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openwrt-xburst/package/ltq-dsl/src/lantiq_mei.c

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/******************************************************************************
Copyright (c) 2009
Infineon Technologies AG
Am Campeon 1-12; 81726 Munich, Germany
For licensing information, see the file 'LICENSE' in the root folder of
this software module.
******************************************************************************/
/*!
\defgroup AMAZON_S_MEI Amazon-S MEI Driver Module
\brief Amazon-S MEI driver module
*/
/*!
\defgroup Internal Compile Parametere
\ingroup AMAZON_S_MEI
\brief exported functions for other driver use
*/
/*!
\file amazon_s_mei_bsp.c
\ingroup AMAZON_S_MEI
\brief Amazon-S MEI driver file
*/
#include <linux/kernel.h>
#include <linux/module.h>
#include <linux/version.h>
#if (LINUX_VERSION_CODE < KERNEL_VERSION(2,6,33))
#include <linux/utsrelease.h>
#else
#include <generated/utsrelease.h>
#endif
#include <linux/types.h>
#include <linux/fs.h>
#include <linux/mm.h>
#include <linux/errno.h>
#include <linux/interrupt.h>
#include <linux/netdevice.h>
#include <linux/etherdevice.h>
#include <linux/proc_fs.h>
#include <linux/init.h>
#include <linux/ioport.h>
#include <linux/delay.h>
#include <linux/device.h>
#include <linux/sched.h>
#include <asm/uaccess.h>
#include <asm/hardirq.h>
#include <lantiq_soc.h>
#include "ifxmips_atm.h"
#define IFX_MEI_BSP
#include "ifxmips_mei_interface.h"
/*#define LTQ_RCU_RST IFX_RCU_RST_REQ
#define LTQ_RCU_RST_REQ_ARC_JTAG IFX_RCU_RST_REQ_ARC_JTAG
#define LTQ_RCU_RST_REQ_DFE IFX_RCU_RST_REQ_DFE
#define LTQ_RCU_RST_REQ_AFE IFX_RCU_RST_REQ_AFE
#define IFXMIPS_FUSE_BASE_ADDR IFX_FUSE_BASE_ADDR
#define IFXMIPS_ICU_IM0_IER IFX_ICU_IM0_IER
#define IFXMIPS_ICU_IM2_IER IFX_ICU_IM2_IER
#define LTQ_MEI_INT IFX_MEI_INT
#define LTQ_MEI_DYING_GASP_INT IFX_MEI_DYING_GASP_INT
#define LTQ_MEI_BASE_ADDR IFX_MEI_SPACE_ACCESS
#define IFXMIPS_PMU_PWDCR IFX_PMU_PWDCR
#define IFXMIPS_MPS_CHIPID IFX_MPS_CHIPID
#define ifxmips_port_reserve_pin ifx_gpio_pin_reserve
#define ifxmips_port_set_dir_in ifx_gpio_dir_in_set
#define ifxmips_port_clear_altsel0 ifx_gpio_altsel0_set
#define ifxmips_port_clear_altsel1 ifx_gpio_altsel1_clear
#define ifxmips_port_set_open_drain ifx_gpio_open_drain_clear
#define ifxmips_port_free_pin ifx_gpio_pin_free
#define ifxmips_mask_and_ack_irq bsp_mask_and_ack_irq
#define IFXMIPS_MPS_CHIPID_VERSION_GET IFX_MCD_CHIPID_VERSION_GET
#define ltq_r32(reg) __raw_readl(reg)
#define ltq_w32(val, reg) __raw_writel(val, reg)
#define ltq_w32_mask(clear, set, reg) ltq_w32((ltq_r32(reg) & ~clear) | set, reg)
*/
#define LTQ_RCU_RST_REQ_DFE (1 << 7)
#define LTQ_RCU_RST_REQ_AFE (1 << 11)
#define LTQ_PMU_BASE (KSEG1 + LTQ_PMU_BASE_ADDR)
#define LTQ_RCU_BASE (KSEG1 + LTQ_RCU_BASE_ADDR)
#define LTQ_ICU_BASE (KSEG1 + LTQ_ICU_BASE_ADDR)
#define LTQ_PMU_PWDCR ((u32 *)(LTQ_PMU_BASE + 0x001C))
#define LTQ_PMU_PWDSR ((u32 *)(LTQ_PMU_BASE + 0x0020))
#define LTQ_RCU_RST ((u32 *)(LTQ_RCU_BASE + 0x0010))
#define LTQ_RCU_RST_ALL 0x40000000
#define LTQ_ICU_IM0_ISR ((u32 *)(LTQ_ICU_BASE + 0x0000))
#define LTQ_ICU_IM0_IER ((u32 *)(LTQ_ICU_BASE + 0x0008))
#define LTQ_ICU_IM0_IOSR ((u32 *)(LTQ_ICU_BASE + 0x0010))
#define LTQ_ICU_IM0_IRSR ((u32 *)(LTQ_ICU_BASE + 0x0018))
#define LTQ_ICU_IM0_IMR ((u32 *)(LTQ_ICU_BASE + 0x0020))
#define LTQ_ICU_IM1_ISR ((u32 *)(LTQ_ICU_BASE + 0x0028))
#define LTQ_ICU_IM2_ISR ((u32 *)(LTQ_ICU_BASE + 0x0050))
#define LTQ_ICU_IM3_ISR ((u32 *)(LTQ_ICU_BASE + 0x0078))
#define LTQ_ICU_IM4_ISR ((u32 *)(LTQ_ICU_BASE + 0x00A0))
#define LTQ_ICU_OFFSET (LTQ_ICU_IM1_ISR - LTQ_ICU_IM0_ISR)
#define LTQ_ICU_IM2_IER (LTQ_ICU_IM0_IER + LTQ_ICU_OFFSET)
#define IFX_MEI_EMSG(fmt, args...) pr_err("[%s %d]: " fmt,__FUNCTION__, __LINE__, ## args)
#define IFX_MEI_DMSG(fmt, args...) pr_debug("[%s %d]: " fmt,__FUNCTION__, __LINE__, ## args)
#define LTQ_FUSE_BASE (KSEG1 + 0x1F107354)
#ifdef CONFIG_LTQ_MEI_FW_LOOPBACK
//#define DFE_MEM_TEST
//#define DFE_PING_TEST
#define DFE_ATM_LOOPBACK
#ifdef DFE_ATM_LOOPBACK
#include <asm/ifxmips/ifxmips_mei_fw_loopback.h>
#endif
void dfe_loopback_irq_handler (DSL_DEV_Device_t *pDev);
#endif //CONFIG_AMAZON_S_MEI_FW_LOOPBACK
DSL_DEV_Version_t bsp_mei_version = {
major: 5,
minor: 0,
revision:0
};
DSL_DEV_HwVersion_t bsp_chip_info;
#define IFX_MEI_DEVNAME "ifx_mei"
#define BSP_MAX_DEVICES 1
DSL_DEV_MeiError_t DSL_BSP_FWDownload (DSL_DEV_Device_t *, const char *, unsigned long, long *, long *);
DSL_DEV_MeiError_t DSL_BSP_Showtime (DSL_DEV_Device_t *, DSL_uint32_t, DSL_uint32_t);
DSL_DEV_MeiError_t DSL_BSP_AdslLedInit (DSL_DEV_Device_t *, DSL_DEV_LedId_t, DSL_DEV_LedType_t, DSL_DEV_LedHandler_t);
//DSL_DEV_MeiError_t DSL_BSP_AdslLedSet (DSL_DEV_Device_t *, DSL_DEV_LedId_t, DSL_DEV_LedMode_t);
DSL_DEV_MeiError_t DSL_BSP_MemoryDebugAccess (DSL_DEV_Device_t *, DSL_BSP_MemoryAccessType_t, DSL_uint32_t, DSL_uint32_t*, DSL_uint32_t);
DSL_DEV_MeiError_t DSL_BSP_SendCMV (DSL_DEV_Device_t *, u16 *, int, u16 *);
int DSL_BSP_KernelIoctls (DSL_DEV_Device_t *, unsigned int, unsigned long);
static DSL_DEV_MeiError_t IFX_MEI_RunAdslModem (DSL_DEV_Device_t *);
static DSL_DEV_MeiError_t IFX_MEI_CpuModeSet (DSL_DEV_Device_t *, DSL_DEV_CpuMode_t);
static DSL_DEV_MeiError_t IFX_MEI_DownloadBootCode (DSL_DEV_Device_t *);
static DSL_DEV_MeiError_t IFX_MEI_ArcJtagEnable (DSL_DEV_Device_t *, int);
static DSL_DEV_MeiError_t IFX_MEI_AdslMailboxIRQEnable (DSL_DEV_Device_t *, int);
static int IFX_MEI_GetPage (DSL_DEV_Device_t *, u32, u32, u32, u32 *, u32 *);
static int IFX_MEI_BarUpdate (DSL_DEV_Device_t *, int);
static ssize_t IFX_MEI_Write (DSL_DRV_file_t *, const char *, size_t, loff_t *);
#if (LINUX_VERSION_CODE < KERNEL_VERSION(2,6,36))
static int IFX_MEI_UserIoctls (DSL_DRV_inode_t *, DSL_DRV_file_t *, unsigned int, unsigned long);
#else
static int IFX_MEI_UserIoctls (DSL_DRV_file_t *, unsigned int, unsigned long);
#endif
static int IFX_MEI_Open (DSL_DRV_inode_t *, DSL_DRV_file_t *);
static int IFX_MEI_Release (DSL_DRV_inode_t *, DSL_DRV_file_t *);
void AMAZON_SE_MEI_ARC_MUX_Test(void);
#ifdef CONFIG_PROC_FS
static int IFX_MEI_ProcRead (struct file *, char *, size_t, loff_t *);
static ssize_t IFX_MEI_ProcWrite (struct file *, const char *, size_t, loff_t *);
#define PROC_ITEMS 11
#define MEI_DIRNAME "ifxmips_mei"
static struct proc_dir_entry *meidir;
static struct file_operations IFX_MEI_ProcOperations = {
read:IFX_MEI_ProcRead,
write:IFX_MEI_ProcWrite,
};
static reg_entry_t regs[BSP_MAX_DEVICES][PROC_ITEMS]; //total items to be monitored by /proc/mei
#define NUM_OF_REG_ENTRY (sizeof(regs[0])/sizeof(reg_entry_t))
#endif //CONFIG_PROC_FS
void IFX_MEI_ARC_MUX_Test(void);
static int adsl_dummy_ledcallback(void);
int (*ifx_mei_atm_showtime_enter)(struct port_cell_info *, void *) = NULL;
EXPORT_SYMBOL(ifx_mei_atm_showtime_enter);
int (*ifx_mei_atm_showtime_exit)(void) = NULL;
EXPORT_SYMBOL(ifx_mei_atm_showtime_exit);
static int (*g_adsl_ledcallback)(void) = adsl_dummy_ledcallback;
static unsigned int g_tx_link_rate[2] = {0};
static void *g_xdata_addr = NULL;
static u32 *mei_arc_swap_buff = NULL; // holding swap pages
#if (LINUX_VERSION_CODE < KERNEL_VERSION(2,6,39))
extern void ltq_mask_and_ack_irq(unsigned int irq_nr);
#define MEI_MASK_AND_ACK_IRQ ltq_mask_and_ack_irq
#else
extern void ltq_mask_and_ack_irq(struct irq_data *d);
static void inline MEI_MASK_AND_ACK_IRQ(int x)
{
struct irq_data d;
d.irq = x;
ltq_mask_and_ack_irq(&d);
}
#endif
#define MEI_MAJOR 105
static int dev_major = MEI_MAJOR;
static struct file_operations bsp_mei_operations = {
owner:THIS_MODULE,
open:IFX_MEI_Open,
release:IFX_MEI_Release,
write:IFX_MEI_Write,
#if (LINUX_VERSION_CODE < KERNEL_VERSION(2,6,36))
ioctl:IFX_MEI_UserIoctls,
#else
unlocked_ioctl:IFX_MEI_UserIoctls,
#endif
};
static DSL_DEV_Device_t dsl_devices[BSP_MAX_DEVICES];
static ifx_mei_device_private_t
sDanube_Mei_Private[BSP_MAX_DEVICES];
static DSL_BSP_EventCallBack_t dsl_bsp_event_callback[DSL_BSP_CB_LAST + 1];
/**
* Write a value to register
* This function writes a value to danube register
*
* \param ul_address The address to write
* \param ul_data The value to write
* \ingroup Internal
*/
static void
IFX_MEI_LongWordWrite (u32 ul_address, u32 ul_data)
{
IFX_MEI_WRITE_REGISTER_L (ul_data, ul_address);
wmb();
return;
}
/**
* Write a value to register
* This function writes a value to danube register
*
* \param pDev the device pointer
* \param ul_address The address to write
* \param ul_data The value to write
* \ingroup Internal
*/
static void
IFX_MEI_LongWordWriteOffset (DSL_DEV_Device_t * pDev, u32 ul_address,
u32 ul_data)
{
IFX_MEI_WRITE_REGISTER_L (ul_data, pDev->base_address + ul_address);
wmb();
return;
}
/**
* Read the danube register
* This function read the value from danube register
*
* \param ul_address The address to write
* \param pul_data Pointer to the data
* \ingroup Internal
*/
static void
IFX_MEI_LongWordRead (u32 ul_address, u32 * pul_data)
{
*pul_data = IFX_MEI_READ_REGISTER_L (ul_address);
rmb();
return;
}
/**
* Read the danube register
* This function read the value from danube register
*
* \param pDev the device pointer
* \param ul_address The address to write
* \param pul_data Pointer to the data
* \ingroup Internal
*/
static void
IFX_MEI_LongWordReadOffset (DSL_DEV_Device_t * pDev, u32 ul_address,
u32 * pul_data)
{
*pul_data = IFX_MEI_READ_REGISTER_L (pDev->base_address + ul_address);
rmb();
return;
}
/**
* Write several DWORD datas to ARC memory via ARC DMA interface
* This function writes several DWORD datas to ARC memory via DMA interface.
*
* \param pDev the device pointer
* \param destaddr The address to write
* \param databuff Pointer to the data buffer
* \param databuffsize Number of DWORDs to write
* \return DSL_DEV_MEI_ERR_SUCCESS or DSL_DEV_MEI_ERR_FAILURE
* \ingroup Internal
*/
static DSL_DEV_MeiError_t
IFX_MEI_DMAWrite (DSL_DEV_Device_t * pDev, u32 destaddr,
u32 * databuff, u32 databuffsize)
{
u32 *p = databuff;
u32 temp;
if (destaddr & 3)
return DSL_DEV_MEI_ERR_FAILURE;
// Set the write transfer address
IFX_MEI_LongWordWriteOffset (pDev, ME_DX_AD, destaddr);
// Write the data pushed across DMA
while (databuffsize--) {
temp = *p;
if (destaddr == MEI_TO_ARC_MAILBOX)
MEI_HALF_WORD_SWAP (temp);
IFX_MEI_LongWordWriteOffset (pDev, (u32) ME_DX_DATA, temp);
p++;
}
return DSL_DEV_MEI_ERR_SUCCESS;
}
/**
* Read several DWORD datas from ARC memory via ARC DMA interface
* This function reads several DWORD datas from ARC memory via DMA interface.
