dahdi-linux/drivers/dahdi/wct4xxp/vpm450m.c

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/*
* Copyright (C) 2005-2006 Digium, Inc.
*
* Mark Spencer <markster@digium.com>
*
* All Rights Reserved
*/
/*
* See http://www.asterisk.org for more information about
* the Asterisk project. Please do not directly contact
* any of the maintainers of this project for assistance;
* the project provides a web site, mailing lists and IRC
* channels for your use.
*
* This program is free software, distributed under the terms of
* the GNU General Public License Version 2 as published by the
* Free Software Foundation. See the LICENSE file included with
* this program for more details.
*/
#include <linux/slab.h>
#include <linux/vmalloc.h>
#include <linux/string.h>
#include <linux/time.h>
#include <linux/version.h>
#include "vpm450m.h"
#include "oct6100api/oct6100_api.h"
#if LINUX_VERSION_CODE < KERNEL_VERSION(2,6,18)
#include <linux/config.h>
#endif
/* API for Octasic access */
UINT32 Oct6100UserGetTime(tPOCT6100_GET_TIME f_pTime)
{
/* Why couldn't they just take a timeval like everyone else? */
struct timeval tv;
unsigned long long total_usecs;
unsigned int mask = ~0;
do_gettimeofday(&tv);
total_usecs = (((unsigned long long)(tv.tv_sec)) * 1000000) +
(((unsigned long long)(tv.tv_usec)));
f_pTime->aulWallTimeUs[0] = (total_usecs & mask);
f_pTime->aulWallTimeUs[1] = (total_usecs >> 32);
return cOCT6100_ERR_OK;
}
UINT32 Oct6100UserMemSet(PVOID f_pAddress, UINT32 f_ulPattern, UINT32 f_ulLength)
{
memset(f_pAddress, f_ulPattern, f_ulLength);
return cOCT6100_ERR_OK;
}
UINT32 Oct6100UserMemCopy(PVOID f_pDestination, const void *f_pSource, UINT32 f_ulLength)
{
memcpy(f_pDestination, f_pSource, f_ulLength);
return cOCT6100_ERR_OK;
}
UINT32 Oct6100UserCreateSerializeObject(tPOCT6100_CREATE_SERIALIZE_OBJECT f_pCreate)
{
return cOCT6100_ERR_OK;
}
UINT32 Oct6100UserDestroySerializeObject(tPOCT6100_DESTROY_SERIALIZE_OBJECT f_pDestroy)
{
#ifdef OCTASIC_DEBUG
printk(KERN_DEBUG "I should never be called! (destroy serialize object)\n");
#endif
return cOCT6100_ERR_OK;
}
UINT32 Oct6100UserSeizeSerializeObject(tPOCT6100_SEIZE_SERIALIZE_OBJECT f_pSeize)
{
/* Not needed */
return cOCT6100_ERR_OK;
}
UINT32 Oct6100UserReleaseSerializeObject(tPOCT6100_RELEASE_SERIALIZE_OBJECT f_pRelease)
{
/* Not needed */
return cOCT6100_ERR_OK;
}
UINT32 Oct6100UserDriverWriteApi(tPOCT6100_WRITE_PARAMS f_pWriteParams)
{
oct_set_reg(f_pWriteParams->pProcessContext, f_pWriteParams->ulWriteAddress, f_pWriteParams->usWriteData);
return cOCT6100_ERR_OK;
}
UINT32 Oct6100UserDriverWriteSmearApi(tPOCT6100_WRITE_SMEAR_PARAMS f_pSmearParams)
{
unsigned int x;
for (x=0;x<f_pSmearParams->ulWriteLength;x++) {
oct_set_reg(f_pSmearParams->pProcessContext, f_pSmearParams->ulWriteAddress + (x << 1), f_pSmearParams->usWriteData);
