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322 lines
12 KiB
C
322 lines
12 KiB
C
#ifndef _OS_H_
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#define _OS_H_
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/*
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* OS specific settings for FreeBSD
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*
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* Copyright by UWM - comments to soft-eng@cs.uwm.edu
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*
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* Redistribution and use in source and binary forms, with or without
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* modification, are permitted provided that the following conditions
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* are met:
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* 1. Redistributions of source code must retain the above copyright
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* notice, this list of conditions and the following disclaimer.
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* 2. Redistributions in binary form must reproduce the above copyright
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* notice, this list of conditions and the following disclaimer in the
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* documentation and/or other materials provided with the distribution.
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*
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* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
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* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
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* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
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* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
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* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
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* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
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* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
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* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
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* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
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* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
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* SUCH DAMAGE.
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*
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* This chould be used as an example when porting the driver to a new
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* operating systems.
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*
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* What you should do is to rewrite the soundcard.c and os.h (this file).
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* You should create a new subdirectory and put these two files there.
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* In addition you have to do a makefile.<OS>.
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*
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* If you have to make changes to other than these two files, please contact me
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* before making the changes. It's possible that I have already made the
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* change.
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*
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* $Id$
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*/
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/*
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* Insert here the includes required by your kernel.
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*/
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#include "param.h"
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#include "systm.h"
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#include "ioctl.h"
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#include "tty.h"
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#include "proc.h"
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#include "user.h"
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#include "conf.h"
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#include "file.h"
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#include "uio.h"
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#include "kernel.h"
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#include "syslog.h"
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#include "errno.h"
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#include "malloc.h"
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#include "buf.h"
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#include "i386/isa/isa_device.h"
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/*
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* Rest of the file is compiled only if the driver is really required.
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*/
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#ifdef CONFIGURE_SOUNDCARD
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/*
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* select() is currently implemented in Linux specific way. Don't enable.
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* I don't remember what the SHORT_BANNERS means so forget it.
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*/
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#undef ALLOW_SELECT
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#define SHORT_BANNERS
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/* The soundcard.h could be in a nonstandard place so inclyde it here. */
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#include <machine/soundcard.h>
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/*
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* Here is the first portability problem. Every OS has it's own way to
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* pass a pointer to the buffer in read() and write() calls. In Linux it's
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* just a char*. In BSD it's struct uio. This parameter is passed to
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* all functions called from read() or write(). Since nothing can be
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* assumed about this structure, the driver uses set of macros for
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* accessing the user buffer.
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*
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* The driver reads/writes bytes in the user buffer sequentially which
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* means that calls like uiomove() can be used.
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*
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* snd_rw_buf is the type which is passed to the device file specific
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* read() and write() calls.
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*
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* The following macros are used to move date to and from the
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* user buffer. These macros should be used only when the
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* target or source parameter has snd_rw_buf type.
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* The offs parameter is a offset relative to the beginning of
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* the user buffer. In Linux the offset is required but for example
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* BSD passes the offset info in the uio structure. It could be usefull
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* if these macros verify that the offs parameter and the value in
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* the snd_rw_buf structure are equal.
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*/
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typedef struct uio snd_rw_buf;
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/*
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* Move bytes from the buffer which the application given in a
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* write() call.
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* offs is position relative to the beginning of the buffer in
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* user space. The count is number of bytes to be moved.
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*/
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#define COPY_FROM_USER(target, source, offs, count) \
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do { if (uiomove(target, count, (struct uio *)source)) { \
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printf ("sb: Bad copyin()!\n"); \
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} } while(0)
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/* Like COPY_FOM_USER but for writes. */
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#define COPY_TO_USER(target, offs, source, count) \
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do { if (uiomove(source, count, (struct uio *)target)) { \
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printf ("sb: Bad copyout()!\n"); \
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} } while(0)
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/*
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* The following macros are like COPY_*_USER but work just with one byte (8bit),
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* short (16 bit) or long (32 bit) at a time.