*
* \param pDev the device pointer
* \param srcaddr The address to read
* \param databuff Pointer to the data buffer
* \param databuffsize Number of DWORDs to read
* \return DSL_DEV_MEI_ERR_SUCCESS or DSL_DEV_MEI_ERR_FAILURE
* \ingroup Internal
*/
static DSL_DEV_MeiError_t
IFX_MEI_DMARead (DSL_DEV_Device_t * pDev, u32 srcaddr, u32 * databuff,
u32 databuffsize)
{
u32 *p = databuff;
u32 temp;
if (srcaddr & 3)
return DSL_DEV_MEI_ERR_FAILURE;
// Set the read transfer address
IFX_MEI_LongWordWriteOffset (pDev, (u32) ME_DX_AD, srcaddr);
// Read the data popped across DMA
while (databuffsize--) {
IFX_MEI_LongWordReadOffset (pDev, (u32) ME_DX_DATA, &temp);
if (databuff == (u32 *) DSL_DEV_PRIVATE(pDev)->CMV_RxMsg) // swap half word
MEI_HALF_WORD_SWAP (temp);
*p = temp;
p++;
}
return DSL_DEV_MEI_ERR_SUCCESS;
}
/**
* Switch the ARC control mode
* This function switchs the ARC control mode to JTAG mode or MEI mode
*
* \param pDev the device pointer
* \param mode The mode want to switch: JTAG_MASTER_MODE or MEI_MASTER_MODE.
* \ingroup Internal
*/
static void
IFX_MEI_ControlModeSet (DSL_DEV_Device_t * pDev, int mode)
{
u32 temp = 0x0;
IFX_MEI_LongWordReadOffset (pDev, (u32) ME_DBG_MASTER, &temp);
switch (mode) {
case JTAG_MASTER_MODE:
temp &= ~(HOST_MSTR);
break;
case MEI_MASTER_MODE:
temp |= (HOST_MSTR);
break;
default:
IFX_MEI_EMSG ("IFX_MEI_ControlModeSet: unkonwn mode [%d]\n", mode);
return;
}
IFX_MEI_LongWordWriteOffset (pDev, (u32) ME_DBG_MASTER, temp);
}
/**
* Disable ARC to MEI interrupt
*
* \param pDev the device pointer
* \ingroup Internal
*/
static void
IFX_MEI_IRQDisable (DSL_DEV_Device_t * pDev)
{
IFX_MEI_LongWordWriteOffset (pDev, (u32) ME_ARC2ME_MASK, 0x0);
}
/**
* Eable ARC to MEI interrupt
*
* \param pDev the device pointer
* \ingroup Internal
*/
static void
IFX_MEI_IRQEnable (DSL_DEV_Device_t * pDev)
{
IFX_MEI_LongWordWriteOffset (pDev, (u32) ME_ARC2ME_MASK, MSGAV_EN);
}
/**
* Poll for transaction complete signal
* This function polls and waits for transaction complete signal.
*
* \param pDev the device pointer
* \ingroup Internal
*/
static void
meiPollForDbgDone (DSL_DEV_Device_t * pDev)
{
u32 query = 0;
int i = 0;
while (i < WHILE_DELAY) {
IFX_MEI_LongWordReadOffset (pDev, (u32) ME_ARC2ME_STAT, &query);
query &= (ARC_TO_MEI_DBG_DONE);
if (query)
break;
i++;
if (i == WHILE_DELAY) {
IFX_MEI_EMSG ("PollforDbg fail!\n");
}
}
IFX_MEI_LongWordWriteOffset (pDev, (u32) ME_ARC2ME_STAT, ARC_TO_MEI_DBG_DONE); // to clear this interrupt
}
/**
* ARC Debug Memory Access for a single DWORD reading.
* This function used for direct, address-based access to ARC memory.
*
* \param pDev the device pointer
* \param DEC_mode ARC memory space to used
* \param address Address to read
* \param data Pointer to data
* \return DSL_DEV_MEI_ERR_SUCCESS or DSL_DEV_MEI_ERR_FAILURE
* \ingroup Internal
*/
static DSL_DEV_MeiError_t
_IFX_MEI_DBGLongWordRead (DSL_DEV_Device_t * pDev, u32 DEC_mode,
u32 address, u32 * data)
{
IFX_MEI_LongWordWriteOffset (pDev, (u32) ME_DBG_DECODE, DEC_mode);
IFX_MEI_LongWordWriteOffset (pDev, (u32) ME_DBG_RD_AD, address);
meiPollForDbgDone (pDev);
IFX_MEI_LongWordReadOffset (pDev, (u32) ME_DBG_DATA, data);
return DSL_DEV_MEI_ERR_SUCCESS;
}
/**
* ARC Debug Memory Access for a single DWORD writing.
* This function used for direct, address-based access to ARC memory.
*
* \param pDev the device pointer
* \param DEC_mode ARC memory space to used
* \param address The address to write
* \param data The data to write
* \return DSL_DEV_MEI_ERR_SUCCESS or DSL_DEV_MEI_ERR_FAILURE
* \ingroup Internal
*/
static DSL_DEV_MeiError_t
_IFX_MEI_DBGLongWordWrite (DSL_DEV_Device_t * pDev, u32 DEC_mode,
u32 address, u32 data)
{
IFX_MEI_LongWordWriteOffset (pDev, (u32) ME_DBG_DECODE, DEC_mode);
IFX_MEI_LongWordWriteOffset (pDev, (u32) ME_DBG_WR_AD, address);
IFX_MEI_LongWordWriteOffset (pDev, (u32) ME_DBG_DATA, data);
meiPollForDbgDone (pDev);
return DSL_DEV_MEI_ERR_SUCCESS;
}
/**
* ARC Debug Memory Access for writing.
* This function used for direct, address-based access to ARC memory.
*
* \param pDev the device pointer
* \param destaddr The address to read
* \param databuffer Pointer to data
* \param databuffsize The number of DWORDs to read
* \return DSL_DEV_MEI_ERR_SUCCESS or DSL_DEV_MEI_ERR_FAILURE
* \ingroup Internal
*/
static DSL_DEV_MeiError_t
IFX_MEI_DebugWrite (DSL_DEV_Device_t * pDev, u32 destaddr,
u32 * databuff, u32 databuffsize)
{
u32 i;
u32 temp = 0x0;
u32 address = 0x0;
u32 *buffer = 0x0;
// Open the debug port before DMP memory write
IFX_MEI_ControlModeSet (pDev, MEI_MASTER_MODE);
// For the requested length, write the address and write the data
address = destaddr;
buffer = databuff;
for (i = 0; i < databuffsize; i++) {
temp = *buffer;
_IFX_MEI_DBGLongWordWrite (pDev, ME_DBG_DECODE_DMP1_MASK, address, temp);
address += 4;
buffer++;
}
// Close the debug port after DMP memory write
IFX_MEI_ControlModeSet (pDev, JTAG_MASTER_MODE);
return DSL_DEV_MEI_ERR_SUCCESS;
}
/**
* ARC Debug Memory Access for reading.
* This function used for direct, address-based access to ARC memory.
*
* \param pDev the device pointer
* \param srcaddr The address to read
* \param databuffer Pointer to data
* \param databuffsize The number of DWORDs to read
* \return DSL_DEV_MEI_ERR_SUCCESS or DSL_DEV_MEI_ERR_FAILURE
* \ingroup Internal
*/
static DSL_DEV_MeiError_t
IFX_MEI_DebugRead (DSL_DEV_Device_t * pDev, u32 srcaddr, u32 * databuff, u32 databuffsize)
{
u32 i;
u32 temp = 0x0;
u32 address = 0x0;
u32 *buffer = 0x0;
// Open the debug port before DMP memory read
IFX_MEI_ControlModeSet (pDev, MEI_MASTER_MODE);
// For the requested length, write the address and read the data
address = srcaddr;
buffer = databuff;
for (i = 0; i < databuffsize; i++) {
_IFX_MEI_DBGLongWordRead (pDev, ME_DBG_DECODE_DMP1_MASK, address, &temp);
*buffer = temp;
address += 4;
buffer++;
}
// Close the debug port after DMP memory read
IFX_MEI_ControlModeSet (pDev, JTAG_MASTER_MODE);
return DSL_DEV_MEI_ERR_SUCCESS;
}
/**
* Send a message to ARC MailBox.
* This function sends a message to ARC Mailbox via ARC DMA interface.
*
* \param pDev the device pointer
* \param msgsrcbuffer Pointer to message.
* \param msgsize The number of words to write.
* \return DSL_DEV_MEI_ERR_SUCCESS or DSL_DEV_MEI_ERR_FAILURE
* \ingroup Internal
*/
static DSL_DEV_MeiError_t
IFX_MEI_MailboxWrite (DSL_DEV_Device_t * pDev, u16 * msgsrcbuffer,
u16 msgsize)
{
int i;
u32 arc_mailbox_status = 0x0;
u32 temp = 0;
DSL_DEV_MeiError_t meiMailboxError = DSL_DEV_MEI_ERR_SUCCESS;
// Write to mailbox
meiMailboxError =
IFX_MEI_DMAWrite (pDev, MEI_TO_ARC_MAILBOX, (u32 *) msgsrcbuffer, msgsize / 2);
meiMailboxError =
IFX_MEI_DMAWrite (pDev, MEI_TO_ARC_MAILBOXR, (u32 *) (&temp), 1);
// Notify arc that mailbox write completed
DSL_DEV_PRIVATE(pDev)->cmv_waiting = 1;
IFX_MEI_LongWordWriteOffset (pDev, (u32) ME_ME2ARC_INT, MEI_TO_ARC_MSGAV);
i = 0;
while (i < WHILE_DELAY) { // wait for ARC to clear the bit
IFX_MEI_LongWordReadOffset (pDev, (u32) ME_ME2ARC_INT, &arc_mailbox_status);
if ((arc_mailbox_status & MEI_TO_ARC_MSGAV) != MEI_TO_ARC_MSGAV)
break;
i++;
if (i == WHILE_DELAY) {
IFX_MEI_EMSG (">>> Timeout waiting for ARC to clear MEI_TO_ARC_MSGAV!!!"
" MEI_TO_ARC message size = %d DWORDs <<<\n", msgsize/2);
meiMailboxError = DSL_DEV_MEI_ERR_FAILURE;
}
}
return meiMailboxError;
}
/**
* Read a message from ARC MailBox.
* This function reads a message from ARC Mailbox via ARC DMA interface.
*
* \param pDev the device pointer
* \param msgsrcbuffer Pointer to message.
* \param msgsize The number of words to read
* \return DSL_DEV_MEI_ERR_SUCCESS or DSL_DEV_MEI_ERR_FAILURE
* \ingroup Internal
*/
static DSL_DEV_MeiError_t
IFX_MEI_MailboxRead (DSL_DEV_Device_t * pDev, u16 * msgdestbuffer,
u16 msgsize)
{
DSL_DEV_MeiError_t meiMailboxError = DSL_DEV_MEI_ERR_SUCCESS;
// Read from mailbox
meiMailboxError =
IFX_MEI_DMARead (pDev, ARC_TO_MEI_MAILBOX, (u32 *) msgdestbuffer, msgsize / 2);
// Notify arc that mailbox read completed
IFX_MEI_LongWordWriteOffset (pDev, (u32) ME_ARC2ME_STAT, ARC_TO_MEI_MSGAV);
return meiMailboxError;
}
/**
* Download boot pages to ARC.
* This function downloads boot pages to ARC.
*
* \param pDev the device pointer
* \return DSL_DEV_MEI_ERR_SUCCESS or DSL_DEV_MEI_ERR_FAILURE
* \ingroup Internal
*/
static DSL_DEV_MeiError_t
IFX_MEI_DownloadBootPages (DSL_DEV_Device_t * pDev)
{
int boot_loop;
int page_size;
u32 dest_addr;
/*
** DMA the boot code page(s)
*/
for (boot_loop = 1;
boot_loop <
(DSL_DEV_PRIVATE(pDev)->img_hdr-> count); boot_loop++) {
if ((DSL_DEV_PRIVATE(pDev)-> img_hdr->page[boot_loop].p_size) & BOOT_FLAG) {
page_size = IFX_MEI_GetPage (pDev, boot_loop,
GET_PROG, MAXSWAPSIZE,
mei_arc_swap_buff,
&dest_addr);
if (page_size > 0) {
IFX_MEI_DMAWrite (pDev, dest_addr,
mei_arc_swap_buff,
page_size);
}
}
if ((DSL_DEV_PRIVATE(pDev)-> img_hdr->page[boot_loop].d_size) & BOOT_FLAG) {
page_size = IFX_MEI_GetPage (pDev, boot_loop,
GET_DATA, MAXSWAPSIZE,
mei_arc_swap_buff,
&dest_addr);
if (page_size > 0) {
IFX_MEI_DMAWrite (pDev, dest_addr,
mei_arc_swap_buff,
page_size);
}
}
}
return DSL_DEV_MEI_ERR_SUCCESS;
}
/**
* Initial efuse rar.
**/
static void
IFX_MEI_FuseInit (DSL_DEV_Device_t * pDev)
{
u32 data = 0;
IFX_MEI_DMAWrite (pDev, IRAM0_BASE, &data, 1);
IFX_MEI_DMAWrite (pDev, IRAM0_BASE + 4, &data, 1);
IFX_MEI_DMAWrite (pDev, IRAM1_BASE, &data, 1);
IFX_MEI_DMAWrite (pDev, IRAM1_BASE + 4, &data, 1);
IFX_MEI_DMAWrite (pDev, BRAM_BASE, &data, 1);
IFX_MEI_DMAWrite (pDev, BRAM_BASE + 4, &data, 1);
IFX_MEI_DMAWrite (pDev, ADSL_DILV_BASE, &data, 1);
IFX_MEI_DMAWrite (pDev, ADSL_DILV_BASE + 4, &data, 1);
}
/**
* efuse rar program
**/
static void
IFX_MEI_FuseProg (DSL_DEV_Device_t * pDev)
{
u32 reg_data, fuse_value;
int i = 0;
IFX_MEI_LongWordRead ((u32) LTQ_RCU_RST, &reg_data);
while ((reg_data & 0x10000000) == 0) {
IFX_MEI_LongWordRead ((u32) LTQ_RCU_RST, &reg_data);
i++;
/* 0x4000 translate to about 16 ms@111M, so should be enough */
if (i == 0x4000)
return;
}
// STEP a: Prepare memory for external accesses
// Write fuse_en bit24
IFX_MEI_LongWordRead ((u32) LTQ_RCU_RST, &reg_data);
IFX_MEI_LongWordWrite ((u32) LTQ_RCU_RST, reg_data | (1 << 24));
IFX_MEI_FuseInit (pDev);
for (i = 0; i < 4; i++) {
IFX_MEI_LongWordRead ((u32) (LTQ_FUSE_BASE) + i * 4, &fuse_value);
switch (fuse_value & 0xF0000) {
case 0x80000:
reg_data = ((fuse_value & RX_DILV_ADDR_BIT_MASK) |
(RX_DILV_ADDR_BIT_MASK + 0x1));
IFX_MEI_DMAWrite (pDev, ADSL_DILV_BASE, &reg_data, 1);
break;
case 0x90000:
reg_data = ((fuse_value & RX_DILV_ADDR_BIT_MASK) |
(RX_DILV_ADDR_BIT_MASK + 0x1));
IFX_MEI_DMAWrite (pDev, ADSL_DILV_BASE + 4, &reg_data, 1);
break;
case 0xA0000:
reg_data = ((fuse_value & IRAM0_ADDR_BIT_MASK) |
(IRAM0_ADDR_BIT_MASK + 0x1));
IFX_MEI_DMAWrite (pDev, IRAM0_BASE, &reg_data, 1);
break;
case 0xB0000:
reg_data = ((fuse_value & IRAM0_ADDR_BIT_MASK) |
(IRAM0_ADDR_BIT_MASK + 0x1));
IFX_MEI_DMAWrite (pDev, IRAM0_BASE + 4, &reg_data, 1);
break;
case 0xC0000:
reg_data = ((fuse_value & IRAM1_ADDR_BIT_MASK) |
(IRAM1_ADDR_BIT_MASK + 0x1));
IFX_MEI_DMAWrite (pDev, IRAM1_BASE, &reg_data, 1);
break;
case 0xD0000:
reg_data = ((fuse_value & IRAM1_ADDR_BIT_MASK) |
(IRAM1_ADDR_BIT_MASK + 0x1));
IFX_MEI_DMAWrite (pDev, IRAM1_BASE + 4, &reg_data, 1);
break;
case 0xE0000:
reg_data = ((fuse_value & BRAM_ADDR_BIT_MASK) |
(BRAM_ADDR_BIT_MASK + 0x1));
IFX_MEI_DMAWrite (pDev, BRAM_BASE, &reg_data, 1);
break;
case 0xF0000:
reg_data = ((fuse_value & BRAM_ADDR_BIT_MASK) |
(BRAM_ADDR_BIT_MASK + 0x1));
IFX_MEI_DMAWrite (pDev, BRAM_BASE + 4, &reg_data, 1);
break;
default: // PPE efuse
break;
}
}
IFX_MEI_LongWordRead ((u32) LTQ_RCU_RST, &reg_data);
IFX_MEI_LongWordWrite ((u32) LTQ_RCU_RST, reg_data & ~(1 << 24));
IFX_MEI_LongWordRead ((u32) LTQ_RCU_RST, &reg_data);
}
/**
* Enable DFE Clock
* This function enables DFE Clock
*
* \param pDev the device pointer
* \return DSL_DEV_MEI_ERR_SUCCESS or DSL_DEV_MEI_ERR_FAILURE
* \ingroup Internal
*/
static DSL_DEV_MeiError_t
IFX_MEI_EnableCLK (DSL_DEV_Device_t * pDev)
{
u32 arc_debug_data = 0;
IFX_MEI_ControlModeSet (pDev, MEI_MASTER_MODE);
//enable ac_clk signal
_IFX_MEI_DBGLongWordRead (pDev, ME_DBG_DECODE_DMP1_MASK,
CRI_CCR0, &arc_debug_data);
arc_debug_data |= ACL_CLK_MODE_ENABLE;
_IFX_MEI_DBGLongWordWrite (pDev, ME_DBG_DECODE_DMP1_MASK,
CRI_CCR0, arc_debug_data);
IFX_MEI_ControlModeSet (pDev, JTAG_MASTER_MODE);
return DSL_DEV_MEI_ERR_SUCCESS;
}
/**
* Halt the ARC.