}
return cOCT6100_ERR_OK;
}
UINT32 Oct6100UserDriverWriteBurstApi(tPOCT6100_WRITE_BURST_PARAMS f_pBurstParams)
{
unsigned int x;
for (x=0;x<f_pBurstParams->ulWriteLength;x++) {
oct_set_reg(f_pBurstParams->pProcessContext, f_pBurstParams->ulWriteAddress + (x << 1), f_pBurstParams->pusWriteData[x]);
}
return cOCT6100_ERR_OK;
}
UINT32 Oct6100UserDriverReadApi(tPOCT6100_READ_PARAMS f_pReadParams)
{
*(f_pReadParams->pusReadData) = oct_get_reg(f_pReadParams->pProcessContext, f_pReadParams->ulReadAddress);
return cOCT6100_ERR_OK;
}
UINT32 Oct6100UserDriverReadBurstApi(tPOCT6100_READ_BURST_PARAMS f_pBurstParams)
{
unsigned int x;
for (x=0;x<f_pBurstParams->ulReadLength;x++) {
f_pBurstParams->pusReadData[x] = oct_get_reg(f_pBurstParams->pProcessContext, f_pBurstParams->ulReadAddress + (x << 1));
}
return cOCT6100_ERR_OK;
}
#define SOUT_G168_1100GB_ON 0x40000004
#define SOUT_DTMF_1 0x40000011
#define SOUT_DTMF_2 0x40000012
#define SOUT_DTMF_3 0x40000013
#define SOUT_DTMF_A 0x4000001A
#define SOUT_DTMF_4 0x40000014
#define SOUT_DTMF_5 0x40000015
#define SOUT_DTMF_6 0x40000016
#define SOUT_DTMF_B 0x4000001B
#define SOUT_DTMF_7 0x40000017
#define SOUT_DTMF_8 0x40000018
#define SOUT_DTMF_9 0x40000019
#define SOUT_DTMF_C 0x4000001C
#define SOUT_DTMF_STAR 0x4000001E
#define SOUT_DTMF_0 0x40000010
#define SOUT_DTMF_POUND 0x4000001F
#define SOUT_DTMF_D 0x4000001D
#define ROUT_G168_2100GB_ON 0x10000000
#define ROUT_G168_2100GB_WSPR 0x10000002
#define ROUT_SOUT_G168_2100HB_END 0x50000003
#define ROUT_G168_1100GB_ON 0x10000004
#define ROUT_DTMF_1 0x10000011
#define ROUT_DTMF_2 0x10000012
#define ROUT_DTMF_3 0x10000013
#define ROUT_DTMF_A 0x1000001A
#define ROUT_DTMF_4 0x10000014
#define ROUT_DTMF_5 0x10000015
#define ROUT_DTMF_6 0x10000016
#define ROUT_DTMF_B 0x1000001B
#define ROUT_DTMF_7 0x10000017
#define ROUT_DTMF_8 0x10000018
#define ROUT_DTMF_9 0x10000019
#define ROUT_DTMF_C 0x1000001C
#define ROUT_DTMF_STAR 0x1000001E
#define ROUT_DTMF_0 0x10000010
#define ROUT_DTMF_POUND 0x1000001F
#define ROUT_DTMF_D 0x1000001D
#if 0
#define cOCT6100_ECHO_OP_MODE_DIGITAL cOCT6100_ECHO_OP_MODE_HT_FREEZE
#else
#define cOCT6100_ECHO_OP_MODE_DIGITAL cOCT6100_ECHO_OP_MODE_POWER_DOWN
#endif
struct vpm450m {
tPOCT6100_INSTANCE_API pApiInstance;
UINT32 aulEchoChanHndl[ 128 ];
int chanflags[128];
int ecmode[128];
int numchans;
};
#define FLAG_DTMF (1 << 0)
#define FLAG_MUTE (1 << 1)
#define FLAG_ECHO (1 << 2)
static unsigned int tones[] = {
SOUT_DTMF_1,
SOUT_DTMF_2,
SOUT_DTMF_3,
SOUT_DTMF_A,
SOUT_DTMF_4,
SOUT_DTMF_5,
SOUT_DTMF_6,
SOUT_DTMF_B,
SOUT_DTMF_7,
SOUT_DTMF_8,
SOUT_DTMF_9,
SOUT_DTMF_C,
SOUT_DTMF_STAR,
SOUT_DTMF_0,
SOUT_DTMF_POUND,
SOUT_DTMF_D,
SOUT_G168_1100GB_ON,
ROUT_DTMF_1,
ROUT_DTMF_2,
ROUT_DTMF_3,
ROUT_DTMF_A,
