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linux_dsm_epyc7002/drivers/isdn/hardware/mISDN/isdnhdlc.c
David S. Miller 8a7e8ff8ce isdn: deprecate non-mISDN drivers 
When isdn4linux came up in the context of another patch series, I
 remembered that we had discussed removing it a while ago.
 
 It turns out that the suggestion from Karsten Keil wa to remove I4L
 in 2018 after the last public ISDN networks are shut down. This has
 happened now (with a very small number of exceptions), so I guess it's
 time to try again.
 
 We currently have three ISDN stacks in the kernel: the original
 isdn4linux (with the hisax driver), the newer CAPI (with four drivers),
 and finally the mISDN stack (supporting roughly the same hardware as
 hisax).
 
 As far as I can tell, anyone using ISDN with mainline kernel drivers in
 the past few years uses mISDN, and this is typically used for voice-only
 PBX installations that don't require a public network.
 
 The older stacks support additional features for data networks, but those
 typically make no sense any more if there is no network to connect to.
 
 My proposal for this time is to kill off isdn4linux entirely, as it seems
 to have been unusable for quite a while. This code has been abandoned
 for many years and it does cause problems for treewide maintenance as
 it tends to do everything that we try to stop doing.
 Birger Harzenetter mentioned that is is still using i4l in order to
 make use of the 'divert' feature that is not part of mISDN, but has
 otherwise moved on to mISDN for normal operation, like apparently
 everyone else.
 
 CAPI in turn is not quite as obsolete, but two of the drivers (avm
 and hysdn) don't seem to be used at all, while another one (gigaset)
 will stop being maintained as Paul Bolle is no longer able to
 test it after the network gets shut down in September.
 All three are now moved into drivers/staging to let others speak
 up in case there are remaining users.
 This leaves Bluetooth CMTP as the only remaining user of CAPI, but
 Marcel Holtmann wishes to keep maintaining it.
 
 For the discussion on version 1, see [2]
 Unfortunately, Karsten Keil as the maintainer has not participated in
 the discussion.
 
       Arnd
 
 [1] https://patchwork.kernel.org/patch/8484861/#17900371
 [2] https://listserv.isdn4linux.de/pipermail/isdn4linux/2019-April/thread.html
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Merge tag 'isdn-removal' of https://git.kernel.org/pub/scm/linux/kernel/git/arnd/playground

Arnd Bergmann says:

====================
isdn: deprecate non-mISDN drivers

When isdn4linux came up in the context of another patch series, I
remembered that we had discussed removing it a while ago.

It turns out that the suggestion from Karsten Keil wa to remove I4L
in 2018 after the last public ISDN networks are shut down. This has
happened now (with a very small number of exceptions), so I guess it's
time to try again.

We currently have three ISDN stacks in the kernel: the original
isdn4linux (with the hisax driver), the newer CAPI (with four drivers),
and finally the mISDN stack (supporting roughly the same hardware as
hisax).

As far as I can tell, anyone using ISDN with mainline kernel drivers in
the past few years uses mISDN, and this is typically used for voice-only
PBX installations that don't require a public network.

The older stacks support additional features for data networks, but those
typically make no sense any more if there is no network to connect to.

My proposal for this time is to kill off isdn4linux entirely, as it seems
to have been unusable for quite a while. This code has been abandoned
for many years and it does cause problems for treewide maintenance as
it tends to do everything that we try to stop doing.
Birger Harzenetter mentioned that is is still using i4l in order to
make use of the 'divert' feature that is not part of mISDN, but has
otherwise moved on to mISDN for normal operation, like apparently
everyone else.

CAPI in turn is not quite as obsolete, but two of the drivers (avm
and hysdn) don't seem to be used at all, while another one (gigaset)
will stop being maintained as Paul Bolle is no longer able to
test it after the network gets shut down in September.
All three are now moved into drivers/staging to let others speak
up in case there are remaining users.
This leaves Bluetooth CMTP as the only remaining user of CAPI, but
Marcel Holtmann wishes to keep maintaining it.

For the discussion on version 1, see [2]
Unfortunately, Karsten Keil as the maintainer has not participated in
the discussion.

