Merge git://git.kernel.org/pub/scm/linux/kernel/git/gregkh/staging-2.6

* git://git.kernel.org/pub/scm/linux/kernel/git/gregkh/staging-2.6: (42 commits)
  Staging: usbip: fix build warning on 64bit kernels
  Staging: me4000: remove some compiler warnings
  Staging: wbusb: fix a bunch of compiler warnings
  Staging: w35und: module init cleanup
  Staging: w35und: use gotos for error handling
  Staging: w35und: remove spinlock wrappers
  Staging: sxg: fix compiler warnings.
  Staging: sxg: fix up unused function warnings
  Staging: sxg: clean up C99 comments
  Staging: Lindent the echo driver
  Staging: SLICOSS: Free multicast list at driver exit
  Staging: PCC-ACPI: Fix all checkpatch errors
  Staging: pcc-acpi: update to latest version
  Staging: Clean up sxg driver
  Staging: remove remaining uses of __FUNCTION__
  Staging: add poch driver
  Staging: wlan-ng: fix build error if wireless networking is not enabled
  Staging: echo: remove annoying "end of function" markers
  Staging: echo: remove __cplusplus macro magic
  Staging: echo: remove dead code
  ...
This commit is contained in:
Linus Torvalds 2008-10-23 10:09:33 -07:00
Родитель 92fb83afd6 51b90540dd
Коммит 45432371b4
77 изменённых файлов: 5557 добавлений и 3084 удалений

Просмотреть файл

@ -43,4 +43,8 @@ source "drivers/staging/echo/Kconfig"
source "drivers/staging/at76_usb/Kconfig"
source "drivers/staging/pcc-acpi/Kconfig"
source "drivers/staging/poch/Kconfig"
endif # STAGING

Просмотреть файл

@ -13,3 +13,5 @@ obj-$(CONFIG_W35UND) += winbond/
obj-$(CONFIG_PRISM2_USB) += wlan-ng/
obj-$(CONFIG_ECHO) += echo/
obj-$(CONFIG_USB_ATMEL) += at76_usb/
obj-$(CONFIG_PCC_ACPI) += pcc-acpi/
obj-$(CONFIG_POCH) += poch/

Просмотреть файл

@ -2319,9 +2319,11 @@ static int at76_iw_handler_get_scan(struct net_device *netdev,
if (!iwe)
return -ENOMEM;
if (priv->scan_state != SCAN_COMPLETED)
if (priv->scan_state != SCAN_COMPLETED) {
/* scan not yet finished */
kfree(iwe);
return -EAGAIN;
}
spin_lock_irqsave(&priv->bss_list_spinlock, flags);

Просмотреть файл

@ -30,114 +30,98 @@
#if !defined(_BIT_OPERATIONS_H_)
#define _BIT_OPERATIONS_H_
#ifdef __cplusplus
extern "C" {
#endif
#if defined(__i386__) || defined(__x86_64__)
/*! \brief Find the bit position of the highest set bit in a word
\param bits The word to be searched
\return The bit number of the highest set bit, or -1 if the word is zero. */
static __inline__ int top_bit(unsigned int bits)
{
int res;
int res;
__asm__ (" xorl %[res],%[res];\n"
" decl %[res];\n"
" bsrl %[bits],%[res]\n"
: [res] "=&r" (res)
: [bits] "rm" (bits));
return res;
__asm__(" xorl %[res],%[res];\n"
" decl %[res];\n"
" bsrl %[bits],%[res]\n"
:[res] "=&r" (res)
:[bits] "rm"(bits)
);
return res;
}
/*- End of function --------------------------------------------------------*/
/*! \brief Find the bit position of the lowest set bit in a word
\param bits The word to be searched
\return The bit number of the lowest set bit, or -1 if the word is zero. */
static __inline__ int bottom_bit(unsigned int bits)
{
int res;
int res;
__asm__ (" xorl %[res],%[res];\n"
" decl %[res];\n"
" bsfl %[bits],%[res]\n"
: [res] "=&r" (res)
: [bits] "rm" (bits));
return res;
__asm__(" xorl %[res],%[res];\n"
" decl %[res];\n"
" bsfl %[bits],%[res]\n"
:[res] "=&r" (res)
:[bits] "rm"(bits)
);
return res;
}
/*- End of function --------------------------------------------------------*/
#else
static __inline__ int top_bit(unsigned int bits)
{
int i;
int i;
if (bits == 0)
return -1;
i = 0;
if (bits & 0xFFFF0000)
{
bits &= 0xFFFF0000;
i += 16;
}
if (bits & 0xFF00FF00)
{
bits &= 0xFF00FF00;
i += 8;
}
if (bits & 0xF0F0F0F0)
{
bits &= 0xF0F0F0F0;
i += 4;
}
if (bits & 0xCCCCCCCC)
{
bits &= 0xCCCCCCCC;
i += 2;
}
if (bits & 0xAAAAAAAA)
{
bits &= 0xAAAAAAAA;
i += 1;
}
return i;
if (bits == 0)
return -1;
i = 0;
if (bits & 0xFFFF0000) {
bits &= 0xFFFF0000;
i += 16;
}
if (bits & 0xFF00FF00) {
bits &= 0xFF00FF00;
i += 8;
}
if (bits & 0xF0F0F0F0) {
bits &= 0xF0F0F0F0;
i += 4;
}
if (bits & 0xCCCCCCCC) {
bits &= 0xCCCCCCCC;
i += 2;
}
if (bits & 0xAAAAAAAA) {
bits &= 0xAAAAAAAA;
i += 1;
}
return i;
}
/*- End of function --------------------------------------------------------*/
static __inline__ int bottom_bit(unsigned int bits)
{
int i;
int i;
if (bits == 0)
return -1;
i = 32;
if (bits & 0x0000FFFF)
{
bits &= 0x0000FFFF;
i -= 16;
}
if (bits & 0x00FF00FF)
{
bits &= 0x00FF00FF;
i -= 8;
}
if (bits & 0x0F0F0F0F)
{
bits &= 0x0F0F0F0F;
i -= 4;
}
if (bits & 0x33333333)
{
bits &= 0x33333333;
i -= 2;
}
if (bits & 0x55555555)
{
bits &= 0x55555555;
i -= 1;
}
return i;
if (bits == 0)
return -1;
i = 32;
if (bits & 0x0000FFFF) {
bits &= 0x0000FFFF;
i -= 16;
}
if (bits & 0x00FF00FF) {
bits &= 0x00FF00FF;
i -= 8;
}
if (bits & 0x0F0F0F0F) {
bits &= 0x0F0F0F0F;
i -= 4;
}
if (bits & 0x33333333) {
bits &= 0x33333333;
i -= 2;
}
if (bits & 0x55555555) {
bits &= 0x55555555;
i -= 1;
}
return i;
}
/*- End of function --------------------------------------------------------*/
#endif
/*! \brief Bit reverse a byte.
@ -146,16 +130,16 @@ static __inline__ int bottom_bit(unsigned int bits)
static __inline__ uint8_t bit_reverse8(uint8_t x)
{
#if defined(__i386__) || defined(__x86_64__)
/* If multiply is fast */
return ((x*0x0802U & 0x22110U) | (x*0x8020U & 0x88440U))*0x10101U >> 16;
/* If multiply is fast */
return ((x * 0x0802U & 0x22110U) | (x * 0x8020U & 0x88440U)) *
0x10101U >> 16;
#else
/* If multiply is slow, but we have a barrel shifter */
x = (x >> 4) | (x << 4);
x = ((x & 0xCC) >> 2) | ((x & 0x33) << 2);
return ((x & 0xAA) >> 1) | ((x & 0x55) << 1);
/* If multiply is slow, but we have a barrel shifter */
x = (x >> 4) | (x << 4);
x = ((x & 0xCC) >> 2) | ((x & 0x33) << 2);
return ((x & 0xAA) >> 1) | ((x & 0x55) << 1);
#endif
}
/*- End of function --------------------------------------------------------*/
/*! \brief Bit reverse a 16 bit word.
\param data The word to be reversed.
@ -193,9 +177,8 @@ uint16_t make_mask16(uint16_t x);
\return The word with the single set bit. */
static __inline__ uint32_t least_significant_one32(uint32_t x)
{
return (x & (-(int32_t) x));
return (x & (-(int32_t) x));
}
/*- End of function --------------------------------------------------------*/
/*! \brief Find the most significant one in a word, and return a word
with just that bit set.
@ -204,50 +187,42 @@ static __inline__ uint32_t least_significant_one32(uint32_t x)
static __inline__ uint32_t most_significant_one32(uint32_t x)
{
#if defined(__i386__) || defined(__x86_64__)
return 1 << top_bit(x);
return 1 << top_bit(x);
#else
x = make_mask32(x);
return (x ^ (x >> 1));
x = make_mask32(x);
return (x ^ (x >> 1));
#endif
}
/*- End of function --------------------------------------------------------*/
/*! \brief Find the parity of a byte.
\param x The byte to be checked.
\return 1 for odd, or 0 for even. */
static __inline__ int parity8(uint8_t x)
{
x = (x ^ (x >> 4)) & 0x0F;
return (0x6996 >> x) & 1;
x = (x ^ (x >> 4)) & 0x0F;
return (0x6996 >> x) & 1;
}
/*- End of function --------------------------------------------------------*/
/*! \brief Find the parity of a 16 bit word.
\param x The word to be checked.
\return 1 for odd, or 0 for even. */
static __inline__ int parity16(uint16_t x)
{
x ^= (x >> 8);
x = (x ^ (x >> 4)) & 0x0F;
return (0x6996 >> x) & 1;
x ^= (x >> 8);
x = (x ^ (x >> 4)) & 0x0F;
return (0x6996 >> x) & 1;
}
/*- End of function --------------------------------------------------------*/
/*! \brief Find the parity of a 32 bit word.
\param x The word to be checked.
\return 1 for odd, or 0 for even. */
static __inline__ int parity32(uint32_t x)
{
x ^= (x >> 16);
x ^= (x >> 8);
x = (x ^ (x >> 4)) & 0x0F;
return (0x6996 >> x) & 1;
x ^= (x >> 16);
x ^= (x >> 8);
x = (x ^ (x >> 4)) & 0x0F;
return (0x6996 >> x) & 1;
}
/*- End of function --------------------------------------------------------*/
#ifdef __cplusplus
}
#endif
#endif
/*- End of file ------------------------------------------------------------*/

Просмотреть файл

@ -74,7 +74,6 @@
Steve also has some nice notes on echo cancellers in echo.h
References:
[1] Ochiai, Areseki, and Ogihara, "Echo Canceller with Two Echo
@ -105,20 +104,18 @@
Mark, Pawel, and Pavel.
*/
#include <linux/kernel.h> /* We're doing kernel work */
#include <linux/kernel.h> /* We're doing kernel work */
#include <linux/module.h>
#include <linux/kernel.h>
#include <linux/slab.h>
#define malloc(a) kmalloc((a), GFP_KERNEL)
#define free(a) kfree(a)
#include "bit_operations.h"
#include "echo.h"
#define MIN_TX_POWER_FOR_ADAPTION 64
#define MIN_RX_POWER_FOR_ADAPTION 64
#define DTD_HANGOVER 600 /* 600 samples, or 75ms */
#define DC_LOG2BETA 3 /* log2() of DC filter Beta */
#define DTD_HANGOVER 600 /* 600 samples, or 75ms */
#define DC_LOG2BETA 3 /* log2() of DC filter Beta */
/*-----------------------------------------------------------------------*\
FUNCTIONS
@ -126,59 +123,58 @@
/* adapting coeffs using the traditional stochastic descent (N)LMS algorithm */
#ifdef __BLACKFIN_ASM__
static void __inline__ lms_adapt_bg(echo_can_state_t *ec, int clean, int shift)
#ifdef __bfin__
static void __inline__ lms_adapt_bg(struct oslec_state *ec, int clean,
int shift)
{
int i, j;
int offset1;
int offset2;
int factor;
int exp;
int16_t *phist;
int n;
int i, j;
int offset1;
int offset2;
int factor;
int exp;
int16_t *phist;
int n;
if (shift > 0)
factor = clean << shift;
else
factor = clean >> -shift;
if (shift > 0)
factor = clean << shift;
else
factor = clean >> -shift;
/* Update the FIR taps */
/* Update the FIR taps */
offset2 = ec->curr_pos;
offset1 = ec->taps - offset2;
phist = &ec->fir_state_bg.history[offset2];
offset2 = ec->curr_pos;
offset1 = ec->taps - offset2;
phist = &ec->fir_state_bg.history[offset2];
/* st: and en: help us locate the assembler in echo.s */
/* st: and en: help us locate the assembler in echo.s */
//asm("st:");
n = ec->taps;
for (i = 0, j = offset2; i < n; i++, j++)
{
exp = *phist++ * factor;
ec->fir_taps16[1][i] += (int16_t) ((exp+(1<<14)) >> 15);
}
//asm("en:");
//asm("st:");
n = ec->taps;
for (i = 0, j = offset2; i < n; i++, j++) {
exp = *phist++ * factor;
ec->fir_taps16[1][i] += (int16_t) ((exp + (1 << 14)) >> 15);
}
//asm("en:");
/* Note the asm for the inner loop above generated by Blackfin gcc
4.1.1 is pretty good (note even parallel instructions used):
/* Note the asm for the inner loop above generated by Blackfin gcc
4.1.1 is pretty good (note even parallel instructions used):
R0 = W [P0++] (X);
R0 *= R2;
R0 = R0 + R3 (NS) ||
R1 = W [P1] (X) ||
nop;
R0 >>>= 15;
R0 = R0 + R1;
W [P1++] = R0;
R0 = W [P0++] (X);
R0 *= R2;
R0 = R0 + R3 (NS) ||
R1 = W [P1] (X) ||
nop;
R0 >>>= 15;
R0 = R0 + R1;
W [P1++] = R0;
A block based update algorithm would be much faster but the
above can't be improved on much. Every instruction saved in
the loop above is 2 MIPs/ch! The for loop above is where the
Blackfin spends most of it's time - about 17 MIPs/ch measured
with speedtest.c with 256 taps (32ms). Write-back and
Write-through cache gave about the same performance.
*/
A block based update algorithm would be much faster but the
above can't be improved on much. Every instruction saved in
the loop above is 2 MIPs/ch! The for loop above is where the
Blackfin spends most of it's time - about 17 MIPs/ch measured
with speedtest.c with 256 taps (32ms). Write-back and
Write-through cache gave about the same performance.
*/
}
/*
@ -200,392 +196,393 @@ static void __inline__ lms_adapt_bg(echo_can_state_t *ec, int clean, int shift)
*/
#else
static __inline__ void lms_adapt_bg(echo_can_state_t *ec, int clean, int shift)
static __inline__ void lms_adapt_bg(struct oslec_state *ec, int clean,
int shift)
{
int i;
int i;
int offset1;
int offset2;
int factor;
int exp;
int offset1;
int offset2;
int factor;
int exp;
if (shift > 0)
factor = clean << shift;
else
factor = clean >> -shift;
if (shift > 0)
factor = clean << shift;
else
factor = clean >> -shift;
/* Update the FIR taps */
/* Update the FIR taps */
offset2 = ec->curr_pos;
offset1 = ec->taps - offset2;
offset2 = ec->curr_pos;
offset1 = ec->taps - offset2;
for (i = ec->taps - 1; i >= offset1; i--)
{
exp = (ec->fir_state_bg.history[i - offset1]*factor);
ec->fir_taps16[1][i] += (int16_t) ((exp+(1<<14)) >> 15);
}
for ( ; i >= 0; i--)
{
exp = (ec->fir_state_bg.history[i + offset2]*factor);
ec->fir_taps16[1][i] += (int16_t) ((exp+(1<<14)) >> 15);
}
for (i = ec->taps - 1; i >= offset1; i--) {
exp = (ec->fir_state_bg.history[i - offset1] * factor);
ec->fir_taps16[1][i] += (int16_t) ((exp + (1 << 14)) >> 15);
}
for (; i >= 0; i--) {
exp = (ec->fir_state_bg.history[i + offset2] * factor);
ec->fir_taps16[1][i] += (int16_t) ((exp + (1 << 14)) >> 15);
}
}
#endif
/*- End of function --------------------------------------------------------*/
echo_can_state_t *echo_can_create(int len, int adaption_mode)
struct oslec_state *oslec_create(int len, int adaption_mode)
{
echo_can_state_t *ec;
int i;
int j;
struct oslec_state *ec;
int i;
ec = kmalloc(sizeof(*ec), GFP_KERNEL);
if (ec == NULL)
return NULL;
memset(ec, 0, sizeof(*ec));
ec = kzalloc(sizeof(*ec), GFP_KERNEL);
if (!ec)
return NULL;
ec->taps = len;
ec->log2taps = top_bit(len);
ec->curr_pos = ec->taps - 1;
ec->taps = len;
ec->log2taps = top_bit(len);
ec->curr_pos = ec->taps - 1;
for (i = 0; i < 2; i++)
{
if ((ec->fir_taps16[i] = (int16_t *) malloc((ec->taps)*sizeof(int16_t))) == NULL)
{
for (j = 0; j < i; j++)
kfree(ec->fir_taps16[j]);
kfree(ec);
return NULL;
}
memset(ec->fir_taps16[i], 0, (ec->taps)*sizeof(int16_t));
}
for (i = 0; i < 2; i++) {
ec->fir_taps16[i] =
kcalloc(ec->taps, sizeof(int16_t), GFP_KERNEL);
if (!ec->fir_taps16[i])
goto error_oom;
}
fir16_create(&ec->fir_state,
ec->fir_taps16[0],
ec->taps);
fir16_create(&ec->fir_state_bg,
ec->fir_taps16[1],
ec->taps);
fir16_create(&ec->fir_state, ec->fir_taps16[0], ec->taps);
fir16_create(&ec->fir_state_bg, ec->fir_taps16[1], ec->taps);
for(i=0; i<5; i++) {
ec->xvtx[i] = ec->yvtx[i] = ec->xvrx[i] = ec->yvrx[i] = 0;
}
for (i = 0; i < 5; i++) {
ec->xvtx[i] = ec->yvtx[i] = ec->xvrx[i] = ec->yvrx[i] = 0;
}
ec->cng_level = 1000;
echo_can_adaption_mode(ec, adaption_mode);
ec->cng_level = 1000;
oslec_adaption_mode(ec, adaption_mode);
ec->snapshot = (int16_t*)malloc(ec->taps*sizeof(int16_t));
memset(ec->snapshot, 0, sizeof(int16_t)*ec->taps);
ec->snapshot = kcalloc(ec->taps, sizeof(int16_t), GFP_KERNEL);
if (!ec->snapshot)
goto error_oom;
ec->cond_met = 0;
ec->Pstates = 0;
ec->Ltxacc = ec->Lrxacc = ec->Lcleanacc = ec->Lclean_bgacc = 0;
ec->Ltx = ec->Lrx = ec->Lclean = ec->Lclean_bg = 0;
ec->tx_1 = ec->tx_2 = ec->rx_1 = ec->rx_2 = 0;
ec->Lbgn = ec->Lbgn_acc = 0;
ec->Lbgn_upper = 200;
ec->Lbgn_upper_acc = ec->Lbgn_upper << 13;
ec->cond_met = 0;
ec->Pstates = 0;
ec->Ltxacc = ec->Lrxacc = ec->Lcleanacc = ec->Lclean_bgacc = 0;
ec->Ltx = ec->Lrx = ec->Lclean = ec->Lclean_bg = 0;
ec->tx_1 = ec->tx_2 = ec->rx_1 = ec->rx_2 = 0;
ec->Lbgn = ec->Lbgn_acc = 0;
ec->Lbgn_upper = 200;
ec->Lbgn_upper_acc = ec->Lbgn_upper << 13;
return ec;
return ec;
error_oom:
for (i = 0; i < 2; i++)
kfree(ec->fir_taps16[i]);
kfree(ec);
return NULL;
}
/*- End of function --------------------------------------------------------*/
void echo_can_free(echo_can_state_t *ec)
EXPORT_SYMBOL_GPL(oslec_create);
void oslec_free(struct oslec_state *ec)
{
int i;
fir16_free(&ec->fir_state);
fir16_free(&ec->fir_state_bg);
for (i = 0; i < 2; i++)
for (i = 0; i < 2; i++)
kfree(ec->fir_taps16[i]);
kfree(ec->snapshot);
kfree(ec);
}
/*- End of function --------------------------------------------------------*/
void echo_can_adaption_mode(echo_can_state_t *ec, int adaption_mode)
EXPORT_SYMBOL_GPL(oslec_free);
void oslec_adaption_mode(struct oslec_state *ec, int adaption_mode)
{
ec->adaption_mode = adaption_mode;
ec->adaption_mode = adaption_mode;
}
/*- End of function --------------------------------------------------------*/
void echo_can_flush(echo_can_state_t *ec)
EXPORT_SYMBOL_GPL(oslec_adaption_mode);
void oslec_flush(struct oslec_state *ec)
{
int i;
int i;
ec->Ltxacc = ec->Lrxacc = ec->Lcleanacc = ec->Lclean_bgacc = 0;
ec->Ltx = ec->Lrx = ec->Lclean = ec->Lclean_bg = 0;
ec->tx_1 = ec->tx_2 = ec->rx_1 = ec->rx_2 = 0;
ec->Ltxacc = ec->Lrxacc = ec->Lcleanacc = ec->Lclean_bgacc = 0;
ec->Ltx = ec->Lrx = ec->Lclean = ec->Lclean_bg = 0;
ec->tx_1 = ec->tx_2 = ec->rx_1 = ec->rx_2 = 0;
ec->Lbgn = ec->Lbgn_acc = 0;
ec->Lbgn_upper = 200;
ec->Lbgn_upper_acc = ec->Lbgn_upper << 13;
ec->Lbgn = ec->Lbgn_acc = 0;
ec->Lbgn_upper = 200;
ec->Lbgn_upper_acc = ec->Lbgn_upper << 13;
ec->nonupdate_dwell = 0;
ec->nonupdate_dwell = 0;
fir16_flush(&ec->fir_state);
fir16_flush(&ec->fir_state_bg);
ec->fir_state.curr_pos = ec->taps - 1;
ec->fir_state_bg.curr_pos = ec->taps - 1;
for (i = 0; i < 2; i++)
memset(ec->fir_taps16[i], 0, ec->taps*sizeof(int16_t));
fir16_flush(&ec->fir_state);
fir16_flush(&ec->fir_state_bg);
ec->fir_state.curr_pos = ec->taps - 1;
ec->fir_state_bg.curr_pos = ec->taps - 1;
for (i = 0; i < 2; i++)
memset(ec->fir_taps16[i], 0, ec->taps * sizeof(int16_t));
ec->curr_pos = ec->taps - 1;
ec->Pstates = 0;
ec->curr_pos = ec->taps - 1;
ec->Pstates = 0;
}
/*- End of function --------------------------------------------------------*/
void echo_can_snapshot(echo_can_state_t *ec) {
memcpy(ec->snapshot, ec->fir_taps16[0], ec->taps*sizeof(int16_t));
EXPORT_SYMBOL_GPL(oslec_flush);
void oslec_snapshot(struct oslec_state *ec)
{
memcpy(ec->snapshot, ec->fir_taps16[0], ec->taps * sizeof(int16_t));
}
/*- End of function --------------------------------------------------------*/
EXPORT_SYMBOL_GPL(oslec_snapshot);
/* Dual Path Echo Canceller ------------------------------------------------*/
int16_t echo_can_update(echo_can_state_t *ec, int16_t tx, int16_t rx)
int16_t oslec_update(struct oslec_state *ec, int16_t tx, int16_t rx)
{
int32_t echo_value;
int clean_bg;
int tmp, tmp1;
int32_t echo_value;
int clean_bg;
int tmp, tmp1;
/* Input scaling was found be required to prevent problems when tx
starts clipping. Another possible way to handle this would be the
filter coefficent scaling. */
/* Input scaling was found be required to prevent problems when tx
starts clipping. Another possible way to handle this would be the
filter coefficent scaling. */
ec->tx = tx; ec->rx = rx;
tx >>=1;
rx >>=1;
ec->tx = tx;
ec->rx = rx;
tx >>= 1;
rx >>= 1;
/*
Filter DC, 3dB point is 160Hz (I think), note 32 bit precision required
otherwise values do not track down to 0. Zero at DC, Pole at (1-Beta)
only real axis. Some chip sets (like Si labs) don't need
this, but something like a $10 X100P card does. Any DC really slows
down convergence.
/*
Filter DC, 3dB point is 160Hz (I think), note 32 bit precision required
otherwise values do not track down to 0. Zero at DC, Pole at (1-Beta)
only real axis. Some chip sets (like Si labs) don't need
this, but something like a $10 X100P card does. Any DC really slows
down convergence.
Note: removes some low frequency from the signal, this reduces
the speech quality when listening to samples through headphones
but may not be obvious through a telephone handset.
Note: removes some low frequency from the signal, this reduces
the speech quality when listening to samples through headphones
but may not be obvious through a telephone handset.
Note that the 3dB frequency in radians is approx Beta, e.g. for
Beta = 2^(-3) = 0.125, 3dB freq is 0.125 rads = 159Hz.
*/
Note that the 3dB frequency in radians is approx Beta, e.g. for
Beta = 2^(-3) = 0.125, 3dB freq is 0.125 rads = 159Hz.
*/
if (ec->adaption_mode & ECHO_CAN_USE_RX_HPF) {
tmp = rx << 15;
if (ec->adaption_mode & ECHO_CAN_USE_RX_HPF) {
tmp = rx << 15;
#if 1
/* Make sure the gain of the HPF is 1.0. This can still saturate a little under
impulse conditions, and it might roll to 32768 and need clipping on sustained peak
level signals. However, the scale of such clipping is small, and the error due to
any saturation should not markedly affect the downstream processing. */
tmp -= (tmp >> 4);
/* Make sure the gain of the HPF is 1.0. This can still saturate a little under
impulse conditions, and it might roll to 32768 and need clipping on sustained peak
level signals. However, the scale of such clipping is small, and the error due to
any saturation should not markedly affect the downstream processing. */
tmp -= (tmp >> 4);
#endif
ec->rx_1 += -(ec->rx_1>>DC_LOG2BETA) + tmp - ec->rx_2;
ec->rx_1 += -(ec->rx_1 >> DC_LOG2BETA) + tmp - ec->rx_2;
/* hard limit filter to prevent clipping. Note that at this stage
rx should be limited to +/- 16383 due to right shift above */
tmp1 = ec->rx_1 >> 15;
if (tmp1 > 16383) tmp1 = 16383;
if (tmp1 < -16383) tmp1 = -16383;
rx = tmp1;
ec->rx_2 = tmp;
}
/* Block average of power in the filter states. Used for
adaption power calculation. */
{
int new, old;
/* efficient "out with the old and in with the new" algorithm so
we don't have to recalculate over the whole block of
samples. */
new = (int)tx * (int)tx;
old = (int)ec->fir_state.history[ec->fir_state.curr_pos] *
(int)ec->fir_state.history[ec->fir_state.curr_pos];
ec->Pstates += ((new - old) + (1<<ec->log2taps)) >> ec->log2taps;
if (ec->Pstates < 0) ec->Pstates = 0;
}
/* Calculate short term average levels using simple single pole IIRs */
ec->Ltxacc += abs(tx) - ec->Ltx;
ec->Ltx = (ec->Ltxacc + (1<<4)) >> 5;
ec->Lrxacc += abs(rx) - ec->Lrx;
ec->Lrx = (ec->Lrxacc + (1<<4)) >> 5;
/* Foreground filter ---------------------------------------------------*/
ec->fir_state.coeffs = ec->fir_taps16[0];
echo_value = fir16(&ec->fir_state, tx);
ec->clean = rx - echo_value;
ec->Lcleanacc += abs(ec->clean) - ec->Lclean;
ec->Lclean = (ec->Lcleanacc + (1<<4)) >> 5;
/* Background filter ---------------------------------------------------*/
echo_value = fir16(&ec->fir_state_bg, tx);
clean_bg = rx - echo_value;
ec->Lclean_bgacc += abs(clean_bg) - ec->Lclean_bg;
ec->Lclean_bg = (ec->Lclean_bgacc + (1<<4)) >> 5;
/* Background Filter adaption -----------------------------------------*/
/* Almost always adap bg filter, just simple DT and energy
detection to minimise adaption in cases of strong double talk.
However this is not critical for the dual path algorithm.
*/
ec->factor = 0;
ec->shift = 0;
if ((ec->nonupdate_dwell == 0)) {
int P, logP, shift;
/* Determine:
f = Beta * clean_bg_rx/P ------ (1)
where P is the total power in the filter states.
The Boffins have shown that if we obey (1) we converge
quickly and avoid instability.
The correct factor f must be in Q30, as this is the fixed
point format required by the lms_adapt_bg() function,
therefore the scaled version of (1) is:
(2^30) * f = (2^30) * Beta * clean_bg_rx/P
factor = (2^30) * Beta * clean_bg_rx/P ----- (2)
We have chosen Beta = 0.25 by experiment, so:
factor = (2^30) * (2^-2) * clean_bg_rx/P
(30 - 2 - log2(P))
factor = clean_bg_rx 2 ----- (3)
To avoid a divide we approximate log2(P) as top_bit(P),
which returns the position of the highest non-zero bit in
P. This approximation introduces an error as large as a
factor of 2, but the algorithm seems to handle it OK.
Come to think of it a divide may not be a big deal on a
modern DSP, so its probably worth checking out the cycles
for a divide versus a top_bit() implementation.
*/
P = MIN_TX_POWER_FOR_ADAPTION + ec->Pstates;
logP = top_bit(P) + ec->log2taps;
shift = 30 - 2 - logP;
ec->shift = shift;
lms_adapt_bg(ec, clean_bg, shift);
}
/* very simple DTD to make sure we dont try and adapt with strong
near end speech */
ec->adapt = 0;
if ((ec->Lrx > MIN_RX_POWER_FOR_ADAPTION) && (ec->Lrx > ec->Ltx))
ec->nonupdate_dwell = DTD_HANGOVER;
if (ec->nonupdate_dwell)
ec->nonupdate_dwell--;
/* Transfer logic ------------------------------------------------------*/
/* These conditions are from the dual path paper [1], I messed with
them a bit to improve performance. */
if ((ec->adaption_mode & ECHO_CAN_USE_ADAPTION) &&
(ec->nonupdate_dwell == 0) &&
(8*ec->Lclean_bg < 7*ec->Lclean) /* (ec->Lclean_bg < 0.875*ec->Lclean) */ &&
(8*ec->Lclean_bg < ec->Ltx) /* (ec->Lclean_bg < 0.125*ec->Ltx) */ )
{
if (ec->cond_met == 6) {
/* BG filter has had better results for 6 consecutive samples */
ec->adapt = 1;
memcpy(ec->fir_taps16[0], ec->fir_taps16[1], ec->taps*sizeof(int16_t));
/* hard limit filter to prevent clipping. Note that at this stage
rx should be limited to +/- 16383 due to right shift above */
tmp1 = ec->rx_1 >> 15;
if (tmp1 > 16383)
tmp1 = 16383;
if (tmp1 < -16383)
tmp1 = -16383;
rx = tmp1;
ec->rx_2 = tmp;
}
else
ec->cond_met++;
}
else
ec->cond_met = 0;
/* Non-Linear Processing ---------------------------------------------------*/
/* Block average of power in the filter states. Used for
adaption power calculation. */
ec->clean_nlp = ec->clean;
if (ec->adaption_mode & ECHO_CAN_USE_NLP)
{
/* Non-linear processor - a fancy way to say "zap small signals, to avoid
residual echo due to (uLaw/ALaw) non-linearity in the channel.". */
if ((16*ec->Lclean < ec->Ltx))
{
/* Our e/c has improved echo by at least 24 dB (each factor of 2 is 6dB,
so 2*2*2*2=16 is the same as 6+6+6+6=24dB) */
if (ec->adaption_mode & ECHO_CAN_USE_CNG)
{
ec->cng_level = ec->Lbgn;
int new, old;
/* Very elementary comfort noise generation. Just random
numbers rolled off very vaguely Hoth-like. DR: This
noise doesn't sound quite right to me - I suspect there
are some overlfow issues in the filtering as it's too
"crackly". TODO: debug this, maybe just play noise at
high level or look at spectrum.
*/
ec->cng_rndnum = 1664525U*ec->cng_rndnum + 1013904223U;
ec->cng_filter = ((ec->cng_rndnum & 0xFFFF) - 32768 + 5*ec->cng_filter) >> 3;
ec->clean_nlp = (ec->cng_filter*ec->cng_level*8) >> 14;
}
else if (ec->adaption_mode & ECHO_CAN_USE_CLIP)
{
/* This sounds much better than CNG */
if (ec->clean_nlp > ec->Lbgn)
ec->clean_nlp = ec->Lbgn;
if (ec->clean_nlp < -ec->Lbgn)
ec->clean_nlp = -ec->Lbgn;
/* efficient "out with the old and in with the new" algorithm so
we don't have to recalculate over the whole block of
samples. */
new = (int)tx *(int)tx;
old = (int)ec->fir_state.history[ec->fir_state.curr_pos] *
(int)ec->fir_state.history[ec->fir_state.curr_pos];
ec->Pstates +=
((new - old) + (1 << ec->log2taps)) >> ec->log2taps;
if (ec->Pstates < 0)
ec->Pstates = 0;
}
else
{
/* just mute the residual, doesn't sound very good, used mainly
in G168 tests */
ec->clean_nlp = 0;
}
}
else {
/* Background noise estimator. I tried a few algorithms
here without much luck. This very simple one seems to
work best, we just average the level using a slow (1 sec
time const) filter if the current level is less than a
(experimentally derived) constant. This means we dont
include high level signals like near end speech. When
combined with CNG or especially CLIP seems to work OK.
*/
if (ec->Lclean < 40) {
ec->Lbgn_acc += abs(ec->clean) - ec->Lbgn;
ec->Lbgn = (ec->Lbgn_acc + (1<<11)) >> 12;
}
}
}
/* Roll around the taps buffer */
if (ec->curr_pos <= 0)
ec->curr_pos = ec->taps;
ec->curr_pos--;
/* Calculate short term average levels using simple single pole IIRs */
if (ec->adaption_mode & ECHO_CAN_DISABLE)
ec->clean_nlp = rx;
ec->Ltxacc += abs(tx) - ec->Ltx;
ec->Ltx = (ec->Ltxacc + (1 << 4)) >> 5;
ec->Lrxacc += abs(rx) - ec->Lrx;
ec->Lrx = (ec->Lrxacc + (1 << 4)) >> 5;
/* Output scaled back up again to match input scaling */
/* Foreground filter --------------------------------------------------- */
return (int16_t) ec->clean_nlp << 1;
ec->fir_state.coeffs = ec->fir_taps16[0];
echo_value = fir16(&ec->fir_state, tx);
ec->clean = rx - echo_value;
ec->Lcleanacc += abs(ec->clean) - ec->Lclean;
ec->Lclean = (ec->Lcleanacc + (1 << 4)) >> 5;
/* Background filter --------------------------------------------------- */
echo_value = fir16(&ec->fir_state_bg, tx);
clean_bg = rx - echo_value;
ec->Lclean_bgacc += abs(clean_bg) - ec->Lclean_bg;
ec->Lclean_bg = (ec->Lclean_bgacc + (1 << 4)) >> 5;
/* Background Filter adaption ----------------------------------------- */
/* Almost always adap bg filter, just simple DT and energy
detection to minimise adaption in cases of strong double talk.
However this is not critical for the dual path algorithm.
*/
ec->factor = 0;
ec->shift = 0;
if ((ec->nonupdate_dwell == 0)) {
int P, logP, shift;
/* Determine:
f = Beta * clean_bg_rx/P ------ (1)
where P is the total power in the filter states.
The Boffins have shown that if we obey (1) we converge
quickly and avoid instability.
The correct factor f must be in Q30, as this is the fixed
point format required by the lms_adapt_bg() function,
therefore the scaled version of (1) is:
(2^30) * f = (2^30) * Beta * clean_bg_rx/P
factor = (2^30) * Beta * clean_bg_rx/P ----- (2)
We have chosen Beta = 0.25 by experiment, so:
factor = (2^30) * (2^-2) * clean_bg_rx/P
(30 - 2 - log2(P))
factor = clean_bg_rx 2 ----- (3)
To avoid a divide we approximate log2(P) as top_bit(P),
which returns the position of the highest non-zero bit in
P. This approximation introduces an error as large as a
factor of 2, but the algorithm seems to handle it OK.
Come to think of it a divide may not be a big deal on a
modern DSP, so its probably worth checking out the cycles
for a divide versus a top_bit() implementation.
*/
P = MIN_TX_POWER_FOR_ADAPTION + ec->Pstates;
logP = top_bit(P) + ec->log2taps;
shift = 30 - 2 - logP;
ec->shift = shift;
lms_adapt_bg(ec, clean_bg, shift);
}
/* very simple DTD to make sure we dont try and adapt with strong
near end speech */
ec->adapt = 0;
if ((ec->Lrx > MIN_RX_POWER_FOR_ADAPTION) && (ec->Lrx > ec->Ltx))
ec->nonupdate_dwell = DTD_HANGOVER;
if (ec->nonupdate_dwell)
ec->nonupdate_dwell--;
/* Transfer logic ------------------------------------------------------ */
/* These conditions are from the dual path paper [1], I messed with
them a bit to improve performance. */
if ((ec->adaption_mode & ECHO_CAN_USE_ADAPTION) &&
(ec->nonupdate_dwell == 0) &&
(8 * ec->Lclean_bg <
7 * ec->Lclean) /* (ec->Lclean_bg < 0.875*ec->Lclean) */ &&
(8 * ec->Lclean_bg <
ec->Ltx) /* (ec->Lclean_bg < 0.125*ec->Ltx) */ ) {
if (ec->cond_met == 6) {
/* BG filter has had better results for 6 consecutive samples */
ec->adapt = 1;
memcpy(ec->fir_taps16[0], ec->fir_taps16[1],
ec->taps * sizeof(int16_t));
} else
ec->cond_met++;
} else
ec->cond_met = 0;
/* Non-Linear Processing --------------------------------------------------- */
ec->clean_nlp = ec->clean;
if (ec->adaption_mode & ECHO_CAN_USE_NLP) {
/* Non-linear processor - a fancy way to say "zap small signals, to avoid
residual echo due to (uLaw/ALaw) non-linearity in the channel.". */
if ((16 * ec->Lclean < ec->Ltx)) {
/* Our e/c has improved echo by at least 24 dB (each factor of 2 is 6dB,
so 2*2*2*2=16 is the same as 6+6+6+6=24dB) */
if (ec->adaption_mode & ECHO_CAN_USE_CNG) {
ec->cng_level = ec->Lbgn;
/* Very elementary comfort noise generation. Just random
numbers rolled off very vaguely Hoth-like. DR: This
noise doesn't sound quite right to me - I suspect there
are some overlfow issues in the filtering as it's too
"crackly". TODO: debug this, maybe just play noise at
high level or look at spectrum.
*/
ec->cng_rndnum =
1664525U * ec->cng_rndnum + 1013904223U;
ec->cng_filter =
((ec->cng_rndnum & 0xFFFF) - 32768 +
5 * ec->cng_filter) >> 3;
ec->clean_nlp =
(ec->cng_filter * ec->cng_level * 8) >> 14;
} else if (ec->adaption_mode & ECHO_CAN_USE_CLIP) {
/* This sounds much better than CNG */
if (ec->clean_nlp > ec->Lbgn)
ec->clean_nlp = ec->Lbgn;
if (ec->clean_nlp < -ec->Lbgn)
ec->clean_nlp = -ec->Lbgn;
} else {
/* just mute the residual, doesn't sound very good, used mainly
in G168 tests */
ec->clean_nlp = 0;
}
} else {
/* Background noise estimator. I tried a few algorithms
here without much luck. This very simple one seems to
work best, we just average the level using a slow (1 sec
time const) filter if the current level is less than a
(experimentally derived) constant. This means we dont
include high level signals like near end speech. When
combined with CNG or especially CLIP seems to work OK.
*/
if (ec->Lclean < 40) {
ec->Lbgn_acc += abs(ec->clean) - ec->Lbgn;
ec->Lbgn = (ec->Lbgn_acc + (1 << 11)) >> 12;
}
}
}
/* Roll around the taps buffer */
if (ec->curr_pos <= 0)
ec->curr_pos = ec->taps;
ec->curr_pos--;
if (ec->adaption_mode & ECHO_CAN_DISABLE)
ec->clean_nlp = rx;
/* Output scaled back up again to match input scaling */
return (int16_t) ec->clean_nlp << 1;
}
/*- End of function --------------------------------------------------------*/
EXPORT_SYMBOL_GPL(oslec_update);
/* This function is seperated from the echo canceller is it is usually called
as part of the tx process. See rx HP (DC blocking) filter above, it's
@ -608,25 +605,35 @@ int16_t echo_can_update(echo_can_state_t *ec, int16_t tx, int16_t rx)
precision, which noise shapes things, giving very clean DC removal.
*/
int16_t echo_can_hpf_tx(echo_can_state_t *ec, int16_t tx) {
int tmp, tmp1;
int16_t oslec_hpf_tx(struct oslec_state * ec, int16_t tx)
{
int tmp, tmp1;
if (ec->adaption_mode & ECHO_CAN_USE_TX_HPF) {
tmp = tx << 15;
if (ec->adaption_mode & ECHO_CAN_USE_TX_HPF) {
tmp = tx << 15;
#if 1
/* Make sure the gain of the HPF is 1.0. The first can still saturate a little under
impulse conditions, and it might roll to 32768 and need clipping on sustained peak
level signals. However, the scale of such clipping is small, and the error due to
any saturation should not markedly affect the downstream processing. */
tmp -= (tmp >> 4);
/* Make sure the gain of the HPF is 1.0. The first can still saturate a little under
impulse conditions, and it might roll to 32768 and need clipping on sustained peak
level signals. However, the scale of such clipping is small, and the error due to
any saturation should not markedly affect the downstream processing. */
tmp -= (tmp >> 4);
#endif
ec->tx_1 += -(ec->tx_1>>DC_LOG2BETA) + tmp - ec->tx_2;
tmp1 = ec->tx_1 >> 15;
if (tmp1 > 32767) tmp1 = 32767;
if (tmp1 < -32767) tmp1 = -32767;
tx = tmp1;
ec->tx_2 = tmp;
}
ec->tx_1 += -(ec->tx_1 >> DC_LOG2BETA) + tmp - ec->tx_2;
tmp1 = ec->tx_1 >> 15;
if (tmp1 > 32767)
tmp1 = 32767;
if (tmp1 < -32767)
tmp1 = -32767;
tx = tmp1;
ec->tx_2 = tmp;
}
return tx;
return tx;
}
EXPORT_SYMBOL_GPL(oslec_hpf_tx);
MODULE_LICENSE("GPL");
MODULE_AUTHOR("David Rowe");
MODULE_DESCRIPTION("Open Source Line Echo Canceller");
MODULE_VERSION("0.3.0");

