Atmosphere/thermosphere/src/uart.h

/*
 * Copyright (c) 2018 naehrwert
 * Copyright (c) 2018-2019 Atmosphère-NX
 *
 * This program is free software; you can redistribute it and/or modify it
 * under the terms and conditions of the GNU General Public License,
 * version 2, as published by the Free Software Foundation.
 *
 * This program is distributed in the hope it will be useful, but WITHOUT
 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
 * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License for
 * more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */

#pragma once
#include "utils.h"

#define UART_BASE 0x70006000ull

#define BAUD_115200 115200

/* Exosphère: add the clkreset values for UART C,D,E */
typedef enum {
    UART_A = 0,
    UART_B = 1,
    UART_C = 2,
    UART_D = 3,
    UART_E = 4,
} UartDevice;

/* 36.3.12 UART_VENDOR_STATUS_0_0 */
typedef enum {
    UART_VENDOR_STATE_TX_IDLE = 1 << 0,
    UART_VENDOR_STATE_RX_IDLE = 1 << 1,

    /* This bit is set to 1 when a read is issued to an empty FIFO and gets cleared on register read (sticky bit until read)
    0 = NO_UNDERRUN
    1 = UNDERRUN
    */
    UART_VENDOR_STATE_RX_UNDERRUN = 1 << 2,

    /* This bit is set to 1 when write data is issued to the TX FIFO when it is already full and gets cleared on register read (sticky bit until read)
    0 = NO_OVERRUN
    1 = OVERRUN
    */
    UART_VENDOR_STATE_TX_OVERRUN = 1 << 3,

    UART_VENDOR_STATE_RX_FIFO_COUNTER = 0b111111 << 16, /* reflects number of current entries in RX FIFO */
    UART_VENDOR_STATE_TX_FIFO_COUNTER = 0b111111 << 24 /* reflects number of current entries in TX FIFO */
} UartVendorStatus;

/* 36.3.6 UART_LSR_0 */
typedef enum {
    UART_LSR_RDR           = 1 << 0, /* Receiver Data Ready */
    UART_LSR_OVRF          = 1 << 1, /* Receiver Overrun Error */
    UART_LSR_PERR          = 1 << 2, /* Parity Error */
    UART_LSR_FERR          = 1 << 3, /* Framing Error */
    UART_LSR_BRK           = 1 << 4, /* BREAK condition detected on line */
    UART_LSR_THRE          = 1 << 5, /* Transmit Holding Register is Empty -- OK to write data */
    UART_LSR_TMTY          = 1 << 6, /* Transmit Shift Register empty status */
    UART_LSR_FIFOE         = 1 << 7, /* Receive FIFO Error */
    UART_LSR_TX_FIFO_FULL  = 1 << 8, /* Transmitter FIFO full status */
    UART_LSR_RX_FIFO_EMPTY = 1 << 9, /* Receiver FIFO empty status */
} UartLineStatus;

/* 36.3.4 UART_LCR_0 */
typedef enum {
    UART_LCR_WD_LENGTH_5 = 0, /* word length 5 */
    UART_LCR_WD_LENGTH_6 = 1, /* word length 6 */
    UART_LCR_WD_LENGTH_7 = 2, /* word length 7 */
    UART_LCR_WD_LENGTH_8 = 3, /* word length 8 */

    /* STOP:
    0 = Transmit 1 stop bit
    1 = Transmit 2 stop bits (receiver always checks for 1 stop bit)
    */
    UART_LCR_STOP        = 1 << 2, 
    UART_LCR_PAR         = 1 << 3, /* Parity enabled */
    UART_LCR_EVEN        = 1 << 4, /* Even parity format. There will always be an even number of 1s in the binary representation (PAR = 1) */
    UART_LCR_SET_P       = 1 << 5, /* Set (force) parity to value in LCR[4] */
    UART_LCR_SET_B       = 1 << 6, /* Set BREAK condition -- Transmitter sends all zeroes to indicate BREAK */
    UART_LCR_DLAB        = 1 << 7, /* Divisor Latch Access Bit (set to allow programming of the DLH, DLM Divisors) */
} UartLineControl;

/* 36.3.3 UART_IIR_FCR_0 */
typedef enum {
    UART_FCR_FCR_EN_FIFO = 1 << 0, /* Enable the transmit and receive FIFOs. This bit should be enabled */
    UART_FCR_RX_CLR      = 1 << 1, /* Clears the contents of the receive FIFO and resets its counter logic to 0 (the receive shift register is not cleared or altered). This bit returns to 0 after clearing the FIFOs */
    UART_FCR_TX_CLR      = 1 << 2, /* Clears the contents of the transmit FIFO and resets its counter logic to 0 (the transmit shift register is not cleared or altered). This bit returns to 0 after clearing the FIFOs */

