Commit 6bccc65a authored by Roland Vossen's avatar Roland Vossen Committed by Greg Kroah-Hartman

staging: brcm80211: removed static function declarations in dma.c

Reported-by: default avatarJohannes Berg <johannes@sipsolutions.net>
Signed-off-by: default avatarRoland Vossen <rvossen@broadcom.com>
Signed-off-by: default avatarGreg Kroah-Hartman <gregkh@suse.de>
parent 0390bf7a
......@@ -197,16 +197,34 @@
#define txd64 dregs.d64_u.txd_64
#define rxd64 dregs.d64_u.rxd_64
/*
* default dma message level (if input msg_level
* pointer is null in dma_attach())
*/
static uint dma_msg_level;
#define MAXNAMEL 8 /* 8 char names */
#define DI_INFO(dmah) ((dma_info_t *)dmah)
/* descriptor bumping macros */
/* faster than %, but n must be power of 2 */
#define XXD(x, n) ((x) & ((n) - 1))
#define TXD(x) XXD((x), di->ntxd)
#define RXD(x) XXD((x), di->nrxd)
#define NEXTTXD(i) TXD((i) + 1)
#define PREVTXD(i) TXD((i) - 1)
#define NEXTRXD(i) RXD((i) + 1)
#define PREVRXD(i) RXD((i) - 1)
#define NTXDACTIVE(h, t) TXD((t) - (h))
#define NRXDACTIVE(h, t) RXD((t) - (h))
/* macros to convert between byte offsets and indexes */
#define B2I(bytes, type) ((bytes) / sizeof(type))
#define I2B(index, type) ((index) * sizeof(type))
#define PCI32ADDR_HIGH 0xc0000000 /* address[31:30] */
#define PCI32ADDR_HIGH_SHIFT 30 /* address[31:30] */
#define PCI64ADDR_HIGH 0x80000000 /* address[63] */
#define PCI64ADDR_HIGH_SHIFT 31 /* address[63] */
/*
* DMA Descriptor
* Descriptors are only read by the hardware, never written back.
......@@ -298,51 +316,202 @@ struct dma_info {
bool aligndesc_4k;
};
/* descriptor bumping macros */
/* faster than %, but n must be power of 2 */
#define XXD(x, n) ((x) & ((n) - 1))
/*
* default dma message level (if input msg_level
* pointer is null in dma_attach())
*/
static uint dma_msg_level;
#define TXD(x) XXD((x), di->ntxd)
#define RXD(x) XXD((x), di->nrxd)
#define NEXTTXD(i) TXD((i) + 1)
#define PREVTXD(i) TXD((i) - 1)
#define NEXTRXD(i) RXD((i) + 1)
#define PREVRXD(i) RXD((i) - 1)
static uint _dma_ctrlflags(struct dma_info *di, uint mask, uint flags)
{
uint dmactrlflags = di->dma.dmactrlflags;
#define NTXDACTIVE(h, t) TXD((t) - (h))
#define NRXDACTIVE(h, t) RXD((t) - (h))
if (di == NULL) {
DMA_ERROR(("%s: _dma_ctrlflags: NULL dma handle\n", di->name));
return 0;
}
/* macros to convert between byte offsets and indexes */
#define B2I(bytes, type) ((bytes) / sizeof(type))
#define I2B(index, type) ((index) * sizeof(type))
dmactrlflags &= ~mask;
dmactrlflags |= flags;
#define PCI32ADDR_HIGH 0xc0000000 /* address[31:30] */
#define PCI32ADDR_HIGH_SHIFT 30 /* address[31:30] */
/* If trying to enable parity, check if parity is actually supported */
if (dmactrlflags & DMA_CTRL_PEN) {
u32 control;
#define PCI64ADDR_HIGH 0x80000000 /* address[63] */
#define PCI64ADDR_HIGH_SHIFT 31 /* address[63] */
control = R_REG(&di->d64txregs->control);
W_REG(&di->d64txregs->control,
control | D64_XC_PD);
if (R_REG(&di->d64txregs->control) & D64_XC_PD)
/* We *can* disable it so it is supported,