Просмотреть файл

@ -118,23 +118,14 @@ a minor burden.
*/
#include "fir.h"
/* Mask bits for the adaption mode */
#define ECHO_CAN_USE_ADAPTION 0x01
#define ECHO_CAN_USE_NLP 0x02
#define ECHO_CAN_USE_CNG 0x04
#define ECHO_CAN_USE_CLIP 0x08
#define ECHO_CAN_USE_TX_HPF 0x10
#define ECHO_CAN_USE_RX_HPF 0x20
#define ECHO_CAN_DISABLE 0x40
#include "oslec.h"
/*!
G.168 echo canceller descriptor. This defines the working state for a line
echo canceller.
*/
typedef struct
{
int16_t tx,rx;
struct oslec_state {
int16_t tx, rx;
int16_t clean;
int16_t clean_nlp;
@ -176,45 +167,6 @@ typedef struct
/* snapshot sample of coeffs used for development */
int16_t *snapshot;
} echo_can_state_t;
};
/*! Create a voice echo canceller context.
\param len The length of the canceller, in samples.
\return The new canceller context, or NULL if the canceller could not be created.
*/
echo_can_state_t *echo_can_create(int len, int adaption_mode);
/*! Free a voice echo canceller context.
\param ec The echo canceller context.
*/
void echo_can_free(echo_can_state_t *ec);
/*! Flush (reinitialise) a voice echo canceller context.
\param ec The echo canceller context.
*/
void echo_can_flush(echo_can_state_t *ec);
/*! Set the adaption mode of a voice echo canceller context.
\param ec The echo canceller context.
\param adapt The mode.
*/
void echo_can_adaption_mode(echo_can_state_t *ec, int adaption_mode);
void echo_can_snapshot(echo_can_state_t *ec);
/*! Process a sample through a voice echo canceller.
\param ec The echo canceller context.
\param tx The transmitted audio sample.
\param rx The received audio sample.
\return The clean (echo cancelled) received sample.
*/
int16_t echo_can_update(echo_can_state_t *ec, int16_t tx, int16_t rx);
/*! Process to high pass filter the tx signal.
\param ec The echo canceller context.
\param tx The transmitted auio sample.
\return The HP filtered transmit sample, send this to your D/A.
*/
int16_t echo_can_hpf_tx(echo_can_state_t *ec, int16_t tx);
#endif /* __ECHO_H */
#endif /* __ECHO_H */

Просмотреть файл

@ -72,8 +72,7 @@
16 bit integer FIR descriptor. This defines the working state for a single
instance of an FIR filter using 16 bit integer coefficients.
*/
typedef struct
{
typedef struct {
int taps;
int curr_pos;
const int16_t *coeffs;
@ -85,8 +84,7 @@ typedef struct
instance of an FIR filter using 32 bit integer coefficients, and filtering
16 bit integer data.
*/
typedef struct
{
typedef struct {
int taps;
int curr_pos;
const int32_t *coeffs;
@ -97,273 +95,201 @@ typedef struct
Floating point FIR descriptor. This defines the working state for a single
instance of an FIR filter using floating point coefficients and data.
*/
typedef struct
{
typedef struct {
int taps;
int curr_pos;
const float *coeffs;
float *history;
} fir_float_state_t;
#ifdef __cplusplus
extern "C" {
#endif
static __inline__ const int16_t *fir16_create(fir16_state_t *fir,
const int16_t *coeffs,
int taps)
static __inline__ const int16_t *fir16_create(fir16_state_t * fir,
const int16_t * coeffs, int taps)
{
fir->taps = taps;
fir->curr_pos = taps - 1;
fir->coeffs = coeffs;
#if defined(USE_MMX) || defined(USE_SSE2) || defined(__BLACKFIN_ASM__)
if ((fir->history = malloc(2*taps*sizeof(int16_t))))
memset(fir->history, 0, 2*taps*sizeof(int16_t));
#if defined(USE_MMX) || defined(USE_SSE2) || defined(__bfin__)
fir->history = kcalloc(2 * taps, sizeof(int16_t), GFP_KERNEL);
#else
if ((fir->history = (int16_t *) malloc(taps*sizeof(int16_t))))
memset(fir->history, 0, taps*sizeof(int16_t));
fir->history = kcalloc(taps, sizeof(int16_t), GFP_KERNEL);
#endif
return fir->history;
}
/*- End of function --------------------------------------------------------*/
static __inline__ void fir16_flush(fir16_state_t *fir)
static __inline__ void fir16_flush(fir16_state_t * fir)
{
#if defined(USE_MMX) || defined(USE_SSE2) || defined(__BLACKFIN_ASM__)
memset(fir->history, 0, 2*fir->taps*sizeof(int16_t));
#if defined(USE_MMX) || defined(USE_SSE2) || defined(__bfin__)
memset(fir->history, 0, 2 * fir->taps * sizeof(int16_t));
#else
memset(fir->history, 0, fir->taps*sizeof(int16_t));
memset(fir->history, 0, fir->taps * sizeof(int16_t));
#endif
}
/*- End of function --------------------------------------------------------*/
static __inline__ void fir16_free(fir16_state_t *fir)
static __inline__ void fir16_free(fir16_state_t * fir)
{
free(fir->history);
kfree(fir->history);
}
/*- End of function --------------------------------------------------------*/
#ifdef __BLACKFIN_ASM__
#ifdef __bfin__
static inline int32_t dot_asm(short *x, short *y, int len)
{
int dot;
int dot;
len--;
len--;
__asm__
(
"I0 = %1;\n\t"
"I1 = %2;\n\t"
"A0 = 0;\n\t"
"R0.L = W[I0++] || R1.L = W[I1++];\n\t"
"LOOP dot%= LC0 = %3;\n\t"
"LOOP_BEGIN dot%=;\n\t"
"A0 += R0.L * R1.L (IS) || R0.L = W[I0++] || R1.L = W[I1++];\n\t"
"LOOP_END dot%=;\n\t"
"A0 += R0.L*R1.L (IS);\n\t"
"R0 = A0;\n\t"
"%0 = R0;\n\t"
: "=&d" (dot)
: "a" (x), "a" (y), "a" (len)
: "I0", "I1", "A1", "A0", "R0", "R1"
);
__asm__("I0 = %1;\n\t"
"I1 = %2;\n\t"
"A0 = 0;\n\t"
"R0.L = W[I0++] || R1.L = W[I1++];\n\t"
"LOOP dot%= LC0 = %3;\n\t"
"LOOP_BEGIN dot%=;\n\t"
"A0 += R0.L * R1.L (IS) || R0.L = W[I0++] || R1.L = W[I1++];\n\t"
"LOOP_END dot%=;\n\t"
"A0 += R0.L*R1.L (IS);\n\t"
"R0 = A0;\n\t"
"%0 = R0;\n\t"
:"=&d"(dot)
:"a"(x), "a"(y), "a"(len)
:"I0", "I1", "A1", "A0", "R0", "R1"
);
return dot;
return dot;
}
#endif
/*- End of function --------------------------------------------------------*/
static __inline__ int16_t fir16(fir16_state_t *fir, int16_t sample)
static __inline__ int16_t fir16(fir16_state_t * fir, int16_t sample)
{
int32_t y;
int32_t y;
#if defined(USE_MMX)
int i;
mmx_t *mmx_coeffs;
mmx_t *mmx_hist;
int i;
mmx_t *mmx_coeffs;
mmx_t *mmx_hist;
fir->history[fir->curr_pos] = sample;
fir->history[fir->curr_pos + fir->taps] = sample;
fir->history[fir->curr_pos] = sample;
fir->history[fir->curr_pos + fir->taps] = sample;
mmx_coeffs = (mmx_t *) fir->coeffs;
mmx_hist = (mmx_t *) &fir->history[fir->curr_pos];
i = fir->taps;
pxor_r2r(mm4, mm4);
/* 8 samples per iteration, so the filter must be a multiple of 8 long. */
while (i > 0)
{
movq_m2r(mmx_coeffs[0], mm0);
movq_m2r(mmx_coeffs[1], mm2);
movq_m2r(mmx_hist[0], mm1);
movq_m2r(mmx_hist[1], mm3);
mmx_coeffs += 2;
mmx_hist += 2;
pmaddwd_r2r(mm1, mm0);
pmaddwd_r2r(mm3, mm2);
paddd_r2r(mm0, mm4);
paddd_r2r(mm2, mm4);
i -= 8;
}
movq_r2r(mm4, mm0);
psrlq_i2r(32, mm0);
paddd_r2r(mm0, mm4);
movd_r2m(mm4, y);
emms();
mmx_coeffs = (mmx_t *) fir->coeffs;
mmx_hist = (mmx_t *) & fir->history[fir->curr_pos];
i = fir->taps;
pxor_r2r(mm4, mm4);
/* 8 samples per iteration, so the filter must be a multiple of 8 long. */
while (i > 0) {
movq_m2r(mmx_coeffs[0], mm0);
movq_m2r(mmx_coeffs[1], mm2);
movq_m2r(mmx_hist[0], mm1);
movq_m2r(mmx_hist[1], mm3);
mmx_coeffs += 2;
mmx_hist += 2;
pmaddwd_r2r(mm1, mm0);
pmaddwd_r2r(mm3, mm2);
paddd_r2r(mm0, mm4);
paddd_r2r(mm2, mm4);
i -= 8;
}
movq_r2r(mm4, mm0);
psrlq_i2r(32, mm0);
paddd_r2r(mm0, mm4);
movd_r2m(mm4, y);
emms();
#elif defined(USE_SSE2)
int i;
xmm_t *xmm_coeffs;
xmm_t *xmm_hist;
int i;
xmm_t *xmm_coeffs;
xmm_t *xmm_hist;
fir->history[fir->curr_pos] = sample;
fir->history[fir->curr_pos + fir->taps] = sample;
fir->history[fir->curr_pos] = sample;
fir->history[fir->curr_pos + fir->taps] = sample;
xmm_coeffs = (xmm_t *) fir->coeffs;
xmm_hist = (xmm_t *) &fir->history[fir->curr_pos];
i = fir->taps;
pxor_r2r(xmm4, xmm4);
/* 16 samples per iteration, so the filter must be a multiple of 16 long. */
while (i > 0)
{
movdqu_m2r(xmm_coeffs[0], xmm0);
movdqu_m2r(xmm_coeffs[1], xmm2);
movdqu_m2r(xmm_hist[0], xmm1);
movdqu_m2r(xmm_hist[1], xmm3);
xmm_coeffs += 2;
xmm_hist += 2;
pmaddwd_r2r(xmm1, xmm0);
pmaddwd_r2r(xmm3, xmm2);
paddd_r2r(xmm0, xmm4);
paddd_r2r(xmm2, xmm4);
i -= 16;
}
movdqa_r2r(xmm4, xmm0);
psrldq_i2r(8, xmm0);
paddd_r2r(xmm0, xmm4);
movdqa_r2r(xmm4, xmm0);
psrldq_i2r(4, xmm0);
paddd_r2r(xmm0, xmm4);
movd_r2m(xmm4, y);
#elif defined(__BLACKFIN_ASM__)
fir->history[fir->curr_pos] = sample;
fir->history[fir->curr_pos + fir->taps] = sample;
y = dot_asm((int16_t*)fir->coeffs, &fir->history[fir->curr_pos], fir->taps);
xmm_coeffs = (xmm_t *) fir->coeffs;
xmm_hist = (xmm_t *) & fir->history[fir->curr_pos];
i = fir->taps;
pxor_r2r(xmm4, xmm4);
/* 16 samples per iteration, so the filter must be a multiple of 16 long. */
while (i > 0) {
movdqu_m2r(xmm_coeffs[0], xmm0);
movdqu_m2r(xmm_coeffs[1], xmm2);
movdqu_m2r(xmm_hist[0], xmm1);
movdqu_m2r(xmm_hist[1], xmm3);
xmm_coeffs += 2;
xmm_hist += 2;
pmaddwd_r2r(xmm1, xmm0);
pmaddwd_r2r(xmm3, xmm2);
paddd_r2r(xmm0, xmm4);
paddd_r2r(xmm2, xmm4);
i -= 16;
}
movdqa_r2r(xmm4, xmm0);
psrldq_i2r(8, xmm0);
paddd_r2r(xmm0, xmm4);
movdqa_r2r(xmm4, xmm0);
psrldq_i2r(4, xmm0);
paddd_r2r(xmm0, xmm4);
movd_r2m(xmm4, y);
#elif defined(__bfin__)
fir->history[fir->curr_pos] = sample;
fir->history[fir->curr_pos + fir->taps] = sample;
y = dot_asm((int16_t *) fir->coeffs, &fir->history[fir->curr_pos],
fir->taps);
#else
int i;
int offset1;
int offset2;
int i;
int offset1;
int offset2;
fir->history[fir->curr_pos] = sample;
fir->history[fir->curr_pos] = sample;
offset2 = fir->curr_pos;
offset1 = fir->taps - offset2;
y = 0;
for (i = fir->taps - 1; i >= offset1; i--)
y += fir->coeffs[i]*fir->history[i - offset1];
for ( ; i >= 0; i--)
y += fir->coeffs[i]*fir->history[i + offset2];
offset2 = fir->curr_pos;
offset1 = fir->taps - offset2;
y = 0;
for (i = fir->taps - 1; i >= offset1; i--)
y += fir->coeffs[i] * fir->history[i - offset1];
for (; i >= 0; i--)
y += fir->coeffs[i] * fir->history[i + offset2];
#endif
if (fir->curr_pos <= 0)
fir->curr_pos = fir->taps;
fir->curr_pos--;
return (int16_t) (y >> 15);
if (fir->curr_pos <= 0)
fir->curr_pos = fir->taps;
fir->curr_pos--;
return (int16_t) (y >> 15);
}
/*- End of function --------------------------------------------------------*/
static __inline__ const int16_t *fir32_create(fir32_state_t *fir,
const int32_t *coeffs,
int taps)
static __inline__ const int16_t *fir32_create(fir32_state_t * fir,
const int32_t * coeffs, int taps)
{
fir->taps = taps;
fir->curr_pos = taps - 1;
fir->coeffs = coeffs;
fir->history = (int16_t *) malloc(taps*sizeof(int16_t));
if (fir->history)
memset(fir->history, '\0', taps*sizeof(int16_t));
return fir->history;
fir->taps = taps;
fir->curr_pos = taps - 1;
fir->coeffs = coeffs;
fir->history = kcalloc(taps, sizeof(int16_t), GFP_KERNEL);
return fir->history;
}
/*- End of function --------------------------------------------------------*/
static __inline__ void fir32_flush(fir32_state_t *fir)
static __inline__ void fir32_flush(fir32_state_t * fir)
{
memset(fir->history, 0, fir->taps*sizeof(int16_t));
memset(fir->history, 0, fir->taps * sizeof(int16_t));
}
/*- End of function --------------------------------------------------------*/
static __inline__ void fir32_free(fir32_state_t *fir)
static __inline__ void fir32_free(fir32_state_t * fir)
{
free(fir->history);
kfree(fir->history);
}
/*- End of function --------------------------------------------------------*/
static __inline__ int16_t fir32(fir32_state_t *fir, int16_t sample)
static __inline__ int16_t fir32(fir32_state_t * fir, int16_t sample)
{
int i;
int32_t y;
int offset1;
int offset2;
int i;
int32_t y;
int offset1;
int offset2;
fir->history[fir->curr_pos] = sample;
offset2 = fir->curr_pos;
offset1 = fir->taps - offset2;
y = 0;
for (i = fir->taps - 1; i >= offset1; i--)
y += fir->coeffs[i]*fir->history[i - offset1];
for ( ; i >= 0; i--)
y += fir->coeffs[i]*fir->history[i + offset2];
if (fir->curr_pos <= 0)
fir->curr_pos = fir->taps;
fir->curr_pos--;
return (int16_t) (y >> 15);
fir->history[fir->curr_pos] = sample;
offset2 = fir->curr_pos;
offset1 = fir->taps - offset2;
y = 0;
for (i = fir->taps - 1; i >= offset1; i--)
y += fir->coeffs[i] * fir->history[i - offset1];
for (; i >= 0; i--)
y += fir->coeffs[i] * fir->history[i + offset2];
if (fir->curr_pos <= 0)
fir->curr_pos = fir->taps;
fir->curr_pos--;
return (int16_t) (y >> 15);
}
/*- End of function --------------------------------------------------------*/
#ifndef __KERNEL__
static __inline__ const float *fir_float_create(fir_float_state_t *fir,
const float *coeffs,
int taps)
{
fir->taps = taps;
fir->curr_pos = taps - 1;
fir->coeffs = coeffs;
fir->history = (float *) malloc(taps*sizeof(float));
if (fir->history)
memset(fir->history, '\0', taps*sizeof(float));
return fir->history;
}
/*- End of function --------------------------------------------------------*/
static __inline__ void fir_float_free(fir_float_state_t *fir)
{
free(fir->history);
}
/*- End of function --------------------------------------------------------*/
static __inline__ int16_t fir_float(fir_float_state_t *fir, int16_t sample)
{
int i;
float y;
int offset1;
int offset2;
fir->history[fir->curr_pos] = sample;
offset2 = fir->curr_pos;
offset1 = fir->taps - offset2;
y = 0;
for (i = fir->taps - 1; i >= offset1; i--)
y += fir->coeffs[i]*fir->history[i - offset1];
for ( ; i >= 0; i--)
y += fir->coeffs[i]*fir->history[i + offset2];
if (fir->curr_pos <= 0)
fir->curr_pos = fir->taps;
fir->curr_pos--;
return (int16_t) y;
}
/*- End of function --------------------------------------------------------*/
#endif
#ifdef __cplusplus
}
#endif
#endif
/*- End of file ------------------------------------------------------------*/

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@ -27,24 +27,23 @@
* values by ULL, lest they be truncated by the compiler)
*/
typedef union {
long long q; /* Quadword (64-bit) value */
unsigned long long uq; /* Unsigned Quadword */
int d[2]; /* 2 Doubleword (32-bit) values */
unsigned int ud[2]; /* 2 Unsigned Doubleword */
short w[4]; /* 4 Word (16-bit) values */
unsigned short uw[4]; /* 4 Unsigned Word */
char b[8]; /* 8 Byte (8-bit) values */
unsigned char ub[8]; /* 8 Unsigned Byte */
float s[2]; /* Single-precision (32-bit) value */
} mmx_t; /* On an 8-byte (64-bit) boundary */
typedef union {
long long q; /* Quadword (64-bit) value */
unsigned long long uq; /* Unsigned Quadword */
int d[2]; /* 2 Doubleword (32-bit) values */
unsigned int ud[2]; /* 2 Unsigned Doubleword */
short w[4]; /* 4 Word (16-bit) values */
unsigned short uw[4]; /* 4 Unsigned Word */
char b[8]; /* 8 Byte (8-bit) values */
unsigned char ub[8]; /* 8 Unsigned Byte */
float s[2]; /* Single-precision (32-bit) value */
} mmx_t; /* On an 8-byte (64-bit) boundary */
/* SSE registers */
typedef union {
char b[16];
} xmm_t;
#define mmx_i2r(op,imm,reg) \
__asm__ __volatile__ (#op " %0, %%" #reg \
: /* nothing */ \
@ -63,7 +62,6 @@ typedef union {
#define mmx_r2r(op,regs,regd) \
__asm__ __volatile__ (#op " %" #regs ", %" #regd)
#define emms() __asm__ __volatile__ ("emms")
#define movd_m2r(var,reg) mmx_m2r (movd, var, reg)
@ -192,16 +190,13 @@ typedef union {
#define pxor_m2r(var,reg) mmx_m2r (pxor, var, reg)
#define pxor_r2r(regs,regd) mmx_r2r (pxor, regs, regd)
/* 3DNOW extensions */
#define pavgusb_m2r(var,reg) mmx_m2r (pavgusb, var, reg)
#define pavgusb_r2r(regs,regd) mmx_r2r (pavgusb, regs, regd)
/* AMD MMX extensions - also available in intel SSE */
#define mmx_m2ri(op,mem,reg,imm) \
__asm__ __volatile__ (#op " %1, %0, %%" #reg \
: /* nothing */ \
@ -216,7 +211,6 @@ typedef union {
: /* nothing */ \
: "m" (mem))
#define maskmovq(regs,maskreg) mmx_r2ri (maskmovq, regs, maskreg)
#define movntq_r2m(mmreg,var) mmx_r2m (movntq, mmreg, var)
@ -284,5 +278,4 @@ typedef union {
#define punpcklqdq_r2r(regs,regd) mmx_r2r (punpcklqdq, regs, regd)
#define punpckhqdq_r2r(regs,regd) mmx_r2r (punpckhqdq, regs, regd)
#endif /* AVCODEC_I386MMX_H */

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@ -0,0 +1,86 @@
/*
* OSLEC - A line echo canceller. This code is being developed
* against and partially complies with G168. Using code from SpanDSP
*
* Written by Steve Underwood <steveu@coppice.org>
* and David Rowe <david_at_rowetel_dot_com>
*
* Copyright (C) 2001 Steve Underwood and 2007-2008 David Rowe
*
* All rights reserved.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License version 2, as
* published by the Free Software Foundation.
*
* 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.
*
* 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., 675 Mass Ave, Cambridge, MA 02139, USA.
*
*/
#ifndef __OSLEC_H
#define __OSLEC_H
/* TODO: document interface */
/* Mask bits for the adaption mode */
#define ECHO_CAN_USE_ADAPTION 0x01
#define ECHO_CAN_USE_NLP 0x02
#define ECHO_CAN_USE_CNG 0x04
#define ECHO_CAN_USE_CLIP 0x08
#define ECHO_CAN_USE_TX_HPF 0x10
#define ECHO_CAN_USE_RX_HPF 0x20
#define ECHO_CAN_DISABLE 0x40
/*!
G.168 echo canceller descriptor. This defines the working state for a line
echo canceller.
*/
struct oslec_state;
/*! Create a voice echo canceller context.
\param len The length of the canceller, in samples.
\return The new canceller context, or NULL if the canceller could not be created.
*/
struct oslec_state *oslec_create(int len, int adaption_mode);
/*! Free a voice echo canceller context.
\param ec The echo canceller context.
*/
void oslec_free(struct oslec_state *ec);
/*! Flush (reinitialise) a voice echo canceller context.
\param ec The echo canceller context.
*/
void oslec_flush(struct oslec_state *ec);
/*! Set the adaption mode of a voice echo canceller context.
\param ec The echo canceller context.
\param adapt The mode.
*/
void oslec_adaption_mode(struct oslec_state *ec, int adaption_mode);
void oslec_snapshot(struct oslec_state *ec);
/*! Process a sample through a voice echo canceller.
\param ec The echo canceller context.
\param tx The transmitted audio sample.
\param rx The received audio sample.
\return The clean (echo cancelled) received sample.
*/
int16_t oslec_update(struct oslec_state *ec, int16_t tx, int16_t rx);
/*! Process to high pass filter the tx signal.
\param ec The echo canceller context.
\param tx The transmitted auio sample.
\return The HP filtered transmit sample, send this to your D/A.
*/
int16_t oslec_hpf_tx(struct oslec_state *ec, int16_t tx);
#endif /* __OSLEC_H */

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@ -84,7 +84,6 @@
#include <linux/if_arp.h>
#include <linux/ioport.h>
#include <linux/random.h>
#include <linux/delay.h>
#include "et1310_phy.h"
#include "et1310_pm.h"
@ -95,7 +94,6 @@
#include "et131x_initpci.h"
#include "et1310_address_map.h"
#include "et1310_jagcore.h"
#include "et1310_tx.h"
#include "et1310_rx.h"
#include "et1310_mac.h"

Просмотреть файл

@ -97,7 +97,6 @@
#include "et131x_isr.h"
#include "et1310_address_map.h"
#include "et1310_jagcore.h"
#include "et1310_tx.h"
#include "et1310_rx.h"
#include "et1310_mac.h"

Просмотреть файл

@ -97,7 +97,6 @@
#include "et131x_isr.h"
#include "et1310_address_map.h"
#include "et1310_jagcore.h"
#include "et1310_tx.h"
#include "et1310_rx.h"
#include "et1310_mac.h"

Просмотреть файл

@ -16,7 +16,6 @@
*/
#include <linux/module.h>
#include <linux/version.h>
#include <linux/init.h>
#include <linux/delay.h>
#include <linux/sched.h>

Просмотреть файл

@ -26,7 +26,6 @@
#include <linux/module.h>
#include <linux/init.h>
#include <linux/version.h>
#include <linux/time.h>
#include <linux/mm.h>
#include <linux/device.h>

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@ -15,7 +15,6 @@
* Inc., 59 Temple Place - Suite 330, Boston MA 02111-1307, USA.
*/
#include <linux/version.h>
#include <linux/module.h>
#include <linux/init.h>
#include <linux/delay.h>

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@ -16,7 +16,6 @@
*/
#include <linux/module.h>
#include <linux/version.h>
#include <linux/kernel.h>
#include <linux/init.h>
#include <linux/wait.h>

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@ -17,7 +17,6 @@
#include <linux/kernel.h>
#include <linux/module.h>
#include <linux/version.h>
#include <linux/moduleparam.h>
#include <linux/init.h>
#include <linux/spinlock.h>

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@ -17,7 +17,6 @@
#include <linux/module.h>
#include <linux/init.h>
#include <linux/version.h>
#include <linux/i2c.h>
#include <linux/videodev2.h>

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@ -17,7 +17,6 @@
#include <linux/module.h>
#include <linux/init.h>
#include <linux/version.h>
#include <linux/i2c.h>
#include <linux/videodev2.h>
#include <linux/ioctl.h>

