ref: e4191b8d11ae31efe758abfa5b48bf0b99c912a4
dir: /sys/src/9/zynq/uartzynq.c/
#include "u.h" #include "../port/lib.h" #include "mem.h" #include "dat.h" #include "fns.h" #include "io.h" enum { CTRL = 0, MODE, IRQEN, IRQDIS, MASK, INTSTAT, RXFIFOLVL = 0x20/4, CHANSTAT = 0x2C/4, FIFO = 0x30/4, }; enum { TXFULL = 1<<4, TXEMPTY = 1<<3, RXEMPTY = 1<<1, RXTRIG = 1<<0, }; typedef struct Ctlr { Lock; ulong *r; int irq, iena; } Ctlr; extern PhysUart zynqphysuart; static Ctlr zctlr[1] = { { .r = (void *) VMAP, .irq = UART1IRQ, } }; static Uart zuart[1] = { { .regs = &zctlr[0], .name = "UART1", .freq = 25000000, .phys = &zynqphysuart, .console = 1, .baud = 115200, } }; void uartconsinit(void) { consuart = zuart; uartctl(consuart, "l8 pn s1"); } static Uart * zuartpnp(void) { return zuart; } static void zuartkick(Uart *uart) { Ctlr *ct; int i; ct = uart->regs; for(i = 0; i < 128; i++){ if((ct->r[CHANSTAT] & TXFULL) != 0) break; if(uart->op >= uart->oe && uartstageoutput(uart) == 0) break; ct->r[FIFO] = *uart->op++; } } static void zuartintr(Ureg *, void *arg) { Uart *uart; Ctlr *ct; int c; ulong fl; uart = arg; ct = uart->regs; fl = ct->r[INTSTAT] & ct->r[MASK]; ct->r[INTSTAT] = fl; if((fl & RXTRIG) != 0) while((ct->r[CHANSTAT] & RXEMPTY) == 0){ c = ct->r[FIFO]; uartrecv(uart, c); } if((fl & TXEMPTY) != 0) uartkick(uart); } static void zuartenable(Uart *uart, int ie) { Ctlr *ctlr; ctlr = uart->regs; ilock(ctlr); while((ctlr->r[CHANSTAT] & TXEMPTY) == 0) ; ctlr->r[IRQDIS] = -1; ctlr->r[RXFIFOLVL] = 1; if(ie){ if(!ctlr->iena){ intrenable(ctlr->irq, zuartintr, uart, LEVEL, uart->name); ctlr->iena = 1; } ctlr->r[IRQEN] = RXTRIG | TXEMPTY; } iunlock(ctlr); } static int zuartgetc(Uart *uart) { Ctlr *c; c = uart->regs; while((c->r[CHANSTAT] & RXEMPTY) != 0) ; return c->r[FIFO]; } static void zuartputc(Uart *uart, int c) { Ctlr *ct; ct = uart->regs; while((ct->r[CHANSTAT] & TXFULL) != 0) ; ct->r[FIFO] = c; return; } int zuartbits(Uart *uart, int n) { Ctlr *ct; ct = uart->regs; ct->r[MODE] &= ~6; switch(n){ case 8: return 0; case 7: ct->r[MODE] |= 4; return 0; case 6: ct->r[MODE] |= 6; return 0; default: return -1; } } int zuartbaud(Uart *, int n) { print("uart baud %d\n", n); return 0; } int zuartparity(Uart *uart, int p) { Ctlr *ct; ct = uart->regs; switch(p){ case 'o': ct->r[MODE] = ct->r[MODE] & ~0x38 | 0x08; return 0; case 'e': ct->r[MODE] = ct->r[MODE] & ~0x38; return 0; case 'n': ct->r[MODE] = ct->r[MODE] & 0x38 | 0x20; return 0; default: return -1; } } void zuartnop(Uart *, int) { } int zuartnope(Uart *, int) { return -1; } PhysUart zynqphysuart = { .pnp = zuartpnp, .enable = zuartenable, .kick = zuartkick, .getc = zuartgetc, .putc = zuartputc, .bits = zuartbits, .baud = zuartbaud, .parity = zuartparity, .stop = zuartnope, .rts = zuartnop, .dtr = zuartnop, .dobreak = zuartnop, .fifo = zuartnop, .power = zuartnop, .modemctl = zuartnop, };