* restore control register
*/
W_REG(&di->d64txregs->control,
control);
else
/* Not supported, don't allow it to be enabled */
dmactrlflags &= ~DMA_CTRL_PEN;
}
di->dma.dmactrlflags = dmactrlflags;
return dmactrlflags;
}
static bool _dma64_addrext(struct dma64regs *dma64regs)
{
u32 w;
OR_REG(&dma64regs->control, D64_XC_AE);
w = R_REG(&dma64regs->control);
AND_REG(&dma64regs->control, ~D64_XC_AE);
return (w & D64_XC_AE) == D64_XC_AE;
}
/*
* return true if this dma engine supports DmaExtendedAddrChanges,
* otherwise false
*/
static bool _dma_isaddrext(struct dma_info *di)
{
/* DMA64 supports full 32- or 64-bit operation. AE is always valid */
/* not all tx or rx channel are available */
if (di->d64txregs != NULL) {
if (!_dma64_addrext(di->d64txregs))
DMA_ERROR(("%s: _dma_isaddrext: DMA64 tx doesn't have "
"AE set\n", di->name));
return true;
} else if (di->d64rxregs != NULL) {
if (!_dma64_addrext(di->d64rxregs))
DMA_ERROR(("%s: _dma_isaddrext: DMA64 rx doesn't have "
"AE set\n", di->name));
return true;
}
return false;
}
/* Common prototypes */
static bool _dma_isaddrext(struct dma_info *di);
static bool _dma_descriptor_align(struct dma_info *di);
static bool _dma_alloc(struct dma_info *di, uint direction);
static void _dma_ddtable_init(struct dma_info *di, uint direction,
dma_addr_t pa);
static void _dma_rxenable(struct dma_info *di);
static struct sk_buff *_dma_getnextrxp(struct dma_info *di, bool forceall);
static uint _dma_ctrlflags(struct dma_info *di, uint mask, uint flags);
static u8 dma_align_sizetobits(uint size);
static bool _dma_descriptor_align(struct dma_info *di)
{
u32 addrl;
/* Check to see if the descriptors need to be aligned on 4K/8K or not */
if (di->d64txregs != NULL) {
W_REG(&di->d64txregs->addrlow, 0xff0);
addrl = R_REG(&di->d64txregs->addrlow);
if (addrl != 0)
return false;
} else if (di->d64rxregs != NULL) {
W_REG(&di->d64rxregs->addrlow, 0xff0);
addrl = R_REG(&di->d64rxregs->addrlow);
if (addrl != 0)
return false;
}
return true;
}
void *dma_alloc_consistent(struct pci_dev *pdev, uint size, u16 align_bits,
uint *alloced, dma_addr_t *pap)
{
if (align_bits) {
u16 align = (1 << align_bits);
if (!IS_ALIGNED(PAGE_SIZE, align))
size += align;
*alloced = size;
}
return pci_alloc_consistent(pdev, size, pap);
}
static
u8 dma_align_sizetobits(uint size)
{
u8 bitpos = 0;
while (size >>= 1)
bitpos++;
return bitpos;
}
/* This function ensures that the DMA descriptor ring will not get allocated
* across Page boundary. If the allocation is done across the page boundary
* at the first time, then it is freed and the allocation is done at
* descriptor ring size aligned location. This will ensure that the ring will
* not cross page boundary
*/
static void *dma_ringalloc(struct dma_info *di, u32 boundary, uint size,
u16 *alignbits, uint *alloced,
dma_addr_t *descpa);
dma_addr_t *descpa)
{
void *va;
u32 desc_strtaddr;
u32 alignbytes = 1 << *alignbits;
/* Prototypes for 64-bit routines */
static bool dma64_alloc(struct dma_info *di, uint direction);