    /* DMA:
    0 = DMA_MODE_0
    1 = DMA_MODE_1
    */
    UART_FCR_DMA         = 1 << 3,

    /* TX_TRIG
    0 = FIFO_COUNT_GREATER_16
    1 = FIFO_COUNT_GREATER_8
    2 = FIFO_COUNT_GREATER_4
    3 = FIFO_COUNT_GREATER_1
    */
    UART_FCR_TX_TRIG                       = 3 << 4,
    UART_FCR_TX_TRIG_FIFO_COUNT_GREATER_16 = 0 << 4,
    UART_FCR_TX_TRIG_FIFO_COUNT_GREATER_8  = 1 << 4,
    UART_FCR_TX_TRIG_FIFO_COUNT_GREATER_4  = 2 << 4,
    UART_FCR_TX_TRIG_FIFO_COUNT_GREATER_1  = 3 << 4,

    /* RX_TRIG
    0 = FIFO_COUNT_GREATER_1
    1 = FIFO_COUNT_GREATER_4
    2 = FIFO_COUNT_GREATER_8
    3 = FIFO_COUNT_GREATER_16 
    */
    UART_FCR_RX_TRIG                       = 3 << 6,
    UART_FCR_RX_TRIG_FIFO_COUNT_GREATER_1  = 0 << 6,
    UART_FCR_RX_TRIG_FIFO_COUNT_GREATER_4  = 1 << 6,
    UART_FCR_RX_TRIG_FIFO_COUNT_GREATER_8  = 2 << 6,
    UART_FCR_RX_TRIG_FIFO_COUNT_GREATER_16 = 3 << 6,
} UartFifoControl;

/* 36.3.3 UART_IIR_FCR_0 */
typedef enum {
    UART_IIR_IS_STA  = 1 << 0, /* Interrupt Pending if ZERO */
    UART_IIR_IS_PRI0 = 1 << 1, /* Encoded Interrupt ID Refer to IIR[3:0] table [36.3.3] */
    UART_IIR_IS_PRI1 = 1 << 2, /* Encoded Interrupt ID Refer to IIR[3:0] table */
    UART_IIR_IS_PRI2 = 1 << 3, /* Encoded Interrupt ID Refer to IIR[3:0] table */

    /* FIFO Mode Status
    0 = 16450 mode (no FIFO)
    1 = 16550 mode (FIFO)
    */
    UART_IIR_EN_FIFO    = 3 << 6,
    UART_IIR_MODE_16450 = 0 << 6,
    UART_IIR_MODE_16550 = 1 << 6,
} UartInterruptIdentification;

typedef struct {
    /* 0x00 */ u32 UART_THR_DLAB;
    /* 0x04 */ u32 UART_IER_DLAB;
    /* 0x08 */ u32 UART_IIR_FCR;
    /* 0x0C */ u32 UART_LCR;
    /* 0x10 */ u32 UART_MCR;
    /* 0x14 */ u32 UART_LSR;
    /* 0x18 */ u32 UART_MSR;
    /* 0x1C */ u32 UART_SPR;
    /* 0x20 */ u32 UART_IRDA_CSR;
    /* 0x24 */ u32 UART_RX_FIFO_CFG;
    /* 0x28 */ u32 UART_MIE;
    /* 0x2C */ u32 UART_VENDOR_STATUS;
    /* 0x30 */ uint8_t _pad_30[0x0C];
    /* 0x3C */ u32 UART_ASR;
} uart_t;

void uart_select(UartDevice dev);
void uart_init(UartDevice dev, u32 baud);
void uart_wait_idle(UartDevice dev, UartVendorStatus status);
void uart_send(UartDevice dev, const void *buf, size_t len);
void uart_recv(UartDevice dev, void *buf, size_t len);

static inline volatile uart_t *get_uart_device(UartDevice dev) {
    static const size_t offsets[] = {0, 0x40, 0x200, 0x300, 0x400};
    return (volatile uart_t *)(UART_BASE + offsets[dev]);
}
thermosphere: "write" placeholder code 2019-07-16 23:49:47 +00:00			`/*`
			`* Copyright (c) 2018 naehrwert`
			`* Copyright (c) 2018-2019 Atmosphère-NX`
			`*`
			`* This program is free software; you can redistribute it and/or modify it`
			`* under the terms and conditions of the GNU General Public License,`
			`* version 2, as published by the Free Software Foundation.`
			`*`
			`* This program is distributed in the hope it will be useful, but WITHOUT`
			`* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or`
			`* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for`
			`* more details.`
			`*`
			`* You should have received a copy of the GNU General Public License`
			`* along with this program. If not, see <http://www.gnu.org/licenses/>.`
			`*/`

