/* * Copyright (c) 2021-2023 HPMicro * * SPDX-License-Identifier: BSD-3-Clause */ #include #ifdef BSP_USING_ADC #include #include "board.h" #include "drv_adc.h" #ifdef BSP_USING_ADC12 #include "hpm_adc12_drv.h" #endif #ifdef BSP_USING_ADC16 #include "hpm_adc16_drv.h" #endif #include "hpm_sysctl_drv.h" typedef struct { bool enabled; } adc_channel_state_t; typedef struct { char *adc_name; struct rt_adc_device hpm_adc_device; bool is_adc12; bool adc_enabled; uint32_t adc_base; adc_channel_state_t chn_state[16]; }hpm_rtt_adc; static uint32_t hpm_adc_init_clock(struct rt_adc_device *device); static rt_err_t hpm_adc_enabled(struct rt_adc_device *device, rt_int8_t channel, rt_bool_t enabled); static rt_err_t hpm_get_adc_value(struct rt_adc_device *device, rt_int8_t channel, rt_uint32_t *value); static rt_uint8_t hpm_get_resolution(struct rt_adc_device *device); static rt_int16_t hpm_get_vref(struct rt_adc_device *device); static const struct rt_adc_ops hpm_adc_ops = { .enabled = hpm_adc_enabled, .convert = hpm_get_adc_value, .get_resolution = hpm_get_resolution, .get_vref = hpm_get_vref, }; static hpm_rtt_adc hpm_adc_config_tbl[] = { #ifdef BSP_USING_ADC0 { .adc_name = "adc0", #ifdef BSP_USING_ADC12 .is_adc12 = true, #else .is_adc12 = false, #endif .adc_base = (uint32_t)HPM_ADC0, }, #endif #ifdef BSP_USING_ADC1 { .adc_name = "adc1", #ifdef BSP_USING_ADC12 .is_adc12 = true, #else .is_adc12 = false, #endif .adc_base = (uint32_t)HPM_ADC1, }, #endif #ifdef BSP_USING_ADC2 { .adc_name = "adc2", #ifdef BSP_USING_ADC12 .is_adc12 = true, #else .is_adc12 = false, #endif .adc_base = (uint32_t)HPM_ADC2, }, #endif #ifdef BSP_USING_ADC3 { .adc_name = "adc3", .is_adc12 = false, .adc_base = (uint32_t)HPM_ADC3, }, #endif }; static uint8_t adc_nums = sizeof(hpm_adc_config_tbl) / sizeof(hpm_rtt_adc); static uint32_t hpm_adc_init_clock(struct rt_adc_device *device) { hpm_rtt_adc *hpm_adc; uint32_t clock_freq = 0; RT_ASSERT(device != RT_NULL); hpm_adc = (hpm_rtt_adc *)device->parent.user_data; #if defined(ADC12_SOC_MAX_CH_NUM) if (hpm_adc->is_adc12) { clock_freq = board_init_adc12_clock((ADC12_Type*)hpm_adc->adc_base); } else #endif { clock_freq = board_init_adc16_clock((ADC16_Type*)hpm_adc->adc_base); } return clock_freq; } static rt_err_t init_adc_config(hpm_rtt_adc *adc) { hpm_stat_t ret; if (adc->is_adc12) { #ifdef BSP_USING_ADC12 adc12_config_t cfg; adc12_get_default_config(&cfg); cfg.res = adc12_res_12_bits; cfg.conv_mode = adc12_conv_mode_oneshot; cfg.adc_ahb_en = true; cfg.adc_clk_div = 3; ret = adc12_init((ADC12_Type *)adc->adc_base, &cfg); if (ret != status_success) { return RT_ERROR; } #endif } else { #ifdef BSP_USING_ADC16 adc16_config_t cfg; adc16_get_default_config(&cfg); cfg.conv_mode = adc16_conv_mode_oneshot; cfg.res = adc16_res_16_bits; cfg.adc_clk_div = 4; cfg.sel_sync_ahb = true; cfg.adc_ahb_en = true; cfg.wait_dis = 