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@ -17,7 +17,6 @@
#include <linux/module.h>
#include <linux/init.h>
#include <linux/version.h>
#include <linux/i2c.h>
#include <linux/videodev2.h>
#include <linux/ioctl.h>

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@ -17,7 +17,6 @@
#include <linux/module.h>
#include <linux/init.h>
#include <linux/version.h>
#include <linux/i2c.h>
#include <linux/videodev2.h>
#include <media/tuner.h>

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@ -17,7 +17,6 @@
#include <linux/module.h>
#include <linux/init.h>
#include <linux/version.h>
#include <linux/i2c.h>
#include <linux/videodev2.h>
#include <linux/ioctl.h>

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@ -17,7 +17,6 @@
#include <linux/module.h>
#include <linux/init.h>
#include <linux/version.h>
#include <linux/i2c.h>
#include <linux/videodev2.h>
#include <linux/ioctl.h>

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@ -17,7 +17,6 @@
#include <linux/module.h>
#include <linux/init.h>
#include <linux/version.h>
#include <linux/i2c.h>
#include <linux/videodev2.h>
#include <media/tvaudio.h>

Разница между файлами не показана из-за своего большого размера Загрузить разницу

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@ -329,46 +329,46 @@
Circular buffer used for analog input/output reads/writes.
===========================================================================*/
typedef struct me4000_circ_buf {
struct me4000_circ_buf {
s16 *buf;
int volatile head;
int volatile tail;
} me4000_circ_buf_t;
};
/*=============================================================================
Information about the hardware capabilities
===========================================================================*/
typedef struct me4000_ao_info {
struct me4000_ao_info {
int count;
int fifo_count;
} me4000_ao_info_t;
};
typedef struct me4000_ai_info {
struct me4000_ai_info {
int count;
int sh_count;
int diff_count;
int ex_trig_analog;
} me4000_ai_info_t;
};
typedef struct me4000_dio_info {
struct me4000_dio_info {
int count;
} me4000_dio_info_t;
};
typedef struct me4000_cnt_info {
struct me4000_cnt_info {
int count;
} me4000_cnt_info_t;
};
typedef struct me4000_board {
struct me4000_board {
u16 vendor_id;
u16 device_id;
me4000_ao_info_t ao;
me4000_ai_info_t ai;
me4000_dio_info_t dio;
me4000_cnt_info_t cnt;
} me4000_board_t;
struct me4000_ao_info ao;
struct me4000_ai_info ai;
struct me4000_dio_info dio;
struct me4000_cnt_info cnt;
};
static me4000_board_t me4000_boards[] = {
static struct me4000_board me4000_boards[] = {
{PCI_VENDOR_ID_MEILHAUS, 0x4610, {0, 0}, {16, 0, 0, 0}, {4}, {3}},
{PCI_VENDOR_ID_MEILHAUS, 0x4650, {0, 0}, {16, 0, 0, 0}, {4}, {0}},
@ -391,8 +391,6 @@ static me4000_board_t me4000_boards[] = {
{0},
};
#define ME4000_BOARD_VERSIONS (sizeof(me4000_boards) / sizeof(me4000_board_t) - 1)
/*=============================================================================
PCI device table.
This is used by modprobe to translate PCI IDs to drivers.
@ -427,19 +425,19 @@ MODULE_DEVICE_TABLE(pci, me4000_pci_table);
Global board and subdevice information structures
===========================================================================*/
typedef struct me4000_info {
struct me4000_info {
struct list_head list; // List of all detected boards
int board_count; // Index of the board after detection
unsigned long plx_regbase; // PLX configuration space base address
unsigned long me4000_regbase; // Base address of the ME4000
unsigned long timer_regbase; // Base address of the timer circuit
unsigned long program_regbase; // Base address to set the program pin for the xilinx
resource_size_t me4000_regbase; // Base address of the ME4000
resource_size_t timer_regbase; // Base address of the timer circuit
resource_size_t program_regbase; // Base address to set the program pin for the xilinx
unsigned long plx_regbase_size; // PLX register set space
unsigned long me4000_regbase_size; // ME4000 register set space
unsigned long timer_regbase_size; // Timer circuit register set space
unsigned long program_regbase_size; // Size of program base address of the ME4000
resource_size_t me4000_regbase_size; // ME4000 register set space
resource_size_t timer_regbase_size; // Timer circuit register set space
resource_size_t program_regbase_size; // Size of program base address of the ME4000
unsigned int serial_no; // Serial number of the board
unsigned char hw_revision; // Hardware revision of the board
@ -451,7 +449,7 @@ typedef struct me4000_info {
int pci_func_no; // PCI function number
struct pci_dev *pci_dev_p; // General PCI information
me4000_board_t *board_p; // Holds the board capabilities
struct me4000_board *board_p; // Holds the board capabilities
unsigned int irq; // IRQ assigned from the PCI BIOS
unsigned int irq_count; // Count of external interrupts
@ -464,18 +462,18 @@ typedef struct me4000_info {
struct me4000_dio_context *dio_context; // Digital I/O specific context
struct me4000_cnt_context *cnt_context; // Counter specific context
struct me4000_ext_int_context *ext_int_context; // External interrupt specific context
} me4000_info_t;
};
typedef struct me4000_ao_context {
struct me4000_ao_context {
struct list_head list; // linked list of me4000_ao_context_t
int index; // Index in the list
int mode; // Indicates mode (0 = single, 1 = wraparound, 2 = continous)
int dac_in_use; // Indicates if already opend
spinlock_t use_lock; // Guards in_use
spinlock_t int_lock; // Used when locking out interrupts
me4000_circ_buf_t circ_buf; // Circular buffer
struct me4000_circ_buf circ_buf; // Circular buffer
wait_queue_head_t wait_queue; // Wait queue to sleep while blocking write
me4000_info_t *board_info;
struct me4000_info *board_info;
unsigned int irq; // The irq associated with this ADC
int volatile pipe_flag; // Indicates broken pipe set from me4000_ao_isr()
unsigned long ctrl_reg;
@ -486,9 +484,9 @@ typedef struct me4000_ao_context {
unsigned long irq_status_reg;
unsigned long preload_reg;
struct fasync_struct *fasync_p; // Queue for asynchronous notification
} me4000_ao_context_t;
};
typedef struct me4000_ai_context {
struct me4000_ai_context {
struct list_head list; // linked list of me4000_ai_info_t
int mode; // Indicates mode
int in_use; // Indicates if already opend
@ -496,9 +494,9 @@ typedef struct me4000_ai_context {
spinlock_t int_lock; // Used when locking out interrupts
int number; // Number of the DAC
unsigned int irq; // The irq associated with this ADC
me4000_circ_buf_t circ_buf; // Circular buffer
struct me4000_circ_buf circ_buf; // Circular buffer
wait_queue_head_t wait_queue; // Wait queue to sleep while blocking read
me4000_info_t *board_info;
struct me4000_info *board_info;
struct fasync_struct *fasync_p; // Queue for asynchronous notification
@ -523,48 +521,48 @@ typedef struct me4000_ai_context {
unsigned long channel_list_count;
unsigned long sample_counter;
int sample_counter_reload;
} me4000_ai_context_t;
};
typedef struct me4000_dio_context {
struct me4000_dio_context {
struct list_head list; // linked list of me4000_dio_context_t
int in_use; // Indicates if already opend
spinlock_t use_lock; // Guards in_use
int number;
int dio_count;
me4000_info_t *board_info;
struct me4000_info *board_info;
unsigned long dir_reg;
unsigned long ctrl_reg;
unsigned long port_0_reg;
unsigned long port_1_reg;
unsigned long port_2_reg;
unsigned long port_3_reg;
} me4000_dio_context_t;
};
typedef struct me4000_cnt_context {
struct me4000_cnt_context {
struct list_head list; // linked list of me4000_dio_context_t
int in_use; // Indicates if already opend
spinlock_t use_lock; // Guards in_use
int number;
int cnt_count;
me4000_info_t *board_info;
struct me4000_info *board_info;
unsigned long ctrl_reg;
unsigned long counter_0_reg;
unsigned long counter_1_reg;
unsigned long counter_2_reg;
} me4000_cnt_context_t;
};
typedef struct me4000_ext_int_context {
struct me4000_ext_int_context {
struct list_head list; // linked list of me4000_dio_context_t
int in_use; // Indicates if already opend
spinlock_t use_lock; // Guards in_use
int number;
me4000_info_t *board_info;
struct me4000_info *board_info;
unsigned int irq;
unsigned long int_count;
struct fasync_struct *fasync_ptr;
unsigned long ctrl_reg;
unsigned long irq_status_reg;
} me4000_ext_int_context_t;
};
#endif
@ -745,12 +743,12 @@ typedef struct me4000_ext_int_context {
General type definitions
----------------------------------------------------------------------------*/
typedef struct me4000_user_info {
struct me4000_user_info {
int board_count; // Index of the board after detection
unsigned long plx_regbase; // PLX configuration space base address
unsigned long me4000_regbase; // Base address of the ME4000
resource_size_t me4000_regbase; // Base address of the ME4000
unsigned long plx_regbase_size; // PLX register set space
unsigned long me4000_regbase_size; // ME4000 register set space
resource_size_t me4000_regbase_size; // ME4000 register set space
unsigned long serial_no; // Serial number of the board
unsigned char hw_revision; // Hardware revision of the board
unsigned short vendor_id; // Meilhaus vendor id (0x1402)
@ -773,62 +771,62 @@ typedef struct me4000_user_info {
int dio_count; // Count of digital I/O ports
int cnt_count; // Count of counters
} me4000_user_info_t;
};
/*-----------------------------------------------------------------------------
Type definitions for analog output
----------------------------------------------------------------------------*/
typedef struct me4000_ao_channel_list {
struct me4000_ao_channel_list {
unsigned long count;
unsigned long *list;
} me4000_ao_channel_list_t;
};
/*-----------------------------------------------------------------------------
Type definitions for analog input
----------------------------------------------------------------------------*/
typedef struct me4000_ai_channel_list {
struct me4000_ai_channel_list {
unsigned long count;
unsigned long *list;
} me4000_ai_channel_list_t;
};
typedef struct me4000_ai_timer {
struct me4000_ai_timer {
unsigned long pre_chan;
unsigned long chan;
unsigned long scan_low;
unsigned long scan_high;
} me4000_ai_timer_t;
};
typedef struct me4000_ai_config {
me4000_ai_timer_t timer;
me4000_ai_channel_list_t channel_list;
struct me4000_ai_config {
struct me4000_ai_timer timer;
struct me4000_ai_channel_list channel_list;
int sh;
} me4000_ai_config_t;
};
typedef struct me4000_ai_single {
struct me4000_ai_single {
int channel;
int range;
int mode;
short value;
unsigned long timeout;
} me4000_ai_single_t;
};
typedef struct me4000_ai_trigger {
struct me4000_ai_trigger {
int mode;
int edge;
} me4000_ai_trigger_t;
};
typedef struct me4000_ai_sc {
struct me4000_ai_sc {
unsigned long value;
int reload;
} me4000_ai_sc_t;
};
/*-----------------------------------------------------------------------------
Type definitions for eeprom
----------------------------------------------------------------------------*/
typedef struct me4000_eeprom {
struct me4000_eeprom {
unsigned long date;
short uni_10_offset;
short uni_10_fullscale;
@ -842,45 +840,45 @@ typedef struct me4000_eeprom {
short diff_10_fullscale;
short diff_2_5_offset;
short diff_2_5_fullscale;
} me4000_eeprom_t;
};
/*-----------------------------------------------------------------------------
Type definitions for digital I/O
----------------------------------------------------------------------------*/
typedef struct me4000_dio_config {
struct me4000_dio_config {
int port;
int mode;
int function;
} me4000_dio_config_t;
};
typedef struct me4000_dio_byte {
struct me4000_dio_byte {
int port;
unsigned char byte;
} me4000_dio_byte_t;
};
/*-----------------------------------------------------------------------------
Type definitions for counters
----------------------------------------------------------------------------*/
typedef struct me4000_cnt {
struct me4000_cnt {
int counter;
unsigned short value;
} me4000_cnt_t;
};
typedef struct me4000_cnt_config {
struct me4000_cnt_config {
int counter;
int mode;
} me4000_cnt_config_t;
};
/*-----------------------------------------------------------------------------
Type definitions for external interrupt
----------------------------------------------------------------------------*/
typedef struct {
struct me4000_int {
int int1_count;
int int2_count;
} me4000_int_type;
};
/*-----------------------------------------------------------------------------
The ioctls of the board
@ -888,7 +886,8 @@ typedef struct {
#define ME4000_IOCTL_MAXNR 50
#define ME4000_MAGIC 'y'
#define ME4000_GET_USER_INFO _IOR (ME4000_MAGIC, 0, me4000_user_info_t)
#define ME4000_GET_USER_INFO _IOR (ME4000_MAGIC, 0, \
struct me4000_user_info)
#define ME4000_AO_START _IOW (ME4000_MAGIC, 1, unsigned long)
#define ME4000_AO_STOP _IO (ME4000_MAGIC, 2)
@ -904,25 +903,35 @@ typedef struct {
#define ME4000_AO_DISABLE_DO _IO (ME4000_MAGIC, 12)
#define ME4000_AO_FSM_STATE _IOR (ME4000_MAGIC, 13, int)
#define ME4000_AI_SINGLE _IOR (ME4000_MAGIC, 14, me4000_ai_single_t)
#define ME4000_AI_SINGLE _IOR (ME4000_MAGIC, 14, \
struct me4000_ai_single)
#define ME4000_AI_START _IOW (ME4000_MAGIC, 15, unsigned long)
#define ME4000_AI_STOP _IO (ME4000_MAGIC, 16)
#define ME4000_AI_IMMEDIATE_STOP _IO (ME4000_MAGIC, 17)
#define ME4000_AI_EX_TRIG_ENABLE _IO (ME4000_MAGIC, 18)
#define ME4000_AI_EX_TRIG_DISABLE _IO (ME4000_MAGIC, 19)
#define ME4000_AI_EX_TRIG_SETUP _IOW (ME4000_MAGIC, 20, me4000_ai_trigger_t)
#define ME4000_AI_CONFIG _IOW (ME4000_MAGIC, 21, me4000_ai_config_t)
#define ME4000_AI_SC_SETUP _IOW (ME4000_MAGIC, 22, me4000_ai_sc_t)
#define ME4000_AI_EX_TRIG_SETUP _IOW (ME4000_MAGIC, 20, \
struct me4000_ai_trigger)
#define ME4000_AI_CONFIG _IOW (ME4000_MAGIC, 21, \
struct me4000_ai_config)
#define ME4000_AI_SC_SETUP _IOW (ME4000_MAGIC, 22, \
struct me4000_ai_sc)
#define ME4000_AI_FSM_STATE _IOR (ME4000_MAGIC, 23, int)
#define ME4000_DIO_CONFIG _IOW (ME4000_MAGIC, 24, me4000_dio_config_t)
#define ME4000_DIO_GET_BYTE _IOR (ME4000_MAGIC, 25, me4000_dio_byte_t)
#define ME4000_DIO_SET_BYTE _IOW (ME4000_MAGIC, 26, me4000_dio_byte_t)
#define ME4000_DIO_CONFIG _IOW (ME4000_MAGIC, 24, \
struct me4000_dio_config)
#define ME4000_DIO_GET_BYTE _IOR (ME4000_MAGIC, 25, \
struct me4000_dio_byte)
#define ME4000_DIO_SET_BYTE _IOW (ME4000_MAGIC, 26, \
struct me4000_dio_byte)
#define ME4000_DIO_RESET _IO (ME4000_MAGIC, 27)
#define ME4000_CNT_READ _IOR (ME4000_MAGIC, 28, me4000_cnt_t)
#define ME4000_CNT_WRITE _IOW (ME4000_MAGIC, 29, me4000_cnt_t)
#define ME4000_CNT_CONFIG _IOW (ME4000_MAGIC, 30, me4000_cnt_config_t)
#define ME4000_CNT_READ _IOR (ME4000_MAGIC, 28, \
struct me4000_cnt)
#define ME4000_CNT_WRITE _IOW (ME4000_MAGIC, 29, \
struct me4000_cnt)
#define ME4000_CNT_CONFIG _IOW (ME4000_MAGIC, 30, \
struct me4000_cnt_config)
#define ME4000_CNT_RESET _IO (ME4000_MAGIC, 31)
#define ME4000_EXT_INT_DISABLE _IO (ME4000_MAGIC, 32)
@ -934,13 +943,16 @@ typedef struct {
#define ME4000_AI_FULLSCALE_ENABLE _IO (ME4000_MAGIC, 37)
#define ME4000_AI_FULLSCALE_DISABLE _IO (ME4000_MAGIC, 38)
#define ME4000_AI_EEPROM_READ _IOR (ME4000_MAGIC, 39, me4000_eeprom_t)
#define ME4000_AI_EEPROM_WRITE _IOW (ME4000_MAGIC, 40, me4000_eeprom_t)
#define ME4000_AI_EEPROM_READ _IOR (ME4000_MAGIC, 39, \
struct me4000_eeprom)
#define ME4000_AI_EEPROM_WRITE _IOW (ME4000_MAGIC, 40, \
struct me4000_eeprom)
#define ME4000_AO_SIMULTANEOUS_EX_TRIG _IO (ME4000_MAGIC, 41)
#define ME4000_AO_SIMULTANEOUS_SW _IO (ME4000_MAGIC, 42)
#define ME4000_AO_SIMULTANEOUS_DISABLE _IO (ME4000_MAGIC, 43)
#define ME4000_AO_SIMULTANEOUS_UPDATE _IOW (ME4000_MAGIC, 44, me4000_ao_channel_list_t)
#define ME4000_AO_SIMULTANEOUS_UPDATE _IOW (ME4000_MAGIC, 44, \
struct me4000_ao_channel_list)
#define ME4000_AO_SYNCHRONOUS_EX_TRIG _IO (ME4000_MAGIC, 45)
#define ME4000_AO_SYNCHRONOUS_SW _IO (ME4000_MAGIC, 46)

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@ -0,0 +1,11 @@
config PCC_ACPI
tristate "Panasonic ACPI Hotkey support"
depends on ACPI
default n
---help---
This driver provides support for Panasonic hotkeys through the
ACPI interface. This works for the Panasonic R1 (N variant),
R2, R3, T2, W2, and Y2 laptops.
To compile this driver as a module, choose M here. The module
will be called pcc-acpi.

Просмотреть файл

@ -0,0 +1 @@
obj-$(CONFIG_PCC_ACPI) += pcc-acpi.o

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@ -0,0 +1,7 @@
TODO:
- Lindent fixes
- checkpatch.pl fixes
- verify that the acpi interface is correct
- remove /proc dependancy if needed (not sure yet.)
Please send any patches for this driver to Greg Kroah-Hartman <greg@kroah.com>

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@ -0,0 +1,6 @@
config POCH
tristate "Redrapids Pocket Change CardBus support"
depends on PCI && UIO
default N
---help---
Enable support for Redrapids Pocket Change CardBus devices.

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@ -0,0 +1 @@
obj-$(CONFIG_POCH) += poch.o

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@ -0,0 +1,7 @@
TODO:
- fix transmit overflows
- audit userspace interfaces
- get reserved major/minor if needed
Please send patches to Greg Kroah-Hartman <greg@kroah.com> and
Vijay Kumar <vijaykumar@bravegnu.org> and Jaya Kumar <jayakumar.lkml@gmail.com>

1425
drivers/staging/poch/poch.c Normal file

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@ -0,0 +1,29 @@
/*
* User-space DMA and UIO based Redrapids Pocket Change CardBus driver
*
* Copyright 2008 Vijay Kumar <vijaykumar@bravegnu.org>
*
* Part of userspace API. Should be moved to a header file in
* include/linux for final version.
*
*/
struct poch_cbuf_header {
__s32 group_size_bytes;
__s32 group_count;
__s32 group_offsets[0];
};
struct poch_counters {
__u32 fifo_empty;
__u32 fifo_overflow;
__u32 pll_unlock;
};
#define POCH_IOC_NUM '9'
#define POCH_IOC_TRANSFER_START _IO(POCH_IOC_NUM, 0)
#define POCH_IOC_TRANSFER_STOP _IO(POCH_IOC_NUM, 1)
#define POCH_IOC_GET_COUNTERS _IOR(POCH_IOC_NUM, 2, \
struct poch_counters)
#define POCH_IOC_SYNC_GROUP_FOR_USER _IO(POCH_IOC_NUM, 3)
#define POCH_IOC_SYNC_GROUP_FOR_DEVICE _IO(POCH_IOC_NUM, 4)

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@ -54,7 +54,6 @@
* IS-NIC driver.
*/
#include <linux/version.h>
#define SLIC_DUMP_ENABLED 0
#define KLUDGE_FOR_4GB_BOUNDARY 1
@ -96,17 +95,9 @@
#include <linux/moduleparam.h>
#include <linux/types.h>
#include <linux/slab.h>
#include <linux/delay.h>
#include <linux/init.h>
#include <linux/pci.h>
#include <linux/dma-mapping.h>
#include <linux/netdevice.h>
#include <linux/etherdevice.h>
#include <linux/mii.h>
#include <linux/if_vlan.h>
#include <linux/skbuff.h>
#include <linux/string.h>
#include <asm/unaligned.h>
#include <linux/ethtool.h>
@ -275,7 +266,6 @@ static void slic_dbg_register_trace(struct adapter *adapter,
card->reg_value[i], card->reg_valueh[i]);
}
}
}
#endif
static void slic_init_adapter(struct net_device *netdev,
@ -606,6 +596,7 @@ static void __devexit slic_entry_remove(struct pci_dev *pcidev)
uint mmio_len = 0;
struct adapter *adapter = (struct adapter *) netdev_priv(dev);
struct sliccard *card;
struct mcast_address *mcaddr, *mlist;
ASSERT(adapter);
DBG_MSG("slicoss: %s ENTER dev[%p] adapter[%p]\n", __func__, dev,
@ -625,6 +616,13 @@ static void __devexit slic_entry_remove(struct pci_dev *pcidev)
DBG_MSG("slicoss: %s iounmap dev->base_addr[%x]\n", __func__,
(uint) dev->base_addr);
iounmap((void __iomem *)dev->base_addr);
/* free multicast addresses */
mlist = adapter->mcastaddrs;
while (mlist) {
mcaddr = mlist;
mlist = mlist->next;
kfree(mcaddr);
}
ASSERT(adapter->card);
card = adapter->card;
ASSERT(card->adapters_allocated);

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@ -7,6 +7,7 @@ TODO:
- remove wrappers
- checkpatch.pl cleanups
- new functionality that the card needs
- remove reliance on x86
Please send patches to:
Greg Kroah-Hartman <gregkh@suse.de>

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@ -44,7 +44,6 @@
#define FALSE (0)
#define TRUE (1)
typedef struct _LIST_ENTRY {
struct _LIST_ENTRY *nle_flink;
struct _LIST_ENTRY *nle_blink;
@ -69,35 +68,32 @@ typedef struct _LIST_ENTRY {
/* These two have to be inlined since they return things. */
static __inline PLIST_ENTRY
RemoveHeadList(list_entry *l)
static __inline PLIST_ENTRY RemoveHeadList(list_entry * l)
{
list_entry *f;
list_entry *e;
list_entry *f;
list_entry *e;
e = l->nle_flink;
f = e->nle_flink;
l->nle_flink = f;
f->nle_blink = l;
e = l->nle_flink;
f = e->nle_flink;
l->nle_flink = f;
f->nle_blink = l;
return (e);
return (e);
}
static __inline PLIST_ENTRY
RemoveTailList(list_entry *l)
static __inline PLIST_ENTRY RemoveTailList(list_entry * l)
{
list_entry *b;
list_entry *e;
list_entry *b;
list_entry *e;
e = l->nle_blink;
b = e->nle_blink;
l->nle_blink = b;
b->nle_flink = l;
e = l->nle_blink;
b = e->nle_blink;
l->nle_blink = b;
b->nle_flink = l;
return (e);
return (e);
}
#define InsertTailList(l, e) \
do { \
list_entry *b; \
@ -120,7 +116,6 @@ RemoveTailList(list_entry *l)
(l)->nle_flink = (e); \
} while (0)
#define ATK_DEBUG 1
#if ATK_DEBUG
@ -133,7 +128,6 @@ RemoveTailList(list_entry *l)
#define SLIC_TIMESTAMP(value)
#endif
/****************** SXG DEFINES *****************************************/
#ifdef ATKDBG
@ -150,5 +144,4 @@ RemoveTailList(list_entry *l)
#define WRITE_REG64(a,reg,value,cpu) sxg_reg64_write((a),(&reg),(value),(cpu))
#define READ_REG(reg,value) (value) = readl((void __iomem *)(&reg))
#endif /* _SLIC_OS_SPECIFIC_H_ */
#endif /* _SLIC_OS_SPECIFIC_H_ */

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@ -58,7 +58,7 @@
{ \
if (!(a)) { \
DBG_ERROR("ASSERT() Failure: file %s, function %s line %d\n",\
__FILE__, __FUNCTION__, __LINE__); \
__FILE__, __func__, __LINE__); \
} \
}
#endif

