staging:csr: remove usage of CsrSnprintf and use scnprintf

This change tries to achieve the removal of the csr driver defined snprintf
and uses the kernel defined snprintf.

After this change i got following build warnings, which are solved in this patch

warnings generated:

drivers/staging/csr/io.c:929:13: warning: format ‘%lu’ expects type ‘long unsigned int’, but argument 4 has type ‘u32’
drivers/staging/csr/io.c:929:13: warning: format ‘%lu’ expects type ‘long unsigned int’, but argument 5 has type ‘u32’
drivers/staging/csr/csr_wifi_hip_udi.c: In function ‘unifi_print_status’:
drivers/staging/csr/csr_wifi_hip_udi.c:78:27: warning: format ‘%lu’ expects type ‘long unsigned int’, but argument 4 has type ‘u32’
drivers/staging/csr/csr_wifi_hip_udi.c:151:27: warning: format ‘%u’ expects type ‘unsigned int’, but argument 5 has type ‘long int’
drivers/staging/csr/csr_wifi_hip_udi.c:257:27: warning: format ‘%lu’ expects type ‘long unsigned int’, but argument 4 has type ‘u32’
drivers/staging/csr/csr_wifi_hip_udi.c:257:27: warning: format ‘%lu’ expects type ‘long unsigned int’, but argument 5 has type ‘u32’
drivers/staging/csr/csr_wifi_hip_udi.c:261:27: warning: format ‘%lu’ expects type ‘long unsigned int’, but argument 4 has type ‘u32’

Signed-off-by: Devendra Naga <develkernel412222@gmail.com>
Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
This commit is contained in:
Devendra Naga 2012-08-16 21:50:03 +05:30 committed by Greg Kroah-Hartman
parent 4f870fe626
commit c4f9e64456
7 changed files with 66 additions and 120 deletions

View File

@ -25,7 +25,6 @@ csr_wifi-y := bh.o \
unifi_event.o \
unifi_pdu_processing.o \
unifi_sme.o \
csr_formatted_io.o \
csr_wifi_hip_card_sdio.o \
csr_wifi_hip_card_sdio_intr.o \
csr_wifi_hip_card_sdio_mem.o \

View File

@ -1,27 +0,0 @@
/*****************************************************************************
(c) Cambridge Silicon Radio Limited 2010
All rights reserved and confidential information of CSR
Refer to LICENSE.txt included with this source for details
on the license terms.
*****************************************************************************/
#include <linux/kernel.h>
#include "csr_formatted_io.h"
s32 CsrSnprintf(char *dest, size_t n, const char *fmt, ...)
{
s32 r;
va_list args;
va_start(args, fmt);
r = vsnprintf(dest, n, fmt, args);
va_end(args);
if (dest && (n > 0))
{
dest[n - 1] = '\0';
}
return r;
}

View File

@ -1,25 +0,0 @@
#ifndef CSR_FORMATTED_IO_H__
#define CSR_FORMATTED_IO_H__
/*****************************************************************************
(c) Cambridge Silicon Radio Limited 2010
All rights reserved and confidential information of CSR
Refer to LICENSE.txt included with this source for details
on the license terms.
*****************************************************************************/
#ifdef __cplusplus
extern "C" {
#endif
#include <linux/types.h>
s32 CsrSnprintf(char *dest, size_t n, const char *fmt, ...);
#ifdef __cplusplus
}
#endif
#endif

View File

@ -1612,13 +1612,13 @@ static CsrResult card_allocate_memory_resources(card_t *card)
/* Reset any state carried forward from a previous life */
card->fh_command_queue.q_rd_ptr = 0;
card->fh_command_queue.q_wr_ptr = 0;
(void)CsrSnprintf(card->fh_command_queue.name, UNIFI_QUEUE_NAME_MAX_LENGTH,
(void)scnprintf(card->fh_command_queue.name, UNIFI_QUEUE_NAME_MAX_LENGTH,
"fh_cmd_q");
for (i = 0; i < UNIFI_NO_OF_TX_QS; i++)
{
card->fh_traffic_queue[i].q_rd_ptr = 0;
card->fh_traffic_queue[i].q_wr_ptr = 0;
(void)CsrSnprintf(card->fh_traffic_queue[i].name,
(void)scnprintf(card->fh_traffic_queue[i].name,
UNIFI_QUEUE_NAME_MAX_LENGTH, "fh_data_q%d", i);
}
#ifndef CSR_WIFI_HIP_TA_DISABLE
@ -1826,13 +1826,13 @@ static void card_init_soft_queues(card_t *card)
/* Reset any state carried forward from a previous life */
card->fh_command_queue.q_rd_ptr = 0;
card->fh_command_queue.q_wr_ptr = 0;
(void)CsrSnprintf(card->fh_command_queue.name, UNIFI_QUEUE_NAME_MAX_LENGTH,
(void)scnprintf(card->fh_command_queue.name, UNIFI_QUEUE_NAME_MAX_LENGTH,
"fh_cmd_q");
for (i = 0; i < UNIFI_NO_OF_TX_QS; i++)
{
card->fh_traffic_queue[i].q_rd_ptr = 0;
card->fh_traffic_queue[i].q_wr_ptr = 0;
(void)CsrSnprintf(card->fh_traffic_queue[i].name,
(void)scnprintf(card->fh_traffic_queue[i].name,
UNIFI_QUEUE_NAME_MAX_LENGTH, "fh_data_q%d", i);
}
#ifndef CSR_WIFI_HIP_TA_DISABLE

