#include "u.h" #include "../port/lib.h" #include "mem.h" #include "dat.h" #include "fns.h" #include "io.h" #include "../port/error.h" #include "../port/netif.h" /* this isn't strictly an sa1110 driver. The rts/cts stuff is h3650 specific */ static void sa1110_uartpower(Uart *, int); enum { /* ctl[0] bits */ Parity= 1<<0, Even= 1<<1, Stop2= 1<<2, Bits8= 1<<3, SCE= 1<<4, /* synchronous clock enable */ RCE= 1<<5, /* rx on falling edge of clock */ TCE= 1<<6, /* tx on falling edge of clock */ /* ctl[3] bits */ Rena= 1<<0, /* receiver enable */ Tena= 1<<1, /* transmitter enable */ Break= 1<<2, /* force TXD3 low */ Rintena= 1<<3, /* enable receive interrupt */ Tintena= 1<<4, /* enable transmitter interrupt */ Loopback= 1<<5, /* loop back data */ /* data bits */ DEparity= 1<<8, /* parity error */ DEframe= 1<<9, /* framing error */ DEoverrun= 1<<10, /* overrun error */ /* status[0] bits */ Tint= 1<<0, /* transmit fifo half full interrupt */ Rint0= 1<<1, /* receiver fifo 1/3-2/3 full */ Rint1= 1<<2, /* receiver fifo not empty and receiver idle */ Breakstart= 1<<3, Breakend= 1<<4, Fifoerror= 1<<5, /* fifo error */ /* status[1] bits */ Tbusy= 1<<0, /* transmitting */ Rnotempty= 1<<1, /* receive fifo not empty */ Tnotfull= 1<<2, /* transmit fifo not full */ ParityError= 1<<3, FrameError= 1<<4, Overrun= 1<<5, }; extern PhysUart sa1110physuart; //static Uart sa1110uart[2] = { { .regs = (void*)UART3REGS, .name = "serialport3", .freq = ClockFreq, .bits = 8, .stop = 1, .parity = 'n', .baud = 115200, .phys = &sa1110physuart, .special = 0, .next = &sa1110uart[1], }, { .regs = (void*)UART1REGS, .name = "serialport1", .freq = ClockFreq, .bits = 8, .stop = 1, .parity = 'n', .baud = 115200, .phys = &sa1110physuart, .putc = µcputc, .special = 0, .next = nil, }, }; static Uart* µcuart; #define R(p) ((Uartregs*)((p)->regs)) #define SR(p) ((Uartregs*)((p)->saveregs)) /* * enable a port's interrupts. set DTR and RTS */ static void sa1110_uartenable(Uart *p, int intena) { ulong s; s = R(p)->ctl[3] & ~(Rintena|Tintena|Rena|Tena); if(intena) R(p)->ctl[3] = s |Rintena|Tintena|Rena|Tena; else R(p)->ctl[3] = s | Rena|Tena; } /* * disable interrupts. clear DTR, and RTS */ static void sa1110_uartdisable(Uart *p) { R(p)->ctl[3] &= ~(Rintena|Tintena|Rena|Tena); } static long sa1110_uartstatus(Uart *p, void *buf, long n, long offset) { char str[256]; ulong ctl0; ctl0 = R(p)->ctl[0]; snprint(str, sizeof(str), "b%d c%d d%d e%d l%d m%d p%c r%d s%d i%d\n" "dev(%d) type(%d) framing(%d) overruns(%d)%s%s%s%s\n", p->baud, p->hup_dcd, 0, p->hup_dsr, (ctl0 & Bits8) ? 8 : 7, 0, (ctl0 & Parity) ? ((ctl0 & Even) ? 'e' : 'o') : 'n', 0, (ctl0 & Stop2) ? 2 : 1, 1, p->dev, p->type, p->ferr, p->oerr, "", "", "", "" ); return readstr(offset, buf, n, str); } /* * set the buad rate */ static int sa1110_uartbaud(Uart *p, int rate) { ulong brconst; ulong ctl3; if(rate <= 0) return -1; /* disable */ ctl3 = R(p)->ctl[3]; R(p)->ctl[3] = 0; brconst = p->freq/(16*rate) - 1; R(p)->ctl[1] = (brconst>>8) & 0xf; R(p)->ctl[2] = brconst & 0xff; /* reenable */ R(p)->ctl[3] = ctl3; p->baud = rate; return 0; } /* * send a break */ static void sa1110_uartbreak(Uart *p, int ms) { if(ms == 0) ms = 200; R(p)->ctl[3] |= Break; tsleep(&up->sleep, return0, 0, ms); R(p)->ctl[3] &= ~Break; } /* * set bits/char */ static int sa1110_uartbits(Uart *p, int n) { ulong ctl0, ctl3; ctl0 = R(p)->ctl[0]; switch(n){ case 7: ctl0 &= ~Bits8; break; case 8: ctl0 |= Bits8; break; default: return -1; } /* disable */ ctl3 = R(p)->ctl[3]; R(p)->ctl[3] = 0; R(p)->ctl[0] = ctl0; /* reenable */ R(p)->ctl[3] = ctl3; p->bits = n; return 0; } /* * set stop bits */ static int sa1110_uartstop(Uart *p, int n) { ulong ctl0, ctl3; ctl0 = R(p)->ctl[0]; switch(n){ case 1: ctl0 &= ~Stop2; break; case 2: ctl0 |= Stop2; break; default: return -1; } /* disable */ ctl3 = R(p)->ctl[3]; R(p)->ctl[3] = 0; R(p)->ctl[0] = ctl0; /* reenable */ R(p)->ctl[3] = ctl3; p->stop = n; return 0; } /* * turn on/off rts */ static void sa1110_uartrts(Uart*, int) { } /* * turn