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@ -14,119 +14,119 @@
*******************************************************************************/
typedef struct _SXG_UCODE_REGS {
// Address 0 - 0x3F = Command codes 0-15 for TCB 0. Excode 0
u32 Icr; // Code = 0 (extended), ExCode = 0 - Int control
u32 RsvdReg1; // Code = 1 - TOE -NA
u32 RsvdReg2; // Code = 2 - TOE -NA
u32 RsvdReg3; // Code = 3 - TOE -NA
u32 RsvdReg4; // Code = 4 - TOE -NA
u32 RsvdReg5; // Code = 5 - TOE -NA
u32 CardUp; // Code = 6 - Microcode initialized when 1
u32 RsvdReg7; // Code = 7 - TOE -NA
u32 CodeNotUsed[8]; // Codes 8-15 not used. ExCode = 0
u32 Icr; // Code = 0 (extended), ExCode = 0 - Int control
u32 RsvdReg1; // Code = 1 - TOE -NA
u32 RsvdReg2; // Code = 2 - TOE -NA
u32 RsvdReg3; // Code = 3 - TOE -NA
u32 RsvdReg4; // Code = 4 - TOE -NA
u32 RsvdReg5; // Code = 5 - TOE -NA
u32 CardUp; // Code = 6 - Microcode initialized when 1
u32 RsvdReg7; // Code = 7 - TOE -NA
u32 CodeNotUsed[8]; // Codes 8-15 not used. ExCode = 0
// This brings us to ExCode 1 at address 0x40 = Interrupt status pointer
u32 Isp; // Code = 0 (extended), ExCode = 1
u32 PadEx1[15]; // Codes 1-15 not used with extended codes
u32 Isp; // Code = 0 (extended), ExCode = 1
u32 PadEx1[15]; // Codes 1-15 not used with extended codes
// ExCode 2 = Interrupt Status Register
u32 Isr; // Code = 0 (extended), ExCode = 2
u32 PadEx2[15];
u32 Isr; // Code = 0 (extended), ExCode = 2
u32 PadEx2[15];
// ExCode 3 = Event base register. Location of event rings
u32 EventBase; // Code = 0 (extended), ExCode = 3
u32 PadEx3[15];
u32 EventBase; // Code = 0 (extended), ExCode = 3
u32 PadEx3[15];
// ExCode 4 = Event ring size
u32 EventSize; // Code = 0 (extended), ExCode = 4
u32 PadEx4[15];
u32 EventSize; // Code = 0 (extended), ExCode = 4
u32 PadEx4[15];
// ExCode 5 = TCB Buffers base address
u32 TcbBase; // Code = 0 (extended), ExCode = 5
u32 PadEx5[15];
u32 TcbBase; // Code = 0 (extended), ExCode = 5
u32 PadEx5[15];
// ExCode 6 = TCB Composite Buffers base address
u32 TcbCompBase; // Code = 0 (extended), ExCode = 6
u32 PadEx6[15];
u32 TcbCompBase; // Code = 0 (extended), ExCode = 6
u32 PadEx6[15];
// ExCode 7 = Transmit ring base address
u32 XmtBase; // Code = 0 (extended), ExCode = 7
u32 PadEx7[15];
u32 XmtBase; // Code = 0 (extended), ExCode = 7
u32 PadEx7[15];
// ExCode 8 = Transmit ring size
u32 XmtSize; // Code = 0 (extended), ExCode = 8
u32 PadEx8[15];
u32 XmtSize; // Code = 0 (extended), ExCode = 8
u32 PadEx8[15];
// ExCode 9 = Receive ring base address
u32 RcvBase; // Code = 0 (extended), ExCode = 9
u32 PadEx9[15];
u32 RcvBase; // Code = 0 (extended), ExCode = 9
u32 PadEx9[15];
// ExCode 10 = Receive ring size
u32 RcvSize; // Code = 0 (extended), ExCode = 10
u32 PadEx10[15];
u32 RcvSize; // Code = 0 (extended), ExCode = 10
u32 PadEx10[15];
// ExCode 11 = Read EEPROM Config
u32 Config; // Code = 0 (extended), ExCode = 11
u32 PadEx11[15];
u32 Config; // Code = 0 (extended), ExCode = 11
u32 PadEx11[15];
// ExCode 12 = Multicast bits 31:0
u32 McastLow; // Code = 0 (extended), ExCode = 12
u32 PadEx12[15];
u32 McastLow; // Code = 0 (extended), ExCode = 12
u32 PadEx12[15];
// ExCode 13 = Multicast bits 63:32
u32 McastHigh; // Code = 0 (extended), ExCode = 13
u32 PadEx13[15];
u32 McastHigh; // Code = 0 (extended), ExCode = 13
u32 PadEx13[15];
// ExCode 14 = Ping
u32 Ping; // Code = 0 (extended), ExCode = 14
u32 PadEx14[15];
u32 Ping; // Code = 0 (extended), ExCode = 14
u32 PadEx14[15];
// ExCode 15 = Link MTU
u32 LinkMtu; // Code = 0 (extended), ExCode = 15
u32 PadEx15[15];
u32 LinkMtu; // Code = 0 (extended), ExCode = 15
u32 PadEx15[15];
// ExCode 16 = Download synchronization
u32 LoadSync; // Code = 0 (extended), ExCode = 16
u32 PadEx16[15];
u32 LoadSync; // Code = 0 (extended), ExCode = 16
u32 PadEx16[15];
// ExCode 17 = Upper DRAM address bits on 32-bit systems
u32 Upper; // Code = 0 (extended), ExCode = 17
u32 PadEx17[15];
u32 Upper; // Code = 0 (extended), ExCode = 17
u32 PadEx17[15];
// ExCode 18 = Slowpath Send Index Address
u32 SPSendIndex; // Code = 0 (extended), ExCode = 18
u32 PadEx18[15];
u32 RsvdXF; // Code = 0 (extended), ExCode = 19
u32 PadEx19[15];
u32 SPSendIndex; // Code = 0 (extended), ExCode = 18
u32 PadEx18[15];
u32 RsvdXF; // Code = 0 (extended), ExCode = 19
u32 PadEx19[15];
// ExCode 20 = Aggregation
u32 Aggregation; // Code = 0 (extended), ExCode = 20
u32 PadEx20[15];
u32 Aggregation; // Code = 0 (extended), ExCode = 20
u32 PadEx20[15];
// ExCode 21 = Receive MDL push timer
u32 PushTicks; // Code = 0 (extended), ExCode = 21
u32 PadEx21[15];
u32 PushTicks; // Code = 0 (extended), ExCode = 21
u32 PadEx21[15];
// ExCode 22 = TOE NA
u32 AckFrequency; // Code = 0 (extended), ExCode = 22
u32 PadEx22[15];
u32 AckFrequency; // Code = 0 (extended), ExCode = 22
u32 PadEx22[15];
// ExCode 23 = TOE NA
u32 RsvdReg23;
u32 PadEx23[15];
u32 RsvdReg23;
u32 PadEx23[15];
// ExCode 24 = TOE NA
u32 RsvdReg24;
u32 PadEx24[15];
u32 RsvdReg24;
u32 PadEx24[15];
// ExCode 25 = TOE NA
u32 RsvdReg25; // Code = 0 (extended), ExCode = 25
u32 PadEx25[15];
u32 RsvdReg25; // Code = 0 (extended), ExCode = 25
u32 PadEx25[15];
// ExCode 26 = Receive checksum requirements
u32 ReceiveChecksum; // Code = 0 (extended), ExCode = 26
u32 PadEx26[15];
u32 ReceiveChecksum; // Code = 0 (extended), ExCode = 26
u32 PadEx26[15];
// ExCode 27 = RSS Requirements
u32 Rss; // Code = 0 (extended), ExCode = 27
u32 PadEx27[15];
u32 Rss; // Code = 0 (extended), ExCode = 27
u32 PadEx27[15];
// ExCode 28 = RSS Table
u32 RssTable; // Code = 0 (extended), ExCode = 28
u32 PadEx28[15];
u32 RssTable; // Code = 0 (extended), ExCode = 28
u32 PadEx28[15];
// ExCode 29 = Event ring release entries
u32 EventRelease; // Code = 0 (extended), ExCode = 29
u32 PadEx29[15];
u32 EventRelease; // Code = 0 (extended), ExCode = 29
u32 PadEx29[15];
// ExCode 30 = Number of receive bufferlist commands on ring 0
u32 RcvCmd; // Code = 0 (extended), ExCode = 30
u32 PadEx30[15];
u32 RcvCmd; // Code = 0 (extended), ExCode = 30
u32 PadEx30[15];
// ExCode 31 = slowpath transmit command - Data[31:0] = 1
u32 XmtCmd; // Code = 0 (extended), ExCode = 31
u32 PadEx31[15];
u32 XmtCmd; // Code = 0 (extended), ExCode = 31
u32 PadEx31[15];
// ExCode 32 = Dump command
u32 DumpCmd; // Code = 0 (extended), ExCode = 32
u32 PadEx32[15];
u32 DumpCmd; // Code = 0 (extended), ExCode = 32
u32 PadEx32[15];
// ExCode 33 = Debug command
u32 DebugCmd; // Code = 0 (extended), ExCode = 33
u32 PadEx33[15];
u32 DebugCmd; // Code = 0 (extended), ExCode = 33
u32 PadEx33[15];
// There are 128 possible extended commands - each of account for 16
// words (including the non-relevent base command codes 1-15).
// Pad for the remainder of these here to bring us to the next CPU
// base. As extended codes are added, reduce the first array value in
// the following field
u32 PadToNextCpu[94][16]; // 94 = 128 - 34 (34 = Excodes 0 - 33)
u32 PadToNextCpu[94][16]; // 94 = 128 - 34 (34 = Excodes 0 - 33)
} SXG_UCODE_REGS, *PSXG_UCODE_REGS;
// Interrupt control register (0) values
@ -141,7 +141,7 @@ typedef struct _SXG_UCODE_REGS {
// The Microcode supports up to 16 RSS queues
#define SXG_MAX_RSS 16
#define SXG_MAX_RSS_TABLE_SIZE 256 // 256-byte max
#define SXG_MAX_RSS_TABLE_SIZE 256 // 256-byte max
#define SXG_RSS_TCP6 0x00000001 // RSS TCP over IPv6
#define SXG_RSS_TCP4 0x00000002 // RSS TCP over IPv4
@ -170,16 +170,16 @@ typedef struct _SXG_UCODE_REGS {
* SXG_UCODE_REGS definition above
*/
typedef struct _SXG_TCB_REGS {
u32 ExCode; /* Extended codes - see SXG_UCODE_REGS */
u32 Xmt; /* Code = 1 - # of Xmt descriptors added to ring */
u32 Rcv; /* Code = 2 - # of Rcv descriptors added to ring */
u32 Rsvd1; /* Code = 3 - TOE NA */
u32 Rsvd2; /* Code = 4 - TOE NA */
u32 Rsvd3; /* Code = 5 - TOE NA */
u32 Invalid; /* Code = 6 - Reserved for "CardUp" see above */
u32 Rsvd4; /* Code = 7 - TOE NA */
u32 Rsvd5; /* Code = 8 - TOE NA */
u32 Pad[7]; /* Codes 8-15 - Not used. */
u32 ExCode; /* Extended codes - see SXG_UCODE_REGS */
u32 Xmt; /* Code = 1 - # of Xmt descriptors added to ring */
u32 Rcv; /* Code = 2 - # of Rcv descriptors added to ring */
u32 Rsvd1; /* Code = 3 - TOE NA */
u32 Rsvd2; /* Code = 4 - TOE NA */
u32 Rsvd3; /* Code = 5 - TOE NA */
u32 Invalid; /* Code = 6 - Reserved for "CardUp" see above */
u32 Rsvd4; /* Code = 7 - TOE NA */
u32 Rsvd5; /* Code = 8 - TOE NA */
u32 Pad[7]; /* Codes 8-15 - Not used. */
} SXG_TCB_REGS, *PSXG_TCB_REGS;
/***************************************************************************
@ -273,27 +273,27 @@ typedef struct _SXG_TCB_REGS {
*/
#pragma pack(push, 1)
typedef struct _SXG_EVENT {
u32 Pad[1]; // not used
u32 SndUna; // SndUna value
u32 Resid; // receive MDL resid
u32 Pad[1]; // not used
u32 SndUna; // SndUna value
u32 Resid; // receive MDL resid
union {
void * HostHandle; // Receive host handle
u32 Rsvd1; // TOE NA
void *HostHandle; // Receive host handle
u32 Rsvd1; // TOE NA
struct {
u32 NotUsed;
u32 Rsvd2; // TOE NA
u32 NotUsed;
u32 Rsvd2; // TOE NA
} Flush;
};
u32 Toeplitz; // RSS Toeplitz hash
u32 Toeplitz; // RSS Toeplitz hash
union {
ushort Rsvd3; // TOE NA
ushort HdrOffset; // Slowpath
ushort Rsvd3; // TOE NA
ushort HdrOffset; // Slowpath
};
ushort Length; //
unsigned char Rsvd4; // TOE NA
unsigned char Code; // Event code
unsigned char CommandIndex; // New ring index
unsigned char Status; // Event status
ushort Length; //
unsigned char Rsvd4; // TOE NA
unsigned char Code; // Event code
unsigned char CommandIndex; // New ring index
unsigned char Status; // Event status
} SXG_EVENT, *PSXG_EVENT;
#pragma pack(pop)
@ -318,12 +318,12 @@ typedef struct _SXG_EVENT {
// Event ring
// Size must be power of 2, between 128 and 16k
#define EVENT_RING_SIZE 4096 // ??
#define EVENT_RING_BATCH 16 // Hand entries back 16 at a time.
#define EVENT_BATCH_LIMIT 256 // Stop processing events after 256 (16 * 16)
#define EVENT_RING_BATCH 16 // Hand entries back 16 at a time.
#define EVENT_BATCH_LIMIT 256 // Stop processing events after 256 (16 * 16)
typedef struct _SXG_EVENT_RING {
SXG_EVENT Ring[EVENT_RING_SIZE];
}SXG_EVENT_RING, *PSXG_EVENT_RING;
SXG_EVENT Ring[EVENT_RING_SIZE];
} SXG_EVENT_RING, *PSXG_EVENT_RING;
/***************************************************************************
*
@ -341,7 +341,7 @@ typedef struct _SXG_EVENT_RING {
#define SXG_TCB_PER_BUCKET 16
#define SXG_TCB_BUCKET_MASK 0xFF0 // Bucket portion of TCB ID
#define SXG_TCB_ELEMENT_MASK 0x00F // Element within bucket
#define SXG_TCB_BUCKETS 256 // 256 * 16 = 4k
#define SXG_TCB_BUCKETS 256 // 256 * 16 = 4k
#define SXG_TCB_BUFFER_SIZE 512 // ASSERT format is correct
@ -368,7 +368,6 @@ typedef struct _SXG_EVENT_RING {
&(_TcpObject)->CompBuffer->Frame.HasVlan.TcpIp6.Ip : \
&(_TcpObject)->CompBuffer->Frame.NoVlan.TcpIp6.Ip
#if DBG
// Horrible kludge to distinguish dumb-nic, slowpath, and
// fastpath traffic. Decrement the HopLimit by one
@ -396,16 +395,16 @@ typedef struct _SXG_EVENT_RING {
* Receive and transmit rings
***************************************************************************/
#define SXG_MAX_RING_SIZE 256
#define SXG_XMT_RING_SIZE 128 // Start with 128
#define SXG_RCV_RING_SIZE 128 // Start with 128
#define SXG_XMT_RING_SIZE 128 // Start with 128
#define SXG_RCV_RING_SIZE 128 // Start with 128
#define SXG_MAX_ENTRIES 4096
// Structure and macros to manage a ring
typedef struct _SXG_RING_INFO {
unsigned char Head; // Where we add entries - Note unsigned char:RING_SIZE
unsigned char Tail; // Where we pull off completed entries
ushort Size; // Ring size - Must be multiple of 2
void * Context[SXG_MAX_RING_SIZE]; // Shadow ring
unsigned char Head; // Where we add entries - Note unsigned char:RING_SIZE
unsigned char Tail; // Where we pull off completed entries
ushort Size; // Ring size - Must be multiple of 2
void *Context[SXG_MAX_RING_SIZE]; // Shadow ring
} SXG_RING_INFO, *PSXG_RING_INFO;
#define SXG_INITIALIZE_RING(_ring, _size) { \
@ -483,40 +482,40 @@ typedef struct _SXG_RING_INFO {
*/
#pragma pack(push, 1)
typedef struct _SXG_CMD {
dma_addr_t Sgl; // Physical address of SGL
dma_addr_t Sgl; // Physical address of SGL
union {
struct {
dma64_addr_t FirstSgeAddress;// Address of first SGE
u32 FirstSgeLength; // Length of first SGE
dma64_addr_t FirstSgeAddress; // Address of first SGE
u32 FirstSgeLength; // Length of first SGE
union {
u32 Rsvd1; // TOE NA
u32 SgeOffset; // Slowpath - 2nd SGE offset
u32 Resid; // MDL completion - clobbers update
u32 Rsvd1; // TOE NA
u32 SgeOffset; // Slowpath - 2nd SGE offset
u32 Resid; // MDL completion - clobbers update
};
union {
u32 TotalLength; // Total transfer length
u32 Mss; // LSO MSS
u32 TotalLength; // Total transfer length
u32 Mss; // LSO MSS
};
} Buffer;
};
union {
struct {
unsigned char Flags:4; // slowpath flags
unsigned char IpHl:4; // Ip header length (>>2)
unsigned char MacLen; // Mac header len
unsigned char Flags:4; // slowpath flags
unsigned char IpHl:4; // Ip header length (>>2)
unsigned char MacLen; // Mac header len
} CsumFlags;
struct {
ushort Flags:4; // slowpath flags
ushort TcpHdrOff:7; // TCP
ushort MacLen:5; // Mac header len
ushort Flags:4; // slowpath flags
ushort TcpHdrOff:7; // TCP
ushort MacLen:5; // Mac header len
} LsoFlags;
ushort Flags; // flags
ushort Flags; // flags
};
union {
ushort SgEntries; // SG entry count including first sge
ushort SgEntries; // SG entry count including first sge
struct {
unsigned char Status; // Copied from event status
unsigned char NotUsed;
unsigned char Status; // Copied from event status
unsigned char NotUsed;
} Status;
};
} SXG_CMD, *PSXG_CMD;
@ -524,8 +523,8 @@ typedef struct _SXG_CMD {
#pragma pack(push, 1)
typedef struct _VLAN_HDR {
ushort VlanTci;
ushort VlanTpid;
ushort VlanTci;
ushort VlanTpid;
} VLAN_HDR, *PVLAN_HDR;
#pragma pack(pop)
@ -561,16 +560,16 @@ typedef struct _VLAN_HDR {
*
*/
// Slowpath CMD flags
#define SXG_SLOWCMD_CSUM_IP 0x01 // Checksum IP
#define SXG_SLOWCMD_CSUM_TCP 0x02 // Checksum TCP
#define SXG_SLOWCMD_LSO 0x04 // Large segment send
#define SXG_SLOWCMD_CSUM_IP 0x01 // Checksum IP
#define SXG_SLOWCMD_CSUM_TCP 0x02 // Checksum TCP
#define SXG_SLOWCMD_LSO 0x04 // Large segment send
typedef struct _SXG_XMT_RING {
SXG_CMD Descriptors[SXG_XMT_RING_SIZE];
SXG_CMD Descriptors[SXG_XMT_RING_SIZE];
} SXG_XMT_RING, *PSXG_XMT_RING;
typedef struct _SXG_RCV_RING {
SXG_CMD Descriptors[SXG_RCV_RING_SIZE];
SXG_CMD Descriptors[SXG_RCV_RING_SIZE];
} SXG_RCV_RING, *PSXG_RCV_RING;
/***************************************************************************
@ -578,8 +577,8 @@ typedef struct _SXG_RCV_RING {
* shared memory allocation
***************************************************************************/
typedef enum {
SXG_BUFFER_TYPE_RCV, // Receive buffer
SXG_BUFFER_TYPE_SGL // SGL buffer
SXG_BUFFER_TYPE_RCV, // Receive buffer
SXG_BUFFER_TYPE_SGL // SGL buffer
} SXG_BUFFER_TYPE;
// State for SXG buffers
@ -668,60 +667,60 @@ typedef enum {
#define SXG_RCV_DATA_BUFFERS 4096 // Amount to give to the card
#define SXG_INITIAL_RCV_DATA_BUFFERS 8192 // Initial pool of buffers
#define SXG_MIN_RCV_DATA_BUFFERS 2048 // Minimum amount and when to get more
#define SXG_MAX_RCV_BLOCKS 128 // = 16384 receive buffers
#define SXG_MAX_RCV_BLOCKS 128 // = 16384 receive buffers
// Receive buffer header
typedef struct _SXG_RCV_DATA_BUFFER_HDR {
dma_addr_t PhysicalAddress; // Buffer physical address
dma_addr_t PhysicalAddress; // Buffer physical address
// Note - DO NOT USE the VirtualAddress field to locate data.
// Use the sxg.h:SXG_RECEIVE_DATA_LOCATION macro instead.
void *VirtualAddress; // Start of buffer
LIST_ENTRY FreeList; // Free queue of buffers
struct _SXG_RCV_DATA_BUFFER_HDR *Next; // Fastpath data buffer queue
u32 Size; // Buffer size
u32 ByteOffset; // See SXG_RESTORE_MDL_OFFSET
unsigned char State; // See SXG_BUFFER state above
unsigned char Status; // Event status (to log PUSH)
struct sk_buff * skb; // Double mapped (nbl and pkt)
void *VirtualAddress; // Start of buffer
LIST_ENTRY FreeList; // Free queue of buffers
struct _SXG_RCV_DATA_BUFFER_HDR *Next; // Fastpath data buffer queue
u32 Size; // Buffer size
u32 ByteOffset; // See SXG_RESTORE_MDL_OFFSET
unsigned char State; // See SXG_BUFFER state above
unsigned char Status; // Event status (to log PUSH)
struct sk_buff *skb; // Double mapped (nbl and pkt)
} SXG_RCV_DATA_BUFFER_HDR, *PSXG_RCV_DATA_BUFFER_HDR;
// SxgSlowReceive uses the PACKET (skb) contained
// in the SXG_RCV_DATA_BUFFER_HDR when indicating dumb-nic data
#define SxgDumbRcvPacket skb
#define SXG_RCV_DATA_HDR_SIZE 256 // Space for SXG_RCV_DATA_BUFFER_HDR
#define SXG_RCV_DATA_HDR_SIZE 256 // Space for SXG_RCV_DATA_BUFFER_HDR
#define SXG_RCV_DATA_BUFFER_SIZE 2048 // Non jumbo = 2k including HDR
#define SXG_RCV_JUMBO_BUFFER_SIZE 10240 // jumbo = 10k including HDR
// Receive data descriptor
typedef struct _SXG_RCV_DATA_DESCRIPTOR {
union {
struct sk_buff * VirtualAddress; // Host handle
u64 ForceTo8Bytes; // Force x86 to 8-byte boundary
struct sk_buff *VirtualAddress; // Host handle
u64 ForceTo8Bytes; // Force x86 to 8-byte boundary
};
dma_addr_t PhysicalAddress;
dma_addr_t PhysicalAddress;
} SXG_RCV_DATA_DESCRIPTOR, *PSXG_RCV_DATA_DESCRIPTOR;
// Receive descriptor block
#define SXG_RCV_DESCRIPTORS_PER_BLOCK 128
#define SXG_RCV_DESCRIPTOR_BLOCK_SIZE 2048 // For sanity check
typedef struct _SXG_RCV_DESCRIPTOR_BLOCK {
SXG_RCV_DATA_DESCRIPTOR Descriptors[SXG_RCV_DESCRIPTORS_PER_BLOCK];
SXG_RCV_DATA_DESCRIPTOR Descriptors[SXG_RCV_DESCRIPTORS_PER_BLOCK];
} SXG_RCV_DESCRIPTOR_BLOCK, *PSXG_RCV_DESCRIPTOR_BLOCK;
// Receive descriptor block header
typedef struct _SXG_RCV_DESCRIPTOR_BLOCK_HDR {
void * VirtualAddress; // Start of 2k buffer
dma_addr_t PhysicalAddress; // ..and it's physical address
LIST_ENTRY FreeList; // Free queue of descriptor blocks
unsigned char State; // See SXG_BUFFER state above
void *VirtualAddress; // Start of 2k buffer
dma_addr_t PhysicalAddress; // ..and it's physical address
LIST_ENTRY FreeList; // Free queue of descriptor blocks
unsigned char State; // See SXG_BUFFER state above
} SXG_RCV_DESCRIPTOR_BLOCK_HDR, *PSXG_RCV_DESCRIPTOR_BLOCK_HDR;
// Receive block header
typedef struct _SXG_RCV_BLOCK_HDR {
void * VirtualAddress; // Start of virtual memory
dma_addr_t PhysicalAddress; // ..and it's physical address
LIST_ENTRY AllList; // Queue of all SXG_RCV_BLOCKS
void *VirtualAddress; // Start of virtual memory
dma_addr_t PhysicalAddress; // ..and it's physical address
LIST_ENTRY AllList; // Queue of all SXG_RCV_BLOCKS
} SXG_RCV_BLOCK_HDR, *PSXG_RCV_BLOCK_HDR;
// Macros to determine data structure offsets into receive block
@ -747,8 +746,8 @@ typedef struct _SXG_RCV_BLOCK_HDR {
// Use the miniport reserved portion of the NBL to locate
// our SXG_RCV_DATA_BUFFER_HDR structure.
typedef struct _SXG_RCV_NBL_RESERVED {
PSXG_RCV_DATA_BUFFER_HDR RcvDataBufferHdr;
void * Available;
PSXG_RCV_DATA_BUFFER_HDR RcvDataBufferHdr;
void *Available;
} SXG_RCV_NBL_RESERVED, *PSXG_RCV_NBL_RESERVED;
#define SXG_RCV_NBL_BUFFER_HDR(_NBL) (((PSXG_RCV_NBL_RESERVED)NET_BUFFER_LIST_MINIPORT_RESERVED(_NBL))->RcvDataBufferHdr)
@ -760,12 +759,11 @@ typedef struct _SXG_RCV_NBL_RESERVED {
#define SXG_MIN_SGL_BUFFERS 2048 // Minimum amount and when to get more
#define SXG_MAX_SGL_BUFFERS 16384 // Maximum to allocate (note ADAPT:ushort)
// Self identifying structure type
typedef enum _SXG_SGL_TYPE {
SXG_SGL_DUMB, // Dumb NIC SGL
SXG_SGL_SLOW, // Slowpath protocol header - see below
SXG_SGL_CHIMNEY // Chimney offload SGL
SXG_SGL_DUMB, // Dumb NIC SGL
SXG_SGL_SLOW, // Slowpath protocol header - see below
SXG_SGL_CHIMNEY // Chimney offload SGL
} SXG_SGL_TYPE, PSXG_SGL_TYPE;
// Note - the description below is Microsoft specific
@ -774,14 +772,14 @@ typedef enum _SXG_SGL_TYPE {
// for the SCATTER_GATHER_LIST portion of the SXG_SCATTER_GATHER data structure.
// The following considerations apply when setting this value:
// - First, the Sahara card is designed to read the Microsoft SGL structure
// straight out of host memory. This means that the SGL must reside in
// shared memory. If the length here is smaller than the SGL for the
// NET_BUFFER, then NDIS will allocate its own buffer. The buffer
// that NDIS allocates is not in shared memory, so when this happens,
// the SGL will need to be copied to a set of SXG_SCATTER_GATHER buffers.
// In other words.. we don't want this value to be too small.
// straight out of host memory. This means that the SGL must reside in
// shared memory. If the length here is smaller than the SGL for the
// NET_BUFFER, then NDIS will allocate its own buffer. The buffer
// that NDIS allocates is not in shared memory, so when this happens,
// the SGL will need to be copied to a set of SXG_SCATTER_GATHER buffers.
// In other words.. we don't want this value to be too small.
// - On the other hand.. we're allocating up to 16k of these things. If
// we make this too big, we start to consume a ton of memory..
// we make this too big, we start to consume a ton of memory..
// At the moment, I'm going to limit the number of SG entries to 150.
// If each entry maps roughly 4k, then this should cover roughly 600kB
// NET_BUFFERs. Furthermore, since each entry is 24 bytes, the total
@ -801,24 +799,23 @@ typedef enum _SXG_SGL_TYPE {
// the SGL. The following structure defines an x64
// formatted SGL entry
typedef struct _SXG_X64_SGE {
dma64_addr_t Address; // same as wdm.h
u32 Length; // same as wdm.h
u32 CompilerPad;// The compiler pads to 8-bytes
u64 Reserved; // u32 * in wdm.h. Force to 8 bytes
dma64_addr_t Address; // same as wdm.h
u32 Length; // same as wdm.h
u32 CompilerPad; // The compiler pads to 8-bytes
u64 Reserved; // u32 * in wdm.h. Force to 8 bytes
} SXG_X64_SGE, *PSXG_X64_SGE;
typedef struct _SCATTER_GATHER_ELEMENT {
dma64_addr_t Address; // same as wdm.h
u32 Length; // same as wdm.h
u32 CompilerPad;// The compiler pads to 8-bytes
u64 Reserved; // u32 * in wdm.h. Force to 8 bytes
dma64_addr_t Address; // same as wdm.h
u32 Length; // same as wdm.h
u32 CompilerPad; // The compiler pads to 8-bytes
u64 Reserved; // u32 * in wdm.h. Force to 8 bytes
} SCATTER_GATHER_ELEMENT, *PSCATTER_GATHER_ELEMENT;
typedef struct _SCATTER_GATHER_LIST {
u32 NumberOfElements;
u32 * Reserved;
SCATTER_GATHER_ELEMENT Elements[];
u32 NumberOfElements;
u32 *Reserved;
SCATTER_GATHER_ELEMENT Elements[];
} SCATTER_GATHER_LIST, *PSCATTER_GATHER_LIST;
// The card doesn't care about anything except elements, so
@ -826,26 +823,26 @@ typedef struct _SCATTER_GATHER_LIST {
// SGL structure. But redefine from wdm.h:SCATTER_GATHER_LIST so
// we can specify SXG_X64_SGE and define a fixed number of elements
typedef struct _SXG_X64_SGL {
u32 NumberOfElements;
u32 * Reserved;
SXG_X64_SGE Elements[SXG_SGL_ENTRIES];
u32 NumberOfElements;
u32 *Reserved;
SXG_X64_SGE Elements[SXG_SGL_ENTRIES];
} SXG_X64_SGL, *PSXG_X64_SGL;
typedef struct _SXG_SCATTER_GATHER {
SXG_SGL_TYPE Type; // FIRST! Dumb-nic or offload
void * adapter; // Back pointer to adapter
LIST_ENTRY FreeList; // Free SXG_SCATTER_GATHER blocks
LIST_ENTRY AllList; // All SXG_SCATTER_GATHER blocks
dma_addr_t PhysicalAddress;// physical address
unsigned char State; // See SXG_BUFFER state above
unsigned char CmdIndex; // Command ring index
struct sk_buff * DumbPacket; // Associated Packet
u32 Direction; // For asynchronous completions
u32 CurOffset; // Current SGL offset
u32 SglRef; // SGL reference count
VLAN_HDR VlanTag; // VLAN tag to be inserted into SGL
PSCATTER_GATHER_LIST pSgl; // SGL Addr. Possibly &Sgl
SXG_X64_SGL Sgl; // SGL handed to card
SXG_SGL_TYPE Type; // FIRST! Dumb-nic or offload
void *adapter; // Back pointer to adapter
LIST_ENTRY FreeList; // Free SXG_SCATTER_GATHER blocks
LIST_ENTRY AllList; // All SXG_SCATTER_GATHER blocks
dma_addr_t PhysicalAddress; // physical address
unsigned char State; // See SXG_BUFFER state above
unsigned char CmdIndex; // Command ring index
struct sk_buff *DumbPacket; // Associated Packet
u32 Direction; // For asynchronous completions
u32 CurOffset; // Current SGL offset
u32 SglRef; // SGL reference count
VLAN_HDR VlanTag; // VLAN tag to be inserted into SGL
PSCATTER_GATHER_LIST pSgl; // SGL Addr. Possibly &Sgl
SXG_X64_SGL Sgl; // SGL handed to card
} SXG_SCATTER_GATHER, *PSXG_SCATTER_GATHER;
#if defined(CONFIG_X86_64)
@ -856,6 +853,5 @@ typedef struct _SXG_SCATTER_GATHER {
#define SXG_SGL_BUFFER(_SxgSgl) NULL
#define SXG_SGL_BUF_SIZE 0
#else
Stop Compilation;
Stop Compilation;
#endif

