_gpio(gpio_num_t gpio) esp_err_t
}
gpio_etm_task_t --|> esp_etm_task_t : Inheritance
class gpio_etm_task_t {
-int chan_id
+add_gpio(gpio_num) esp_err_t
+rm_gpio(gpio_num) esp_err_t
}
gptimer_t "1" --> "1..*" gptimer_etm_event_t : Has
gptimer_t "1" --> "1..*" gptimer_etm_task_t : Has
class gptimer_t {
-gptimer_etm_event_t[] events
-gptimer_etm_task_t[] tasks
}
gptimer_etm_event_t --|> esp_etm_event_t : Inheritance
class gptimer_etm_event_t {
}
gptimer_etm_task_t --|> esp_etm_task_t : Inheritance
class gptimer_etm_task_t {
}
DMA Service
With the increasing demand, the hardware design of DMA is changing along the way. At first, each peripheral has a dedicated DMA controller. Later, a centralized DMA controller is introduced, which is called GDMA in the software.
There may be multiple GDMA instances on a chip, some is attached to the AHB bus and some is attached to the AXI bus. But their functionalities are almost the same.
Some high-performance peripherals, such as MIPI, require DMA to provide more functions, such as hardware handshake mechanism, address growth mode, out-of-order transmission and so on. Therefore, a new DMA controller, called DW_GDMA was born. The prefix DW is taken from DesignWare.
Please note that the specific DMA controller to be used for peripherals is determined by the specific chip. It is possible that, on chip A, SPI works with AHB GDMA, while on chip B, SPI works with AXI GDMA.