linux/drivers/usb/host/uhci-hcd.h
yuan linyu 2c93e790e8 usb: add CONFIG_USB_PCI for system have both PCI HW and non-PCI based USB HW
a lot of embeded system SOC (e.g. freescale T2080) have both
PCI and USB modules. But USB module is controlled by registers directly,
it have no relationship with PCI module.

when say N here it will not build PCI related code in USB driver.

Signed-off-by: yuan linyu <Linyu.Yuan@alcatel-sbell.com.cn>
Acked-by: Felipe Balbi <felipe.balbi@linux.intel.com>
Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2017-03-17 13:16:56 +09:00

661 lines
21 KiB
C

#ifndef __LINUX_UHCI_HCD_H
#define __LINUX_UHCI_HCD_H
#include <linux/list.h>
#include <linux/usb.h>
#define usb_packetid(pipe) (usb_pipein(pipe) ? USB_PID_IN : USB_PID_OUT)
#define PIPE_DEVEP_MASK 0x0007ff00
/*
* Universal Host Controller Interface data structures and defines
*/
/* Command register */
#define USBCMD 0
#define USBCMD_RS 0x0001 /* Run/Stop */
#define USBCMD_HCRESET 0x0002 /* Host reset */
#define USBCMD_GRESET 0x0004 /* Global reset */
#define USBCMD_EGSM 0x0008 /* Global Suspend Mode */
#define USBCMD_FGR 0x0010 /* Force Global Resume */
#define USBCMD_SWDBG 0x0020 /* SW Debug mode */
#define USBCMD_CF 0x0040 /* Config Flag (sw only) */
#define USBCMD_MAXP 0x0080 /* Max Packet (0 = 32, 1 = 64) */
/* Status register */
#define USBSTS 2
#define USBSTS_USBINT 0x0001 /* Interrupt due to IOC */
#define USBSTS_ERROR 0x0002 /* Interrupt due to error */
#define USBSTS_RD 0x0004 /* Resume Detect */
#define USBSTS_HSE 0x0008 /* Host System Error: PCI problems */
#define USBSTS_HCPE 0x0010 /* Host Controller Process Error:
* the schedule is buggy */
#define USBSTS_HCH 0x0020 /* HC Halted */
/* Interrupt enable register */
#define USBINTR 4
#define USBINTR_TIMEOUT 0x0001 /* Timeout/CRC error enable */
#define USBINTR_RESUME 0x0002 /* Resume interrupt enable */
#define USBINTR_IOC 0x0004 /* Interrupt On Complete enable */
#define USBINTR_SP 0x0008 /* Short packet interrupt enable */
#define USBFRNUM 6
#define USBFLBASEADD 8
#define USBSOF 12
#define USBSOF_DEFAULT 64 /* Frame length is exactly 1 ms */
/* USB port status and control registers */
#define USBPORTSC1 16
#define USBPORTSC2 18
#define USBPORTSC_CCS 0x0001 /* Current Connect Status
* ("device present") */
#define USBPORTSC_CSC 0x0002 /* Connect Status Change */
#define USBPORTSC_PE 0x0004 /* Port Enable */
#define USBPORTSC_PEC 0x0008 /* Port Enable Change */
#define USBPORTSC_DPLUS 0x0010 /* D+ high (line status) */
#define USBPORTSC_DMINUS 0x0020 /* D- high (line status) */
#define USBPORTSC_RD 0x0040 /* Resume Detect */
#define USBPORTSC_RES1 0x0080 /* reserved, always 1 */
#define USBPORTSC_LSDA 0x0100 /* Low Speed Device Attached */
#define USBPORTSC_PR 0x0200 /* Port Reset */
/* OC and OCC from Intel 430TX and later (not UHCI 1.1d spec) */
#define USBPORTSC_OC 0x0400 /* Over Current condition */
