rt-thread/bsp/allwinner/libraries/sunxi-hal/hal/source/ir/hal_ir.c

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/* Copyright (c) 2019-2025 Allwinner Technology Co., Ltd. ALL rights reserved.
* Allwinner is a trademark of Allwinner Technology Co.,Ltd., registered in
* the the People's Republic of China and other countries.
* All Allwinner Technology Co.,Ltd. trademarks are used with permission.
* DISCLAIMER
* THIRD PARTY LICENCES MAY BE REQUIRED TO IMPLEMENT THE SOLUTION/PRODUCT.
* IF YOU NEED TO INTEGRATE THIRD PARTY¡¯S TECHNOLOGY (SONY, DTS, DOLBY, AVS OR MPEGLA, ETC.)
* IN ALLWINNERS¡¯SDK OR PRODUCTS, YOU SHALL BE SOLELY RESPONSIBLE TO OBTAIN
* ALL APPROPRIATELY REQUIRED THIRD PARTY LICENCES.
* ALLWINNER SHALL HAVE NO WARRANTY, INDEMNITY OR OTHER OBLIGATIONS WITH RESPECT TO MATTERS
* COVERED UNDER ANY REQUIRED THIRD PARTY LICENSE.
* YOU ARE SOLELY RESPONSIBLE FOR YOUR USAGE OF THIRD PARTY¡¯S TECHNOLOGY.
* THIS SOFTWARE IS PROVIDED BY ALLWINNER"AS IS" AND TO THE MAXIMUM EXTENT
* PERMITTED BY LAW, ALLWINNER EXPRESSLY DISCLAIMS ALL WARRANTIES OF ANY KIND,
* WHETHER EXPRESS, IMPLIED OR STATUTORY, INCLUDING WITHOUT LIMITATION REGARDING
* THE TITLE, NON-INFRINGEMENT, ACCURACY, CONDITION, COMPLETENESS, PERFORMANCE
* OR MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE.
* IN NO EVENT SHALL ALLWINNER BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
* NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS, OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT,
* STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED
* OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include <interrupt.h>
#include <hal_clk.h>
#include <sunxi_hal_ir.h>
#include <init.h>
#define IRADC_ERR(fmt, arg...) printf("%s()%d " fmt, __func__, __LINE__, ##arg)
#define IRADC_INIT(fmt, arg...) printf("%s()%d " fmt, __func__, __LINE__, ##arg)
#ifdef IRADC_DEBUG
#define IR_INFO(fmt, arg...) printf("%s()%d " fmt, __func__, __LINE__, ##arg)
#define IR_INFO_IRQ(fmt, arg...) __log("%s()%d " fmt, __func__, __LINE__, ##arg)
#else
#define IR_INFO(fmt, arg...) \
do { \
} while (0);
#define IR_INFO_IRQ(fmt, arg...) \
do { \
} while (0);
#endif
hal_ir_t hal_ir;
static inline u8 ir_get_data(uint32_t reg_base)
{
return (u8)(hal_readl(reg_base + IR_RXDAT_REG) & 0xff);
}
static inline uint32_t ir_get_intsta(uint32_t reg_base)
{
return hal_readl(reg_base + IR_RXINTS_REG);
}
static inline void ir_clr_intsta(uint32_t reg_base, uint32_t bitmap)
{
uint32_t tmp = hal_readl(reg_base + IR_RXINTS_REG);
tmp &= ~0xff;
tmp |= bitmap & 0xff;
hal_writel(tmp, reg_base + IR_RXINTS_REG);
}
static irqreturn_t ir_handler(int irq, void *dev)
{
hal_ir_t *ir = (hal_ir_t *)dev;
uint32_t intsta, dcnt;
uint32_t i = 0;
uint32_t reg_data = 0;
IR_INFO_IRQ("IR RX IRQ Serve\n");
