rtl8188eu/os_dep/osdep_service.c

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/******************************************************************************
*
* Copyright(c) 2007 - 2012 Realtek Corporation. All rights reserved.
*
* This program is free software; you can redistribute it and/or modify it
* under the terms of version 2 of the GNU General Public License 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.,
* 51 Franklin Street, Fifth Floor, Boston, MA 02110, USA
*
*
******************************************************************************/
#define _OSDEP_SERVICE_C_
#include <drv_types.h>
#define RT_TAG '1178'
#ifdef DBG_MEMORY_LEAK
atomic_t _malloc_cnt = ATOMIC_INIT(0);
atomic_t _malloc_size = ATOMIC_INIT(0);
#endif /* DBG_MEMORY_LEAK */
/*
* Translate the OS dependent @param error_code to OS independent RTW_STATUS_CODE
* @return: one of RTW_STATUS_CODE
*/
inline int RTW_STATUS_CODE(int error_code)
{
if (error_code >= 0)
return _SUCCESS;
switch (error_code) {
/* case -ETIMEDOUT: */
/* return RTW_STATUS_TIMEDOUT; */
default:
return _FAIL;
}
}
u32 rtw_atoi(u8 *s)
{
int num = 0, flag = 0;
int i;
for (i = 0; i <= strlen(s); i++) {
if (s[i] >= '0' && s[i] <= '9')
num = num * 10 + s[i] - '0';
else if (s[0] == '-' && i == 0)
flag = 1;
else
break;
}
if (flag == 1)
num = num * -1;
return num;
}
inline u8 *_rtw_vmalloc(u32 sz)
{
u8 *pbuf;
pbuf = vmalloc(sz);
#ifdef DBG_MEMORY_LEAK
if (pbuf != NULL) {
atomic_inc(&_malloc_cnt);
atomic_add(sz, &_malloc_size);
}
#endif /* DBG_MEMORY_LEAK */
return pbuf;
}
inline u8 *_rtw_zvmalloc(u32 sz)
{
u8 *pbuf;
pbuf = _rtw_vmalloc(sz);
if (pbuf != NULL)
memset(pbuf, 0, sz);
return pbuf;
}
inline void _rtw_vmfree(u8 *pbuf, u32 sz)
{
vfree(pbuf);
#ifdef DBG_MEMORY_LEAK
atomic_dec(&_malloc_cnt);
atomic_sub(sz, &_malloc_size);
#endif /* DBG_MEMORY_LEAK */
}
u8 *_rtw_malloc(u32 sz)
{
u8 *pbuf = NULL;
#ifdef RTK_DMP_PLATFORM
if (sz > 0x4000)
pbuf = (u8 *)dvr_malloc(sz);
else
#endif
pbuf = kmalloc(sz, in_interrupt() ? GFP_ATOMIC : GFP_KERNEL);
#ifdef DBG_MEMORY_LEAK
if (pbuf != NULL) {
atomic_inc(&_malloc_cnt);
atomic_add(sz, &_malloc_size);
}
#endif /* DBG_MEMORY_LEAK */
return pbuf;
}
u8 *_rtw_zmalloc(u32 sz)
{
u8 *pbuf = _rtw_malloc(sz);
if (pbuf != NULL)
memset(pbuf, 0, sz);
return pbuf;
}
void _rtw_mfree(u8 *pbuf, u32 sz)
{
#ifdef RTK_DMP_PLATFORM
if (sz > 0x4000)
dvr_free(pbuf);
else
#endif
kfree(pbuf);
#ifdef DBG_MEMORY_LEAK
atomic_dec(&_malloc_cnt);
atomic_sub(sz, &_malloc_size);
#endif /* DBG_MEMORY_LEAK */
}
inline struct sk_buff *_rtw_skb_alloc(u32 sz)
{
return __dev_alloc_skb(sz, in_interrupt() ? GFP_ATOMIC : GFP_KERNEL);
}
inline void _rtw_skb_free(struct sk_buff *skb)
{
dev_kfree_skb_any(skb);
}
inline struct sk_buff *_rtw_skb_copy(const struct sk_buff *skb)
{
return skb_copy(skb, in_interrupt() ? GFP_ATOMIC : GFP_KERNEL);
}
inline struct sk_buff *_rtw_skb_clone(struct sk_buff *skb)
{
return skb_clone(skb, in_interrupt() ? GFP_ATOMIC : GFP_KERNEL);
}
inline struct sk_buff *_rtw_pskb_copy(struct sk_buff *skb)
{
#if (LINUX_VERSION_CODE >= KERNEL_VERSION(2, 6, 36))
return pskb_copy(skb, in_interrupt() ? GFP_ATOMIC : GFP_KERNEL);
#else
return skb_clone(skb, in_interrupt() ? GFP_ATOMIC : GFP_KERNEL);
#endif
}
inline int _rtw_netif_rx(_nic_hdl ndev, struct sk_buff *skb)
{
skb->dev = ndev;
return netif_rx(skb);
}
#ifdef CONFIG_RTW_NAPI
inline int _rtw_netif_receive_skb(_nic_hdl ndev, struct sk_buff *skb)
{
skb->dev = ndev;
return netif_receive_skb(skb);
}
#ifdef CONFIG_RTW_GRO
inline gro_result_t _rtw_napi_gro_receive(struct napi_struct *napi, struct sk_buff *skb)
{
return napi_gro_receive(napi, skb);
}
#endif /* CONFIG_RTW_GRO */
#endif /* CONFIG_RTW_NAPI */
void _rtw_skb_queue_purge(struct sk_buff_head *list)
{
struct sk_buff *skb;
while ((skb = skb_dequeue(list)) != NULL)
_rtw_skb_free(skb);
}
inline void *_rtw_usb_buffer_alloc(struct usb_device *dev, size_t size, dma_addr_t *dma)
{
#if (LINUX_VERSION_CODE >= KERNEL_VERSION(2, 6, 35))
return usb_alloc_coherent(dev, size, (in_interrupt() ? GFP_ATOMIC : GFP_KERNEL), dma);
#else
return usb_buffer_alloc(dev, size, (in_interrupt() ? GFP_ATOMIC : GFP_KERNEL), dma);
#endif
}
inline void _rtw_usb_buffer_free(struct usb_device *dev, size_t size, void *addr, dma_addr_t dma)
{
#if (LINUX_VERSION_CODE >= KERNEL_VERSION(2, 6, 35))
usb_free_coherent(dev, size, addr, dma);
#else
usb_buffer_free(dev, size, addr, dma);
#endif
}
#if defined(DBG_MEM_ALLOC)
struct rtw_mem_stat {
ATOMIC_T alloc; /* the memory bytes we allocate currently */
ATOMIC_T peak; /* the peak memory bytes we allocate */
ATOMIC_T alloc_cnt; /* the alloc count for alloc currently */
ATOMIC_T alloc_err_cnt; /* the error times we fail to allocate memory */
};
struct rtw_mem_stat rtw_mem_type_stat[mstat_tf_idx(MSTAT_TYPE_MAX)];
#ifdef RTW_MEM_FUNC_STAT
struct rtw_mem_stat rtw_mem_func_stat[mstat_ff_idx(MSTAT_FUNC_MAX)];
#endif
char *MSTAT_TYPE_str[] = {
"VIR",
"PHY",
"SKB",
"USB",
};
#ifdef RTW_MEM_FUNC_STAT
char *MSTAT_FUNC_str[] = {
