/* * * =================================== * HARP | Host ATM Research Platform * =================================== * * * This Host ATM Research Platform ("HARP") file (the "Software") is * made available by Network Computing Services, Inc. ("NetworkCS") * "AS IS". NetworkCS does not provide maintenance, improvements or * support of any kind. * * NETWORKCS MAKES NO WARRANTIES OR REPRESENTATIONS, EXPRESS OR IMPLIED, * INCLUDING, BUT NOT LIMITED TO, IMPLIED WARRANTIES OF MERCHANTABILITY * AND FITNESS FOR A PARTICULAR PURPOSE, AS TO ANY ELEMENT OF THE * SOFTWARE OR ANY SUPPORT PROVIDED IN CONNECTION WITH THIS SOFTWARE. * In no event shall NetworkCS be responsible for any damages, including * but not limited to consequential damages, arising from or relating to * any use of the Software or related support. * * Copyright 1994-1998 Network Computing Services, Inc. * * Copies of this Software may be made, however, the above copyright * notice must be reproduced on all copies. * * @(#) $FreeBSD: src/sys/netatm/port.h,v 1.2.2.2 2003/01/23 21:06:44 sam Exp $ * @(#) $DragonFly: src/sys/netproto/atm/port.h,v 1.9 2006/09/05 17:41:18 dillon Exp $ * */ /* * System Configuration * -------------------- * * Porting aides * */ #ifndef _NETATM_PORT_H #define _NETATM_PORT_H /* * Kernel memory management * * KM_ALLOC(size, type, flags) * Returns an allocated kernel memory chunk of size bytes. * KM_FREE(addr, size, type) * Free a kernel memory chunk of size bytes. * KM_CMP(b1, b2, len) * Compares len bytes of data from b1 against b2. * KM_COPY(from, to, len) * Copies len bytes of data from from to to. * KM_ZERO(addr, len) * Zeros len bytes of data from addr. * */ #ifdef ATM_KERNEL #include #define KM_ALLOC(size, type, flags) kmalloc((size), (type), (flags)) #define KM_FREE(addr, size, type) kfree((addr), (type)) #define KM_CMP(b1, b2, len) bcmp((b1), (b2), (len)) #define KM_COPY(from, to, len) bcopy((from), (to), (len)) #define KM_ZERO(addr, len) bzero((addr), (len)) #define XM_COPY(f, t, l) KM_COPY((f), (t), (l)) #else /* * User-space memory management * * UM_ALLOC(size) Returns an allocated kernel memory chunk of size bytes. * UM_FREE(addr) Free a kernel memory chunk of size bytes. * UM_COPY(from, to, len) * Copies len bytes of data from from to to. * UM_ZERO(addr, len) Zeros len bytes of data from addr. * */ #define UM_ALLOC(size) malloc((size_t)(size)) #define UM_FREE(addr) free((void *)(addr)) #define UM_COPY(from, to, len) bcopy((void *)(from), (void *)(to),\ (size_t)(len)) #define UM_ZERO(addr, len) bzero((void *)(addr), (size_t)(len)) #define XM_COPY(f, t, l) UM_COPY((f), (t), (l)) #endif /* ATM_KERNEL */ #ifdef ATM_KERNEL /* * Kernel buffers * * KBuffer Typedef for a kernel buffer. * * KB_NEXT(bfr) Access next buffer in chain (r/w). * KB_LEN(bfr) Access length of data in this buffer (r/w). * KB_QNEXT(bfr) Access next buffer in queue (r/w). * * KB_ALLOC(bfr, size, flags, type) * Allocates a new kernel buffer of at least size bytes. * KB_ALLOCPKT(bfr, size, flags, type) * Allocates a new kernel packet header buffer of at * least size bytes. * KB_ALLOCEXT(bfr, size, flags, type) * Allocates a new kernel buffer with external storage * of at least size bytes. * KB_FREEONE(bfr, nxt) Free buffer bfr and set next buffer in chain in nxt. * KB_FREEALL(bfr) Free bfr's entire buffer chain. * KB_COPY(bfr, off, len, new, flags) * Copy len bytes of user data from buffer