0; ret = adc16_init((ADC16_Type *)adc->adc_base, &cfg); if (ret != status_success) { return RT_ERROR; } #endif } return RT_EOK; } static rt_err_t init_channel_config(hpm_rtt_adc *adc, uint16_t channel) { hpm_stat_t ret; if (adc->is_adc12) { #ifdef BSP_USING_ADC12 adc12_channel_config_t ch_cfg; adc12_get_channel_default_config(&ch_cfg); ch_cfg.ch = adc->channel; ch_cfg.diff_sel = adc12_sample_signal_single_ended; ch_cfg.sample_cycle = 20; ret = adc12_init_channel((ADC12_Type *)adc->adc_base, &ch_cfg); if (ret != status_success) { return RT_ERROR; } #endif } else { #ifdef BSP_USING_ADC16 adc16_channel_config_t ch_cfg; adc16_get_channel_default_config(&ch_cfg); ch_cfg.ch = channel; ch_cfg.sample_cycle = 20; ret = adc16_init_channel((ADC16_Type *)adc->adc_base, &ch_cfg); if (ret != status_success) { return RT_ERROR; } #endif } return RT_EOK; } static rt_err_t hpm_adc_enabled(struct rt_adc_device *device, rt_int8_t channel, rt_bool_t enabled) { hpm_rtt_adc *hpm_adc; rt_err_t ret; RT_ASSERT(device != RT_NULL); hpm_adc = (hpm_rtt_adc *)device->parent.user_data; if (enabled == RT_TRUE) { if (!hpm_adc->chn_state[channel].enabled) { if (!hpm_adc->adc_enabled) { (void)hpm_adc_init_clock(device); ret = init_adc_config(hpm_adc); if (ret != RT_EOK) { return RT_ERROR; } hpm_adc->adc_enabled = true; } hpm_adc->chn_state[channel].enabled = true; ret = init_channel_config(hpm_adc, channel); if (ret != RT_EOK) { return RT_ERROR; } } } else { /* Since the ADC channel cannot be truly disabled, do nothing here */ } return RT_EOK; } static rt_err_t hpm_get_adc_value(struct rt_adc_device *device, rt_int8_t channel, rt_uint32_t *value) { hpm_rtt_adc *hpm_adc; rt_err_t ret; rt_uint16_t val; RT_ASSERT(device != RT_NULL); RT_ASSERT(value != RT_NULL); hpm_adc = (hpm_rtt_adc *)device->parent.user_data; uint32_t adc_chn = (uint16_t)channel; if (hpm_adc->is_adc12) { #ifdef BSP_USING_ADC12 adc12_get_oneshot_result((ADC12_Type *)hpm_adc->adc_base, adc_chn, &val); *value = val; #endif } else { #ifdef BSP_USING_ADC16 hpm_stat_t status = adc16_get_oneshot_result((ADC16_Type *)hpm_adc->adc_base, adc_chn, &val); *value = val; // rt_kprintf("%s, status=%d\n", __func__, status); #endif } return RT_EOK; } static rt_uint8_t hpm_get_resolution(struct rt_adc_device *device) { hpm_rtt_adc *hpm_adc; RT_ASSERT(device != RT_NULL); hpm_adc = (hpm_rtt_adc *)device->parent.user_data; if (hpm_adc->is_adc12) { return 12; } else { return 16; } } static rt_int16_t hpm_get_vref(struct rt_adc_device *device) { return -RT_EIO; } int rt_hw_adc_init(void) { rt_err_t ret = RT_EOK; for (uint32_t i = 0; i < adc_nums; i++) { ret = rt_hw_adc_register(&hpm_adc_config_tbl[i].hpm_adc_device, hpm_adc_config_tbl[i].adc_name, &hpm_adc_ops, &hpm_adc_config_tbl[i]); if (ret != RT_EOK) { ret = RT_ERROR; break; } } return ret; } INIT_BOARD_EXPORT(rt_hw_adc_init); #endif /* BSP_USING_ADC */