"UNSP",
"IO",
"TXIO",
"RXIO",
"TX",
"RX",
};
#endif
void rtw_mstat_dump(void *sel)
{
int i;
int value_t[4][mstat_tf_idx(MSTAT_TYPE_MAX)];
#ifdef RTW_MEM_FUNC_STAT
int value_f[4][mstat_ff_idx(MSTAT_FUNC_MAX)];
#endif
int vir_alloc, vir_peak, vir_alloc_err, phy_alloc, phy_peak, phy_alloc_err;
int tx_alloc, tx_peak, tx_alloc_err, rx_alloc, rx_peak, rx_alloc_err;
for (i = 0; i < mstat_tf_idx(MSTAT_TYPE_MAX); i++) {
value_t[0][i] = ATOMIC_READ(&(rtw_mem_type_stat[i].alloc));
value_t[1][i] = ATOMIC_READ(&(rtw_mem_type_stat[i].peak));
value_t[2][i] = ATOMIC_READ(&(rtw_mem_type_stat[i].alloc_cnt));
value_t[3][i] = ATOMIC_READ(&(rtw_mem_type_stat[i].alloc_err_cnt));
}
#ifdef RTW_MEM_FUNC_STAT
for (i = 0; i < mstat_ff_idx(MSTAT_FUNC_MAX); i++) {
value_f[0][i] = ATOMIC_READ(&(rtw_mem_func_stat[i].alloc));
value_f[1][i] = ATOMIC_READ(&(rtw_mem_func_stat[i].peak));
value_f[2][i] = ATOMIC_READ(&(rtw_mem_func_stat[i].alloc_cnt));
value_f[3][i] = ATOMIC_READ(&(rtw_mem_func_stat[i].alloc_err_cnt));
}
#endif
RTW_PRINT_SEL(sel, "===================== MSTAT =====================\n");
RTW_PRINT_SEL(sel, "%4s %10s %10s %10s %10s\n", "TAG", "alloc", "peak", "aloc_cnt", "err_cnt");
RTW_PRINT_SEL(sel, "-------------------------------------------------\n");
for (i = 0; i < mstat_tf_idx(MSTAT_TYPE_MAX); i++)
RTW_PRINT_SEL(sel, "%4s %10d %10d %10d %10d\n", MSTAT_TYPE_str[i], value_t[0][i], value_t[1][i], value_t[2][i], value_t[3][i]);
#ifdef RTW_MEM_FUNC_STAT
RTW_PRINT_SEL(sel, "-------------------------------------------------\n");
for (i = 0; i < mstat_ff_idx(MSTAT_FUNC_MAX); i++)
RTW_PRINT_SEL(sel, "%4s %10d %10d %10d %10d\n", MSTAT_FUNC_str[i], value_f[0][i], value_f[1][i], value_f[2][i], value_f[3][i]);
#endif
}
void rtw_mstat_update(const enum mstat_f flags, const MSTAT_STATUS status, u32 sz)
{
static u32 update_time = 0;
int peak, alloc;
int i;
/* initialization */
if (!update_time) {
for (i = 0; i < mstat_tf_idx(MSTAT_TYPE_MAX); i++) {
ATOMIC_SET(&(rtw_mem_type_stat[i].alloc), 0);
ATOMIC_SET(&(rtw_mem_type_stat[i].peak), 0);
ATOMIC_SET(&(rtw_mem_type_stat[i].alloc_cnt), 0);
ATOMIC_SET(&(rtw_mem_type_stat[i].alloc_err_cnt), 0);
}
#ifdef RTW_MEM_FUNC_STAT
for (i = 0; i < mstat_ff_idx(MSTAT_FUNC_MAX); i++) {
ATOMIC_SET(&(rtw_mem_func_stat[i].alloc), 0);
ATOMIC_SET(&(rtw_mem_func_stat[i].peak), 0);
ATOMIC_SET(&(rtw_mem_func_stat[i].alloc_cnt), 0);
ATOMIC_SET(&(rtw_mem_func_stat[i].alloc_err_cnt), 0);
}
#endif
}
switch (status) {
case MSTAT_ALLOC_SUCCESS:
ATOMIC_INC(&(rtw_mem_type_stat[mstat_tf_idx(flags)].alloc_cnt));
alloc = ATOMIC_ADD_RETURN(&(rtw_mem_type_stat[mstat_tf_idx(flags)].alloc), sz);
peak = ATOMIC_READ(&(rtw_mem_type_stat[mstat_tf_idx(flags)].peak));
if (peak < alloc)
ATOMIC_SET(&(rtw_mem_type_stat[mstat_tf_idx(flags)].peak), alloc);
#ifdef RTW_MEM_FUNC_STAT
ATOMIC_INC(&(rtw_mem_func_stat[mstat_ff_idx(flags)].alloc_cnt));
alloc = ATOMIC_ADD_RETURN(&(rtw_mem_func_stat[mstat_ff_idx(flags)].alloc), sz);
peak = ATOMIC_READ(&(rtw_mem_func_stat[mstat_ff_idx(flags)].peak));
if (peak < alloc)
ATOMIC_SET(&(rtw_mem_func_stat[mstat_ff_idx(flags)].peak), alloc);
#endif
break;
case MSTAT_ALLOC_FAIL:
ATOMIC_INC(&(rtw_mem_type_stat[mstat_tf_idx(flags)].alloc_err_cnt));
#ifdef RTW_MEM_FUNC_STAT
ATOMIC_INC(&(rtw_mem_func_stat[mstat_ff_idx(flags)].alloc_err_cnt));
#endif
break;
case MSTAT_FREE:
ATOMIC_DEC(&(rtw_mem_type_stat[mstat_tf_idx(flags)].alloc_cnt));
ATOMIC_SUB(&(rtw_mem_type_stat[mstat_tf_idx(flags)].alloc), sz);
#ifdef RTW_MEM_FUNC_STAT
ATOMIC_DEC(&(rtw_mem_func_stat[mstat_ff_idx(flags)].alloc_cnt));
ATOMIC_SUB(&(rtw_mem_func_stat[mstat_ff_idx(flags)].alloc), sz);
#endif
break;
};
/* if (rtw_get_passing_time_ms(update_time) > 5000) { */
/* rtw_mstat_dump(RTW_DBGDUMP); */
update_time = rtw_get_current_time();
/* } */
}
#ifndef SIZE_MAX
#define SIZE_MAX (~(size_t)0)
#endif
struct mstat_sniff_rule {
enum mstat_f flags;
size_t lb;
size_t hb;
};
struct mstat_sniff_rule mstat_sniff_rules[] = {
{MSTAT_TYPE_PHY, 4097, SIZE_MAX},
};
int mstat_sniff_rule_num = sizeof(mstat_sniff_rules) / sizeof(struct mstat_sniff_rule);
bool match_mstat_sniff_rules(const enum mstat_f flags, const size_t size)
{
int i;
for (i = 0; i < mstat_sniff_rule_num; i++) {
if (mstat_sniff_rules[i].flags == flags
&& mstat_sniff_rules[i].lb <= size
&& mstat_sniff_rules[i].hb >= size)
return true;
}
return false;
}
inline u8 *dbg_rtw_vmalloc(u32 sz, const enum mstat_f flags, const char *func, const int line)
{
u8 *p;
if (match_mstat_sniff_rules(flags, sz))
RTW_INFO("DBG_MEM_ALLOC %s:%d %s(%d)\n", func, line, __func__, (sz));
p = _rtw_vmalloc((sz));
rtw_mstat_update(
flags
, p ? MSTAT_ALLOC_SUCCESS : MSTAT_ALLOC_FAIL
, sz
);
return p;
}
inline u8 *dbg_rtw_zvmalloc(u32 sz, const enum mstat_f flags, const char *func, const int line)
{
u8 *p;
if (match_mstat_sniff_rules(flags, sz))
RTW_INFO("DBG_MEM_ALLOC %s:%d %s(%d)\n", func, line, __func__, (sz));
p = _rtw_zvmalloc((sz));
rtw_mstat_update(
flags
, p ? MSTAT_ALLOC_SUCCESS : MSTAT_ALLOC_FAIL