* This function halts the ARC.
*
* \param pDev the device pointer
* \return DSL_DEV_MEI_ERR_SUCCESS or DSL_DEV_MEI_ERR_FAILURE
* \ingroup Internal
*/
static DSL_DEV_MeiError_t
IFX_MEI_HaltArc (DSL_DEV_Device_t * pDev)
{
u32 arc_debug_data = 0x0;
// Switch arc control from JTAG mode to MEI mode
IFX_MEI_ControlModeSet (pDev, MEI_MASTER_MODE);
_IFX_MEI_DBGLongWordRead (pDev, MEI_DEBUG_DEC_AUX_MASK,
ARC_DEBUG, &arc_debug_data);
arc_debug_data |= ARC_DEBUG_HALT;
_IFX_MEI_DBGLongWordWrite (pDev, MEI_DEBUG_DEC_AUX_MASK,
ARC_DEBUG, arc_debug_data);
// Switch arc control from MEI mode to JTAG mode
IFX_MEI_ControlModeSet (pDev, JTAG_MASTER_MODE);
MEI_WAIT (10);
return DSL_DEV_MEI_ERR_SUCCESS;
}
/**
* Run the ARC.
* This function runs the ARC.
*
* \param pDev the device pointer
* \return DSL_DEV_MEI_ERR_SUCCESS or DSL_DEV_MEI_ERR_FAILURE
* \ingroup Internal
*/
static DSL_DEV_MeiError_t
IFX_MEI_RunArc (DSL_DEV_Device_t * pDev)
{
u32 arc_debug_data = 0x0;
// Switch arc control from JTAG mode to MEI mode- write '1' to bit0
IFX_MEI_ControlModeSet (pDev, MEI_MASTER_MODE);
_IFX_MEI_DBGLongWordRead (pDev, MEI_DEBUG_DEC_AUX_MASK,
AUX_STATUS, &arc_debug_data);
// Write debug data reg with content ANDd with 0xFDFFFFFF (halt bit cleared)
arc_debug_data &= ~ARC_AUX_HALT;
_IFX_MEI_DBGLongWordWrite (pDev, MEI_DEBUG_DEC_AUX_MASK,
AUX_STATUS, arc_debug_data);
// Switch arc control from MEI mode to JTAG mode- write '0' to bit0
IFX_MEI_ControlModeSet (pDev, JTAG_MASTER_MODE);
// Enable mask for arc codeswap interrupts
IFX_MEI_IRQEnable (pDev);
return DSL_DEV_MEI_ERR_SUCCESS;
}
/**
* Reset the ARC.
* This function resets the ARC.
*
* \param pDev the device pointer
* \return DSL_DEV_MEI_ERR_SUCCESS or DSL_DEV_MEI_ERR_FAILURE
* \ingroup Internal
*/
static DSL_DEV_MeiError_t
IFX_MEI_ResetARC (DSL_DEV_Device_t * pDev)
{
u32 arc_debug_data = 0;
IFX_MEI_HaltArc (pDev);
IFX_MEI_LongWordRead ((u32) LTQ_RCU_RST, &arc_debug_data);
IFX_MEI_LongWordWrite ((u32) LTQ_RCU_RST,
arc_debug_data | LTQ_RCU_RST_REQ_DFE | LTQ_RCU_RST_REQ_AFE);
// reset ARC
IFX_MEI_LongWordWriteOffset (pDev, (u32) ME_RST_CTRL, MEI_SOFT_RESET);
IFX_MEI_LongWordWriteOffset (pDev, (u32) ME_RST_CTRL, 0);
IFX_MEI_IRQDisable (pDev);
IFX_MEI_EnableCLK (pDev);
#if 0
// reset part of PPE
*(unsigned long *) (BSP_PPE32_SRST) = 0xC30;
*(unsigned long *) (BSP_PPE32_SRST) = 0xFFF;
#endif
DSL_DEV_PRIVATE(pDev)->modem_ready = 0;
return DSL_DEV_MEI_ERR_SUCCESS;
}
DSL_DEV_MeiError_t
DSL_BSP_Showtime (DSL_DEV_Device_t * dev, DSL_uint32_t rate_fast, DSL_uint32_t rate_intl)
{
struct port_cell_info port_cell = {0};
IFX_MEI_EMSG ("Datarate US intl = %d, fast = %d\n", (int)rate_intl,
(int)rate_fast);
if ( rate_fast )
g_tx_link_rate[0] = rate_fast / (53 * 8);
if ( rate_intl )
g_tx_link_rate[1] = rate_intl / (53 * 8);
if ( g_tx_link_rate[0] == 0 && g_tx_link_rate[1] == 0 ) {
IFX_MEI_EMSG ("Got rate fail.\n");
}
if ( ifx_mei_atm_showtime_enter )
{
port_cell.port_num = 2;
port_cell.tx_link_rate[0] = g_tx_link_rate[0];
port_cell.tx_link_rate[1] = g_tx_link_rate[1];
ifx_mei_atm_showtime_enter(&port_cell, g_xdata_addr);
}
else
{
IFX_MEI_EMSG("no hookup from ATM driver to set cell rate\n");
}
return DSL_DEV_MEI_ERR_SUCCESS;
};
/**
* Reset/halt/run the DFE.
* This function provide operations to reset/halt/run the DFE.
*
* \param pDev the device pointer
* \param mode which operation want to do
* \return DSL_DEV_MEI_ERR_SUCCESS or DSL_DEV_MEI_ERR_FAILURE
* \ingroup Internal
*/
static DSL_DEV_MeiError_t
IFX_MEI_CpuModeSet (DSL_DEV_Device_t *pDev,
DSL_DEV_CpuMode_t mode)
{
DSL_DEV_MeiError_t err_ret = DSL_DEV_MEI_ERR_FAILURE;
switch (mode) {
case DSL_CPU_HALT:
err_ret = IFX_MEI_HaltArc (pDev);
break;
case DSL_CPU_RUN:
err_ret = IFX_MEI_RunArc (pDev);
break;
case DSL_CPU_RESET:
err_ret = IFX_MEI_ResetARC (pDev);
break;
default:
break;
}
return err_ret;
}
/**
* Accress DFE memory.
* This function provide a way to access DFE memory;
*
* \param pDev the device pointer
* \param type read or write
* \param destaddr destination address
* \param databuff pointer to hold data
* \param databuffsize size want to read/write
* \return DSL_DEV_MEI_ERR_SUCCESS or DSL_DEV_MEI_ERR_FAILURE
* \ingroup Internal
*/
DSL_DEV_MeiError_t
DSL_BSP_MemoryDebugAccess (DSL_DEV_Device_t * pDev,
DSL_BSP_MemoryAccessType_t type,
DSL_uint32_t destaddr, DSL_uint32_t *databuff,
DSL_uint32_t databuffsize)
{
DSL_DEV_MeiError_t meierr = DSL_DEV_MEI_ERR_SUCCESS;
switch (type) {
case DSL_BSP_MEMORY_READ:
meierr = IFX_MEI_DebugRead (pDev, (u32)destaddr, (u32*)databuff, (u32)databuffsize);
break;
case DSL_BSP_MEMORY_WRITE:
meierr = IFX_MEI_DebugWrite (pDev, (u32)destaddr, (u32*)databuff, (u32)databuffsize);
break;
}
return DSL_DEV_MEI_ERR_SUCCESS;
};
/**
* Download boot code to ARC.
* This function downloads boot code to ARC.
*
* \param pDev the device pointer
* \return DSL_DEV_MEI_ERR_SUCCESS or DSL_DEV_MEI_ERR_FAILURE
* \ingroup Internal
*/
static DSL_DEV_MeiError_t
IFX_MEI_DownloadBootCode (DSL_DEV_Device_t *pDev)
{
IFX_MEI_IRQDisable (pDev);
IFX_MEI_EnableCLK (pDev);
IFX_MEI_FuseProg (pDev); //program fuse rar
IFX_MEI_DownloadBootPages (pDev);
return DSL_DEV_MEI_ERR_SUCCESS;
};
/**
* Enable Jtag debugger interface
* This function setups mips gpio to enable jtag debugger
*
* \param pDev the device pointer
* \param enable enable or disable
* \return DSL_DEV_MEI_ERR_SUCCESS or DSL_DEV_MEI_ERR_FAILURE
* \ingroup Internal
*/
static DSL_DEV_MeiError_t
IFX_MEI_ArcJtagEnable (DSL_DEV_Device_t *dev, int enable)
{
/*
int meierr=0;
u32 reg_data;
switch (enable) {
case 1:
//reserve gpio 9, 10, 11, 14, 19 for ARC JTAG
ifxmips_port_reserve_pin (0, 9);
ifxmips_port_reserve_pin (0, 10);
ifxmips_port_reserve_pin (0, 11);
ifxmips_port_reserve_pin (0, 14);
ifxmips_port_reserve_pin (1, 3);
ifxmips_port_set_dir_in(0, 11);
ifxmips_port_clear_altsel0(0, 11);
ifxmips_port_clear_altsel1(0, 11);
ifxmips_port_set_open_drain(0, 11);
//enable ARC JTAG
IFX_MEI_LongWordRead ((u32) LTQ_RCU_RST, &reg_data);
IFX_MEI_LongWordWrite ((u32) LTQ_RCU_RST, reg_data | LTQ_RCU_RST_REQ_ARC_JTAG);
break;
case 0:
default:
break;
}
jtag_end:
if (meierr)
return DSL_DEV_MEI_ERR_FAILURE;
*/
return DSL_DEV_MEI_ERR_SUCCESS;
};
/**
* Enable DFE to MIPS interrupt
* This function enable DFE to MIPS interrupt
*
* \param pDev the device pointer
* \param enable enable or disable
* \return DSL_DEV_MEI_ERR_SUCCESS or DSL_DEV_MEI_ERR_FAILURE
* \ingroup Internal
*/
static DSL_DEV_MeiError_t
IFX_MEI_AdslMailboxIRQEnable (DSL_DEV_Device_t *pDev, int enable)
{
DSL_DEV_MeiError_t meierr;
switch (enable) {
case 0:
meierr = DSL_DEV_MEI_ERR_SUCCESS;
IFX_MEI_IRQDisable (pDev);
break;
case 1:
IFX_MEI_IRQEnable (pDev);
meierr = DSL_DEV_MEI_ERR_SUCCESS;
break;
default:
meierr = DSL_DEV_MEI_ERR_FAILURE;
break;
}
return meierr;
}
/**
* Get the modem status
* This function return the modem status
*
* \param pDev the device pointer
* \return 1: modem ready 0: not ready
* \ingroup Internal
*/
static int
IFX_MEI_IsModemReady (DSL_DEV_Device_t * pDev)
{
return DSL_DEV_PRIVATE(pDev)->modem_ready;
}
DSL_DEV_MeiError_t
DSL_BSP_AdslLedInit (DSL_DEV_Device_t * dev,
DSL_DEV_LedId_t led_number,
DSL_DEV_LedType_t type,
DSL_DEV_LedHandler_t handler)
{
#if 0
struct led_config_param param;
if (led_number == DSL_LED_LINK_ID && type == DSL_LED_LINK_TYPE && handler == /*DSL_LED_HD_CPU*/DSL_LED_HD_FW) {
param.operation_mask = CONFIG_OPERATION_UPDATE_SOURCE;
param.led = 0x01;
param.source = 0x01;
// bsp_led_config (&param);
} else if (led_number == DSL_LED_DATA_ID && type == DSL_LED_DATA_TYPE && (handler == DSL_LED_HD_FW)) {
param.operation_mask = CONFIG_OPERATION_UPDATE_SOURCE;
param.led = 0x02;
param.source = 0x02;
// bsp_led_config (&param);
}
#endif
return DSL_DEV_MEI_ERR_SUCCESS;
};
#if 0
DSL_DEV_MeiError_t
DSL_BSP_AdslLedSet (DSL_DEV_Device_t * dev, DSL_DEV_LedId_t led_number, DSL_DEV_LedMode_t mode)
{
printk(KERN_INFO "[%s %d]: mode = %#x, led_number = %d\n", __func__, __LINE__, mode, led_number);
switch (mode) {
case DSL_LED_OFF:
switch (led_number) {
case DSL_LED_LINK_ID:
#ifdef CONFIG_BSP_LED
bsp_led_set_blink (1, 0);
bsp_led_set_data (1, 0);
#endif
break;
case DSL_LED_DATA_ID:
#ifdef CONFIG_BSP_LED
bsp_led_set_blink (0, 0);
bsp_led_set_data (0, 0);
#endif
break;
}
break;
case DSL_LED_FLASH:
switch (led_number) {
case DSL_LED_LINK_ID:
#ifdef CONFIG_BSP_LED
bsp_led_set_blink (1, 1); // data
#endif
break;
case DSL_LED_DATA_ID:
#ifdef CONFIG_BSP_LED
bsp_led_set_blink (0, 1); // data
#endif
break;
}
break;
case DSL_LED_ON:
switch (led_number) {
case DSL_LED_LINK_ID:
#ifdef CONFIG_BSP_LED
bsp_led_set_blink (1, 0);
bsp_led_set_data (1, 1);
#endif
break;
case DSL_LED_DATA_ID:
#ifdef CONFIG_BSP_LED
bsp_led_set_blink (0, 0);
bsp_led_set_data (0, 1);
#endif
break;
}
break;
}
return DSL_DEV_MEI_ERR_SUCCESS;
};
#endif
/**
* Compose a message.