static struct sk_buff *dma64_getnextrxp(struct dma_info *di, bool forceall);
static bool dma64_rxidle(struct dma_info *di);
static bool _dma64_addrext(struct dma64regs *dma64regs);
va = dma_alloc_consistent(di->pbus, size, *alignbits, alloced, descpa);
static inline u32 parity32(u32 data);
if (NULL == va)
return NULL;
desc_strtaddr = (u32) roundup((unsigned long)va, alignbytes);
if (((desc_strtaddr + size - 1) & boundary) != (desc_strtaddr
& boundary)) {
*alignbits = dma_align_sizetobits(size);
pci_free_consistent(di->pbus, size, va, *descpa);
va = dma_alloc_consistent(di->pbus, size, *alignbits,
alloced, descpa);
}
return va;
}
static bool dma64_alloc(struct dma_info *di, uint direction)
{
u16 size;
uint ddlen;
void *va;
uint alloced = 0;
u16 align;
u16 align_bits;
ddlen = sizeof(struct dma64desc);
size = (direction == DMA_TX) ? (di->ntxd * ddlen) : (di->nrxd * ddlen);
align_bits = di->dmadesc_align;
align = (1 << align_bits);
if (direction == DMA_TX) {
va = dma_ringalloc(di, D64RINGALIGN, size, &align_bits,
&alloced, &di->txdpaorig);
if (va == NULL) {
DMA_ERROR(("%s: dma64_alloc: DMA_ALLOC_CONSISTENT(ntxd)"
" failed\n", di->name));
return false;
}
align = (1 << align_bits);
di->txd64 = (struct dma64desc *)
roundup((unsigned long)va, align);
di->txdalign = (uint) ((s8 *)di->txd64 - (s8 *) va);
di->txdpa = di->txdpaorig + di->txdalign;
di->txdalloc = alloced;
} else {
va = dma_ringalloc(di, D64RINGALIGN, size, &align_bits,
&alloced, &di->rxdpaorig);
if (va == NULL) {
DMA_ERROR(("%s: dma64_alloc: DMA_ALLOC_CONSISTENT(nrxd)"
" failed\n", di->name));
return false;
}
align = (1 << align_bits);
di->rxd64 = (struct dma64desc *)
roundup((unsigned long)va, align);
di->rxdalign = (uint) ((s8 *)di->rxd64 - (s8 *) va);
di->rxdpa = di->rxdpaorig + di->rxdalign;
di->rxdalloc = alloced;
}
return true;
}
static bool _dma_alloc(struct dma_info *di, uint direction)
{
return dma64_alloc(di, direction);
}
struct dma_pub *dma_attach(char *name, struct si_pub *sih,
void *dmaregstx, void *dmaregsrx, uint ntxd,
......@@ -551,23 +720,6 @@ dma64_dd_upd(struct dma_info *di, struct dma64desc *ddring,
}
}
static bool _dma_alloc(struct dma_info *di, uint direction)
{
return dma64_alloc(di, direction);
}
void *dma_alloc_consistent(struct pci_dev *pdev, uint size, u16 align_bits,
uint *alloced, dma_addr_t *pap)
{
if (align_bits) {
u16 align = (1 << align_bits);
if (!IS_ALIGNED(PAGE_SIZE, align))
size += align;
*alloced = size;
}
return pci_alloc_consistent(pdev, size, pap);
}
/* !! may be called with core in reset */
void dma_detach(struct dma_pub *pub)
{
......@@ -594,49 +746,6 @@ void dma_detach(struct dma_pub *pub)
}
static bool _dma_descriptor_align(struct dma_info *di)
{
u32 addrl;
/* Check to see if the descriptors need to be aligned on 4K/8K or not */
if (di->d64txregs != NULL) {
W_REG(&di->d64txregs->addrlow, 0xff0);
addrl = R_REG(&di->d64txregs->addrlow);
if (addrl != 0)
return false;
} else if (di->d64rxregs != NULL) {
