/**************************************************************************//** * * @copyright (C) 2020 Nuvoton Technology Corp. All rights reserved. * * SPDX-License-Identifier: Apache-2.0 * * Change Logs: * Date Author Notes * 2020-12-1 Wayne First version * ******************************************************************************/ #include #if defined(BSP_USING_PWM) #define LOG_TAG "drv.pwm" #define DBG_ENABLE #define DBG_SECTION_NAME "drv.pwm" #define DBG_LEVEL DBG_INFO #define DBG_COLOR #include #include #include #include #include "NuMicro.h" #include "drv_sys.h" enum { PWM_START = -1, #if defined(BSP_USING_PWM0) PWM0_IDX, #endif #if defined(BSP_USING_PWM1) PWM1_IDX, #endif PWM_CNT }; #define NU_PWM_BA_DISTANCE (PWM1_BA - PWM0_BA) #define NU_PWM_CHANNEL_NUM 4 struct nu_pwm { struct rt_device_pwm dev; char *name; uint32_t base_addr; E_SYS_IPRST rstidx; E_SYS_IPCLK clkidx; }; typedef struct nu_pwm *nu_pwm_t; static struct nu_pwm nu_pwm_arr [] = { #if defined(BSP_USING_PWM0) { .name = "pwm0", .base_addr = PWM0_BA, .rstidx = PWM0RST, .clkidx = PWM0CKEN, }, #endif #if defined(BSP_USING_PWM1) { .name = "pwm1", .base_addr = PWM1_BA, .rstidx = PWM1RST, .clkidx = PWM1CKEN, }, #endif }; /* pwm nu_pwm */ static rt_err_t nu_pwm_control(struct rt_device_pwm *device, int cmd, void *arg); static struct rt_pwm_ops nu_pwm_ops = { .control = nu_pwm_control }; static rt_err_t nu_pwm_enable(struct rt_device_pwm *device, struct rt_pwm_configuration *config, rt_bool_t enable) { nu_pwm_t psNuPWM = (nu_pwm_t)device; rt_err_t result = RT_EOK; rt_uint32_t ch = config->channel; if (enable == RT_TRUE) { uint32_t u32RegAdrrPCR = psNuPWM->base_addr + 0x8; uint32_t u32PCRChAlign = (!ch) ? 0x9 : (0x9 << (4 + ch * 4)); /* Period and enable channel. */ outpw(u32RegAdrrPCR, inpw(u32RegAdrrPCR) | u32PCRChAlign); } else { uint32_t u32RegAdrrPCR = psNuPWM->base_addr + 0x8; uint32_t u32PCRChAlign = (!ch) ? 0x1 : (0x1 << (4 + ch * 4)); outpw(u32RegAdrrPCR, inpw(u32RegAdrrPCR) & ~u32PCRChAlign); } return result; } static rt_err_t nu_pwm_get(struct rt_device_pwm *device, struct rt_pwm_configuration *config) { nu_pwm_t psNuPWM = (nu_pwm_t)device; uint32_t u32RegAdrrPPR = psNuPWM->base_addr; uint32_t u32RegAdrrCSR = psNuPWM->base_addr + 0x04; uint32_t u32RegAdrrCNR = psNuPWM->base_addr + 0xC + (config->channel * 0xC); uint32_t u32RegAdrrCMR = psNuPWM->base_addr + 0x10 + (config->channel * 0xC); uint32_t u32PWMSrcClk = sysGetClock(SYS_PCLK2) * 1000000; uint32_t u32CMR, u32CNR; double douDutyCycle; /* unit:% */ uint32_t u32PWMOutClk; /* unit:Hz */ uint32_t u32Prescale, u32Divider; u32CNR = inpw(u32RegAdrrCNR) + 1; u32CMR = inpw(u32RegAdrrCMR) + 1; u32Prescale = ((inpw(u32RegAdrrPPR) & (0xff << ((config->channel >> 1) * 8))) >> ((config->channel >> 1) * 8)) + 1; u32Divider = (inpw(u32RegAdrrCSR) & (0x7 << (4 * config->channel))) >> (4 * config->channel); /* Re-convert register to real value */ if (u32Divider == 4) u32Divider = 1; else if (u32Divider == 0) u32Divider = 2; else if (u32Divider == 1) u32Divider = 4; else if (u32Divider == 2) u32Divider = 8; else // 3 u32Divider = 16; douDutyCycle = (double)u32CMR / u32CNR; u32PWMOutClk = u32PWMSrcClk / (u32Prescale * u32Divider * u32CNR); config->period = 1000000000 / u32PWMOutClk; /* In ns. */ config->pulse = douDutyCycle * config->period; LOG_I("%s %d %d %d\n", ((nu_pwm_t)device)->name, config->channel, config->period, config->pulse); return RT_EOK; } uint32_t nu_pwm_config(uint32_t u32PwmBaseAddr, uint32_t u32ChannelNum, uint32_t u32Frequency, uint32_t u32PulseInHz) { uint32_t i; uint8_t u8Divider = 1, u8Prescale = 0xFF; uint16_t u16CNR = 0xFFFF; uint16_t u16CMR = 0xFFFF; uint32_t u32RegAdrrPPR = u32PwmBaseAddr; uint32_t u32RegAdrrCSR = u32PwmBaseAddr + 0x04; uint32_t u32RegAdrrCNR = u32PwmBaseAddr + 0xC + (u32ChannelNum * 0xC); uint32_t u32RegAdrrCMR = u32PwmBaseAddr + 0x10 + (u32ChannelNum * 0xC); uint32_t u32PWMSrcClk = sysGetClock(SYS_PCLK2) * 1000000; uint32_t u32PWMOutClk = 0; if (u32Frequency > u32PWMSrcClk) return 0; /* PWM_Freq = PCLK2 / (Prescale+1) / (Clock Divider) / (CNR+1) PCLK / PWM_Freq = (Prescale+1) * (Clock Divider) * (CNR+1) PCLK / PWM_Freq / (Clock Divider) = (Prescale+1) * (CNR+1) */ /* clk divider could only be 1, 2, 4, 8, 16 */ for (; u8Divider < 17; u8Divider <<= 1) { i = (u32PWMSrcClk / u32Frequency) / u8Divider; /* If target value is larger than CNR * prescale, need to use a larger divider */ if (i > (0x10000 * 0x100)) continue; /* CNR = 0xFFFF + 1, get a prescaler that CNR value is below 0xFFFF */ u8Prescale = (i + 0xFFFF) / 0x10000; /* u8Prescale must at least be 2, otherwise the output stop */ if (u8Prescale < 2) u8Prescale = 2; i /= u8Prescale; if (i < 0x10000) { if (i == 1) u16CNR = 1; // Too fast, and PWM cannot generate expected frequency... else u16CNR = i; break; } } u32PWMOutClk = u32PWMSrcClk / (u8Prescale * u8Divider * u16CNR); /* For fill into registers. */ u8Prescale -= 1; u16CNR -= 1; /* Convert to real register value */ if (u8Divider == 1) u8Divider = 4; else if (u8Divider == 2) u8Divider = 0; else if (u8Divider == 4) u8Divider = 1; else if (u8Divider == 8) u8Divider = 2; else // 16 u8Divider = 3; /* Every two channels share a prescaler */ outpw(u32RegAdrrPPR, (inpw(u32RegAdrrPPR) & ~(0xff << ((u32ChannelNum >> 1) * 8))) | (u8Prescale << ((u32ChannelNum >> 1) * 8))); /* Update CLKSEL in specified channel in CSR field. */ outpw(u32RegAdrrCSR, inpw(u32RegAdrrCSR) & ~(0x7 << (4 * u32ChannelNum)) | (u8Divider << (4 * u32ChannelNum))); u16CMR = u32Frequency * (u16CNR + 1) / u32PulseInHz; outpw(u32RegAdrrCMR, (u16CMR == 0) ? 0 : u16CMR - 1); outpw(u32RegAdrrCNR, u16CNR); return (u32PWMOutClk); } static rt_err_t nu_pwm_set(struct rt_device_pwm *device, struct rt_pwm_configuration *config) { nu_pwm_t psNuPWM = (nu_pwm_t)device; rt_err_t result = -RT_EINVAL; rt_uint32_t u32FreqInHz; /* unit:Hz */ rt_uint32_t u32PulseInHz; /* unit:% */ if (config->period < 1000 || !config->period || !config->pulse) goto exit_nu_pwm_set; /* Calculate frequency, Unit is in us. */ u32FreqInHz = (1000000000) / config->period; u32PulseInHz = (1000000000) / config->pulse; nu_pwm_config(psNuPWM->base_addr, config->channel, u32FreqInHz, u32PulseInHz); result = RT_EOK; exit_nu_pwm_set: return -(result); } static rt_err_t nu_pwm_control(struct rt_device_pwm *device, int cmd, void *arg) { struct rt_pwm_configuration *config = (struct rt_pwm_configuration *)arg; RT_ASSERT(device != RT_NULL); RT_ASSERT(config != RT_NULL); if (config->channel > NU_PWM_CHANNEL_NUM) return -(RT_EINVAL); switch (cmd) { case PWM_CMD_ENABLE: return nu_pwm_enable(device, config, RT_TRUE); case PWM_CMD_DISABLE: return nu_pwm_enable(device, config, RT_FALSE); case PWM_CMD_SET: return nu_pwm_set(device, config); case PWM_CMD_GET: return nu_pwm_get(device, config); default: break; } return -(RT_ERROR); } int rt_hw_pwm_init(void) { rt_err_t ret; int i; for (i = (PWM_START + 1); i < PWM_CNT; i++) { nu_sys_ipclk_enable(nu_pwm_arr[i].clkidx); nu_sys_ip_reset(nu_pwm_arr[i].rstidx); ret = rt_device_pwm_register(&nu_pwm_arr[i].dev, nu_pwm_arr[i].name, &nu_pwm_ops, RT_NULL); RT_ASSERT(ret == RT_EOK); } return 0; } INIT_DEVICE_EXPORT(rt_hw_pwm_init); #endif