* This function compose a message from opcode, group, address, index, size, and data
*
* \param opcode The message opcode
* \param group The message group number
* \param address The message address.
* \param index The message index.
* \param size The number of words to read/write.
* \param data The pointer to data.
* \param CMVMSG The pointer to message buffer.
* \ingroup Internal
*/
void
makeCMV (u8 opcode, u8 group, u16 address, u16 index, int size, u16 * data, u16 *CMVMSG)
{
memset (CMVMSG, 0, MSG_LENGTH * 2);
CMVMSG[0] = (opcode << 4) + (size & 0xf);
CMVMSG[1] = (((index == 0) ? 0 : 1) << 7) + (group & 0x7f);
CMVMSG[2] = address;
CMVMSG[3] = index;
if (opcode == H2D_CMV_WRITE)
memcpy (CMVMSG + 4, data, size * 2);
return;
}
/**
* Send a message to ARC and read the response
* This function sends a message to arc, waits the response, and reads the responses.
*
* \param pDev the device pointer
* \param request Pointer to the request
* \param reply Wait reply or not.
* \param response Pointer to the response
* \return DSL_DEV_MEI_ERR_SUCCESS or DSL_DEV_MEI_ERR_FAILURE
* \ingroup Internal
*/
DSL_DEV_MeiError_t
DSL_BSP_SendCMV (DSL_DEV_Device_t * pDev, u16 * request, int reply, u16 * response) // write cmv to arc, if reply needed, wait for reply
{
DSL_DEV_MeiError_t meierror;
#if defined(BSP_PORT_RTEMS)
int delay_counter = 0;
#endif
if (MEI_MUTEX_LOCK (DSL_DEV_PRIVATE(pDev)->mei_cmv_sema))
return -ERESTARTSYS;
DSL_DEV_PRIVATE(pDev)->cmv_reply = reply;
memset (DSL_DEV_PRIVATE(pDev)->CMV_RxMsg, 0,
sizeof (DSL_DEV_PRIVATE(pDev)->
CMV_RxMsg));
DSL_DEV_PRIVATE(pDev)->arcmsgav = 0;
meierror = IFX_MEI_MailboxWrite (pDev, request, MSG_LENGTH);
if (meierror != DSL_DEV_MEI_ERR_SUCCESS) {
DSL_DEV_PRIVATE(pDev)->cmv_waiting = 0;
DSL_DEV_PRIVATE(pDev)->arcmsgav = 0;
IFX_MEI_EMSG ("MailboxWrite Fail!\n");
IFX_MEI_EMSG ("Resetting ARC...\n");
IFX_MEI_ResetARC(pDev);
MEI_MUTEX_UNLOCK (DSL_DEV_PRIVATE(pDev)->mei_cmv_sema);
return meierror;
}
else {
DSL_DEV_PRIVATE(pDev)->cmv_count++;
}
if (DSL_DEV_PRIVATE(pDev)->cmv_reply ==
NO_REPLY) {
MEI_MUTEX_UNLOCK (DSL_DEV_PRIVATE(pDev)->mei_cmv_sema);
return DSL_DEV_MEI_ERR_SUCCESS;
}
#if !defined(BSP_PORT_RTEMS)
if (DSL_DEV_PRIVATE(pDev)->arcmsgav == 0)
MEI_WAIT_EVENT_TIMEOUT (DSL_DEV_PRIVATE(pDev)->wait_queue_arcmsgav, CMV_TIMEOUT);
#else
while (DSL_DEV_PRIVATE(pDev)->arcmsgav == 0 && delay_counter < CMV_TIMEOUT / 5) {
MEI_WAIT (5);
delay_counter++;
}
#endif
DSL_DEV_PRIVATE(pDev)->cmv_waiting = 0;
if (DSL_DEV_PRIVATE(pDev)->arcmsgav == 0) { //CMV_timeout
DSL_DEV_PRIVATE(pDev)->arcmsgav = 0;
IFX_MEI_EMSG ("\%s: DSL_DEV_MEI_ERR_MAILBOX_TIMEOUT\n",
__FUNCTION__);
MEI_MUTEX_UNLOCK (DSL_DEV_PRIVATE(pDev)->mei_cmv_sema);
return DSL_DEV_MEI_ERR_MAILBOX_TIMEOUT;
}
else {
DSL_DEV_PRIVATE(pDev)->arcmsgav = 0;
DSL_DEV_PRIVATE(pDev)->
reply_count++;
memcpy (response, DSL_DEV_PRIVATE(pDev)->CMV_RxMsg, MSG_LENGTH * 2);
MEI_MUTEX_UNLOCK (DSL_DEV_PRIVATE(pDev)->mei_cmv_sema);
return DSL_DEV_MEI_ERR_SUCCESS;
}
MEI_MUTEX_UNLOCK (DSL_DEV_PRIVATE(pDev)->mei_cmv_sema);
return DSL_DEV_MEI_ERR_SUCCESS;
}
/**
* Reset the ARC, download boot codes, and run the ARC.
* This function resets the ARC, downloads boot codes to ARC, and runs the ARC.
*
* \param pDev the device pointer
* \return DSL_DEV_MEI_ERR_SUCCESS or DSL_DEV_MEI_ERR_FAILURE
* \ingroup Internal
*/
static DSL_DEV_MeiError_t
IFX_MEI_RunAdslModem (DSL_DEV_Device_t *pDev)
{
int nSize = 0, idx = 0;
uint32_t im0_register, im2_register;
// DSL_DEV_WinHost_Message_t m;
if (mei_arc_swap_buff == NULL) {
mei_arc_swap_buff =
(u32 *) kmalloc (MAXSWAPSIZE * 4, GFP_KERNEL);
if (mei_arc_swap_buff == NULL) {
IFX_MEI_EMSG (">>> malloc fail for codeswap buff!!! <<<\n");
return DSL_DEV_MEI_ERR_FAILURE;
}
IFX_MEI_DMSG("allocate %dKB swap buff memory at: 0x%p\n", ksize(mei_arc_swap_buff)/1024, mei_arc_swap_buff);
}
DSL_DEV_PRIVATE(pDev)->img_hdr =
(ARC_IMG_HDR *) DSL_DEV_PRIVATE(pDev)->adsl_mem_info[0].address;
if ((DSL_DEV_PRIVATE(pDev)->img_hdr->
count) * sizeof (ARC_SWP_PAGE_HDR) > SDRAM_SEGMENT_SIZE) {
IFX_MEI_EMSG ("firmware header size is bigger than 64K segment size\n");
return DSL_DEV_MEI_ERR_FAILURE;
}
// check image size
for (idx = 0; idx < MAX_BAR_REGISTERS; idx++) {
nSize += DSL_DEV_PRIVATE(pDev)->adsl_mem_info[idx].nCopy;
}
if (nSize !=
DSL_DEV_PRIVATE(pDev)->image_size) {
IFX_MEI_EMSG ("Firmware download is not completed. Please download firmware again!\n");
return DSL_DEV_MEI_ERR_FAILURE;
}
// TODO: check crc
///
IFX_MEI_ResetARC (pDev);
IFX_MEI_HaltArc (pDev);
IFX_MEI_BarUpdate (pDev, DSL_DEV_PRIVATE(pDev)->nBar);
//IFX_MEI_DMSG("Starting to meiDownloadBootCode\n");
IFX_MEI_DownloadBootCode (pDev);
im0_register = (*LTQ_ICU_IM0_IER) & (1 << 20);
im2_register = (*LTQ_ICU_IM2_IER) & (1 << 20);
/* Turn off irq */
#ifdef CONFIG_SOC_AMAZON_SE
#define IFXMIPS_USB_OC_INT0 (INT_NUM_IM4_IRL0 + 23)
disable_irq (IFXMIPS_USB_OC_INT0);
// disable_irq (IFXMIPS_USB_OC_INT2);
#elif defined(CONFIG_SOC_AR9)
#define IFXMIPS_USB_OC_INT0 (INT_NUM_IM4_IRL1 + 28)
disable_irq (IFXMIPS_USB_OC_INT0);
// disable_irq (IFXMIPS_USB_OC_INT2);
#elif defined(CONFIG_SOC_XWAY)
disable_irq (LTQ_USB_OC_INT);
#else
#error unkonwn arch
#endif
disable_irq (pDev->nIrq[IFX_DYING_GASP]);
IFX_MEI_RunArc (pDev);
MEI_WAIT_EVENT_TIMEOUT (DSL_DEV_PRIVATE(pDev)->wait_queue_modemready, 1000);
#ifdef CONFIG_SOC_AMAZON_SE
MEI_MASK_AND_ACK_IRQ (IFXMIPS_USB_OC_INT0);
// MEI_MASK_AND_ACK_IRQ (IFXMIPS_USB_OC_INT2);
#elif defined(CONFIG_SOC_AR9)
MEI_MASK_AND_ACK_IRQ (IFXMIPS_USB_OC_INT0);
// MEI_MASK_AND_ACK_IRQ (IFXMIPS_USB_OC_INT2);
#elif defined(CONFIG_SOC_XWAY)
MEI_MASK_AND_ACK_IRQ (LTQ_USB_OC_INT);
#else
#error unkonwn arch
#endif
MEI_MASK_AND_ACK_IRQ (pDev->nIrq[IFX_DYING_GASP]);
/* Re-enable irq */
enable_irq(pDev->nIrq[IFX_DYING_GASP]);
*LTQ_ICU_IM0_IER |= im0_register;
*LTQ_ICU_IM2_IER |= im2_register;
if (DSL_DEV_PRIVATE(pDev)->modem_ready != 1) {
IFX_MEI_EMSG ("Modem failed to be ready!\n");
return DSL_DEV_MEI_ERR_FAILURE;
} else {
IFX_MEI_DMSG("Modem is ready.\n");
return DSL_DEV_MEI_ERR_SUCCESS;
}
}
/**
* Get the page's data pointer
* This function caculats the data address from the firmware header.
*
* \param pDev the device pointer
* \param Page The page number.
* \param data Data page or program page.
* \param MaxSize The maximum size to read.
* \param Buffer Pointer to data.
* \param Dest Pointer to the destination address.
* \return The number of bytes to read.
* \ingroup Internal
*/
static int
IFX_MEI_GetPage (DSL_DEV_Device_t * pDev, u32 Page, u32 data,
u32 MaxSize, u32 * Buffer, u32 * Dest)
{
u32 size;
u32 i;
u32 *p;
u32 idx, offset, nBar = 0;
if (Page > DSL_DEV_PRIVATE(pDev)->img_hdr->count)
return -2;
/*
** Get program or data size, depending on "data" flag
*/
size = (data == GET_DATA) ? (DSL_DEV_PRIVATE(pDev)->img_hdr->page[Page].d_size) :
(DSL_DEV_PRIVATE(pDev)->img_hdr->page[Page].p_size);
size &= BOOT_FLAG_MASK; // Clear boot bit!
if (size > MaxSize)
return -1;
if (size == 0)
return 0;
/*
** Get program or data offset, depending on "data" flag
*/
i = data ? (DSL_DEV_PRIVATE(pDev)->img_hdr->page[Page].d_offset) :
(DSL_DEV_PRIVATE(pDev)->img_hdr->page[Page].p_offset);
/*
** Copy data/program to buffer
*/
idx = i / SDRAM_SEGMENT_SIZE;
offset = i % SDRAM_SEGMENT_SIZE;
p = (u32 *) ((u8 *) DSL_DEV_PRIVATE(pDev)->adsl_mem_info[idx].address + offset);
for (i = 0; i < size; i++) {
if (offset + i * 4 - (nBar * SDRAM_SEGMENT_SIZE) >= SDRAM_SEGMENT_SIZE) {
idx++;
nBar++;
p = (u32 *) ((u8 *) KSEG1ADDR ((u32)DSL_DEV_PRIVATE(pDev)->adsl_mem_info[idx].address));
}
Buffer[i] = *p++;
}
/*
** Pass back data/program destination address
*/
*Dest = data ? (DSL_DEV_PRIVATE(pDev)-> img_hdr->page[Page].d_dest) :
(DSL_DEV_PRIVATE(pDev)->img_hdr->page[Page].p_dest);
return size;
}
/**
* Free the memory for ARC firmware
*
* \param pDev the device pointer
* \param type Free all memory or free the unused memory after showtime
* \ingroup Internal
*/
const char *free_str[4] = {"Invalid", "Free_Reload", "Free_Showtime", "Free_All"};
static int
IFX_MEI_DFEMemoryFree (DSL_DEV_Device_t * pDev, int type)
{
int idx = 0;
smmu_mem_info_t *adsl_mem_info =
DSL_DEV_PRIVATE(pDev)->adsl_mem_info;
for (idx = 0; idx < MAX_BAR_REGISTERS; idx++) {
if (type == FREE_ALL ||adsl_mem_info[idx].type == type) {
if (adsl_mem_info[idx].size > 0) {
IFX_MEI_DMSG ("Freeing memory %p (%s)\n", adsl_mem_info[idx].org_address, free_str[adsl_mem_info[idx].type]);
if ( idx == XDATA_REGISTER ) {
g_xdata_addr = NULL;
if ( ifx_mei_atm_showtime_exit )
ifx_mei_atm_showtime_exit();
}
kfree (adsl_mem_info[idx].org_address);
adsl_mem_info[idx].org_address = 0;
adsl_mem_info[idx].address = 0;
adsl_mem_info[idx].size = 0;
adsl_mem_info[idx].type = 0;
adsl_mem_info[idx].nCopy = 0;
}
}
}
if(mei_arc_swap_buff != NULL){
IFX_MEI_DMSG("free %dKB swap buff memory at: 0x%p\n", ksize(mei_arc_swap_buff)/1024, mei_arc_swap_buff);
kfree(mei_arc_swap_buff);
mei_arc_swap_buff=NULL;
}
return 0;
}
static int
IFX_MEI_DFEMemoryAlloc (DSL_DEV_Device_t * pDev, long size)
{
unsigned long mem_ptr;
char *org_mem_ptr = NULL;
int idx = 0;
long total_size = 0;
int err = 0;
smmu_mem_info_t *adsl_mem_info =
((ifx_mei_device_private_t *) pDev->pPriv)->adsl_mem_info;
// DSL_DEV_PRIVATE(pDev)->adsl_mem_info;
int allocate_size = SDRAM_SEGMENT_SIZE;
IFX_MEI_DMSG("image_size = %ld\n", size);
// Alloc Swap Pages
for (idx = 0; size > 0 && idx < MAX_BAR_REGISTERS; idx++) {
// skip bar15 for XDATA usage.
if (idx == XDATA_REGISTER)
continue;
#if 0
if (size < SDRAM_SEGMENT_SIZE) {
allocate_size = size;
if (allocate_size < 1024)
allocate_size = 1024;
}
#endif
if (idx == (MAX_BAR_REGISTERS - 1))
allocate_size = size;
else
allocate_size = SDRAM_SEGMENT_SIZE;
org_mem_ptr = kmalloc (allocate_size + 1024, GFP_KERNEL);
if (org_mem_ptr == NULL) {
IFX_MEI_EMSG ("%d: kmalloc %d bytes memory fail!\n", idx, allocate_size);
err = -ENOMEM;
goto allocate_error;
}
mem_ptr = (unsigned long) (org_mem_ptr + 1023) & ~(1024 -1);
adsl_mem_info[idx].address = (char *) mem_ptr;
adsl_mem_info[idx].org_address = org_mem_ptr;
adsl_mem_info[idx].size = allocate_size;
size -= allocate_size;
total_size += allocate_size;
}
if (size > 0) {
IFX_MEI_EMSG ("Image size is too large!\n");
err = -EFBIG;
goto allocate_error;
}
err = idx;
return err;
allocate_error:
IFX_MEI_DFEMemoryFree (pDev, FREE_ALL);
return err;
}
/**
* Program the BAR registers
*
* \param pDev the device pointer
* \param nTotalBar The number of bar to program.