			`#pragma once`
			`#include "utils.h"`

			`#define UART_BASE 0x70006000ull`

			`#define BAUD_115200 115200`

			`/* Exosphère: add the clkreset values for UART C,D,E */`
			`typedef enum {`
			`UART_A = 0,`
			`UART_B = 1,`
			`UART_C = 2,`
			`UART_D = 3,`
			`UART_E = 4,`
			`} UartDevice;`

			`/* 36.3.12 UART_VENDOR_STATUS_0_0 */`
			`typedef enum {`
			`UART_VENDOR_STATE_TX_IDLE = 1 << 0,`
			`UART_VENDOR_STATE_RX_IDLE = 1 << 1,`

			`/* This bit is set to 1 when a read is issued to an empty FIFO and gets cleared on register read (sticky bit until read)`
			`0 = NO_UNDERRUN`
			`1 = UNDERRUN`
			`*/`
			`UART_VENDOR_STATE_RX_UNDERRUN = 1 << 2,`

			`/* This bit is set to 1 when write data is issued to the TX FIFO when it is already full and gets cleared on register read (sticky bit until read)`
			`0 = NO_OVERRUN`
			`1 = OVERRUN`
			`*/`
			`UART_VENDOR_STATE_TX_OVERRUN = 1 << 3,`

			`UART_VENDOR_STATE_RX_FIFO_COUNTER = 0b111111 << 16, /* reflects number of current entries in RX FIFO */`
			`UART_VENDOR_STATE_TX_FIFO_COUNTER = 0b111111 << 24 /* reflects number of current entries in TX FIFO */`
			`} UartVendorStatus;`

			`/* 36.3.6 UART_LSR_0 */`
			`typedef enum {`
			`UART_LSR_RDR = 1 << 0, /* Receiver Data Ready */`
			`UART_LSR_OVRF = 1 << 1, /* Receiver Overrun Error */`
			`UART_LSR_PERR = 1 << 2, /* Parity Error */`
			`UART_LSR_FERR = 1 << 3, /* Framing Error */`
			`UART_LSR_BRK = 1 << 4, /* BREAK condition detected on line */`
			`UART_LSR_THRE = 1 << 5, /* Transmit Holding Register is Empty -- OK to write data */`
			`UART_LSR_TMTY = 1 << 6, /* Transmit Shift Register empty status */`
			`UART_LSR_FIFOE = 1 << 7, /* Receive FIFO Error */`
			`UART_LSR_TX_FIFO_FULL = 1 << 8, /* Transmitter FIFO full status */`
			`UART_LSR_RX_FIFO_EMPTY = 1 << 9, /* Receiver FIFO empty status */`
			`} UartLineStatus;`

			`/* 36.3.4 UART_LCR_0 */`
			`typedef enum {`
			`UART_LCR_WD_LENGTH_5 = 0, /* word length 5 */`
			`UART_LCR_WD_LENGTH_6 = 1, /* word length 6 */`
			`UART_LCR_WD_LENGTH_7 = 2, /* word length 7 */`
			`UART_LCR_WD_LENGTH_8 = 3, /* word length 8 */`

			`/* STOP:`
			`0 = Transmit 1 stop bit`
			`1 = Transmit 2 stop bits (receiver always checks for 1 stop bit)`
			`*/`
			`UART_LCR_STOP = 1 << 2,`
			`UART_LCR_PAR = 1 << 3, /* Parity enabled */`
			`UART_LCR_EVEN = 1 << 4, /* Even parity format. There will always be an even number of 1s in the binary representation (PAR = 1) */`
			`UART_LCR_SET_P = 1 << 5, /* Set (force) parity to value in LCR[4] */`
			`UART_LCR_SET_B = 1 << 6, /* Set BREAK condition -- Transmitter sends all zeroes to indicate BREAK */`
			`UART_LCR_DLAB = 1 << 7, /* Divisor Latch Access Bit (set to allow programming of the DLH, DLM Divisors) */`
			`} UartLineControl;`

			`/* 36.3.3 UART_IIR_FCR_0 */`
			`typedef enum {`
			`UART_FCR_FCR_EN_FIFO = 1 << 0, /* Enable the transmit and receive FIFOs. This bit should be enabled */`
			`UART_FCR_RX_CLR = 1 << 1, /* Clears the contents of the receive FIFO and resets its counter logic to 0 (the receive shift register is not cleared or altered). This bit returns to 0 after clearing the FIFOs */`
			`UART_FCR_TX_CLR = 1 << 2, /* Clears the contents of the transmit FIFO and resets its counter logic to 0 (the transmit shift register is not cleared or altered). This bit returns to 0 after clearing the FIFOs */`