W_REG(&di->d64rxregs->addrlow, 0xff0);
addrl = R_REG(&di->d64rxregs->addrlow);
if (addrl != 0)
return false;
}
return true;
}
/*
* return true if this dma engine supports DmaExtendedAddrChanges,
* otherwise false
*/
static bool _dma_isaddrext(struct dma_info *di)
{
/* DMA64 supports full 32- or 64-bit operation. AE is always valid */
/* not all tx or rx channel are available */
if (di->d64txregs != NULL) {
if (!_dma64_addrext(di->d64txregs))
DMA_ERROR(("%s: _dma_isaddrext: DMA64 tx doesn't have "
"AE set\n", di->name));
return true;
} else if (di->d64rxregs != NULL) {
if (!_dma64_addrext(di->d64rxregs))
DMA_ERROR(("%s: _dma_isaddrext: DMA64 rx doesn't have "
"AE set\n", di->name));
return true;
}
return false;
}
/* initialize descriptor table base address */
static void
_dma_ddtable_init(struct dma_info *di, uint direction, dma_addr_t pa)
......@@ -679,6 +788,27 @@ _dma_ddtable_init(struct dma_info *di, uint direction, dma_addr_t pa)
}
}
static void _dma_rxenable(struct dma_info *di)
{
uint dmactrlflags = di->dma.dmactrlflags;
u32 control;
DMA_TRACE(("%s: dma_rxenable\n", di->name));
control =
(R_REG(&di->d64rxregs->control) & D64_RC_AE) |
D64_RC_RE;
if ((dmactrlflags & DMA_CTRL_PEN) == 0)
control |= D64_RC_PD;
if (dmactrlflags & DMA_CTRL_ROC)
control |= D64_RC_OC;
W_REG(&di->d64rxregs->control,
((di->rxoffset << D64_RC_RO_SHIFT) | control));
}
void dma_rxinit(struct dma_pub *pub)
{
struct dma_info *di = (struct dma_info *)pub;
......@@ -705,25 +835,49 @@ void dma_rxinit(struct dma_pub *pub)
_dma_ddtable_init(di, DMA_RX, di->rxdpa);
}
static void _dma_rxenable(struct dma_info *di)
static struct sk_buff *dma64_getnextrxp(struct dma_info *di, bool forceall)
{
uint dmactrlflags = di->dma.dmactrlflags;
u32 control;
uint i, curr;
struct sk_buff *rxp;
dma_addr_t pa;
DMA_TRACE(("%s: dma_rxenable\n", di->name));
i = di->rxin;
control =
(R_REG(&di->d64rxregs->control) & D64_RC_AE) |
D64_RC_RE;
/* return if no packets posted */
if (i == di->rxout)
return NULL;
if ((dmactrlflags & DMA_CTRL_PEN) == 0)
control |= D64_RC_PD;
curr =
B2I(((R_REG(&di->d64rxregs->status0) & D64_RS0_CD_MASK) -
di->rcvptrbase) & D64_RS0_CD_MASK, struct dma64desc);
if (dmactrlflags & DMA_CTRL_ROC)
control |= D64_RC_OC;
/* ignore curr if forceall */
if (!forceall && (i == curr))
return NULL;
W_REG(&di->d64rxregs->control,
((di->rxoffset << D64_RC_RO_SHIFT) | control));
/* get the packet pointer that corresponds to the rx descriptor */
rxp = di->rxp[i];
di->rxp[i] = NULL;
pa = cpu_to_le32(di->rxd64[i].addrlow) - di->dataoffsetlow;
/* clear this packet from the descriptor ring */
pci_unmap_single(di->pbus, pa, di->rxbufsize, PCI_DMA_FROMDEVICE);
di->rxd64[i].addrlow = 0xdeadbeef;
di->rxd64[i].addrhigh = 0xdeadbeef;
di->rxin = NEXTRXD(i);
return rxp;
}
static struct sk_buff *_dma_getnextrxp(struct dma_info *di, bool forceall)
{
if (di->nrxd == 0)
return NULL;
return dma64_getnextrxp(di, forceall);
}
/*
......@@ -795,6 +949,17 @@ struct sk_buff *dma_rx(struct dma_pub *pub)
return head;
}
