kopia lustrzana https://github.com/espressif/esp-idf
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12 KiB
ReStructuredText
190 wiersze
12 KiB
ReStructuredText
ULP Coprocessor programming
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=============================
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:link_to_translation:`zh_CN:[中文]`
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The Ultra Low Power (ULP) coprocessor is a simple finite state machine (FSM) which is designed to perform measurements using the ADC, temperature sensor, and external I2C sensors, while the main processors are in deep sleep mode. The ULP coprocessor can access the RTC_SLOW_MEM memory region, and registers in the RTC_CNTL, RTC_IO, and SARADC peripherals. The ULP coprocessor uses fixed-width 32-bit instructions, 32-bit memory addressing, and has 4 general-purpose 16-bit registers. This coprocessor is referred to as `ULP FSM` in ESP-IDF.
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.. only:: esp32s2 or esp32s3
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{IDF_TARGET_NAME} provides a second type of ULP coprocessor which is based on a RISC-V instruction set architecture. For details regarding `ULP RISC-V` refer :doc:`ULP-RISC-V Coprocessor <./ulp-risc-v>`.
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Installing the Toolchain
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------------------------
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The ULP FSM coprocessor code is written in assembly and compiled using the `binutils-esp32ulp toolchain`_.
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If you have already set up ESP-IDF with CMake build system according to the :doc:`Getting Started Guide <../../get-started/index>`, then the ULP FSM toolchain will already be installed.
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.. only:: esp32
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If you are using ESP-IDF with the legacy GNU Make based build system, refer to the instructions on this page: :doc:`ulp-legacy`.
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Programming ULP FSM
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-------------------
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The ULP FSM can be programmed using the supported instruction set. Alternatively, the ULP FSM coprocessor can also be programmed using C Macros on the main CPU. Theses two methods are described in the following section:
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.. toctree::
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:maxdepth: 1
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Instruction set reference for {IDF_TARGET_NAME} ULP <ulp_instruction_set>
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Programming using macros (legacy) <ulp_macros>
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Compiling the ULP Code
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-----------------------
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To compile the ULP FSM code as part of the component, the following steps must be taken:
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1. The ULP FSM code, written in assembly, must be added to one or more files with `.S` extension. These files must be placed into a separate directory inside the component directory, for instance, `ulp/`.
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.. note: When registering the component (via ``idf_component_register``), this directory should not be added to the ``SRC_DIRS`` argument. The logic behind this is that the ESP-IDF build system will compile files found in ``SRC_DIRS`` based on their extensions. For ``.S`` files, ``{IDF_TARGET_TOOLCHAIN_PREFIX}-as`` assembler is used. This is not desirable for ULP FSM assembly files, so the easiest way to achieve the distinction is by placing ULP FSM assembly files into a separate directory. The ULP FSM assembly source files should also **not** be added to ``SRCS`` for the same reason. See the step below for how to properly add ULP FSM assembly source files.
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2. Call ``ulp_embed_binary`` from the component CMakeLists.txt after registration. For example::
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...
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idf_component_register()
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set(ulp_app_name ulp_${COMPONENT_NAME})
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set(ulp_s_sources ulp/ulp_assembly_source_file.S)
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set(ulp_exp_dep_srcs "ulp_c_source_file.c")
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ulp_embed_binary(${ulp_app_name} "${ulp_s_sources}" "${ulp_exp_dep_srcs}")
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The first argument to ``ulp_embed_binary`` specifies the ULP FSM binary name. The name specified here will also be used by other generated artifacts such as the ELF file, map file, header file and linker export file. The second argument specifies the ULP FSM assembly source files. Finally, the third argument specifies the list of component source files which include the header file to be generated. This list is needed to build the dependencies correctly and ensure that the generated header file will be created before any of these files are compiled. See the section below for the concept of generated header files for ULP applications.
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3. Build the application as usual (e.g. `idf.py app`).
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Inside, the build system will take the following steps to build ULP FSM program:
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1. **Run each assembly file (foo.S) through the C preprocessor.** This step generates the preprocessed assembly files (foo.ulp.S) in the component build directory. This step also generates dependency files (foo.ulp.d).