#define USBPORTSC_OCC 0x0800 /* Over Current Change R/WC */
#define USBPORTSC_SUSP 0x1000 /* Suspend */
#define USBPORTSC_RES2 0x2000 /* reserved, write zeroes */
#define USBPORTSC_RES3 0x4000 /* reserved, write zeroes */
#define USBPORTSC_RES4 0x8000 /* reserved, write zeroes */
/* PCI legacy support register */
#define USBLEGSUP 0xc0
#define USBLEGSUP_DEFAULT 0x2000 /* only PIRQ enable set */
#define USBLEGSUP_RWC 0x8f00 /* the R/WC bits */
#define USBLEGSUP_RO 0x5040 /* R/O and reserved bits */
/* PCI Intel-specific resume-enable register */
#define USBRES_INTEL 0xc4
#define USBPORT1EN 0x01
#define USBPORT2EN 0x02
#define UHCI_PTR_BITS(uhci) cpu_to_hc32((uhci), 0x000F)
#define UHCI_PTR_TERM(uhci) cpu_to_hc32((uhci), 0x0001)
#define UHCI_PTR_QH(uhci) cpu_to_hc32((uhci), 0x0002)
#define UHCI_PTR_DEPTH(uhci) cpu_to_hc32((uhci), 0x0004)
#define UHCI_PTR_BREADTH(uhci) cpu_to_hc32((uhci), 0x0000)
#define UHCI_NUMFRAMES 1024 /* in the frame list [array] */
#define UHCI_MAX_SOF_NUMBER 2047 /* in an SOF packet */
#define CAN_SCHEDULE_FRAMES 1000 /* how far in the future frames
* can be scheduled */
#define MAX_PHASE 32 /* Periodic scheduling length */
/* When no queues need Full-Speed Bandwidth Reclamation,
* delay this long before turning FSBR off */
#define FSBR_OFF_DELAY msecs_to_jiffies(10)
/* If a queue hasn't advanced after this much time, assume it is stuck */
#define QH_WAIT_TIMEOUT msecs_to_jiffies(200)
/*
* __hc32 and __hc16 are "Host Controller" types, they may be equivalent to
* __leXX (normally) or __beXX (given UHCI_BIG_ENDIAN_DESC), depending on
* the host controller implementation.
*
* To facilitate the strongest possible byte-order checking from "sparse"
* and so on, we use __leXX unless that's not practical.
*/
#ifdef CONFIG_USB_UHCI_BIG_ENDIAN_DESC
typedef __u32 __bitwise __hc32;
typedef __u16 __bitwise __hc16;
#else
#define __hc32 __le32
#define __hc16 __le16
#endif
/*
* Queue Headers
*/
/*
* One role of a QH is to hold a queue of TDs for some endpoint. One QH goes
* with each endpoint, and qh->element (updated by the HC) is either:
* - the next unprocessed TD in the endpoint's queue, or
* - UHCI_PTR_TERM (when there's no more traffic for this endpoint).
*
* The other role of a QH is to serve as a "skeleton" framelist entry, so we
* can easily splice a QH for some endpoint into the schedule at the right
* place. Then qh->element is UHCI_PTR_TERM.
*
* In the schedule, qh->link maintains a list of QHs seen by the HC:
* skel1 --> ep1-qh --> ep2-qh --> ... --> skel2 --> ...
*
* qh->node is the software equivalent of qh->link. The differences
* are that the software list is doubly-linked and QHs in the UNLINKING
* state are on the software list but not the hardware schedule.
*
* For bookkeeping purposes we maintain QHs even for Isochronous endpoints,
* but they never get added to the hardware schedule.
