lib/utils/serial/sifive-uart.c - opensbi - Git at Google

 /*
  * SPDX-License-Identifier: BSD-2-Clause
  *
  * Copyright (c) 2019 Western Digital Corporation or its affiliates.
  *
  * Authors:
  *   Anup Patel <anup.patel@wdc.com>
  */

 #include <sbi/riscv_io.h>
 #include <sbi/sbi_console.h>
 #include <sbi_utils/serial/sifive-uart.h>

 /* clang-format off */

 #define UART_REG_TXFIFO		0
 #define UART_REG_RXFIFO		1
 #define UART_REG_TXCTRL		2
 #define UART_REG_RXCTRL		3
 #define UART_REG_IE		4
 #define UART_REG_IP		5
 #define UART_REG_DIV		6

 #define UART_TXFIFO_FULL	0x80000000
 #define UART_RXFIFO_EMPTY	0x80000000
 #define UART_RXFIFO_DATA	0x000000ff
 #define UART_TXCTRL_TXEN	0x1
 #define UART_RXCTRL_RXEN	0x1

 /* clang-format on */

 static volatile char *uart_base;
 static u32 uart_in_freq;
 static u32 uart_baudrate;

 /**
  * Find minimum divisor divides in_freq to max_target_hz;
  * Based on uart driver n SiFive FSBL.
  *
  * f_baud = f_in / (div + 1) => div = (f_in / f_baud) - 1
  * The nearest integer solution requires rounding up as to not exceed max_target_hz.
  * div  = ceil(f_in / f_baud) - 1
  *	= floor((f_in - 1 + f_baud) / f_baud) - 1
  * This should not overflow as long as (f_in - 1 + f_baud) does not exceed
  * 2^32 - 1, which is unlikely since we represent frequencies in kHz.
  */
 static inline unsigned int uart_min_clk_divisor(uint64_t in_freq,
 						uint64_t max_target_hz)
 {
 	uint64_t quotient = (in_freq + max_target_hz - 1) / (max_target_hz);

 	/* Avoid underflow */
 	if (quotient == 0)
 		return 0;
 	else
 		return quotient - 1;
 }

 static u32 get_reg(u32 num)
 {
 	return readl(uart_base + (num * 0x4));
 }

 static void set_reg(u32 num, u32 val)
 {
 	writel(val, uart_base + (num * 0x4));
 }

 static void sifive_uart_putc(char ch)
 {
 	while (get_reg(UART_REG_TXFIFO) & UART_TXFIFO_FULL)
 		;

 	set_reg(UART_REG_TXFIFO, ch);
 }

 static int sifive_uart_getc(void)
 {
 	u32 ret = get_reg(UART_REG_RXFIFO);

 	if (!(ret & UART_RXFIFO_EMPTY))
 		return ret & UART_RXFIFO_DATA;

 	return -1;
 }

 static struct sbi_console_device sifive_console = {
 	.name = "sifive_uart",
 	.console_putc = sifive_uart_putc,
 	.console_getc = sifive_uart_getc
 };

 int sifive_uart_init(unsigned long base, u32 in_freq, u32 baudrate)
 {
 	uart_base     = (volatile char *)base;
 	uart_in_freq  = in_freq;
 	uart_baudrate = baudrate;

 	/* Configure baudrate */
 	if (in_freq && baudrate)
 		set_reg(UART_REG_DIV, uart_min_clk_divisor(in_freq, baudrate));

 	/* Disable interrupts */
 	set_reg(UART_REG_IE, 0);

 	/* Enable TX */
 	set_reg(UART_REG_TXCTRL, UART_TXCTRL_TXEN);

 	/* Enable Rx */
 	set_reg(UART_REG_RXCTRL, UART_RXCTRL_RXEN);

 	sbi_console_set_device(&sifive_console);

 	return 0;
 }
	/*
	* SPDX-License-Identifier: BSD-2-Clause
	*
	* Copyright (c) 2019 Western Digital Corporation or its affiliates.
	*
	* Authors:
	* Anup Patel <anup.patel@wdc.com>
	*/

	#include <sbi/riscv_io.h>
	#include <sbi/sbi_console.h>
	#include <sbi_utils/serial/sifive-uart.h>

	/* clang-format off */

	#define UART_REG_TXFIFO 0
	#define UART_REG_RXFIFO 1
	#define UART_REG_TXCTRL 2
	#define UART_REG_RXCTRL 3
	#define UART_REG_IE 4
	#define UART_REG_IP 5
	#define UART_REG_DIV 6

	#define UART_TXFIFO_FULL 0x80000000
	#define UART_RXFIFO_EMPTY 0x80000000
	#define UART_RXFIFO_DATA 0x000000ff
	#define UART_TXCTRL_TXEN 0x1
	#define UART_RXCTRL_RXEN 0x1

	/* clang-format on */

	static volatile char *uart_base;
	static u32 uart_in_freq;
	static u32 uart_baudrate;

	/**
	* Find minimum divisor divides in_freq to max_target_hz;
	* Based on uart driver n SiFive FSBL.
	*
	* f_baud = f_in / (div + 1) => div = (f_in / f_baud) - 1
	* The nearest integer solution requires rounding up as to not exceed max_target_hz.
	* div = ceil(f_in / f_baud) - 1
	* = floor((f_in - 1 + f_baud) / f_baud) - 1
	* This should not overflow as long as (f_in - 1 + f_baud) does not exceed
	* 2^32 - 1, which is unlikely since we represent frequencies in kHz.
	*/
	static inline unsigned int uart_min_clk_divisor(uint64_t in_freq,
	uint64_t max_target_hz)
	{
	uint64_t quotient = (in_freq + max_target_hz - 1) / (max_target_hz);

	/* Avoid underflow */
	if (quotient == 0)
	return 0;
	else
	return quotient - 1;
	}

	static u32 get_reg(u32 num)
	{
	return readl(uart_base + (num * 0x4));
	}

	static void set_reg(u32 num, u32 val)
	{
	writel(val, uart_base + (num * 0x4));
	}

	static void sifive_uart_putc(char ch)
	{
	while (get_reg(UART_REG_TXFIFO) & UART_TXFIFO_FULL)
	;

	set_reg(UART_REG_TXFIFO, ch);
	}

	static int sifive_uart_getc(void)
	{
	u32 ret = get_reg(UART_REG_RXFIFO);

	if (!(ret & UART_RXFIFO_EMPTY))
	return ret & UART_RXFIFO_DATA;

	return -1;
	}

	static struct sbi_console_device sifive_console = {
	.name = "sifive_uart",
	.console_putc = sifive_uart_putc,
	.console_getc = sifive_uart_getc
	};

	int sifive_uart_init(unsigned long base, u32 in_freq, u32 baudrate)
	{
	uart_base = (volatile char *)base;
	uart_in_freq = in_freq;
	uart_baudrate = baudrate;

	/* Configure baudrate */
	if (in_freq && baudrate)
	set_reg(UART_REG_DIV, uart_min_clk_divisor(in_freq, baudrate));

	/* Disable interrupts */
	set_reg(UART_REG_IE, 0);

	/* Enable TX */
	set_reg(UART_REG_TXCTRL, UART_TXCTRL_TXEN);

	/* Enable Rx */
	set_reg(UART_REG_RXCTRL, UART_RXCTRL_RXEN);

	sbi_console_set_device(&sifive_console);

	return 0;
	}