* \ingroup Internal
*/
static int
IFX_MEI_BarUpdate (DSL_DEV_Device_t * pDev, int nTotalBar)
{
int idx = 0;
smmu_mem_info_t *adsl_mem_info =
DSL_DEV_PRIVATE(pDev)->adsl_mem_info;
for (idx = 0; idx < nTotalBar; idx++) {
//skip XDATA register
if (idx == XDATA_REGISTER)
continue;
IFX_MEI_LongWordWriteOffset (pDev, (u32) ME_XMEM_BAR_BASE + idx * 4,
(((uint32_t) adsl_mem_info[idx].address) & 0x0FFFFFFF));
}
for (idx = nTotalBar; idx < MAX_BAR_REGISTERS; idx++) {
if (idx == XDATA_REGISTER)
continue;
IFX_MEI_LongWordWriteOffset (pDev, (u32) ME_XMEM_BAR_BASE + idx * 4,
(((uint32_t)adsl_mem_info[nTotalBar - 1].address) & 0x0FFFFFFF));
/* These are for /proc/danube_mei/meminfo purpose */
adsl_mem_info[idx].address = adsl_mem_info[nTotalBar - 1].address;
adsl_mem_info[idx].org_address = adsl_mem_info[nTotalBar - 1].org_address;
adsl_mem_info[idx].size = 0; /* Prevent it from being freed */
}
g_xdata_addr = adsl_mem_info[XDATA_REGISTER].address;
IFX_MEI_LongWordWriteOffset (pDev, (u32) ME_XMEM_BAR_BASE + XDATA_REGISTER * 4,
(((uint32_t) adsl_mem_info [XDATA_REGISTER].address) & 0x0FFFFFFF));
// update MEI_XDATA_BASE_SH
IFX_MEI_LongWordWriteOffset (pDev, (u32) ME_XDATA_BASE_SH,
((unsigned long)adsl_mem_info[XDATA_REGISTER].address) & 0x0FFFFFFF);
return DSL_DEV_MEI_ERR_SUCCESS;
}
/* This copies the firmware from secondary storage to 64k memory segment in SDRAM */
DSL_DEV_MeiError_t
DSL_BSP_FWDownload (DSL_DEV_Device_t * pDev, const char *buf,
unsigned long size, long *loff, long *current_offset)
{
ARC_IMG_HDR img_hdr_tmp;
smmu_mem_info_t *adsl_mem_info = DSL_DEV_PRIVATE(pDev)->adsl_mem_info;
size_t nRead = 0, nCopy = 0;
char *mem_ptr;
ssize_t retval = -ENOMEM;
int idx = 0;
IFX_MEI_DMSG("\n");
if (*loff == 0) {
if (size < sizeof (img_hdr_tmp)) {
IFX_MEI_EMSG ("Firmware size is too small!\n");
return retval;
}
copy_from_user ((char *) &img_hdr_tmp, buf, sizeof (img_hdr_tmp));
// header of image_size and crc are not included.
DSL_DEV_PRIVATE(pDev)->image_size = le32_to_cpu (img_hdr_tmp.size) + 8;
if (DSL_DEV_PRIVATE(pDev)->image_size > 1024 * 1024) {
IFX_MEI_EMSG ("Firmware size is too large!\n");
return retval;
}
// check if arc is halt
IFX_MEI_ResetARC (pDev);
IFX_MEI_HaltArc (pDev);
IFX_MEI_DFEMemoryFree (pDev, FREE_ALL); //free all
retval = IFX_MEI_DFEMemoryAlloc (pDev, DSL_DEV_PRIVATE(pDev)->image_size);
if (retval < 0) {
IFX_MEI_EMSG ("Error: No memory space left.\n");
goto error;
}
for (idx = 0; idx < retval; idx++) {
//skip XDATA register
if (idx == XDATA_REGISTER)
continue;
if (idx * SDRAM_SEGMENT_SIZE < le32_to_cpu (img_hdr_tmp.page[0].p_offset))
adsl_mem_info[idx].type = FREE_RELOAD;
else
adsl_mem_info[idx].type = FREE_SHOWTIME;
}
DSL_DEV_PRIVATE(pDev)->nBar = retval;
DSL_DEV_PRIVATE(pDev)->img_hdr =
(ARC_IMG_HDR *) adsl_mem_info[0].address;
adsl_mem_info[XDATA_REGISTER].org_address = kmalloc (SDRAM_SEGMENT_SIZE + 1024, GFP_KERNEL);
adsl_mem_info[XDATA_REGISTER].address =
(char *) ((unsigned long) (adsl_mem_info[XDATA_REGISTER].org_address + 1023) & 0xFFFFFC00);
adsl_mem_info[XDATA_REGISTER].size = SDRAM_SEGMENT_SIZE;
if (adsl_mem_info[XDATA_REGISTER].address == NULL) {
IFX_MEI_EMSG ("kmalloc memory fail!\n");
retval = -ENOMEM;
goto error;
}
adsl_mem_info[XDATA_REGISTER].type = FREE_RELOAD;
IFX_MEI_DMSG("-> IFX_MEI_BarUpdate()\n");
IFX_MEI_BarUpdate (pDev, (DSL_DEV_PRIVATE(pDev)->nBar));
}
else if (DSL_DEV_PRIVATE(pDev)-> image_size == 0) {
IFX_MEI_EMSG ("Error: Firmware size=0! \n");
goto error;
}
nRead = 0;
while (nRead < size) {
long offset = ((long) (*loff) + nRead) % SDRAM_SEGMENT_SIZE;
idx = (((long) (*loff)) + nRead) / SDRAM_SEGMENT_SIZE;
mem_ptr = (char *) KSEG1ADDR ((unsigned long) (adsl_mem_info[idx].address) + offset);
if ((size - nRead + offset) > SDRAM_SEGMENT_SIZE)
nCopy = SDRAM_SEGMENT_SIZE - offset;
else
nCopy = size - nRead;
copy_from_user (mem_ptr, buf + nRead, nCopy);
for (offset = 0; offset < (nCopy / 4); offset++) {
((unsigned long *) mem_ptr)[offset] = le32_to_cpu (((unsigned long *) mem_ptr)[offset]);
}
nRead += nCopy;
adsl_mem_info[idx].nCopy += nCopy;
}
*loff += size;
*current_offset = size;
return DSL_DEV_MEI_ERR_SUCCESS;
error:
IFX_MEI_DFEMemoryFree (pDev, FREE_ALL);
return DSL_DEV_MEI_ERR_FAILURE;
}
/*
* Register a callback event.
* Return:
* -1 if the event already has a callback function registered.
* 0 success
*/
int DSL_BSP_EventCBRegister(DSL_BSP_EventCallBack_t *p)
{
if (!p) {
IFX_MEI_EMSG("Invalid parameter!\n");
return -EINVAL;
}
if (p->event > DSL_BSP_CB_LAST || p->event < DSL_BSP_CB_FIRST) {
IFX_MEI_EMSG("Invalid Event %d\n", p->event);
return -EINVAL;
}
if (dsl_bsp_event_callback[p->event].function) {
IFX_MEI_EMSG("Event %d already has a callback function registered!\n", p->event);
return -1;
} else {
dsl_bsp_event_callback[p->event].function = p->function;
dsl_bsp_event_callback[p->event].event = p->event;
dsl_bsp_event_callback[p->event].pData = p->pData;
}
return 0;
}
int DSL_BSP_EventCBUnregister(DSL_BSP_EventCallBack_t *p)
{
if (!p) {
IFX_MEI_EMSG("Invalid parameter!\n");
return -EINVAL;
}
if (p->event > DSL_BSP_CB_LAST || p->event < DSL_BSP_CB_FIRST) {
IFX_MEI_EMSG("Invalid Event %d\n", p->event);
return -EINVAL;
}
if (dsl_bsp_event_callback[p->event].function) {
IFX_MEI_EMSG("Unregistering Event %d...\n", p->event);
dsl_bsp_event_callback[p->event].function = NULL;
dsl_bsp_event_callback[p->event].pData = NULL;
} else {
IFX_MEI_EMSG("Event %d is not registered!\n", p->event);
return -1;
}
return 0;
}
/**
* MEI Dying Gasp interrupt handler
*
* \param int1
* \param void0
* \param regs Pointer to the structure of danube mips registers
* \ingroup Internal
*/
static irqreturn_t IFX_MEI_Dying_Gasp_IrqHandle (int int1, void *void0)
{
DSL_DEV_Device_t *pDev = (DSL_DEV_Device_t *) void0;
DSL_BSP_CB_Type_t event;
if (pDev == NULL)
IFX_MEI_EMSG("Error: Got Interrupt but pDev is NULL!!!!\n");
#ifndef CONFIG_SMP
disable_irq (pDev->nIrq[IFX_DYING_GASP]);
#else
disable_irq_nosync(pDev->nIrq[IFX_DYING_GASP]);
#endif
event = DSL_BSP_CB_DYING_GASP;
if (dsl_bsp_event_callback[event].function)
(*dsl_bsp_event_callback[event].function)(pDev, event, dsl_bsp_event_callback[event].pData);
#ifdef CONFIG_USE_EMULATOR
IFX_MEI_EMSG("Dying Gasp! Shutting Down... (Work around for Amazon-S Venus emulator)\n");
#else
IFX_MEI_EMSG("Dying Gasp! Shutting Down...\n");
// kill_proc (1, SIGINT, 1); /* Ask init to reboot us */
#endif
return IRQ_HANDLED;
}
extern void ifx_usb_enable_afe_oc(void);
/**
* MEI interrupt handler
*
* \param int1
* \param void0
* \param regs Pointer to the structure of danube mips registers
* \ingroup Internal
*/
static irqreturn_t IFX_MEI_IrqHandle (int int1, void *void0)
{
u32 scratch;
DSL_DEV_Device_t *pDev = (DSL_DEV_Device_t *) void0;
#if defined(CONFIG_LTQ_MEI_FW_LOOPBACK) && defined(DFE_PING_TEST)
dfe_loopback_irq_handler (pDev);
return IRQ_HANDLED;
#endif //CONFIG_AMAZON_S_MEI_FW_LOOPBACK
DSL_BSP_CB_Type_t event;
if (pDev == NULL)
IFX_MEI_EMSG("Error: Got Interrupt but pDev is NULL!!!!\n");
IFX_MEI_DebugRead (pDev, ARC_MEI_MAILBOXR, &scratch, 1);
if (scratch & OMB_CODESWAP_MESSAGE_MSG_TYPE_MASK) {
IFX_MEI_EMSG("Receive Code Swap Request interrupt!!!\n");
return IRQ_HANDLED;
}
else if (scratch & OMB_CLEAREOC_INTERRUPT_CODE) {
// clear eoc message interrupt
IFX_MEI_DMSG("OMB_CLEAREOC_INTERRUPT_CODE\n");
event = DSL_BSP_CB_CEOC_IRQ;
IFX_MEI_LongWordWriteOffset (pDev, (u32) ME_ARC2ME_STAT, ARC_TO_MEI_MSGAV);
if (dsl_bsp_event_callback[event].function)
(*dsl_bsp_event_callback[event].function)(pDev, event, dsl_bsp_event_callback[event].pData);
} else if (scratch & OMB_REBOOT_INTERRUPT_CODE) {
// Reboot
IFX_MEI_DMSG("OMB_REBOOT_INTERRUPT_CODE\n");
event = DSL_BSP_CB_FIRMWARE_REBOOT;
IFX_MEI_LongWordWriteOffset (pDev, (u32) ME_ARC2ME_STAT, ARC_TO_MEI_MSGAV);
if (dsl_bsp_event_callback[event].function)
(*dsl_bsp_event_callback[event].function)(pDev, event, dsl_bsp_event_callback[event].pData);
} else { // normal message
IFX_MEI_MailboxRead (pDev, DSL_DEV_PRIVATE(pDev)->CMV_RxMsg, MSG_LENGTH);
if (DSL_DEV_PRIVATE(pDev)-> cmv_waiting == 1) {
DSL_DEV_PRIVATE(pDev)-> arcmsgav = 1;
DSL_DEV_PRIVATE(pDev)-> cmv_waiting = 0;
#if !defined(BSP_PORT_RTEMS)
MEI_WAKEUP_EVENT (DSL_DEV_PRIVATE(pDev)->wait_queue_arcmsgav);
#endif
}
else {
DSL_DEV_PRIVATE(pDev)-> modem_ready_cnt++;
memcpy ((char *) DSL_DEV_PRIVATE(pDev)->Recent_indicator,
(char *) DSL_DEV_PRIVATE(pDev)->CMV_RxMsg, MSG_LENGTH * 2);
if (((DSL_DEV_PRIVATE(pDev)->CMV_RxMsg[0] & 0xff0) >> 4) == D2H_AUTONOMOUS_MODEM_READY_MSG) {
//check ARC ready message
IFX_MEI_DMSG ("Got MODEM_READY_MSG\n");
DSL_DEV_PRIVATE(pDev)->modem_ready = 1;
MEI_WAKEUP_EVENT (DSL_DEV_PRIVATE(pDev)->wait_queue_modemready);
}
}
}
return IRQ_HANDLED;
}
int
DSL_BSP_ATMLedCBRegister (int (*ifx_adsl_ledcallback) (void))
{
g_adsl_ledcallback = ifx_adsl_ledcallback;
return 0;
}
int
DSL_BSP_ATMLedCBUnregister (int (*ifx_adsl_ledcallback) (void))
{
g_adsl_ledcallback = adsl_dummy_ledcallback;
return 0;
}
#if 0
int
DSL_BSP_EventCBRegister (int (*ifx_adsl_callback)
