remarkable-linux/drivers/char/mwave/3780i.c
Tim Schmielau 4e57b68178 [PATCH] fix missing includes
I recently picked up my older work to remove unnecessary #includes of
sched.h, starting from a patch by Dave Jones to not include sched.h
from module.h. This reduces the number of indirect includes of sched.h
by ~300. Another ~400 pointless direct includes can be removed after
this disentangling (patch to follow later).
However, quite a few indirect includes need to be fixed up for this.

In order to feed the patches through -mm with as little disturbance as
possible, I've split out the fixes I accumulated up to now (complete for
i386 and x86_64, more archs to follow later) and post them before the real
patch.  This way this large part of the patch is kept simple with only
adding #includes, and all hunks are independent of each other.  So if any
hunk rejects or gets in the way of other patches, just drop it.  My scripts
will pick it up again in the next round.

Signed-off-by: Tim Schmielau <tim@physik3.uni-rostock.de>
Signed-off-by: Andrew Morton <akpm@osdl.org>
Signed-off-by: Linus Torvalds <torvalds@osdl.org>
2005-10-30 17:37:32 -08:00

732 lines
21 KiB
C

/*
*
* 3780i.c -- helper routines for the 3780i DSP
*
*
* Written By: Mike Sullivan IBM Corporation
*
* Copyright (C) 1999 IBM Corporation
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* NO WARRANTY
* THE PROGRAM IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OR
* CONDITIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED INCLUDING, WITHOUT
* LIMITATION, ANY WARRANTIES OR CONDITIONS OF TITLE, NON-INFRINGEMENT,
* MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Each Recipient is
* solely responsible for determining the appropriateness of using and
* distributing the Program and assumes all risks associated with its
* exercise of rights under this Agreement, including but not limited to
* the risks and costs of program errors, damage to or loss of data,
* programs or equipment, and unavailability or interruption of operations.
*
* DISCLAIMER OF LIABILITY
* NEITHER RECIPIENT NOR ANY CONTRIBUTORS SHALL HAVE ANY LIABILITY FOR ANY
* DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING WITHOUT LIMITATION LOST PROFITS), 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 OR DISTRIBUTION OF THE PROGRAM OR THE EXERCISE OF ANY RIGHTS GRANTED
* HEREUNDER, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGES
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*
*
* 10/23/2000 - Alpha Release
* First release to the public
*/
#include <linux/config.h>
#include <linux/kernel.h>
#include <linux/unistd.h>
#include <linux/delay.h>
#include <linux/ioport.h>
#include <linux/init.h>
#include <linux/bitops.h>
#include <linux/sched.h> /* cond_resched() */
#include <asm/io.h>
#include <asm/uaccess.h>
#include <asm/system.h>
#include <asm/irq.h>
#include "smapi.h"
#include "mwavedd.h"
#include "3780i.h"