, sz
);
return p;
}
inline void dbg_rtw_vmfree(u8 *pbuf, u32 sz, const enum mstat_f flags, const char *func, const int line)
{
if (match_mstat_sniff_rules(flags, sz))
RTW_INFO("DBG_MEM_ALLOC %s:%d %s(%d)\n", func, line, __func__, (sz));
_rtw_vmfree((pbuf), (sz));
rtw_mstat_update(
flags
, MSTAT_FREE
, sz
);
}
inline u8 *dbg_rtw_malloc(u32 sz, const enum mstat_f flags, const char *func, const int line)
{
u8 *p;
if (match_mstat_sniff_rules(flags, sz))
RTW_INFO("DBG_MEM_ALLOC %s:%d %s(%d)\n", func, line, __func__, (sz));
p = _rtw_malloc((sz));
rtw_mstat_update(
flags
, p ? MSTAT_ALLOC_SUCCESS : MSTAT_ALLOC_FAIL
, sz
);
return p;
}
inline u8 *dbg_rtw_zmalloc(u32 sz, const enum mstat_f flags, const char *func, const int line)
{
u8 *p;
if (match_mstat_sniff_rules(flags, sz))
RTW_INFO("DBG_MEM_ALLOC %s:%d %s(%d)\n", func, line, __func__, (sz));
p = _rtw_zmalloc((sz));
rtw_mstat_update(
flags
, p ? MSTAT_ALLOC_SUCCESS : MSTAT_ALLOC_FAIL
, sz
);
return p;
}
inline void dbg_rtw_mfree(u8 *pbuf, u32 sz, const enum mstat_f flags, const char *func, const int line)
{
if (match_mstat_sniff_rules(flags, sz))
RTW_INFO("DBG_MEM_ALLOC %s:%d %s(%d)\n", func, line, __func__, (sz));
_rtw_mfree((pbuf), (sz));
rtw_mstat_update(
flags
, MSTAT_FREE
, sz
);
}
inline struct sk_buff *dbg_rtw_skb_alloc(unsigned int size, const enum mstat_f flags, const char *func, int line)
{
struct sk_buff *skb;
unsigned int truesize = 0;
skb = _rtw_skb_alloc(size);
if (skb)
truesize = skb->truesize;
if (!skb || truesize < size || match_mstat_sniff_rules(flags, truesize))
RTW_INFO("DBG_MEM_ALLOC %s:%d %s(%d), skb:%p, truesize=%u\n", func, line, __func__, size, skb, truesize);
rtw_mstat_update(
flags
, skb ? MSTAT_ALLOC_SUCCESS : MSTAT_ALLOC_FAIL
, truesize
);
return skb;
}
inline void dbg_rtw_skb_free(struct sk_buff *skb, const enum mstat_f flags, const char *func, int line)
{
unsigned int truesize = skb->truesize;
if (match_mstat_sniff_rules(flags, truesize))
RTW_INFO("DBG_MEM_ALLOC %s:%d %s, truesize=%u\n", func, line, __func__, truesize);
_rtw_skb_free(skb);
rtw_mstat_update(
flags
, MSTAT_FREE
, truesize
);
}
inline struct sk_buff *dbg_rtw_skb_copy(const struct sk_buff *skb, const enum mstat_f flags, const char *func, const int line)
{
struct sk_buff *skb_cp;
unsigned int truesize = skb->truesize;
unsigned int cp_truesize = 0;
skb_cp = _rtw_skb_copy(skb);
if (skb_cp)
cp_truesize = skb_cp->truesize;
if (!skb_cp || cp_truesize < truesize || match_mstat_sniff_rules(flags, cp_truesize))
RTW_INFO("DBG_MEM_ALLOC %s:%d %s(%u), skb_cp:%p, cp_truesize=%u\n", func, line, __func__, truesize, skb_cp, cp_truesize);
rtw_mstat_update(
flags
, skb_cp ? MSTAT_ALLOC_SUCCESS : MSTAT_ALLOC_FAIL
, truesize
);
return skb_cp;
}
inline struct sk_buff *dbg_rtw_skb_clone(struct sk_buff *skb, const enum mstat_f flags, const char *func, const int line)
{
struct sk_buff *skb_cl;
unsigned int truesize = skb->truesize;
unsigned int cl_truesize = 0;
skb_cl = _rtw_skb_clone(skb);
if (skb_cl)
cl_truesize = skb_cl->truesize;
if (!skb_cl || cl_truesize < truesize || match_mstat_sniff_rules(flags, cl_truesize))
RTW_INFO("DBG_MEM_ALLOC %s:%d %s(%u), skb_cl:%p, cl_truesize=%u\n", func, line, __func__, truesize, skb_cl, cl_truesize);
rtw_mstat_update(
flags
, skb_cl ? MSTAT_ALLOC_SUCCESS : MSTAT_ALLOC_FAIL
, truesize
);
return skb_cl;
}
inline int dbg_rtw_netif_rx(_nic_hdl ndev, struct sk_buff *skb, const enum mstat_f flags, const char *func, int line)
{
int ret;
unsigned int truesize = skb->truesize;
if (match_mstat_sniff_rules(flags, truesize))
RTW_INFO("DBG_MEM_ALLOC %s:%d %s, truesize=%u\n", func, line, __func__, truesize);
ret = _rtw_netif_rx(ndev, skb);
rtw_mstat_update(
flags
, MSTAT_FREE
, truesize
);
return ret;
}
#ifdef CONFIG_RTW_NAPI
inline int dbg_rtw_netif_receive_skb(_nic_hdl ndev, struct sk_buff *skb, const enum mstat_f flags, const char *func, int line)
{
int ret;
unsigned int truesize = skb->truesize;
if (match_mstat_sniff_rules(flags, truesize))
RTW_INFO("DBG_MEM_ALLOC %s:%d %s, truesize=%u\n", func, line, __func__, truesize);
ret = _rtw_netif_receive_skb(ndev, skb);
rtw_mstat_update(
flags
, MSTAT_FREE
, truesize
);
return ret;
}
#ifdef CONFIG_RTW_GRO
inline gro_result_t dbg_rtw_napi_gro_receive(struct napi_struct *napi, struct sk_buff *skb, const enum mstat_f flags, const char *func, int line)
{
int ret;
unsigned int truesize = skb->truesize;
if (match_mstat_sniff_rules(flags, truesize))
RTW_INFO("DBG_MEM_ALLOC %s:%d %s, truesize=%u\n", func, line, __func__, truesize);
ret = _rtw_napi_gro_receive(napi, skb);
rtw_mstat_update(
flags
, MSTAT_FREE
, truesize
);
return ret;
}
#endif /* CONFIG_RTW_GRO */
#endif /* CONFIG_RTW_NAPI */
inline void dbg_rtw_skb_queue_purge(struct sk_buff_head *list, enum mstat_f flags, const char *func, int line)
{
struct sk_buff *skb;
while ((skb = skb_dequeue(list)) != NULL)
dbg_rtw_skb_free(skb, flags, func, line);
}
inline void *dbg_rtw_usb_buffer_alloc(struct usb_device *dev, size_t size, dma_addr_t *dma, const enum mstat_f flags, const char *func, int line)