bfr starting at * byte offset off and return new buffer chain in new. * If len is KB_COPYALL, copy until end of chain. * KB_COPYDATA(bfr, off, len, datap) * Copy data from buffer bfr starting at byte offset off * for len bytes into the data area pointed to by datap. * Returns the number of bytes not copied to datap. * KB_PULLUP(bfr, n, new) * Get at least the first n bytes of data in the buffer * chain headed by bfr contiguous in the first buffer. * Returns the (potentially new) head of the chain in new. * On failure the chain is freed and NULL is returned. * KB_LINKHEAD(new, head) * Link the kernel buffer new at the head of the buffer * chain headed by head. If both new and head are * packet header buffers, new will become the packet * header for the chain. * KB_LINK(new, prev) * Link the kernel buffer new into the buffer chain * after the buffer prev. * KB_UNLINKHEAD(head, next) * Unlink the kernel buffer from the head of the buffer * chain headed by head. The buffer head will be freed * and the new chain head will be placed in next. * KB_UNLINK(old, prev, next) * Unlink the kernel buffer old with previous buffer prev * from its buffer chain. The following buffer in the * chain will be placed in next and the buffer old will * be freed. * KB_ISPKT(bfr) Tests whether bfr is a packet header buffer. * KB_ISEXT(bfr) Tests whether bfr has external storage. * KB_BFRSTART(bfr, x, t) * Sets x (cast to type t) to point to the start of the * buffer space in bfr. * KB_BFREND(bfr, x, t) * Sets x (cast to type t) to point one byte past the end * of the buffer space in bfr. * KB_BFRLEN(bfr) Returns length of buffer space in bfr. * KB_DATASTART(bfr, x, t) * Sets x (cast to type t) to point to the start of the * buffer data contained in bfr. * KB_DATAEND(bfr, x, t) * Sets x (cast to type t) to point one byte past the end * of the buffer data contained in bfr. * KB_HEADSET(bfr, n) Sets the start address for buffer data in buffer bfr to * n bytes from the beginning of the buffer space. * KB_HEADMOVE(bfr, n) Adjust buffer data controls to move data down (n > 0) * or up (n < 0) n bytes in the buffer bfr. * KB_HEADADJ(bfr, n) Adjust buffer data controls to add (n > 0) or subtract * (n < 0) n bytes of data to/from the beginning of bfr. * KB_TAILADJ(bfr, n) Adjust buffer data controls to add (n > 0) or subtract * (n < 0) n bytes of data to/from the end of bfr. * KB_TAILALIGN(bfr, n) Set buffer data controls to place an object of size n * at the end of bfr, longword aligned. * KB_HEADROOM(bfr, n) Set n to the amount of buffer space available before * the start of data in bfr. * KB_TAILROOM(bfr, n) Set n to the amount of buffer space available after * the end of data in bfr. * KB_PLENGET(bfr, n) Set n to bfr's packet length. * KB_PLENSET(bfr, n) Set bfr's packet length to n. * KB_PLENADJ(bfr, n) Adjust total packet length by n bytes. * */ #include typedef struct mbuf KBuffer; #define KB_F_WAIT MB_WAIT #define KB_F_NOWAIT MB_DONTWAIT #define KB_T_HEADER MT_HEADER #define KB_T_DATA MT_DATA #define KB_COPYALL M_COPYALL #define KB_NEXT(bfr) (bfr)->m_next #define KB_LEN(bfr) (bfr)->m_len #define KB_QNEXT(bfr) (bfr)->m_nextpkt #define KB_ALLOC(bfr, size, flags, type) { \ if ((size) <= MLEN) { \ MGET((bfr), (flags), (type)); \ } else \ (bfr) = NULL; \ } #define KB_ALLOCPKT(bfr, size, flags, type) { \ if ((size) <= MHLEN) { \ MGETHDR((bfr), (flags), (type)); \ } else \ (bfr) = NULL; \ } #define KB_ALLOCEXT(bfr, size, flags, type) { \ if ((size) <= MCLBYTES) { \ MGET((bfr), (flags), (type)); \ if ((bfr) != NULL) { \ MCLGET((bfr), (flags)); \ if (((bfr)->m_flags & M_EXT) == 0) { \ m_freem((bfr)); \ (bfr) = NULL; \ } \ } \ } else \ (bfr) = NULL; \ } #define KB_FREEONE(bfr, nxt) { \ (nxt) = m_free(bfr); \ } #define KB_FREEALL(bfr) { \ m_freem(bfr); \ } #define KB_COPY(bfr, off, len, new, flags) { \ (new) = m_copym((bfr), (off), (len), (flags)); \ } #define KB_COPYDATA(bfr, off, len, datap) \ (m_copydata((bfr), (off), (len), (datap)), 0) #define KB_PULLUP(bfr, n, new) { \ (new) = m_pullup((bfr), (n)); \ } #define KB_LINKHEAD(new, head) { \ if ((head) && KB_ISPKT(new) && KB_ISPKT(head)) {\ M_MOVE_PKTHDR((new), (head)); \ } \ (new)->m_next = (head); \ } #define KB_LINK(new, prev) { \ (new)->m_next = (prev)->m_next; \ (prev)->m_next = (new); \ } #define KB_UNLINKHEAD(head, next) { \ next = m_free((head)); \ } #define KB_UNLINK(old, prev, next) { \ next = m_free((old)); \ (prev)->m_next = (next); \ } #define KB_ISPKT(bfr) (((bfr)->m_flags & M_PKTHDR) != 0) #define KB_ISEXT(bfr) (((bfr)->m_flags & M_EXT) != 0) #define KB_BFRSTART(bfr, x, t) { \ if ((bfr)->m_flags & M_EXT) \ (x) = (t)((bfr)->m_ext.ext_buf); \ else if ((bfr)->m_flags & M_PKTHDR) \ (x) = (t)(&(bfr)->m_pktdat); \ else \ (x) = (t)((bfr)->m_dat); \ } #define KB_BFREND(bfr, x, t) { \ if ((bfr)->m_flags & M_EXT) \ (x) = (t)((bfr)->m_ext.ext_buf + (bfr)->m_ext.ext_size);\ else if ((bfr)->m_flags & M_PKTHDR) \ (x) = (t)(&(bfr)->m_pktdat + MHLEN); \ else \ (x) = (t)((bfr)->m_dat + MLEN); \ } #define KB_BFRLEN(bfr) \ (((bfr)->m_flags & M_EXT) ? (bfr)->m_ext.ext_size : \ (((bfr)->m_flags & M_PKTHDR) ? MHLEN : MLEN)) #define KB_DATASTART(bfr, x, t) { \ (x) = mtod((bfr), t); \ } #define KB_DATAEND(bfr, x, t) { \ (x) = (t)(mtod((bfr), caddr_t) + (bfr)->m_len); \ } #define KB_HEADSET(bfr, n) { \ if ((bfr)->m_flags & M_EXT) \ (bfr)->m_data = (bfr)->m_ext.ext_buf + (n); \ else if ((bfr)->m_flags & M_PKTHDR) \ (bfr)->m_data = (bfr)->m_pktdat + (n); \ else \ (bfr)->m_data = (bfr)->m_dat + (n); \ } #define KB_HEADMOVE(bfr, n) { \ (bfr)->m_data += (n); \ } #define KB_HEADADJ(bfr, n) { \ (bfr)->m_len += (n); \ (bfr)->m_data -= (n); \ } #define KB_TAILADJ(bfr, n) { \ (bfr)->m_len += (n); \ } #define KB_TAILALIGN(bfr, n) { \ (bfr)->m_len = (n); \ if ((bfr)->m_flags & M_EXT) \ (bfr)->m_data = (caddr_t)(((u_int)(bfr)->m_ext.ext_buf \ + (bfr)->m_ext.ext_size - (n)) & ~(sizeof(long) - 1));\ else \ (bfr)->m_data = (caddr_t)(((u_int)(bfr)->m_dat + MLEN - (n)) \ & ~(sizeof(long) - 1)); \ } #define KB_HEADROOM(bfr, n) { \ /* n = M_LEADINGSPACE(bfr) XXX */ \ (n) = ((bfr)->m_flags & M_EXT ? (bfr)->m_data - (bfr)->m_ext.ext_buf : \ (bfr)->m_flags & M_PKTHDR ? (bfr)->m_data - (bfr)->m_pktdat : \ (bfr)->m_data - (bfr)->m_dat); \ } #define KB_TAILROOM(bfr, n) { \ (n) = M_TRAILINGSPACE(bfr); \ } #define KB_PLENGET(bfr, n) { \ (n) = (bfr)->m_pkthdr.len; \ } #define KB_PLENSET(bfr, n) { \ (bfr)->m_pkthdr.len = (n); \ } #define KB_PLENADJ(bfr, n) { \ (bfr)->m_pkthdr.len += (n); \ } /* * Kernel time * * KTimeout_ret Typedef for timeout() function return * * KT_TIME(t) Sets t to the current time. * */ typedef void KTimeout_ret; #define KT_TIME(t) microtime(&t) #endif /* ATM_KERNEL */ #ifndef MAX #define MAX(a,b) max((a),(b)) #endif #ifndef MIN #define MIN(a,b) min((a),(b)) #endif #endif /* _NETATM_PORT_H */