ROUT_DTMF_4,
ROUT_DTMF_5,
ROUT_DTMF_6,
ROUT_DTMF_B,
ROUT_DTMF_7,
ROUT_DTMF_8,
ROUT_DTMF_9,
ROUT_DTMF_C,
ROUT_DTMF_STAR,
ROUT_DTMF_0,
ROUT_DTMF_POUND,
ROUT_DTMF_D,
ROUT_G168_1100GB_ON,
};
static void vpm450m_setecmode(struct vpm450m *vpm450m, int channel, int mode)
{
tOCT6100_CHANNEL_MODIFY *modify;
UINT32 ulResult;
if (vpm450m->ecmode[channel] == mode)
return;
modify = kmalloc(sizeof(tOCT6100_CHANNEL_MODIFY), GFP_ATOMIC);
if (!modify) {
printk(KERN_NOTICE "wct4xxp: Unable to allocate memory for setec!\n");
return;
}
Oct6100ChannelModifyDef(modify);
modify->ulEchoOperationMode = mode;
modify->ulChannelHndl = vpm450m->aulEchoChanHndl[channel];
ulResult = Oct6100ChannelModify(vpm450m->pApiInstance, modify);
if (ulResult != GENERIC_OK) {
printk(KERN_NOTICE "Failed to apply echo can changes on channel %d!\n", channel);
} else {
#ifdef OCTASIC_DEBUG
printk(KERN_DEBUG "Echo can on channel %d set to %d\n", channel, mode);
#endif
vpm450m->ecmode[channel] = mode;
}
kfree(modify);
}
void vpm450m_setdtmf(struct vpm450m *vpm450m, int channel, int detect, int mute)
{
tOCT6100_CHANNEL_MODIFY *modify;
UINT32 ulResult;
modify = kmalloc(sizeof(tOCT6100_CHANNEL_MODIFY), GFP_KERNEL);
if (!modify) {
printk(KERN_NOTICE "wct4xxp: Unable to allocate memory for setdtmf!\n");
return;
}
Oct6100ChannelModifyDef(modify);
modify->ulChannelHndl = vpm450m->aulEchoChanHndl[channel];
if (mute) {
vpm450m->chanflags[channel] |= FLAG_MUTE;
modify->VqeConfig.fDtmfToneRemoval = TRUE;
} else {
vpm450m->chanflags[channel] &= ~FLAG_MUTE;
modify->VqeConfig.fDtmfToneRemoval = FALSE;
}
if (detect)
vpm450m->chanflags[channel] |= FLAG_DTMF;
else
vpm450m->chanflags[channel] &= ~FLAG_DTMF;
if (vpm450m->chanflags[channel] & (FLAG_DTMF|FLAG_MUTE)) {
if (!(vpm450m->chanflags[channel] & FLAG_ECHO)) {
vpm450m_setecmode(vpm450m, channel, cOCT6100_ECHO_OP_MODE_HT_RESET);
vpm450m_setecmode(vpm450m, channel, cOCT6100_ECHO_OP_MODE_HT_FREEZE);
}
} else {
if (!(vpm450m->chanflags[channel] & FLAG_ECHO))
vpm450m_setecmode(vpm450m, channel, cOCT6100_ECHO_OP_MODE_DIGITAL);
}
ulResult = Oct6100ChannelModify(vpm450m->pApiInstance, modify);
if (ulResult != GENERIC_OK) {
printk(KERN_NOTICE "Failed to apply dtmf mute changes on channel %d!\n", channel);
}
/* printk(KERN_DEBUG "VPM450m: Setting DTMF on channel %d: %s / %s\n", channel, (detect ? "DETECT" : "NO DETECT"), (mute ? "MUTE" : "NO MUTE")); */
kfree(modify);
}
void vpm450m_setec(struct vpm450m *vpm450m, int channel, int eclen)
{
if (eclen) {
vpm450m->chanflags[channel] |= FLAG_ECHO;
vpm450m_setecmode(vpm450m, channel, cOCT6100_ECHO_OP_MODE_HT_RESET);
vpm450m_setecmode(vpm450m, channel, cOCT6100_ECHO_OP_MODE_NORMAL);
} else {
vpm450m->chanflags[channel] &= ~FLAG_ECHO;
if (vpm450m->chanflags[channel] & (FLAG_DTMF | FLAG_MUTE)) {