{
void *p;
if (match_mstat_sniff_rules(flags, size))
RTW_INFO("DBG_MEM_ALLOC %s:%d %s(%zu)\n", func, line, __func__, size);
p = _rtw_usb_buffer_alloc(dev, size, dma);
rtw_mstat_update(
flags
, p ? MSTAT_ALLOC_SUCCESS : MSTAT_ALLOC_FAIL
, size
);
return p;
}
inline void dbg_rtw_usb_buffer_free(struct usb_device *dev, size_t size, void *addr, dma_addr_t dma, const enum mstat_f flags, const char *func, int line)
{
if (match_mstat_sniff_rules(flags, size))
RTW_INFO("DBG_MEM_ALLOC %s:%d %s(%zu)\n", func, line, __func__, size);
_rtw_usb_buffer_free(dev, size, addr, dma);
rtw_mstat_update(
flags
, MSTAT_FREE
, size
);
}
#endif /* defined(DBG_MEM_ALLOC) */
void *rtw_malloc2d(int h, int w, size_t size)
{
int j;
void **a = (void **) rtw_zmalloc(h * sizeof(void *) + h * w * size);
if (a == NULL) {
RTW_INFO("%s: alloc memory fail!\n", __func__);
return NULL;
}
for (j = 0; j < h; j++)
a[j] = ((char *)(a + h)) + j * w * size;
return a;
}
void rtw_mfree2d(void *pbuf, int h, int w, int size)
{
rtw_mfree((u8 *)pbuf, h * sizeof(void *) + w * h * size);
}
void _rtw_init_sema(_sema *sema, int init_val)
{
sema_init(sema, init_val);
}
void _rtw_free_sema(_sema *sema)
{
}
void _rtw_up_sema(_sema *sema)
{
up(sema);
}
u32 _rtw_down_sema(_sema *sema)
{
if (down_interruptible(sema))
return _FAIL;
return _SUCCESS;
}
void _rtw_mutex_init(_mutex *pmutex)
{
#if (LINUX_VERSION_CODE >= KERNEL_VERSION(2, 6, 37))
mutex_init(pmutex);
#else
init_MUTEX(pmutex);
#endif
}
void _rtw_mutex_free(_mutex *pmutex)
{
#if (LINUX_VERSION_CODE >= KERNEL_VERSION(2, 6, 37))
mutex_destroy(pmutex);
#endif
}
void _rtw_spinlock_free(_lock *plock)
{
}
void _rtw_spinlock(_lock *plock)
{
spin_lock(plock);
}
void _rtw_spinunlock(_lock *plock)
{
spin_unlock(plock);
}
void _rtw_spinlock_ex(_lock *plock)
{
spin_lock(plock);
}
void _rtw_spinunlock_ex(_lock *plock)
{
spin_unlock(plock);
}
void _rtw_init_queue(_queue *pqueue)
{
INIT_LIST_HEAD(&(pqueue->queue));
spin_lock_init(&(pqueue->lock));
}
void _rtw_deinit_queue(_queue *pqueue)
{
_rtw_spinlock_free(&(pqueue->lock));
}
u32 _rtw_queue_empty(_queue *pqueue)
{
return list_empty(&(pqueue->queue));
}
u32 rtw_end_of_queue_search(_list *head, _list *plist)
{
if (head == plist)
return true;
else
return false;
}
u32 rtw_get_current_time(void)
{
return jiffies;
}
inline u32 rtw_systime_to_ms(u32 systime)
{
return systime * 1000 / HZ;
}
inline u32 rtw_ms_to_systime(u32 ms)
{
return ms * HZ / 1000;
}
/* the input parameter start use the same unit as returned by rtw_get_current_time */
inline s32 rtw_get_passing_time_ms(u32 start)
{
return rtw_systime_to_ms(jiffies - start);
}
inline s32 rtw_get_time_interval_ms(u32 start, u32 end)
{
return rtw_systime_to_ms(end - start);
}
void rtw_sleep_schedulable(int ms)
{
u32 delta;
delta = (ms * HZ) / 1000; /* (ms) */
if (delta == 0) {
delta = 1;/* 1 ms */
}
set_current_state(TASK_INTERRUPTIBLE);
if (schedule_timeout(delta) != 0)
return ;
return;
}
void rtw_msleep_os(int ms)
{
#if (LINUX_VERSION_CODE >= KERNEL_VERSION(2, 6, 36))
if (ms < 20) {
unsigned long us = ms * 1000UL;
usleep_range(us, us + 1000UL);
} else
#endif
msleep((unsigned int)ms);
}
void rtw_usleep_os(int us)
{
/* msleep((unsigned int)us); */
#if (LINUX_VERSION_CODE >= KERNEL_VERSION(2, 6, 36))
usleep_range(us, us + 1);
#else
if (1 < (us / 1000))
msleep(1);
else
msleep((us / 1000) + 1);
#endif
}
#ifdef DBG_DELAY_OS
void _rtw_mdelay_os(int ms, const char *func, const int line)
{
RTW_INFO("%s:%d %s(%d)\n", func, line, __func__, ms);
mdelay((unsigned long)ms);
}
void _rtw_udelay_os(int us, const char *func, const int line)
{
RTW_INFO("%s:%d %s(%d)\n", func, line, __func__, us);
udelay((unsigned long)us);
}
#else
void rtw_mdelay_os(int ms)
{
mdelay((unsigned long)ms);
}
void rtw_udelay_os(int us)
{
udelay((unsigned long)us);
}
#endif
void rtw_yield_os(void)
{
yield();
}
#define RTW_SUSPEND_LOCK_NAME "rtw_wifi"
#define RTW_SUSPEND_EXT_LOCK_NAME "rtw_wifi_ext"
#define RTW_SUSPEND_RX_LOCK_NAME "rtw_wifi_rx"
#define RTW_SUSPEND_TRAFFIC_LOCK_NAME "rtw_wifi_traffic"
#define RTW_SUSPEND_RESUME_LOCK_NAME "rtw_wifi_resume"
#define RTW_RESUME_SCAN_LOCK_NAME "rtw_wifi_scan"
#ifdef CONFIG_WAKELOCK
static struct wake_lock rtw_suspend_lock;
static struct wake_lock rtw_suspend_ext_lock;
static struct wake_lock rtw_suspend_rx_lock;
static struct wake_lock rtw_suspend_traffic_lock;
static struct wake_lock rtw_suspend_resume_lock;
static struct wake_lock rtw_resume_scan_lock;
#elif defined(CONFIG_ANDROID_POWER)
static android_suspend_lock_t rtw_suspend_lock = {
.name = RTW_SUSPEND_LOCK_NAME
};
static android_suspend_lock_t rtw_suspend_ext_lock = {
.name = RTW_SUSPEND_EXT_LOCK_NAME
};
static android_suspend_lock_t rtw_suspend_rx_lock = {
.name = RTW_SUSPEND_RX_LOCK_NAME
};
static android_suspend_lock_t rtw_suspend_traffic_lock = {
.name = RTW_SUSPEND_TRAFFIC_LOCK_NAME
};
static android_suspend_lock_t rtw_suspend_resume_lock = {
.name = RTW_SUSPEND_RESUME_LOCK_NAME
};