View File

@ -64,104 +64,104 @@ s32 unifi_print_status(card_t *card, char *str, s32 *remain)
}
i = n = 0;
written = CsrSnprintf(p, remaining, "Chip ID %u\n",
written = scnprintf(p, remaining, "Chip ID %u\n",
(u16)card->chip_id);
UNIFI_SNPRINTF_RET(p, remaining, written);
written = CsrSnprintf(p, remaining, "Chip Version %04X\n",
written = scnprintf(p, remaining, "Chip Version %04X\n",
card->chip_version);
UNIFI_SNPRINTF_RET(p, remaining, written);
written = CsrSnprintf(p, remaining, "HIP v%u.%u\n",
written = scnprintf(p, remaining, "HIP v%u.%u\n",
(card->config_data.version >> 8) & 0xFF,
card->config_data.version & 0xFF);
UNIFI_SNPRINTF_RET(p, remaining, written);
written = CsrSnprintf(p, remaining, "Build %lu: %s\n",
written = scnprintf(p, remaining, "Build %u: %s\n",
card->build_id, card->build_id_string);
UNIFI_SNPRINTF_RET(p, remaining, written);
cfg = &card->config_data;
written = CsrSnprintf(p, remaining, "sdio ctrl offset %u\n",
written = scnprintf(p, remaining, "sdio ctrl offset %u\n",
cfg->sdio_ctrl_offset);
UNIFI_SNPRINTF_RET(p, remaining, written);
written = CsrSnprintf(p, remaining, "fromhost sigbuf handle %u\n",
written = scnprintf(p, remaining, "fromhost sigbuf handle %u\n",
cfg->fromhost_sigbuf_handle);
UNIFI_SNPRINTF_RET(p, remaining, written);
written = CsrSnprintf(p, remaining, "tohost_sigbuf_handle %u\n",
written = scnprintf(p, remaining, "tohost_sigbuf_handle %u\n",
cfg->tohost_sigbuf_handle);
UNIFI_SNPRINTF_RET(p, remaining, written);
written = CsrSnprintf(p, remaining, "num_fromhost_sig_frags %u\n",
written = scnprintf(p, remaining, "num_fromhost_sig_frags %u\n",
cfg->num_fromhost_sig_frags);
UNIFI_SNPRINTF_RET(p, remaining, written);
written = CsrSnprintf(p, remaining, "num_tohost_sig_frags %u\n",
written = scnprintf(p, remaining, "num_tohost_sig_frags %u\n",
cfg->num_tohost_sig_frags);
UNIFI_SNPRINTF_RET(p, remaining, written);
written = CsrSnprintf(p, remaining, "num_fromhost_data_slots %u\n",
written = scnprintf(p, remaining, "num_fromhost_data_slots %u\n",
cfg->num_fromhost_data_slots);
UNIFI_SNPRINTF_RET(p, remaining, written);
written = CsrSnprintf(p, remaining, "num_tohost_data_slots %u\n",
written = scnprintf(p, remaining, "num_tohost_data_slots %u\n",
cfg->num_tohost_data_slots);
UNIFI_SNPRINTF_RET(p, remaining, written);
written = CsrSnprintf(p, remaining, "data_slot_size %u\n",
written = scnprintf(p, remaining, "data_slot_size %u\n",
cfg->data_slot_size);
UNIFI_SNPRINTF_RET(p, remaining, written);
/* Added by protocol version 0x0001 */
written = CsrSnprintf(p, remaining, "overlay_size %u\n",
written = scnprintf(p, remaining, "overlay_size %u\n",
(u16)cfg->overlay_size);
UNIFI_SNPRINTF_RET(p, remaining, written);
/* Added by protocol version 0x0300 */
written = CsrSnprintf(p, remaining, "data_slot_round %u\n",
written = scnprintf(p, remaining, "data_slot_round %u\n",
cfg->data_slot_round);
UNIFI_SNPRINTF_RET(p, remaining, written);
written = CsrSnprintf(p, remaining, "sig_frag_size %u\n",
written = scnprintf(p, remaining, "sig_frag_size %u\n",
cfg->sig_frag_size);
UNIFI_SNPRINTF_RET(p, remaining, written);
/* Added by protocol version 0x0300 */
written = CsrSnprintf(p, remaining, "tohost_sig_pad %u\n",
written = scnprintf(p, remaining, "tohost_sig_pad %u\n",
cfg->tohost_signal_padding);