intsta = ir_get_intsta(ir->reg_base);
ir_clr_intsta(ir->reg_base, intsta);
/* get the count of signal */
dcnt = (intsta >> 8) & 0x7f;
IR_INFO_IRQ("receive cnt :%d\n", dcnt);
/* Read FIFO and fill the raw event */
for (i = 0; i < dcnt; i++)
{
/* get the data from fifo */
reg_data = ir_get_data(ir->reg_base);
ir->callback(IR_RXINTS_RXDA, reg_data);
}
if (intsta & IR_RXINTS_RXPE)
{
/* The last pulse can not call ir_raw_event_store() since miss
* invert level in above, manu call
*/
ir->callback(IR_RXINTS_RXPE, reg_data);
}
if (intsta & IR_RXINTS_RXOF)
{
/* FIFO Overflow */
ir->callback(IR_RXINTS_RXPE, reg_data);
}
return IRQ_HANDLED;
}
static void ir_mode_set(uint32_t reg_base, enum ir_mode set_mode)
{
uint32_t ctrl_reg = 0;
switch (set_mode)
{
case CIR_MODE_ENABLE:
ctrl_reg = hal_readl(reg_base + IR_CTRL_REG);
ctrl_reg |= IR_CIR_MODE;
break;
case IR_MODULE_ENABLE:
ctrl_reg = hal_readl(reg_base + IR_CTRL_REG);
ctrl_reg |= IR_ENTIRE_ENABLE;
break;
case IR_BOTH_PULSE_MODE:
ctrl_reg = hal_readl(reg_base + IR_CTRL_REG);
ctrl_reg |= IR_BOTH_PULSE;
break;
case IR_LOW_PULSE_MODE:
ctrl_reg = hal_readl(reg_base + IR_CTRL_REG);
ctrl_reg |= IR_LOW_PULSE;
break;
case IR_HIGH_PULSE_MODE:
ctrl_reg = hal_readl(reg_base + IR_CTRL_REG);
ctrl_reg |= IR_HIGH_PULSE;
break;
default:
IRADC_ERR("ir_mode_set error!!\n");
return;
}
hal_writel(ctrl_reg, reg_base + IR_CTRL_REG);
}
static void ir_sample_config(uint32_t reg_base,
enum ir_sample_config set_sample)
{
uint32_t sample_reg = 0;
sample_reg = hal_readl(reg_base + IR_SPLCFG_REG);
switch (set_sample)
{
case IR_SAMPLE_REG_CLEAR:
sample_reg = 0;
break;
case IR_CLK_SAMPLE:
sample_reg |= IR_SAMPLE_DEV;
break;
case IR_FILTER_TH_NEC:
sample_reg |= IR_RXFILT_VAL;
break;
case IR_FILTER_TH_RC5:
sample_reg |= IR_RXFILT_VAL_RC5;
break;
case IR_IDLE_TH:
sample_reg |= IR_RXIDLE_VAL;
break;
case IR_ACTIVE_TH:
sample_reg |= IR_ACTIVE_T;
sample_reg |= IR_ACTIVE_T_C;
break;
case IR_ACTIVE_TH_SAMPLE:
sample_reg |= IR_ACTIVE_T_SAMPLE;
sample_reg &= ~IR_ACTIVE_T_C;
break;
default:
IRADC_ERR("config err !\n");;
}
hal_writel(sample_reg, reg_base + IR_SPLCFG_REG);
}
static void ir_signal_invert(uint32_t reg_base)
{
uint32_t reg_value;
reg_value = 0x1 << 2;
hal_writel(reg_value, reg_base + IR_RXCFG_REG);
}
static void ir_irq_config(uint32_t reg_base, enum ir_irq_config set_irq)
{
uint32_t irq_reg = 0;
switch (set_irq)
{
case IR_IRQ_STATUS_CLEAR:
hal_writel(0xef, reg_base + IR_RXINTS_REG);
return;
case IR_IRQ_ENABLE:
irq_reg = hal_readl(reg_base + IR_RXINTE_REG);
irq_reg |= IR_IRQ_STATUS;
break;
case IR_IRQ_FIFO_SIZE:
irq_reg = hal_readl(reg_base + IR_RXINTE_REG);
irq_reg |= IR_FIFO_20;
break;
default:
return;
}
hal_writel(irq_reg, reg_base + IR_RXINTE_REG);
}
static void hal_ir_reg_cfg(uint32_t reg_base)
{
/* Enable IR Mode */