*/
#define QH_STATE_IDLE 1 /* QH is not being used */
#define QH_STATE_UNLINKING 2 /* QH has been removed from the
* schedule but the hardware may
* still be using it */
#define QH_STATE_ACTIVE 3 /* QH is on the schedule */
struct uhci_qh {
/* Hardware fields */
__hc32 link; /* Next QH in the schedule */
__hc32 element; /* Queue element (TD) pointer */
/* Software fields */
dma_addr_t dma_handle;
struct list_head node; /* Node in the list of QHs */
struct usb_host_endpoint *hep; /* Endpoint information */
struct usb_device *udev;
struct list_head queue; /* Queue of urbps for this QH */
struct uhci_td *dummy_td; /* Dummy TD to end the queue */
struct uhci_td *post_td; /* Last TD completed */
struct usb_iso_packet_descriptor *iso_packet_desc;
/* Next urb->iso_frame_desc entry */
unsigned long advance_jiffies; /* Time of last queue advance */
unsigned int unlink_frame; /* When the QH was unlinked */
unsigned int period; /* For Interrupt and Isochronous QHs */
short phase; /* Between 0 and period-1 */
short load; /* Periodic time requirement, in us */
unsigned int iso_frame; /* Frame # for iso_packet_desc */
int state; /* QH_STATE_xxx; see above */
int type; /* Queue type (control, bulk, etc) */
int skel; /* Skeleton queue number */
unsigned int initial_toggle:1; /* Endpoint's current toggle value */
unsigned int needs_fixup:1; /* Must fix the TD toggle values */
unsigned int is_stopped:1; /* Queue was stopped by error/unlink */
unsigned int wait_expired:1; /* QH_WAIT_TIMEOUT has expired */
unsigned int bandwidth_reserved:1; /* Periodic bandwidth has
* been allocated */
} __attribute__((aligned(16)));
/*
* We need a special accessor for the element pointer because it is
* subject to asynchronous updates by the controller.
*/
#define qh_element(qh) ACCESS_ONCE((qh)->element)
#define LINK_TO_QH(uhci, qh) (UHCI_PTR_QH((uhci)) | \
cpu_to_hc32((uhci), (qh)->dma_handle))
/*
* Transfer Descriptors
*/
/*
* for TD <status>:
*/
#define TD_CTRL_SPD (1 << 29) /* Short Packet Detect */
#define TD_CTRL_C_ERR_MASK (3 << 27) /* Error Counter bits */
#define TD_CTRL_C_ERR_SHIFT 27
#define TD_CTRL_LS (1 << 26) /* Low Speed Device */
#define TD_CTRL_IOS (1 << 25) /* Isochronous Select */
#define TD_CTRL_IOC (1 << 24) /* Interrupt on Complete */
#define TD_CTRL_ACTIVE (1 << 23) /* TD Active */
#define TD_CTRL_STALLED (1 << 22) /* TD Stalled */
#define TD_CTRL_DBUFERR (1 << 21) /* Data Buffer Error */
#define TD_CTRL_BABBLE (1 << 20) /* Babble Detected */
#define TD_CTRL_NAK (1 << 19) /* NAK Received */
#define TD_CTRL_CRCTIMEO (1 << 18) /* CRC/Time Out Error */
#define TD_CTRL_BITSTUFF (1 << 17) /* Bit Stuff Error */
#define TD_CTRL_ACTLEN_MASK 0x7FF /* actual length, encoded as n - 1 */
#define uhci_maxerr(err) ((err) << TD_CTRL_C_ERR_SHIFT)
#define uhci_status_bits(ctrl_sts) ((ctrl_sts) & 0xF60000)
#define uhci_actual_length(ctrl_sts) (((ctrl_sts) + 1) & \
TD_CTRL_ACTLEN_MASK) /* 1-based */
/*
* for TD <info>: (a.k.a. Token)
*/
#define td_token(uhci, td) hc32_to_cpu((uhci), (td)->token)
#define TD_TOKEN_DEVADDR_SHIFT 8
#define TD_TOKEN_TOGGLE_SHIFT 19
#define TD_TOKEN_TOGGLE (1 << 19)
#define TD_TOKEN_EXPLEN_SHIFT 21
#define TD_TOKEN_EXPLEN_MASK 0x7FF /* expected length, encoded as n-1 */
#define TD_TOKEN_PID_MASK 0xFF