      Arnd

[1] https://patchwork.kernel.org/patch/8484861/#17900371
[2] https://listserv.isdn4linux.de/pipermail/isdn4linux/2019-April/thread.html
====================

Signed-off-by: David S. Miller <davem@davemloft.net>
2019-06-02 17:48:58 -07:00

618 lines
15 KiB
C
Raw Blame History

// SPDX-License-Identifier: GPL-2.0-or-later
/*
* isdnhdlc.c -- General purpose ISDN HDLC decoder.
*
* Copyright (C)
* 2009 Karsten Keil <keil@b1-systems.de>
* 2002 Wolfgang Mües <wolfgang@iksw-muees.de>
* 2001 Frode Isaksen <fisaksen@bewan.com>
* 2001 Kai Germaschewski <kai.germaschewski@gmx.de>
*/
#include <linux/module.h>
#include <linux/init.h>
#include <linux/crc-ccitt.h>
#include <linux/bitrev.h>
#include "isdnhdlc.h"
/*-------------------------------------------------------------------*/
MODULE_AUTHOR("Wolfgang Mües <wolfgang@iksw-muees.de>, "
"Frode Isaksen <fisaksen@bewan.com>, "
"Kai Germaschewski <kai.germaschewski@gmx.de>");
MODULE_DESCRIPTION("General purpose ISDN HDLC decoder");
MODULE_LICENSE("GPL");
/*-------------------------------------------------------------------*/
enum {
HDLC_FAST_IDLE, HDLC_GET_FLAG_B0, HDLC_GETFLAG_B1A6, HDLC_GETFLAG_B7,
HDLC_GET_DATA, HDLC_FAST_FLAG
};
enum {
HDLC_SEND_DATA, HDLC_SEND_CRC1, HDLC_SEND_FAST_FLAG,
HDLC_SEND_FIRST_FLAG, HDLC_SEND_CRC2, HDLC_SEND_CLOSING_FLAG,
HDLC_SEND_IDLE1, HDLC_SEND_FAST_IDLE, HDLC_SENDFLAG_B0,
HDLC_SENDFLAG_B1A6, HDLC_SENDFLAG_B7, STOPPED, HDLC_SENDFLAG_ONE
};
void isdnhdlc_rcv_init(struct isdnhdlc_vars *hdlc, u32 features)
{
memset(hdlc, 0, sizeof(struct isdnhdlc_vars));
hdlc->state = HDLC_GET_DATA;
if (features & HDLC_56KBIT)
hdlc->do_adapt56 = 1;
if (features & HDLC_BITREVERSE)
hdlc->do_bitreverse = 1;
}
EXPORT_SYMBOL(isdnhdlc_out_init);
void isdnhdlc_out_init(struct isdnhdlc_vars *hdlc, u32 features)
{
memset(hdlc, 0, sizeof(struct isdnhdlc_vars));
if (features & HDLC_DCHANNEL) {
hdlc->dchannel = 1;
hdlc->state = HDLC_SEND_FIRST_FLAG;
} else {
hdlc->dchannel = 0;
hdlc->state = HDLC_SEND_FAST_FLAG;
hdlc->ffvalue = 0x7e;
}
hdlc->cbin = 0x7e;
if (features & HDLC_56KBIT) {
hdlc->do_adapt56 = 1;
hdlc->state = HDLC_SENDFLAG_B0;
} else
hdlc->data_bits = 8;
if (features & HDLC_BITREVERSE)
hdlc->do_bitreverse = 1;
}
EXPORT_SYMBOL(isdnhdlc_rcv_init);
static int
check_frame(struct isdnhdlc_vars *hdlc)
{
int status;
if (hdlc->dstpos < 2) /* too small - framing error */
status = -HDLC_FRAMING_ERROR;
else if (hdlc->crc != 0xf0b8) /* crc error */
status = -HDLC_CRC_ERROR;
else {
/* remove CRC */
hdlc->dstpos -= 2;
/* good frame */
status = hdlc->dstpos;
}
return status;
}
/*
isdnhdlc_decode - decodes HDLC frames from a transparent bit stream.
The source buffer is scanned for valid HDLC frames looking for