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@ -13,11 +13,11 @@
/*******************************************************************************
* Configuration space
*******************************************************************************/
// PCI Vendor ID
#define SXG_VENDOR_ID 0x139A // Alacritech's Vendor ID
/* PCI Vendor ID */
#define SXG_VENDOR_ID 0x139A /* Alacritech's Vendor ID */
// PCI Device ID
#define SXG_DEVICE_ID 0x0009 // Sahara Device ID
#define SXG_DEVICE_ID 0x0009 /* Sahara Device ID */
//
// Subsystem IDs.
@ -141,7 +141,7 @@ typedef struct _SXG_HW_REGS {
#define SXG_REGISTER_SIZE_PER_CPU 0x00002000 // Used to sanity check UCODE_REGS structure
// Sahara receive sequencer status values
#define SXG_RCV_STATUS_ATTN 0x80000000 // Attention
#define SXG_RCV_STATUS_ATTN 0x80000000 // Attention
#define SXG_RCV_STATUS_TRANSPORT_MASK 0x3F000000 // Transport mask
#define SXG_RCV_STATUS_TRANSPORT_ERROR 0x20000000 // Transport error
#define SXG_RCV_STATUS_TRANSPORT_CSUM 0x23000000 // Transport cksum error
@ -156,9 +156,9 @@ typedef struct _SXG_HW_REGS {
#define SXG_RCV_STATUS_TRANSPORT_FTP 0x03000000 // Transport FTP
#define SXG_RCV_STATUS_TRANSPORT_HTTP 0x02000000 // Transport HTTP
#define SXG_RCV_STATUS_TRANSPORT_SMB 0x01000000 // Transport SMB
#define SXG_RCV_STATUS_NETWORK_MASK 0x00FF0000 // Network mask
#define SXG_RCV_STATUS_NETWORK_MASK 0x00FF0000 // Network mask
#define SXG_RCV_STATUS_NETWORK_ERROR 0x00800000 // Network error
#define SXG_RCV_STATUS_NETWORK_CSUM 0x00830000 // Network cksum error
#define SXG_RCV_STATUS_NETWORK_CSUM 0x00830000 // Network cksum error
#define SXG_RCV_STATUS_NETWORK_UFLOW 0x00820000 // Network underflow error
#define SXG_RCV_STATUS_NETWORK_HDRLEN 0x00800000 // Network header length
#define SXG_RCV_STATUS_NETWORK_OFLOW 0x00400000 // Network overflow detected
@ -167,67 +167,67 @@ typedef struct _SXG_HW_REGS {
#define SXG_RCV_STATUS_NETWORK_OFFSET 0x00080000 // Network offset detected
#define SXG_RCV_STATUS_NETWORK_FRAGMENT 0x00040000 // Network fragment detected
#define SXG_RCV_STATUS_NETWORK_TRANS_MASK 0x00030000 // Network transport type mask
#define SXG_RCV_STATUS_NETWORK_UDP 0x00020000 // UDP
#define SXG_RCV_STATUS_NETWORK_TCP 0x00010000 // TCP
#define SXG_RCV_STATUS_IPONLY 0x00008000 // IP-only not TCP
#define SXG_RCV_STATUS_PKT_PRI 0x00006000 // Receive priority
#define SXG_RCV_STATUS_PKT_PRI_SHFT 13 // Receive priority shift
#define SXG_RCV_STATUS_PARITY 0x00001000 // MAC Receive RAM parity error
#define SXG_RCV_STATUS_ADDRESS_MASK 0x00000F00 // Link address detection mask
#define SXG_RCV_STATUS_ADDRESS_D 0x00000B00 // Link address D
#define SXG_RCV_STATUS_ADDRESS_C 0x00000A00 // Link address C
#define SXG_RCV_STATUS_ADDRESS_B 0x00000900 // Link address B
#define SXG_RCV_STATUS_ADDRESS_A 0x00000800 // Link address A
#define SXG_RCV_STATUS_NETWORK_UDP 0x00020000 // UDP
#define SXG_RCV_STATUS_NETWORK_TCP 0x00010000 // TCP
#define SXG_RCV_STATUS_IPONLY 0x00008000 // IP-only not TCP
#define SXG_RCV_STATUS_PKT_PRI 0x00006000 // Receive priority
#define SXG_RCV_STATUS_PKT_PRI_SHFT 13 // Receive priority shift
#define SXG_RCV_STATUS_PARITY 0x00001000 // MAC Receive RAM parity error
#define SXG_RCV_STATUS_ADDRESS_MASK 0x00000F00 // Link address detection mask
#define SXG_RCV_STATUS_ADDRESS_D 0x00000B00 // Link address D
#define SXG_RCV_STATUS_ADDRESS_C 0x00000A00 // Link address C
#define SXG_RCV_STATUS_ADDRESS_B 0x00000900 // Link address B
#define SXG_RCV_STATUS_ADDRESS_A 0x00000800 // Link address A
#define SXG_RCV_STATUS_ADDRESS_BCAST 0x00000300 // Link address broadcast
#define SXG_RCV_STATUS_ADDRESS_MCAST 0x00000200 // Link address multicast
#define SXG_RCV_STATUS_ADDRESS_CMCAST 0x00000100 // Link control multicast
#define SXG_RCV_STATUS_LINK_MASK 0x000000FF // Link status mask
#define SXG_RCV_STATUS_LINK_ERROR 0x00000080 // Link error
#define SXG_RCV_STATUS_LINK_MASK 0x000000FF // Link status mask
#define SXG_RCV_STATUS_LINK_PARITY 0x00000087 // RcvMacQ parity error
#define SXG_RCV_STATUS_LINK_EARLY 0x00000086 // Data early
#define SXG_RCV_STATUS_LINK_MASK 0x000000FF // Link status mask
#define SXG_RCV_STATUS_LINK_ERROR 0x00000080 // Link error
#define SXG_RCV_STATUS_LINK_MASK 0x000000FF // Link status mask
#define SXG_RCV_STATUS_LINK_PARITY 0x00000087 // RcvMacQ parity error
#define SXG_RCV_STATUS_LINK_EARLY 0x00000086 // Data early
#define SXG_RCV_STATUS_LINK_BUFOFLOW 0x00000085 // Buffer overflow
#define SXG_RCV_STATUS_LINK_CODE 0x00000084 // Link code error
#define SXG_RCV_STATUS_LINK_DRIBBLE 0x00000083 // Dribble nibble
#define SXG_RCV_STATUS_LINK_CRC 0x00000082 // CRC error
#define SXG_RCV_STATUS_LINK_OFLOW 0x00000081 // Link overflow
#define SXG_RCV_STATUS_LINK_UFLOW 0x00000080 // Link underflow
#define SXG_RCV_STATUS_LINK_8023 0x00000020 // 802.3
#define SXG_RCV_STATUS_LINK_SNAP 0x00000010 // Snap
#define SXG_RCV_STATUS_LINK_VLAN 0x00000008 // VLAN
#define SXG_RCV_STATUS_LINK_CODE 0x00000084 // Link code error
#define SXG_RCV_STATUS_LINK_DRIBBLE 0x00000083 // Dribble nibble
#define SXG_RCV_STATUS_LINK_CRC 0x00000082 // CRC error
#define SXG_RCV_STATUS_LINK_OFLOW 0x00000081 // Link overflow
#define SXG_RCV_STATUS_LINK_UFLOW 0x00000080 // Link underflow
#define SXG_RCV_STATUS_LINK_8023 0x00000020 // 802.3
#define SXG_RCV_STATUS_LINK_SNAP 0x00000010 // Snap
#define SXG_RCV_STATUS_LINK_VLAN 0x00000008 // VLAN
#define SXG_RCV_STATUS_LINK_TYPE_MASK 0x00000007 // Network type mask
#define SXG_RCV_STATUS_LINK_CONTROL 0x00000003 // Control packet
#define SXG_RCV_STATUS_LINK_IPV6 0x00000002 // IPv6 packet
#define SXG_RCV_STATUS_LINK_IPV4 0x00000001 // IPv4 packet
#define SXG_RCV_STATUS_LINK_CONTROL 0x00000003 // Control packet
#define SXG_RCV_STATUS_LINK_IPV6 0x00000002 // IPv6 packet
#define SXG_RCV_STATUS_LINK_IPV4 0x00000001 // IPv4 packet
/***************************************************************************
* Sahara receive and transmit configuration registers
***************************************************************************/
#define RCV_CONFIG_RESET 0x80000000 // RcvConfig register reset
#define RCV_CONFIG_ENABLE 0x40000000 // Enable the receive logic
#define RCV_CONFIG_ENPARSE 0x20000000 // Enable the receive parser
#define RCV_CONFIG_SOCKET 0x10000000 // Enable the socket detector
#define RCV_CONFIG_RCVBAD 0x08000000 // Receive all bad frames
#define RCV_CONFIG_CONTROL 0x04000000 // Receive all control frames
#define RCV_CONFIG_RCVPAUSE 0x02000000 // Enable pause transmit when attn
#define RCV_CONFIG_TZIPV6 0x01000000 // Include TCP port w/ IPv6 toeplitz
#define RCV_CONFIG_TZIPV4 0x00800000 // Include TCP port w/ IPv4 toeplitz
#define RCV_CONFIG_FLUSH 0x00400000 // Flush buffers
#define RCV_CONFIG_RESET 0x80000000 // RcvConfig register reset
#define RCV_CONFIG_ENABLE 0x40000000 // Enable the receive logic
#define RCV_CONFIG_ENPARSE 0x20000000 // Enable the receive parser
#define RCV_CONFIG_SOCKET 0x10000000 // Enable the socket detector
#define RCV_CONFIG_RCVBAD 0x08000000 // Receive all bad frames
#define RCV_CONFIG_CONTROL 0x04000000 // Receive all control frames
#define RCV_CONFIG_RCVPAUSE 0x02000000 // Enable pause transmit when attn
#define RCV_CONFIG_TZIPV6 0x01000000 // Include TCP port w/ IPv6 toeplitz
#define RCV_CONFIG_TZIPV4 0x00800000 // Include TCP port w/ IPv4 toeplitz
#define RCV_CONFIG_FLUSH 0x00400000 // Flush buffers
#define RCV_CONFIG_PRIORITY_MASK 0x00300000 // Priority level
#define RCV_CONFIG_HASH_MASK 0x00030000 // Hash depth
#define RCV_CONFIG_HASH_8 0x00000000 // Hash depth 8
#define RCV_CONFIG_HASH_16 0x00010000 // Hash depth 16
#define RCV_CONFIG_HASH_4 0x00020000 // Hash depth 4
#define RCV_CONFIG_HASH_2 0x00030000 // Hash depth 2
#define RCV_CONFIG_HASH_8 0x00000000 // Hash depth 8
#define RCV_CONFIG_HASH_16 0x00010000 // Hash depth 16
#define RCV_CONFIG_HASH_4 0x00020000 // Hash depth 4
#define RCV_CONFIG_HASH_2 0x00030000 // Hash depth 2
#define RCV_CONFIG_BUFLEN_MASK 0x0000FFF0 // Buffer length bits 15:4. ie multiple of 16.
#define RCV_CONFIG_SKT_DIS 0x00000008 // Disable socket detection on attn
#define RCV_CONFIG_SKT_DIS 0x00000008 // Disable socket detection on attn
// Macro to determine RCV_CONFIG_BUFLEN based on maximum frame size.
// We add 18 bytes for Sahara receive status and padding, plus 4 bytes for CRC,
// and round up to nearest 16 byte boundary
#define RCV_CONFIG_BUFSIZE(_MaxFrame) ((((_MaxFrame) + 22) + 15) & RCV_CONFIG_BUFLEN_MASK)
#define XMT_CONFIG_RESET 0x80000000 // XmtConfig register reset
#define XMT_CONFIG_ENABLE 0x40000000 // Enable transmit logic
#define XMT_CONFIG_RESET 0x80000000 // XmtConfig register reset
#define XMT_CONFIG_ENABLE 0x40000000 // Enable transmit logic
#define XMT_CONFIG_MAC_PARITY 0x20000000 // Inhibit MAC RAM parity error
#define XMT_CONFIG_BUF_PARITY 0x10000000 // Inhibit D2F buffer parity error
#define XMT_CONFIG_MEM_PARITY 0x08000000 // Inhibit 1T SRAM parity error
@ -249,9 +249,9 @@ typedef struct _SXG_HW_REGS {
// A-XGMAC Configuration Register 1
#define AXGMAC_CFG1_XMT_PAUSE 0x80000000 // Allow the sending of Pause frames
#define AXGMAC_CFG1_XMT_EN 0x40000000 // Enable transmit
#define AXGMAC_CFG1_XMT_EN 0x40000000 // Enable transmit
#define AXGMAC_CFG1_RCV_PAUSE 0x20000000 // Allow the detection of Pause frames
#define AXGMAC_CFG1_RCV_EN 0x10000000 // Enable receive
#define AXGMAC_CFG1_RCV_EN 0x10000000 // Enable receive
#define AXGMAC_CFG1_XMT_STATE 0x04000000 // Current transmit state - READ ONLY
#define AXGMAC_CFG1_RCV_STATE 0x01000000 // Current receive state - READ ONLY
#define AXGMAC_CFG1_XOFF_SHORT 0x00001000 // Only pause for 64 slot on XOFF
@ -262,24 +262,24 @@ typedef struct _SXG_HW_REGS {
#define AXGMAC_CFG1_RCV_FCS2 0x00000200 // Delay receive FCS 2 4-byte words
#define AXGMAC_CFG1_RCV_FCS3 0x00000300 // Delay receive FCS 3 4-byte words
#define AXGMAC_CFG1_PKT_OVERRIDE 0x00000080 // Per-packet override enable
#define AXGMAC_CFG1_SWAP 0x00000040 // Byte swap enable
#define AXGMAC_CFG1_SWAP 0x00000040 // Byte swap enable
#define AXGMAC_CFG1_SHORT_ASSERT 0x00000020 // ASSERT srdrpfrm on short frame (<64)
#define AXGMAC_CFG1_RCV_STRICT 0x00000010 // RCV only 802.3AE when CLEAR
#define AXGMAC_CFG1_CHECK_LEN 0x00000008 // Verify frame length
#define AXGMAC_CFG1_GEN_FCS 0x00000004 // Generate FCS
#define AXGMAC_CFG1_GEN_FCS 0x00000004 // Generate FCS
#define AXGMAC_CFG1_PAD_MASK 0x00000003 // Mask for pad bits
#define AXGMAC_CFG1_PAD_64 0x00000001 // Pad frames to 64 bytes
#define AXGMAC_CFG1_PAD_64 0x00000001 // Pad frames to 64 bytes
#define AXGMAC_CFG1_PAD_VLAN 0x00000002 // Detect VLAN and pad to 68 bytes
#define AXGMAC_CFG1_PAD_68 0x00000003 // Pad to 68 bytes
#define AXGMAC_CFG1_PAD_68 0x00000003 // Pad to 68 bytes
// A-XGMAC Configuration Register 2
#define AXGMAC_CFG2_GEN_PAUSE 0x80000000 // Generate single pause frame (test)
#define AXGMAC_CFG2_LF_MANUAL 0x08000000 // Manual link fault sequence
#define AXGMAC_CFG2_LF_AUTO 0x04000000 // Auto link fault sequence
#define AXGMAC_CFG2_LF_AUTO 0x04000000 // Auto link fault sequence
#define AXGMAC_CFG2_LF_REMOTE 0x02000000 // Remote link fault (READ ONLY)
#define AXGMAC_CFG2_LF_LOCAL 0x01000000 // Local link fault (READ ONLY)
#define AXGMAC_CFG2_IPG_MASK 0x001F0000 // Inter packet gap
#define AXGMAC_CFG2_IPG_SHIFT 16
#define AXGMAC_CFG2_IPG_SHIFT 16
#define AXGMAC_CFG2_PAUSE_XMT 0x00008000 // Pause transmit module
#define AXGMAC_CFG2_IPG_EXTEN 0x00000020 // Enable IPG extension algorithm
#define AXGMAC_CFG2_IPGEX_MASK 0x0000001F // IPG extension
@ -299,9 +299,9 @@ typedef struct _SXG_HW_REGS {
#define AXGMAC_SARHIGH_OCTET_SIX 0x00FF0000 // Sixth octet
// A-XGMAC Maximum frame length register
#define AXGMAC_MAXFRAME_XMT 0x3FFF0000 // Maximum transmit frame length
#define AXGMAC_MAXFRAME_XMT 0x3FFF0000 // Maximum transmit frame length
#define AXGMAC_MAXFRAME_XMT_SHIFT 16
#define AXGMAC_MAXFRAME_RCV 0x0000FFFF // Maximum receive frame length
#define AXGMAC_MAXFRAME_RCV 0x0000FFFF // Maximum receive frame length
// This register doesn't need to be written for standard MTU.
// For jumbo, I'll just statically define the value here. This
// value sets the receive byte count to 9036 (0x234C) and the
@ -324,34 +324,34 @@ typedef struct _SXG_HW_REGS {
// A-XGMAC AMIIM Field Register
#define AXGMAC_AMIIM_FIELD_ST 0xC0000000 // 2-bit ST field
#define AXGMAC_AMIIM_FIELD_ST_SHIFT 30
#define AXGMAC_AMIIM_FIELD_ST_SHIFT 30
#define AXGMAC_AMIIM_FIELD_OP 0x30000000 // 2-bit OP field
#define AXGMAC_AMIIM_FIELD_OP_SHIFT 28
#define AXGMAC_AMIIM_FIELD_PORT_ADDR 0x0F800000 // Port address field (hstphyadx in spec)
#define AXGMAC_AMIIM_FIELD_OP_SHIFT 28
#define AXGMAC_AMIIM_FIELD_PORT_ADDR 0x0F800000 // Port address field (hstphyadx in spec)
#define AXGMAC_AMIIM_FIELD_PORT_SHIFT 23
#define AXGMAC_AMIIM_FIELD_DEV_ADDR 0x007C0000 // Device address field (hstregadx in spec)
#define AXGMAC_AMIIM_FIELD_DEV_SHIFT 18
#define AXGMAC_AMIIM_FIELD_TA 0x00030000 // 2-bit TA field
#define AXGMAC_AMIIM_FIELD_TA_SHIFT 16
#define AXGMAC_AMIIM_FIELD_TA_SHIFT 16
#define AXGMAC_AMIIM_FIELD_DATA 0x0000FFFF // Data field
// Values for the AXGMAC_AMIIM_FIELD_OP field in the A-XGMAC AMIIM Field Register
#define MIIM_OP_ADDR 0 // MIIM Address set operation
#define MIIM_OP_WRITE 1 // MIIM Write register operation
#define MIIM_OP_READ 2 // MIIM Read register operation
#define MIIM_OP_ADDR 0 // MIIM Address set operation
#define MIIM_OP_WRITE 1 // MIIM Write register operation
#define MIIM_OP_READ 2 // MIIM Read register operation
#define MIIM_OP_ADDR_SHIFT (MIIM_OP_ADDR << AXGMAC_AMIIM_FIELD_OP_SHIFT)
// Values for the AXGMAC_AMIIM_FIELD_PORT_ADDR field in the A-XGMAC AMIIM Field Register
#define MIIM_PORT_NUM 1 // All Sahara MIIM modules use port 1
#define MIIM_PORT_NUM 1 // All Sahara MIIM modules use port 1
// Values for the AXGMAC_AMIIM_FIELD_DEV_ADDR field in the A-XGMAC AMIIM Field Register
#define MIIM_DEV_PHY_PMA 1 // PHY PMA/PMD module MIIM device number
#define MIIM_DEV_PHY_PCS 3 // PHY PCS module MIIM device number
#define MIIM_DEV_PHY_XS 4 // PHY XS module MIIM device number
#define MIIM_DEV_XGXS 5 // XGXS MIIM device number
#define MIIM_DEV_PHY_PMA 1 // PHY PMA/PMD module MIIM device number
#define MIIM_DEV_PHY_PCS 3 // PHY PCS module MIIM device number
#define MIIM_DEV_PHY_XS 4 // PHY XS module MIIM device number
#define MIIM_DEV_XGXS 5 // XGXS MIIM device number
// Values for the AXGMAC_AMIIM_FIELD_TA field in the A-XGMAC AMIIM Field Register
#define MIIM_TA_10GB 2 // set to 2 for 10 GB operation
#define MIIM_TA_10GB 2 // set to 2 for 10 GB operation
// A-XGMAC AMIIM Configuration Register
#define AXGMAC_AMIIM_CFG_NOPREAM 0x00000080 // Bypass preamble of mngmt frame
@ -365,25 +365,25 @@ typedef struct _SXG_HW_REGS {
#define AXGMAC_AMIIM_INDC_BUSY 0x00000001 // Set until cmd operation complete
// Link Status and Control Register
#define LS_PHY_CLR_RESET 0x80000000 // Clear reset signal to PHY
#define LS_PHY_CLR_RESET 0x80000000 // Clear reset signal to PHY
#define LS_SERDES_POWER_DOWN 0x40000000 // Power down the Sahara Serdes
#define LS_XGXS_ENABLE 0x20000000 // Enable the XAUI XGXS logic
#define LS_XGXS_CTL 0x10000000 // Hold XAUI XGXS logic reset until Serdes is up
#define LS_SERDES_DOWN 0x08000000 // When 0, XAUI Serdes is up and initialization is complete
#define LS_TRACE_DOWN 0x04000000 // When 0, Trace Serdes is up and initialization is complete
#define LS_PHY_CLK_25MHZ 0x02000000 // Set PHY clock to 25 MHz (else 156.125 MHz)
#define LS_PHY_CLK_EN 0x01000000 // Enable clock to PHY
#define LS_XAUI_LINK_UP 0x00000010 // XAUI link is up
#define LS_XAUI_LINK_CHNG 0x00000008 // XAUI link status has changed
#define LS_LINK_ALARM 0x00000004 // Link alarm pin
#define LS_ATTN_CTRL_MASK 0x00000003 // Mask link attention control bits
#define LS_ATTN_ALARM 0x00000000 // 00 => Attn on link alarm
#define LS_XGXS_ENABLE 0x20000000 // Enable the XAUI XGXS logic
#define LS_XGXS_CTL 0x10000000 // Hold XAUI XGXS logic reset until Serdes is up
#define LS_SERDES_DOWN 0x08000000 // When 0, XAUI Serdes is up and initialization is complete
#define LS_TRACE_DOWN 0x04000000 // When 0, Trace Serdes is up and initialization is complete
#define LS_PHY_CLK_25MHZ 0x02000000 // Set PHY clock to 25 MHz (else 156.125 MHz)
#define LS_PHY_CLK_EN 0x01000000 // Enable clock to PHY
#define LS_XAUI_LINK_UP 0x00000010 // XAUI link is up
#define LS_XAUI_LINK_CHNG 0x00000008 // XAUI link status has changed
#define LS_LINK_ALARM 0x00000004 // Link alarm pin
#define LS_ATTN_CTRL_MASK 0x00000003 // Mask link attention control bits
#define LS_ATTN_ALARM 0x00000000 // 00 => Attn on link alarm
#define LS_ATTN_ALARM_OR_STAT_CHNG 0x00000001 // 01 => Attn on link alarm or status change
#define LS_ATTN_STAT_CHNG 0x00000002 // 10 => Attn on link status change
#define LS_ATTN_NONE 0x00000003 // 11 => no Attn
#define LS_ATTN_STAT_CHNG 0x00000002 // 10 => Attn on link status change
#define LS_ATTN_NONE 0x00000003 // 11 => no Attn
// Link Address High Registers
#define LINK_ADDR_ENABLE 0x80000000 // Enable this link address
#define LINK_ADDR_ENABLE 0x80000000 // Enable this link address
/***************************************************************************
@ -396,7 +396,7 @@ typedef struct _SXG_HW_REGS {
#define XGXS_ADDRESS_STATUS1 0x0001 // XS Status 1
#define XGXS_ADDRESS_DEVID_LOW 0x0002 // XS Device ID (low)
#define XGXS_ADDRESS_DEVID_HIGH 0x0003 // XS Device ID (high)
#define XGXS_ADDRESS_SPEED 0x0004 // XS Speed ability
#define XGXS_ADDRESS_SPEED 0x0004 // XS Speed ability
#define XGXS_ADDRESS_DEV_LOW 0x0005 // XS Devices in package
#define XGXS_ADDRESS_DEV_HIGH 0x0006 // XS Devices in package
#define XGXS_ADDRESS_STATUS2 0x0008 // XS Status 2
@ -410,27 +410,27 @@ typedef struct _SXG_HW_REGS {
#define XGXS_ADDRESS_RESET_HI2 0x8003 // Vendor-Specific Reset Hi 2
// XS Control 1 register bit definitions
#define XGXS_CONTROL1_RESET 0x8000 // Reset - self clearing
#define XGXS_CONTROL1_RESET 0x8000 // Reset - self clearing
#define XGXS_CONTROL1_LOOPBACK 0x4000 // Enable loopback
#define XGXS_CONTROL1_SPEED1 0x2000 // 0 = unspecified, 1 = 10Gb+
#define XGXS_CONTROL1_LOWPOWER 0x0400 // 1 = Low power mode
#define XGXS_CONTROL1_SPEED2 0x0040 // Same as SPEED1 (?)
#define XGXS_CONTROL1_SPEED 0x003C // Everything reserved except zero (?)
#define XGXS_CONTROL1_SPEED 0x003C // Everything reserved except zero (?)
// XS Status 1 register bit definitions
#define XGXS_STATUS1_FAULT 0x0080 // Fault detected
#define XGXS_STATUS1_LINK 0x0004 // 1 = Link up
#define XGXS_STATUS1_FAULT 0x0080 // Fault detected
#define XGXS_STATUS1_LINK 0x0004 // 1 = Link up
#define XGXS_STATUS1_LOWPOWER 0x0002 // 1 = Low power supported
// XS Speed register bit definitions
#define XGXS_SPEED_10G 0x0001 // 1 = 10G capable
#define XGXS_SPEED_10G 0x0001 // 1 = 10G capable
// XS Devices register bit definitions
#define XGXS_DEVICES_DTE 0x0020 // DTE XS Present
#define XGXS_DEVICES_PHY 0x0010 // PHY XS Present
#define XGXS_DEVICES_PCS 0x0008 // PCS Present
#define XGXS_DEVICES_WIS 0x0004 // WIS Present
#define XGXS_DEVICES_PMD 0x0002 // PMD/PMA Present
#define XGXS_DEVICES_DTE 0x0020 // DTE XS Present
#define XGXS_DEVICES_PHY 0x0010 // PHY XS Present
#define XGXS_DEVICES_PCS 0x0008 // PCS Present
#define XGXS_DEVICES_WIS 0x0004 // WIS Present
#define XGXS_DEVICES_PMD 0x0002 // PMD/PMA Present
#define XGXS_DEVICES_CLAUSE22 0x0001 // Clause 22 registers present
// XS Devices High register bit definitions
@ -444,18 +444,18 @@ typedef struct _SXG_HW_REGS {
#define XGXS_STATUS2_RCV_FAULT 0x0400 // Receive fault
// XS Package ID High register bit definitions
#define XGXS_PKGID_HIGH_ORG 0xFC00 // Organizationally Unique
#define XGXS_PKGID_HIGH_MFG 0x03F0 // Manufacturer Model
#define XGXS_PKGID_HIGH_REV 0x000F // Revision Number
#define XGXS_PKGID_HIGH_ORG 0xFC00 // Organizationally Unique
#define XGXS_PKGID_HIGH_MFG 0x03F0 // Manufacturer Model
#define XGXS_PKGID_HIGH_REV 0x000F // Revision Number
// XS Lane Status register bit definitions
#define XGXS_LANE_PHY 0x1000 // PHY/DTE lane alignment status
#define XGXS_LANE_PATTERN 0x0800 // Pattern testing ability
#define XGXS_LANE_LOOPBACK 0x0400 // PHY loopback ability
#define XGXS_LANE_SYNC3 0x0008 // Lane 3 sync
#define XGXS_LANE_SYNC2 0x0004 // Lane 2 sync
#define XGXS_LANE_SYNC1 0x0002 // Lane 1 sync
#define XGXS_LANE_SYNC0 0x0001 // Lane 0 sync
#define XGXS_LANE_PHY 0x1000 // PHY/DTE lane alignment status
#define XGXS_LANE_PATTERN 0x0800 // Pattern testing ability
#define XGXS_LANE_LOOPBACK 0x0400 // PHY loopback ability
#define XGXS_LANE_SYNC3 0x0008 // Lane 3 sync
#define XGXS_LANE_SYNC2 0x0004 // Lane 2 sync
#define XGXS_LANE_SYNC1 0x0002 // Lane 1 sync
#define XGXS_LANE_SYNC0 0x0001 // Lane 0 sync
// XS Test Control register bit definitions
#define XGXS_TEST_PATTERN_ENABLE 0x0004 // Test pattern enabled
@ -473,10 +473,10 @@ typedef struct _SXG_HW_REGS {
// LASI (Link Alarm Status Interrupt) Registers (located in MIIM_DEV_PHY_PMA device)
#define LASI_RX_ALARM_CONTROL 0x9000 // LASI RX_ALARM Control
#define LASI_TX_ALARM_CONTROL 0x9001 // LASI TX_ALARM Control
#define LASI_CONTROL 0x9002 // LASI Control
#define LASI_CONTROL 0x9002 // LASI Control
#define LASI_RX_ALARM_STATUS 0x9003 // LASI RX_ALARM Status
#define LASI_TX_ALARM_STATUS 0x9004 // LASI TX_ALARM Status
#define LASI_STATUS 0x9005 // LASI Status
#define LASI_STATUS 0x9005 // LASI Status
// LASI_CONTROL bit definitions
#define LASI_CTL_RX_ALARM_ENABLE 0x0004 // Enable RX_ALARM interrupts
@ -489,34 +489,34 @@ typedef struct _SXG_HW_REGS {
#define LASI_STATUS_LS_ALARM 0x0001 // Link Status
// PHY registers - PMA/PMD (device 1)
#define PHY_PMA_CONTROL1 0x0000 // PMA/PMD Control 1
#define PHY_PMA_STATUS1 0x0001 // PMA/PMD Status 1
#define PHY_PMA_RCV_DET 0x000A // PMA/PMD Receive Signal Detect
#define PHY_PMA_CONTROL1 0x0000 // PMA/PMD Control 1
#define PHY_PMA_STATUS1 0x0001 // PMA/PMD Status 1
#define PHY_PMA_RCV_DET 0x000A // PMA/PMD Receive Signal Detect
// other PMA/PMD registers exist and can be defined as needed
// PHY registers - PCS (device 3)
#define PHY_PCS_CONTROL1 0x0000 // PCS Control 1
#define PHY_PCS_STATUS1 0x0001 // PCS Status 1
#define PHY_PCS_10G_STATUS1 0x0020 // PCS 10GBASE-R Status 1
#define PHY_PCS_CONTROL1 0x0000 // PCS Control 1
#define PHY_PCS_STATUS1 0x0001 // PCS Status 1
#define PHY_PCS_10G_STATUS1 0x0020 // PCS 10GBASE-R Status 1
// other PCS registers exist and can be defined as needed
// PHY registers - XS (device 4)
#define PHY_XS_CONTROL1 0x0000 // XS Control 1
#define PHY_XS_STATUS1 0x0001 // XS Status 1
#define PHY_XS_LANE_STATUS 0x0018 // XS Lane Status
#define PHY_XS_CONTROL1 0x0000 // XS Control 1
#define PHY_XS_STATUS1 0x0001 // XS Status 1
#define PHY_XS_LANE_STATUS 0x0018 // XS Lane Status
// other XS registers exist and can be defined as needed
// PHY_PMA_CONTROL1 register bit definitions
#define PMA_CONTROL1_RESET 0x8000 // PMA/PMD reset
#define PMA_CONTROL1_RESET 0x8000 // PMA/PMD reset
// PHY_PMA_RCV_DET register bit definitions
#define PMA_RCV_DETECT 0x0001 // PMA/PMD receive signal detect
#define PMA_RCV_DETECT 0x0001 // PMA/PMD receive signal detect
// PHY_PCS_10G_STATUS1 register bit definitions
#define PCS_10B_BLOCK_LOCK 0x0001 // PCS 10GBASE-R locked to receive blocks
#define PCS_10B_BLOCK_LOCK 0x0001 // PCS 10GBASE-R locked to receive blocks
// PHY_XS_LANE_STATUS register bit definitions
#define XS_LANE_ALIGN 0x1000 // XS transmit lanes aligned
#define XS_LANE_ALIGN 0x1000 // XS transmit lanes aligned
// PHY Microcode download data structure
typedef struct _PHY_UCODE {
@ -558,8 +558,8 @@ typedef struct _XMT_DESC {
// command codes
#define XMT_DESC_CMD_RAW_SEND 0 // raw send descriptor
#define XMT_DESC_CMD_CSUM_INSERT 1 // checksum insert descriptor
#define XMT_DESC_CMD_FORMAT 2 // format descriptor
#define XMT_DESC_CMD_PRIME 3 // prime descriptor
#define XMT_DESC_CMD_FORMAT 2 // format descriptor
#define XMT_DESC_CMD_PRIME 3 // prime descriptor
#define XMT_DESC_CMD_CODE_SHFT 6 // comand code shift (shift to bits [31:30] in word 0)
// shifted command codes
#define XMT_RAW_SEND (XMT_DESC_CMD_RAW_SEND << XMT_DESC_CMD_CODE_SHFT)
@ -569,22 +569,22 @@ typedef struct _XMT_DESC {
// XMT_DESC Control Byte (XmtCtl) definitions
// NOTE: These bits do not work on Sahara (Rev A)!
#define XMT_CTL_PAUSE_FRAME 0x80 // current frame is a pause control frame (for statistics)
#define XMT_CTL_PAUSE_FRAME 0x80 // current frame is a pause control frame (for statistics)
#define XMT_CTL_CONTROL_FRAME 0x40 // current frame is a control frame (for statistics)
#define XMT_CTL_PER_PKT_QUAL 0x20 // per packet qualifier
#define XMT_CTL_PAD_MODE_NONE 0x00 // do not pad frame
#define XMT_CTL_PAD_MODE_64 0x08 // pad frame to 64 bytes
#define XMT_CTL_PAD_MODE_64 0x08 // pad frame to 64 bytes
#define XMT_CTL_PAD_MODE_VLAN_68 0x10 // pad frame to 64 bytes, and VLAN frames to 68 bytes
#define XMT_CTL_PAD_MODE_68 0x18 // pad frame to 68 bytes
#define XMT_CTL_GEN_FCS 0x04 // generate FCS (CRC) for this frame
#define XMT_CTL_DELAY_FCS_0 0x00 // do not delay FCS calcution
#define XMT_CTL_DELAY_FCS_1 0x01 // delay FCS calculation by 1 (4-byte) word
#define XMT_CTL_DELAY_FCS_2 0x02 // delay FCS calculation by 2 (4-byte) words
#define XMT_CTL_DELAY_FCS_3 0x03 // delay FCS calculation by 3 (4-byte) words
#define XMT_CTL_PAD_MODE_68 0x18 // pad frame to 68 bytes
#define XMT_CTL_GEN_FCS 0x04 // generate FCS (CRC) for this frame
#define XMT_CTL_DELAY_FCS_0 0x00 // do not delay FCS calcution
#define XMT_CTL_DELAY_FCS_1 0x01 // delay FCS calculation by 1 (4-byte) word
#define XMT_CTL_DELAY_FCS_2 0x02 // delay FCS calculation by 2 (4-byte) words
#define XMT_CTL_DELAY_FCS_3 0x03 // delay FCS calculation by 3 (4-byte) words
// XMT_DESC XmtBufId definition
#define XMT_BUF_ID_SHFT 8 // The Xmt buffer ID is formed by dividing
// the buffer (DRAM) address by 256 (or << 8)
#define XMT_BUF_ID_SHFT 8 // The Xmt buffer ID is formed by dividing
// the buffer (DRAM) address by 256 (or << 8)
/*****************************************************************************
* Receiver Sequencer Definitions
@ -594,8 +594,8 @@ typedef struct _XMT_DESC {
#define RCV_EVTQ_RBFID_MASK 0x0000FFFF // bit mask for the Receive Buffer ID
// Receive Buffer ID definition
#define RCV_BUF_ID_SHFT 5 // The Rcv buffer ID is formed by dividing
// the buffer (DRAM) address by 32 (or << 5)
#define RCV_BUF_ID_SHFT 5 // The Rcv buffer ID is formed by dividing
// the buffer (DRAM) address by 32 (or << 5)
// Format of the 18 byte Receive Buffer returned by the
// Receive Sequencer for received packets
@ -623,48 +623,48 @@ typedef struct _RCV_BUF_HDR {
* Queue definitions
*****************************************************************************/
// Ingress (read only) queue numbers
#define PXY_BUF_Q 0 // Proxy Buffer Queue
#define HST_EVT_Q 1 // Host Event Queue
#define XMT_BUF_Q 2 // Transmit Buffer Queue
#define SKT_EVL_Q 3 // RcvSqr Socket Event Low Priority Queue
#define RCV_EVL_Q 4 // RcvSqr Rcv Event Low Priority Queue
#define SKT_EVH_Q 5 // RcvSqr Socket Event High Priority Queue
#define RCV_EVH_Q 6 // RcvSqr Rcv Event High Priority Queue
#define DMA_RSP_Q 7 // Dma Response Queue - one per CPU context
// Local (read/write) queue numbers
#define LOCAL_A_Q 8 // Spare local Queue
#define LOCAL_B_Q 9 // Spare local Queue
#define LOCAL_C_Q 10 // Spare local Queue
#define FSM_EVT_Q 11 // Finite-State-Machine Event Queue
#define SBF_PAL_Q 12 // System Buffer Physical Address (low) Queue
#define SBF_PAH_Q 13 // System Buffer Physical Address (high) Queue
#define SBF_VAL_Q 14 // System Buffer Virtual Address (low) Queue
#define SBF_VAH_Q 15 // System Buffer Virtual Address (high) Queue
// Egress (write only) queue numbers
#define H2G_CMD_Q 16 // Host to GlbRam DMA Command Queue
#define H2D_CMD_Q 17 // Host to DRAM DMA Command Queue
#define G2H_CMD_Q 18 // GlbRam to Host DMA Command Queue
#define G2D_CMD_Q 19 // GlbRam to DRAM DMA Command Queue
#define D2H_CMD_Q 20 // DRAM to Host DMA Command Queue
#define D2G_CMD_Q 21 // DRAM to GlbRam DMA Command Queue
#define D2D_CMD_Q 22 // DRAM to DRAM DMA Command Queue
#define PXL_CMD_Q 23 // Low Priority Proxy Command Queue
#define PXH_CMD_Q 24 // High Priority Proxy Command Queue
#define RSQ_CMD_Q 25 // Receive Sequencer Command Queue
#define RCV_BUF_Q 26 // Receive Buffer Queue
/* Ingress (read only) queue numbers */
#define PXY_BUF_Q 0 /* Proxy Buffer Queue */
#define HST_EVT_Q 1 /* Host Event Queue */
#define XMT_BUF_Q 2 /* Transmit Buffer Queue */
#define SKT_EVL_Q 3 /* RcvSqr Socket Event Low Priority Queue */
#define RCV_EVL_Q 4 /* RcvSqr Rcv Event Low Priority Queue */
#define SKT_EVH_Q 5 /* RcvSqr Socket Event High Priority Queue */
#define RCV_EVH_Q 6 /* RcvSqr Rcv Event High Priority Queue */
#define DMA_RSP_Q 7 /* Dma Response Queue - one per CPU context */
/* Local (read/write) queue numbers */
#define LOCAL_A_Q 8 /* Spare local Queue */
#define LOCAL_B_Q 9 /* Spare local Queue */
#define LOCAL_C_Q 10 /* Spare local Queue */
#define FSM_EVT_Q 11 /* Finite-State-Machine Event Queue */
#define SBF_PAL_Q 12 /* System Buffer Physical Address (low) Queue */
#define SBF_PAH_Q 13 /* System Buffer Physical Address (high) Queue */
#define SBF_VAL_Q 14 /* System Buffer Virtual Address (low) Queue */
#define SBF_VAH_Q 15 /* System Buffer Virtual Address (high) Queue */
/* Egress (write only) queue numbers */
#define H2G_CMD_Q 16 /* Host to GlbRam DMA Command Queue */
#define H2D_CMD_Q 17 /* Host to DRAM DMA Command Queue */
#define G2H_CMD_Q 18 /* GlbRam to Host DMA Command Queue */
#define G2D_CMD_Q 19 /* GlbRam to DRAM DMA Command Queue */
#define D2H_CMD_Q 20 /* DRAM to Host DMA Command Queue */
#define D2G_CMD_Q 21 /* DRAM to GlbRam DMA Command Queue */
#define D2D_CMD_Q 22 /* DRAM to DRAM DMA Command Queue */
#define PXL_CMD_Q 23 /* Low Priority Proxy Command Queue */
#define PXH_CMD_Q 24 /* High Priority Proxy Command Queue */
#define RSQ_CMD_Q 25 /* Receive Sequencer Command Queue */
#define RCV_BUF_Q 26 /* Receive Buffer Queue */
// Bit definitions for the Proxy Command queues (PXL_CMD_Q and PXH_CMD_Q)
#define PXY_COPY_EN 0x00200000 // enable copy of xmt descriptor to xmt command queue
#define PXY_SIZE_16 0x00000000 // copy 16 bytes
#define PXY_SIZE_32 0x00100000 // copy 32 bytes
/* Bit definitions for the Proxy Command queues (PXL_CMD_Q and PXH_CMD_Q) */
#define PXY_COPY_EN 0x00200000 /* enable copy of xmt descriptor to xmt command queue */
#define PXY_SIZE_16 0x00000000 /* copy 16 bytes */
#define PXY_SIZE_32 0x00100000 /* copy 32 bytes */
/*****************************************************************************
* SXG EEPROM/Flash Configuration Definitions
*****************************************************************************/
#pragma pack(push, 1)
//
/* */
typedef struct _HW_CFG_DATA {
ushort Addr;
union {
@ -673,22 +673,22 @@ typedef struct _HW_CFG_DATA {
};
} HW_CFG_DATA, *PHW_CFG_DATA;
//
/* */
#define NUM_HW_CFG_ENTRIES ((128/sizeof(HW_CFG_DATA)) - 4)
// MAC address
/* MAC address */
typedef struct _SXG_CONFIG_MAC {
unsigned char MacAddr[6]; // MAC Address
unsigned char MacAddr[6]; /* MAC Address */
} SXG_CONFIG_MAC, *PSXG_CONFIG_MAC;
//
/* */
typedef struct _ATK_FRU {
unsigned char PartNum[6];
unsigned char Revision[2];
unsigned char Serial[14];
} ATK_FRU, *PATK_FRU;
// OEM FRU Format types
/* OEM FRU Format types */
#define ATK_FRU_FORMAT 0x0000
#define CPQ_FRU_FORMAT 0x0001
#define DELL_FRU_FORMAT 0x0002
@ -697,24 +697,24 @@ typedef struct _ATK_FRU {
#define EMC_FRU_FORMAT 0x0005
#define NO_FRU_FORMAT 0xFFFF
// EEPROM/Flash Format
/* EEPROM/Flash Format */
typedef struct _SXG_CONFIG {
//
// Section 1 (128 bytes)
//
ushort MagicWord; // EEPROM/FLASH Magic code 'A5A5'
ushort SpiClks; // SPI bus clock dividers
/* */
/* Section 1 (128 bytes) */
/* */
ushort MagicWord; /* EEPROM/FLASH Magic code 'A5A5' */
ushort SpiClks; /* SPI bus clock dividers */
HW_CFG_DATA HwCfg[NUM_HW_CFG_ENTRIES];
//
//
//
ushort Version; // EEPROM format version
SXG_CONFIG_MAC MacAddr[4]; // space for 4 MAC addresses
ATK_FRU AtkFru; // FRU information
ushort OemFruFormat; // OEM FRU format type
unsigned char OemFru[76]; // OEM FRU information (optional)
ushort Checksum; // Checksum of section 2
// CS info XXXTODO
/* */
/* */
/* */
ushort Version; /* EEPROM format version */
SXG_CONFIG_MAC MacAddr[4]; /* space for 4 MAC addresses */
ATK_FRU AtkFru; /* FRU information */
ushort OemFruFormat; /* OEM FRU format type */
unsigned char OemFru[76]; /* OEM FRU information (optional) */
ushort Checksum; /* Checksum of section 2 */
/* CS info XXXTODO */
} SXG_CONFIG, *PSXG_CONFIG;
#pragma pack(pop)
@ -723,12 +723,12 @@ typedef struct _SXG_CONFIG {
*****************************************************************************/
// Sahara (ASIC level) defines
#define SAHARA_GRAM_SIZE 0x020000 // GRAM size - 128 KB
#define SAHARA_DRAM_SIZE 0x200000 // DRAM size - 2 MB
#define SAHARA_QRAM_SIZE 0x004000 // QRAM size - 16K entries (64 KB)
#define SAHARA_WCS_SIZE 0x002000 // WCS - 8K instructions (x 108 bits)
#define SAHARA_GRAM_SIZE 0x020000 // GRAM size - 128 KB
#define SAHARA_DRAM_SIZE 0x200000 // DRAM size - 2 MB
#define SAHARA_QRAM_SIZE 0x004000 // QRAM size - 16K entries (64 KB)
#define SAHARA_WCS_SIZE 0x002000 // WCS - 8K instructions (x 108 bits)
// Arabia (board level) defines
#define FLASH_SIZE 0x080000 // 512 KB (4 Mb)
#define EEPROM_SIZE_XFMR 512 // true EEPROM size (bytes), including xfmr area
#define EEPROM_SIZE_NO_XFMR 256 // EEPROM size excluding xfmr area
#define FLASH_SIZE 0x080000 // 512 KB (4 Mb)
#define EEPROM_SIZE_XFMR 512 // true EEPROM size (bytes), including xfmr area
#define EEPROM_SIZE_NO_XFMR 256 // EEPROM size excluding xfmr area

