/* * Copyright (c) 2020-2021, Bluetrum Development Team * * SPDX-License-Identifier: Apache-2.0 * * Change Logs: * Date Author Notes * 2021-04-12 greedyhao first version */ #include #ifdef BSP_USING_IRRX //#define DRV_DEBUG #define LOG_TAG "drv.irrx" #include #ifdef BSP_USING_TIM3 #error "IRRX is conflict with hardware timer3!" #endif #ifdef BSP_USING_IRRX_HW ///硬件IR receiver参数 #define IR32KSEL_EN 0 //IR clock source select 32K #if IR32KSEL_EN #define RPTERR_CNT 33 //配置11.25ms ± (RPTERR_CNT + 1)*32K的repeat code允许范围 #define DATERR_CNT 33 //配置13.5ms ± (DATERR_CNT + 1)*32K引导码允许范围 #define ONEERR_CNT 7 //配置2.25ms ± (ONEERR_CNT + 1)*32K的logic "1"允许范围 #define ZEROERR_CNT 3 //配置1.12ms ± (ONEERR_CNT + 1)*32K数logic "0"允许范围 #define TOPR_CNT 55 //IR time out length = (TOPR + 1) * 64 *32K #else #define RPTERR_CNT 1000 //配置11.25ms ± (RPTERR_CNT + 1)us的repeat code允许范围 #define DATERR_CNT 1000 //配置13.5ms ± (DATERR_CNT + 1)us引导码允许范围 #define ONEERR_CNT 250 //配置2.25ms ± (ONEERR_CNT + 1)us的logic "1"允许范围 #define ZEROERR_CNT 125 //配置1.12ms ± (ONEERR_CNT + 1)us数logic "0"允许范围 #define TOPR_CNT 1718 //IR time out length = (TOPR + 1) * 64 us #endif // IR32KSEL_EN #endif // BSP_USING_IRRX_HW #define NO_KEY (0u) struct ab32_irrx_data{ rt_uint16_t cnt; //ir data bit counter rt_uint16_t rpt_cnt; //ir repeat counter rt_uint16_t addr; //address, inverted address Extended NEC: 16bits address rt_uint16_t cmd; //command, inverted command }; typedef struct ab32_irrx_data *ab32_irrx_data_t; static struct ab32_irrx_data _irrx = {0}; /** * @brief A non-zero value is returned * when IR key is detectedto be pressed. * * @param addr inverted address Extended NEC: 16bits address * @param cmd inverted command */ rt_section(".irq.irrx") rt_uint8_t ab32_get_irkey(rt_uint16_t *addr, rt_uint16_t *cmd) { if (_irrx.cnt != 32) { return NO_KEY; } if (addr != RT_NULL) { *addr = _irrx.addr; } if (cmd != RT_NULL) { *cmd = _irrx.cmd; } return !NO_KEY; } /** * @brief Invalid the current IR key. * */ void ab32_clr_irkey(void) { _irrx.cnt = 0; } #ifdef BSP_USING_IRRX_HW rt_section(".irq.irrx") static void irrx_isr(int vector, void *param) { rt_interrupt_enter(); //IR RX data finish interrupt if (IRRXCON & BIT(16)) { IRRXCPND = BIT(16); _irrx.addr = (rt_uint16_t)IRRXDAT; _irrx.cmd = (rt_uint16_t)(IRRXDAT >> 16); _irrx.cnt = 32; } //IR key release interrupt if (IRRXCON & BIT(17)) { IRRXCPND = BIT(17); _irrx.cnt = 0; } rt_interrupt_leave(); } static void _irrx_hw_init(void) { GPIOEDE |= BIT(6); GPIOEPU |= BIT(6); GPIOEDIR |= BIT(6); FUNCMCON2 |= 0xf << 20; FUNCMCON2 |= (7 << 20); //IR mapping to G6 rt_memset(&_irrx, 0, sizeof(_irrx)); IRRXERR0 = (RPTERR_CNT << 16) | DATERR_CNT; //RPTERR[27:16], DATERR[11:0] IRRXERR1 = (TOPR_CNT << 20) | (ONEERR_CNT << 10) | ZEROERR_CNT; //TOPR[31:20], ONEERR[19:10], ZEROERR[9:0] #if IR32KSEL_EN CLKCON1 &= ~BIT(5); CLKCON1 |= BIT(4); //enable 26M分频32K IRRXCON |= BIT(3); //ir clock source select 32K #endif // IR32KSEL_EN rt_hw_interrupt_install(IRQ_IRRX_VECTOR, irrx_isr, RT_NULL, "irrx_isr"); IRRXCON = 0x03; // LOG_D("IRRXCON:%08x", IRRXCON); } #endif #ifdef BSP_USING_IRRX_SW #define TMR3_RCLK (1000u) //xosc26m_div 1M rt_section(".irq.irrx") static void irrx_isr(int vector, void *param) { rt_uint32_t tmrcnt; if (TMR3CON & BIT(17)) { //timer1 capture interrupt TMR3CNT = TMR3CNT - TMR3CPT; tmrcnt = TMR3CPT; TMR3CPND = BIT(17); tmrcnt /= TMR3_RCLK; //convert to ms } else if (TMR3CON & BIT(16)){ //timer1 overflow interrupt TMR3CPND = BIT(16); tmrcnt = 110; //110ms overflow } else { return; } //processing repeat code if (_irrx.cnt == 32) { if ((tmrcnt >= 10) && (tmrcnt <= 12)) { //repeat code is simply 9ms+2.25ms _irrx.rpt_cnt = 0; } else { _irrx.rpt_cnt += tmrcnt; if (_irrx.rpt_cnt > 108) { _irrx.rpt_cnt = 0; _irrx.cnt = 0; //ir key release } } return; } else if ((tmrcnt > 7) || (tmrcnt == 0)) { //A message is started by a 9ms AGC burst _irrx.rpt_cnt = 0; _irrx.cnt = 0; //ir key message started return; } _irrx.cmd >>= 1; _irrx.cnt++; if (tmrcnt == 2) { //Bit time of 1.125ms(0) or 2.25ms(1) _irrx.cmd |= 0x8000; } if (_irrx.cnt == 16) { _irrx.addr = _irrx.cmd; //save address data } else if (_irrx.cnt == 32) { //got ir key message if ((rt_uint8_t)_irrx.cmd > 96) { _irrx.cmd = NO_KEY; } } } static void timer3_init(void) { rt_hw_interrupt_install(IRQ_IRRX_VECTOR, irrx_isr, RT_NULL, "irrx_isr"); TMR3CNT = 0; TMR3PR = TMR3_RCLK*110 - 1; //110ms Timer overflow interrupt TMR3CON = BIT(8) | BIT(7) | BIT(5) | BIT(2) | BIT(1) | BIT(0); //capture & overflow interrupt enable, falling edge, Capture Mode } static void _irrx_hw_init(void) { GPIOEDE |= BIT(6); GPIOEPU |= BIT(6); GPIOEDIR |= BIT(6); FUNCMCON2 |= 0xf << 4; FUNCMCON2 |= (7 << 4); // timer3 G6 PE6 capture rt_memset(&_irrx, 0, sizeof(_irrx)); timer3_init(); } #endif static int ab32_irrx_init(void) { _irrx_hw_init(); LOG_D("irrx init success"); return RT_EOK; } INIT_BOARD_EXPORT(ab32_irrx_init); #endif