static DEFINE_SPINLOCK(dsp_lock);
static unsigned long flags;
static void PaceMsaAccess(unsigned short usDspBaseIO)
{
cond_resched();
udelay(100);
cond_resched();
}
unsigned short dsp3780I_ReadMsaCfg(unsigned short usDspBaseIO,
unsigned long ulMsaAddr)
{
unsigned short val;
PRINTK_3(TRACE_3780I,
"3780i::dsp3780I_ReadMsaCfg entry usDspBaseIO %x ulMsaAddr %lx\n",
usDspBaseIO, ulMsaAddr);
spin_lock_irqsave(&dsp_lock, flags);
OutWordDsp(DSP_MsaAddrLow, (unsigned short) ulMsaAddr);
OutWordDsp(DSP_MsaAddrHigh, (unsigned short) (ulMsaAddr >> 16));
val = InWordDsp(DSP_MsaDataDSISHigh);
spin_unlock_irqrestore(&dsp_lock, flags);
PRINTK_2(TRACE_3780I, "3780i::dsp3780I_ReadMsaCfg exit val %x\n", val);
return val;
}
void dsp3780I_WriteMsaCfg(unsigned short usDspBaseIO,
unsigned long ulMsaAddr, unsigned short usValue)
{
PRINTK_4(TRACE_3780I,
"3780i::dsp3780i_WriteMsaCfg entry usDspBaseIO %x ulMsaAddr %lx usValue %x\n",
usDspBaseIO, ulMsaAddr, usValue);
spin_lock_irqsave(&dsp_lock, flags);
OutWordDsp(DSP_MsaAddrLow, (unsigned short) ulMsaAddr);
OutWordDsp(DSP_MsaAddrHigh, (unsigned short) (ulMsaAddr >> 16));
OutWordDsp(DSP_MsaDataDSISHigh, usValue);
spin_unlock_irqrestore(&dsp_lock, flags);
}
static void dsp3780I_WriteGenCfg(unsigned short usDspBaseIO, unsigned uIndex,
unsigned char ucValue)
{
DSP_ISA_SLAVE_CONTROL rSlaveControl;
DSP_ISA_SLAVE_CONTROL rSlaveControl_Save;
PRINTK_4(TRACE_3780I,
"3780i::dsp3780i_WriteGenCfg entry usDspBaseIO %x uIndex %x ucValue %x\n",
usDspBaseIO, uIndex, ucValue);
MKBYTE(rSlaveControl) = InByteDsp(DSP_IsaSlaveControl);
PRINTK_2(TRACE_3780I,
"3780i::dsp3780i_WriteGenCfg rSlaveControl %x\n",
MKBYTE(rSlaveControl));
rSlaveControl_Save = rSlaveControl;
rSlaveControl.ConfigMode = TRUE;
PRINTK_2(TRACE_3780I,
"3780i::dsp3780i_WriteGenCfg entry rSlaveControl+ConfigMode %x\n",
MKBYTE(rSlaveControl));
OutByteDsp(DSP_IsaSlaveControl, MKBYTE(rSlaveControl));
OutByteDsp(DSP_ConfigAddress, (unsigned char) uIndex);
OutByteDsp(DSP_ConfigData, ucValue);
OutByteDsp(DSP_IsaSlaveControl, MKBYTE(rSlaveControl_Save));
PRINTK_1(TRACE_3780I, "3780i::dsp3780i_WriteGenCfg exit\n");
}
#if 0
unsigned char dsp3780I_ReadGenCfg(unsigned short usDspBaseIO,
unsigned uIndex)
{
DSP_ISA_SLAVE_CONTROL rSlaveControl;
DSP_ISA_SLAVE_CONTROL rSlaveControl_Save;
unsigned char ucValue;
PRINTK_3(TRACE_3780I,
"3780i::dsp3780i_ReadGenCfg entry usDspBaseIO %x uIndex %x\n",
usDspBaseIO, uIndex);
MKBYTE(rSlaveControl) = InByteDsp(DSP_IsaSlaveControl);
rSlaveControl_Save = rSlaveControl;
rSlaveControl.ConfigMode = TRUE;
OutByteDsp(DSP_IsaSlaveControl, MKBYTE(rSlaveControl));
OutByteDsp(DSP_ConfigAddress, (unsigned char) uIndex);
ucValue = InByteDsp(DSP_ConfigData);
OutByteDsp(DSP_IsaSlaveControl, MKBYTE(rSlaveControl_Save));
PRINTK_2(TRACE_3780I,
"3780i::dsp3780i_ReadGenCfg exit ucValue %x\n", ucValue);
return ucValue;
}
#endif /* 0 */
int dsp3780I_EnableDSP(DSP_3780I_CONFIG_SETTINGS * pSettings,