flags (01111110) to indicate the start of a frame. If the start of
the frame is found, the bit stuffing is removed (0 after 5 1's).
When a new flag is found, the complete frame has been received
and the CRC is checked.
If a valid frame is found, the function returns the frame length
excluding the CRC with the bit HDLC_END_OF_FRAME set.
If the beginning of a valid frame is found, the function returns
the length.
If a framing error is found (too many 1s and not a flag) the function
returns the length with the bit HDLC_FRAMING_ERROR set.
If a CRC error is found the function returns the length with the
bit HDLC_CRC_ERROR set.
If the frame length exceeds the destination buffer size, the function
returns the length with the bit HDLC_LENGTH_ERROR set.
src - source buffer
slen - source buffer length
count - number of bytes removed (decoded) from the source buffer
dst _ destination buffer
dsize - destination buffer size
returns - number of decoded bytes in the destination buffer and status
flag.
*/
int isdnhdlc_decode(struct isdnhdlc_vars *hdlc, const u8 *src, int slen,
int *count, u8 *dst, int dsize)
{
int status = 0;
static const unsigned char fast_flag[] = {
0x00, 0x00, 0x00, 0x20, 0x30, 0x38, 0x3c, 0x3e, 0x3f
};
static const unsigned char fast_flag_value[] = {
0x00, 0x7e, 0xfc, 0xf9, 0xf3, 0xe7, 0xcf, 0x9f, 0x3f
};
static const unsigned char fast_abort[] = {
0x00, 0x00, 0x80, 0xc0, 0xe0, 0xf0, 0xf8, 0xfc, 0xfe, 0xff
};
#define handle_fast_flag(h) \
do { \
if (h->cbin == fast_flag[h->bit_shift]) { \
h->ffvalue = fast_flag_value[h->bit_shift]; \
h->state = HDLC_FAST_FLAG; \
h->ffbit_shift = h->bit_shift; \
h->bit_shift = 1; \
} else { \
h->state = HDLC_GET_DATA; \
h->data_received = 0; \
} \
} while (0)
#define handle_abort(h) \
do { \
h->shift_reg = fast_abort[h->ffbit_shift - 1]; \
h->hdlc_bits1 = h->ffbit_shift - 2; \
if (h->hdlc_bits1 < 0) \
h->hdlc_bits1 = 0; \
h->data_bits = h->ffbit_shift - 1; \
h->state = HDLC_GET_DATA; \
h->data_received = 0; \
} while (0)
*count = slen;
while (slen > 0) {
if (hdlc->bit_shift == 0) {
/* the code is for bitreverse streams */
if (hdlc->do_bitreverse == 0)
hdlc->cbin = bitrev8(*src++);
else
hdlc->cbin = *src++;
slen--;
hdlc->bit_shift = 8;
if (hdlc->do_adapt56)
hdlc->bit_shift--;
}
switch (hdlc->state) {
case STOPPED:
return 0;
case HDLC_FAST_IDLE:
if (hdlc->cbin == 0xff) {
hdlc->bit_shift = 0;
break;
}
hdlc->state = HDLC_GET_FLAG_B0;
hdlc->hdlc_bits1 = 0;
hdlc->bit_shift = 8;
break;
case HDLC_GET_FLAG_B0:
if (!(hdlc->cbin & 0x80)) {
hdlc->state = HDLC_GETFLAG_B1A6;
hdlc->hdlc_bits1 = 0;
} else {
if ((!hdlc->do_adapt56) &&
(++hdlc->hdlc_bits1 >= 8) &&
(hdlc->bit_shift == 1))
hdlc->state = HDLC_FAST_IDLE;
}
hdlc->cbin <<= 1;
hdlc->bit_shift--;
break;