static android_suspend_lock_t rtw_resume_scan_lock = {
.name = RTW_RESUME_SCAN_LOCK_NAME
};
#endif
inline void rtw_suspend_lock_init(void)
{
#ifdef CONFIG_WAKELOCK
wake_lock_init(&rtw_suspend_lock, WAKE_LOCK_SUSPEND, RTW_SUSPEND_LOCK_NAME);
wake_lock_init(&rtw_suspend_ext_lock, WAKE_LOCK_SUSPEND, RTW_SUSPEND_EXT_LOCK_NAME);
wake_lock_init(&rtw_suspend_rx_lock, WAKE_LOCK_SUSPEND, RTW_SUSPEND_RX_LOCK_NAME);
wake_lock_init(&rtw_suspend_traffic_lock, WAKE_LOCK_SUSPEND, RTW_SUSPEND_TRAFFIC_LOCK_NAME);
wake_lock_init(&rtw_suspend_resume_lock, WAKE_LOCK_SUSPEND, RTW_SUSPEND_RESUME_LOCK_NAME);
wake_lock_init(&rtw_resume_scan_lock, WAKE_LOCK_SUSPEND, RTW_RESUME_SCAN_LOCK_NAME);
#elif defined(CONFIG_ANDROID_POWER)
android_init_suspend_lock(&rtw_suspend_lock);
android_init_suspend_lock(&rtw_suspend_ext_lock);
android_init_suspend_lock(&rtw_suspend_rx_lock);
android_init_suspend_lock(&rtw_suspend_traffic_lock);
android_init_suspend_lock(&rtw_suspend_resume_lock);
android_init_suspend_lock(&rtw_resume_scan_lock);
#endif
}
inline void rtw_suspend_lock_uninit(void)
{
#ifdef CONFIG_WAKELOCK
wake_lock_destroy(&rtw_suspend_lock);
wake_lock_destroy(&rtw_suspend_ext_lock);
wake_lock_destroy(&rtw_suspend_rx_lock);
wake_lock_destroy(&rtw_suspend_traffic_lock);
wake_lock_destroy(&rtw_suspend_resume_lock);
wake_lock_destroy(&rtw_resume_scan_lock);
#elif defined(CONFIG_ANDROID_POWER)
android_uninit_suspend_lock(&rtw_suspend_lock);
android_uninit_suspend_lock(&rtw_suspend_ext_lock);
android_uninit_suspend_lock(&rtw_suspend_rx_lock);
android_uninit_suspend_lock(&rtw_suspend_traffic_lock);
android_uninit_suspend_lock(&rtw_suspend_resume_lock);
android_uninit_suspend_lock(&rtw_resume_scan_lock);
#endif
}
inline void rtw_lock_suspend(void)
{
#ifdef CONFIG_WAKELOCK
wake_lock(&rtw_suspend_lock);
#elif defined(CONFIG_ANDROID_POWER)
android_lock_suspend(&rtw_suspend_lock);
#endif
#if defined(CONFIG_WAKELOCK) || defined(CONFIG_ANDROID_POWER)
/* RTW_INFO("####%s: suspend_lock_count:%d####\n", __func__, rtw_suspend_lock.stat.count); */
#endif
}
inline void rtw_unlock_suspend(void)
{
#ifdef CONFIG_WAKELOCK
wake_unlock(&rtw_suspend_lock);
#elif defined(CONFIG_ANDROID_POWER)
android_unlock_suspend(&rtw_suspend_lock);
#endif
#if defined(CONFIG_WAKELOCK) || defined(CONFIG_ANDROID_POWER)
/* RTW_INFO("####%s: suspend_lock_count:%d####\n", __func__, rtw_suspend_lock.stat.count); */
#endif
}
inline void rtw_resume_lock_suspend(void)
{
#ifdef CONFIG_WAKELOCK
wake_lock(&rtw_suspend_resume_lock);
#elif defined(CONFIG_ANDROID_POWER)
android_lock_suspend(&rtw_suspend_resume_lock);
#endif
#if defined(CONFIG_WAKELOCK) || defined(CONFIG_ANDROID_POWER)
/* RTW_INFO("####%s: suspend_lock_count:%d####\n", __func__, rtw_suspend_lock.stat.count); */
#endif
}
inline void rtw_resume_unlock_suspend(void)
{
#ifdef CONFIG_WAKELOCK
wake_unlock(&rtw_suspend_resume_lock);
#elif defined(CONFIG_ANDROID_POWER)
android_unlock_suspend(&rtw_suspend_resume_lock);
#endif
#if defined(CONFIG_WAKELOCK) || defined(CONFIG_ANDROID_POWER)
/* RTW_INFO("####%s: suspend_lock_count:%d####\n", __func__, rtw_suspend_lock.stat.count); */
#endif
}
inline void rtw_lock_suspend_timeout(u32 timeout_ms)
{
#ifdef CONFIG_WAKELOCK
wake_lock_timeout(&rtw_suspend_lock, rtw_ms_to_systime(timeout_ms));
#elif defined(CONFIG_ANDROID_POWER)
android_lock_suspend_auto_expire(&rtw_suspend_lock, rtw_ms_to_systime(timeout_ms));
#endif
}
inline void rtw_lock_ext_suspend_timeout(u32 timeout_ms)
{
#ifdef CONFIG_WAKELOCK
wake_lock_timeout(&rtw_suspend_ext_lock, rtw_ms_to_systime(timeout_ms));
#elif defined(CONFIG_ANDROID_POWER)
android_lock_suspend_auto_expire(&rtw_suspend_ext_lock, rtw_ms_to_systime(timeout_ms));
#endif
/* RTW_INFO("EXT lock timeout:%d\n", timeout_ms); */
}
inline void rtw_lock_rx_suspend_timeout(u32 timeout_ms)
{
#ifdef CONFIG_WAKELOCK
wake_lock_timeout(&rtw_suspend_rx_lock, rtw_ms_to_systime(timeout_ms));
#elif defined(CONFIG_ANDROID_POWER)
android_lock_suspend_auto_expire(&rtw_suspend_rx_lock, rtw_ms_to_systime(timeout_ms));
#endif
/* RTW_INFO("RX lock timeout:%d\n", timeout_ms); */
}
inline void rtw_lock_traffic_suspend_timeout(u32 timeout_ms)
{
#ifdef CONFIG_WAKELOCK
wake_lock_timeout(&rtw_suspend_traffic_lock, rtw_ms_to_systime(timeout_ms));
#elif defined(CONFIG_ANDROID_POWER)
android_lock_suspend_auto_expire(&rtw_suspend_traffic_lock, rtw_ms_to_systime(timeout_ms));
#endif
/* RTW_INFO("traffic lock timeout:%d\n", timeout_ms); */
}
inline void rtw_lock_resume_scan_timeout(u32 timeout_ms)
{
#ifdef CONFIG_WAKELOCK
wake_lock_timeout(&rtw_resume_scan_lock, rtw_ms_to_systime(timeout_ms));
#elif defined(CONFIG_ANDROID_POWER)
android_lock_suspend_auto_expire(&rtw_resume_scan_lock, rtw_ms_to_systime(timeout_ms));
#endif
/* RTW_INFO("resume scan lock:%d\n", timeout_ms); */
}
inline void ATOMIC_SET(ATOMIC_T *v, int i)
{
atomic_set(v, i);
}
inline int ATOMIC_READ(ATOMIC_T *v)
{
return atomic_read(v);
}
inline void ATOMIC_ADD(ATOMIC_T *v, int i)
{
atomic_add(i, v);
}
inline void ATOMIC_SUB(ATOMIC_T *v, int i)