vpm450m_setecmode(vpm450m, channel, cOCT6100_ECHO_OP_MODE_HT_RESET);
vpm450m_setecmode(vpm450m, channel, cOCT6100_ECHO_OP_MODE_HT_FREEZE);
} else
vpm450m_setecmode(vpm450m, channel, cOCT6100_ECHO_OP_MODE_DIGITAL);
}
/* printk(KERN_DEBUG "VPM450m: Setting EC on channel %d to %d\n", channel, eclen); */
}
int vpm450m_checkirq(struct vpm450m *vpm450m)
{
tOCT6100_INTERRUPT_FLAGS InterruptFlags;
Oct6100InterruptServiceRoutineDef(&InterruptFlags);
Oct6100InterruptServiceRoutine(vpm450m->pApiInstance, &InterruptFlags);
return InterruptFlags.fToneEventsPending ? 1 : 0;
}
int vpm450m_getdtmf(struct vpm450m *vpm450m, int *channel, int *tone, int *start)
{
tOCT6100_TONE_EVENT tonefound;
tOCT6100_EVENT_GET_TONE tonesearch;
UINT32 ulResult;
Oct6100EventGetToneDef(&tonesearch);
tonesearch.pToneEvent = &tonefound;
tonesearch.ulMaxToneEvent = 1;
ulResult = Oct6100EventGetTone(vpm450m->pApiInstance, &tonesearch);
if (tonesearch.ulNumValidToneEvent) {
if (channel)
*channel = tonefound.ulUserChanId;
if (tone) {
switch(tonefound.ulToneDetected) {
case SOUT_DTMF_1:
*tone = '1';
break;
case SOUT_DTMF_2:
*tone = '2';
break;
case SOUT_DTMF_3:
*tone = '3';
break;
case SOUT_DTMF_A:
*tone = 'A';
break;
case SOUT_DTMF_4:
*tone = '4';
break;
case SOUT_DTMF_5:
*tone = '5';
break;
case SOUT_DTMF_6:
*tone = '6';
break;
case SOUT_DTMF_B:
*tone = 'B';
break;
case SOUT_DTMF_7:
*tone = '7';
break;
case SOUT_DTMF_8:
*tone = '8';
break;
case SOUT_DTMF_9:
*tone = '9';
break;
case SOUT_DTMF_C:
*tone = 'C';
break;
case SOUT_DTMF_STAR:
*tone = '*';
break;
case SOUT_DTMF_0:
*tone = '0';
break;
case SOUT_DTMF_POUND:
*tone = '#';
break;
case SOUT_DTMF_D:
*tone = 'D';
break;
case SOUT_G168_1100GB_ON:
*tone = 'f';
break;
default:
#ifdef OCTASIC_DEBUG
printk(KERN_DEBUG "Unknown tone value %08x\n", tonefound.ulToneDetected);
#endif
*tone = 'u';
break;
}
}
if (start)
*start = (tonefound.ulEventType == cOCT6100_TONE_PRESENT);
return 1;
}
return 0;
}
unsigned int get_vpm450m_capacity(void *wc)
{
UINT32 ulResult;
tOCT6100_API_GET_CAPACITY_PINS CapacityPins;
Oct6100ApiGetCapacityPinsDef(&CapacityPins);
CapacityPins.pProcessContext = wc;
CapacityPins.ulMemoryType = cOCT6100_MEM_TYPE_DDR;
CapacityPins.fEnableMemClkOut = TRUE;
CapacityPins.ulMemClkFreq = cOCT6100_MCLK_FREQ_133_MHZ;
ulResult = Oct6100ApiGetCapacityPins(&CapacityPins);
if (ulResult != cOCT6100_ERR_OK) {
printk(KERN_DEBUG "Failed to get chip capacity, code %08x!\n", ulResult);
return 0;
}
return CapacityPins.ulCapacityValue;
}
struct vpm450m *init_vpm450m(void *wc, int *isalaw, int numspans, const struct firmware *firmware)
{
tOCT6100_CHIP_OPEN *ChipOpen;
tOCT6100_GET_INSTANCE_SIZE InstanceSize;
tOCT6100_CHANNEL_OPEN *ChannelOpen;
UINT32 ulResult;
struct vpm450m *vpm450m;
int x,y,law;
#ifdef CONFIG_4KSTACKS
unsigned long flags;
