NetBSD/sys/arch/sparc64/include/bsd_openprom.h
1998-06-20 04:58:50 +00:00

328 lines
12 KiB
C

/* $NetBSD: bsd_openprom.h,v 1.1.1.1 1998/06/20 04:58:51 eeh Exp $ */
/*
* Copyright (c) 1992, 1993
* The Regents of the University of California. All rights reserved.
*
* This code is derived from software contributed to Berkeley by
* Jan-Simon Pendry.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. All advertising materials mentioning features or use of this software
* must display the following acknowledgement:
* This product includes software developed by the University of
* California, Berkeley and its contributors.
* 4. Neither the name of the University nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*
* @(#)bsd_openprom.h 8.1 (Berkeley) 6/11/93
*/
/*
* Sun4m support by Aaron Brown, Harvard University.
* Changes Copyright (c) 1995 The President and Fellows of Harvard College.
* All rights reserved.
*/
/*
* This file defines the interface between the kernel and the Openboot PROM.
* N.B.: this has been tested only on interface versions 0 and 2 (we have
* never seen interface version 1).
*/
/*
* The v0 interface tells us what virtual memory to scan to avoid PMEG
* conflicts, but the v2 interface fails to do so, and we must `magically'
* know where the OPENPROM lives in virtual space.
*/
#define OPENPROM_STARTVADDR 0xffd00000
#define OPENPROM_ENDVADDR 0xfff00000
#define OPENPROM_MAGIC 0x10010407
/*
* Version 0 PROM vector device operations (collected here to emphasise that
* they are deprecated). Open and close are obvious. Read and write are
* segregated according to the device type (block, network, or character);
* this is unnecessary and was eliminated from the v2 device operations, but
* we are stuck with it.
*
* Seek is probably only useful on tape devices, since the only character
* devices are the serial ports.
*
* Note that a v0 device name is always exactly two characters ("sd", "le",
* and so forth).
*/
struct v0devops {
int (*v0_open) __P((char *dev));
int (*v0_close) __P((int d));
int (*v0_rbdev) __P((int d, int nblks, int blkno, void *addr));
int (*v0_wbdev) __P((int d, int nblks, int blkno, void *addr));
int (*v0_wnet) __P((int d, int nbytes, void *addr));
int (*v0_rnet) __P((int d, int nbytes, void *addr));
int (*v0_rcdev) __P((int d, int nbytes, int, void *addr));
int (*v0_wcdev) __P((int d, int nbytes, int, void *addr));
int (*v0_seek) __P((int d, long offset, int whence));
};
/*
* Version 2 device operations. Open takes a device `path' such as
* /sbus/le@0,c00000,0 or /sbus/esp@.../sd@0,0, which means it can open
* anything anywhere, without any magic translation.
*
* The memory allocator and map functions are included here even though
* they relate only indirectly to devices (e.g., mmap is good for mapping
* device memory, and drivers need to allocate space in which to record
* the device state).
*/
struct v2devops {
/*
* Convert an `instance handle' (acquired through v2_open()) to
* a `package handle', a.k.a. a `node'.
*/
int (*v2_fd_phandle) __P((int d));
/* Memory allocation and release. */
void *(*v2_malloc) __P((caddr_t va, u_int sz));
void (*v2_free) __P((caddr_t va, u_int sz));
/* Device memory mapper. */
caddr_t (*v2_mmap) __P((caddr_t va, int asi, u_int pa, u_int sz));
void (*v2_munmap) __P((caddr_t va, u_int sz));
/* Device open, close, etc. */
int (*v2_open) __P((char *devpath));
void (*v2_close) __P((int d));
int (*v2_read) __P((int d, void *buf, int nbytes));
int (*v2_write) __P((int d, void *buf, int nbytes));
void (*v2_seek) __P((int d, int hi, int lo));
void (*v2_chain) __P((void)); /* ??? */
void (*v2_release) __P((void)); /* ??? */
};
/*
* The v0 interface describes memory regions with these linked lists.
* (The !$&@#+ v2 interface reformats these as properties, so that we
* have to extract them into local temporary memory and reinterpret them.)
*/
struct v0mlist {
struct v0mlist *next;
caddr_t addr;
u_int nbytes;
};
/*
* V0 gives us three memory lists: Total physical memory, VM reserved to
* the PROM, and available physical memory (which, presumably, is just the
* total minus any pages mapped in the PROM's VM region). We can find the
* reserved PMEGs by scanning the taken VM. Unfortunately, the V2 prom
* forgot to provide taken VM, and we are stuck with scanning ``magic''
* addresses.
*/
struct v0mem {
struct v0mlist **v0_phystot; /* physical memory */
struct v0mlist **v0_vmprom; /* VM used by PROM */
struct v0mlist **v0_physavail; /* available physical memory */
};
/*
* The version 0 PROM breaks up the string given to the boot command and
* leaves the decoded version behind.
*/
struct v0bootargs {
char *ba_argv[8]; /* argv format for boot string */
char ba_args[100]; /* string space */
char ba_bootdev[2]; /* e.g., "sd" for `b sd(...' */
int ba_ctlr; /* controller # */
int ba_unit; /* unit # */
int ba_part; /* partition # */
char *ba_kernel; /* kernel to boot, e.g., "vmunix" */
void *ba_spare0; /* not decoded here XXX */
};
/*
* The version 2 PROM interface uses the more general, if less convenient,
* approach of passing the boot strings unchanged. We also get open file
* numbers for stdin and stdout (keyboard and screen, or whatever), for use
* with the v2 device ops.
*/
struct v2bootargs {
char **v2_bootpath; /* V2: Path to boot device */
char **v2_bootargs; /* V2: Boot args */
int *v2_fd0; /* V2: Stdin descriptor */
int *v2_fd1; /* V2: Stdout descriptor */
};
/*
* The following structure defines the primary PROM vector interface.