ir_mode_set(reg_base, CIR_MODE_ENABLE);
/* Config IR Smaple Register */
ir_sample_config(reg_base, IR_SAMPLE_REG_CLEAR);
ir_sample_config(reg_base, IR_CLK_SAMPLE);
ir_sample_config(reg_base, IR_IDLE_TH); /* Set Idle Threshold */
/* rc5 Set Active Threshold */
ir_sample_config(reg_base, IR_ACTIVE_TH_SAMPLE);
ir_sample_config(reg_base, IR_FILTER_TH_NEC); /* Set Filter Threshold */
ir_signal_invert(reg_base);
/* Clear All Rx Interrupt Status */
ir_irq_config(reg_base, IR_IRQ_STATUS_CLEAR);
/* Set Rx Interrupt Enable */
ir_irq_config(reg_base, IR_IRQ_ENABLE);
/* Rx FIFO Threshold = FIFOsz/2; */
ir_irq_config(reg_base, IR_IRQ_FIFO_SIZE);
/* for NEC decode which start with high level in the header so should
* use IR_HIGH_PULSE_MODE mode, but some ICs don't support this function
* therefor use IR_BOTH_PULSE_MODE mode as default
*/
ir_mode_set(reg_base, IR_BOTH_PULSE_MODE);
/* Enable IR Module */
ir_mode_set(reg_base, IR_MODULE_ENABLE);
}
static hal_ir_status_t hal_ir_clk_init(void)
{
int ret;
int32_t rate;
hal_clk_id_t mclk = HAL_CLK_PERIPH_IRTX;
ret = hal_clk_set_parent(mclk, HAL_CLK_SRC_HOSC24M);
if (ret)
{
IRADC_ERR("[ir] clk set parent failed! return %d\n", ret);
return IR_CLK_ERR;
}
rate = hal_clk_round_rate(mclk, IR_CLK);
if (rate < 0)
{
IRADC_ERR("[ir] clk round rate failed! return %ld\n", rate);
return IR_CLK_ERR;
}
ret = hal_clk_set_rate(mclk, rate);
if (ret)
{
IRADC_ERR("[ir] clk set rate failed! return %d\n", ret);
return IR_CLK_ERR;
}
rate = hal_clk_get_rate(mclk);
if (rate < 0)
{
IRADC_ERR("[ir] clk get rate failed! return %ld\n", rate);
return IR_CLK_ERR;
}
ret = hal_clock_enable(mclk);
if (ret)
{
IRADC_ERR("[ir] couldn't enable mlck! return %d\n", ret);
return IR_CLK_ERR;
}
return IR_OK;
}
static hal_ir_status_t hal_ir_pinctrl_init(hal_ir_t *ir)
{
int ret;
ret = hal_gpio_pinmux_set_function(ir->pin, ir->pin_mux);
if (ret)
{
IRADC_ERR(
"[ir] PIN set function failed! return %d\n", ret);
return IR_PIN_ERR;
}
ret = hal_gpio_set_driving_level(ir->pin, ir->pin_drv);
if (ret)
{
IRADC_ERR(
"[ir] PIN set driving level failed! return %d\n", ret);
return IR_PIN_ERR;
}
return IR_OK;
}
int hal_ir_register_callback(ir_callback_t callback)
{
hal_ir_t *ir = &hal_ir;
ir->callback = callback;
return IR_OK;
}
int hal_ir_init(void)
{
hal_ir_t *ir = &hal_ir;
ir->reg_base = SUNXI_IRADC_PBASE;
ir->irq_num = SUNXI_IRQ_IRADC;
ir->pin = IRADC_PIN;
ir->pin_drv = IR_DRVSEL;
ir->pin_mux = IR_MUXSEL;
IRADC_INIT("ir init\n");
if (hal_ir_pinctrl_init(ir))
{
IRADC_ERR("ir init pinctrl error\n");
return IR_PIN_ERR;
}
if (hal_ir_clk_init())
{
IRADC_ERR("ir init clk error\n");
return IR_CLK_ERR;
}
hal_ir_reg_cfg(ir->reg_base);
if (request_irq(ir->irq_num, ir_handler, 0, "ir", ir))
{
IRADC_ERR("ir request irq failed\n");
return IR_IRQ_ERR;
}
enable_irq(ir->irq_num);
return IR_OK;
}