#endif
if (!(vpm450m = kmalloc(sizeof(struct vpm450m), GFP_KERNEL)))
return NULL;
memset(vpm450m, 0, sizeof(struct vpm450m));
if (!(ChipOpen = kmalloc(sizeof(tOCT6100_CHIP_OPEN), GFP_KERNEL))) {
kfree(vpm450m);
return NULL;
}
memset(ChipOpen, 0, sizeof(tOCT6100_CHIP_OPEN));
if (!(ChannelOpen = kmalloc(sizeof(tOCT6100_CHANNEL_OPEN), GFP_KERNEL))) {
kfree(vpm450m);
kfree(ChipOpen);
return NULL;
}
memset(ChannelOpen, 0, sizeof(tOCT6100_CHANNEL_OPEN));
for (x=0;x<128;x++)
vpm450m->ecmode[x] = -1;
vpm450m->numchans = numspans * 32;
printk(KERN_INFO "VPM450: echo cancellation for %d channels\n", vpm450m->numchans);
Oct6100ChipOpenDef(ChipOpen);
/* Setup Chip Open Parameters */
ChipOpen->ulUpclkFreq = cOCT6100_UPCLK_FREQ_33_33_MHZ;
Oct6100GetInstanceSizeDef(&InstanceSize);
ChipOpen->pProcessContext = wc;
ChipOpen->pbyImageFile = firmware->data;
ChipOpen->ulImageSize = firmware->size;
ChipOpen->fEnableMemClkOut = TRUE;
ChipOpen->ulMemClkFreq = cOCT6100_MCLK_FREQ_133_MHZ;
ChipOpen->ulMaxChannels = vpm450m->numchans;
ChipOpen->ulMemoryType = cOCT6100_MEM_TYPE_DDR;
ChipOpen->ulMemoryChipSize = cOCT6100_MEMORY_CHIP_SIZE_32MB;
ChipOpen->ulNumMemoryChips = 1;
ChipOpen->ulMaxTdmStreams = 4;
ChipOpen->aulTdmStreamFreqs[0] = cOCT6100_TDM_STREAM_FREQ_8MHZ;
ChipOpen->ulTdmSampling = cOCT6100_TDM_SAMPLE_AT_FALLING_EDGE;
#if 0
ChipOpen->fEnableAcousticEcho = TRUE;
#endif
ulResult = Oct6100GetInstanceSize(ChipOpen, &InstanceSize);
if (ulResult != cOCT6100_ERR_OK) {
printk(KERN_NOTICE "Failed to get instance size, code %08x!\n", ulResult);
kfree(vpm450m);
kfree(ChipOpen);
kfree(ChannelOpen);
return NULL;
}
vpm450m->pApiInstance = vmalloc(InstanceSize.ulApiInstanceSize);
if (!vpm450m->pApiInstance) {
printk(KERN_NOTICE "Out of memory (can't allocate %d bytes)!\n", InstanceSize.ulApiInstanceSize);
kfree(vpm450m);
kfree(ChipOpen);
kfree(ChannelOpen);
return NULL;
}
/* I don't know what to curse more in this comment, the problems caused by
* the 4K kernel stack limit change or the octasic API for being so darn
* stack unfriendly. Stupid, stupid, stupid. So we disable IRQs so we
* don't run the risk of overflowing the stack while we initialize the
* octasic. */
#ifdef CONFIG_4KSTACKS
local_irq_save(flags);
#endif
ulResult = Oct6100ChipOpen(vpm450m->pApiInstance, ChipOpen);
if (ulResult != cOCT6100_ERR_OK) {
printk(KERN_NOTICE "Failed to open chip, code %08x!\n", ulResult);
#ifdef CONFIG_4KSTACKS
local_irq_restore(flags);
#endif
vfree(vpm450m->pApiInstance);
kfree(vpm450m);
kfree(ChipOpen);
kfree(ChannelOpen);
return NULL;
}
for (x=0;x<128;x++) {
/* execute this loop always on 4 span cards but
* on 2 span cards only execute for the channels related to our spans */
if (( numspans > 2) || ((x & 0x03) <2)) {
/* span timeslots are interleaved 12341234...