{
atomic_sub(i, v);
}
inline void ATOMIC_INC(ATOMIC_T *v)
{
atomic_inc(v);
}
inline void ATOMIC_DEC(ATOMIC_T *v)
{
atomic_dec(v);
}
inline int ATOMIC_ADD_RETURN(ATOMIC_T *v, int i)
{
return atomic_add_return(i, v);
}
inline int ATOMIC_SUB_RETURN(ATOMIC_T *v, int i)
{
return atomic_sub_return(i, v);
}
inline int ATOMIC_INC_RETURN(ATOMIC_T *v)
{
return atomic_inc_return(v);
}
inline int ATOMIC_DEC_RETURN(ATOMIC_T *v)
{
return atomic_dec_return(v);
}
/*
* Open a file with the specific @param path, @param flag, @param mode
* @param fpp the pointer of struct file pointer to get struct file pointer while file opening is success
* @param path the path of the file to open
* @param flag file operation flags, please refer to linux document
* @param mode please refer to linux document
* @return Linux specific error code
*/
static int openFile(struct file **fpp, const char *path, int flag, int mode)
{
struct file *fp;
fp = filp_open(path, flag, mode);
if (IS_ERR(fp)) {
*fpp = NULL;
return PTR_ERR(fp);
} else {
*fpp = fp;
return 0;
}
}
/*
* Close the file with the specific @param fp
* @param fp the pointer of struct file to close
* @return always 0
*/
static int closeFile(struct file *fp)
{
filp_close(fp, NULL);
return 0;
}
static int readFile(struct file *fp, char *buf, int len)
{
int rlen = 0, sum = 0;
#if (LINUX_VERSION_CODE >= KERNEL_VERSION(4, 1, 0))
if (!(fp->f_mode & FMODE_CAN_READ))
#else
if (!fp->f_op || !fp->f_op->read)
#endif
return -EPERM;
while (sum < len) {
#if (LINUX_VERSION_CODE >= KERNEL_VERSION(4, 1, 0))
#if (LINUX_VERSION_CODE >= KERNEL_VERSION(4, 14, 0))
rlen = kernel_read(fp, buf + sum, len - sum, &fp->f_pos);
#else
rlen = __vfs_read(fp, buf + sum, len - sum, &fp->f_pos);
#endif
#else
rlen = fp->f_op->read(fp, buf + sum, len - sum, &fp->f_pos);
#endif
if (rlen > 0)
sum += rlen;
else if (0 != rlen)
return rlen;
else
break;
}
return sum;
}
static int writeFile(struct file *fp, char *buf, int len)
{
int wlen = 0, sum = 0;
if (!fp->f_op || !fp->f_op->write)
return -EPERM;
while (sum < len) {
wlen = fp->f_op->write(fp, buf + sum, len - sum, &fp->f_pos);
if (wlen > 0)
sum += wlen;
else if (0 != wlen)
return wlen;
else
break;
}
return sum;
}
/*
* Test if the specifi @param path is a file and readable
* If readable, @param sz is got
* @param path the path of the file to test
* @return Linux specific error code
*/
static int isFileReadable(const char *path, u32 *sz)
{
struct file *fp;
int ret = 0;
mm_segment_t oldfs;
char buf;
fp = filp_open(path, O_RDONLY, 0);
if (IS_ERR(fp))
ret = PTR_ERR(fp);
else {
oldfs = get_fs();
set_fs(get_ds());
if (1 != readFile(fp, &buf, 1))
ret = PTR_ERR(fp);
if (ret == 0 && sz) {
#if (LINUX_VERSION_CODE >= KERNEL_VERSION(3, 19, 0))
*sz = i_size_read(fp->f_path.dentry->d_inode);
#else
*sz = i_size_read(fp->f_dentry->d_inode);
#endif
}
set_fs(oldfs);
filp_close(fp, NULL);
}
return ret;
}
/*
* Open the file with @param path and retrive the file content into memory starting from @param buf for @param sz at most
* @param path the path of the file to open and read
* @param buf the starting address of the buffer to store file content
* @param sz how many bytes to read at most
* @return the byte we've read, or Linux specific error code
*/
static int retriveFromFile(const char *path, u8 *buf, u32 sz)
{
int ret = -1;
mm_segment_t oldfs;
struct file *fp;
if (path && buf) {
ret = openFile(&fp, path, O_RDONLY, 0);
if (0 == ret) {
RTW_INFO("%s openFile path:%s fp=%p\n", __func__, path , fp);
oldfs = get_fs();
set_fs(get_ds());
ret = readFile(fp, buf, sz);
set_fs(oldfs);
closeFile(fp);
RTW_INFO("%s readFile, ret:%d\n", __func__, ret);
} else
RTW_INFO("%s openFile path:%s Fail, ret:%d\n", __func__, path, ret);
} else {
RTW_INFO("%s NULL pointer\n", __func__);
ret = -EINVAL;
}
return ret;
}
/*
* Open the file with @param path and wirte @param sz byte of data starting from @param buf into the file
* @param path the path of the file to open and write
* @param buf the starting address of the data to write into file
* @param sz how many bytes to write at most
* @return the byte we've written, or Linux specific error code
*/
static int storeToFile(const char *path, u8 *buf, u32 sz)
{
int ret = 0;
mm_segment_t oldfs;
struct file *fp;
if (path && buf) {
ret = openFile(&fp, path, O_CREAT | O_WRONLY, 0666);
if (0 == ret) {
RTW_INFO("%s openFile path:%s fp=%p\n", __func__, path , fp);
oldfs = get_fs();
set_fs(get_ds());
ret = writeFile(fp, buf, sz);
set_fs(oldfs);
closeFile(fp);
RTW_INFO("%s writeFile, ret:%d\n", __func__, ret);
} else
RTW_INFO("%s openFile path:%s Fail, ret:%d\n", __func__, path, ret);
} else {
RTW_INFO("%s NULL pointer\n", __func__);
ret = -EINVAL;
}
return ret;
}
/*
* Test if the specifi @param path is a file and readable
* @param path the path of the file to test
* @return true or false
*/
int rtw_is_file_readable(const char *path)
{
if (isFileReadable(path, NULL) == 0)
return true;
else
return false;
}
/*
* Test if the specifi @param path is a file and readable.