unsigned short *pIrqMap,
unsigned short *pDmaMap)
{
unsigned short usDspBaseIO = pSettings->usDspBaseIO;
int i;
DSP_UART_CFG_1 rUartCfg1;
DSP_UART_CFG_2 rUartCfg2;
DSP_HBRIDGE_CFG_1 rHBridgeCfg1;
DSP_HBRIDGE_CFG_2 rHBridgeCfg2;
DSP_BUSMASTER_CFG_1 rBusmasterCfg1;
DSP_BUSMASTER_CFG_2 rBusmasterCfg2;
DSP_ISA_PROT_CFG rIsaProtCfg;
DSP_POWER_MGMT_CFG rPowerMgmtCfg;
DSP_HBUS_TIMER_CFG rHBusTimerCfg;
DSP_LBUS_TIMEOUT_DISABLE rLBusTimeoutDisable;
DSP_CHIP_RESET rChipReset;
DSP_CLOCK_CONTROL_1 rClockControl1;
DSP_CLOCK_CONTROL_2 rClockControl2;
DSP_ISA_SLAVE_CONTROL rSlaveControl;
DSP_HBRIDGE_CONTROL rHBridgeControl;
unsigned short ChipID = 0;
unsigned short tval;
PRINTK_2(TRACE_3780I,
"3780i::dsp3780I_EnableDSP entry pSettings->bDSPEnabled %x\n",
pSettings->bDSPEnabled);
if (!pSettings->bDSPEnabled) {
PRINTK_ERROR( KERN_ERR "3780i::dsp3780I_EnableDSP: Error: DSP not enabled. Aborting.\n" );
return -EIO;
}
PRINTK_2(TRACE_3780I,
"3780i::dsp3780i_EnableDSP entry pSettings->bModemEnabled %x\n",
pSettings->bModemEnabled);
if (pSettings->bModemEnabled) {
rUartCfg1.Reserved = rUartCfg2.Reserved = 0;
rUartCfg1.IrqActiveLow = pSettings->bUartIrqActiveLow;
rUartCfg1.IrqPulse = pSettings->bUartIrqPulse;
rUartCfg1.Irq =
(unsigned char) pIrqMap[pSettings->usUartIrq];
switch (pSettings->usUartBaseIO) {
case 0x03F8:
rUartCfg1.BaseIO = 0;
break;
case 0x02F8:
rUartCfg1.BaseIO = 1;
break;
case 0x03E8:
rUartCfg1.BaseIO = 2;
break;
case 0x02E8:
rUartCfg1.BaseIO = 3;
break;
}
rUartCfg2.Enable = TRUE;
}
rHBridgeCfg1.Reserved = rHBridgeCfg2.Reserved = 0;
rHBridgeCfg1.IrqActiveLow = pSettings->bDspIrqActiveLow;
rHBridgeCfg1.IrqPulse = pSettings->bDspIrqPulse;
rHBridgeCfg1.Irq = (unsigned char) pIrqMap[pSettings->usDspIrq];
rHBridgeCfg1.AccessMode = 1;
rHBridgeCfg2.Enable = TRUE;
rBusmasterCfg2.Reserved = 0;
rBusmasterCfg1.Dma = (unsigned char) pDmaMap[pSettings->usDspDma];
rBusmasterCfg1.NumTransfers =
(unsigned char) pSettings->usNumTransfers;
rBusmasterCfg1.ReRequest = (unsigned char) pSettings->usReRequest;
rBusmasterCfg1.MEMCS16 = pSettings->bEnableMEMCS16;
rBusmasterCfg2.IsaMemCmdWidth =
(unsigned char) pSettings->usIsaMemCmdWidth;
rIsaProtCfg.Reserved = 0;
rIsaProtCfg.GateIOCHRDY = pSettings->bGateIOCHRDY;
rPowerMgmtCfg.Reserved = 0;
rPowerMgmtCfg.Enable = pSettings->bEnablePwrMgmt;
rHBusTimerCfg.LoadValue =
(unsigned char) pSettings->usHBusTimerLoadValue;
rLBusTimeoutDisable.Reserved = 0;
rLBusTimeoutDisable.DisableTimeout =
pSettings->bDisableLBusTimeout;
MKWORD(rChipReset) = ~pSettings->usChipletEnable;
rClockControl1.Reserved1 = rClockControl1.Reserved2 = 0;
rClockControl1.N_Divisor = pSettings->usN_Divisor;
rClockControl1.M_Multiplier = pSettings->usM_Multiplier;
rClockControl2.Reserved = 0;
rClockControl2.PllBypass = pSettings->bPllBypass;
/* Issue a soft reset to the chip */
/* Note: Since we may be coming in with 3780i clocks suspended, we must keep
* soft-reset active for 10ms.