UNIFI_SNPRINTF_RET(p, remaining, written);
written = CsrSnprintf(p, remaining, "\nInternal state:\n");
written = scnprintf(p, remaining, "\nInternal state:\n");
UNIFI_SNPRINTF_RET(p, remaining, written);
written = CsrSnprintf(p, remaining, "Last PHY PANIC: %04x:%04x\n",
written = scnprintf(p, remaining, "Last PHY PANIC: %04x:%04x\n",
card->last_phy_panic_code, card->last_phy_panic_arg);
UNIFI_SNPRINTF_RET(p, remaining, written);
written = CsrSnprintf(p, remaining, "Last MAC PANIC: %04x:%04x\n",
written = scnprintf(p, remaining, "Last MAC PANIC: %04x:%04x\n",
card->last_mac_panic_code, card->last_mac_panic_arg);
UNIFI_SNPRINTF_RET(p, remaining, written);
written = CsrSnprintf(p, remaining, "fhsr: %u\n",
written = scnprintf(p, remaining, "fhsr: %u\n",
(u16)card->from_host_signals_r);
UNIFI_SNPRINTF_RET(p, remaining, written);
written = CsrSnprintf(p, remaining, "fhsw: %u\n",
written = scnprintf(p, remaining, "fhsw: %u\n",
(u16)card->from_host_signals_w);
UNIFI_SNPRINTF_RET(p, remaining, written);
written = CsrSnprintf(p, remaining, "thsr: %u\n",
written = scnprintf(p, remaining, "thsr: %u\n",
(u16)card->to_host_signals_r);
UNIFI_SNPRINTF_RET(p, remaining, written);
written = CsrSnprintf(p, remaining, "thsw: %u\n",
written = scnprintf(p, remaining, "thsw: %u\n",
(u16)card->to_host_signals_w);
UNIFI_SNPRINTF_RET(p, remaining, written);
written = CsrSnprintf(p, remaining,
"fh buffer contains: %u signals, %u bytes\n",
written = scnprintf(p, remaining,
"fh buffer contains: %d signals, %ld bytes\n",
card->fh_buffer.count,
card->fh_buffer.ptr - card->fh_buffer.buf);
UNIFI_SNPRINTF_RET(p, remaining, written);
written = CsrSnprintf(p, remaining, "paused: ");
written = scnprintf(p, remaining, "paused: ");
UNIFI_SNPRINTF_RET(p, remaining, written);
for (i = 0; i < sizeof(card->tx_q_paused_flag) / sizeof(card->tx_q_paused_flag[0]); i++)
{
written = CsrSnprintf(p, remaining, card->tx_q_paused_flag[i]?"1" : "0");
written = scnprintf(p, remaining, card->tx_q_paused_flag[i]?"1" : "0");
UNIFI_SNPRINTF_RET(p, remaining, written);
}
written = CsrSnprintf(p, remaining, "\n");
written = scnprintf(p, remaining, "\n");
UNIFI_SNPRINTF_RET(p, remaining, written);
written = CsrSnprintf(p, remaining,
written = scnprintf(p, remaining,
"fh command q: %u waiting, %u free of %u:\n",
CSR_WIFI_HIP_Q_SLOTS_USED(&card->fh_command_queue),
CSR_WIFI_HIP_Q_SLOTS_FREE(&card->fh_command_queue),
@ -169,7 +169,7 @@ s32 unifi_print_status(card_t *card, char *str, s32 *remain)
UNIFI_SNPRINTF_RET(p, remaining, written);
for (i = 0; i < UNIFI_NO_OF_TX_QS; i++)
{
written = CsrSnprintf(p, remaining,
written = scnprintf(p, remaining,
"fh traffic q[%u]: %u waiting, %u free of %u:\n",
i,
CSR_WIFI_HIP_Q_SLOTS_USED(&card->fh_traffic_queue[i]),
@ -178,58 +178,58 @@ s32 unifi_print_status(card_t *card, char *str, s32 *remain)
UNIFI_SNPRINTF_RET(p, remaining, written);
}
written = CsrSnprintf(p, remaining, "fh data slots free: %u\n",
written = scnprintf(p, remaining, "fh data slots free: %u\n",
card->from_host_data?CardGetFreeFromHostDataSlots(card) : 0);
UNIFI_SNPRINTF_RET(p, remaining, written);
written = CsrSnprintf(p, remaining, "From host data slots:");
written = scnprintf(p, remaining, "From host data slots:");
UNIFI_SNPRINTF_RET(p, remaining, written);
n = card->config_data.num_fromhost_data_slots;