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2. **Run preprocessed assembly sources through the assembler.** This produces object (foo.ulp.o) and listing (foo.ulp.lst) files. Listing files are generated for debugging purposes and are not used at later stages of the build process.
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3. **Run the linker script template through the C preprocessor.** The template is located in ``components/ulp/ld`` directory.
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4. **Link the object files into an output ELF file** (``ulp_app_name.elf``). The Map file (``ulp_app_name.map``) generated at this stage may be useful for debugging purposes.
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5. **Dump the contents of the ELF file into a binary** (``ulp_app_name.bin``) which can then be embedded into the application.
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6. **Generate a list of global symbols** (``ulp_app_name.sym``) in the ELF file using ``esp32ulp-elf-nm``.
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7. **Create an LD export script and a header file** (``ulp_app_name.ld`` and ``ulp_app_name.h``) containing the symbols from ``ulp_app_name.sym``. This is done using the ``esp32ulp_mapgen.py`` utility.
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8. **Add the generated binary to the list of binary files** to be embedded into the application.
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Accessing the ULP FSM Program Variables
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---------------------------------------
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Global symbols defined in the ULP FSM program may be used inside the main program.
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For example, the ULP FSM program may define a variable ``measurement_count`` which will define the number of ADC measurements the program needs to make before waking up the chip from deep sleep::
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.global measurement_count
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measurement_count: .long 0
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// later, use measurement_count
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move r3, measurement_count
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ld r3, r3, 0
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The main program needs to initialize this variable before the ULP program is started. The build system makes this possible by generating the ``${ULP_APP_NAME}.h`` and ``${ULP_APP_NAME}.ld`` files which define the global symbols present in the ULP program. Each global symbol defined in the ULP program is included in these files and are prefixed with ``ulp_``.
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The header file contains the declaration of the symbol::
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extern uint32_t ulp_measurement_count;
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Note that all symbols (variables, arrays, functions) are declared as ``uint32_t``. For functions and arrays, take the address of the symbol and cast it to the appropriate type.
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The generated linker script file defines the locations of symbols in RTC_SLOW_MEM::
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PROVIDE ( ulp_measurement_count = 0x50000060 );
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To access the ULP program variables from the main program, the generated header file should be included using an ``include`` statement. This will allow the ULP program variables to be accessed as regular variables::
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#include "ulp_app_name.h"
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// later
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void init_ulp_vars() {
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ulp_measurement_count = 64;
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}
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.. only:: esp32
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Note that the ULP FSM program can only use the lower 16 bits of each 32-bit word in RTC memory, because the registers are 16-bit, and there is no instruction to load from the high part of the word. Likewise, the ULP store instruction writes register values into the lower 16 bits of the 32-bit word in RTC memory. The upper 16 bits are written with a value which depends on the address of the store instruction, thus when reading variables written by the ULP coprocessor, the main application needs to mask the upper 16 bits, e.g.::
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printf("Last measurement value: %d\n", ulp_last_measurement & UINT16_MAX);
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Starting the ULP FSM Program
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----------------------------
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To run a ULP FSM program, the main application needs to load the ULP program into RTC memory using the :cpp:func:`ulp_load_binary` function, and then start it using the :cpp:func:`ulp_run` function.
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Note that the ``Enable Ultra Low Power (ULP) Coprocessor`` option must be enabled in menuconfig to work with ULP. To select the type of ULP to be used, the ``ULP Co-processor type`` option must be set. To reserve memory for the ULP, the ``RTC slow memory reserved for coprocessor`` option must be set to a value big enough to store ULP code and data. If the application components contain multiple ULP programs, then the size of the RTC memory must be sufficient to hold the largest one.