#define uhci_explen(len) ((((len) - 1) & TD_TOKEN_EXPLEN_MASK) << \
TD_TOKEN_EXPLEN_SHIFT)
#define uhci_expected_length(token) ((((token) >> TD_TOKEN_EXPLEN_SHIFT) + \
1) & TD_TOKEN_EXPLEN_MASK)
#define uhci_toggle(token) (((token) >> TD_TOKEN_TOGGLE_SHIFT) & 1)
#define uhci_endpoint(token) (((token) >> 15) & 0xf)
#define uhci_devaddr(token) (((token) >> TD_TOKEN_DEVADDR_SHIFT) & 0x7f)
#define uhci_devep(token) (((token) >> TD_TOKEN_DEVADDR_SHIFT) & 0x7ff)
#define uhci_packetid(token) ((token) & TD_TOKEN_PID_MASK)
#define uhci_packetout(token) (uhci_packetid(token) != USB_PID_IN)
#define uhci_packetin(token) (uhci_packetid(token) == USB_PID_IN)
/*
* The documentation says "4 words for hardware, 4 words for software".
*
* That's silly, the hardware doesn't care. The hardware only cares that
* the hardware words are 16-byte aligned, and we can have any amount of
* sw space after the TD entry.
*
* td->link points to either another TD (not necessarily for the same urb or
* even the same endpoint), or nothing (PTR_TERM), or a QH.
*/
struct uhci_td {
/* Hardware fields */
__hc32 link;
__hc32 status;
__hc32 token;
__hc32 buffer;
/* Software fields */
dma_addr_t dma_handle;
struct list_head list;
int frame; /* for iso: what frame? */
struct list_head fl_list;
} __attribute__((aligned(16)));
/*
* We need a special accessor for the control/status word because it is
* subject to asynchronous updates by the controller.
*/
#define td_status(uhci, td) hc32_to_cpu((uhci), \
ACCESS_ONCE((td)->status))
#define LINK_TO_TD(uhci, td) (cpu_to_hc32((uhci), (td)->dma_handle))
/*
* Skeleton Queue Headers
*/
/*
* The UHCI driver uses QHs with Interrupt, Control and Bulk URBs for
* automatic queuing. To make it easy to insert entries into the schedule,
* we have a skeleton of QHs for each predefined Interrupt latency.
* Asynchronous QHs (low-speed control, full-speed control, and bulk)
* go onto the period-1 interrupt list, since they all get accessed on
* every frame.
*
* When we want to add a new QH, we add it to the list starting from the
* appropriate skeleton QH. For instance, the schedule can look like this:
*
* skel int128 QH
* dev 1 interrupt QH
* dev 5 interrupt QH
* skel int64 QH
* skel int32 QH
* ...
* skel int1 + async QH
* dev 5 low-speed control QH
* dev 1 bulk QH
* dev 2 bulk QH
*
* There is a special terminating QH used to keep full-speed bandwidth
* reclamation active when no full-speed control or bulk QHs are linked
* into the schedule. It has an inactive TD (to work around a PIIX bug,
* see the Intel errata) and it points back to itself.
*
* There's a special skeleton QH for Isochronous QHs which never appears
* on the schedule. Isochronous TDs go on the schedule before the
* the skeleton QHs. The hardware accesses them directly rather than
* through their QH, which is used only for bookkeeping purposes.
* While the UHCI spec doesn't forbid the use of QHs for Isochronous,
* it doesn't use them either. And the spec says that queues never
* advance on an error completion status, which makes them totally
* unsuitable for Isochronous transfers.
*
* There's also a special skeleton QH used for QHs which are in the process
* of unlinking and so may still be in use by the hardware. It too never
* appears on the schedule.