(DSL_BSP_CB_Event_t * param))
{
int error = 0;
if (DSL_EventCB == NULL) {
DSL_EventCB = ifx_adsl_callback;
}
else {
error = -EIO;
}
return error;
}
int
DSL_BSP_EventCBUnregister (int (*ifx_adsl_callback)
(DSL_BSP_CB_Event_t * param))
{
int error = 0;
if (DSL_EventCB == ifx_adsl_callback) {
DSL_EventCB = NULL;
}
else {
error = -EIO;
}
return error;
}
static int
DSL_BSP_GetEventCB (int (**ifx_adsl_callback)
(DSL_BSP_CB_Event_t * param))
{
*ifx_adsl_callback = DSL_EventCB;
return 0;
}
#endif
#ifdef CONFIG_LTQ_MEI_FW_LOOPBACK
#define mte_reg_base (0x4800*4+0x20000)
/* Iridia Registers Address Constants */
#define MTE_Reg(r) (int)(mte_reg_base + (r*4))
#define IT_AMODE MTE_Reg(0x0004)
#define TIMER_DELAY (1024)
#define BC0_BYTES (32)
#define BC1_BYTES (30)
#define NUM_MB (12)
#define TIMEOUT_VALUE 2000
static void
BFMWait (u32 cycle)
{
u32 i;
for (i = 0; i < cycle; i++);
}
static void
WriteRegLong (u32 addr, u32 data)
{
//*((volatile u32 *)(addr)) = data;
IFX_MEI_WRITE_REGISTER_L (data, addr);
}
static u32
ReadRegLong (u32 addr)
{
// u32 rd_val;
//rd_val = *((volatile u32 *)(addr));
// return rd_val;
return IFX_MEI_READ_REGISTER_L (addr);
}
/* This routine writes the mailbox with the data in an input array */
static void
WriteMbox (u32 * mboxarray, u32 size)
{
IFX_MEI_DebugWrite (&dsl_devices[0], IMBOX_BASE, mboxarray, size);
IFX_MEI_DMSG("write to %X\n", IMBOX_BASE);
IFX_MEI_LongWordWriteOffset (&dsl_devices[0], (u32) ME_ME2ARC_INT, MEI_TO_ARC_MSGAV);
}
/* This routine reads the output mailbox and places the results into an array */
static void
ReadMbox (u32 * mboxarray, u32 size)
{
IFX_MEI_DebugRead (&dsl_devices[0], OMBOX_BASE, mboxarray, size);
IFX_MEI_DMSG("read from %X\n", OMBOX_BASE);
}
static void
MEIWriteARCValue (u32 address, u32 value)
{
u32 i, check = 0;
/* Write address register */
IFX_MEI_WRITE_REGISTER_L (address, ME_DBG_WR_AD + LTQ_MEI_BASE_ADDR);
/* Write data register */
IFX_MEI_WRITE_REGISTER_L (value, ME_DBG_DATA + LTQ_MEI_BASE_ADDR);
/* wait until complete - timeout at 40 */
for (i = 0; i < 40; i++) {
check = IFX_MEI_READ_REGISTER_L (ME_ARC2ME_STAT + LTQ_MEI_BASE_ADDR);
if ((check & ARC_TO_MEI_DBG_DONE))
break;
}
/* clear the flag */
IFX_MEI_WRITE_REGISTER_L (ARC_TO_MEI_DBG_DONE, ME_ARC2ME_STAT + LTQ_MEI_BASE_ADDR);
}
void
arc_code_page_download (uint32_t arc_code_length, uint32_t * start_address)
{
int count;
IFX_MEI_DMSG("try to download pages,size=%d\n", arc_code_length);
IFX_MEI_ControlModeSet (&dsl_devices[0], MEI_MASTER_MODE);
IFX_MEI_HaltArc (&dsl_devices[0]);
IFX_MEI_LongWordWriteOffset (&dsl_devices[0], (u32) ME_DX_AD, 0);
for (count = 0; count < arc_code_length; count++) {
IFX_MEI_LongWordWriteOffset (&dsl_devices[0], (u32) ME_DX_DATA,
*(start_address + count));
}
IFX_MEI_ControlModeSet (&dsl_devices[0], JTAG_MASTER_MODE);
}
static int
load_jump_table (unsigned long addr)
{
int i;
uint32_t addr_le, addr_be;
uint32_t jump_table[32];
for (i = 0; i < 16; i++) {
addr_le = i * 8 + addr;
addr_be = ((addr_le >> 16) & 0xffff);
addr_be |= ((addr_le & 0xffff) << 16);
jump_table[i * 2 + 0] = 0x0f802020;
jump_table[i * 2 + 1] = addr_be;
//printk("jt %X %08X %08X\n",i,jump_table[i*2+0],jump_table[i*2+1]);
}
arc_code_page_download (32, &jump_table[0]);
return 0;
}
int got_int = 0;
void
dfe_loopback_irq_handler (DSL_DEV_Device_t *pDev)
{
uint32_t rd_mbox[10];
memset (&rd_mbox[0], 0, 10 * 4);
ReadMbox (&rd_mbox[0], 6);
if (rd_mbox[0] == 0x0) {
FX_MEI_DMSG("Get ARC_ACK\n");
got_int = 1;
}
else if (rd_mbox[0] == 0x5) {
IFX_MEI_DMSG("Get ARC_BUSY\n");
got_int = 2;
}
else if (rd_mbox[0] == 0x3) {
IFX_MEI_DMSG("Get ARC_EDONE\n");
if (rd_mbox[1] == 0x0) {
got_int = 3;
IFX_MEI_DMSG("Get E_MEMTEST\n");
if (rd_mbox[2] != 0x1) {
got_int = 4;
IFX_MEI_DMSG("Get Result %X\n", rd_mbox[2]);
}
}
}
IFX_MEI_LongWordWriteOffset (&dsl_devices[0], (u32) ME_ARC2ME_STAT,
ARC_TO_MEI_DBG_DONE);
MEI_MASK_AND_ACK_IRQ (pDev->nIrq[IFX_DFEIR]);
disable_irq (pDev->nIrq[IFX_DFEIR]);
//got_int = 1;
return;
}
static void
wait_mem_test_result (void)
{
uint32_t mbox[5];
mbox[0] = 0;
IFX_MEI_DMSG("Waiting Starting\n");
while (mbox[0] == 0) {
ReadMbox (&mbox[0], 5);
}
IFX_MEI_DMSG("Try to get mem test result.\n");
ReadMbox (&mbox[0], 5);
if (mbox[0] == 0xA) {
IFX_MEI_DMSG("Success.\n");
}
else if (mbox[0] == 0xA) {
IFX_MEI_EMSG("Fail,address %X,except data %X,receive data %X\n",
mbox[1], mbox[2], mbox[3]);
}
else {
IFX_MEI_EMSG("Fail\n");
}
}
static int
arc_ping_testing (DSL_DEV_Device_t *pDev)
{
#define MEI_PING 0x00000001
uint32_t wr_mbox[10], rd_mbox[10];
int i;
for (i = 0; i < 10; i++) {
wr_mbox[i] = 0;
rd_mbox[i] = 0;
}
FX_MEI_DMSG("send ping msg\n");
wr_mbox[0] = MEI_PING;
WriteMbox (&wr_mbox[0], 10);
while (got_int == 0) {
MEI_WAIT (100);
}
IFX_MEI_DMSG("send start event\n");
got_int = 0;
wr_mbox[0] = 0x4;
wr_mbox[1] = 0;
wr_mbox[2] = 0;
wr_mbox[3] = (uint32_t) 0xf5acc307e;
wr_mbox[4] = 5;
wr_mbox[5] = 2;
wr_mbox[6] = 0x1c000;
wr_mbox[7] = 64;
wr_mbox[8] = 0;
wr_mbox[9] = 0;
WriteMbox (&wr_mbox[0], 10);
DSL_ENABLE_IRQ (pDev->nIrq[IFX_DFEIR]);
//printk("IFX_MEI_MailboxWrite ret=%d\n",i);
IFX_MEI_LongWordWriteOffset (&dsl_devices[0],
(u32) ME_ME2ARC_INT,
MEI_TO_ARC_MSGAV);
IFX_MEI_DMSG("sleeping\n");
while (1) {
if (got_int > 0) {
if (got_int > 3)
IFX_MEI_DMSG("got_int >>>> 3\n");
else
IFX_MEI_DMSG("got int = %d\n", got_int);
got_int = 0;
//schedule();
DSL_ENABLE_IRQ (pDev->nIrq[IFX_DFEIR]);
}
//mbox_read(&rd_mbox[0],6);
MEI_WAIT (100);
}
return 0;
}
static DSL_DEV_MeiError_t
DFE_Loopback_Test (void)
{
int i = 0;
u32 arc_debug_data = 0, temp;
DSL_DEV_Device_t *pDev = &dsl_devices[0];
uint32_t wr_mbox[10];
IFX_MEI_ResetARC (pDev);
// start the clock
arc_debug_data = ACL_CLK_MODE_ENABLE;
IFX_MEI_DebugWrite (pDev, CRI_CCR0, &arc_debug_data, 1);
#if defined( DFE_PING_TEST )|| defined( DFE_ATM_LOOPBACK)
// WriteARCreg(AUX_XMEM_LTEST,0);
IFX_MEI_ControlModeSet (pDev, MEI_MASTER_MODE);
#define AUX_XMEM_LTEST 0x128
_IFX_MEI_DBGLongWordWrite (pDev, MEI_DEBUG_DEC_AUX_MASK, AUX_XMEM_LTEST, 0);
IFX_MEI_ControlModeSet (pDev, JTAG_MASTER_MODE);
// WriteARCreg(AUX_XDMA_GAP,0);
IFX_MEI_ControlModeSet (pDev, MEI_MASTER_MODE);
#define AUX_XDMA_GAP 0x114
_IFX_MEI_DBGLongWordWrite (pDev, MEI_DEBUG_DEC_AUX_MASK, AUX_XDMA_GAP, 0);
IFX_MEI_ControlModeSet (pDev, JTAG_MASTER_MODE);
IFX_MEI_ControlModeSet (pDev, MEI_MASTER_MODE);
temp = 0;
_IFX_MEI_DBGLongWordWrite (pDev, MEI_DEBUG_DEC_AUX_MASK,
(u32) ME_XDATA_BASE_SH + LTQ_MEI_BASE_ADDR, temp);
IFX_MEI_ControlModeSet (pDev, JTAG_MASTER_MODE);
i = IFX_MEI_DFEMemoryAlloc (pDev, SDRAM_SEGMENT_SIZE * 16);
if (i >= 0) {
int idx;
for (idx = 0; idx < i; idx++) {
DSL_DEV_PRIVATE(pDev)->adsl_mem_info[idx].type = FREE_RELOAD;
IFX_MEI_WRITE_REGISTER_L ((((uint32_t) DSL_DEV_PRIVATE(pDev)->adsl_mem_info[idx].address) & 0x0fffffff),
LTQ_MEI_BASE_ADDR + ME_XMEM_BAR_BASE + idx * 4);
IFX_MEI_DMSG("bar%d(%X)=%X\n", idx,
LTQ_MEI_BASE_ADDR + ME_XMEM_BAR_BASE +
idx * 4, (((uint32_t)
((ifx_mei_device_private_t *)
pDev->pPriv)->adsl_mem_info[idx].
address) & 0x0fffffff));
memset ((u8 *) DSL_DEV_PRIVATE(pDev)->adsl_mem_info[idx].address, 0, SDRAM_SEGMENT_SIZE);
}
IFX_MEI_LongWordWriteOffset (pDev, (u32) ME_XDATA_BASE_SH,
((unsigned long) DSL_DEV_PRIVATE(pDev)->adsl_mem_info[XDATA_REGISTER].address) & 0x0FFFFFFF);
}
else {
IFX_MEI_EMSG ("cannot load image: no memory\n");
return DSL_DEV_MEI_ERR_FAILURE;
}
//WriteARCreg(AUX_IC_CTRL,2);
IFX_MEI_DMSG("Setting MEI_MASTER_MODE..\n");
IFX_MEI_ControlModeSet (pDev, MEI_MASTER_MODE);
#define AUX_IC_CTRL 0x11
_IFX_MEI_DBGLongWordWrite (pDev, MEI_DEBUG_DEC_AUX_MASK,
AUX_IC_CTRL, 2);
IFX_MEI_DMSG("Setting JTAG_MASTER_MODE..\n");
IFX_MEI_ControlModeSet (pDev, JTAG_MASTER_MODE);
IFX_MEI_DMSG("Halting ARC...\n");
IFX_MEI_HaltArc (&dsl_devices[0]);
#ifdef DFE_PING_TEST
IFX_MEI_DMSG("ping test image size=%d\n", sizeof (arc_ahb_access_code));
memcpy ((u8 *) (DSL_DEV_PRIVATE(pDev)->
adsl_mem_info[0].address + 0x1004),
&arc_ahb_access_code[0], sizeof (arc_ahb_access_code));
load_jump_table (0x80000 + 0x1004);
#endif //DFE_PING_TEST
IFX_MEI_DMSG("ARC ping test code download complete\n");
#endif //defined( DFE_PING_TEST )|| defined( DFE_ATM_LOOPBACK)
#ifdef DFE_MEM_TEST
IFX_MEI_LongWordWriteOffset (&dsl_devices[0], (u32) ME_ARC2ME_MASK, MSGAV_EN);
arc_code_page_download (1537, &code_array[0]);
IFX_MEI_DMSG("ARC mem test code download complete\n");
#endif //DFE_MEM_TEST
#ifdef DFE_ATM_LOOPBACK
arc_debug_data = 0xf;
arc_code_page_download (sizeof(code_array) / sizeof(*code_array), &code_array[0]);
wr_mbox[0] = 0; //TIMER_DELAY - org: 1024
wr_mbox[1] = 0; //TXFB_START0
wr_mbox[2] = 0x7f; //TXFB_END0 - org: 49
wr_mbox[3] = 0x80; //TXFB_START1 - org: 80
wr_mbox[4] = 0xff; //TXFB_END1 - org: 109
wr_mbox[5] = 0x100; //RXFB_START0 - org: 0
wr_mbox[6] = 0x17f; //RXFB_END0 - org: 49
wr_mbox[7] = 0x180; //RXFB_START1 - org: 256
wr_mbox[8] = 0x1ff; //RXFB_END1 - org: 315
WriteMbox (&wr_mbox[0], 9);
// Start Iridia IT_AMODE (in dmp access) why is it required?