static bool dma64_rxidle(struct dma_info *di)
{
DMA_TRACE(("%s: dma_rxidle\n", di->name));
if (di->nrxd == 0)
return true;
return ((R_REG(&di->d64rxregs->status0) & D64_RS0_CD_MASK) ==
(R_REG(&di->d64rxregs->ptr) & D64_RS0_CD_MASK));
}
/*
* post receive buffers
* return false is refill failed completely and ring is empty this will stall
......@@ -894,14 +1059,6 @@ void dma_rxreclaim(struct dma_pub *pub)
brcmu_pkt_buf_free_skb(p);
}
static struct sk_buff *_dma_getnextrxp(struct dma_info *di, bool forceall)
{
if (di->nrxd == 0)
return NULL;
return dma64_getnextrxp(di, forceall);
}
void dma_counterreset(struct dma_pub *pub)
{
/* reset all software counters */
......@@ -910,41 +1067,6 @@ void dma_counterreset(struct dma_pub *pub)
pub->txnobuf = 0;
}
static uint _dma_ctrlflags(struct dma_info *di, uint mask, uint flags)
{
uint dmactrlflags = di->dma.dmactrlflags;
if (di == NULL) {
DMA_ERROR(("%s: _dma_ctrlflags: NULL dma handle\n", di->name));
return 0;
}
dmactrlflags &= ~mask;
dmactrlflags |= flags;
/* If trying to enable parity, check if parity is actually supported */
if (dmactrlflags & DMA_CTRL_PEN) {
u32 control;
control = R_REG(&di->d64txregs->control);
W_REG(&di->d64txregs->control,
control | D64_XC_PD);
if (R_REG(&di->d64txregs->control) & D64_XC_PD)
/* We *can* disable it so it is supported,
* restore control register
*/
W_REG(&di->d64txregs->control,
control);
else
/* Not supported, don't allow it to be enabled */
dmactrlflags &= ~DMA_CTRL_PEN;
}
di->dma.dmactrlflags = dmactrlflags;
return dmactrlflags;
}
/* get the address of the var in order to change later */
unsigned long dma_getvar(struct dma_pub *pub, const char *name)
{
......@@ -955,45 +1077,6 @@ unsigned long dma_getvar(struct dma_pub *pub, const char *name)
return 0;
}
static
u8 dma_align_sizetobits(uint size)
{
u8 bitpos = 0;
while (size >>= 1)
bitpos++;
return bitpos;
}
/* This function ensures that the DMA descriptor ring will not get allocated
* across Page boundary. If the allocation is done across the page boundary
* at the first time, then it is freed and the allocation is done at
* descriptor ring size aligned location. This will ensure that the ring will
* not cross page boundary
*/
static void *dma_ringalloc(struct dma_info *di, u32 boundary, uint size,
u16 *alignbits, uint *alloced,
dma_addr_t *descpa)
{
void *va;
u32 desc_strtaddr;
u32 alignbytes = 1 << *alignbits;
va = dma_alloc_consistent(di->pbus, size, *alignbits, alloced, descpa);
if (NULL == va)
return NULL;
desc_strtaddr = (u32) roundup((unsigned long)va, alignbytes);
if (((desc_strtaddr + size - 1) & boundary) != (desc_strtaddr
& boundary)) {
*alignbits = dma_align_sizetobits(size);
pci_free_consistent(di->pbus, size, va, *descpa);
va = dma_alloc_consistent(di->pbus, size, *alignbits,
alloced, descpa);
}
return va;
}
/* 64-bit DMA functions */
void dma_txinit(struct dma_pub *pub)
......@@ -1083,54 +1166,6 @@ void dma_txreclaim(struct dma_pub *pub, enum txd_range range)
}
}
static bool dma64_alloc(struct dma_info *di, uint direction)