*/
#define UHCI_NUM_SKELQH 11
#define SKEL_UNLINK 0
#define skel_unlink_qh skelqh[SKEL_UNLINK]
#define SKEL_ISO 1
#define skel_iso_qh skelqh[SKEL_ISO]
/* int128, int64, ..., int1 = 2, 3, ..., 9 */
#define SKEL_INDEX(exponent) (9 - exponent)
#define SKEL_ASYNC 9
#define skel_async_qh skelqh[SKEL_ASYNC]
#define SKEL_TERM 10
#define skel_term_qh skelqh[SKEL_TERM]
/* The following entries refer to sublists of skel_async_qh */
#define SKEL_LS_CONTROL 20
#define SKEL_FS_CONTROL 21
#define SKEL_FSBR SKEL_FS_CONTROL
#define SKEL_BULK 22
/*
* The UHCI controller and root hub
*/
/*
* States for the root hub:
*
* To prevent "bouncing" in the presence of electrical noise,
* when there are no devices attached we delay for 1 second in the
* RUNNING_NODEVS state before switching to the AUTO_STOPPED state.
*
* (Note that the AUTO_STOPPED state won't be necessary once the hub
* driver learns to autosuspend.)
*/
enum uhci_rh_state {
/* In the following states the HC must be halted.
* These two must come first. */
UHCI_RH_RESET,
UHCI_RH_SUSPENDED,
UHCI_RH_AUTO_STOPPED,
UHCI_RH_RESUMING,
/* In this state the HC changes from running to halted,
* so it can legally appear either way. */
UHCI_RH_SUSPENDING,
/* In the following states it's an error if the HC is halted.
* These two must come last. */
UHCI_RH_RUNNING, /* The normal state */
UHCI_RH_RUNNING_NODEVS, /* Running with no devices attached */
};
/*
* The full UHCI controller information:
*/
struct uhci_hcd {
/* debugfs */
struct dentry *dentry;
/* Grabbed from PCI */
unsigned long io_addr;
/* Used when registers are memory mapped */
void __iomem *regs;
struct dma_pool *qh_pool;
struct dma_pool *td_pool;
struct uhci_td *term_td; /* Terminating TD, see UHCI bug */
struct uhci_qh *skelqh[UHCI_NUM_SKELQH]; /* Skeleton QHs */
struct uhci_qh *next_qh; /* Next QH to scan */
spinlock_t lock;
dma_addr_t frame_dma_handle; /* Hardware frame list */
__hc32 *frame;
void **frame_cpu; /* CPU's frame list */
enum uhci_rh_state rh_state;
unsigned long auto_stop_time; /* When to AUTO_STOP */
unsigned int frame_number; /* As of last check */
unsigned int is_stopped;
#define UHCI_IS_STOPPED 9999 /* Larger than a frame # */
unsigned int last_iso_frame; /* Frame of last scan */
unsigned int cur_iso_frame; /* Frame for current scan */
unsigned int scan_in_progress:1; /* Schedule scan is running */
unsigned int need_rescan:1; /* Redo the schedule scan */
unsigned int dead:1; /* Controller has died */
unsigned int RD_enable:1; /* Suspended root hub with
Resume-Detect interrupts
enabled */
unsigned int is_initialized:1; /* Data structure is usable */
unsigned int fsbr_is_on:1; /* FSBR is turned on */
unsigned int fsbr_is_wanted:1; /* Does any URB want FSBR? */
unsigned int fsbr_expiring:1; /* FSBR is timing out */
struct timer_list fsbr_timer; /* For turning off FBSR */
/* Silicon quirks */
unsigned int oc_low:1; /* OverCurrent bit active low */
unsigned int wait_for_hp:1; /* Wait for HP port reset */
unsigned int big_endian_mmio:1; /* Big endian registers */