case HDLC_GETFLAG_B1A6:
if (hdlc->cbin & 0x80) {
hdlc->hdlc_bits1++;
if (hdlc->hdlc_bits1 == 6)
hdlc->state = HDLC_GETFLAG_B7;
} else
hdlc->hdlc_bits1 = 0;
hdlc->cbin <<= 1;
hdlc->bit_shift--;
break;
case HDLC_GETFLAG_B7:
if (hdlc->cbin & 0x80) {
hdlc->state = HDLC_GET_FLAG_B0;
} else {
hdlc->state = HDLC_GET_DATA;
hdlc->crc = 0xffff;
hdlc->shift_reg = 0;
hdlc->hdlc_bits1 = 0;
hdlc->data_bits = 0;
hdlc->data_received = 0;
}
hdlc->cbin <<= 1;
hdlc->bit_shift--;
break;
case HDLC_GET_DATA:
if (hdlc->cbin & 0x80) {
hdlc->hdlc_bits1++;
switch (hdlc->hdlc_bits1) {
case 6:
break;
case 7:
if (hdlc->data_received)
/* bad frame */
status = -HDLC_FRAMING_ERROR;
if (!hdlc->do_adapt56) {
if (hdlc->cbin == fast_abort
[hdlc->bit_shift + 1]) {
hdlc->state =
HDLC_FAST_IDLE;
hdlc->bit_shift = 1;
break;
}
} else
hdlc->state = HDLC_GET_FLAG_B0;
break;
default:
hdlc->shift_reg >>= 1;
hdlc->shift_reg |= 0x80;
hdlc->data_bits++;
break;
}
} else {
switch (hdlc->hdlc_bits1) {
case 5:
break;
case 6:
if (hdlc->data_received)
status = check_frame(hdlc);
hdlc->crc = 0xffff;
hdlc->shift_reg = 0;
hdlc->data_bits = 0;
if (!hdlc->do_adapt56)
handle_fast_flag(hdlc);
else {
hdlc->state = HDLC_GET_DATA;
hdlc->data_received = 0;
}
break;
default:
hdlc->shift_reg >>= 1;
hdlc->data_bits++;
break;
}
hdlc->hdlc_bits1 = 0;
}
if (status) {
hdlc->dstpos = 0;
*count -= slen;
hdlc->cbin <<= 1;
hdlc->bit_shift--;
return status;
}
if (hdlc->data_bits == 8) {
hdlc->data_bits = 0;
hdlc->data_received = 1;
hdlc->crc = crc_ccitt_byte(hdlc->crc,
hdlc->shift_reg);
/* good byte received */
if (hdlc->dstpos < dsize)
dst[hdlc->dstpos++] = hdlc->shift_reg;
else {
/* frame too long */
status = -HDLC_LENGTH_ERROR;
hdlc->dstpos = 0;
}
}
hdlc->cbin <<= 1;
hdlc->bit_shift--;
break;
case HDLC_FAST_FLAG:
if (hdlc->cbin == hdlc->ffvalue) {
hdlc->bit_shift = 0;
break;
} else {
if (hdlc->cbin == 0xff) {
hdlc->state = HDLC_FAST_IDLE;
hdlc->bit_shift = 0;
} else if (hdlc->ffbit_shift == 8) {
hdlc->state = HDLC_GETFLAG_B7;
break;
} else
handle_abort(hdlc);
}
break;
default:
break;
}
}
*count -= slen;
return 0;
}
EXPORT_SYMBOL(isdnhdlc_decode);
/*
isdnhdlc_encode - encodes HDLC frames to a transparent bit stream.
The bit stream starts with a beginning flag (01111110). After
that each byte is added to the bit stream with bit stuffing added
(0 after 5 1's).
When the last byte has been removed from the source buffer, the
CRC (2 bytes is added) and the frame terminates with the ending flag.
For the dchannel, the idle character (all 1's) is also added at the end.
If this function is called with empty source buffer (slen=0), flags or
idle character will be generated.
src - source buffer
slen - source buffer length
count - number of bytes removed (encoded) from source buffer