{
u16 size;
uint ddlen;
void *va;
uint alloced = 0;
u16 align;
u16 align_bits;
ddlen = sizeof(struct dma64desc);
size = (direction == DMA_TX) ? (di->ntxd * ddlen) : (di->nrxd * ddlen);
align_bits = di->dmadesc_align;
align = (1 << align_bits);
if (direction == DMA_TX) {
va = dma_ringalloc(di, D64RINGALIGN, size, &align_bits,
&alloced, &di->txdpaorig);
if (va == NULL) {
DMA_ERROR(("%s: dma64_alloc: DMA_ALLOC_CONSISTENT(ntxd)"
" failed\n", di->name));
return false;
}
align = (1 << align_bits);
di->txd64 = (struct dma64desc *)
roundup((unsigned long)va, align);
di->txdalign = (uint) ((s8 *)di->txd64 - (s8 *) va);
di->txdpa = di->txdpaorig + di->txdalign;
di->txdalloc = alloced;
} else {
va = dma_ringalloc(di, D64RINGALIGN, size, &align_bits,
&alloced, &di->rxdpaorig);
if (va == NULL) {
DMA_ERROR(("%s: dma64_alloc: DMA_ALLOC_CONSISTENT(nrxd)"
" failed\n", di->name));
return false;
}
align = (1 << align_bits);
di->rxd64 = (struct dma64desc *)
roundup((unsigned long)va, align);
di->rxdalign = (uint) ((s8 *)di->rxd64 - (s8 *) va);
di->rxdpa = di->rxdpaorig + di->rxdalign;
di->rxdalloc = alloced;
}
return true;
}
bool dma_txreset(struct dma_pub *pub)
{
struct dma_info *di = (struct dma_info *)pub;
......@@ -1157,17 +1192,6 @@ bool dma_txreset(struct dma_pub *pub)
return status == D64_XS0_XS_DISABLED;
}
static bool dma64_rxidle(struct dma_info *di)
{
DMA_TRACE(("%s: dma_rxidle\n", di->name));
if (di->nrxd == 0)
return true;
return ((R_REG(&di->d64rxregs->status0) & D64_RS0_CD_MASK) ==
(R_REG(&di->d64rxregs->ptr) & D64_RS0_CD_MASK));
}
bool dma_rxreset(struct dma_pub *pub)
{
struct dma_info *di = (struct dma_info *)pub;
......@@ -1357,52 +1381,6 @@ struct sk_buff *dma_getnexttxp(struct dma_pub *pub, enum txd_range range)
return NULL;
}
static struct sk_buff *dma64_getnextrxp(struct dma_info *di, bool forceall)
{
uint i, curr;
struct sk_buff *rxp;
dma_addr_t pa;
i = di->rxin;
/* return if no packets posted */
if (i == di->rxout)
return NULL;
curr =
B2I(((R_REG(&di->d64rxregs->status0) & D64_RS0_CD_MASK) -
di->rcvptrbase) & D64_RS0_CD_MASK, struct dma64desc);
/* ignore curr if forceall */
if (!forceall && (i == curr))
return NULL;
/* get the packet pointer that corresponds to the rx descriptor */
rxp = di->rxp[i];
di->rxp[i] = NULL;
pa = cpu_to_le32(di->rxd64[i].addrlow) - di->dataoffsetlow;
/* clear this packet from the descriptor ring */
pci_unmap_single(di->pbus, pa, di->rxbufsize, PCI_DMA_FROMDEVICE);
di->rxd64[i].addrlow = 0xdeadbeef;
di->rxd64[i].addrhigh = 0xdeadbeef;
di->rxin = NEXTRXD(i);
return rxp;
}
static bool _dma64_addrext(struct dma64regs *dma64regs)
{
u32 w;
OR_REG(&dma64regs->control, D64_XC_AE);
w = R_REG(&dma64regs->control);
AND_REG(&dma64regs->control, ~D64_XC_AE);
return (w & D64_XC_AE) == D64_XC_AE;
}
/*
* Mac80211 initiated actions sometimes require packets in the DMA queue to be
* modified. The modified portion of the packet is not under control of the DMA
......
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