unsigned int big_endian_desc:1; /* Big endian descriptors */
/* Support for port suspend/resume/reset */
unsigned long port_c_suspend; /* Bit-arrays of ports */
unsigned long resuming_ports;
unsigned long ports_timeout; /* Time to stop signalling */
struct list_head idle_qh_list; /* Where the idle QHs live */
int rh_numports; /* Number of root-hub ports */
wait_queue_head_t waitqh; /* endpoint_disable waiters */
int num_waiting; /* Number of waiters */
int total_load; /* Sum of array values */
short load[MAX_PHASE]; /* Periodic allocations */
/* Reset host controller */
void (*reset_hc) (struct uhci_hcd *uhci);
int (*check_and_reset_hc) (struct uhci_hcd *uhci);
/* configure_hc should perform arch specific settings, if needed */
void (*configure_hc) (struct uhci_hcd *uhci);
/* Check for broken resume detect interrupts */
int (*resume_detect_interrupts_are_broken) (struct uhci_hcd *uhci);
/* Check for broken global suspend */
int (*global_suspend_mode_is_broken) (struct uhci_hcd *uhci);
};
/* Convert between a usb_hcd pointer and the corresponding uhci_hcd */
static inline struct uhci_hcd *hcd_to_uhci(struct usb_hcd *hcd)
{
return (struct uhci_hcd *) (hcd->hcd_priv);
}
static inline struct usb_hcd *uhci_to_hcd(struct uhci_hcd *uhci)
{
return container_of((void *) uhci, struct usb_hcd, hcd_priv);
}
#define uhci_dev(u) (uhci_to_hcd(u)->self.controller)
/* Utility macro for comparing frame numbers */
#define uhci_frame_before_eq(f1, f2) (0 <= (int) ((f2) - (f1)))
/*
* Private per-URB data
*/
struct urb_priv {
struct list_head node; /* Node in the QH's urbp list */
struct urb *urb;
struct uhci_qh *qh; /* QH for this URB */
struct list_head td_list;
unsigned fsbr:1; /* URB wants FSBR */
};
/* Some special IDs */
#define PCI_VENDOR_ID_GENESYS 0x17a0
#define PCI_DEVICE_ID_GL880S_UHCI 0x8083
/*
* Functions used to access controller registers. The UCHI spec says that host
* controller I/O registers are mapped into PCI I/O space. For non-PCI hosts
* we use memory mapped registers.
*/
#ifndef CONFIG_USB_UHCI_SUPPORT_NON_PCI_HC
/* Support PCI only */
static inline u32 uhci_readl(const struct uhci_hcd *uhci, int reg)
{
return inl(uhci->io_addr + reg);
}
static inline void uhci_writel(const struct uhci_hcd *uhci, u32 val, int reg)
{
outl(val, uhci->io_addr + reg);
}
static inline u16 uhci_readw(const struct uhci_hcd *uhci, int reg)
{
return inw(uhci->io_addr + reg);
}
static inline void uhci_writew(const struct uhci_hcd *uhci, u16 val, int reg)
{
outw(val, uhci->io_addr + reg);
}
static inline u8 uhci_readb(const struct uhci_hcd *uhci, int reg)
{
return inb(uhci->io_addr + reg);
}
static inline void uhci_writeb(const struct uhci_hcd *uhci, u8 val, int reg)
{
outb(val, uhci->io_addr + reg);
}
#else
/* Support non-PCI host controllers */
#ifdef CONFIG_USB_PCI
/* Support PCI and non-PCI host controllers */
#define uhci_has_pci_registers(u) ((u)->io_addr != 0)
#else
/* Support non-PCI host controllers only */
#define uhci_has_pci_registers(u) 0