on/off dtr */ static void sa1110_uartdtr(Uart*, int) { } /* * turn on/off modem flow control on/off (rts/cts) */ static void sa1110_uartmodemctl(Uart *p, int on) { if(on) { } else { p->cts = 1; } } /* * set parity */ static int sa1110_uartparity(Uart *p, int type) { ulong ctl0, ctl3; ctl0 = R(p)->ctl[0]; switch(type){ case 'e': ctl0 |= Parity|Even; break; case 'o': ctl0 |= Parity; break; default: ctl0 &= ~(Parity|Even); break; } /* disable */ ctl3 = R(p)->ctl[3]; R(p)->ctl[3] = 0; R(p)->ctl[0] = ctl0; /* reenable */ R(p)->ctl[3] = ctl3; return 0; } /* * restart output if not blocked and OK to send */ static void sa1110_uartkick(Uart *p) { int i; R(p)->ctl[3] &= ~Tintena; if(p->cts == 0 || p->blocked) return; for(i = 0; i < 1024; i++){ if(!(R(p)->status[1] & Tnotfull)){ R(p)->ctl[3] |= Tintena; break; } if(p->op >= p->oe && uartstageoutput(p) == 0) break; R(p)->data = *p->op++; } } /* * take an interrupt */ static void sa1110_uartintr(Ureg*, void *x) { Uart *p; ulong s; Uartregs *regs; p = x; regs = p->regs; /* receiver interrupt, snarf bytes */ while(regs->status[1] & Rnotempty) uartrecv(p, regs->data); /* remember and reset interrupt causes */ s = regs->status[0]; regs->status[0] |= s; if(s & Tint){ /* transmitter interrupt, restart */ uartkick(p); } if(s & (ParityError|FrameError|Overrun)){ if(s & ParityError) p->parity++; if(s & FrameError) p->ferr++; if(s & Overrun) p->oerr++; } /* receiver interrupt, snarf bytes */ while(regs->status[1] & Rnotempty) uartrecv(p, regs->data); } static Uart* sa1110_pnp(void) { return sa1110uart; } static int sa1110_getc(Uart *uart) { Uartregs *ur; ur = uart->regs; while((ur->status[1] & Rnotempty) == 0) ; return ur->data; } static void sa1110_putc(Uart *uart, int c) { Uartregs *ur; ur = uart->regs; /* wait for output ready */ while((ur->status[1] & Tnotfull) == 0) ; ur->data = c; while((ur->status[1] & Tbusy)) ; } PhysUart sa1110physuart = { .name= "sa1110", .pnp= sa1110_pnp, .enable= sa1110_uartenable, .disable= sa1110_uartdisable, .bits= sa1110_uartbits, .kick= sa1110_uartkick, .modemctl= sa1110_uartmodemctl, .baud= sa1110_uartbaud, .stop= sa1110_uartstop, .parity= sa1110_uartparity, .dobreak= sa1110_uartbreak, .rts= sa1110_uartrts, .dtr= sa1110_uartdtr, .status= sa1110_uartstatus, .power= sa1110_uartpower, .getc= sa1110_getc, .putc= sa1110_putc, }; /* * for iprint, just write it */ void serialµcputs(uchar *str, int n) { Uartregs *ur; if(µcuart == nil) return; ur = µcuart->regs; while(n-- > 0){ /* wait for output ready */ while((ur->status[1] & Tnotfull) == 0) ; ur->data = *str++; } while((ur->status[1] & Tbusy)) ; } enum { /* gpclk register 0 */ Gpclk_sus= 1<<0, /* set uart mode */ }; Gpclkregs *gpclkregs; /* * setup all uarts (called early by main() to allow debugging output to * a serial port) */ void sa1110_uartsetup(int console) { Uart *p; /* external serial port (eia0) */ p = &sa1110uart[0]; p->regs = mapspecial(UART3REGS, sizeof(Uartregs)); p->saveregs = xalloc(sizeof(Uartregs)); /* set eia0 up as a console */ if(console){ uartctl(p, "b115200 l8 pn s1"); (*p->phys->enable)(p, 0); p->console = 1; consuart = p; } intrenable(IRQ, IRQuart3, sa1110_uartintr, p, p->name); /* port for talking to microcontroller (eia1) */ gpclkregs = mapspecial(GPCLKREGS, sizeof(Gpclkregs)); gpclkregs->r0 = Gpclk_sus; /* set uart mode */ p = &sa1110uart[1]; p->regs = mapspecial(UART1REGS, sizeof(Uartregs)); p->saveregs = xalloc(sizeof(Uartregs)); uartctl(p, "b115200 l8 pn s1"); µcuart = p; p->special = 1; (*p->phys->enable)(p, 0); intrenable(IRQ, IRQuart1b, sa1110_uartintr, p, p->name); } static void uartcpy(Uartregs *to, Uartregs *from) { to->ctl[0] = from->ctl[0]; // to->ctl[1] = from->ctl[1]; // to->ctl[2] = from->ctl[2]; to->ctl[3] = from->ctl[3]; } static void sa1110_uartpower(Uart *p, int powerup) { if (powerup) { /* power up, restore the registers */ uartcpy(R(p), SR(p)); R(p)->status[0] = R(p)->status[0]; } else { /* power down, save the registers */ uartcpy(SR(p), R(p)); } }