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@ -34,7 +34,7 @@ static PHY_UCODE PhyUcode[] = {
*/
/* Addr, Data */
{0xc017, 0xfeb0}, /* flip RX_LOS polarity (mandatory */
/* patch for SFP+ applications) */
/* patch for SFP+ applications) */
{0xC001, 0x0428}, /* flip RX serial polarity */
{0xc013, 0xf341}, /* invert lxmit clock (mandatory patch) */
@ -43,7 +43,7 @@ static PHY_UCODE PhyUcode[] = {
{0xc210, 0x8000}, /* reset datapath (mandatory patch) */
{0xc210, 0x0000}, /* reset datapath (mandatory patch) */
{0x0000, 0x0032}, /* wait for 50ms for datapath reset to */
/* complete. (mandatory patch) */
/* complete. (mandatory patch) */
/* Configure the LED's */
{0xc214, 0x0099}, /* configure the LED drivers */
@ -52,15 +52,15 @@ static PHY_UCODE PhyUcode[] = {
/* Transceiver-specific MDIO Patches: */
{0xc010, 0x448a}, /* (bit 14) mask out high BER input from the */
/* LOS signal in 1.000A */
/* (mandatory patch for SR code)*/
/* LOS signal in 1.000A */
/* (mandatory patch for SR code) */
{0xc003, 0x0181}, /* (bit 7) enable the CDR inc setting in */
/* 1.C005 (mandatory patch for SR code) */
/* 1.C005 (mandatory patch for SR code) */
/* Transceiver-specific Microcontroller Initialization: */
{0xc04a, 0x5200}, /* activate microcontroller and pause */
{0x0000, 0x0032}, /* wait 50ms for microcontroller before */
/* writing in code. */
/* writing in code. */
/* code block starts here: */
{0xcc00, 0x2009},

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@ -221,7 +221,7 @@ static void usbip_dump_request_type(__u8 rt)
static void usbip_dump_usb_ctrlrequest(struct usb_ctrlrequest *cmd)
{
if (!cmd) {
printk(" %s : null pointer\n", __FUNCTION__);
printk(" %s : null pointer\n", __func__);
return;
}

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@ -202,7 +202,7 @@ static void vhci_rx_pdu(struct usbip_device *ud)
ret = usbip_xmit(0, ud->tcp_socket, (char *) &pdu, sizeof(pdu), 0);
if (ret != sizeof(pdu)) {
uerr("receiving pdu failed! size is %d, should be %d\n",
ret, sizeof(pdu));
ret, (unsigned int)sizeof(pdu));
usbip_event_add(ud, VDEV_EVENT_ERROR_TCP);
return;
}

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@ -1,6 +1,6 @@
config W35UND
tristate "Winbond driver"
depends on MAC80211 && WLAN_80211 && EXPERIMENTAL && !4KSTACKS
depends on MAC80211 && WLAN_80211 && USB && EXPERIMENTAL && !4KSTACKS
default n
---help---
This is highly experimental driver for winbond wifi card on some Kohjinsha notebooks

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@ -5,6 +5,7 @@ TODO:
- remove typedefs
- remove unused ioctls
- use cfg80211 for regulatory stuff
- fix 4k stack problems
Please send patches to Greg Kroah-Hartman <greg@kroah.com> and
Pavel Machek <pavel@suse.cz>

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@ -24,7 +24,7 @@ void DesiredRate2InfoElement(PWB32_ADAPTER Adapter, u8 *addr, u16 *iFildOffset,
u8 *pBasicRateSet, u8 BasicRateCount,
u8 *pOperationRateSet, u8 OperationRateCount);
void BSSAddIBSSdata(PWB32_ADAPTER Adapter, PWB_BSSDESCRIPTION psDesData);
unsigned char boCmpMacAddr( PUCHAR, PUCHAR );
unsigned char boCmpMacAddr( u8 *, u8 *);
unsigned char boCmpSSID(struct SSID_Element *psSSID1, struct SSID_Element *psSSID2);
u16 wBSSfindSSID(PWB32_ADAPTER Adapter, struct SSID_Element *psSsid);
u16 wRoamingQuery(PWB32_ADAPTER Adapter);
@ -42,11 +42,11 @@ void RateReSortForSRate(PWB32_ADAPTER Adapter, u8 *RateArray, u8 num);
void Assemble_IE(PWB32_ADAPTER Adapter, u16 wBssIdx);
void SetMaxTxRate(PWB32_ADAPTER Adapter);
void CreateWpaIE(PWB32_ADAPTER Adapter, u16* iFildOffset, PUCHAR msg, struct Management_Frame* msgHeader,
void CreateWpaIE(PWB32_ADAPTER Adapter, u16* iFildOffset, u8 *msg, struct Management_Frame* msgHeader,
struct Association_Request_Frame_Body* msgBody, u16 iMSindex); //added by WS 05/14/05
#ifdef _WPA2_
void CreateRsnIE(PWB32_ADAPTER Adapter, u16* iFildOffset, PUCHAR msg, struct Management_Frame* msgHeader,
void CreateRsnIE(PWB32_ADAPTER Adapter, u16* iFildOffset, u8 *msg, struct Management_Frame* msgHeader,
struct Association_Request_Frame_Body* msgBody, u16 iMSindex);//added by WS 05/14/05
u16 SearchPmkid(PWB32_ADAPTER Adapter, struct Management_Frame* msgHeader,

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@ -25,9 +25,9 @@ typedef struct tkip
s32 bytes_in_M; // # bytes in M
} tkip_t;
//void _append_data( PUCHAR pData, u16 size, tkip_t *p );
void Mds_MicGet( void* Adapter, void* pRxLayer1, PUCHAR pKey, PUCHAR pMic );
void Mds_MicFill( void* Adapter, void* pDes, PUCHAR XmitBufAddress );
//void _append_data( u8 *pData, u16 size, tkip_t *p );
void Mds_MicGet( void* Adapter, void* pRxLayer1, u8 *pKey, u8 *pMic );
void Mds_MicFill( void* Adapter, void* pDes, u8 *XmitBufAddress );

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@ -39,14 +39,6 @@
// Common type definition
//===============================================================
typedef u8* PUCHAR;
typedef s8* PCHAR;
typedef u8* PBOOLEAN;
typedef u16* PUSHORT;
typedef u32* PULONG;
typedef s16* PSHORT;
//===========================================
#define IGNORE 2
#define SUCCESS 1
@ -110,16 +102,9 @@ typedef struct urb * PURB;
#define OS_ATOMIC_READ( _A, _V ) _V
#define OS_ATOMIC_INC( _A, _V ) EncapAtomicInc( _A, (void*)_V )
#define OS_ATOMIC_DEC( _A, _V ) EncapAtomicDec( _A, (void*)_V )
#define OS_MEMORY_CLEAR( _A, _S ) memset( (PUCHAR)_A,0,_S)
#define OS_MEMORY_CLEAR( _A, _S ) memset( (u8 *)_A,0,_S)
#define OS_MEMORY_COMPARE( _A, _B, _S ) (memcmp(_A,_B,_S)? 0 : 1) // Definition is reverse with Ndis 1: the same 0: different
#define OS_SPIN_LOCK spinlock_t
#define OS_SPIN_LOCK_ALLOCATE( _S ) spin_lock_init( _S );
#define OS_SPIN_LOCK_FREE( _S )
#define OS_SPIN_LOCK_ACQUIRED( _S ) spin_lock_irq( _S )
#define OS_SPIN_LOCK_RELEASED( _S ) spin_unlock_irq( _S );
#define OS_TIMER struct timer_list
#define OS_TIMER_INITIAL( _T, _F, _P ) \
{ \

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@ -10,7 +10,7 @@ extern void phy_calibration_winbond(hw_data_t *phw_data, u32 frequency);
// Flag : AUTO_INCREMENT - RegisterNo will auto increment 4
// NO_INCREMENT - Function will write data into the same register
unsigned char
Wb35Reg_BurstWrite(phw_data_t pHwData, u16 RegisterNo, PULONG pRegisterData, u8 NumberOfData, u8 Flag)
Wb35Reg_BurstWrite(phw_data_t pHwData, u16 RegisterNo, u32 * pRegisterData, u8 NumberOfData, u8 Flag)
{
PWB35REG pWb35Reg = &pHwData->Wb35Reg;
PURB pUrb = NULL;
@ -30,13 +30,13 @@ Wb35Reg_BurstWrite(phw_data_t pHwData, u16 RegisterNo, PULONG pRegisterData, u8
if( pUrb && pRegQueue ) {
pRegQueue->DIRECT = 2;// burst write register
pRegQueue->INDEX = RegisterNo;
pRegQueue->pBuffer = (PULONG)((PUCHAR)pRegQueue + sizeof(REG_QUEUE));
pRegQueue->pBuffer = (u32 *)((u8 *)pRegQueue + sizeof(REG_QUEUE));
memcpy( pRegQueue->pBuffer, pRegisterData, DataSize );
//the function for reversing register data from little endian to big endian
for( i=0; i<NumberOfData ; i++ )
pRegQueue->pBuffer[i] = cpu_to_le32( pRegQueue->pBuffer[i] );
dr = (struct usb_ctrlrequest *)((PUCHAR)pRegQueue + sizeof(REG_QUEUE) + DataSize);
dr = (struct usb_ctrlrequest *)((u8 *)pRegQueue + sizeof(REG_QUEUE) + DataSize);
dr->bRequestType = USB_TYPE_VENDOR | USB_DIR_OUT | USB_RECIP_DEVICE;
dr->bRequest = 0x04; // USB or vendor-defined request code, burst mode
dr->wValue = cpu_to_le16( Flag ); // 0: Register number auto-increment, 1: No auto increment
@ -46,14 +46,14 @@ Wb35Reg_BurstWrite(phw_data_t pHwData, u16 RegisterNo, PULONG pRegisterData, u8
pRegQueue->pUsbReq = dr;
pRegQueue->pUrb = pUrb;
OS_SPIN_LOCK_ACQUIRED( &pWb35Reg->EP0VM_spin_lock );
spin_lock_irq( &pWb35Reg->EP0VM_spin_lock );
if (pWb35Reg->pRegFirst == NULL)
pWb35Reg->pRegFirst = pRegQueue;
else
pWb35Reg->pRegLast->Next = pRegQueue;
pWb35Reg->pRegLast = pRegQueue;
OS_SPIN_LOCK_RELEASED( &pWb35Reg->EP0VM_spin_lock );
spin_unlock_irq( &pWb35Reg->EP0VM_spin_lock );
// Start EP0VM
Wb35Reg_EP0VM_start(pHwData);
@ -181,7 +181,7 @@ Wb35Reg_Write( phw_data_t pHwData, u16 RegisterNo, u32 RegisterValue )
pRegQueue->INDEX = RegisterNo;
pRegQueue->VALUE = cpu_to_le32(RegisterValue);
pRegQueue->RESERVED_VALID = FALSE;
dr = (struct usb_ctrlrequest *)((PUCHAR)pRegQueue + sizeof(REG_QUEUE));
dr = (struct usb_ctrlrequest *)((u8 *)pRegQueue + sizeof(REG_QUEUE));
dr->bRequestType = USB_TYPE_VENDOR|USB_DIR_OUT |USB_RECIP_DEVICE;
dr->bRequest = 0x03; // USB or vendor-defined request code, burst mode
dr->wValue = cpu_to_le16(0x0);
@ -193,14 +193,14 @@ Wb35Reg_Write( phw_data_t pHwData, u16 RegisterNo, u32 RegisterValue )
pRegQueue->pUsbReq = dr;
pRegQueue->pUrb = pUrb;
OS_SPIN_LOCK_ACQUIRED(&pWb35Reg->EP0VM_spin_lock );
spin_lock_irq(&pWb35Reg->EP0VM_spin_lock );
if (pWb35Reg->pRegFirst == NULL)
pWb35Reg->pRegFirst = pRegQueue;
else
pWb35Reg->pRegLast->Next = pRegQueue;
pWb35Reg->pRegLast = pRegQueue;
OS_SPIN_LOCK_RELEASED( &pWb35Reg->EP0VM_spin_lock );
spin_unlock_irq( &pWb35Reg->EP0VM_spin_lock );
// Start EP0VM
Wb35Reg_EP0VM_start(pHwData);
@ -220,7 +220,7 @@ Wb35Reg_Write( phw_data_t pHwData, u16 RegisterNo, u32 RegisterValue )
// FALSE : register not support
unsigned char
Wb35Reg_WriteWithCallbackValue( phw_data_t pHwData, u16 RegisterNo, u32 RegisterValue,
PCHAR pValue, s8 Len)
s8 *pValue, s8 Len)
{
PWB35REG pWb35Reg = &pHwData->Wb35Reg;
struct usb_ctrlrequest *dr;
@ -243,7 +243,7 @@ Wb35Reg_WriteWithCallbackValue( phw_data_t pHwData, u16 RegisterNo, u32 Register
//NOTE : Users must guarantee the size of value will not exceed the buffer size.
memcpy(pRegQueue->RESERVED, pValue, Len);
pRegQueue->RESERVED_VALID = TRUE;
dr = (struct usb_ctrlrequest *)((PUCHAR)pRegQueue + sizeof(REG_QUEUE));
dr = (struct usb_ctrlrequest *)((u8 *)pRegQueue + sizeof(REG_QUEUE));
dr->bRequestType = USB_TYPE_VENDOR|USB_DIR_OUT |USB_RECIP_DEVICE;
dr->bRequest = 0x03; // USB or vendor-defined request code, burst mode
dr->wValue = cpu_to_le16(0x0);
@ -254,14 +254,14 @@ Wb35Reg_WriteWithCallbackValue( phw_data_t pHwData, u16 RegisterNo, u32 Register
pRegQueue->Next = NULL;
pRegQueue->pUsbReq = dr;
pRegQueue->pUrb = pUrb;
OS_SPIN_LOCK_ACQUIRED (&pWb35Reg->EP0VM_spin_lock );
spin_lock_irq (&pWb35Reg->EP0VM_spin_lock );
if( pWb35Reg->pRegFirst == NULL )
pWb35Reg->pRegFirst = pRegQueue;
else
pWb35Reg->pRegLast->Next = pRegQueue;
pWb35Reg->pRegLast = pRegQueue;
OS_SPIN_LOCK_RELEASED ( &pWb35Reg->EP0VM_spin_lock );
spin_unlock_irq ( &pWb35Reg->EP0VM_spin_lock );
// Start EP0VM
Wb35Reg_EP0VM_start(pHwData);
@ -278,10 +278,10 @@ Wb35Reg_WriteWithCallbackValue( phw_data_t pHwData, u16 RegisterNo, u32 Register
// FALSE : register not support
// pRegisterValue : It must be a resident buffer due to asynchronous read register.
unsigned char
Wb35Reg_ReadSync( phw_data_t pHwData, u16 RegisterNo, PULONG pRegisterValue )
Wb35Reg_ReadSync( phw_data_t pHwData, u16 RegisterNo, u32 * pRegisterValue )
{
PWB35REG pWb35Reg = &pHwData->Wb35Reg;
PULONG pltmp = pRegisterValue;
u32 * pltmp = pRegisterValue;
int ret = -1;
// Module shutdown
@ -327,7 +327,7 @@ Wb35Reg_ReadSync( phw_data_t pHwData, u16 RegisterNo, PULONG pRegisterValue
// FALSE : register not support
// pRegisterValue : It must be a resident buffer due to asynchronous read register.
unsigned char
Wb35Reg_Read(phw_data_t pHwData, u16 RegisterNo, PULONG pRegisterValue )
Wb35Reg_Read(phw_data_t pHwData, u16 RegisterNo, u32 * pRegisterValue )
{
PWB35REG pWb35Reg = &pHwData->Wb35Reg;
struct usb_ctrlrequest * dr;
@ -348,7 +348,7 @@ Wb35Reg_Read(phw_data_t pHwData, u16 RegisterNo, PULONG pRegisterValue )
pRegQueue->DIRECT = 0;// read register
pRegQueue->INDEX = RegisterNo;
pRegQueue->pBuffer = pRegisterValue;
dr = (struct usb_ctrlrequest *)((PUCHAR)pRegQueue + sizeof(REG_QUEUE));
dr = (struct usb_ctrlrequest *)((u8 *)pRegQueue + sizeof(REG_QUEUE));
dr->bRequestType = USB_TYPE_VENDOR|USB_RECIP_DEVICE|USB_DIR_IN;
dr->bRequest = 0x01; // USB or vendor-defined request code, burst mode
dr->wValue = cpu_to_le16(0x0);
@ -359,14 +359,14 @@ Wb35Reg_Read(phw_data_t pHwData, u16 RegisterNo, PULONG pRegisterValue )
pRegQueue->Next = NULL;
pRegQueue->pUsbReq = dr;
pRegQueue->pUrb = pUrb;
OS_SPIN_LOCK_ACQUIRED ( &pWb35Reg->EP0VM_spin_lock );
spin_lock_irq ( &pWb35Reg->EP0VM_spin_lock );
if( pWb35Reg->pRegFirst == NULL )
pWb35Reg->pRegFirst = pRegQueue;
else
pWb35Reg->pRegLast->Next = pRegQueue;
pWb35Reg->pRegLast = pRegQueue;
OS_SPIN_LOCK_RELEASED( &pWb35Reg->EP0VM_spin_lock );
spin_unlock_irq( &pWb35Reg->EP0VM_spin_lock );
// Start EP0VM
Wb35Reg_EP0VM_start( pHwData );
@ -399,7 +399,7 @@ Wb35Reg_EP0VM(phw_data_t pHwData )
PWB35REG pWb35Reg = &pHwData->Wb35Reg;
PURB pUrb;
struct usb_ctrlrequest *dr;
PULONG pBuffer;
u32 * pBuffer;
int ret = -1;
PREG_QUEUE pRegQueue;
@ -411,9 +411,9 @@ Wb35Reg_EP0VM(phw_data_t pHwData )
goto cleanup;
// Get the register data and send to USB through Irp
OS_SPIN_LOCK_ACQUIRED( &pWb35Reg->EP0VM_spin_lock );
spin_lock_irq( &pWb35Reg->EP0VM_spin_lock );
pRegQueue = pWb35Reg->pRegFirst;
OS_SPIN_LOCK_RELEASED( &pWb35Reg->EP0VM_spin_lock );
spin_unlock_irq( &pWb35Reg->EP0VM_spin_lock );
if (!pRegQueue)
goto cleanup;
@ -429,7 +429,7 @@ Wb35Reg_EP0VM(phw_data_t pHwData )
usb_fill_control_urb( pUrb, pHwData->WbUsb.udev,
REG_DIRECTION(pHwData->WbUsb.udev,pRegQueue),
(PUCHAR)dr,pBuffer,cpu_to_le16(dr->wLength),
(u8 *)dr,pBuffer,cpu_to_le16(dr->wLength),
Wb35Reg_EP0VM_complete, (void*)pHwData);
pWb35Reg->EP0vm_state = VM_RUNNING;
@ -468,12 +468,12 @@ Wb35Reg_EP0VM_complete(PURB pUrb)
OS_ATOMIC_DEC( pHwData->Adapter, &pWb35Reg->RegFireCount );
} else {
// Complete to send, remove the URB from the first
OS_SPIN_LOCK_ACQUIRED( &pWb35Reg->EP0VM_spin_lock );
spin_lock_irq( &pWb35Reg->EP0VM_spin_lock );
pRegQueue = pWb35Reg->pRegFirst;
if (pRegQueue == pWb35Reg->pRegLast)
pWb35Reg->pRegLast = NULL;
pWb35Reg->pRegFirst = pWb35Reg->pRegFirst->Next;
OS_SPIN_LOCK_RELEASED( &pWb35Reg->EP0VM_spin_lock );
spin_unlock_irq( &pWb35Reg->EP0VM_spin_lock );
if (pWb35Reg->EP0VM_status) {
#ifdef _PE_REG_DUMP_
@ -513,7 +513,7 @@ Wb35Reg_destroy(phw_data_t pHwData)
OS_SLEEP(10000); // Delay for waiting function enter 940623.1.b
// Release all the data in RegQueue
OS_SPIN_LOCK_ACQUIRED( &pWb35Reg->EP0VM_spin_lock );
spin_lock_irq( &pWb35Reg->EP0VM_spin_lock );
pRegQueue = pWb35Reg->pRegFirst;
while (pRegQueue) {
if (pRegQueue == pWb35Reg->pRegLast)
@ -521,7 +521,7 @@ Wb35Reg_destroy(phw_data_t pHwData)
pWb35Reg->pRegFirst = pWb35Reg->pRegFirst->Next;
pUrb = pRegQueue->pUrb;
OS_SPIN_LOCK_RELEASED( &pWb35Reg->EP0VM_spin_lock );
spin_unlock_irq( &pWb35Reg->EP0VM_spin_lock );
if (pUrb) {
usb_free_urb(pUrb);
kfree(pRegQueue);
@ -530,14 +530,11 @@ Wb35Reg_destroy(phw_data_t pHwData)
WBDEBUG(("EP0 queue release error\n"));
#endif
}
OS_SPIN_LOCK_ACQUIRED( &pWb35Reg->EP0VM_spin_lock );
spin_lock_irq( &pWb35Reg->EP0VM_spin_lock );
pRegQueue = pWb35Reg->pRegFirst;
}
OS_SPIN_LOCK_RELEASED( &pWb35Reg->EP0VM_spin_lock );
// Free resource
OS_SPIN_LOCK_FREE( &pWb35Reg->EP0VM_spin_lock );
spin_unlock_irq( &pWb35Reg->EP0VM_spin_lock );
}
//====================================================================================
@ -550,7 +547,7 @@ unsigned char Wb35Reg_initial(phw_data_t pHwData)
u32 SoftwareSet, VCO_trim, TxVga, Region_ScanInterval;
// Spin lock is acquired for read and write IRP command
OS_SPIN_LOCK_ALLOCATE( &pWb35Reg->EP0VM_spin_lock );
spin_lock_init( &pWb35Reg->EP0VM_spin_lock );
// Getting RF module type from EEPROM ------------------------------------
Wb35Reg_WriteSync( pHwData, 0x03b4, 0x080d0000 ); // Start EEPROM access + Read + address(0x0d)
@ -655,7 +652,7 @@ unsigned char Wb35Reg_initial(phw_data_t pHwData)
// version in _GENREQ.ASM of the DWB NE1000/2000 driver.
//==================================================================================
u32
CardComputeCrc(PUCHAR Buffer, u32 Length)
CardComputeCrc(u8 * Buffer, u32 Length)
{
u32 Crc, Carry;
u32 i, j;

Просмотреть файл

@ -29,16 +29,16 @@ void EEPROMTxVgaAdjust( phw_data_t pHwData ); // 20060619.5 Add
void Wb35Reg_destroy( phw_data_t pHwData );
unsigned char Wb35Reg_Read( phw_data_t pHwData, u16 RegisterNo, PULONG pRegisterValue );
unsigned char Wb35Reg_ReadSync( phw_data_t pHwData, u16 RegisterNo, PULONG pRegisterValue );
unsigned char Wb35Reg_Read( phw_data_t pHwData, u16 RegisterNo, u32 * pRegisterValue );
unsigned char Wb35Reg_ReadSync( phw_data_t pHwData, u16 RegisterNo, u32 * pRegisterValue );
unsigned char Wb35Reg_Write( phw_data_t pHwData, u16 RegisterNo, u32 RegisterValue );
unsigned char Wb35Reg_WriteSync( phw_data_t pHwData, u16 RegisterNo, u32 RegisterValue );
unsigned char Wb35Reg_WriteWithCallbackValue( phw_data_t pHwData,
u16 RegisterNo,
u32 RegisterValue,
PCHAR pValue,
s8 Len);
unsigned char Wb35Reg_BurstWrite( phw_data_t pHwData, u16 RegisterNo, PULONG pRegisterData, u8 NumberOfData, u8 Flag );
s8 *pValue,
s8 Len);
unsigned char Wb35Reg_BurstWrite( phw_data_t pHwData, u16 RegisterNo, u32 * pRegisterData, u8 NumberOfData, u8 Flag );
void Wb35Reg_EP0VM( phw_data_t pHwData );
void Wb35Reg_EP0VM_start( phw_data_t pHwData );
@ -47,7 +47,7 @@ void Wb35Reg_EP0VM_complete( PURB pUrb );
u32 BitReverse( u32 dwData, u32 DataLength);
void CardGetMulticastBit( u8 Address[MAC_ADDR_LENGTH], u8 *Byte, u8 *Value );
u32 CardComputeCrc( PUCHAR Buffer, u32 Length );
u32 CardComputeCrc( u8 * Buffer, u32 Length );
void Wb35Reg_phy_calibration( phw_data_t pHwData );
void Wb35Reg_Update( phw_data_t pHwData, u16 RegisterNo, u32 RegisterValue );

Просмотреть файл

@ -75,7 +75,7 @@ typedef struct _REG_QUEUE
union
{
u32 VALUE;
PULONG pBuffer;
u32 * pBuffer;
};
u8 RESERVED[4];// space reserved for communication
@ -143,7 +143,7 @@ typedef struct _WB35REG
//-------------------
// VM
//-------------------
OS_SPIN_LOCK EP0VM_spin_lock; // 4B
spinlock_t EP0VM_spin_lock; // 4B
u32 EP0VM_status;//$$
PREG_QUEUE pRegFirst;
PREG_QUEUE pRegLast;

Просмотреть файл

@ -27,7 +27,7 @@ void Wb35Rx_start(phw_data_t pHwData)
void Wb35Rx( phw_data_t pHwData )
{
PWB35RX pWb35Rx = &pHwData->Wb35Rx;
PUCHAR pRxBufferAddress;
u8 * pRxBufferAddress;
PURB pUrb = (PURB)pWb35Rx->RxUrb;
int retv;
u32 RxBufferId;
@ -35,51 +35,50 @@ void Wb35Rx( phw_data_t pHwData )
//
// Issuing URB
//
do {
if (pHwData->SurpriseRemove || pHwData->HwStop)
break;
if (pHwData->SurpriseRemove || pHwData->HwStop)
goto error;
if (pWb35Rx->rx_halt)
break;
if (pWb35Rx->rx_halt)
goto error;
// Get RxBuffer's ID
RxBufferId = pWb35Rx->RxBufferId;
if (!pWb35Rx->RxOwner[RxBufferId]) {
// It's impossible to run here.
#ifdef _PE_RX_DUMP_
WBDEBUG(("Rx driver fifo unavailable\n"));
#endif
break;
}
// Get RxBuffer's ID
RxBufferId = pWb35Rx->RxBufferId;
if (!pWb35Rx->RxOwner[RxBufferId]) {
// It's impossible to run here.
#ifdef _PE_RX_DUMP_
WBDEBUG(("Rx driver fifo unavailable\n"));
#endif
goto error;
}
// Update buffer point, then start to bulkin the data from USB
pWb35Rx->RxBufferId++;
pWb35Rx->RxBufferId %= MAX_USB_RX_BUFFER_NUMBER;
// Update buffer point, then start to bulkin the data from USB
pWb35Rx->RxBufferId++;
pWb35Rx->RxBufferId %= MAX_USB_RX_BUFFER_NUMBER;
pWb35Rx->CurrentRxBufferId = RxBufferId;
pWb35Rx->CurrentRxBufferId = RxBufferId;
if (1 != OS_MEMORY_ALLOC((void* *)&pWb35Rx->pDRx, MAX_USB_RX_BUFFER)) {
printk("w35und: Rx memory alloc failed\n");
break;
}
pRxBufferAddress = pWb35Rx->pDRx;
if (1 != OS_MEMORY_ALLOC((void* *)&pWb35Rx->pDRx, MAX_USB_RX_BUFFER)) {
printk("w35und: Rx memory alloc failed\n");
goto error;
}
pRxBufferAddress = pWb35Rx->pDRx;
usb_fill_bulk_urb(pUrb, pHwData->WbUsb.udev,
usb_rcvbulkpipe(pHwData->WbUsb.udev, 3),
pRxBufferAddress, MAX_USB_RX_BUFFER,
Wb35Rx_Complete, pHwData);
usb_fill_bulk_urb(pUrb, pHwData->WbUsb.udev,
usb_rcvbulkpipe(pHwData->WbUsb.udev, 3),
pRxBufferAddress, MAX_USB_RX_BUFFER,
Wb35Rx_Complete, pHwData);
pWb35Rx->EP3vm_state = VM_RUNNING;
pWb35Rx->EP3vm_state = VM_RUNNING;
retv = wb_usb_submit_urb(pUrb);
retv = wb_usb_submit_urb(pUrb);
if (retv != 0) {
printk("Rx URB sending error\n");
break;
}
return;
} while(FALSE);
if (retv != 0) {
printk("Rx URB sending error\n");
goto error;
}
return;
error:
// VM stop
pWb35Rx->EP3vm_state = VM_STOP;
OS_ATOMIC_DEC( pHwData->Adapter, &pWb35Rx->RxFireCounter );
@ -89,7 +88,7 @@ void Wb35Rx_Complete(PURB pUrb)
{
phw_data_t pHwData = pUrb->context;
PWB35RX pWb35Rx = &pHwData->Wb35Rx;
PUCHAR pRxBufferAddress;
u8 * pRxBufferAddress;
u32 SizeCheck;
u16 BulkLength;
u32 RxBufferId;
@ -99,65 +98,63 @@ void Wb35Rx_Complete(PURB pUrb)
pWb35Rx->EP3vm_state = VM_COMPLETED;
pWb35Rx->EP3VM_status = pUrb->status;//Store the last result of Irp
do {
RxBufferId = pWb35Rx->CurrentRxBufferId;
RxBufferId = pWb35Rx->CurrentRxBufferId;
pRxBufferAddress = pWb35Rx->pDRx;
BulkLength = (u16)pUrb->actual_length;
pRxBufferAddress = pWb35Rx->pDRx;
BulkLength = (u16)pUrb->actual_length;
// The IRP is completed
pWb35Rx->EP3vm_state = VM_COMPLETED;
// The IRP is completed
pWb35Rx->EP3vm_state = VM_COMPLETED;
if (pHwData->SurpriseRemove || pHwData->HwStop) // Must be here, or RxBufferId is invalid
break;
if (pHwData->SurpriseRemove || pHwData->HwStop) // Must be here, or RxBufferId is invalid
goto error;
if (pWb35Rx->rx_halt)
break;
if (pWb35Rx->rx_halt)
goto error;
// Start to process the data only in successful condition
pWb35Rx->RxOwner[ RxBufferId ] = 0; // Set the owner to driver
R00.value = le32_to_cpu(*(PULONG)pRxBufferAddress);
// Start to process the data only in successful condition
pWb35Rx->RxOwner[ RxBufferId ] = 0; // Set the owner to driver
R00.value = le32_to_cpu(*(u32 *)pRxBufferAddress);
// The URB is completed, check the result
if (pWb35Rx->EP3VM_status != 0) {
#ifdef _PE_USB_STATE_DUMP_
WBDEBUG(("EP3 IoCompleteRoutine return error\n"));
DebugUsbdStatusInformation( pWb35Rx->EP3VM_status );
#endif
// The URB is completed, check the result
if (pWb35Rx->EP3VM_status != 0) {
#ifdef _PE_USB_STATE_DUMP_
WBDEBUG(("EP3 IoCompleteRoutine return error\n"));
DebugUsbdStatusInformation( pWb35Rx->EP3VM_status );
#endif
pWb35Rx->EP3vm_state = VM_STOP;
goto error;
}
// 20060220 For recovering. check if operating in single USB mode
if (!HAL_USB_MODE_BURST(pHwData)) {
SizeCheck = R00.R00_receive_byte_count; //20060926 anson's endian
if ((SizeCheck & 0x03) > 0)
SizeCheck -= 4;
SizeCheck = (SizeCheck + 3) & ~0x03;
SizeCheck += 12; // 8 + 4 badbeef
if ((BulkLength > 1600) ||
(SizeCheck > 1600) ||
(BulkLength != SizeCheck) ||
(BulkLength == 0)) { // Add for fail Urb
pWb35Rx->EP3vm_state = VM_STOP;
break;
pWb35Rx->Ep3ErrorCount2++;
}
}
// 20060220 For recovering. check if operating in single USB mode
if (!HAL_USB_MODE_BURST(pHwData)) {
SizeCheck = R00.R00_receive_byte_count; //20060926 anson's endian
if ((SizeCheck & 0x03) > 0)
SizeCheck -= 4;
SizeCheck = (SizeCheck + 3) & ~0x03;
SizeCheck += 12; // 8 + 4 badbeef
if ((BulkLength > 1600) ||
(SizeCheck > 1600) ||
(BulkLength != SizeCheck) ||
(BulkLength == 0)) { // Add for fail Urb
pWb35Rx->EP3vm_state = VM_STOP;
pWb35Rx->Ep3ErrorCount2++;
}
}
// Indicating the receiving data
pWb35Rx->ByteReceived += BulkLength;
pWb35Rx->RxBufferSize[ RxBufferId ] = BulkLength;
// Indicating the receiving data
pWb35Rx->ByteReceived += BulkLength;
pWb35Rx->RxBufferSize[ RxBufferId ] = BulkLength;
if (!pWb35Rx->RxOwner[ RxBufferId ])
Wb35Rx_indicate(pHwData);
if (!pWb35Rx->RxOwner[ RxBufferId ])
Wb35Rx_indicate(pHwData);
kfree(pWb35Rx->pDRx);
// Do the next receive
Wb35Rx(pHwData);
return;
} while(FALSE);
kfree(pWb35Rx->pDRx);
// Do the next receive
Wb35Rx(pHwData);
return;
error:
pWb35Rx->RxOwner[ RxBufferId ] = 1; // Set the owner to hardware
OS_ATOMIC_DEC( pHwData->Adapter, &pWb35Rx->RxFireCounter );
pWb35Rx->EP3vm_state = VM_STOP;
@ -223,7 +220,7 @@ void Wb35Rx_reset_descriptor( phw_data_t pHwData )
void Wb35Rx_adjust(PDESCRIPTOR pRxDes)
{
PULONG pRxBufferAddress;
u32 * pRxBufferAddress;
u32 DecryptionMethod;
u32 i;
u16 BufferSize;
@ -264,7 +261,7 @@ u16 Wb35Rx_indicate(phw_data_t pHwData)
{
DESCRIPTOR RxDes;
PWB35RX pWb35Rx = &pHwData->Wb35Rx;
PUCHAR pRxBufferAddress;
u8 * pRxBufferAddress;
u16 PacketSize;
u16 stmp, BufferSize, stmp2 = 0;
u32 RxBufferId;
@ -283,13 +280,13 @@ u16 Wb35Rx_indicate(phw_data_t pHwData)
// Parse the bulkin buffer
while (BufferSize >= 4) {
if ((cpu_to_le32(*(PULONG)pRxBufferAddress) & 0x0fffffff) == RX_END_TAG) //Is ending? 921002.9.a
if ((cpu_to_le32(*(u32 *)pRxBufferAddress) & 0x0fffffff) == RX_END_TAG) //Is ending? 921002.9.a
break;
// Get the R00 R01 first
RxDes.R00.value = le32_to_cpu(*(PULONG)pRxBufferAddress);
RxDes.R00.value = le32_to_cpu(*(u32 *)pRxBufferAddress);
PacketSize = (u16)RxDes.R00.R00_receive_byte_count;
RxDes.R01.value = le32_to_cpu(*((PULONG)(pRxBufferAddress+4)));
RxDes.R01.value = le32_to_cpu(*((u32 *)(pRxBufferAddress+4)));
// For new DMA 4k
if ((PacketSize & 0x03) > 0)
PacketSize -= 4;

