/* SPDX-License-Identifier: GPL-2.0-only */ /* * Derived from Cavium's BSD-3 Clause OCTEONTX-SDK-6.2.0. */ #include #include #include #include #include #include #include #include #include #include union cn81xx_uart_ctl { u64 u; struct { u64 uctl_rst : 1; u64 uaa_rst : 1; u64 : 2; u64 csclk_en : 1; u64 : 19; u64 h_clkdiv_sel : 3; u64 : 1; u64 h_clkdiv_rst : 1; u64 h_clk_byp_sel : 1; u64 h_clk_en : 1; u64 : 33; } s; }; struct cn81xx_uart { struct pl011_uart pl011; union cn81xx_uart_ctl uctl_ctl; u8 rsvd4[0x8]; u64 uctl_spare0; u8 rsvd5[0xe0]; u64 uctl_spare1; }; #define UART_IBRD_BAUD_DIVINT_SHIFT 0 #define UART_IBRD_BAUD_DIVINT_MASK 0xffff #define UART_FBRD_BAUD_DIVFRAC_SHIFT 0 #define UART_FBRD_BAUD_DIVFRAC_MASK 0x3f check_member(cn81xx_uart, uctl_ctl, 0x1000); check_member(cn81xx_uart, uctl_spare1, 0x10f8); #define UART_SCLK_DIV 3 /** * Returns the current UART HCLK divider * * @param reg The H_CLKDIV_SEL value * @return The HCLK divider */ static size_t uart_sclk_divisor(const size_t reg) { static const u8 div[] = {1, 2, 4, 6, 8, 16, 24, 32}; assert(reg < ARRAY_SIZE(div)); return div[reg]; } /** * Returns the current UART HCLK * * @param uart The UART to operate on * @return The HCLK in Hz */ static size_t uart_hclk(struct cn81xx_uart *uart) { union cn81xx_uart_ctl ctl; const uint64_t sclk = thunderx_get_io_clock(); ctl.u = read64(&uart->uctl_ctl); return sclk / uart_sclk_divisor(ctl.s.h_clkdiv_sel); } unsigned int uart_platform_refclk(void) { struct cn81xx_uart *uart = (struct cn81xx_uart *)CONFIG_CONSOLE_SERIAL_UART_ADDRESS; if (!uart) return 0; return uart_hclk(uart); } uintptr_t uart_platform_base(unsigned int idx) { return CONFIG_CONSOLE_SERIAL_UART_ADDRESS; } /** * Waits given count if HCLK cycles * * @param uart The UART to operate on * @param hclks The number of HCLK cycles to wait */ static void uart_wait_hclk(struct cn81xx_uart *uart, const size_t hclks) { const size_t hclk = uart_hclk(uart); const size_t delay = (hclks * 1000000ULL) / hclk; udelay(MAX(delay, 1)); } /** * Returns the UART state. * * @param bus The UART to operate on * @return Boolean: True if UART is enabled */ int uart_is_enabled(const size_t bus) { struct cn81xx_uart *uart = (struct cn81xx_uart *)UAAx_PF_BAR0(bus); union cn81xx_uart_ctl ctl; assert(uart); if (!uart) return 0; ctl.u = read64(&uart->uctl_ctl); return !!ctl.s.csclk_en; } /** * Setup UART with desired BAUD rate in 8N1, no parity mode. * * @param bus The UART to operate on * @param baudrate baudrate to set up * * @return Boolean: True on error */ int uart_setup(const size_t bus, int baudrate) { union cn81xx_uart_ctl ctl; struct cn81xx_uart *uart = (struct cn81xx_uart *)UAAx_PF_BAR0(bus); assert(uart); if (!uart) return 1; /* 1.2.1 Initialization Sequence (Power-On/Hard/Cold Reset) */ /* 1. Wait for IOI reset (srst_n) to deassert. */ /** * 2. Assert all resets: * a. UAA reset: UCTL_CTL[UAA_RST] = 1 * b. UCTL reset: UCTL_CTL[UCTL_RST] = 1 */ ctl.u = read64(&uart->uctl_ctl); ctl.s.uctl_rst = 1; ctl.s.uaa_rst = 1; write64(&uart->uctl_ctl, ctl.u); /** * 3. Configure the HCLK: * a. Reset the clock dividers: UCTL_CTL[H_CLKDIV_RST] = 1. * b. Select the HCLK frequency * i. UCTL_CTL[H_CLKDIV] = desired value, * ii. UCTL_CTL[H_CLKDIV_EN] = 1 to enable the HCLK. * iii. Readback UCTL_CTL to ensure the values take effect. * c. Deassert the HCLK clock divider reset: UCTL_CTL[H_CLKDIV_RST] = 0. */ ctl.u = read64(&uart->uctl_ctl); ctl.s.h_clkdiv_sel = UART_SCLK_DIV; write64(&uart->uctl_ctl, ctl.u); ctl.u = read64(&uart->uctl_ctl); ctl.s.h_clk_byp_sel = 0; write64(&uart->uctl_ctl, ctl.u); ctl.u = read64(&uart->uctl_ctl); ctl.s.h_clk_en = 1; write64(&uart->uctl_ctl, ctl.u); ctl.u = read64(&uart->uctl_ctl); ctl.s.h_clkdiv_rst = 0; write64(&uart->uctl_ctl, ctl.u); /** * 4. Wait 20 HCLK cycles from step 3 for HCLK to start and async fifo * to properly reset. */ uart_wait_hclk(uart, 20 + 1); /** * 5. Deassert UCTL and UAHC resets: * a. UCTL_CTL[UCTL_RST] = 0 * b. Wait 10 HCLK cycles. * c. UCTL_CTL[UAHC_RST] = 0 * d. You will have to wait 10 HCLK cycles before accessing any * HCLK-only registers. */ ctl.u = read64(&uart->uctl_ctl); ctl.s.uctl_rst = 0; write64(&uart->uctl_ctl, ctl.u); uart_wait_hclk(uart, 10 + 1); ctl.u = read64(&uart->uctl_ctl); ctl.s.uaa_rst = 0; write64(&uart->uctl_ctl, ctl.u); uart_wait_hclk(uart, 10 + 1); /** * 6. Enable conditional SCLK of UCTL by writing * UCTL_CTL[CSCLK_EN] = 1. */ ctl.u = read64(&uart->uctl_ctl); ctl.s.csclk_en = 1; write64(&uart->uctl_ctl, ctl.u); /** * Exit here if the UART is not going to be used in coreboot. * The previous initialization steps are sufficient to make the Linux * kernel not panic. */ if (!baudrate) return 0; /** * 7. Initialize the integer and fractional baud rate divider registers * UARTIBRD and UARTFBRD as follows: * a. Baud Rate Divisor = UARTCLK/(16xBaud Rate) = BRDI + BRDF * b. The fractional register BRDF, m is calculated as * integer(BRDF x 64 + 0.5) * Example calculation: * If the required baud rate is 230400 and hclk = 4MHz then: * Baud Rate Divisor = (4x10^6)/(16x230400) = 1.085 * This means BRDI = 1 and BRDF = 0.085. * Therefore, fractional part, BRDF = integer((0.085x64)+0.5) = 5 * Generated baud rate divider = 1+5/64 = 1.078 */ u64 divisor = thunderx_get_io_clock() / (baudrate * 16 * uart_sclk_divisor(UART_SCLK_DIV) / 64); write32(&uart->pl011.ibrd, divisor >> 6); write32(&uart->pl011.fbrd, divisor & UART_FBRD_BAUD_DIVFRAC_MASK); /** * 8. Program the line control register UAA(0..1)_LCR_H and the control * register UAA(0..1)_CR */ /* 8-bits, FIFO enable */ write32(&uart->pl011.lcr_h, PL011_UARTLCR_H_WLEN_8 | PL011_UARTLCR_H_FEN); /* RX/TX enable, UART enable */ write32(&uart->pl011.cr, PL011_UARTCR_RXE | PL011_UARTCR_TXE | PL011_UARTCR_UARTEN); return 0; }