rt-thread/bsp/phytium/libraries/standalone/drivers/i2c/fi2c/fi2c_master.c

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/*
* Copyright : (C) 2022 Phytium Information Technology, Inc.
* All Rights Reserved.
*
* This program is OPEN SOURCE software: you can redistribute it and/or modify it
* under the terms of the Phytium Public License as published by the Phytium Technology Co.,Ltd,
* either version 1.0 of the License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,but WITHOUT ANY WARRANTY;
* without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
* See the Phytium Public License for more details.
*
*
* FilePath: fi2c_master.c
* Date: 2022-02-10 14:53:42
* LastEditTime: 2022-02-18 08:36:46
* Description:  This files is for
*
* Modify History:
* Ver   Who        Date         Changes
* ----- ------     --------    --------------------------------------
*/
/*
- 一些驱动模块直接操作硬件的I/O接口无法实现有意义的操作此时需要针对中间件或者用户使用习惯设计此模块 i2c,nand,eth
- 部分场景适用, 分角色的 I/O 操作
- 此模块的函数原型在fooxx.h 中声明一次,方便用户或者中间件层调用
*/
/***************************** Include Files *********************************/
#include "fio.h"
#include "fsleep.h"
#include "fdebug.h"
#include "fi2c_hw.h"
#include "fi2c.h"
#include "finterrupt.h"
/************************** Constant Definitions *****************************/
/**************************** Type Definitions *******************************/
/***************** Macros (Inline Functions) Definitions *********************/
#define FI2C_DEBUG_TAG "I2C_MASTER"
#define FI2C_ERROR(format, ...) FT_DEBUG_PRINT_E(FI2C_DEBUG_TAG, format, ##__VA_ARGS__)
#define FI2C_INFO(format, ...) FT_DEBUG_PRINT_I(FI2C_DEBUG_TAG, format, ##__VA_ARGS__)
#define FI2C_DEBUG(format, ...) FT_DEBUG_PRINT_D(FI2C_DEBUG_TAG, format, ##__VA_ARGS__)
#define FI2C_TIMEOUT 500
/************************** Function Prototypes ******************************/
/************************** Variable Definitions *****************************/
/*****************************************************************************/
/**
* @name: FI2cMasterStartTrans
* @msg: I2C主机开始传输
* @return {*}
* @param {FI2c} *instance_p, I2C驱动实例数据
* @param {u32} mem_addr, 从机的片内偏移
* @param {u8} mem_byte_len, Size of internal memory address 1->8bit ~ 4->32bit
* @param {u8} flag ,for cmd reg STOP,RESTART.
*/
static FError FI2cMasterStartTrans(FI2c *instance_p, u32 mem_addr, u8 mem_byte_len, u16 flag)
{
FASSERT(instance_p);
uintptr base_addr = instance_p->config.base_addr;
FError ret = FI2C_SUCCESS;
u32 addr_len = mem_byte_len;
ret = FI2cWaitBusBusy(base_addr);
if (FI2C_SUCCESS != ret)
return ret;
ret = FI2cSetTar(base_addr, instance_p->config.slave_addr); /* 设备地址 */