dst _ destination buffer
dsize - destination buffer size
returns - number of encoded bytes in the destination buffer
*/
int isdnhdlc_encode(struct isdnhdlc_vars *hdlc, const u8 *src, u16 slen,
int *count, u8 *dst, int dsize)
{
static const unsigned char xfast_flag_value[] = {
0x7e, 0x3f, 0x9f, 0xcf, 0xe7, 0xf3, 0xf9, 0xfc, 0x7e
};
int len = 0;
*count = slen;
/* special handling for one byte frames */
if ((slen == 1) && (hdlc->state == HDLC_SEND_FAST_FLAG))
hdlc->state = HDLC_SENDFLAG_ONE;
while (dsize > 0) {
if (hdlc->bit_shift == 0) {
if (slen && !hdlc->do_closing) {
hdlc->shift_reg = *src++;
slen--;
if (slen == 0)
/* closing sequence, CRC + flag(s) */
hdlc->do_closing = 1;
hdlc->bit_shift = 8;
} else {
if (hdlc->state == HDLC_SEND_DATA) {
if (hdlc->data_received) {
hdlc->state = HDLC_SEND_CRC1;
hdlc->crc ^= 0xffff;
hdlc->bit_shift = 8;
hdlc->shift_reg =
hdlc->crc & 0xff;
} else if (!hdlc->do_adapt56)
hdlc->state =
HDLC_SEND_FAST_FLAG;
else
hdlc->state =
HDLC_SENDFLAG_B0;
}
}
}
switch (hdlc->state) {
case STOPPED:
while (dsize--)
*dst++ = 0xff;
return dsize;
case HDLC_SEND_FAST_FLAG:
hdlc->do_closing = 0;
if (slen == 0) {
/* the code is for bitreverse streams */
if (hdlc->do_bitreverse == 0)
*dst++ = bitrev8(hdlc->ffvalue);
else
*dst++ = hdlc->ffvalue;
len++;
dsize--;
break;
}
/* fall through */
case HDLC_SENDFLAG_ONE:
if (hdlc->bit_shift == 8) {
hdlc->cbin = hdlc->ffvalue >>
(8 - hdlc->data_bits);
hdlc->state = HDLC_SEND_DATA;
hdlc->crc = 0xffff;
hdlc->hdlc_bits1 = 0;
hdlc->data_received = 1;
}
break;
case HDLC_SENDFLAG_B0:
hdlc->do_closing = 0;
hdlc->cbin <<= 1;
hdlc->data_bits++;
hdlc->hdlc_bits1 = 0;
hdlc->state = HDLC_SENDFLAG_B1A6;
break;
case HDLC_SENDFLAG_B1A6:
hdlc->cbin <<= 1;
hdlc->data_bits++;
hdlc->cbin++;
if (++hdlc->hdlc_bits1 == 6)
hdlc->state = HDLC_SENDFLAG_B7;
break;
case HDLC_SENDFLAG_B7:
hdlc->cbin <<= 1;
hdlc->data_bits++;
if (slen == 0) {
hdlc->state = HDLC_SENDFLAG_B0;
break;
}
if (hdlc->bit_shift == 8) {
hdlc->state = HDLC_SEND_DATA;
hdlc->crc = 0xffff;
hdlc->hdlc_bits1 = 0;
hdlc->data_received = 1;
}
break;
case HDLC_SEND_FIRST_FLAG:
hdlc->data_received = 1;
if (hdlc->data_bits == 8) {
hdlc->state = HDLC_SEND_DATA;
hdlc->crc = 0xffff;
hdlc->hdlc_bits1 = 0;
break;
}
hdlc->cbin <<= 1;
hdlc->data_bits++;
if (hdlc->shift_reg & 0x01)
hdlc->cbin++;
hdlc->shift_reg >>= 1;
hdlc->bit_shift--;
if (hdlc->bit_shift == 0) {
hdlc->state = HDLC_SEND_DATA;
hdlc->crc = 0xffff;
hdlc->hdlc_bits1 = 0;
}
break;
case HDLC_SEND_DATA:
hdlc->cbin <<= 1;
hdlc->data_bits++;
if (hdlc->hdlc_bits1 == 5) {
hdlc->hdlc_bits1 = 0;
break;
}
if (hdlc->bit_shift == 8)
hdlc->crc = crc_ccitt_byte(hdlc->crc,
hdlc->shift_reg);
if (hdlc->shift_reg & 0x01) {