for (i = 0; i < n && card->from_host_data; i++)
{
written = CsrSnprintf(p, remaining, " %u",
written = scnprintf(p, remaining, " %u",
(u16)card->from_host_data[i].bd.data_length);
UNIFI_SNPRINTF_RET(p, remaining, written);
}
written = CsrSnprintf(p, remaining, "\n");
written = scnprintf(p, remaining, "\n");
UNIFI_SNPRINTF_RET(p, remaining, written);
written = CsrSnprintf(p, remaining, "To host data slots:");
written = scnprintf(p, remaining, "To host data slots:");
UNIFI_SNPRINTF_RET(p, remaining, written);
n = card->config_data.num_tohost_data_slots;
for (i = 0; i < n && card->to_host_data; i++)
{
written = CsrSnprintf(p, remaining, " %u",
written = scnprintf(p, remaining, " %u",
(u16)card->to_host_data[i].data_length);
UNIFI_SNPRINTF_RET(p, remaining, written);
}
written = CsrSnprintf(p, remaining, "\n");
written = scnprintf(p, remaining, "\n");
UNIFI_SNPRINTF_RET(p, remaining, written);
#ifdef CSR_UNSAFE_SDIO_ACCESS
written = CsrSnprintf(p, remaining, "Host State: %s\n", states[card->host_state]);
written = scnprintf(p, remaining, "Host State: %s\n", states[card->host_state]);
UNIFI_SNPRINTF_RET(p, remaining, written);
r = unifi_check_io_status(card, &iostate);
if (iostate == 1)
{
written = CsrSnprintf(p, remaining, "I/O Check: F1 disabled\n");
written = scnprintf(p, remaining, "I/O Check: F1 disabled\n");
UNIFI_SNPRINTF_RET(p, remaining, written);
}
else
{
if (iostate == 1)
{
written = CsrSnprintf(p, remaining, "I/O Check: pending interrupt\n");
written = scnprintf(p, remaining, "I/O Check: pending interrupt\n");
UNIFI_SNPRINTF_RET(p, remaining, written);
}
written = CsrSnprintf(p, remaining, "BH reason interrupt = %d\n",
written = scnprintf(p, remaining, "BH reason interrupt = %d\n",
card->bh_reason_unifi);
UNIFI_SNPRINTF_RET(p, remaining, written);
written = CsrSnprintf(p, remaining, "BH reason host = %d\n",
written = scnprintf(p, remaining, "BH reason host = %d\n",
card->bh_reason_host);
UNIFI_SNPRINTF_RET(p, remaining, written);
@ -238,26 +238,26 @@ s32 unifi_print_status(card_t *card, char *str, s32 *remain)
r = unifi_read_8_or_16(card, card->sdio_ctrl_addr + 2, &b);
if ((r == CSR_RESULT_SUCCESS) && (!(b & 0x80)))
{
written = CsrSnprintf(p, remaining, "fhsr: %u (driver thinks is %u)\n",
written = scnprintf(p, remaining, "fhsr: %u (driver thinks is %u)\n",
b, card->from_host_signals_r);
UNIFI_SNPRINTF_RET(p, remaining, written);
break;
}
}
iostate = unifi_read_shared_count(card, card->sdio_ctrl_addr + 4);
written = CsrSnprintf(p, remaining, "thsw: %u (driver thinks is %u)\n",
written = scnprintf(p, remaining, "thsw: %u (driver thinks is %u)\n",
iostate, card->to_host_signals_w);
UNIFI_SNPRINTF_RET(p, remaining, written);
}
#endif
written = CsrSnprintf(p, remaining, "\nStats:\n");
written = scnprintf(p, remaining, "\nStats:\n");
UNIFI_SNPRINTF_RET(p, remaining, written);
written = CsrSnprintf(p, remaining, "Total SDIO bytes: R=%lu W=%lu\n",
written = scnprintf(p, remaining, "Total SDIO bytes: R=%u W=%u\n",
card->sdio_bytes_read, card->sdio_bytes_written);
UNIFI_SNPRINTF_RET(p, remaining, written);
written = CsrSnprintf(p, remaining, "Interrupts generated on card: %lu\n",
written = scnprintf(p, remaining, "Interrupts generated on card: %u\n",
card->unifi_interrupt_seq);
UNIFI_SNPRINTF_RET(p, remaining, written);