if (FI2C_SUCCESS != ret)
return ret;
while (addr_len)
{
ret = FI2cWaitStatus(base_addr, FI2C_STATUS_TFNF);
if (FI2C_SUCCESS != ret)
break;
if (FI2C_GET_STATUS(base_addr) & FI2C_STATUS_TFNF)
{
addr_len--;
if (addr_len != 0)
{
FI2C_WRITE_REG32(base_addr, FI2C_DATA_CMD_OFFSET,
(mem_addr >> (addr_len * BITS_PER_BYTE)) & FI2C_DATA_MASK); /* word address */
}
else
{
FI2C_WRITE_REG32(base_addr, FI2C_DATA_CMD_OFFSET,
((mem_addr >> (addr_len * BITS_PER_BYTE)) & FI2C_DATA_MASK) + flag); /* word address */
}
}
}
return ret;
}
/**
* @name: FI2cMasterStopTrans
* @msg: I2C主机结束传输
* @return {*}
* @param {FI2c} *instance_p, I2C驱动实例数据
*/
static FError FI2cMasterStopTrans(FI2c *instance_p)
{
FASSERT(instance_p);
FError ret = FI2C_SUCCESS;
uintptr base_addr = instance_p->config.base_addr;
u32 reg_val;
u32 timeout = 0;
FI2C_INFO("GET MASTER STOP, stat: 0x%x, 0x%x", FI2C_READ_INTR_STAT(base_addr),
FI2C_READ_RAW_INTR_STAT(base_addr));
while (TRUE)
{
if (FI2C_READ_RAW_INTR_STAT(base_addr) & FI2C_INTR_STOP_DET)
{
reg_val = FI2C_READ_REG32(base_addr, FI2C_CLR_STOP_DET_OFFSET); /* read to clr intr status */
break;
}
else if (FI2C_TIMEOUT < ++timeout)
{
break; /* wait timeout, but no error code ret */
}
}
ret = FI2cWaitBusBusy(base_addr);
if (FI2C_SUCCESS == ret)
ret = FI2cFlushRxFifo(base_addr);
return ret;
}
/**
* @name: FI2cMasterReadPoll
* @msg: I2C主机读阻塞直到完成读操作或失败
* @return {FError *} 返回错误码
* @param {FI2c} *instance_p I2C驱动实例数据
* @param {u32} mem_addr 从机的内部偏移地址
* @param {u8} mem_byte_len, Size of internal memory address 1->8bit ~ 4->32bit
* @param {u8} *buf_p 读目的缓冲区
* @param {int} buf_len 读目的缓冲区长度
*/
FError FI2cMasterReadPoll(FI2c *instance_p, u32 mem_addr, u8 mem_byte_len, u8 *buf_p, u32 buf_len)
{
FError ret = FI2C_SUCCESS;
FASSERT(instance_p);
u32 mask;
u32 reg_val;
u32 tx_len = buf_len;
u32 rx_len = buf_len;
u32 rx_limit, tx_limit;
u32 trans_timeout = 0;
uintptr base_addr = instance_p->config.base_addr;
if (FT_COMPONENT_IS_READY != instance_p->is_ready)
{
FI2C_ERROR("i2c driver not ready");
return FI2C_ERR_NOT_READY;
}
if (FI2C_MASTER != instance_p->config.work_mode)
{
FI2C_ERROR("i2c work mode shall be master");
return FI2C_ERR_INVAL_STATE;
}
ret = FI2cMasterStartTrans(instance_p, mem_addr, mem_byte_len, FI2C_DATA_CMD_WRITE);
if (FI2C_SUCCESS != ret)
return ret;
/*for trigger rx intr*/
while (tx_len > 0 || rx_len > 0)
{
/* code */
rx_limit = FI2C_IIC_FIFO_MAX_LV - FI2C_READ_REG32(base_addr, FI2C_RXFLR_OFFSET);
tx_limit = FI2C_IIC_FIFO_MAX_LV - FI2C_READ_REG32(base_addr, FI2C_TXFLR_OFFSET);
while (tx_len > 0 & rx_limit > 0 & tx_limit > 0)
{
/* code */
if (tx_len == 1)
{
reg_val = FI2C_DATA_CMD_READ | FI2C_DATA_CMD_STOP;