hdlc->hdlc_bits1++;
hdlc->cbin++;
hdlc->shift_reg >>= 1;
hdlc->bit_shift--;
} else {
hdlc->hdlc_bits1 = 0;
hdlc->shift_reg >>= 1;
hdlc->bit_shift--;
}
break;
case HDLC_SEND_CRC1:
hdlc->cbin <<= 1;
hdlc->data_bits++;
if (hdlc->hdlc_bits1 == 5) {
hdlc->hdlc_bits1 = 0;
break;
}
if (hdlc->shift_reg & 0x01) {
hdlc->hdlc_bits1++;
hdlc->cbin++;
hdlc->shift_reg >>= 1;
hdlc->bit_shift--;
} else {
hdlc->hdlc_bits1 = 0;
hdlc->shift_reg >>= 1;
hdlc->bit_shift--;
}
if (hdlc->bit_shift == 0) {
hdlc->shift_reg = (hdlc->crc >> 8);
hdlc->state = HDLC_SEND_CRC2;
hdlc->bit_shift = 8;
}
break;
case HDLC_SEND_CRC2:
hdlc->cbin <<= 1;
hdlc->data_bits++;
if (hdlc->hdlc_bits1 == 5) {
hdlc->hdlc_bits1 = 0;
break;
}
if (hdlc->shift_reg & 0x01) {
hdlc->hdlc_bits1++;
hdlc->cbin++;
hdlc->shift_reg >>= 1;
hdlc->bit_shift--;
} else {
hdlc->hdlc_bits1 = 0;
hdlc->shift_reg >>= 1;
hdlc->bit_shift--;
}
if (hdlc->bit_shift == 0) {
hdlc->shift_reg = 0x7e;
hdlc->state = HDLC_SEND_CLOSING_FLAG;
hdlc->bit_shift = 8;
}
break;
case HDLC_SEND_CLOSING_FLAG:
hdlc->cbin <<= 1;
hdlc->data_bits++;
if (hdlc->hdlc_bits1 == 5) {
hdlc->hdlc_bits1 = 0;
break;
}
if (hdlc->shift_reg & 0x01)
hdlc->cbin++;
hdlc->shift_reg >>= 1;
hdlc->bit_shift--;
if (hdlc->bit_shift == 0) {
hdlc->ffvalue =
xfast_flag_value[hdlc->data_bits];
if (hdlc->dchannel) {
hdlc->ffvalue = 0x7e;
hdlc->state = HDLC_SEND_IDLE1;
hdlc->bit_shift = 8-hdlc->data_bits;
if (hdlc->bit_shift == 0)
hdlc->state =
HDLC_SEND_FAST_IDLE;
} else {
if (!hdlc->do_adapt56) {
hdlc->state =
HDLC_SEND_FAST_FLAG;
hdlc->data_received = 0;
} else {
hdlc->state = HDLC_SENDFLAG_B0;
hdlc->data_received = 0;
}
/* Finished this frame, send flags */
if (dsize > 1)
dsize = 1;
}
}
break;
case HDLC_SEND_IDLE1:
hdlc->do_closing = 0;
hdlc->cbin <<= 1;
hdlc->cbin++;
hdlc->data_bits++;
hdlc->bit_shift--;
if (hdlc->bit_shift == 0) {
hdlc->state = HDLC_SEND_FAST_IDLE;
hdlc->bit_shift = 0;
}
break;
case HDLC_SEND_FAST_IDLE:
hdlc->do_closing = 0;
hdlc->cbin = 0xff;
hdlc->data_bits = 8;
if (hdlc->bit_shift == 8) {
hdlc->cbin = 0x7e;
hdlc->state = HDLC_SEND_FIRST_FLAG;
} else {
/* the code is for bitreverse streams */
if (hdlc->do_bitreverse == 0)
*dst++ = bitrev8(hdlc->cbin);
else
*dst++ = hdlc->cbin;
hdlc->bit_shift = 0;
hdlc->data_bits = 0;
len++;
dsize = 0;
}
break;
default:
break;
}
if (hdlc->do_adapt56) {
if (hdlc->data_bits == 7) {
hdlc->cbin <<= 1;
hdlc->cbin++;
hdlc->data_bits++;
}
}
if (hdlc->data_bits == 8) {
/* the code is for bitreverse streams */
if (hdlc->do_bitreverse == 0)
*dst++ = bitrev8(hdlc->cbin);
else
*dst++ = hdlc->cbin;
hdlc->data_bits = 0;
len++;
dsize--;
}
}
*count -= slen;
return len;
}
EXPORT_SYMBOL(isdnhdlc_encode);
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