*/
rSlaveControl.ClockControl = 0;
rSlaveControl.SoftReset = TRUE;
rSlaveControl.ConfigMode = FALSE;
rSlaveControl.Reserved = 0;
PRINTK_4(TRACE_3780I,
"3780i::dsp3780i_EnableDSP usDspBaseIO %x index %x taddr %x\n",
usDspBaseIO, DSP_IsaSlaveControl,
usDspBaseIO + DSP_IsaSlaveControl);
PRINTK_2(TRACE_3780I,
"3780i::dsp3780i_EnableDSP rSlaveContrl %x\n",
MKWORD(rSlaveControl));
spin_lock_irqsave(&dsp_lock, flags);
OutWordDsp(DSP_IsaSlaveControl, MKWORD(rSlaveControl));
MKWORD(tval) = InWordDsp(DSP_IsaSlaveControl);
PRINTK_2(TRACE_3780I,
"3780i::dsp3780i_EnableDSP rSlaveControl 2 %x\n", tval);
for (i = 0; i < 11; i++)
udelay(2000);
rSlaveControl.SoftReset = FALSE;
OutWordDsp(DSP_IsaSlaveControl, MKWORD(rSlaveControl));
MKWORD(tval) = InWordDsp(DSP_IsaSlaveControl);
PRINTK_2(TRACE_3780I,
"3780i::dsp3780i_EnableDSP rSlaveControl 3 %x\n", tval);
/* Program our general configuration registers */
WriteGenCfg(DSP_HBridgeCfg1Index, MKBYTE(rHBridgeCfg1));
WriteGenCfg(DSP_HBridgeCfg2Index, MKBYTE(rHBridgeCfg2));
WriteGenCfg(DSP_BusMasterCfg1Index, MKBYTE(rBusmasterCfg1));
WriteGenCfg(DSP_BusMasterCfg2Index, MKBYTE(rBusmasterCfg2));
WriteGenCfg(DSP_IsaProtCfgIndex, MKBYTE(rIsaProtCfg));
WriteGenCfg(DSP_PowerMgCfgIndex, MKBYTE(rPowerMgmtCfg));
WriteGenCfg(DSP_HBusTimerCfgIndex, MKBYTE(rHBusTimerCfg));
if (pSettings->bModemEnabled) {
WriteGenCfg(DSP_UartCfg1Index, MKBYTE(rUartCfg1));
WriteGenCfg(DSP_UartCfg2Index, MKBYTE(rUartCfg2));
}
rHBridgeControl.EnableDspInt = FALSE;
rHBridgeControl.MemAutoInc = TRUE;
rHBridgeControl.IoAutoInc = FALSE;
rHBridgeControl.DiagnosticMode = FALSE;
PRINTK_3(TRACE_3780I,
"3780i::dsp3780i_EnableDSP DSP_HBridgeControl %x rHBridgeControl %x\n",
DSP_HBridgeControl, MKWORD(rHBridgeControl));
OutWordDsp(DSP_HBridgeControl, MKWORD(rHBridgeControl));
spin_unlock_irqrestore(&dsp_lock, flags);
WriteMsaCfg(DSP_LBusTimeoutDisable, MKWORD(rLBusTimeoutDisable));
WriteMsaCfg(DSP_ClockControl_1, MKWORD(rClockControl1));
WriteMsaCfg(DSP_ClockControl_2, MKWORD(rClockControl2));
WriteMsaCfg(DSP_ChipReset, MKWORD(rChipReset));
ChipID = ReadMsaCfg(DSP_ChipID);
PRINTK_2(TRACE_3780I,
"3780i::dsp3780I_EnableDSP exiting bRC=TRUE, ChipID %x\n",
ChipID);
return 0;
}
int dsp3780I_DisableDSP(DSP_3780I_CONFIG_SETTINGS * pSettings)
{
unsigned short usDspBaseIO = pSettings->usDspBaseIO;
DSP_ISA_SLAVE_CONTROL rSlaveControl;
PRINTK_1(TRACE_3780I, "3780i::dsp3780i_DisableDSP entry\n");
rSlaveControl.ClockControl = 0;
rSlaveControl.SoftReset = TRUE;
rSlaveControl.ConfigMode = FALSE;
rSlaveControl.Reserved = 0;
spin_lock_irqsave(&dsp_lock, flags);
OutWordDsp(DSP_IsaSlaveControl, MKWORD(rSlaveControl));
udelay(5);
rSlaveControl.ClockControl = 1;
OutWordDsp(DSP_IsaSlaveControl, MKWORD(rSlaveControl));
spin_unlock_irqrestore(&dsp_lock, flags);
udelay(5);
PRINTK_1(TRACE_3780I, "3780i::dsp3780i_DisableDSP exit\n");
return 0;
}
int dsp3780I_Reset(DSP_3780I_CONFIG_SETTINGS * pSettings)
{
unsigned short usDspBaseIO = pSettings->usDspBaseIO;