FI2C_WRITE_REG32(instance_p->config.base_addr, FI2C_DATA_CMD_OFFSET, reg_val);
}
else
{
reg_val = FI2C_DATA_CMD_READ;
FI2C_WRITE_REG32(instance_p->config.base_addr, FI2C_DATA_CMD_OFFSET, reg_val);
}
tx_len--;
rx_limit--;
tx_limit--;
}
u8 rx_tem = FI2C_READ_REG32(base_addr, FI2C_RXFLR_OFFSET);
while (rx_tem > 0 & rx_len > 0)
{
/* code */
if (FI2C_GET_STATUS(base_addr) & FI2C_STATUS_RFNE)
{
/* trans one byte */
*buf_p++ = FI2C_READ_DATA(base_addr);
rx_len--;
rx_tem--;
trans_timeout = 0;
}
else if (FI2C_TIMEOUT < (++trans_timeout))
{
ret = FI2C_ERR_TIMEOUT;
FI2C_ERROR("timeout in i2c master read");
break;
}
}
}
if (FI2C_SUCCESS == ret)
{
ret = FI2cMasterStopTrans(instance_p);
}
return ret;
}
/**
* @name: FI2cMasterWritePoll
* @msg: I2C主机写阻塞直到完成写操作或失败
* @return {FError *} 返回错误码
* @param {FI2c} *instance_p I2C驱动实例数据
* @param {u32} mem_addr 从机的内部偏移地址
* @param {u8} mem_byte_len, Size of internal memory address 1->8bit ~ 4->32bit
* @param {u8} *buf_p 写源缓冲区
* @param {size_t} buf_len 写源缓冲区长度
*/
FError FI2cMasterWritePoll(FI2c *instance_p, u32 mem_addr, u8 mem_byte_len, const u8 *buf_p, u32 buf_len)
{
FASSERT(instance_p && buf_p);
FError ret = FI2C_SUCCESS;
u32 buf_idx = buf_len;
u32 tx_limit;
uintptr base_addr = instance_p->config.base_addr;
u32 reg_val;
u32 trans_timeout = 0;
if (FT_COMPONENT_IS_READY != instance_p->is_ready)
{
FI2C_ERROR("i2c driver not ready");
return FI2C_ERR_NOT_READY;
}
if (FI2C_MASTER != instance_p->config.work_mode)
{
FI2C_ERROR("i2c work mode shall be master");
return FI2C_ERR_INVAL_STATE;
}
ret = FI2cMasterStartTrans(instance_p, mem_addr, mem_byte_len, FI2C_DATA_CMD_WRITE);
if (FI2C_SUCCESS != ret)
return ret;
while (buf_idx)
{
tx_limit = FI2C_IIC_FIFO_MAX_LV - FI2C_READ_REG32(base_addr, FI2C_TXFLR_OFFSET);
while (tx_limit > 0 & buf_idx > 0)
{
if (FI2C_GET_STATUS(base_addr) & FI2C_STATUS_TFNF)
{
if (1 == buf_idx)
{
reg_val = (FI2C_DATA_MASK & *buf_p) |
FI2C_DATA_CMD_WRITE |
FI2C_DATA_CMD_STOP;
FI2C_INFO("Write Stop Singal");
}
else
{
reg_val = (FI2C_DATA_MASK & *buf_p) |
FI2C_DATA_CMD_WRITE;
}
buf_idx--;
tx_limit--;
FI2C_WRITE_REG32(base_addr, FI2C_DATA_CMD_OFFSET, reg_val);
buf_p++;
trans_timeout = 0;
}
else if (FI2C_TIMEOUT < ++trans_timeout)
{
ret = FI2C_ERR_TIMEOUT;
FI2C_ERROR("timeout in i2c master write");
break;
}
}
}
if (FI2C_SUCCESS == ret)
{
ret = FI2cMasterStopTrans(instance_p);
}
return ret;
}
/**
* @name: FI2cMasterReadIntr
* @msg: I2C主机读中断完成读操作或失败
* @return {FError *} 返回错误码
* @param {FI2c} *instance_p I2C驱动实例数据
* @param {u32} mem_addr 从机的内部偏移地址
* @param {u8} mem_byte_len, Size of internal memory address 1->8bit ~ 4->32bit
* @param {u8} *buf_p 读目的缓冲区
* @param {int} buf_len 读目的缓冲区长度