* therefore, the lower 2 bits tell us which span this
* timeslot/channel
*/
if (isalaw[x & 0x03])
law = cOCT6100_PCM_A_LAW;
else
law = cOCT6100_PCM_U_LAW;
Oct6100ChannelOpenDef(ChannelOpen);
ChannelOpen->pulChannelHndl = &vpm450m->aulEchoChanHndl[x];
ChannelOpen->ulUserChanId = x;
ChannelOpen->TdmConfig.ulRinPcmLaw = law;
ChannelOpen->TdmConfig.ulRinStream = 0;
ChannelOpen->TdmConfig.ulRinTimeslot = x;
ChannelOpen->TdmConfig.ulSinPcmLaw = law;
ChannelOpen->TdmConfig.ulSinStream = 1;
ChannelOpen->TdmConfig.ulSinTimeslot = x;
ChannelOpen->TdmConfig.ulSoutPcmLaw = law;
ChannelOpen->TdmConfig.ulSoutStream = 2;
ChannelOpen->TdmConfig.ulSoutTimeslot = x;
ChannelOpen->TdmConfig.ulRoutPcmLaw = law;
ChannelOpen->TdmConfig.ulRoutStream = 3;
ChannelOpen->TdmConfig.ulRoutTimeslot = x;
ChannelOpen->VqeConfig.fEnableNlp = TRUE;
ChannelOpen->VqeConfig.fRinDcOffsetRemoval = TRUE;
ChannelOpen->VqeConfig.fSinDcOffsetRemoval = TRUE;
ChannelOpen->fEnableToneDisabler = TRUE;
ChannelOpen->ulEchoOperationMode = cOCT6100_ECHO_OP_MODE_DIGITAL;
ulResult = Oct6100ChannelOpen(vpm450m->pApiInstance, ChannelOpen);
if (ulResult != GENERIC_OK) {
printk(KERN_NOTICE "Failed to open channel %d!\n", x);
}
for (y=0;y<sizeof(tones) / sizeof(tones[0]); y++) {
tOCT6100_TONE_DETECTION_ENABLE enable;
Oct6100ToneDetectionEnableDef(&enable);
enable.ulChannelHndl = vpm450m->aulEchoChanHndl[x];
enable.ulToneNumber = tones[y];
if (Oct6100ToneDetectionEnable(vpm450m->pApiInstance, &enable) != GENERIC_OK)
printk(KERN_NOTICE "Failed to enable tone detection on channel %d for tone %d!\n", x, y);
}
}
}
#ifdef CONFIG_4KSTACKS
local_irq_restore(flags);
#endif
kfree(ChipOpen);
kfree(ChannelOpen);
return vpm450m;
}
void release_vpm450m(struct vpm450m *vpm450m)
{
UINT32 ulResult;
tOCT6100_CHIP_CLOSE ChipClose;
Oct6100ChipCloseDef(&ChipClose);
ulResult = Oct6100ChipClose(vpm450m->pApiInstance, &ChipClose);
if (ulResult != cOCT6100_ERR_OK) {
printk(KERN_NOTICE "Failed to close chip, code %08x!\n", ulResult);
}
vfree(vpm450m->pApiInstance);
kfree(vpm450m);
}