IFX_MEI_DebugWrite (&dsl_devices[0], 0x32010, &arc_debug_data, 1);
#endif //DFE_ATM_LOOPBACK
IFX_MEI_IRQEnable (pDev);
IFX_MEI_DMSG("run ARC...\n");
IFX_MEI_RunArc (&dsl_devices[0]);
#ifdef DFE_PING_TEST
arc_ping_testing (pDev);
#endif //DFE_PING_TEST
#ifdef DFE_MEM_TEST
wait_mem_test_result ();
#endif //DFE_MEM_TEST
IFX_MEI_DFEMemoryFree (pDev, FREE_ALL);
return DSL_DEV_MEI_ERR_SUCCESS;
}
#endif //CONFIG_AMAZON_S_MEI_FW_LOOPBACK
static int
IFX_MEI_InitDevNode (int num)
{
if (num == 0) {
if ((dev_major = register_chrdev (dev_major, IFX_MEI_DEVNAME, &bsp_mei_operations)) < 0) {
IFX_MEI_EMSG ("register_chrdev(%d %s) failed!\n", dev_major, IFX_MEI_DEVNAME);
return -ENODEV;
}
}
return 0;
}
static int
IFX_MEI_CleanUpDevNode (int num)
{
if (num == 0)
unregister_chrdev (dev_major, MEI_DIRNAME);
return 0;
}
static int
IFX_MEI_InitDevice (int num)
{
DSL_DEV_Device_t *pDev;
u32 temp;
pDev = &dsl_devices[num];
if (pDev == NULL)
return -ENOMEM;
pDev->pPriv = &sDanube_Mei_Private[num];
memset (pDev->pPriv, 0, sizeof (ifx_mei_device_private_t));
memset (&DSL_DEV_PRIVATE(pDev)->
adsl_mem_info[0], 0,
sizeof (smmu_mem_info_t) * MAX_BAR_REGISTERS);
if (num == 0) {
pDev->nIrq[IFX_DFEIR] = LTQ_MEI_INT;
pDev->nIrq[IFX_DYING_GASP] = LTQ_MEI_DYING_GASP_INT;
pDev->base_address = KSEG1 + LTQ_MEI_BASE_ADDR;
/* Power up MEI */
#ifdef CONFIG_LANTIQ_AMAZON_SE
*LTQ_PMU_PWDCR &= ~(1 << 9); // enable dsl
*LTQ_PMU_PWDCR &= ~(1 << 15); // enable AHB base
#else
temp = ltq_r32(LTQ_PMU_PWDCR);
temp &= 0xffff7dbe;
ltq_w32(temp, LTQ_PMU_PWDCR);
#endif
}
pDev->nInUse = 0;
DSL_DEV_PRIVATE(pDev)->modem_ready = 0;
DSL_DEV_PRIVATE(pDev)->arcmsgav = 0;
MEI_INIT_WAKELIST ("arcq", DSL_DEV_PRIVATE(pDev)->wait_queue_arcmsgav); // for ARCMSGAV
MEI_INIT_WAKELIST ("arcr", DSL_DEV_PRIVATE(pDev)->wait_queue_modemready); // for arc modem ready
MEI_MUTEX_INIT (DSL_DEV_PRIVATE(pDev)->mei_cmv_sema, 1); // semaphore initialization, mutex
#if 0
MEI_MASK_AND_ACK_IRQ (pDev->nIrq[IFX_DFEIR]);
MEI_MASK_AND_ACK_IRQ (pDev->nIrq[IFX_DYING_GASP]);
#endif
if (request_irq (pDev->nIrq[IFX_DFEIR], IFX_MEI_IrqHandle, 0, "DFEIR", pDev) != 0) {
IFX_MEI_EMSG ("request_irq %d failed!\n", pDev->nIrq[IFX_DFEIR]);
return -1;
}
/*if (request_irq (pDev->nIrq[IFX_DYING_GASP], IFX_MEI_Dying_Gasp_IrqHandle, 0, "DYING_GASP", pDev) != 0) {
IFX_MEI_EMSG ("request_irq %d failed!\n", pDev->nIrq[IFX_DYING_GASP]);
return -1;
}*/
// IFX_MEI_DMSG("Device %d initialized. IER %#x\n", num, bsp_get_irq_ier(pDev->nIrq[IFX_DYING_GASP]));
return 0;
}
static int
IFX_MEI_ExitDevice (int num)
{
DSL_DEV_Device_t *pDev;
pDev = &dsl_devices[num];
if (pDev == NULL)
return -EIO;
disable_irq (pDev->nIrq[IFX_DFEIR]);
disable_irq (pDev->nIrq[IFX_DYING_GASP]);
free_irq(pDev->nIrq[IFX_DFEIR], pDev);
free_irq(pDev->nIrq[IFX_DYING_GASP], pDev);
return 0;
}
static DSL_DEV_Device_t *
IFX_BSP_HandleGet (int maj, int num)
{
if (num > BSP_MAX_DEVICES)
return NULL;
return &dsl_devices[num];
}
DSL_DEV_Device_t *
DSL_BSP_DriverHandleGet (int maj, int num)
{
DSL_DEV_Device_t *pDev;
if (num > BSP_MAX_DEVICES)
return NULL;
pDev = &dsl_devices[num];
if (!try_module_get(pDev->owner))
return NULL;
pDev->nInUse++;
return pDev;
}
int
DSL_BSP_DriverHandleDelete (DSL_DEV_Device_t * nHandle)
{
DSL_DEV_Device_t *pDev = (DSL_DEV_Device_t *) nHandle;
if (pDev->nInUse)
pDev->nInUse--;
module_put(pDev->owner);
return 0;
}
static int
IFX_MEI_Open (DSL_DRV_inode_t * ino, DSL_DRV_file_t * fil)
{
int maj = MAJOR (ino->i_rdev);
int num = MINOR (ino->i_rdev);
DSL_DEV_Device_t *pDev = NULL;
if ((pDev = DSL_BSP_DriverHandleGet (maj, num)) == NULL) {
IFX_MEI_EMSG("open(%d:%d) fail!\n", maj, num);
return -EIO;
}
fil->private_data = pDev;
return 0;
}
static int
IFX_MEI_Release (DSL_DRV_inode_t * ino, DSL_DRV_file_t * fil)
{
//int maj = MAJOR(ino->i_rdev);
int num = MINOR (ino->i_rdev);
DSL_DEV_Device_t *pDev;
pDev = &dsl_devices[num];
if (pDev == NULL)
return -EIO;
DSL_BSP_DriverHandleDelete (pDev);
return 0;
}
/**
* Callback function for linux userspace program writing
*/
static ssize_t
IFX_MEI_Write (DSL_DRV_file_t * filp, const char *buf, size_t size, loff_t * loff)
{
DSL_DEV_MeiError_t mei_error = DSL_DEV_MEI_ERR_FAILURE;
long offset = 0;
DSL_DEV_Device_t *pDev = (DSL_DEV_Device_t *) filp->private_data;
if (pDev == NULL)
return -EIO;
mei_error =
DSL_BSP_FWDownload (pDev, buf, size, (long *) loff, &offset);
if (mei_error == DSL_DEV_MEI_ERR_FAILURE)
return -EIO;
return (ssize_t) offset;
}
/**
* Callback function for linux userspace program ioctling
*/
static int
IFX_MEI_IoctlCopyFrom (int from_kernel, char *dest, char *from, int size)
{
int ret = 0;
if (!from_kernel)
ret = copy_from_user ((char *) dest, (char *) from, size);
else
ret = (int)memcpy ((char *) dest, (char *) from, size);
return ret;
}
static int
IFX_MEI_IoctlCopyTo (int from_kernel, char *dest, char *from, int size)
{
int ret = 0;
if (!from_kernel)
ret = copy_to_user ((char *) dest, (char *) from, size);
else
ret = (int)memcpy ((char *) dest, (char *) from, size);
return ret;
}
static int
IFX_MEI_Ioctls (DSL_DEV_Device_t * pDev, int from_kernel, unsigned int command, unsigned long lon)
{
int i = 0;
int meierr = DSL_DEV_MEI_ERR_SUCCESS;
u32 base_address = LTQ_MEI_BASE_ADDR;
DSL_DEV_WinHost_Message_t winhost_msg, m;
DSL_DEV_MeiDebug_t debugrdwr;
DSL_DEV_MeiReg_t regrdwr;
switch (command) {
case DSL_FIO_BSP_CMV_WINHOST:
IFX_MEI_IoctlCopyFrom (from_kernel, (char *) winhost_msg.msg.TxMessage,
(char *) lon, MSG_LENGTH * 2);
if ((meierr = DSL_BSP_SendCMV (pDev, winhost_msg.msg.TxMessage, YES_REPLY,
winhost_msg.msg.RxMessage)) != DSL_DEV_MEI_ERR_SUCCESS) {
IFX_MEI_EMSG ("WINHOST CMV fail :TxMessage:%X %X %X %X, RxMessage:%X %X %X %X %X\n",
winhost_msg.msg.TxMessage[0], winhost_msg.msg.TxMessage[1], winhost_msg.msg.TxMessage[2], winhost_msg.msg.TxMessage[3],
winhost_msg.msg.RxMessage[0], winhost_msg.msg.RxMessage[1], winhost_msg.msg.RxMessage[2], winhost_msg.msg.RxMessage[3],
winhost_msg.msg.RxMessage[4]);
meierr = DSL_DEV_MEI_ERR_FAILURE;
}
else {
IFX_MEI_IoctlCopyTo (from_kernel, (char *) lon,
(char *) winhost_msg.msg.RxMessage,
MSG_LENGTH * 2);
}
break;
case DSL_FIO_BSP_CMV_READ:
IFX_MEI_IoctlCopyFrom (from_kernel, (char *) (&regrdwr),
(char *) lon, sizeof (DSL_DEV_MeiReg_t));
IFX_MEI_LongWordRead ((u32) regrdwr.iAddress,
(u32 *) & (regrdwr.iData));
IFX_MEI_IoctlCopyTo (from_kernel, (char *) lon,
(char *) (&regrdwr),
sizeof (DSL_DEV_MeiReg_t));
break;
case DSL_FIO_BSP_CMV_WRITE:
IFX_MEI_IoctlCopyFrom (from_kernel, (char *) (&regrdwr),
(char *) lon, sizeof (DSL_DEV_MeiReg_t));
IFX_MEI_LongWordWrite ((u32) regrdwr.iAddress,
regrdwr.iData);
break;
case DSL_FIO_BSP_GET_BASE_ADDRESS:
IFX_MEI_IoctlCopyTo (from_kernel, (char *) lon,
(char *) (&base_address),
sizeof (base_address));
break;
case DSL_FIO_BSP_IS_MODEM_READY:
i = IFX_MEI_IsModemReady (pDev);
IFX_MEI_IoctlCopyTo (from_kernel, (char *) lon,
(char *) (&i), sizeof (int));
meierr = DSL_DEV_MEI_ERR_SUCCESS;
break;
case DSL_FIO_BSP_RESET:
case DSL_FIO_BSP_REBOOT:
meierr = IFX_MEI_CpuModeSet (pDev, DSL_CPU_RESET);
meierr = IFX_MEI_CpuModeSet (pDev, DSL_CPU_HALT);
break;
case DSL_FIO_BSP_HALT:
meierr = IFX_MEI_CpuModeSet (pDev, DSL_CPU_HALT);
break;
case DSL_FIO_BSP_RUN:
meierr = IFX_MEI_CpuModeSet (pDev, DSL_CPU_RUN);
break;
case DSL_FIO_BSP_BOOTDOWNLOAD:
meierr = IFX_MEI_DownloadBootCode (pDev);
break;
case DSL_FIO_BSP_JTAG_ENABLE:
meierr = IFX_MEI_ArcJtagEnable (pDev, 1);
break;
case DSL_FIO_BSP_REMOTE:
IFX_MEI_IoctlCopyFrom (from_kernel, (char *) (&i),
(char *) lon, sizeof (int));
meierr = IFX_MEI_AdslMailboxIRQEnable (pDev, i);
break;
case DSL_FIO_BSP_DSL_START:
IFX_MEI_DMSG("DSL_FIO_BSP_DSL_START\n");
if ((meierr = IFX_MEI_RunAdslModem (pDev)) != DSL_DEV_MEI_ERR_SUCCESS) {
IFX_MEI_EMSG ("IFX_MEI_RunAdslModem() error...");
meierr = DSL_DEV_MEI_ERR_FAILURE;
}
break;
case DSL_FIO_BSP_DEBUG_READ:
case DSL_FIO_BSP_DEBUG_WRITE:
IFX_MEI_IoctlCopyFrom (from_kernel,
(char *) (&debugrdwr),
(char *) lon,
sizeof (debugrdwr));
if (command == DSL_FIO_BSP_DEBUG_READ)
meierr = DSL_BSP_MemoryDebugAccess (pDev,
DSL_BSP_MEMORY_READ,
debugrdwr.
iAddress,
debugrdwr.
buffer,
debugrdwr.
iCount);
else
meierr = DSL_BSP_MemoryDebugAccess (pDev,
DSL_BSP_MEMORY_WRITE,
debugrdwr.
iAddress,
debugrdwr.
buffer,
debugrdwr.
iCount);
IFX_MEI_IoctlCopyTo (from_kernel, (char *) lon, (char *) (&debugrdwr), sizeof (debugrdwr));
break;
case DSL_FIO_BSP_GET_VERSION:
IFX_MEI_IoctlCopyTo (from_kernel, (char *) lon, (char *) (&bsp_mei_version), sizeof (DSL_DEV_Version_t));
break;
#define LTQ_MPS_CHIPID_VERSION_GET(value) (((value) >> 28) & ((1 << 4) - 1))
case DSL_FIO_BSP_GET_CHIP_INFO:
bsp_chip_info.major = 1;
bsp_chip_info.minor = LTQ_MPS_CHIPID_VERSION_GET(*LTQ_MPS_CHIPID);
IFX_MEI_IoctlCopyTo (from_kernel, (char *) lon, (char *) (&bsp_chip_info), sizeof (DSL_DEV_HwVersion_t));
meierr = DSL_DEV_MEI_ERR_SUCCESS;
break;
case DSL_FIO_BSP_FREE_RESOURCE:
makeCMV (H2D_CMV_READ, DSL_CMV_GROUP_STAT, 4, 0, 1, NULL, m.msg.TxMessage);
if (DSL_BSP_SendCMV (pDev, m.msg.TxMessage, YES_REPLY, m.msg.RxMessage) != DSL_DEV_MEI_ERR_SUCCESS) {
meierr = DSL_DEV_MEI_ERR_FAILURE;
return -EIO;
}
IFX_MEI_DMSG("RxMessage[4] = %#x\n", m.msg.RxMessage[4]);
if (!(m.msg.RxMessage[4] & DSL_DEV_STAT_CODESWAP_COMPLETE)) {
meierr = DSL_DEV_MEI_ERR_FAILURE;
return -EAGAIN;
}
IFX_MEI_DMSG("Freeing all memories marked FREE_SHOWTIME\n");
IFX_MEI_DFEMemoryFree (pDev, FREE_SHOWTIME);
meierr = DSL_DEV_MEI_ERR_SUCCESS;
break;
#ifdef CONFIG_IFXMIPS_AMAZON_SE
case DSL_FIO_ARC_MUX_TEST:
AMAZON_SE_MEI_ARC_MUX_Test();
break;
#endif
default:
// IFX_MEI_EMSG("Invalid IOCTL command: %d\n");
break;
}
return meierr;
}
#ifdef CONFIG_IFXMIPS_AMAZON_SE
void AMAZON_SE_MEI_ARC_MUX_Test(void)
{
u32 *p, i;
*LTQ_RCU_RST |= LTQ_RCU_RST_REQ_MUX_ARC;
p = (u32*)(DFE_LDST_BASE_ADDR + IRAM0_BASE);
IFX_MEI_EMSG("Writing to IRAM0(%p)...\n", p);
for (i = 0; i < IRAM0_SIZE/sizeof(u32); i++, p++) {
*p = 0xdeadbeef;
if (*p != 0xdeadbeef)
IFX_MEI_EMSG("%p: %#x\n", p, *p);
}
p = (u32*)(DFE_LDST_BASE_ADDR + IRAM1_BASE);
IFX_MEI_EMSG("Writing to IRAM1(%p)...\n", p);
for (i = 0; i < IRAM1_SIZE/sizeof(u32); i++, p++) {
*p = 0xdeadbeef;
if (*p != 0xdeadbeef)
IFX_MEI_EMSG("%p: %#x\n", p, *p);
}
p = (u32*)(DFE_LDST_BASE_ADDR + BRAM_BASE);
IFX_MEI_EMSG("Writing to BRAM(%p)...\n", p);
for (i = 0; i < BRAM_SIZE/sizeof(u32); i++, p++) {
*p = 0xdeadbeef;
if (*p != 0xdeadbeef)
IFX_MEI_EMSG("%p: %#x\n", p, *p);
}
p = (u32*)(DFE_LDST_BASE_ADDR + XRAM_BASE);
IFX_MEI_EMSG("Writing to XRAM(%p)...\n", p);
for (i = 0; i < XRAM_SIZE/sizeof(u32); i++, p++) {
*p = 0xdeadbeef;
if (*p != 0xdeadbeef)
IFX_MEI_EMSG("%p: %#x\n", p, *p);
}
p = (u32*)(DFE_LDST_BASE_ADDR + YRAM_BASE);
IFX_MEI_EMSG("Writing to YRAM(%p)...\n", p);