*/
FError FI2cMasterReadIntr(FI2c *instance_p, u32 mem_addr, u8 mem_byte_len, u8 *buf_p, u32 buf_len)
{
FError ret = FI2C_SUCCESS;
FASSERT(instance_p);
u32 mask;
u32 reg_val;
u32 trans_timeout;
if (FT_COMPONENT_IS_READY != instance_p->is_ready)
{
FI2C_ERROR("i2c driver not ready");
return FI2C_ERR_NOT_READY;
}
if (FI2C_MASTER != instance_p->config.work_mode)
{
FI2C_ERROR("i2c work mode shall be master");
return FI2C_ERR_INVAL_STATE;
}
while (instance_p->status != STATUS_IDLE)
{
/* code */
fsleep_millisec(1);
if (FI2C_TIMEOUT < (++trans_timeout))
{
ret = FI2C_ERR_TIMEOUT;
FI2C_ERROR("timeout in i2c master read intr.");
break;
}
}
instance_p->rxframe.data_buff = buf_p;
instance_p->rxframe.rx_total_num = buf_len;
instance_p->txframe.tx_total_num = buf_len;
instance_p->rxframe.rx_cnt = 0;
FI2C_SET_RX_TL(instance_p->config.base_addr, 0);/* 0 表示接收缓冲区大于等于 1 时触发中断 */
ret = FI2cMasterStartTrans(instance_p, mem_addr, mem_byte_len, FI2C_DATA_CMD_WRITE);
instance_p->status = STATUS_READ_IN_PROGRESS;
if (FI2C_SUCCESS != ret)
return ret;
mask = FI2C_GET_INTRRUPT_MASK(instance_p->config.base_addr);
mask |= FI2C_INTR_MASTER_RD_MASK;
ret = FI2cMasterSetupIntr(instance_p, mask);
if (FI2C_SUCCESS != ret)
return ret;
return ret;
}
/**
* @name: FI2cMasterWriteIntr
* @msg: I2C主机写中断写操作或失败
* @return {FError *} 返回错误码
* @param {FI2c} *instance_p I2C驱动实例数据
* @param {u32} mem_addr 从机的内部偏移地址
* @param {u8} mem_byte_len, Size of internal memory address 1->8bit ~ 4->32bit
* @param {u8} *buf_p 写源缓冲区
* @param {size_t} buf_len 写源缓冲区长度
*/
FError FI2cMasterWriteIntr(FI2c *instance_p, u32 mem_addr, u8 mem_byte_len, const u8 *buf_p, u32 buf_len)
{
FError ret = FI2C_SUCCESS;
FASSERT(instance_p);
u32 mask;
u32 trans_timeout = 0;
if (FT_COMPONENT_IS_READY != instance_p->is_ready)
{
FI2C_ERROR("i2c driver not ready");
return FI2C_ERR_NOT_READY;
}
if (FI2C_MASTER != instance_p->config.work_mode)
{
FI2C_ERROR("i2c work mode shall be master");
return FI2C_ERR_INVAL_STATE;
}
while (instance_p->status != STATUS_IDLE)
{
/* code */
fsleep_millisec(1);
if (FI2C_TIMEOUT < (++trans_timeout))
{
ret = FI2C_ERR_TIMEOUT;
FI2C_ERROR("timeout in i2c master write intr.");
break;
}
}
instance_p->txframe.data_buff = buf_p;
instance_p->txframe.tx_total_num = buf_len;
instance_p->txframe.tx_cnt = 0;
ret = FI2cMasterStartTrans(instance_p, mem_addr, mem_byte_len, FI2C_DATA_CMD_WRITE);
if (FI2C_SUCCESS != ret)
return ret;
instance_p->status = STATUS_WRITE_IN_PROGRESS;
mask = FI2C_GET_INTRRUPT_MASK(instance_p->config.base_addr);
mask |= FI2C_INTR_MASTER_WR_MASK;
ret = FI2cMasterSetupIntr(instance_p, mask);
if (FI2C_SUCCESS != ret)
return ret;
return ret;
}