			`/* DMA:`
			`0 = DMA_MODE_0`
			`1 = DMA_MODE_1`
			`*/`
			`UART_FCR_DMA = 1 << 3,`

			`/* TX_TRIG`
			`0 = FIFO_COUNT_GREATER_16`
			`1 = FIFO_COUNT_GREATER_8`
			`2 = FIFO_COUNT_GREATER_4`
			`3 = FIFO_COUNT_GREATER_1`
			`*/`
			`UART_FCR_TX_TRIG = 3 << 4,`
			`UART_FCR_TX_TRIG_FIFO_COUNT_GREATER_16 = 0 << 4,`
			`UART_FCR_TX_TRIG_FIFO_COUNT_GREATER_8 = 1 << 4,`
			`UART_FCR_TX_TRIG_FIFO_COUNT_GREATER_4 = 2 << 4,`
			`UART_FCR_TX_TRIG_FIFO_COUNT_GREATER_1 = 3 << 4,`

			`/* RX_TRIG`
			`0 = FIFO_COUNT_GREATER_1`
			`1 = FIFO_COUNT_GREATER_4`
			`2 = FIFO_COUNT_GREATER_8`
			`3 = FIFO_COUNT_GREATER_16`
			`*/`
			`UART_FCR_RX_TRIG = 3 << 6,`
			`UART_FCR_RX_TRIG_FIFO_COUNT_GREATER_1 = 0 << 6,`
			`UART_FCR_RX_TRIG_FIFO_COUNT_GREATER_4 = 1 << 6,`
			`UART_FCR_RX_TRIG_FIFO_COUNT_GREATER_8 = 2 << 6,`
			`UART_FCR_RX_TRIG_FIFO_COUNT_GREATER_16 = 3 << 6,`
			`} UartFifoControl;`

			`/* 36.3.3 UART_IIR_FCR_0 */`
			`typedef enum {`
			`UART_IIR_IS_STA = 1 << 0, /* Interrupt Pending if ZERO */`
			`UART_IIR_IS_PRI0 = 1 << 1, /* Encoded Interrupt ID Refer to IIR[3:0] table [36.3.3] */`
			`UART_IIR_IS_PRI1 = 1 << 2, /* Encoded Interrupt ID Refer to IIR[3:0] table */`
			`UART_IIR_IS_PRI2 = 1 << 3, /* Encoded Interrupt ID Refer to IIR[3:0] table */`

			`/* FIFO Mode Status`
			`0 = 16450 mode (no FIFO)`
			`1 = 16550 mode (FIFO)`
			`*/`
			`UART_IIR_EN_FIFO = 3 << 6,`
			`UART_IIR_MODE_16450 = 0 << 6,`
			`UART_IIR_MODE_16550 = 1 << 6,`
			`} UartInterruptIdentification;`

			`typedef struct {`
			`/* 0x00 */ u32 UART_THR_DLAB;`
			`/* 0x04 */ u32 UART_IER_DLAB;`
			`/* 0x08 */ u32 UART_IIR_FCR;`
			`/* 0x0C */ u32 UART_LCR;`
			`/* 0x10 */ u32 UART_MCR;`
			`/* 0x14 */ u32 UART_LSR;`
			`/* 0x18 */ u32 UART_MSR;`
			`/* 0x1C */ u32 UART_SPR;`
			`/* 0x20 */ u32 UART_IRDA_CSR;`
			`/* 0x24 */ u32 UART_RX_FIFO_CFG;`
			`/* 0x28 */ u32 UART_MIE;`
			`/* 0x2C */ u32 UART_VENDOR_STATUS;`
			`/* 0x30 */ uint8_t _pad_30[0x0C];`
			`/* 0x3C */ u32 UART_ASR;`
			`} uart_t;`

			`void uart_select(UartDevice dev);`
			`void uart_init(UartDevice dev, u32 baud);`
			`void uart_wait_idle(UartDevice dev, UartVendorStatus status);`
			`void uart_send(UartDevice dev, const void *buf, size_t len);`
			`void uart_recv(UartDevice dev, void *buf, size_t len);`

			`static inline volatile uart_t *get_uart_device(UartDevice dev) {`
			`static const size_t offsets[] = {0, 0x40, 0x200, 0x300, 0x400};`
			`return (volatile uart_t *)(UART_BASE + offsets[dev]);`
			`}`