* If readable, @param sz is got
* @param path the path of the file to test
* @return true or false
*/
int rtw_is_file_readable_with_size(const char *path, u32 *sz)
{
if (isFileReadable(path, sz) == 0)
return true;
else
return false;
}
/*
* Open the file with @param path and retrive the file content into memory starting from @param buf for @param sz at most
* @param path the path of the file to open and read
* @param buf the starting address of the buffer to store file content
* @param sz how many bytes to read at most
* @return the byte we've read
*/
int rtw_retrieve_from_file(const char *path, u8 *buf, u32 sz)
{
int ret = retriveFromFile(path, buf, sz);
return ret >= 0 ? ret : 0;
}
/*
* Open the file with @param path and wirte @param sz byte of data starting from @param buf into the file
* @param path the path of the file to open and write
* @param buf the starting address of the data to write into file
* @param sz how many bytes to write at most
* @return the byte we've written
*/
int rtw_store_to_file(const char *path, u8 *buf, u32 sz)
{
int ret = storeToFile(path, buf, sz);
return ret >= 0 ? ret : 0;
}
struct net_device *rtw_alloc_etherdev_with_old_priv(int sizeof_priv, void *old_priv)
{
struct net_device *pnetdev;
struct rtw_netdev_priv_indicator *pnpi;
#if (LINUX_VERSION_CODE >= KERNEL_VERSION(2, 6, 35))
pnetdev = alloc_etherdev_mq(sizeof(struct rtw_netdev_priv_indicator), 4);
#else
pnetdev = alloc_etherdev(sizeof(struct rtw_netdev_priv_indicator));
#endif
if (!pnetdev)
goto RETURN;
pnpi = netdev_priv(pnetdev);
pnpi->priv = old_priv;
pnpi->sizeof_priv = sizeof_priv;
RETURN:
return pnetdev;
}
struct net_device *rtw_alloc_etherdev(int sizeof_priv)
{
struct net_device *pnetdev;
struct rtw_netdev_priv_indicator *pnpi;
#if (LINUX_VERSION_CODE >= KERNEL_VERSION(2, 6, 35))
pnetdev = alloc_etherdev_mq(sizeof(struct rtw_netdev_priv_indicator), 4);
#else
pnetdev = alloc_etherdev(sizeof(struct rtw_netdev_priv_indicator));
#endif
if (!pnetdev)
goto RETURN;
pnpi = netdev_priv(pnetdev);
pnpi->priv = rtw_zvmalloc(sizeof_priv);
if (!pnpi->priv) {
free_netdev(pnetdev);
pnetdev = NULL;
goto RETURN;
}
pnpi->sizeof_priv = sizeof_priv;
RETURN:
return pnetdev;
}
void rtw_free_netdev(struct net_device *netdev)
{
struct rtw_netdev_priv_indicator *pnpi;
if (!netdev)
goto RETURN;
pnpi = netdev_priv(netdev);
if (!pnpi->priv)
goto RETURN;
free_netdev(netdev);
RETURN:
return;
}
int rtw_change_ifname(_adapter *padapter, const char *ifname)
{
struct dvobj_priv *dvobj;
struct net_device *pnetdev;
struct net_device *cur_pnetdev;
struct rereg_nd_name_data *rereg_priv;
int ret;
u8 rtnl_lock_needed;
if (!padapter)
goto error;
dvobj = adapter_to_dvobj(padapter);
cur_pnetdev = padapter->pnetdev;
rereg_priv = &padapter->rereg_nd_name_priv;
/* free the old_pnetdev */
if (rereg_priv->old_pnetdev) {
free_netdev(rereg_priv->old_pnetdev);
rereg_priv->old_pnetdev = NULL;
}
rtnl_lock_needed = rtw_rtnl_lock_needed(dvobj);
if (rtnl_lock_needed)
unregister_netdev(cur_pnetdev);
else
unregister_netdevice(cur_pnetdev);
rereg_priv->old_pnetdev = cur_pnetdev;
pnetdev = rtw_init_netdev(padapter);
if (!pnetdev) {
ret = -1;
goto error;
}
SET_NETDEV_DEV(pnetdev, dvobj_to_dev(adapter_to_dvobj(padapter)));
rtw_init_netdev_name(pnetdev, ifname);
memcpy(pnetdev->dev_addr, adapter_mac_addr(padapter), ETH_ALEN);
if (rtnl_lock_needed)
ret = register_netdev(pnetdev);
else
ret = register_netdevice(pnetdev);
if (ret != 0) {
goto error;
}
return 0;
error:
return -1;
}
#ifdef CONFIG_PLATFORM_SPRD
#ifdef do_div
#undef do_div
#endif
#include <asm-generic/div64.h>
#endif
u64 rtw_modular64(u64 x, u64 y)
{
return do_div(x, y);
}
u64 rtw_division64(u64 x, u64 y)
{
do_div(x, y);
return x;
}
inline u32 rtw_random32(void)
{
#if (LINUX_VERSION_CODE >= KERNEL_VERSION(3, 8, 0))
return prandom_u32();
#elif (LINUX_VERSION_CODE <= KERNEL_VERSION(2, 6, 18))
u32 random_int;
get_random_bytes(&random_int , 4);
return random_int;
#else
return random32();
#endif
}
void rtw_buf_free(u8 **buf, u32 *buf_len)
{
u32 ori_len;
if (!buf || !buf_len)
return;
ori_len = *buf_len;
if (*buf) {
u32 tmp_buf_len = *buf_len;
*buf_len = 0;
rtw_mfree(*buf, tmp_buf_len);
*buf = NULL;
}
}
void rtw_buf_update(u8 **buf, u32 *buf_len, u8 *src, u32 src_len)
{
u32 ori_len = 0, dup_len = 0;
u8 *ori = NULL;
u8 *dup = NULL;
if (!buf || !buf_len)
return;
if (!src || !src_len)
goto keep_ori;
/* duplicate src */
dup = rtw_malloc(src_len);
if (dup) {
dup_len = src_len;
memcpy(dup, src, dup_len);
}
keep_ori:
ori = *buf;
ori_len = *buf_len;
/* replace buf with dup */
*buf_len = 0;
*buf = dup;
*buf_len = dup_len;
/* free ori */