* The Boot PROM hands the kernel a pointer to this structure in %o0.
* There are numerous substructures defined below.
*/
struct promvec {
/* Version numbers. */
u_int pv_magic; /* Magic number */
u_int pv_romvec_vers; /* interface version (0, 2) */
u_int pv_plugin_vers; /* ??? */
u_int pv_printrev; /* PROM rev # (* 10, e.g 1.9 = 19) */
/* Version 0 memory descriptors (see below). */
struct v0mem pv_v0mem; /* V0: Memory description lists. */
/* Node operations (see below). */
struct nodeops *pv_nodeops; /* node functions */
char **pv_bootstr; /* Boot command, eg sd(0,0,0)vmunix */
struct v0devops pv_v0devops; /* V0: device ops */
/*
* PROMDEV_* cookies. I fear these may vanish in lieu of fd0/fd1
* (see below) in future PROMs, but for now they work fine.
*/
char *pv_stdin; /* stdin cookie */
char *pv_stdout; /* stdout cookie */
#define PROMDEV_KBD 0 /* input from keyboard */
#define PROMDEV_SCREEN 0 /* output to screen */
#define PROMDEV_TTYA 1 /* in/out to ttya */
#define PROMDEV_TTYB 2 /* in/out to ttyb */
/* Blocking getchar/putchar. NOT REENTRANT! (grr) */
int (*pv_getchar) __P((void));
void (*pv_putchar) __P((int ch));
/* Non-blocking variants that return -1 on error. */
int (*pv_nbgetchar) __P((void));
int (*pv_nbputchar) __P((int ch));
/* Put counted string (can be very slow). */
void (*pv_putstr) __P((char *str, int len));
/* Miscellany. */
void (*pv_reboot) __P((char *bootstr));
void (*pv_printf) __P((const char *fmt, ...));
void (*pv_abort) __P((void)); /* L1-A abort */
int *pv_ticks; /* Ticks since last reset */
__dead void (*pv_halt) __P((void)) __attribute__((noreturn));/* Halt! */
void (**pv_synchook) __P((void)); /* "sync" command hook */
/*
* This eval's a FORTH string. Unfortunately, its interface
* changed between V0 and V2, which gave us much pain.
*/
union {
void (*v0_eval) __P((int len, char *str));
void (*v2_eval) __P((char *str));
} pv_fortheval;
struct v0bootargs **pv_v0bootargs; /* V0: Boot args */
/* Extract Ethernet address from network device. */
u_int (*pv_enaddr) __P((int d, char *enaddr));
struct v2bootargs pv_v2bootargs; /* V2: Boot args + std in/out */
struct v2devops pv_v2devops; /* V2: device operations */
int pv_spare[15];
/*
* The following is machine-dependent.
*
* The sun4c needs a PROM function to set a PMEG for another
* context, so that the kernel can map itself in all contexts.
* It is not possible simply to set the context register, because
* contexts 1 through N may have invalid translations for the
* current program counter. The hardware has a mode in which
* all memory references go to the PROM, so the PROM can do it
* easily.
*/
void (*pv_setctxt) __P((int ctxt, caddr_t va, int pmeg));
#if defined(SUN4M) && defined(notyet)
/*
* The following are V3 ROM functions to handle MP machines in the
* Sun4m series. They have undefined results when run on a uniprocessor!
*/
int (*pv_v3cpustart) __P((u_int module, u_int ctxtbl,
int context, caddr_t pc));
int (*pv_v3cpustop) __P((u_int module));
int (*pv_v3cpuidle) __P((u_int module));
int (*pv_v3cpuresume) __P((u_int module));
#endif
};
/*
* In addition to the global stuff defined in the PROM vectors above,
* the PROM has quite a collection of `nodes'. A node is described by
* an integer---these seem to be internal pointers, actually---and the
* nodes are arranged into an N-ary tree. Each node implements a fixed
* set of functions, as described below. The first two deal with the tree
* structure, allowing traversals in either breadth- or depth-first fashion.
* The rest deal with `properties'.
*
* A node property is simply a name/value pair. The names are C strings
* (NUL-terminated); the values are arbitrary byte strings (counted strings).
* Many values are really just C strings. Sometimes these are NUL-terminated,
* sometimes not, depending on the the interface version; v0 seems to
* terminate and v2 not. Many others are simply integers stored as four
* bytes in machine order: you just get them and go. The third popular
* format is an `address', which is made up of one or more sets of three
* integers as defined below.
*
* N.B.: for the `next' functions, next(0) = first, and next(last) = 0.
* Whoever designed this part had good taste. On the other hand, these
* operation vectors are global, rather than per-node, yet the pointers
* are not in the openprom vectors but rather found by indirection from
* there. So the taste balances out.
*/
struct openprom_addr {
int oa_space; /* address space (may be relative) */
u_int oa_base; /* address within space */
u_int oa_size; /* extent (number of bytes) */
};
struct nodeops {
/*
* Tree traversal.
*/
int (*no_nextnode) __P((int node)); /* next(node) */
int (*no_child) __P((int node)); /* first child */
/*
* Property functions. Proper use of getprop requires calling
* proplen first to make sure it fits. Kind of a pain, but no
* doubt more convenient for the PROM coder.
*/
int (*no_proplen) __P((int node, caddr_t name));
int (*no_getprop) __P((int node, caddr_t name, caddr_t val));
int (*no_setprop) __P((int node, caddr_t name, caddr_t val,
int len));
caddr_t (*no_nextprop) __P((int node, caddr_t name));
};
void romhalt __P((void))
__attribute__((__noreturn__));
void romboot __P((char *))
__attribute__((__noreturn__));
extern struct promvec *promvec;