View File

@ -98,7 +98,6 @@ extern "C" {
#include "csr_framework_ext.h" /* from the synergy porting folder */
#include "csr_sdio.h" /* from the synergy porting folder */
#include "csr_macro.h" /* from the synergy porting folder */
#include "csr_formatted_io.h" /* from the synergy gsp folder */
#include "csr_wifi_result.h"
/* Utility MACROS. Note that UNIFI_MAC_ADDRESS_CMP returns TRUE on success */

View File

@ -347,7 +347,7 @@ register_unifi_sdio(CsrSdioFunction *sdio_dev, int bus_id, struct device *dev)
/*
* We use the slot number as unifi device index.
*/
snprintf(priv->proc_entry_name, 64, "driver/unifi%d", priv->instance);
scnprintf(priv->proc_entry_name, 64, "driver/unifi%d", priv->instance);
/*
* The following complex casting is in place in order to eliminate 64-bit compilation warning
* "cast to/from pointer from/to integer of different size"
@ -904,54 +904,54 @@ uf_read_proc(char *page, char **start, off_t offset, int count,
orig_p = p;
written = CsrSnprintf(p, remain, "UniFi SDIO Driver: %s %s %s\n",
written = scnprintf(p, remain, "UniFi SDIO Driver: %s %s %s\n",
CSR_WIFI_VERSION, __DATE__, __TIME__);
UNIFI_SNPRINTF_RET(p, remain, written);
#ifdef CSR_SME_USERSPACE
written = CsrSnprintf(p, remain, "SME: CSR userspace ");
written = scnprintf(p, remain, "SME: CSR userspace ");
UNIFI_SNPRINTF_RET(p, remain, written);
#ifdef CSR_SUPPORT_WEXT
written = CsrSnprintf(p, remain, "with WEXT support\n");
written = scnprintf(p, remain, "with WEXT support\n");
#else
written = CsrSnprintf(p, remain, "\n");
written = scnprintf(p, remain, "\n");
#endif /* CSR_SUPPORT_WEXT */
UNIFI_SNPRINTF_RET(p, remain, written);
#endif /* CSR_SME_USERSPACE */
#ifdef CSR_NATIVE_LINUX
written = CsrSnprintf(p, remain, "SME: native\n");
written = scnprintf(p, remain, "SME: native\n");
UNIFI_SNPRINTF_RET(p, remain, written);
#endif
#ifdef CSR_SUPPORT_SME
written = CsrSnprintf(p, remain,
"Firmware (ROM) build:%lu, Patch:%lu\n",
written = scnprintf(p, remain,
"Firmware (ROM) build:%u, Patch:%u\n",
priv->card_info.fw_build,
priv->sme_versions.firmwarePatch);
UNIFI_SNPRINTF_RET(p, remain, written);
#endif
p += unifi_print_status(priv->card, p, &remain);
written = CsrSnprintf(p, remain, "Last dbg str: %s\n",
written = scnprintf(p, remain, "Last dbg str: %s\n",
priv->last_debug_string);
UNIFI_SNPRINTF_RET(p, remain, written);
written = CsrSnprintf(p, remain, "Last dbg16:");
written = scnprintf(p, remain, "Last dbg16:");
UNIFI_SNPRINTF_RET(p, remain, written);
for (i = 0; i < 8; i++) {
written = CsrSnprintf(p, remain, " %04X",
written = scnprintf(p, remain, " %04X",
priv->last_debug_word16[i]);
UNIFI_SNPRINTF_RET(p, remain, written);
}
written = CsrSnprintf(p, remain, "\n");
written = scnprintf(p, remain, "\n");
UNIFI_SNPRINTF_RET(p, remain, written);
written = CsrSnprintf(p, remain, " ");
written = scnprintf(p, remain, " ");
UNIFI_SNPRINTF_RET(p, remain, written);
for (; i < 16; i++) {
written = CsrSnprintf(p, remain, " %04X",
written = scnprintf(p, remain, " %04X",
priv->last_debug_word16[i]);
UNIFI_SNPRINTF_RET(p, remain, written);
}
written = CsrSnprintf(p, remain, "\n");
written = scnprintf(p, remain, "\n");
UNIFI_SNPRINTF_RET(p, remain, written);
*start = page;