DSP_BOOT_DOMAIN rBootDomain;
DSP_HBRIDGE_CONTROL rHBridgeControl;
PRINTK_1(TRACE_3780I, "3780i::dsp3780i_Reset entry\n");
spin_lock_irqsave(&dsp_lock, flags);
/* Mask DSP to PC interrupt */
MKWORD(rHBridgeControl) = InWordDsp(DSP_HBridgeControl);
PRINTK_2(TRACE_3780I, "3780i::dsp3780i_Reset rHBridgeControl %x\n",
MKWORD(rHBridgeControl));
rHBridgeControl.EnableDspInt = FALSE;
OutWordDsp(DSP_HBridgeControl, MKWORD(rHBridgeControl));
spin_unlock_irqrestore(&dsp_lock, flags);
/* Reset the core via the boot domain register */
rBootDomain.ResetCore = TRUE;
rBootDomain.Halt = TRUE;
rBootDomain.NMI = TRUE;
rBootDomain.Reserved = 0;
PRINTK_2(TRACE_3780I, "3780i::dsp3780i_Reset rBootDomain %x\n",
MKWORD(rBootDomain));
WriteMsaCfg(DSP_MspBootDomain, MKWORD(rBootDomain));
/* Reset all the chiplets and then reactivate them */
WriteMsaCfg(DSP_ChipReset, 0xFFFF);
udelay(5);
WriteMsaCfg(DSP_ChipReset,
(unsigned short) (~pSettings->usChipletEnable));
PRINTK_1(TRACE_3780I, "3780i::dsp3780i_Reset exit bRC=0\n");
return 0;
}
int dsp3780I_Run(DSP_3780I_CONFIG_SETTINGS * pSettings)
{
unsigned short usDspBaseIO = pSettings->usDspBaseIO;
DSP_BOOT_DOMAIN rBootDomain;
DSP_HBRIDGE_CONTROL rHBridgeControl;
PRINTK_1(TRACE_3780I, "3780i::dsp3780i_Run entry\n");
/* Transition the core to a running state */
rBootDomain.ResetCore = TRUE;
rBootDomain.Halt = FALSE;
rBootDomain.NMI = TRUE;
rBootDomain.Reserved = 0;
WriteMsaCfg(DSP_MspBootDomain, MKWORD(rBootDomain));
udelay(5);
rBootDomain.ResetCore = FALSE;
WriteMsaCfg(DSP_MspBootDomain, MKWORD(rBootDomain));
udelay(5);
rBootDomain.NMI = FALSE;
WriteMsaCfg(DSP_MspBootDomain, MKWORD(rBootDomain));
udelay(5);
/* Enable DSP to PC interrupt */
spin_lock_irqsave(&dsp_lock, flags);
MKWORD(rHBridgeControl) = InWordDsp(DSP_HBridgeControl);
rHBridgeControl.EnableDspInt = TRUE;
PRINTK_2(TRACE_3780I, "3780i::dsp3780i_Run rHBridgeControl %x\n",
MKWORD(rHBridgeControl));
OutWordDsp(DSP_HBridgeControl, MKWORD(rHBridgeControl));
spin_unlock_irqrestore(&dsp_lock, flags);
PRINTK_1(TRACE_3780I, "3780i::dsp3780i_Run exit bRC=TRUE\n");
return 0;
}
int dsp3780I_ReadDStore(unsigned short usDspBaseIO, void __user *pvBuffer,
unsigned uCount, unsigned long ulDSPAddr)
{
unsigned short __user *pusBuffer = pvBuffer;
unsigned short val;
PRINTK_5(TRACE_3780I,
"3780i::dsp3780I_ReadDStore entry usDspBaseIO %x, pusBuffer %p, uCount %x, ulDSPAddr %lx\n",
usDspBaseIO, pusBuffer, uCount, ulDSPAddr);
/* Set the initial MSA address. No adjustments need to be made to data store addresses */
spin_lock_irqsave(&dsp_lock, flags);
OutWordDsp(DSP_MsaAddrLow, (unsigned short) ulDSPAddr);
OutWordDsp(DSP_MsaAddrHigh, (unsigned short) (ulDSPAddr >> 16));
spin_unlock_irqrestore(&dsp_lock, flags);
/* Transfer the memory block */
while (uCount-- != 0) {
spin_lock_irqsave(&dsp_lock, flags);
val = InWordDsp(DSP_MsaDataDSISHigh);
spin_unlock_irqrestore(&dsp_lock, flags);
if(put_user(val, pusBuffer++))
return -EFAULT;
PRINTK_3(TRACE_3780I,