if (ori && ori_len > 0)
rtw_mfree(ori, ori_len);
}
/**
* rtw_cbuf_full - test if cbuf is full
* @cbuf: pointer of struct rtw_cbuf
*
* Returns: true if cbuf is full
*/
inline bool rtw_cbuf_full(struct rtw_cbuf *cbuf)
{
return (cbuf->write == cbuf->read - 1) ? true : false;
}
/**
* rtw_cbuf_empty - test if cbuf is empty
* @cbuf: pointer of struct rtw_cbuf
*
* Returns: true if cbuf is empty
*/
inline bool rtw_cbuf_empty(struct rtw_cbuf *cbuf)
{
return (cbuf->write == cbuf->read) ? true : false;
}
/**
* rtw_cbuf_push - push a pointer into cbuf
* @cbuf: pointer of struct rtw_cbuf
* @buf: pointer to push in
*
* Lock free operation, be careful of the use scheme
* Returns: true push success
*/
bool rtw_cbuf_push(struct rtw_cbuf *cbuf, void *buf)
{
if (rtw_cbuf_full(cbuf))
return _FAIL;
if (0)
RTW_INFO("%s on %u\n", __func__, cbuf->write);
cbuf->bufs[cbuf->write] = buf;
cbuf->write = (cbuf->write + 1) % cbuf->size;
return _SUCCESS;
}
/**
* rtw_cbuf_pop - pop a pointer from cbuf
* @cbuf: pointer of struct rtw_cbuf
*
* Lock free operation, be careful of the use scheme
* Returns: pointer popped out
*/
void *rtw_cbuf_pop(struct rtw_cbuf *cbuf)
{
void *buf;
if (rtw_cbuf_empty(cbuf))
return NULL;
if (0)
RTW_INFO("%s on %u\n", __func__, cbuf->read);
buf = cbuf->bufs[cbuf->read];
cbuf->read = (cbuf->read + 1) % cbuf->size;
return buf;
}
/**
* rtw_cbuf_alloc - allocte a rtw_cbuf with given size and do initialization
* @size: size of pointer
*
* Returns: pointer of srtuct rtw_cbuf, NULL for allocation failure
*/
struct rtw_cbuf *rtw_cbuf_alloc(u32 size)
{
struct rtw_cbuf *cbuf;
cbuf = (struct rtw_cbuf *)rtw_malloc(sizeof(*cbuf) + sizeof(void *) * size);
if (cbuf) {
cbuf->write = cbuf->read = 0;
cbuf->size = size;
}
return cbuf;
}
/**
* rtw_cbuf_free - free the given rtw_cbuf
* @cbuf: pointer of struct rtw_cbuf to free
*/
void rtw_cbuf_free(struct rtw_cbuf *cbuf)
{
rtw_mfree((u8 *)cbuf, sizeof(*cbuf) + sizeof(void *) * cbuf->size);
}
/**
* map_readN - read a range of map data
* @map: map to read
* @offset: start address to read
* @len: length to read
* @buf: pointer of buffer to store data read
*
* Returns: _SUCCESS or _FAIL
*/
int map_readN(const struct map_t *map, u16 offset, u16 len, u8 *buf)
{
const struct map_seg_t *seg;
int ret = _FAIL;
int i;
if (len == 0) {
rtw_warn_on(1);
goto exit;
}
if (offset + len > map->len) {
rtw_warn_on(1);
goto exit;
}
memset(buf, map->init_value, len);
for (i = 0; i < map->seg_num; i++) {
u8 *c_dst, *c_src;
u16 c_len;
seg = map->segs + i;
if (seg->sa + seg->len <= offset || seg->sa >= offset + len)
continue;
if (seg->sa >= offset) {
c_dst = buf + (seg->sa - offset);
c_src = seg->c;
if (seg->sa + seg->len <= offset + len)
c_len = seg->len;
else
c_len = offset + len - seg->sa;
} else {
c_dst = buf;
c_src = seg->c + (offset - seg->sa);
if (seg->sa + seg->len >= offset + len)
c_len = len;
else
c_len = seg->sa + seg->len - offset;
}
memcpy(c_dst, c_src, c_len);
}
exit:
return ret;
}
/**
* map_read8 - read 1 byte of map data
* @map: map to read
* @offset: address to read
*
* Returns: value of data of specified offset. map.init_value if offset is out of range
*/
u8 map_read8(const struct map_t *map, u16 offset)
{
const struct map_seg_t *seg;
u8 val = map->init_value;
int i;
if (offset + 1 > map->len) {
rtw_warn_on(1);
goto exit;
}
for (i = 0; i < map->seg_num; i++) {
seg = map->segs + i;
if (seg->sa + seg->len <= offset || seg->sa >= offset + 1)
continue;
val = *(seg->c + offset - seg->sa);
break;
}
exit:
return val;
}
/**
* is_null -
*
* Return true if c is null character
* false otherwise.
*/
inline bool is_null(char c)
{
if (c == '\0')
return true;
else
return false;
}
/**
* is_eol -
*
* Return true if c is represent for EOL (end of line)
* false otherwise.
*/
inline bool is_eol(char c)
{
if (c == '\r' || c == '\n')
return true;
else
return false;
}
/**
* is_space -
*
* Return true if c is represent for space
* false otherwise.
*/
inline bool is_space(char c)
{
if (c == ' ' || c == '\t')
return true;
else
return false;
}
/**
* IsHexDigit -
*
* Return true if chTmp is represent for hex digit
* false otherwise.
*/
inline bool IsHexDigit(char chTmp)
{
if ((chTmp >= '0' && chTmp <= '9') ||
(chTmp >= 'a' && chTmp <= 'f') ||
(chTmp >= 'A' && chTmp <= 'F'))
return true;
else
return false;
}
/**
* is_alpha -
*
* Return true if chTmp is represent for alphabet
* false otherwise.
*/
inline bool is_alpha(char chTmp)
{
if ((chTmp >= 'a' && chTmp <= 'z') ||
(chTmp >= 'A' && chTmp <= 'Z'))
return true;
else
return false;
}
inline char alpha_to_upper(char c)
{
if ((c >= 'a' && c <= 'z'))
c = 'A' + (c - 'a');
return c;
}