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* The same restrictions apply than for COPY_*_USER
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*/
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#define GET_BYTE_FROM_USER(target, addr, offs) {uiomove((char*)&(target), 1, (struct uio *)addr);}
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#define GET_SHORT_FROM_USER(target, addr, offs) {uiomove((char*)&(target), 2, (struct uio *)addr);}
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#define GET_WORD_FROM_USER(target, addr, offs) {uiomove((char*)&(target), 4, (struct uio *)addr);}
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#define PUT_WORD_TO_USER(addr, offs, data) {uiomove((char*)&(data), 4, (struct uio *)addr);}
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/*
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* The way how the ioctl arguments are passed is another nonportable thing.
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* In Linux the argument is just a pointer directly to the user segment. On
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* 386bsd the data is already moved to the kernel space. The following
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* macros should handle the difference.
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*/
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/*
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* IOCTL_FROM_USER is used to copy a record pointed by the argument to
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* a buffer in the kernel space. On 386bsd it can be done just by calling
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* memcpy. With Linux a memcpy_from_fs should be called instead.
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* Parameters of the following macros are like in the COPY_*_USER macros.
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*/
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/*
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* When the ioctl argument points to a record or array (longer than 32 bits),
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* the macros IOCTL_*_USER are used. It's assumed that the source and target
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* parameters are direct memory addresses.
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*/
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#define IOCTL_FROM_USER(target, source, offs, count) {memcpy(target, &((source)[offs]), count);}
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#define IOCTL_TO_USER(target, offs, source, count) {memcpy(&((target)[offs]), source, count);}
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/* The following macros are used if the ioctl argument points to 32 bit int */
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#define IOCTL_IN(arg) (*(int*)arg)
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#define IOCTL_OUT(arg, ret) *(int*)arg = ret
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/*
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* When the driver displays something to the console, printk() will be called.
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* The name can be changed here.
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*/
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#define printk printf
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/*
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* The following macros define an interface to the process management.
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*/
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struct snd_wait {
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int mode; int aborting;
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};
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/*
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* DEFINE_WAIT_QUEUE is used where a wait queue is required. It must define
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* a structure which can be passed as a parameter to a sleep(). The second
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* parameter is name of a flag variable (must be defined as int).
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*/
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#define DEFINE_WAIT_QUEUE(qname, flag) static int *qname = NULL; \
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static volatile struct snd_wait flag = {0}
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/* Like the above but defines an array of wait queues and flags */
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#define DEFINE_WAIT_QUEUES(qname, flag) static int *qname = {NULL}; \
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static volatile struct snd_wait flag = {{0}}
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#define RESET_WAIT_QUEUE(q, f) {f.aborting = 0;f.mode = WK_NONE;}
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#define SET_ABORT_FLAG(q, f) f.aborting = 1
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#define TIMED_OUT(q, f) (f.mode & WK_TIMEOUT)
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#define SOMEONE_WAITING(q, f) (f.mode & WK_SLEEP)
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/*
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* This driver handles interrupts little bit nonstandard way. The following
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* macro is used to test if the current process has received a signal which
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* is aborts the process. This macro is called from close() to see if the
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* buffers should be discarded. If this kind info is not available, a constant
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* 1 or 0 could be returned (1 should be better than 0).
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* I'm not sure if the following is correct for FreeBSD.
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*/
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#define PROCESS_ABORTING(q, f) (f.aborting | curproc->p_siglist)
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/*
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* The following macro calls sleep. It should be implemented such that
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* the process is resumed if it receives a signal. The following is propably
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* not the way how it should be done on 386bsd.
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* The on_what parameter is a wait_queue defined with DEFINE_WAIT_QUEUE(),
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* and the second is a workarea parameter. The third is a timeout
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* in ticks. Zero means no timeout.
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*/
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#define DO_SLEEP(q, f, time_limit) \
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{ \
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int flag, chn; \
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f.mode = WK_SLEEP; \
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q = &chn; \
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flag=tsleep((caddr_t)&(chn), (PRIBIO-5)|PCATCH, "sndint", time_limit); \
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if(flag == ERESTART) f.aborting = 1;\
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else f.aborting = 0;\
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f.mode &= ~WK_SLEEP; \
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}
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/* An the following wakes up a process */
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#define WAKE_UP(q, f) {f.mode = WK_WAKEUP;wakeup((caddr_t)q);}
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/*
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* Timing macros. This driver assumes that there is a timer running in the
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* kernel. The timer should return a value which is increased once at every
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* timer tick. The macro HZ should return the number of such ticks/sec.