"3780I::dsp3780I_ReadDStore uCount %x val %x\n",
uCount, val);
PaceMsaAccess(usDspBaseIO);
}
PRINTK_1(TRACE_3780I,
"3780I::dsp3780I_ReadDStore exit bRC=TRUE\n");
return 0;
}
int dsp3780I_ReadAndClearDStore(unsigned short usDspBaseIO,
void __user *pvBuffer, unsigned uCount,
unsigned long ulDSPAddr)
{
unsigned short __user *pusBuffer = pvBuffer;
unsigned short val;
PRINTK_5(TRACE_3780I,
"3780i::dsp3780I_ReadAndDStore entry usDspBaseIO %x, pusBuffer %p, uCount %x, ulDSPAddr %lx\n",
usDspBaseIO, pusBuffer, uCount, ulDSPAddr);
/* Set the initial MSA address. No adjustments need to be made to data store addresses */
spin_lock_irqsave(&dsp_lock, flags);
OutWordDsp(DSP_MsaAddrLow, (unsigned short) ulDSPAddr);
OutWordDsp(DSP_MsaAddrHigh, (unsigned short) (ulDSPAddr >> 16));
spin_unlock_irqrestore(&dsp_lock, flags);
/* Transfer the memory block */
while (uCount-- != 0) {
spin_lock_irqsave(&dsp_lock, flags);
val = InWordDsp(DSP_ReadAndClear);
spin_unlock_irqrestore(&dsp_lock, flags);
if(put_user(val, pusBuffer++))
return -EFAULT;
PRINTK_3(TRACE_3780I,
"3780I::dsp3780I_ReadAndCleanDStore uCount %x val %x\n",
uCount, val);
PaceMsaAccess(usDspBaseIO);
}
PRINTK_1(TRACE_3780I,
"3780I::dsp3780I_ReadAndClearDStore exit bRC=TRUE\n");
return 0;
}
int dsp3780I_WriteDStore(unsigned short usDspBaseIO, void __user *pvBuffer,
unsigned uCount, unsigned long ulDSPAddr)
{
unsigned short __user *pusBuffer = pvBuffer;
PRINTK_5(TRACE_3780I,
"3780i::dsp3780D_WriteDStore entry usDspBaseIO %x, pusBuffer %p, uCount %x, ulDSPAddr %lx\n",
usDspBaseIO, pusBuffer, uCount, ulDSPAddr);
/* Set the initial MSA address. No adjustments need to be made to data store addresses */
spin_lock_irqsave(&dsp_lock, flags);
OutWordDsp(DSP_MsaAddrLow, (unsigned short) ulDSPAddr);
OutWordDsp(DSP_MsaAddrHigh, (unsigned short) (ulDSPAddr >> 16));
spin_unlock_irqrestore(&dsp_lock, flags);
/* Transfer the memory block */
while (uCount-- != 0) {
unsigned short val;
if(get_user(val, pusBuffer++))
return -EFAULT;
spin_lock_irqsave(&dsp_lock, flags);
OutWordDsp(DSP_MsaDataDSISHigh, val);
spin_unlock_irqrestore(&dsp_lock, flags);
PRINTK_3(TRACE_3780I,
"3780I::dsp3780I_WriteDStore uCount %x val %x\n",
uCount, val);
PaceMsaAccess(usDspBaseIO);
}
PRINTK_1(TRACE_3780I,
"3780I::dsp3780D_WriteDStore exit bRC=TRUE\n");
return 0;
}
int dsp3780I_ReadIStore(unsigned short usDspBaseIO, void __user *pvBuffer,
unsigned uCount, unsigned long ulDSPAddr)
{
unsigned short __user *pusBuffer = pvBuffer;
PRINTK_5(TRACE_3780I,
"3780i::dsp3780I_ReadIStore entry usDspBaseIO %x, pusBuffer %p, uCount %x, ulDSPAddr %lx\n",
usDspBaseIO, pusBuffer, uCount, ulDSPAddr);
/*
* Set the initial MSA address. To convert from an instruction store
* address to an MSA address
* shift the address two bits to the left and set bit 22
*/
ulDSPAddr = (ulDSPAddr << 2) | (1 << 22);
spin_lock_irqsave(&dsp_lock, flags);
OutWordDsp(DSP_MsaAddrLow, (unsigned short) ulDSPAddr);
OutWordDsp(DSP_MsaAddrHigh, (unsigned short) (ulDSPAddr >> 16));