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Each ULP program is embedded into the ESP-IDF application as a binary blob. The application can reference this blob and load it in the following way (suppose ULP_APP_NAME was defined to ``ulp_app_name``)::
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extern const uint8_t bin_start[] asm("_binary_ulp_app_name_bin_start");
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extern const uint8_t bin_end[] asm("_binary_ulp_app_name_bin_end");
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void start_ulp_program() {
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ESP_ERROR_CHECK( ulp_load_binary(
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0 // load address, set to 0 when using default linker scripts
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bin_start,
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(bin_end - bin_start) / sizeof(uint32_t)) );
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}
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Once the program is loaded into RTC memory, the application can start it by passing the address of the entry point to the ``ulp_run`` function::
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ESP_ERROR_CHECK( ulp_run(&ulp_entry - RTC_SLOW_MEM) );
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Declaration of the entry point symbol comes from the generated header file mentioned above, ``${ULP_APP_NAME}.h``. In the assembly source of the ULP FSM application, this symbol must be marked as ``.global``::
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.global entry
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entry:
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// code starts here
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.. only:: esp32
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ESP32 ULP program flow
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-----------------------
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ESP32 ULP coprocessor is started by a timer. The timer is started once :cpp:func:`ulp_run` is called. The timer counts a number of RTC_SLOW_CLK ticks (by default, produced by an internal 150 kHz RC oscillator). The number of ticks is set using ``SENS_ULP_CP_SLEEP_CYCx_REG`` registers (x = 0..4). When starting the ULP for the first time, ``SENS_ULP_CP_SLEEP_CYC0_REG`` will be used to set the number of timer ticks. Later the ULP program can select another ``SENS_ULP_CP_SLEEP_CYCx_REG`` register using ``sleep`` instruction.
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The application can set ULP timer period values (SENS_ULP_CP_SLEEP_CYCx_REG, x = 0..4) using ``ulp_set_wakeup_period`` function.
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Once the timer counts the number of ticks set in the selected ``SENS_ULP_CP_SLEEP_CYCx_REG`` register, ULP coprocessor powers up and starts running the program from the entry point set in the call to :cpp:func:`ulp_run`.
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The program runs until it encounters a ``halt`` instruction or an illegal instruction. Once the program halts the ULP coprocessor powers down and the timer is started again.
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To disable the timer (effectively preventing the ULP program from running again), clear the ``RTC_CNTL_ULP_CP_SLP_TIMER_EN`` bit in the ``RTC_CNTL_STATE0_REG`` register. This can be done both from ULP code and from the main program.
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.. only:: esp32s2 or esp32s3
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{IDF_TARGET_NAME} ULP program flow
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----------------------------------
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{IDF_TARGET_NAME} ULP coprocessor is started by a timer. The timer is started once :cpp:func:`ulp_run` is called. The timer counts a number of RTC_SLOW_CLK ticks (by default, produced by an internal 90 kHz RC oscillator). The number of ticks is set using ``RTC_CNTL_ULP_CP_TIMER_1_REG`` register.
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The application can set ULP timer period values by :cpp:func:`ulp_set_wakeup_period` function.
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Once the timer counts the number of ticks set in the selected ``RTC_CNTL_ULP_CP_TIMER_1_REG`` register, ULP coprocessor powers up and starts running the program from the entry point set in the call to :cpp:func:`ulp_run`.
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The program runs until it encounters a ``halt`` instruction or an illegal instruction. Once the program halts, ULP coprocessor powers down, and the timer is started again.
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To disable the timer (effectively preventing the ULP program from running again), clear the ``RTC_CNTL_ULP_CP_SLP_TIMER_EN`` bit in the ``RTC_CNTL_ULP_CP_TIMER_REG`` register. This can be done both from ULP code and from the main program.
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Application Examples
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--------------------
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* ULP FSM Coprocessor counts pulses on an IO while main CPU is in deep sleep: :example:`system/ulp_fsm/ulp`.
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* ULP FSM Coprocessor polls ADC in while main CPU is in deep sleep: :example:`system/ulp_fsm/ulp_adc`.
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API Reference
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-------------
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.. include-build-file:: inc/ulp_common.inc
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.. _binutils-esp32ulp toolchain: https://github.com/espressif/binutils-gdb
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