/* * Copyright (c) 1982, 1986 Regents of the University of California. * All rights reserved. The Berkeley software License Agreement * specifies the terms and conditions for redistribution. * * @(#)if_uba.c 7.5.1.1 (Berkeley) 6/4/87 */ #include "../machine/pte.h" #include "param.h" #include "systm.h" #include "mbuf.h" #include "map.h" #include "buf.h" #include "cmap.h" #include "vmmac.h" #include "socket.h" #include "syslog.h" #include "../net/if.h" #include "../vax/mtpr.h" #include "if_uba.h" #include "../vaxuba/ubareg.h" #include "../vaxuba/ubavar.h" /* * Routines supporting UNIBUS network interfaces. * * TODO: * Support interfaces using only one BDP statically. */ /* * Init UNIBUS for interface on uban whose headers of size hlen are to * end on a page boundary. We allocate a UNIBUS map register for the page * with the header, and nmr more UNIBUS map registers for i/o on the adapter, * doing this once for each read and once for each write buffer. We also * allocate page frames in the mbuffer pool for these pages. */ if_ubaminit(ifu, uban, hlen, nmr, ifr, nr, ifw, nw) register struct ifubinfo *ifu; int uban, hlen, nmr, nr, nw; register struct ifrw *ifr; register struct ifxmt *ifw; { register caddr_t p; caddr_t cp; int i, ncl, off; if (hlen) off = CLBYTES - hlen; else off = 0; ncl = clrnd(nmr) / CLSIZE; if (hlen) ncl++; if (ifr[0].ifrw_addr) cp = ifr[0].ifrw_addr - off; else { cp = m_clalloc((nr + nw) * ncl, MPG_SPACE, M_DONTWAIT); if (cp == 0) return (0); p = cp; for (i = 0; i < nr; i++) { ifr[i].ifrw_addr = p + off; p += ncl * CLBYTES; } for (i = 0; i < nw; i++) { ifw[i].ifw_base = p; ifw[i].ifw_addr = p + off; p += ncl * CLBYTES; } ifu->iff_hlen = hlen; ifu->iff_uban = uban; ifu->iff_uba = uba_hd[uban].uh_uba; } for (i = 0; i < nr; i++) if (if_ubaalloc(ifu, &ifr[i], nmr) == 0) { nr = i; nw = 0; goto bad; } for (i = 0; i < nw; i++) if (if_ubaalloc(ifu, &ifw[i].ifrw, nmr) == 0) { nw = i; goto bad; } while (--nw >= 0) { for (i = 0; i < nmr; i++) ifw[nw].ifw_wmap[i] = ifw[nw].ifw_mr[i]; ifw[nw].ifw_xswapd = 0; ifw[nw].ifw_flags = IFRW_W; ifw[nw].ifw_nmr = nmr; } return (1); bad: while (--nw >= 0) ubarelse(ifu->iff_uban, &ifw[nw].ifw_info); while (--nr >= 0) ubarelse(ifu->iff_uban, &ifr[nr].ifrw_info); m_pgfree(cp, (nr + nw) * ncl); ifr[0].ifrw_addr = 0; return (0); } /* * Setup an ifrw structure by allocating UNIBUS map registers, * possibly a buffered data path, and initializing the fields of * the ifrw structure to minimize run-time overhead. */ static if_ubaalloc(ifu, ifrw, nmr) struct ifubinfo *ifu; register struct ifrw *ifrw; int nmr; { register int info; info = uballoc(ifu->iff_uban, ifrw->ifrw_addr, nmr*NBPG + ifu->iff_hlen, ifu->iff_flags); if (info == 0) return (0); ifrw->ifrw_info = info; ifrw->ifrw_bdp = UBAI_BDP(info); ifrw->ifrw_proto = UBAMR_MRV | (UBAI_BDP(info) << UBAMR_DPSHIFT); ifrw->ifrw_mr = &ifu->iff_uba->uba_map[UBAI_MR(info) + (ifu->iff_hlen? 1 : 0)]; return (1); } /* * Pull read data off a interface. * Len is length of data, with local net header stripped. * Off is non-zero if a trailer protocol was used, and * gives the offset of the trailer information. * We copy the trailer information and then all the normal * data into mbufs. When full cluster sized units are present * on the interface on cluster boundaries we can get them more * easily by remapping, and take advantage of this here. * Prepend a pointer to the interface structure, * so that protocols can determine where incoming packets arrived. * Note: we may be called to receive from a transmit buffer by some * devices. In that case, we must force normal mapping of the buffer, * so that the correct data will appear (only unibus maps are * changed when remapping the transmit buffers). */ struct mbuf * if_ubaget(ifu, ifr, totlen, off0, ifp) struct ifubinfo *ifu; register struct ifrw *ifr; int totlen, off0; struct ifnet *ifp; { struct mbuf *top, **mp; register struct mbuf *m; int off = off0, len; register caddr_t cp = ifr->ifrw_addr + ifu->iff_hlen, pp; top = 0; mp = ⊤ if (ifr->ifrw_flags & IFRW_W) rcv_xmtbuf((struct ifxmt *)ifr); while (totlen > 0) { MGET(m, M_DONTWAIT, MT_DATA); if (m == 0) { m_freem(top); top = 0; goto out; } if (off) { len = totlen - off; cp = ifr->ifrw_addr + ifu->iff_hlen + off; } else len = totlen; if (len >= CLBYTES/2) { struct pte *cpte, *ppte; int x, *ip, i; /* * If doing the first mbuf and * the interface pointer hasn't been put in, * put it in a separate mbuf to preserve alignment. */ if (ifp) { len = 0; goto nopage; } MCLGET(m); if (m->m_len != CLBYTES) goto nopage; m->m_len = MIN(len, CLBYTES); if (!claligned(cp)) goto copy; /* * Switch pages mapped to UNIBUS with new page pp, * as quick form of copy. Remap UNIBUS and invalidate. */ pp = mtod(m, char *); cpte = &Mbmap[mtocl(cp)*CLSIZE]; ppte = &Mbmap[mtocl(pp)*CLSIZE]; x = btop(cp - ifr->ifrw_addr); ip = (int *)&ifr->ifrw_mr[x]; for (i = 0; i < CLSIZE; i++) { struct pte t; t = *ppte; *ppte++ = *cpte; *cpte = t; *ip++ = cpte++->pg_pfnum|ifr->ifrw_proto; mtpr(TBIS, cp); cp += NBPG; mtpr(TBIS, (caddr_t)pp); pp += NBPG; } goto nocopy; } nopage: m->m_off = MMINOFF; if (ifp) { /* * Leave room for ifp. */ m->m_len = MIN(MLEN - sizeof(ifp), len); m->m_off += sizeof(ifp); } else m->m_len = MIN(MLEN, len); copy: bcopy(cp, mtod(m, caddr_t), (unsigned)m->m_len); cp += m->m_len; nocopy: *mp = m; mp = &m->m_next; if (off) { /* sort of an ALGOL-W style for statement... */ off += m->m_len; if (off == totlen) { cp = ifr->ifrw_addr + ifu->iff_hlen; off = 0; totlen = off0; } } else totlen -= m->m_len; if (ifp) { /* * Prepend interface pointer to first mbuf. */ m->m_len += sizeof(ifp); m->m_off -= sizeof(ifp); *(mtod(m, struct ifnet **)) = ifp; ifp = (struct ifnet *)0; } } out: if (ifr->ifrw_flags & IFRW_W) restor_xmtbuf((struct ifxmt *)ifr); return (top); } /* * Change the mapping on a transmit buffer so that if_ubaget may * receive from that buffer. Copy data from any pages mapped to Unibus * into the pages mapped to normal kernel virtual memory, so that * they can be accessed and swapped as usual. We take advantage * of the fact that clusters are placed on the xtofree list * in inverse order, finding the last one. */ static rcv_xmtbuf(ifw) register struct ifxmt *ifw; { register struct mbuf *m; struct mbuf **mprev; register i; char *cp; while (i = ffs((long)ifw->ifw_xswapd)) { cp = ifw->ifw_base + i * CLBYTES; i--; ifw->ifw_xswapd &= ~(1<ifw_xtofree; for (m = ifw->ifw_xtofree; m && m->m_next; m = m->m_next) mprev = &m->m_next; if (m == NULL) break; bcopy(mtod(m, caddr_t), cp, CLBYTES); (void) m_free(m); *mprev = NULL; } ifw->ifw_xswapd = 0; for (i = 0; i < ifw->ifw_nmr; i++) ifw->ifw_mr[i] = ifw->ifw_wmap[i]; } /* * Put a transmit buffer back together after doing an if_ubaget on it, * which may have swapped pages. */ static restor_xmtbuf(ifw) register struct ifxmt *ifw; { register i; for (i = 0; i < ifw->ifw_nmr; i++) ifw->ifw_wmap[i] = ifw->ifw_mr[i]; } /* * Map a chain of mbufs onto a network interface * in preparation for an i/o operation. * The argument chain of mbufs includes the local network * header which is copied to be in the mapped, aligned * i/o space. */ if_ubaput(ifu, ifw, m) struct ifubinfo *ifu; register struct ifxmt *ifw; register struct mbuf *m; { register struct mbuf *mp; register caddr_t cp, dp; register int i; int xswapd = 0; int x, cc, t; cp = ifw->ifw_addr; while (m) { dp = mtod(m, char *); if (claligned(cp) && claligned(dp) && (m->m_len == CLBYTES || m->m_next == (struct mbuf *)0)) { struct pte *pte; int *ip; pte = &Mbmap[mtocl(dp)*CLSIZE]; x = btop(cp - ifw->ifw_addr); ip = (int *)&ifw->ifw_mr[x]; for (i = 0; i < CLSIZE; i++) *ip++ = ifw->ifw_proto | pte++->pg_pfnum; xswapd |= 1 << (x>>(CLSHIFT-PGSHIFT)); mp = m->m_next; m->m_next = ifw->ifw_xtofree; ifw->ifw_xtofree = m; cp += m->m_len; } else { bcopy(mtod(m, caddr_t), cp, (unsigned)m->m_len); cp += m->m_len; MFREE(m, mp); } m = mp; } /* * Xswapd is the set of clusters we just mapped out. Ifu->iff_xswapd * is the set of clusters mapped out from before. We compute * the number of clusters involved in this operation in x. * Clusters mapped out before and involved in this operation * should be unmapped so original pages will be accessed by the device. */ cc = cp - ifw->ifw_addr; x = ((cc - ifu->iff_hlen) + CLBYTES - 1) >> CLSHIFT; ifw->ifw_xswapd &= ~xswapd; while (i = ffs((long)ifw->ifw_xswapd)) { i--; if (i >= x) break; ifw->ifw_xswapd &= ~(1<ifw_mr[i] = ifw->ifw_wmap[i]; i++; } } ifw->ifw_xswapd |= xswapd; return (cc); }