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*/
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#ifndef HZ
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extern int hz;
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#define HZ hz
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#endif
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/*
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* GET_TIME() returns current value of the counter incremented at timer
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* ticks. This can overflow, so the timeout might be real big...
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*
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*/
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extern unsigned long get_time(void);
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#define GET_TIME() get_time()
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/*#define GET_TIME() (lbolt) */ /* Returns current time (1/HZ secs since boot) */
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/*
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* The following three macros are called before and after atomic
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* code sequences. The flags parameter has always type of unsigned long.
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* The macro DISABLE_INTR() should ensure that all interrupts which
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* may invoke any part of the driver (timer, soundcard interrupts) are
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* disabled.
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* RESTORE_INTR() should return the interrupt status back to the
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* state when DISABLE_INTR() was called. The flags parameter is
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* a variable which can carry 32 bits of state information between
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* DISABLE_INTR() and RESTORE_INTR() calls.
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*/
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#define DISABLE_INTR(flags) flags = splhigh()
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#define RESTORE_INTR(flags) splx(flags)
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/*
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* INB() and OUTB() should be obvious. NOTE! The order of
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* paratemeters of OUTB() is different than on some other
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* operating systems.
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*/
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#define INB inb
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/*
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* The outb(0, 0x80) is just for slowdown. It's bit unsafe since
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* this address could be used for something usefull.
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*/
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#define OUTB(addr, data) {outb(data, addr);outb(0, 0x80);}
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/* memcpy() was not defined og 386bsd. Lets define it here */
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#define memcpy(d, s, c) bcopy(s, d, c)
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/*
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* When a error (such as EINVAL) is returned by a function,
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* the following macro is used. The driver assumes that a
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* error is signalled by returning a negative value.
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*/
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#define RET_ERROR(err) -(err)
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/*
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KERNEL_MALLOC() allocates requested number of memory and
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KERNEL_FREE is used to free it.
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These macros are never called from interrupt, in addition the
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nbytes will never be more than 4096 bytes. Generally the driver
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will allocate memory in blocks of 4k. If the kernel has just a
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page level memory allocation, 4K can be safely used as the size
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(the nbytes parameter can be ignored).
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*/
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#define KERNEL_MALLOC(nbytes) malloc(nbytes, M_TEMP, M_WAITOK)
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#define KERNEL_FREE(addr) free(addr, M_TEMP)
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/*
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* The macro PERMANENT_MALLOC(typecast, mem_ptr, size, linux_ptr)
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* returns size bytes of
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* (kernel virtual) memory which will never get freed by the driver.
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* This macro is called only during boot. The linux_ptr is a linux specific
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* parameter which should be ignored in other operating systems.
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* The mem_ptr is a pointer variable where the macro assigns pointer to the
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* memory area. The type is the type of the mem_ptr.
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*/
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#define PERMANENT_MALLOC(typecast, mem_ptr, size, linux_ptr) \
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(mem_ptr) = (typecast)malloc((size), M_TEMP, M_WAITOK)
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/*
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* The macro DEFINE_TIMER defines variables for the ACTIVATE_TIMER if
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* required. The name is the variable/name to be used and the proc is
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* the procedure to be called when the timer expires.
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*/
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#define DEFINE_TIMER(name, proc)
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/*
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* The ACTIVATE_TIMER requests system to call 'proc' after 'time' ticks.
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*/
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#define ACTIVATE_TIMER(name, proc, time) \
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timeout((timeout_func_t)proc, 0, time);
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/*
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* The rest of this file is not complete yet. The functions using these
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* macros will not work
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*/
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#define ALLOC_DMA_CHN(chn) ({ 0; })
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#define RELEASE_DMA_CHN(chn) ({ 0; })
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#define DMA_MODE_READ 0
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#define DMA_MODE_WRITE 1
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#define RELEASE_IRQ(irq_no)
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#endif
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#endif
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