spin_unlock_irqrestore(&dsp_lock, flags);
/* Transfer the memory block */
while (uCount-- != 0) {
unsigned short val_lo, val_hi;
spin_lock_irqsave(&dsp_lock, flags);
val_lo = InWordDsp(DSP_MsaDataISLow);
val_hi = InWordDsp(DSP_MsaDataDSISHigh);
spin_unlock_irqrestore(&dsp_lock, flags);
if(put_user(val_lo, pusBuffer++))
return -EFAULT;
if(put_user(val_hi, pusBuffer++))
return -EFAULT;
PRINTK_4(TRACE_3780I,
"3780I::dsp3780I_ReadIStore uCount %x val_lo %x val_hi %x\n",
uCount, val_lo, val_hi);
PaceMsaAccess(usDspBaseIO);
}
PRINTK_1(TRACE_3780I,
"3780I::dsp3780I_ReadIStore exit bRC=TRUE\n");
return 0;
}
int dsp3780I_WriteIStore(unsigned short usDspBaseIO, void __user *pvBuffer,
unsigned uCount, unsigned long ulDSPAddr)
{
unsigned short __user *pusBuffer = pvBuffer;
PRINTK_5(TRACE_3780I,
"3780i::dsp3780I_WriteIStore entry usDspBaseIO %x, pusBuffer %p, uCount %x, ulDSPAddr %lx\n",
usDspBaseIO, pusBuffer, uCount, ulDSPAddr);
/*
* Set the initial MSA address. To convert from an instruction store
* address to an MSA address
* shift the address two bits to the left and set bit 22
*/
ulDSPAddr = (ulDSPAddr << 2) | (1 << 22);
spin_lock_irqsave(&dsp_lock, flags);
OutWordDsp(DSP_MsaAddrLow, (unsigned short) ulDSPAddr);
OutWordDsp(DSP_MsaAddrHigh, (unsigned short) (ulDSPAddr >> 16));
spin_unlock_irqrestore(&dsp_lock, flags);
/* Transfer the memory block */
while (uCount-- != 0) {
unsigned short val_lo, val_hi;
if(get_user(val_lo, pusBuffer++))
return -EFAULT;
if(get_user(val_hi, pusBuffer++))
return -EFAULT;
spin_lock_irqsave(&dsp_lock, flags);
OutWordDsp(DSP_MsaDataISLow, val_lo);
OutWordDsp(DSP_MsaDataDSISHigh, val_hi);
spin_unlock_irqrestore(&dsp_lock, flags);
PRINTK_4(TRACE_3780I,
"3780I::dsp3780I_WriteIStore uCount %x val_lo %x val_hi %x\n",
uCount, val_lo, val_hi);
PaceMsaAccess(usDspBaseIO);
}
PRINTK_1(TRACE_3780I,
"3780I::dsp3780I_WriteIStore exit bRC=TRUE\n");
return 0;
}
int dsp3780I_GetIPCSource(unsigned short usDspBaseIO,
unsigned short *pusIPCSource)
{
DSP_HBRIDGE_CONTROL rHBridgeControl;
unsigned short temp;
PRINTK_3(TRACE_3780I,
"3780i::dsp3780I_GetIPCSource entry usDspBaseIO %x pusIPCSource %p\n",
usDspBaseIO, pusIPCSource);
/*
* Disable DSP to PC interrupts, read the interrupt register,
* clear the pending IPC bits, and reenable DSP to PC interrupts
*/
spin_lock_irqsave(&dsp_lock, flags);
MKWORD(rHBridgeControl) = InWordDsp(DSP_HBridgeControl);
rHBridgeControl.EnableDspInt = FALSE;
OutWordDsp(DSP_HBridgeControl, MKWORD(rHBridgeControl));
*pusIPCSource = InWordDsp(DSP_Interrupt);
temp = (unsigned short) ~(*pusIPCSource);
PRINTK_3(TRACE_3780I,
"3780i::dsp3780I_GetIPCSource, usIPCSource %x ~ %x\n",
*pusIPCSource, temp);
OutWordDsp(DSP_Interrupt, (unsigned short) ~(*pusIPCSource));
rHBridgeControl.EnableDspInt = TRUE;
OutWordDsp(DSP_HBridgeControl, MKWORD(rHBridgeControl));
spin_unlock_irqrestore(&dsp_lock, flags);
PRINTK_2(TRACE_3780I,
"3780i::dsp3780I_GetIPCSource exit usIPCSource %x\n",
*pusIPCSource);
return 0;
}