#endif
#ifdef CONFIG_USB_UHCI_BIG_ENDIAN_MMIO
/* Support (non-PCI) big endian host controllers */
#define uhci_big_endian_mmio(u) ((u)->big_endian_mmio)
#else
#define uhci_big_endian_mmio(u) 0
#endif
static inline u32 uhci_readl(const struct uhci_hcd *uhci, int reg)
{
if (uhci_has_pci_registers(uhci))
return inl(uhci->io_addr + reg);
#ifdef CONFIG_USB_UHCI_BIG_ENDIAN_MMIO
else if (uhci_big_endian_mmio(uhci))
return readl_be(uhci->regs + reg);
#endif
else
return readl(uhci->regs + reg);
}
static inline void uhci_writel(const struct uhci_hcd *uhci, u32 val, int reg)
{
if (uhci_has_pci_registers(uhci))
outl(val, uhci->io_addr + reg);
#ifdef CONFIG_USB_UHCI_BIG_ENDIAN_MMIO
else if (uhci_big_endian_mmio(uhci))
writel_be(val, uhci->regs + reg);
#endif
else
writel(val, uhci->regs + reg);
}
static inline u16 uhci_readw(const struct uhci_hcd *uhci, int reg)
{
if (uhci_has_pci_registers(uhci))
return inw(uhci->io_addr + reg);
#ifdef CONFIG_USB_UHCI_BIG_ENDIAN_MMIO
else if (uhci_big_endian_mmio(uhci))
return readw_be(uhci->regs + reg);
#endif
else
return readw(uhci->regs + reg);
}
static inline void uhci_writew(const struct uhci_hcd *uhci, u16 val, int reg)
{
if (uhci_has_pci_registers(uhci))
outw(val, uhci->io_addr + reg);
#ifdef CONFIG_USB_UHCI_BIG_ENDIAN_MMIO
else if (uhci_big_endian_mmio(uhci))
writew_be(val, uhci->regs + reg);
#endif
else
writew(val, uhci->regs + reg);
}
static inline u8 uhci_readb(const struct uhci_hcd *uhci, int reg)
{
if (uhci_has_pci_registers(uhci))
return inb(uhci->io_addr + reg);
#ifdef CONFIG_USB_UHCI_BIG_ENDIAN_MMIO
else if (uhci_big_endian_mmio(uhci))
return readb_be(uhci->regs + reg);
#endif
else
return readb(uhci->regs + reg);
}
static inline void uhci_writeb(const struct uhci_hcd *uhci, u8 val, int reg)
{
if (uhci_has_pci_registers(uhci))
outb(val, uhci->io_addr + reg);
#ifdef CONFIG_USB_UHCI_BIG_ENDIAN_MMIO
else if (uhci_big_endian_mmio(uhci))
writeb_be(val, uhci->regs + reg);
#endif
else
writeb(val, uhci->regs + reg);
}
#endif /* CONFIG_USB_UHCI_SUPPORT_NON_PCI_HC */
/*
* The GRLIB GRUSBHC controller can use big endian format for its descriptors.
*
* UHCI controllers accessed through PCI work normally (little-endian
* everywhere), so we don't bother supporting a BE-only mode.
*/
#ifdef CONFIG_USB_UHCI_BIG_ENDIAN_DESC
#define uhci_big_endian_desc(u) ((u)->big_endian_desc)
/* cpu to uhci */
static inline __hc32 cpu_to_hc32(const struct uhci_hcd *uhci, const u32 x)
{
return uhci_big_endian_desc(uhci)
? (__force __hc32)cpu_to_be32(x)
: (__force __hc32)cpu_to_le32(x);
}
/* uhci to cpu */
static inline u32 hc32_to_cpu(const struct uhci_hcd *uhci, const __hc32 x)
{
return uhci_big_endian_desc(uhci)
? be32_to_cpu((__force __be32)x)
: le32_to_cpu((__force __le32)x);
}
#else
/* cpu to uhci */
static inline __hc32 cpu_to_hc32(const struct uhci_hcd *uhci, const u32 x)
{
return cpu_to_le32(x);
}
/* uhci to cpu */
static inline u32 hc32_to_cpu(const struct uhci_hcd *uhci, const __hc32 x)
{
return le32_to_cpu(x);
}
#endif
#endif