Просмотреть файл

@ -41,7 +41,7 @@ typedef struct _WB35RX
u32 Ep3ErrorCount2; // 20060625.1 Usbd for Rx DMA error count
int EP3VM_status;
PUCHAR pDRx;
u8 * pDRx;
} WB35RX, *PWB35RX;

Просмотреть файл

@ -12,7 +12,7 @@
unsigned char
Wb35Tx_get_tx_buffer(phw_data_t pHwData, PUCHAR *pBuffer )
Wb35Tx_get_tx_buffer(phw_data_t pHwData, u8 **pBuffer)
{
PWB35TX pWb35Tx = &pHwData->Wb35Tx;
@ -37,7 +37,7 @@ void Wb35Tx(phw_data_t pHwData)
{
PWB35TX pWb35Tx = &pHwData->Wb35Tx;
PADAPTER Adapter = pHwData->Adapter;
PUCHAR pTxBufferAddress;
u8 *pTxBufferAddress;
PMDS pMds = &Adapter->Mds;
struct urb * pUrb = (struct urb *)pWb35Tx->Tx4Urb;
int retv;
@ -100,25 +100,24 @@ void Wb35Tx_complete(struct urb * pUrb)
pWb35Tx->TxSendIndex++;
pWb35Tx->TxSendIndex %= MAX_USB_TX_BUFFER_NUMBER;
do {
if (pHwData->SurpriseRemove || pHwData->HwStop) // Let WbWlanHalt to handle surprise remove
break;
if (pHwData->SurpriseRemove || pHwData->HwStop) // Let WbWlanHalt to handle surprise remove
goto error;
if (pWb35Tx->tx_halt)
break;
if (pWb35Tx->tx_halt)
goto error;
// The URB is completed, check the result
if (pWb35Tx->EP4VM_status != 0) {
printk("URB submission failed\n");
pWb35Tx->EP4vm_state = VM_STOP;
break; // Exit while(FALSE);
}
// The URB is completed, check the result
if (pWb35Tx->EP4VM_status != 0) {
printk("URB submission failed\n");
pWb35Tx->EP4vm_state = VM_STOP;
goto error;
}
Mds_Tx(Adapter);
Wb35Tx(pHwData);
return;
} while(FALSE);
Mds_Tx(Adapter);
Wb35Tx(pHwData);
return;
error:
OS_ATOMIC_DEC( pHwData->Adapter, &pWb35Tx->TxFireCounter );
pWb35Tx->EP4vm_state = VM_STOP;
}
@ -225,36 +224,33 @@ void Wb35Tx_EP2VM(phw_data_t pHwData)
{
PWB35TX pWb35Tx = &pHwData->Wb35Tx;
struct urb * pUrb = (struct urb *)pWb35Tx->Tx2Urb;
PULONG pltmp = (PULONG)pWb35Tx->EP2_buf;
u32 * pltmp = (u32 *)pWb35Tx->EP2_buf;
int retv;
do {
if (pHwData->SurpriseRemove || pHwData->HwStop)
break;
if (pHwData->SurpriseRemove || pHwData->HwStop)
goto error;
if (pWb35Tx->tx_halt)
break;
if (pWb35Tx->tx_halt)
goto error;
//
// Issuing URB
//
usb_fill_int_urb( pUrb, pHwData->WbUsb.udev, usb_rcvintpipe(pHwData->WbUsb.udev,2),
pltmp, MAX_INTERRUPT_LENGTH, Wb35Tx_EP2VM_complete, pHwData, 32);
//
// Issuing URB
//
usb_fill_int_urb( pUrb, pHwData->WbUsb.udev, usb_rcvintpipe(pHwData->WbUsb.udev,2),
pltmp, MAX_INTERRUPT_LENGTH, Wb35Tx_EP2VM_complete, pHwData, 32);
pWb35Tx->EP2vm_state = VM_RUNNING;
retv = wb_usb_submit_urb( pUrb );
pWb35Tx->EP2vm_state = VM_RUNNING;
retv = wb_usb_submit_urb( pUrb );
if(retv < 0) {
#ifdef _PE_TX_DUMP_
WBDEBUG(("EP2 Tx Irp sending error\n"));
#endif
break;
}
return;
} while(FALSE);
if (retv < 0) {
#ifdef _PE_TX_DUMP_
WBDEBUG(("EP2 Tx Irp sending error\n"));
#endif
goto error;
}
return;
error:
pWb35Tx->EP2vm_state = VM_STOP;
OS_ATOMIC_DEC( pHwData->Adapter, &pWb35Tx->TxResultCount );
}
@ -266,7 +262,7 @@ void Wb35Tx_EP2VM_complete(struct urb * pUrb)
T02_DESCRIPTOR T02, TSTATUS;
PADAPTER Adapter = (PADAPTER)pHwData->Adapter;
PWB35TX pWb35Tx = &pHwData->Wb35Tx;
PULONG pltmp = (PULONG)pWb35Tx->EP2_buf;
u32 * pltmp = (u32 *)pWb35Tx->EP2_buf;
u32 i;
u16 InterruptInLength;
@ -275,38 +271,36 @@ void Wb35Tx_EP2VM_complete(struct urb * pUrb)
pWb35Tx->EP2vm_state = VM_COMPLETED;
pWb35Tx->EP2VM_status = pUrb->status;
do {
// For Linux 2.4. Interrupt will always trigger
if( pHwData->SurpriseRemove || pHwData->HwStop ) // Let WbWlanHalt to handle surprise remove
break;
// For Linux 2.4. Interrupt will always trigger
if (pHwData->SurpriseRemove || pHwData->HwStop) // Let WbWlanHalt to handle surprise remove
goto error;
if( pWb35Tx->tx_halt )
break;
if (pWb35Tx->tx_halt)
goto error;
//The Urb is completed, check the result
if (pWb35Tx->EP2VM_status != 0) {
WBDEBUG(("EP2 IoCompleteRoutine return error\n"));
pWb35Tx->EP2vm_state= VM_STOP;
break; // Exit while(FALSE);
}
//The Urb is completed, check the result
if (pWb35Tx->EP2VM_status != 0) {
WBDEBUG(("EP2 IoCompleteRoutine return error\n"));
pWb35Tx->EP2vm_state= VM_STOP;
goto error;
}
// Update the Tx result
InterruptInLength = pUrb->actual_length;
// Modify for minimum memory access and DWORD alignment.
T02.value = cpu_to_le32(pltmp[0]) >> 8; // [31:8] -> [24:0]
InterruptInLength -= 1;// 20051221.1.c Modify the follow for more stable
InterruptInLength >>= 2; // InterruptInLength/4
for (i=1; i<=InterruptInLength; i++) {
T02.value |= ((cpu_to_le32(pltmp[i]) & 0xff) << 24);
// Update the Tx result
InterruptInLength = pUrb->actual_length;
// Modify for minimum memory access and DWORD alignment.
T02.value = cpu_to_le32(pltmp[0]) >> 8; // [31:8] -> [24:0]
InterruptInLength -= 1;// 20051221.1.c Modify the follow for more stable
InterruptInLength >>= 2; // InterruptInLength/4
for (i = 1; i <= InterruptInLength; i++) {
T02.value |= ((cpu_to_le32(pltmp[i]) & 0xff) << 24);
TSTATUS.value = T02.value; //20061009 anson's endian
Mds_SendComplete( Adapter, &TSTATUS );
T02.value = cpu_to_le32(pltmp[i]) >> 8;
}
return;
} while(FALSE);
TSTATUS.value = T02.value; //20061009 anson's endian
Mds_SendComplete( Adapter, &TSTATUS );
T02.value = cpu_to_le32(pltmp[i]) >> 8;
}
return;
error:
OS_ATOMIC_DEC( pHwData->Adapter, &pWb35Tx->TxResultCount );
pWb35Tx->EP2vm_state = VM_STOP;
}

Просмотреть файл

@ -3,7 +3,7 @@
//====================================
unsigned char Wb35Tx_initial( phw_data_t pHwData );
void Wb35Tx_destroy( phw_data_t pHwData );
unsigned char Wb35Tx_get_tx_buffer( phw_data_t pHwData, PUCHAR *pBuffer );
unsigned char Wb35Tx_get_tx_buffer( phw_data_t pHwData, u8 **pBuffer );
void Wb35Tx_EP2VM( phw_data_t pHwData );
void Wb35Tx_EP2VM_start( phw_data_t pHwData );

Просмотреть файл

@ -6,42 +6,29 @@
#include "sysdef.h"
#include <net/mac80211.h>
MODULE_AUTHOR( DRIVER_AUTHOR );
MODULE_DESCRIPTION( DRIVER_DESC );
MODULE_AUTHOR(DRIVER_AUTHOR);
MODULE_DESCRIPTION(DRIVER_DESC);
MODULE_LICENSE("GPL");
MODULE_VERSION("0.1");
//============================================================
// vendor ID and product ID can into here for others
//============================================================
static struct usb_device_id Id_Table[] =
{
{USB_DEVICE( 0x0416, 0x0035 )},
{USB_DEVICE( 0x18E8, 0x6201 )},
{USB_DEVICE( 0x18E8, 0x6206 )},
{USB_DEVICE( 0x18E8, 0x6217 )},
{USB_DEVICE( 0x18E8, 0x6230 )},
{USB_DEVICE( 0x18E8, 0x6233 )},
{USB_DEVICE( 0x1131, 0x2035 )},
{ }
static struct usb_device_id wb35_table[] __devinitdata = {
{USB_DEVICE(0x0416, 0x0035)},
{USB_DEVICE(0x18E8, 0x6201)},
{USB_DEVICE(0x18E8, 0x6206)},
{USB_DEVICE(0x18E8, 0x6217)},
{USB_DEVICE(0x18E8, 0x6230)},
{USB_DEVICE(0x18E8, 0x6233)},
{USB_DEVICE(0x1131, 0x2035)},
{ 0, }
};
MODULE_DEVICE_TABLE(usb, Id_Table);
MODULE_DEVICE_TABLE(usb, wb35_table);
static struct usb_driver wb35_driver = {
.name = "w35und",
.probe = wb35_probe,
.disconnect = wb35_disconnect,
.id_table = Id_Table,
};
static const struct ieee80211_rate wbsoft_rates[] = {
static struct ieee80211_rate wbsoft_rates[] = {
{ .bitrate = 10, .flags = IEEE80211_RATE_SHORT_PREAMBLE },
};
static const struct ieee80211_channel wbsoft_channels[] = {
static struct ieee80211_channel wbsoft_channels[] = {
{ .center_freq = 2412},
};
@ -62,9 +49,22 @@ static void wbsoft_remove_interface(struct ieee80211_hw *dev,
printk("wbsoft_remove interface called\n");
}
static int wbsoft_nop(void)
static void wbsoft_stop(struct ieee80211_hw *hw)
{
printk("wbsoft_nop called\n");
printk(KERN_INFO "%s called\n", __func__);
}
static int wbsoft_get_stats(struct ieee80211_hw *hw,
struct ieee80211_low_level_stats *stats)
{
printk(KERN_INFO "%s called\n", __func__);
return 0;
}
static int wbsoft_get_tx_stats(struct ieee80211_hw *hw,
struct ieee80211_tx_queue_stats *stats)
{
printk(KERN_INFO "%s called\n", __func__);
return 0;
}
@ -105,8 +105,7 @@ static void wbsoft_configure_filter(struct ieee80211_hw *dev,
*total_flags = new_flags;
}
static int wbsoft_tx(struct ieee80211_hw *dev, struct sk_buff *skb,
struct ieee80211_tx_control *control)
static int wbsoft_tx(struct ieee80211_hw *dev, struct sk_buff *skb)
{
char *buffer = kmalloc(skb->len, GFP_ATOMIC);
printk("Sending frame %d bytes\n", skb->len);
@ -136,7 +135,7 @@ static int wbsoft_config(struct ieee80211_hw *dev, struct ieee80211_conf *conf)
hal_set_current_channel(&my_adapter->sHwData, ch);
hal_set_beacon_period(&my_adapter->sHwData, conf->beacon_int);
// hal_set_cap_info(&my_adapter->sHwData, ?? );
// hal_set_ssid(phw_data_t pHwData, PUCHAR pssid, u8 ssid_len); ??
// hal_set_ssid(phw_data_t pHwData, u8 * pssid, u8 ssid_len); ??
hal_set_accept_broadcast(&my_adapter->sHwData, 1);
hal_set_accept_promiscuous(&my_adapter->sHwData, 1);
hal_set_accept_multicast(&my_adapter->sHwData, 1);
@ -148,7 +147,7 @@ static int wbsoft_config(struct ieee80211_hw *dev, struct ieee80211_conf *conf)
// hal_start_bss(&my_adapter->sHwData, WLAN_BSSTYPE_INFRASTRUCTURE); ??
//void hal_set_rates(phw_data_t pHwData, PUCHAR pbss_rates,
//void hal_set_rates(phw_data_t pHwData, u8 * pbss_rates,
// u8 length, unsigned char basic_rate_set)
return 0;
@ -171,14 +170,14 @@ static u64 wbsoft_get_tsf(struct ieee80211_hw *dev)
static const struct ieee80211_ops wbsoft_ops = {
.tx = wbsoft_tx,
.start = wbsoft_start, /* Start can be pretty much empty as we do WbWLanInitialize() during probe? */
.stop = wbsoft_nop,
.stop = wbsoft_stop,
.add_interface = wbsoft_add_interface,
.remove_interface = wbsoft_remove_interface,
.config = wbsoft_config,
.config_interface = wbsoft_config_interface,
.configure_filter = wbsoft_configure_filter,
.get_stats = wbsoft_nop,
.get_tx_stats = wbsoft_nop,
.get_stats = wbsoft_get_stats,
.get_tx_stats = wbsoft_get_tx_stats,
.get_tsf = wbsoft_get_tsf,
// conf_tx: hal_set_cwmin()/hal_set_cwmax;
};
@ -187,21 +186,6 @@ struct wbsoft_priv {
};
int __init wb35_init(void)
{
printk("[w35und]driver init\n");
return usb_register(&wb35_driver);
}
void __exit wb35_exit(void)
{
printk("[w35und]driver exit\n");
usb_deregister( &wb35_driver );
}
module_init(wb35_init);
module_exit(wb35_exit);
// Usb kernel subsystem will call this function when a new device is plugged into.
int wb35_probe(struct usb_interface *intf, const struct usb_device_id *id_table)
{
@ -210,7 +194,7 @@ int wb35_probe(struct usb_interface *intf, const struct usb_device_id *id_table)
PWBUSB pWbUsb;
struct usb_host_interface *interface;
struct usb_endpoint_descriptor *endpoint;
int i, ret = -1;
int ret = -1;
u32 ltmp;
struct usb_device *udev = interface_to_usbdev(intf);
@ -218,114 +202,95 @@ int wb35_probe(struct usb_interface *intf, const struct usb_device_id *id_table)
printk("[w35und]wb35_probe ->\n");
do {
for (i=0; i<(sizeof(Id_Table)/sizeof(struct usb_device_id)); i++ ) {
if ((udev->descriptor.idVendor == Id_Table[i].idVendor) &&
(udev->descriptor.idProduct == Id_Table[i].idProduct)) {
printk("[w35und]Found supported hardware\n");
break;
}
}
if ((i == (sizeof(Id_Table)/sizeof(struct usb_device_id)))) {
#ifdef _PE_USB_INI_DUMP_
WBDEBUG(("[w35und] This is not the one we are interested about\n"));
#endif
return -ENODEV;
// 20060630.2 Check the device if it already be opened
ret = usb_control_msg(udev, usb_rcvctrlpipe( udev, 0 ),
0x01, USB_TYPE_VENDOR|USB_RECIP_DEVICE|USB_DIR_IN,
0x0, 0x400, &ltmp, 4, HZ*100 );
if (ret < 0)
goto error;
ltmp = cpu_to_le32(ltmp);
if (ltmp) // Is already initialized?
goto error;
Adapter = kzalloc(sizeof(ADAPTER), GFP_KERNEL);
my_adapter = Adapter;
pWbLinux = &Adapter->WbLinux;
pWbUsb = &Adapter->sHwData.WbUsb;
pWbUsb->udev = udev;
interface = intf->cur_altsetting;
endpoint = &interface->endpoint[0].desc;
if (endpoint[2].wMaxPacketSize == 512) {
printk("[w35und] Working on USB 2.0\n");
pWbUsb->IsUsb20 = 1;
}
if (!WbWLanInitialize(Adapter)) {
printk("[w35und]WbWLanInitialize fail\n");
goto error;
}
{
struct wbsoft_priv *priv;
struct ieee80211_hw *dev;
static struct ieee80211_supported_band band;
int res;
dev = ieee80211_alloc_hw(sizeof(*priv), &wbsoft_ops);
if (!dev) {
printk("w35und: ieee80211 alloc failed\n" );
BUG();
}
// 20060630.2 Check the device if it already be opened
ret = usb_control_msg(udev, usb_rcvctrlpipe( udev, 0 ),
0x01, USB_TYPE_VENDOR|USB_RECIP_DEVICE|USB_DIR_IN,
0x0, 0x400, &ltmp, 4, HZ*100 );
if( ret < 0 )
break;
ltmp = cpu_to_le32(ltmp);
if (ltmp) // Is already initialized?
break;
Adapter = kzalloc(sizeof(ADAPTER), GFP_KERNEL);
my_adapter = Adapter;
pWbLinux = &Adapter->WbLinux;
pWbUsb = &Adapter->sHwData.WbUsb;
pWbUsb->udev = udev;
interface = intf->cur_altsetting;
endpoint = &interface->endpoint[0].desc;
if (endpoint[2].wMaxPacketSize == 512) {
printk("[w35und] Working on USB 2.0\n");
pWbUsb->IsUsb20 = 1;
}
if (!WbWLanInitialize(Adapter)) {
printk("[w35und]WbWLanInitialize fail\n");
break;
}
my_dev = dev;
SET_IEEE80211_DEV(dev, &udev->dev);
{
struct wbsoft_priv *priv;
struct ieee80211_hw *dev;
int res;
dev = ieee80211_alloc_hw(sizeof(*priv), &wbsoft_ops);
if (!dev) {
printk("w35und: ieee80211 alloc failed\n" );
BUG();
}
my_dev = dev;
SET_IEEE80211_DEV(dev, &udev->dev);
{
phw_data_t pHwData = &Adapter->sHwData;
unsigned char dev_addr[MAX_ADDR_LEN];
hal_get_permanent_address(pHwData, dev_addr);
SET_IEEE80211_PERM_ADDR(dev, dev_addr);
}
phw_data_t pHwData = &Adapter->sHwData;
unsigned char dev_addr[MAX_ADDR_LEN];
hal_get_permanent_address(pHwData, dev_addr);
SET_IEEE80211_PERM_ADDR(dev, dev_addr);
}
dev->extra_tx_headroom = 12; /* FIXME */
dev->flags = 0;
dev->extra_tx_headroom = 12; /* FIXME */
dev->flags = 0;
dev->channel_change_time = 1000;
// dev->max_rssi = 100;
dev->channel_change_time = 1000;
// dev->max_rssi = 100;
dev->queues = 1;
dev->queues = 1;
static struct ieee80211_supported_band band;
band.channels = wbsoft_channels;
band.n_channels = ARRAY_SIZE(wbsoft_channels);
band.bitrates = wbsoft_rates;
band.n_bitrates = ARRAY_SIZE(wbsoft_rates);
band.channels = wbsoft_channels;
band.n_channels = ARRAY_SIZE(wbsoft_channels);
band.bitrates = wbsoft_rates;
band.n_bitrates = ARRAY_SIZE(wbsoft_rates);
dev->wiphy->bands[IEEE80211_BAND_2GHZ] = &band;
dev->wiphy->bands[IEEE80211_BAND_2GHZ] = &band;
#if 0
wbsoft_modes[0].num_channels = 1;
wbsoft_modes[0].channels = wbsoft_channels;
wbsoft_modes[0].mode = MODE_IEEE80211B;
wbsoft_modes[0].num_rates = ARRAY_SIZE(wbsoft_rates);
wbsoft_modes[0].rates = wbsoft_rates;
wbsoft_modes[0].num_channels = 1;
wbsoft_modes[0].channels = wbsoft_channels;
wbsoft_modes[0].mode = MODE_IEEE80211B;
wbsoft_modes[0].num_rates = ARRAY_SIZE(wbsoft_rates);
wbsoft_modes[0].rates = wbsoft_rates;
res = ieee80211_register_hwmode(dev, &wbsoft_modes[0]);
BUG_ON(res);
res = ieee80211_register_hwmode(dev, &wbsoft_modes[0]);
BUG_ON(res);
#endif
res = ieee80211_register_hw(dev);
BUG_ON(res);
}
res = ieee80211_register_hw(dev);
BUG_ON(res);
}
usb_set_intfdata( intf, Adapter );
printk("[w35und] _probe OK\n");
return 0;
} while(FALSE);
usb_set_intfdata( intf, Adapter );
printk("[w35und] _probe OK\n");
return 0;
error:
return -ENOMEM;
}
@ -401,4 +366,22 @@ void wb35_disconnect(struct usb_interface *intf)
}
static struct usb_driver wb35_driver = {
.name = "w35und",
.id_table = wb35_table,
.probe = wb35_probe,
.disconnect = wb35_disconnect,
};
static int __init wb35_init(void)
{
return usb_register(&wb35_driver);
}
static void __exit wb35_exit(void)
{
usb_deregister(&wb35_driver);
}
module_init(wb35_init);
module_exit(wb35_exit);

Просмотреть файл

@ -40,7 +40,7 @@ Mds_Tx(PADAPTER Adapter)
PMDS pMds = &Adapter->Mds;
DESCRIPTOR TxDes;
PDESCRIPTOR pTxDes = &TxDes;
PUCHAR XmitBufAddress;
u8 *XmitBufAddress;
u16 XmitBufSize, PacketSize, stmp, CurrentSize, FragmentThreshold;
u8 FillIndex, TxDesIndex, FragmentCount, FillCount;
unsigned char BufferFilled = FALSE, MICAdd = 0;
@ -90,7 +90,7 @@ Mds_Tx(PADAPTER Adapter)
BufferFilled = TRUE;
/* Leaves first u8 intact */
memset((PUCHAR)pTxDes + 1, 0, sizeof(DESCRIPTOR) - 1);
memset((u8 *)pTxDes + 1, 0, sizeof(DESCRIPTOR) - 1);
TxDesIndex = pMds->TxDesIndex;//Get the current ID
pTxDes->Descriptor_ID = TxDesIndex;
@ -229,10 +229,10 @@ Mds_SendComplete(PADAPTER Adapter, PT02_DESCRIPTOR pT02)
}
void
Mds_HeaderCopy(PADAPTER Adapter, PDESCRIPTOR pDes, PUCHAR TargetBuffer)
Mds_HeaderCopy(PADAPTER Adapter, PDESCRIPTOR pDes, u8 *TargetBuffer)
{
PMDS pMds = &Adapter->Mds;
PUCHAR src_buffer = pDes->buffer_address[0];//931130.5.g
u8 *src_buffer = pDes->buffer_address[0];//931130.5.g
PT00_DESCRIPTOR pT00;
PT01_DESCRIPTOR pT01;
u16 stmp;
@ -276,7 +276,7 @@ Mds_HeaderCopy(PADAPTER Adapter, PDESCRIPTOR pDes, PUCHAR TargetBuffer)
//
// Set tx rate
//
stmp = *(PUSHORT)(TargetBuffer+30); // 2n alignment address
stmp = *(u16 *)(TargetBuffer+30); // 2n alignment address
//Use basic rate
ctmp1 = ctmpf = CURRENT_TX_RATE_FOR_MNG;
@ -326,11 +326,13 @@ Mds_HeaderCopy(PADAPTER Adapter, PDESCRIPTOR pDes, PUCHAR TargetBuffer)
// The function return the 4n size of usb pk
u16
Mds_BodyCopy(PADAPTER Adapter, PDESCRIPTOR pDes, PUCHAR TargetBuffer)
Mds_BodyCopy(PADAPTER Adapter, PDESCRIPTOR pDes, u8 *TargetBuffer)
{
PT00_DESCRIPTOR pT00;
PMDS pMds = &Adapter->Mds;
PUCHAR buffer, src_buffer, pctmp;
u8 *buffer;
u8 *src_buffer;
u8 *pctmp;
u16 Size = 0;
u16 SizeLeft, CopySize, CopyLeft, stmp;
u8 buf_index, FragmentCount = 0;
@ -354,7 +356,7 @@ Mds_BodyCopy(PADAPTER Adapter, PDESCRIPTOR pDes, PUCHAR TargetBuffer)
SizeLeft -= CopySize;
// 1 Byte operation
pctmp = (PUCHAR)( buffer + 8 + DOT_11_SEQUENCE_OFFSET );
pctmp = (u8 *)( buffer + 8 + DOT_11_SEQUENCE_OFFSET );
*pctmp &= 0xf0;
*pctmp |= FragmentCount;//931130.5.m
if( !FragmentCount )
@ -379,7 +381,7 @@ Mds_BodyCopy(PADAPTER Adapter, PDESCRIPTOR pDes, PUCHAR TargetBuffer)
buf_index++;
buf_index %= MAX_DESCRIPTOR_BUFFER_INDEX;
} else {
PUCHAR pctmp = pDes->buffer_address[buf_index];
u8 *pctmp = pDes->buffer_address[buf_index];
pctmp += CopySize;
pDes->buffer_address[buf_index] = pctmp;
pDes->buffer_size[buf_index] -= CopySize;
@ -419,7 +421,7 @@ Mds_BodyCopy(PADAPTER Adapter, PDESCRIPTOR pDes, PUCHAR TargetBuffer)
pT00->T00_last_mpdu = 1;
pT00->T00_IsLastMpdu = 1;
buffer = (PUCHAR)pT00 + 8; // +8 for USB hdr
buffer = (u8 *)pT00 + 8; // +8 for USB hdr
buffer[1] &= ~0x04; // Clear more frag bit of 802.11 frame control
pDes->FragmentCount = FragmentCount; // Update the correct fragment number
return Size;
@ -427,7 +429,7 @@ Mds_BodyCopy(PADAPTER Adapter, PDESCRIPTOR pDes, PUCHAR TargetBuffer)
void
Mds_DurationSet( PADAPTER Adapter, PDESCRIPTOR pDes, PUCHAR buffer )
Mds_DurationSet( PADAPTER Adapter, PDESCRIPTOR pDes, u8 *buffer )
{
PT00_DESCRIPTOR pT00;
PT01_DESCRIPTOR pT01;
@ -435,7 +437,7 @@ Mds_DurationSet( PADAPTER Adapter, PDESCRIPTOR pDes, PUCHAR buffer )
u8 Rate, i;
unsigned char CTS_on = FALSE, RTS_on = FALSE;
PT00_DESCRIPTOR pNextT00;
u16 BodyLen;
u16 BodyLen = 0;
unsigned char boGroupAddr = FALSE;
@ -574,7 +576,7 @@ Mds_DurationSet( PADAPTER Adapter, PDESCRIPTOR pDes, PUCHAR buffer )
DEFAULT_SIFSTIME*3 );
}
((PUSHORT)buffer)[5] = cpu_to_le16(Duration);// 4 USHOR for skip 8B USB, 2USHORT=FC + Duration
((u16 *)buffer)[5] = cpu_to_le16(Duration);// 4 USHOR for skip 8B USB, 2USHORT=FC + Duration
//----20061009 add by anson's endian
pNextT00->value = cpu_to_le32(pNextT00->value);
@ -615,7 +617,7 @@ Mds_DurationSet( PADAPTER Adapter, PDESCRIPTOR pDes, PUCHAR buffer )
}
}
((PUSHORT)buffer)[5] = cpu_to_le16(Duration);// 4 USHOR for skip 8B USB, 2USHORT=FC + Duration
((u16 *)buffer)[5] = cpu_to_le16(Duration);// 4 USHOR for skip 8B USB, 2USHORT=FC + Duration
pT00->value = cpu_to_le32(pT00->value);
pT01->value = cpu_to_le32(pT01->value);
//--end 20061009 add

Просмотреть файл

@ -1,9 +1,9 @@
unsigned char Mds_initial( PADAPTER Adapter );
void Mds_Destroy( PADAPTER Adapter );
void Mds_Tx( PADAPTER Adapter );
void Mds_HeaderCopy( PADAPTER Adapter, PDESCRIPTOR pDes, PUCHAR TargetBuffer );
u16 Mds_BodyCopy( PADAPTER Adapter, PDESCRIPTOR pDes, PUCHAR TargetBuffer );
void Mds_DurationSet( PADAPTER Adapter, PDESCRIPTOR pDes, PUCHAR TargetBuffer );
void Mds_HeaderCopy( PADAPTER Adapter, PDESCRIPTOR pDes, u8 *TargetBuffer );
u16 Mds_BodyCopy( PADAPTER Adapter, PDESCRIPTOR pDes, u8 *TargetBuffer );
void Mds_DurationSet( PADAPTER Adapter, PDESCRIPTOR pDes, u8 *TargetBuffer );
void Mds_SendComplete( PADAPTER Adapter, PT02_DESCRIPTOR pT02 );
void Mds_MpduProcess( PADAPTER Adapter, PDESCRIPTOR pRxDes );
void Mds_reset_descriptor( PADAPTER Adapter );

Просмотреть файл

@ -86,7 +86,7 @@ typedef struct _MDS
{
// For Tx usage
u8 TxOwner[ ((MAX_USB_TX_BUFFER_NUMBER + 3) & ~0x03) ];
PUCHAR pTxBuffer;
u8 *pTxBuffer;
u16 TxBufferSize[ ((MAX_USB_TX_BUFFER_NUMBER + 1) & ~0x01) ];
u8 TxDesFrom[ ((MAX_USB_TX_DESCRIPTOR + 3) & ~0x03) ];//931130.4.u // 1: MLME 2: NDIS control 3: NDIS data
u8 TxCountInBuffer[ ((MAX_USB_TX_DESCRIPTOR + 3) & ~0x03) ]; // 20060928
@ -103,7 +103,7 @@ typedef struct _MDS
u16 TxResult[ ((MAX_USB_TX_DESCRIPTOR + 1) & ~0x01) ];//Collect the sending result of Mpdu
u8 MicRedundant[8]; // For tmp use
PUCHAR MicWriteAddress[2]; //The start address to fill the Mic, use 2 point due to Mic maybe fragment
u8 *MicWriteAddress[2]; //The start address to fill the Mic, use 2 point due to Mic maybe fragment
u16 MicWriteSize[2]; //931130.4.x
@ -144,7 +144,7 @@ typedef struct _MDS
typedef struct _RxBuffer
{
PUCHAR pBufferAddress; // Pointer the received data buffer.
u8 * pBufferAddress; // Pointer the received data buffer.
u16 BufferSize;
u8 RESERVED;
u8 BufferIndex;// Only 1 byte
@ -176,7 +176,7 @@ typedef struct _RXLAYER1
/////////////////////////////////////////////////////////////////////////////////////////////
// For brand-new Rx system
u8 ReservedBuffer[ 2400 ];//If Buffer ID is reserved one, it must copy the data into this area
PUCHAR ReservedBufferPoint;// Point to the next availabe address of reserved buffer
u8 *ReservedBufferPoint;// Point to the next availabe address of reserved buffer
}RXLAYER1, * PRXLAYER1;

Просмотреть файл

@ -125,12 +125,12 @@
typedef struct _MLME_FRAME
{
//NDIS_PACKET MLME_Packet;
PCHAR pMMPDU;
s8 * pMMPDU;
u16 len;
u8 DataType;
u8 IsInUsed;
OS_SPIN_LOCK MLMESpinLock;
spinlock_t MLMESpinLock;
u8 TxMMPDU[MAX_NUM_TX_MMPDU][MAX_MMPDU_SIZE];
u8 TxMMPDUInUse[ (MAX_NUM_TX_MMPDU+3) & ~0x03 ];

