Merge branch 'fix/fix_esp32p4_freq_switching_timing' into 'master'

fix(esp_hw_support): fix esp32p4 CPU frequency switching timing

Closes IDFCI-2280 and IDFCI-2281

See merge request espressif/esp-idf!33823
This commit is contained in:
Wu Zheng Hui 2024-09-27 19:13:12 +08:00
commit 041a937803

View File

@ -14,7 +14,6 @@
#include "soc/rtc.h"
#include "esp_private/rtc_clk.h"
#include "esp_attr.h"
#include "esp_cpu.h"
#include "esp_hw_log.h"
#include "esp_rom_sys.h"
#include "hal/clk_tree_ll.h"
@ -183,13 +182,7 @@ static void rtc_clk_cpu_freq_to_xtal(int cpu_freq, int div, bool to_default)
clk_ll_mem_set_divider(mem_divider);
clk_ll_sys_set_divider(sys_divider);
clk_ll_apb_set_divider(apb_divider);
#if (!defined(BOOTLOADER_BUILD) && (CONFIG_FREERTOS_NUMBER_OF_CORES == 2))
esp_cpu_stall(1 - esp_cpu_get_core_id());
#endif
clk_ll_bus_update();
#if (!defined(BOOTLOADER_BUILD) && (CONFIG_FREERTOS_NUMBER_OF_CORES == 2))
esp_cpu_unstall(1 - esp_cpu_get_core_id());
#endif
esp_rom_set_cpu_ticks_per_us(cpu_freq);
}
@ -201,13 +194,7 @@ static void rtc_clk_cpu_freq_to_8m(void)
clk_ll_sys_set_divider(1);
clk_ll_apb_set_divider(1);
clk_ll_cpu_set_src(SOC_CPU_CLK_SRC_RC_FAST);
#if (!defined(BOOTLOADER_BUILD) && (CONFIG_FREERTOS_NUMBER_OF_CORES == 2))
esp_cpu_stall(1 - esp_cpu_get_core_id());
#endif
clk_ll_bus_update();
#if (!defined(BOOTLOADER_BUILD) && (CONFIG_FREERTOS_NUMBER_OF_CORES == 2))
esp_cpu_unstall(1 - esp_cpu_get_core_id());
#endif
esp_rom_set_cpu_ticks_per_us(20);
}
@ -218,15 +205,18 @@ static void rtc_clk_cpu_freq_to_8m(void)
*/
static void rtc_clk_cpu_freq_to_cpll_mhz(int cpu_freq_mhz, hal_utils_clk_div_t *div)
{
// CPLL -> CPU_CLK -> MEM_CLK -> SYS_CLK -> APB_CLK
// Constraint: MEM_CLK <= 200MHz, APB_CLK <= 100MHz
// This implies that when clock source is CPLL,
// If cpu_divider < 2, mem_divider must be larger or equal to 2
// If cpu_divider < 2, mem_divider = 2, sys_divider < 2, apb_divider must be larger or equal to 2
// Current available configurations:
// 360 - 360 - 180 - 180 - 90
// 360 - 180 - 180 - 180 - 90
// 360 - 90 - 90 - 90 - 90
/**
* Constraint: MEM_CLK <= 200MHz, APB_CLK <= 100MHz
* This implies that when clock source is CPLL,
* If cpu_divider < 2, mem_divider must be larger or equal to 2
* If cpu_divider < 2, mem_divider = 2, sys_divider < 2, apb_divider must be larger or equal to 2
*
* Current available configurations:
* CPLL -> CPU_CLK -> MEM_CLK -> SYS_CLK -> APB_CLK
* 360 div1 360 div2 180 div1 180 div2 90
* 360 div2 180 div1 180 div1 180 div2 90
* 360 div4 90 div1 90 div1 90 div1 90
*/
uint32_t mem_divider = 1;
uint32_t sys_divider = 1; // We are not going to change this
uint32_t apb_divider = 1;
@ -250,25 +240,39 @@ static void rtc_clk_cpu_freq_to_cpll_mhz(int cpu_freq_mhz, hal_utils_clk_div_t *
// To avoid such case, we will strictly do abort here.
abort();
}
// Update bit does not control CPU clock sel mux. Therefore, there may be a middle state during the switch (CPU rises)
// Since this is upscaling, we need to configure the frequency division coefficient before switching the clock source.
// Otherwise, an intermediate state will occur, in the intermediate state, the frequency of APB/MEM does not meet the
// timing requirements. If there are periperals access that depend on these two clocks at this moment, some exception
// might occur.
clk_ll_cpu_set_divider(div->integer, div->numerator, div->denominator);
clk_ll_mem_set_divider(mem_divider);
clk_ll_sys_set_divider(sys_divider);
// If it's upscaling, the divider of MEM/SYS/APB needs to be increased, to avoid illegal intermediate states,
// the clock divider should be updated in the order from the APB_CLK to CPU_CLK.
// And if it's downscaling, the divider of MEM/SYS/APB needs to be decreased, the clock divider should be updated
// in the order from the CPU_CLK to APB_CLK.
// Otherwise, an intermediate state will occur, in the intermediate state, the frequency of APB/MEM does not meet
// the timing requirements. If there are periperals/CPU access that depend on these two clocks at this moment, some
// exception might occur.
if (cpu_freq_mhz >= esp_rom_get_cpu_ticks_per_us()) {
// Frequency Upscaling
clk_ll_apb_set_divider(apb_divider);
#if (!defined(BOOTLOADER_BUILD) && (CONFIG_FREERTOS_NUMBER_OF_CORES == 2))
// During frequency switching, non-frequency switching cores may have ongoing memory accesses, which may cause access
// failures, stalling non-frequency switching cores here can avoid such failures.
esp_cpu_stall(1 - esp_cpu_get_core_id());
#endif
clk_ll_bus_update();
clk_ll_sys_set_divider(sys_divider);
clk_ll_bus_update();
clk_ll_mem_set_divider(mem_divider);
clk_ll_bus_update();
clk_ll_cpu_set_divider(div->integer, div->numerator, div->denominator);
clk_ll_bus_update();
} else {
// Frequency Downscaling
clk_ll_cpu_set_divider(div->integer, div->numerator, div->denominator);
clk_ll_bus_update();
clk_ll_mem_set_divider(mem_divider);
clk_ll_bus_update();
clk_ll_sys_set_divider(sys_divider);
clk_ll_bus_update();
clk_ll_apb_set_divider(apb_divider);
clk_ll_bus_update();
}
// Update bit does not control CPU clock sel mux, the clock source needs to be switched at
// last to avoid intermediate states.
clk_ll_cpu_set_src(SOC_CPU_CLK_SRC_PLL);
#if (!defined(BOOTLOADER_BUILD) && (CONFIG_FREERTOS_NUMBER_OF_CORES == 2))
esp_cpu_unstall(1 - esp_cpu_get_core_id());
#endif
esp_rom_set_cpu_ticks_per_us(cpu_freq_mhz);
}