ref: 8be7f27b758ef9ef818f68db0d8bcb7b038eae0e
dir: /sys/src/9/arm64/uartqemu.c/
/* * PL011 UART from Miller's BCM2835 driver */ #include "u.h" #include "../port/lib.h" #include "../port/error.h" #include "mem.h" #include "dat.h" #include "fns.h" #include "io.h" enum { DR = 0x00>>2, RSRECR = 0x04>>2, FR = 0x18>>2, TXFE = 1<<7, RXFF = 1<<6, TXFF = 1<<5, RXFE = 1<<4, BUSY = 1<<3, ILPR = 0x20>>2, IBRD = 0x24>>2, FBRD = 0x28>>2, LCRH = 0x2c>>2, WLENM = 3<<5, WLEN8 = 3<<5, WLEN7 = 2<<5, WLEN6 = 1<<5, WLEN5 = 0<<5, FEN = 1<<4, /* fifo enable */ STP2 = 1<<3, /* 2 stop bits */ EPS = 1<<2, /* even parity select */ PEN = 1<<1, /* parity enabled */ BRK = 1<<0, /* send break */ CR = 0x30>>2, CTSEN = 1<<15, RTSEN = 1<<14, RTS = 1<<11, RXE = 1<<9, TXE = 1<<8, LBE = 1<<7, UARTEN = 1<<0, IFLS = 0x34>>2, IMSC = 0x38>>2, TXIM = 1<<5, RXIM = 1<<4, RIS = 0x3c>>2, MIS = 0x40>>2, ICR = 0x44>>2, DMACR = 0x48>>2, ITCR = 0x80>>2, ITIP = 0x84>>2, ITOP = 0x88>>2, TDR = 0x8c>>2, }; extern PhysUart qemuphysuart; static Uart qemuuart = { .regs = (u32int*)(VIRTIO+0x1000000ULL), .name = "uart0", .freq = 24*Mhz, .baud = 115200, .phys = &qemuphysuart, }; static Uart* pnp(void) { return &qemuuart; } static void interrupt(Ureg*, void *arg) { Uart *uart = arg; u32int *reg = (u32int*)uart->regs; coherence(); while((reg[FR] & RXFE) == 0) uartrecv(uart, reg[DR] & 0xFF); if((reg[FR] & TXFF) == 0) uartkick(uart); reg[ICR] = 1<<5 | 1<<6 | 1<<7 | 1<<8 | 1<<9 | 1<<10; coherence(); } static void disable(Uart *uart) { u32int *reg = (u32int*)uart->regs; /* disable interrupt */ reg[IMSC] = 0; coherence(); /* clear interrupt */ reg[ICR] = 1<<5 | 1<<6 | 1<<7 | 1<<8 | 1<<9 | 1<<10; coherence(); /* wait for last transmission to complete */ while((reg[FR] & BUSY) != 0) delay(1); /* disable uart */ reg[CR] = 0; coherence(); /* flush rx fifo */ reg[LCRH] &= ~FEN; coherence(); } static void uartoff(Uart *uart) { u32int *reg = (u32int*)uart->regs; u32int im; im = reg[IMSC]; disable(uart); reg[IMSC] = im; } static void uarton(Uart *uart) { u32int *reg = (u32int*)uart->regs; /* enable fifo */ reg[LCRH] |= FEN; coherence(); /* enable uart */ reg[CR] = UARTEN | RXE | TXE; coherence(); } static void enable(Uart *uart, int ie) { u32int *reg = (u32int*)uart->regs; disable(uart); if(ie){ intrenable(IRQuart, interrupt, uart, BUSUNKNOWN, uart->name); reg[IMSC] = TXIM|RXIM; } uarton(uart); } static void linectl(Uart *uart, u32int set, u32int clr) { u32int *reg = (u32int*)uart->regs; if(uart->enabled) uartoff(uart); reg[LCRH] = set | (reg[LCRH] & ~clr); if(uart->enabled) uarton(uart); } static void kick(Uart *uart) { u32int *reg = (u32int*)uart->regs; coherence(); while((reg[FR] & TXFF) == 0){ if(uart->op >= uart->oe && uartstageoutput(uart) == 0) break; reg[DR] = *(uart->op++); } coherence(); } static void dobreak(Uart *uart, int ms) { linectl(uart, BRK, 0); delay(ms); linectl(uart, 0, BRK); } static int baud(Uart *uart, int n) { u32int *reg = (u32int*)uart->regs; if(uart->freq <= 0 || n <= 0) return -1; if(uart->enabled) uartoff(uart); reg[IBRD] = (uart->freq >> 4) / n; reg[FBRD] = (uart->freq >> 4) % n; if(uart->enabled) uarton(uart); uart->baud = n; return 0; } static int bits(Uart *uart, int n) { switch(n){ case 8: linectl(uart, WLEN8, WLENM); break; case 7: linectl(uart, WLEN7, WLENM); break; case 6: linectl(uart, WLEN6, WLENM); break; case 5: linectl(uart, WLEN5, WLENM); break; default: return -1; } uart->bits = n; return 0; } static int stop(Uart *uart, int n) { switch(n){ case 1: linectl(uart, 0, STP2); break; case 2: linectl(uart, STP2, 0); break; default: return -1; } uart->stop = n; return 0; } static int parity(Uart *uart, int n) { switch(n){ case 'n': linectl(uart, 0, PEN); break; case 'e': linectl(uart, EPS|PEN, 0); break; case 'o': linectl(uart, PEN, EPS); break; default: return -1; } uart->parity = n; return 0; } static void modemctl(Uart *uart, int on) { uart->modem = on; } static void rts(Uart*, int) { } static long status(Uart *uart, void *buf, long n, long offset) { char *p; p = malloc(READSTR); if(p == nil) error(Enomem); snprint(p, READSTR, "b%d\n" "dev(%d) type(%d) framing(%d) overruns(%d) " "berr(%d) serr(%d)\n", uart->baud, uart->dev, uart->type, uart->ferr, uart->oerr, uart->berr, uart->serr ); n = readstr(offset, buf, n, p); free(p); return n; } static void donothing(Uart*, int) { } static void putc(Uart *uart, int c) { u32int *reg = (u32int*)uart->regs; while((reg[FR] & TXFF) != 0) ; reg[DR] = c & 0xFF; } static int getc(Uart *uart) { u32int *reg = (u32int*)uart->regs; while((reg[FR] & RXFE) != 0) ; return reg[DR] & 0xFF; } void uartconsinit(void) { consuart = &qemuuart; consuart->console = 1; uartctl(consuart, "l8 pn s1"); } PhysUart qemuphysuart = { .name = "qemu", .pnp = pnp, .enable = enable, .disable = disable, .kick = kick, .dobreak = dobreak, .baud = baud, .bits = bits, .stop = stop, .parity = parity, .modemctl = donothing, .rts = rts, .dtr = donothing, .status = status, .fifo = donothing, .getc = getc, .putc = putc, };