Просмотреть файл

@ -113,13 +113,13 @@ MLME_GetNextPacket(PADAPTER Adapter, PDESCRIPTOR pDes)
pDes->Type = Adapter->sMlmeFrame.DataType;
}
void MLMEfreeMMPDUBuffer(PWB32_ADAPTER Adapter, PCHAR pData)
void MLMEfreeMMPDUBuffer(PWB32_ADAPTER Adapter, s8 *pData)
{
int i;
// Reclaim the data buffer
for (i = 0; i < MAX_NUM_TX_MMPDU; i++) {
if (pData == (PCHAR)&(Adapter->sMlmeFrame.TxMMPDU[i]))
if (pData == (s8 *)&(Adapter->sMlmeFrame.TxMMPDU[i]))
break;
}
if (Adapter->sMlmeFrame.TxMMPDUInUse[i])

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@ -20,7 +20,7 @@ MLMEGetMMPDUBuffer(
PWB32_ADAPTER Adapter
);
void MLMEfreeMMPDUBuffer( PWB32_ADAPTER Adapter, PCHAR pData);
void MLMEfreeMMPDUBuffer( PWB32_ADAPTER Adapter, s8 * pData);
void MLME_GetNextPacket( PADAPTER Adapter, PDESCRIPTOR pDes );
u8 MLMESendFrame( PWB32_ADAPTER Adapter,
@ -42,7 +42,7 @@ MLMERcvFrame(
void
MLMEReturnPacket(
PWB32_ADAPTER Adapter,
PUCHAR pRxBufer
u8 * pRxBufer
);
#ifdef _IBSS_BEACON_SEQ_STICK_
s8 SendBCNullData(PWB32_ADAPTER Adapter, u16 wIdx);

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@ -922,16 +922,16 @@ Uxx_ReadEthernetAddress( phw_data_t pHwData )
// Only unplug and plug again can make hardware read EEPROM again. 20060727
Wb35Reg_WriteSync( pHwData, 0x03b4, 0x08000000 ); // Start EEPROM access + Read + address(0x0d)
Wb35Reg_ReadSync( pHwData, 0x03b4, &ltmp );
*(PUSHORT)pHwData->PermanentMacAddress = cpu_to_le16((u16)ltmp); //20060926 anson's endian
*(u16 *)pHwData->PermanentMacAddress = cpu_to_le16((u16)ltmp); //20060926 anson's endian
Wb35Reg_WriteSync( pHwData, 0x03b4, 0x08010000 ); // Start EEPROM access + Read + address(0x0d)
Wb35Reg_ReadSync( pHwData, 0x03b4, &ltmp );
*(PUSHORT)(pHwData->PermanentMacAddress + 2) = cpu_to_le16((u16)ltmp); //20060926 anson's endian
*(u16 *)(pHwData->PermanentMacAddress + 2) = cpu_to_le16((u16)ltmp); //20060926 anson's endian
Wb35Reg_WriteSync( pHwData, 0x03b4, 0x08020000 ); // Start EEPROM access + Read + address(0x0d)
Wb35Reg_ReadSync( pHwData, 0x03b4, &ltmp );
*(PUSHORT)(pHwData->PermanentMacAddress + 4) = cpu_to_le16((u16)ltmp); //20060926 anson's endian
*(PUSHORT)(pHwData->PermanentMacAddress + 6) = 0;
Wb35Reg_WriteSync( pHwData, 0x03e8, cpu_to_le32(*(PULONG)pHwData->PermanentMacAddress) ); //20060926 anson's endian
Wb35Reg_WriteSync( pHwData, 0x03ec, cpu_to_le32(*(PULONG)(pHwData->PermanentMacAddress+4)) ); //20060926 anson's endian
*(u16 *)(pHwData->PermanentMacAddress + 4) = cpu_to_le16((u16)ltmp); //20060926 anson's endian
*(u16 *)(pHwData->PermanentMacAddress + 6) = 0;
Wb35Reg_WriteSync( pHwData, 0x03e8, cpu_to_le32(*(u32 *)pHwData->PermanentMacAddress) ); //20060926 anson's endian
Wb35Reg_WriteSync( pHwData, 0x03ec, cpu_to_le32(*(u32 *)(pHwData->PermanentMacAddress+4)) ); //20060926 anson's endian
}
@ -1038,7 +1038,7 @@ void
RFSynthesizer_initial(phw_data_t pHwData)
{
u32 altmp[32];
PULONG pltmp = altmp;
u32 * pltmp = altmp;
u32 ltmp;
u8 number=0x00; // The number of register vale
u8 i;
@ -2358,11 +2358,11 @@ void Mxx_initial( phw_data_t pHwData )
pltmp[2] = pWb35Reg->M2C_MacControl;
// M30 BSSID
pltmp[3] = *(PULONG)pHwData->bssid;
pltmp[3] = *(u32 *)pHwData->bssid;
// M34
pHwData->AID = DEFAULT_AID;
tmp = *(PUSHORT)(pHwData->bssid+4);
tmp = *(u16 *)(pHwData->bssid+4);
tmp |= DEFAULT_AID << 16;
pltmp[4] = tmp;
@ -2428,7 +2428,7 @@ void GetTxVgaFromEEPROM( phw_data_t pHwData )
{
u32 i, j, ltmp;
u16 Value[MAX_TXVGA_EEPROM];
PUCHAR pctmp;
u8 *pctmp;
u8 ctmp=0;
// Get the entire TxVga setting in EEPROM
@ -2441,7 +2441,7 @@ void GetTxVgaFromEEPROM( phw_data_t pHwData )
}
// Adjust the filed which fills with reserved value.
pctmp = (PUCHAR)Value;
pctmp = (u8 *)Value;
for( i=0; i<(MAX_TXVGA_EEPROM*2); i++ )
{
if( pctmp[i] != 0xff )
@ -2480,7 +2480,7 @@ void GetTxVgaFromEEPROM( phw_data_t pHwData )
// This function will use default TxVgaSettingInEEPROM data to calculate new TxVga.
void EEPROMTxVgaAdjust( phw_data_t pHwData ) // 20060619.5 Add
{
PUCHAR pTxVga = pHwData->TxVgaSettingInEEPROM;
u8 * pTxVga = pHwData->TxVgaSettingInEEPROM;
s16 i, stmp;
//-- 2.4G -- 20060704.2 Request from Tiger

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@ -10,4 +10,5 @@
s8 sme_get_rssi(void *pcore_data, s32 *prssi)
{
BUG();
return 0;
}

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@ -208,7 +208,7 @@ s8 sme_set_tx_antenna(void *pcore_data, u32 TxAntenna);
s8 sme_set_IBSS_chan(void *pcore_data, ChanInfo chan);
//20061108 WPS
s8 sme_set_IE_append(void *pcore_data, PUCHAR buffer, u16 buf_len);
s8 sme_set_IE_append(void *pcore_data, u8 *buffer, u16 buf_len);

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@ -1,13 +1,13 @@
#include "os_common.h"
void hal_get_ethernet_address( phw_data_t pHwData, PUCHAR current_address )
void hal_get_ethernet_address( phw_data_t pHwData, u8 *current_address )
{
if( pHwData->SurpriseRemove ) return;
memcpy( current_address, pHwData->CurrentMacAddress, ETH_LENGTH_OF_ADDRESS );
}
void hal_set_ethernet_address( phw_data_t pHwData, PUCHAR current_address )
void hal_set_ethernet_address( phw_data_t pHwData, u8 *current_address )
{
u32 ltmp[2];
@ -15,13 +15,13 @@ void hal_set_ethernet_address( phw_data_t pHwData, PUCHAR current_address )
memcpy( pHwData->CurrentMacAddress, current_address, ETH_LENGTH_OF_ADDRESS );
ltmp[0]= cpu_to_le32( *(PULONG)pHwData->CurrentMacAddress );
ltmp[1]= cpu_to_le32( *(PULONG)(pHwData->CurrentMacAddress + 4) ) & 0xffff;
ltmp[0]= cpu_to_le32( *(u32 *)pHwData->CurrentMacAddress );
ltmp[1]= cpu_to_le32( *(u32 *)(pHwData->CurrentMacAddress + 4) ) & 0xffff;
Wb35Reg_BurstWrite( pHwData, 0x03e8, ltmp, 2, AUTO_INCREMENT );
}
void hal_get_permanent_address( phw_data_t pHwData, PUCHAR pethernet_address )
void hal_get_permanent_address( phw_data_t pHwData, u8 *pethernet_address )
{
if( pHwData->SurpriseRemove ) return;
@ -89,7 +89,7 @@ void hal_halt(phw_data_t pHwData, void *ppa_data)
}
//---------------------------------------------------------------------------------------------------
void hal_set_rates(phw_data_t pHwData, PUCHAR pbss_rates,
void hal_set_rates(phw_data_t pHwData, u8 *pbss_rates,
u8 length, unsigned char basic_rate_set)
{
PWB35REG pWb35Reg = &pHwData->Wb35Reg;
@ -158,13 +158,13 @@ void hal_set_rates(phw_data_t pHwData, PUCHAR pbss_rates,
// Fill data into support rate until buffer full
//---20060926 add by anson's endian
for (i=0; i<4; i++)
*(PULONG)(SupportedRate+(i<<2)) = cpu_to_le32( *(PULONG)(SupportedRate+(i<<2)) );
*(u32 *)(SupportedRate+(i<<2)) = cpu_to_le32( *(u32 *)(SupportedRate+(i<<2)) );
//--- end 20060926 add by anson's endian
Wb35Reg_BurstWrite( pHwData,0x087c, (PULONG)SupportedRate, 4, AUTO_INCREMENT );
pWb35Reg->M7C_MacControl = ((PULONG)SupportedRate)[0];
pWb35Reg->M80_MacControl = ((PULONG)SupportedRate)[1];
pWb35Reg->M84_MacControl = ((PULONG)SupportedRate)[2];
pWb35Reg->M88_MacControl = ((PULONG)SupportedRate)[3];
Wb35Reg_BurstWrite( pHwData,0x087c, (u32 *)SupportedRate, 4, AUTO_INCREMENT );
pWb35Reg->M7C_MacControl = ((u32 *)SupportedRate)[0];
pWb35Reg->M80_MacControl = ((u32 *)SupportedRate)[1];
pWb35Reg->M84_MacControl = ((u32 *)SupportedRate)[2];
pWb35Reg->M88_MacControl = ((u32 *)SupportedRate)[3];
// Fill length
tmp = Count1<<28 | Count2<<24;
@ -206,7 +206,7 @@ void hal_set_current_channel_ex( phw_data_t pHwData, ChanInfo channel )
pWb35Reg->M28_MacControl &= ~0xff; // Clean channel information field
pWb35Reg->M28_MacControl |= channel.ChanNo;
Wb35Reg_WriteWithCallbackValue( pHwData, 0x0828, pWb35Reg->M28_MacControl,
(PCHAR)&channel, sizeof(ChanInfo));
(s8 *)&channel, sizeof(ChanInfo));
}
//---------------------------------------------------------------------------------------------------
void hal_set_current_channel( phw_data_t pHwData, ChanInfo channel )
@ -277,7 +277,7 @@ void hal_set_accept_beacon( phw_data_t pHwData, u8 enable )
Wb35Reg_Write( pHwData, 0x0800, pWb35Reg->M00_MacControl );
}
//---------------------------------------------------------------------------------------------------
void hal_set_multicast_address( phw_data_t pHwData, PUCHAR address, u8 number )
void hal_set_multicast_address( phw_data_t pHwData, u8 *address, u8 number )
{
PWB35REG pWb35Reg = &pHwData->Wb35Reg;
u8 Byte, Bit;
@ -297,7 +297,7 @@ void hal_set_multicast_address( phw_data_t pHwData, PUCHAR address, u8 number )
}
// Updating register
Wb35Reg_BurstWrite( pHwData, 0x0804, (PULONG)pWb35Reg->Multicast, 2, AUTO_INCREMENT );
Wb35Reg_BurstWrite( pHwData, 0x0804, (u32 *)pWb35Reg->Multicast, 2, AUTO_INCREMENT );
}
//---------------------------------------------------------------------------------------------------
u8 hal_get_accept_beacon( phw_data_t pHwData )
@ -806,7 +806,7 @@ u8 hal_get_hw_radio_off( phw_data_t pHwData )
}
}
unsigned char hal_get_dxx_reg( phw_data_t pHwData, u16 number, PULONG pValue )
unsigned char hal_get_dxx_reg( phw_data_t pHwData, u16 number, u32 * pValue )
{
if( number < 0x1000 )
number += 0x1000;

Просмотреть файл

@ -16,23 +16,23 @@
//====================================================================================
// Function declaration
//====================================================================================
void hal_remove_mapping_key( phw_data_t pHwData, PUCHAR pmac_addr );
void hal_remove_mapping_key( phw_data_t pHwData, u8 *pmac_addr );
void hal_remove_default_key( phw_data_t pHwData, u32 index );
unsigned char hal_set_mapping_key( phw_data_t Adapter, PUCHAR pmac_addr, u8 null_key, u8 wep_on, PUCHAR ptx_tsc, PUCHAR prx_tsc, u8 key_type, u8 key_len, PUCHAR pkey_data );
unsigned char hal_set_default_key( phw_data_t Adapter, u8 index, u8 null_key, u8 wep_on, PUCHAR ptx_tsc, PUCHAR prx_tsc, u8 key_type, u8 key_len, PUCHAR pkey_data );
unsigned char hal_set_mapping_key( phw_data_t Adapter, u8 *pmac_addr, u8 null_key, u8 wep_on, u8 *ptx_tsc, u8 *prx_tsc, u8 key_type, u8 key_len, u8 *pkey_data );
unsigned char hal_set_default_key( phw_data_t Adapter, u8 index, u8 null_key, u8 wep_on, u8 *ptx_tsc, u8 *prx_tsc, u8 key_type, u8 key_len, u8 *pkey_data );
void hal_clear_all_default_key( phw_data_t pHwData );
void hal_clear_all_group_key( phw_data_t pHwData );
void hal_clear_all_mapping_key( phw_data_t pHwData );
void hal_clear_all_key( phw_data_t pHwData );
void hal_get_ethernet_address( phw_data_t pHwData, PUCHAR current_address );
void hal_set_ethernet_address( phw_data_t pHwData, PUCHAR current_address );
void hal_get_permanent_address( phw_data_t pHwData, PUCHAR pethernet_address );
void hal_get_ethernet_address( phw_data_t pHwData, u8 *current_address );
void hal_set_ethernet_address( phw_data_t pHwData, u8 *current_address );
void hal_get_permanent_address( phw_data_t pHwData, u8 *pethernet_address );
unsigned char hal_init_hardware( phw_data_t pHwData, PADAPTER Adapter );
void hal_set_power_save_mode( phw_data_t pHwData, unsigned char power_save, unsigned char wakeup, unsigned char dtim );
void hal_get_power_save_mode( phw_data_t pHwData, PBOOLEAN pin_pwr_save );
void hal_get_power_save_mode( phw_data_t pHwData, u8 *pin_pwr_save );
void hal_set_slot_time( phw_data_t pHwData, u8 type );
#define hal_set_atim_window( _A, _ATM )
void hal_set_rates( phw_data_t pHwData, PUCHAR pbss_rates, u8 length, unsigned char basic_rate_set );
void hal_set_rates( phw_data_t pHwData, u8 *pbss_rates, u8 length, unsigned char basic_rate_set );
#define hal_set_basic_rates( _A, _R, _L ) hal_set_rates( _A, _R, _L, TRUE )
#define hal_set_op_rates( _A, _R, _L ) hal_set_rates( _A, _R, _L, FALSE )
void hal_start_bss( phw_data_t pHwData, u8 mac_op_mode );
@ -40,19 +40,19 @@ void hal_join_request( phw_data_t pHwData, u8 bss_type ); // 0:BSS STA 1:IBSS
void hal_stop_sync_bss( phw_data_t pHwData );
void hal_resume_sync_bss( phw_data_t pHwData);
void hal_set_aid( phw_data_t pHwData, u16 aid );
void hal_set_bssid( phw_data_t pHwData, PUCHAR pbssid );
void hal_get_bssid( phw_data_t pHwData, PUCHAR pbssid );
void hal_set_bssid( phw_data_t pHwData, u8 *pbssid );
void hal_get_bssid( phw_data_t pHwData, u8 *pbssid );
void hal_set_beacon_period( phw_data_t pHwData, u16 beacon_period );
void hal_set_listen_interval( phw_data_t pHwData, u16 listen_interval );
void hal_set_cap_info( phw_data_t pHwData, u16 capability_info );
void hal_set_ssid( phw_data_t pHwData, PUCHAR pssid, u8 ssid_len );
void hal_set_ssid( phw_data_t pHwData, u8 *pssid, u8 ssid_len );
void hal_set_current_channel( phw_data_t pHwData, ChanInfo channel );
void hal_set_current_channel_ex( phw_data_t pHwData, ChanInfo channel );
void hal_get_current_channel( phw_data_t pHwData, ChanInfo *channel );
void hal_set_accept_broadcast( phw_data_t pHwData, u8 enable );
void hal_set_accept_multicast( phw_data_t pHwData, u8 enable );
void hal_set_accept_beacon( phw_data_t pHwData, u8 enable );
void hal_set_multicast_address( phw_data_t pHwData, PUCHAR address, u8 number );
void hal_set_multicast_address( phw_data_t pHwData, u8 *address, u8 number );
u8 hal_get_accept_beacon( phw_data_t pHwData );
void hal_stop( phw_data_t pHwData );
void hal_halt( phw_data_t pHwData, void *ppa_data );
@ -97,7 +97,7 @@ void hal_surprise_remove( phw_data_t pHwData );
void hal_rate_change( phw_data_t pHwData ); // Notify the HAL rate is changing 20060613.1
unsigned char hal_get_dxx_reg( phw_data_t pHwData, u16 number, PULONG pValue );
unsigned char hal_get_dxx_reg( phw_data_t pHwData, u16 number, u32 * pValue );
unsigned char hal_set_dxx_reg( phw_data_t pHwData, u16 number, u32 value );
#define hal_get_time_count( _P ) (_P->time_count/10) // return 100ms count
#define hal_detect_error( _P ) (_P->WbUsb.DetectCount)
@ -116,7 +116,7 @@ unsigned char hal_idle( phw_data_t pHwData );
#define pa_stall_execution( _A ) //OS_SLEEP( 1 )
#define hw_get_cxx_reg( _A, _B, _C )
#define hw_set_cxx_reg( _A, _B, _C )
#define hw_get_dxx_reg( _A, _B, _C ) hal_get_dxx_reg( _A, _B, (PULONG)_C )
#define hw_get_dxx_reg( _A, _B, _C ) hal_get_dxx_reg( _A, _B, (u32 *)_C )
#define hw_set_dxx_reg( _A, _B, _C ) hal_set_dxx_reg( _A, _B, (u32)_C )

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@ -461,7 +461,7 @@ typedef struct _HW_DATA_T
//=====================================================================
// Definition for 802.11
//=====================================================================
PUCHAR bssid_pointer; // Used by hal_get_bssid for return value
u8 *bssid_pointer; // Used by hal_get_bssid for return value
u8 bssid[8];// Only 6 byte will be used. 8 byte is required for read buffer
u8 ssid[32];// maximum ssid length is 32 byte
@ -486,7 +486,7 @@ typedef struct _HW_DATA_T
u32 CurrentRadioSw; // 20060320.2 0:On 1:Off
u32 CurrentRadioHw; // 20060825 0:On 1:Off
PUCHAR power_save_point; // Used by hal_get_power_save_mode for return value
u8 *power_save_point; // Used by hal_get_power_save_mode for return value
u8 cwmin;
u8 desired_power_save;
u8 dtim;// Is running dtim

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@ -25,11 +25,11 @@ EncapAtomicInc(PADAPTER Adapter, void* pAtomic)
{
PWBLINUX pWbLinux = &Adapter->WbLinux;
u32 ltmp;
PULONG pltmp = (PULONG)pAtomic;
OS_SPIN_LOCK_ACQUIRED( &pWbLinux->AtomicSpinLock );
u32 * pltmp = (u32 *)pAtomic;
spin_lock_irq( &pWbLinux->AtomicSpinLock );
(*pltmp)++;
ltmp = (*pltmp);
OS_SPIN_LOCK_RELEASED( &pWbLinux->AtomicSpinLock );
spin_unlock_irq( &pWbLinux->AtomicSpinLock );
return ltmp;
}
@ -38,11 +38,11 @@ EncapAtomicDec(PADAPTER Adapter, void* pAtomic)
{
PWBLINUX pWbLinux = &Adapter->WbLinux;
u32 ltmp;
PULONG pltmp = (PULONG)pAtomic;
OS_SPIN_LOCK_ACQUIRED( &pWbLinux->AtomicSpinLock );
u32 * pltmp = (u32 *)pAtomic;
spin_lock_irq( &pWbLinux->AtomicSpinLock );
(*pltmp)--;
ltmp = (*pltmp);
OS_SPIN_LOCK_RELEASED( &pWbLinux->AtomicSpinLock );
spin_unlock_irq( &pWbLinux->AtomicSpinLock );
return ltmp;
}
@ -51,8 +51,8 @@ WBLINUX_Initial(PADAPTER Adapter)
{
PWBLINUX pWbLinux = &Adapter->WbLinux;
OS_SPIN_LOCK_ALLOCATE( &pWbLinux->SpinLock );
OS_SPIN_LOCK_ALLOCATE( &pWbLinux->AtomicSpinLock );
spin_lock_init( &pWbLinux->SpinLock );
spin_lock_init( &pWbLinux->AtomicSpinLock );
return TRUE;
}
@ -79,7 +79,6 @@ void
WBLINUX_Destroy(PADAPTER Adapter)
{
WBLINUX_stop( Adapter );
OS_SPIN_LOCK_FREE( &pWbNdis->SpinLock );
#ifdef _PE_USB_INI_DUMP_
WBDEBUG(("[w35und] unregister_netdev!\n"));
#endif
@ -142,119 +141,118 @@ unsigned char
WbWLanInitialize(PADAPTER Adapter)
{
phw_data_t pHwData;
PUCHAR pMacAddr, pMacAddr2;
u8 *pMacAddr;
u8 *pMacAddr2;
u32 InitStep = 0;
u8 EEPROM_region;
u8 HwRadioOff;
do {
//
// Setting default value for Linux
//
Adapter->sLocalPara.region_INF = REGION_AUTO;
Adapter->sLocalPara.TxRateMode = RATE_AUTO;
psLOCAL->bMacOperationMode = MODE_802_11_BG; // B/G mode
Adapter->Mds.TxRTSThreshold = DEFAULT_RTSThreshold;
Adapter->Mds.TxFragmentThreshold = DEFAULT_FRAGMENT_THRESHOLD;
hal_set_phy_type( &Adapter->sHwData, RF_WB_242_1 );
Adapter->sLocalPara.MTUsize = MAX_ETHERNET_PACKET_SIZE;
psLOCAL->bPreambleMode = AUTO_MODE;
Adapter->sLocalPara.RadioOffStatus.boSwRadioOff = FALSE;
pHwData = &Adapter->sHwData;
hal_set_phy_type( pHwData, RF_DECIDE_BY_INF );
//
// Setting default value for Linux
//
Adapter->sLocalPara.region_INF = REGION_AUTO;
Adapter->sLocalPara.TxRateMode = RATE_AUTO;
psLOCAL->bMacOperationMode = MODE_802_11_BG; // B/G mode
Adapter->Mds.TxRTSThreshold = DEFAULT_RTSThreshold;
Adapter->Mds.TxFragmentThreshold = DEFAULT_FRAGMENT_THRESHOLD;
hal_set_phy_type( &Adapter->sHwData, RF_WB_242_1 );
Adapter->sLocalPara.MTUsize = MAX_ETHERNET_PACKET_SIZE;
psLOCAL->bPreambleMode = AUTO_MODE;
Adapter->sLocalPara.RadioOffStatus.boSwRadioOff = FALSE;
pHwData = &Adapter->sHwData;
hal_set_phy_type( pHwData, RF_DECIDE_BY_INF );
//
// Initial each module and variable
//
if (!WBLINUX_Initial(Adapter)) {
//
// Initial each module and variable
//
if (!WBLINUX_Initial(Adapter)) {
#ifdef _PE_USB_INI_DUMP_
WBDEBUG(("[w35und]WBNDIS initialization failed\n"));
WBDEBUG(("[w35und]WBNDIS initialization failed\n"));
#endif
break;
}
// Initial Software variable
Adapter->sLocalPara.ShutDowned = FALSE;
//added by ws for wep key error detection
Adapter->sLocalPara.bWepKeyError= FALSE;
Adapter->sLocalPara.bToSelfPacketReceived = FALSE;
Adapter->sLocalPara.WepKeyDetectTimerCount= 2 * 100; /// 2 seconds
// Initial USB hal
InitStep = 1;
pHwData = &Adapter->sHwData;
if (!hal_init_hardware(pHwData, Adapter))
break;
EEPROM_region = hal_get_region_from_EEPROM( pHwData );
if (EEPROM_region != REGION_AUTO)
psLOCAL->region = EEPROM_region;
else {
if (psLOCAL->region_INF != REGION_AUTO)
psLOCAL->region = psLOCAL->region_INF;
else
psLOCAL->region = REGION_USA; //default setting
}
// Get Software setting flag from hal
Adapter->sLocalPara.boAntennaDiversity = FALSE;
if (hal_software_set(pHwData) & 0x00000001)
Adapter->sLocalPara.boAntennaDiversity = TRUE;
//
// For TS module
//
InitStep = 2;
// For MDS module
InitStep = 3;
Mds_initial(Adapter);
//=======================================
// Initialize the SME, SCAN, MLME, ROAM
//=======================================
InitStep = 4;
InitStep = 5;
InitStep = 6;
// If no user-defined address in the registry, use the addresss "burned" on the NIC instead.
pMacAddr = Adapter->sLocalPara.ThisMacAddress;
pMacAddr2 = Adapter->sLocalPara.PermanentAddress;
hal_get_permanent_address( pHwData, Adapter->sLocalPara.PermanentAddress );// Reading ethernet address from EEPROM
if (OS_MEMORY_COMPARE(pMacAddr, "\x00\x00\x00\x00\x00\x00", MAC_ADDR_LENGTH )) // Is equal
{
memcpy( pMacAddr, pMacAddr2, MAC_ADDR_LENGTH );
} else {
// Set the user define MAC address
hal_set_ethernet_address( pHwData, Adapter->sLocalPara.ThisMacAddress );
}
//get current antenna
psLOCAL->bAntennaNo = hal_get_antenna_number(pHwData);
#ifdef _PE_STATE_DUMP_
WBDEBUG(("Driver init, antenna no = %d\n", psLOCAL->bAntennaNo));
#endif
hal_get_hw_radio_off( pHwData );
// Waiting for HAL setting OK
while (!hal_idle(pHwData))
OS_SLEEP(10000);
MTO_Init(Adapter);
HwRadioOff = hal_get_hw_radio_off( pHwData );
psLOCAL->RadioOffStatus.boHwRadioOff = !!HwRadioOff;
hal_set_radio_mode( pHwData, (unsigned char)(psLOCAL->RadioOffStatus.boSwRadioOff || psLOCAL->RadioOffStatus.boHwRadioOff) );
hal_driver_init_OK(pHwData) = 1; // Notify hal that the driver is ready now.
//set a tx power for reference.....
// sme_set_tx_power_level(Adapter, 12); FIXME?
return TRUE;
goto error;
}
while(FALSE);
// Initial Software variable
Adapter->sLocalPara.ShutDowned = FALSE;
//added by ws for wep key error detection
Adapter->sLocalPara.bWepKeyError= FALSE;
Adapter->sLocalPara.bToSelfPacketReceived = FALSE;
Adapter->sLocalPara.WepKeyDetectTimerCount= 2 * 100; /// 2 seconds
// Initial USB hal
InitStep = 1;
pHwData = &Adapter->sHwData;
if (!hal_init_hardware(pHwData, Adapter))
goto error;
EEPROM_region = hal_get_region_from_EEPROM( pHwData );
if (EEPROM_region != REGION_AUTO)
psLOCAL->region = EEPROM_region;
else {
if (psLOCAL->region_INF != REGION_AUTO)
psLOCAL->region = psLOCAL->region_INF;
else
psLOCAL->region = REGION_USA; //default setting
}
// Get Software setting flag from hal
Adapter->sLocalPara.boAntennaDiversity = FALSE;
if (hal_software_set(pHwData) & 0x00000001)
Adapter->sLocalPara.boAntennaDiversity = TRUE;
//
// For TS module
//
InitStep = 2;
// For MDS module
InitStep = 3;
Mds_initial(Adapter);
//=======================================
// Initialize the SME, SCAN, MLME, ROAM
//=======================================
InitStep = 4;
InitStep = 5;
InitStep = 6;
// If no user-defined address in the registry, use the addresss "burned" on the NIC instead.
pMacAddr = Adapter->sLocalPara.ThisMacAddress;
pMacAddr2 = Adapter->sLocalPara.PermanentAddress;
hal_get_permanent_address( pHwData, Adapter->sLocalPara.PermanentAddress );// Reading ethernet address from EEPROM
if (OS_MEMORY_COMPARE(pMacAddr, "\x00\x00\x00\x00\x00\x00", MAC_ADDR_LENGTH )) // Is equal
{
memcpy( pMacAddr, pMacAddr2, MAC_ADDR_LENGTH );
} else {
// Set the user define MAC address
hal_set_ethernet_address( pHwData, Adapter->sLocalPara.ThisMacAddress );
}
//get current antenna
psLOCAL->bAntennaNo = hal_get_antenna_number(pHwData);
#ifdef _PE_STATE_DUMP_
WBDEBUG(("Driver init, antenna no = %d\n", psLOCAL->bAntennaNo));
#endif
hal_get_hw_radio_off( pHwData );
// Waiting for HAL setting OK
while (!hal_idle(pHwData))
OS_SLEEP(10000);
MTO_Init(Adapter);
HwRadioOff = hal_get_hw_radio_off( pHwData );
psLOCAL->RadioOffStatus.boHwRadioOff = !!HwRadioOff;
hal_set_radio_mode( pHwData, (unsigned char)(psLOCAL->RadioOffStatus.boSwRadioOff || psLOCAL->RadioOffStatus.boHwRadioOff) );
hal_driver_init_OK(pHwData) = 1; // Notify hal that the driver is ready now.
//set a tx power for reference.....
// sme_set_tx_power_level(Adapter, 12); FIXME?
return TRUE;
error:
switch (InitStep) {
case 5:
case 4:

Просмотреть файл

@ -24,8 +24,8 @@
typedef struct _WBLINUX
{
OS_SPIN_LOCK AtomicSpinLock;
OS_SPIN_LOCK SpinLock;
spinlock_t AtomicSpinLock;
spinlock_t SpinLock;
u32 shutdown;
OS_ATOMIC ThreadCount;

Просмотреть файл

@ -1,6 +1,6 @@
config PRISM2_USB
tristate "Prism2.5 USB driver"
depends on USB
depends on WLAN_80211 && USB
default n
---help---
This is the wlan-ng prism 2.5 USB driver for a wide range of

Просмотреть файл

@ -824,7 +824,7 @@ PD Record codes
#define HFA384x_CMD_MACPORT_SET(value) ((UINT16)HFA384x_CMD_AINFO_SET(value))
#define HFA384x_CMD_ISRECL(value) ((UINT16)(HFA384x_CMD_AINFO_GET((UINT16)(value) & HFA384x_CMD_RECL)))
#define HFA384x_CMD_RECL_SET(value) ((UINT16)HFA384x_CMD_AINFO_SET(value))
#define HFA384x_CMD_QOS_GET(value) ((UINT16((((UINT16)(value))&((UINT16)0x3000)) >> 12))
#define HFA384x_CMD_QOS_GET(value) ((UINT16)((((UINT16)(value))&((UINT16)0x3000)) >> 12))
#define HFA384x_CMD_QOS_SET(value) ((UINT16)((((UINT16)(value)) << 12) & 0x3000))
#define HFA384x_CMD_ISWRITE(value) ((UINT16)(HFA384x_CMD_AINFO_GET((UINT16)(value) & HFA384x_CMD_WRITE)))
#define HFA384x_CMD_WRITE_SET(value) ((UINT16)HFA384x_CMD_AINFO_SET((UINT16)value))

Просмотреть файл

@ -64,7 +64,6 @@
/*================================================================*/
/* Project Includes */
#include "version.h"
#include "p80211hdr.h"
#include "p80211types.h"
#include "p80211msg.h"

Просмотреть файл

@ -90,8 +90,6 @@
#include <linux/usb.h>
//#endif
#include "wlan_compat.h"
/*================================================================*/
/* Project Includes */

Просмотреть файл

@ -245,11 +245,11 @@ typedef int64_t INT64;
# define preempt_count() (0UL)
#endif
#define WLAN_LOG_ERROR(x,args...) printk(KERN_ERR "%s: " x , __FUNCTION__ , ##args);
#define WLAN_LOG_ERROR(x,args...) printk(KERN_ERR "%s: " x , __func__ , ##args);
#define WLAN_LOG_WARNING(x,args...) printk(KERN_WARNING "%s: " x , __FUNCTION__ , ##args);
#define WLAN_LOG_WARNING(x,args...) printk(KERN_WARNING "%s: " x , __func__ , ##args);
#define WLAN_LOG_NOTICE(x,args...) printk(KERN_NOTICE "%s: " x , __FUNCTION__ , ##args);
#define WLAN_LOG_NOTICE(x,args...) printk(KERN_NOTICE "%s: " x , __func__ , ##args);
#define WLAN_LOG_INFO(args... ) printk(KERN_INFO args)
@ -265,7 +265,7 @@ typedef int64_t INT64;
#define DBFENTER { if ( WLAN_DBVAR >= 5 ){ WLAN_LOG_DEBUG(3,"---->\n"); } }
#define DBFEXIT { if ( WLAN_DBVAR >= 5 ){ WLAN_LOG_DEBUG(3,"<----\n"); } }
#define WLAN_LOG_DEBUG(l,x,args...) if ( WLAN_DBVAR >= (l)) printk(KERN_DEBUG "%s(%lu): " x , __FUNCTION__, (preempt_count() & PREEMPT_MASK), ##args );
#define WLAN_LOG_DEBUG(l,x,args...) if ( WLAN_DBVAR >= (l)) printk(KERN_DEBUG "%s(%lu): " x , __func__, (preempt_count() & PREEMPT_MASK), ##args );
#else
#define WLAN_ASSERT(c)
#define WLAN_HEX_DUMP( l, s, p, n)