for (i = 0; i < YRAM_SIZE/sizeof(u32); i++, p++) {
*p = 0xdeadbeef;
if (*p != 0xdeadbeef)
IFX_MEI_EMSG("%p: %#x\n", p, *p);
}
p = (u32*)(DFE_LDST_BASE_ADDR + EXT_MEM_BASE);
IFX_MEI_EMSG("Writing to EXT_MEM(%p)...\n", p);
for (i = 0; i < EXT_MEM_SIZE/sizeof(u32); i++, p++) {
*p = 0xdeadbeef;
if (*p != 0xdeadbeef)
IFX_MEI_EMSG("%p: %#x\n", p, *p);
}
*LTQ_RCU_RST &= ~LTQ_RCU_RST_REQ_MUX_ARC;
}
#endif
int
DSL_BSP_KernelIoctls (DSL_DEV_Device_t * pDev, unsigned int command,
unsigned long lon)
{
int error = 0;
error = IFX_MEI_Ioctls (pDev, 1, command, lon);
return error;
}
#if (LINUX_VERSION_CODE < KERNEL_VERSION(2,6,36))
static int
IFX_MEI_UserIoctls (DSL_DRV_inode_t * ino, DSL_DRV_file_t * fil,
unsigned int command, unsigned long lon)
#else
static int
IFX_MEI_UserIoctls (DSL_DRV_file_t * fil,
unsigned int command, unsigned long lon)
#endif
{
int error = 0;
#if (LINUX_VERSION_CODE < KERNEL_VERSION(2,6,36))
int maj = MAJOR (ino->i_rdev);
int num = MINOR (ino->i_rdev);
#endif
DSL_DEV_Device_t *pDev;
#if (LINUX_VERSION_CODE < KERNEL_VERSION(2,6,36))
pDev = IFX_BSP_HandleGet (maj, num);
#else
pDev = IFX_BSP_HandleGet (0, 0);
#endif
if (pDev == NULL)
return -EIO;
error = IFX_MEI_Ioctls (pDev, 0, command, lon);
return error;
}
#ifdef CONFIG_PROC_FS
/*
* Register a callback function for linux proc filesystem
*/
static int
IFX_MEI_InitProcFS (int num)
{
struct proc_dir_entry *entry;
int i ;
DSL_DEV_Device_t *pDev;
reg_entry_t regs_temp[PROC_ITEMS] = {
/* flag, name, description } */
{NULL, "arcmsgav", "arc to mei message ", 0},
{NULL, "cmv_reply", "cmv needs reply", 0},
{NULL, "cmv_waiting", "waiting for cmv reply from arc", 0},
{NULL, "modem_ready_cnt", "ARC to MEI indicator count", 0},
{NULL, "cmv_count", "MEI to ARC CMVs", 0},
{NULL, "reply_count", "ARC to MEI Reply", 0},
{NULL, "Recent_indicator", "most recent indicator", 0},
{NULL, "fw_version", "Firmware Version", 0},
{NULL, "fw_date", "Firmware Date", 0},
{NULL, "meminfo", "Memory Allocation Information", 0},
{NULL, "version", "MEI version information", 0},
};
pDev = &dsl_devices[num];
if (pDev == NULL)
return -ENOMEM;
regs_temp[0].flag = &(DSL_DEV_PRIVATE(pDev)->arcmsgav);
regs_temp[1].flag = &(DSL_DEV_PRIVATE(pDev)->cmv_reply);
regs_temp[2].flag = &(DSL_DEV_PRIVATE(pDev)->cmv_waiting);
regs_temp[3].flag = &(DSL_DEV_PRIVATE(pDev)->modem_ready_cnt);
regs_temp[4].flag = &(DSL_DEV_PRIVATE(pDev)->cmv_count);
regs_temp[5].flag = &(DSL_DEV_PRIVATE(pDev)->reply_count);
regs_temp[6].flag = (int *) &(DSL_DEV_PRIVATE(pDev)->Recent_indicator);
memcpy ((char *) regs[num], (char *) regs_temp, sizeof (regs_temp));
// procfs
meidir = proc_mkdir (MEI_DIRNAME, NULL);
if (meidir == NULL) {
IFX_MEI_EMSG ("Failed to create /proc/%s\n", MEI_DIRNAME);
return (-ENOMEM);
}
for (i = 0; i < NUM_OF_REG_ENTRY; i++) {
entry = create_proc_entry (regs[num][i].name,
S_IWUSR | S_IRUSR | S_IRGRP |
S_IROTH, meidir);
if (entry) {
regs[num][i].low_ino = entry->low_ino;
entry->proc_fops = &IFX_MEI_ProcOperations;
}
else {
IFX_MEI_EMSG ("Failed to create /proc/%s/%s\n", MEI_DIRNAME, regs[num][i].name);
return (-ENOMEM);
}
}
return 0;
}
/*
* Reading function for linux proc filesystem
*/
static int
IFX_MEI_ProcRead (struct file *file, char *buf, size_t nbytes, loff_t * ppos)
{
int i_ino = (file->f_dentry->d_inode)->i_ino;
char *p = buf;
int i;
int num;
reg_entry_t *entry = NULL;
DSL_DEV_Device_t *pDev = NULL;
DSL_DEV_WinHost_Message_t m;
for (num = 0; num < BSP_MAX_DEVICES; num++) {
for (i = 0; i < NUM_OF_REG_ENTRY; i++) {
if (regs[num][i].low_ino == (unsigned short)i_ino) {
entry = &regs[num][i];
pDev = &dsl_devices[num];
break;
}
}
}
if (entry == NULL)
return -EINVAL;
else if (strcmp(entry->name, "meminfo") == 0) {
if (*ppos > 0) /* Assume reading completed in previous read */
return 0;
p += sprintf (p, "No Address Size\n");
for (i = 0; i < MAX_BAR_REGISTERS; i++) {
p += sprintf (p, "BAR[%02d] Addr:0x%08X Size:%lu\n",
i, (u32) DSL_DEV_PRIVATE(pDev)->adsl_mem_info[i].address,
DSL_DEV_PRIVATE(pDev)-> adsl_mem_info[i].size);
//printk( "BAR[%02d] Addr:0x%08X Size:%d\n",i,adsl_mem_info[i].address,adsl_mem_info[i].size);
}
*ppos += (p - buf);
} else if (strcmp(entry->name, "fw_version") == 0) {
if (*ppos > 0) /* Assume reading completed in previous read */
return 0;
if (DSL_DEV_PRIVATE(pDev)->modem_ready_cnt < 1)
return -EAGAIN;
//major:bits 0-7
//minor:bits 8-15
makeCMV (H2D_CMV_READ, DSL_CMV_GROUP_INFO, 54, 0, 1, NULL, m.msg.TxMessage);
if (DSL_BSP_SendCMV (pDev, m.msg.TxMessage, YES_REPLY, m.msg.RxMessage) != DSL_DEV_MEI_ERR_SUCCESS)
return -EIO;
p += sprintf(p, "FW Version: %d.%d.", m.msg.RxMessage[4] & 0xFF, (m.msg.RxMessage[4] >> 8) & 0xFF);
//sub_version:bits 4-7
//int_version:bits 0-3
//spl_appl:bits 8-13
//rel_state:bits 14-15
makeCMV (H2D_CMV_READ, DSL_CMV_GROUP_INFO, 54, 1, 1, NULL, m.msg.TxMessage);
if (DSL_BSP_SendCMV (pDev, m.msg.TxMessage, YES_REPLY, m.msg.RxMessage) != DSL_DEV_MEI_ERR_SUCCESS)
return -EIO;
p += sprintf(p, "%d.%d.%d.%d\n",
(m.msg.RxMessage[4] >> 4) & 0xF, m.msg.RxMessage[4] & 0xF,
(m.msg.RxMessage[4] >> 14) & 3, (m.msg.RxMessage[4] >> 8) & 0x3F);
*ppos += (p - buf);
} else if (strcmp(entry->name, "fw_date") == 0) {
if (*ppos > 0) /* Assume reading completed in previous read */
return 0;
if (DSL_DEV_PRIVATE(pDev)->modem_ready_cnt < 1)
return -EAGAIN;
makeCMV (H2D_CMV_READ, DSL_CMV_GROUP_INFO, 55, 0, 1, NULL, m.msg.TxMessage);
if (DSL_BSP_SendCMV (pDev, m.msg.TxMessage, YES_REPLY, m.msg.RxMessage) != DSL_DEV_MEI_ERR_SUCCESS)
return -EIO;
/* Day/Month */
p += sprintf(p, "FW Date: %d.%d.", m.msg.RxMessage[4] & 0xFF, (m.msg.RxMessage[4] >> 8) & 0xFF);
makeCMV (H2D_CMV_READ, DSL_CMV_GROUP_INFO, 55, 2, 1, NULL, m.msg.TxMessage);
if (DSL_BSP_SendCMV (pDev, m.msg.TxMessage, YES_REPLY, m.msg.RxMessage) != DSL_DEV_MEI_ERR_SUCCESS)
return -EIO;
/* Year */
p += sprintf(p, "%d ", m.msg.RxMessage[4]);
makeCMV (H2D_CMV_READ, DSL_CMV_GROUP_INFO, 55, 1, 1, NULL, m.msg.TxMessage);
if (DSL_BSP_SendCMV (pDev, m.msg.TxMessage, YES_REPLY, m.msg.RxMessage) != DSL_DEV_MEI_ERR_SUCCESS)
return -EIO;
/* Hour:Minute */
p += sprintf(p, "%d:%d\n", (m.msg.RxMessage[4] >> 8) & 0xFF, m.msg.RxMessage[4] & 0xFF);
*ppos += (p - buf);
} else if (strcmp(entry->name, "version") == 0) {
if (*ppos > 0) /* Assume reading completed in previous read */
return 0;
p += sprintf (p, "IFX MEI V%ld.%ld.%ld\n", bsp_mei_version.major, bsp_mei_version.minor, bsp_mei_version.revision);
*ppos += (p - buf);
} else if (entry->flag != (int *) DSL_DEV_PRIVATE(pDev)->Recent_indicator) {
if (*ppos > 0) /* Assume reading completed in previous read */
return 0; // indicates end of file
p += sprintf (p, "0x%08X\n\n", *(entry->flag));
*ppos += (p - buf);
if ((p - buf) > nbytes) /* Assume output can be read at one time */
return -EINVAL;
} else {
if ((int) (*ppos) / ((int) 7) == 16)
return 0; // indicate end of the message
p += sprintf (p, "0x%04X\n\n", *(((u16 *) (entry->flag)) + (int) (*ppos) / ((int) 7)));
*ppos += (p - buf);
}
return p - buf;
}
/*
* Writing function for linux proc filesystem
*/
static ssize_t
IFX_MEI_ProcWrite (struct file *file, const char *buffer, size_t count, loff_t * ppos)
{
int i_ino = (file->f_dentry->d_inode)->i_ino;
reg_entry_t *current_reg = NULL;
int i = 0;
int num = 0;
unsigned long newRegValue = 0;
char *endp = NULL;
DSL_DEV_Device_t *pDev = NULL;
for (num = 0; num < BSP_MAX_DEVICES; num++) {
for (i = 0; i < NUM_OF_REG_ENTRY; i++) {
if (regs[num][i].low_ino == i_ino) {
current_reg = &regs[num][i];
pDev = &dsl_devices[num];
break;
}
}
}
if ((current_reg == NULL)
|| (current_reg->flag ==
(int *) DSL_DEV_PRIVATE(pDev)->
Recent_indicator))
return -EINVAL;
newRegValue = simple_strtoul (buffer, &endp, 0);
*(current_reg->flag) = (int) newRegValue;
return (count + endp - buffer);
}
#endif //CONFIG_PROC_FS
static int adsl_dummy_ledcallback(void)
{
return 0;
}
int ifx_mei_atm_led_blink(void)
{
return g_adsl_ledcallback();
}
EXPORT_SYMBOL(ifx_mei_atm_led_blink);
int ifx_mei_atm_showtime_check(int *is_showtime, struct port_cell_info *port_cell, void **xdata_addr)
{
int i;
if ( is_showtime ) {
*is_showtime = g_tx_link_rate[0] == 0 && g_tx_link_rate[1] == 0 ? 0 : 1;
}
if ( port_cell ) {
for ( i = 0; i < port_cell->port_num && i < 2; i++ )
port_cell->tx_link_rate[i] = g_tx_link_rate[i];
}
if ( xdata_addr ) {
if ( g_tx_link_rate[0] == 0 && g_tx_link_rate[1] == 0 )
*xdata_addr = NULL;
else
*xdata_addr = g_xdata_addr;
}
return 0;
}
EXPORT_SYMBOL(ifx_mei_atm_showtime_check);
/*
* Writing function for linux proc filesystem
*/
int __init
IFX_MEI_ModuleInit (void)
{
int i = 0;
static struct class *dsl_class;
pr_info("IFX MEI Version %ld.%02ld.%02ld", bsp_mei_version.major, bsp_mei_version.minor, bsp_mei_version.revision);
for (i = 0; i < BSP_MAX_DEVICES; i++) {
if (IFX_MEI_InitDevice (i) != 0) {
IFX_MEI_EMSG("Init device fail!\n");
return -EIO;
}
IFX_MEI_InitDevNode (i);
#ifdef CONFIG_PROC_FS
IFX_MEI_InitProcFS (i);
#endif
}
for (i = 0; i <= DSL_BSP_CB_LAST ; i++)
dsl_bsp_event_callback[i].function = NULL;
#ifdef CONFIG_LTQ_MEI_FW_LOOPBACK
IFX_MEI_DMSG("Start loopback test...\n");
DFE_Loopback_Test ();
#endif
dsl_class = class_create(THIS_MODULE, "ifx_mei");
device_create(dsl_class, NULL, MKDEV(MEI_MAJOR, 0), NULL, "ifx_mei");
return 0;
}
void __exit
IFX_MEI_ModuleExit (void)
{
int i = 0;
int num;
for (num = 0; num < BSP_MAX_DEVICES; num++) {
IFX_MEI_CleanUpDevNode (num);
#ifdef CONFIG_PROC_FS
for (i = 0; i < NUM_OF_REG_ENTRY; i++) {
remove_proc_entry (regs[num][i].name, meidir);
}
#endif
}
remove_proc_entry (MEI_DIRNAME, NULL);
for (i = 0; i < BSP_MAX_DEVICES; i++) {
for (i = 0; i < BSP_MAX_DEVICES; i++) {
IFX_MEI_ExitDevice (i);
}
}
}
/* export function for DSL Driver */
/* The functions of MEI_DriverHandleGet and MEI_DriverHandleDelete are
something like open/close in kernel space , where the open could be used
to register a callback for autonomous messages and returns a mei driver context pointer (comparable to the file descriptor in user space)
The context will be required for the multi line chips future! */
EXPORT_SYMBOL (DSL_BSP_DriverHandleGet);
EXPORT_SYMBOL (DSL_BSP_DriverHandleDelete);
EXPORT_SYMBOL (DSL_BSP_ATMLedCBRegister);
EXPORT_SYMBOL (DSL_BSP_ATMLedCBUnregister);
EXPORT_SYMBOL (DSL_BSP_KernelIoctls);
EXPORT_SYMBOL (DSL_BSP_AdslLedInit);
//EXPORT_SYMBOL (DSL_BSP_AdslLedSet);
EXPORT_SYMBOL (DSL_BSP_FWDownload);
EXPORT_SYMBOL (DSL_BSP_Showtime);
EXPORT_SYMBOL (DSL_BSP_MemoryDebugAccess);
EXPORT_SYMBOL (DSL_BSP_SendCMV);
// provide a register/unregister function for DSL driver to register a event callback function
EXPORT_SYMBOL (DSL_BSP_EventCBRegister);
EXPORT_SYMBOL (DSL_BSP_EventCBUnregister);
module_init (IFX_MEI_ModuleInit);
module_exit (IFX_MEI_ModuleExit);
MODULE_LICENSE("Dual BSD/GPL");