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#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 - basically PCI problems */
#define USBSTS_HCPE 0x0010 /* Host Controller Process Error - the scripts were 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
/* 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_LS 0x0030 /* Line Status */
#define USBPORTSC_RD 0x0040 /* Resume Detect */
#define USBPORTSC_LSDA 0x0100 /* Low Speed Device Attached */
#define USBPORTSC_PR 0x0200 /* Port Reset */
#define USBPORTSC_OC 0x0400 /* Over Current condition */
#define USBPORTSC_SUSP 0x1000 /* Suspend */
/* Legacy support register */
#define USBLEGSUP 0xc0
#define USBLEGSUP_DEFAULT 0x2000 /* only PIRQ enable set */
#define UHCI_NULL_DATA_SIZE 0x7FF /* for UHCI controller TD */
#define UHCI_PTR_BITS cpu_to_le32(0x000F)
#define UHCI_PTR_TERM cpu_to_le32(0x0001)
#define UHCI_PTR_QH cpu_to_le32(0x0002)
#define UHCI_PTR_DEPTH cpu_to_le32(0x0004)
#define UHCI_PTR_BREADTH cpu_to_le32(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 future frames can be scheduled */
struct uhci_frame_list {
__u32 frame[UHCI_NUMFRAMES];
void *frame_cpu[UHCI_NUMFRAMES];
dma_addr_t dma_handle;
};
struct urb_priv;
/*
* One role of a QH is to hold a queue of TDs for some endpoint. Each QH is
* used with one URB, and qh->element (updated by the HC) is either:
* - the next unprocessed TD for the URB, or
* - UHCI_PTR_TERM (when there's no more traffic for this endpoint), or
* - the QH for the next URB queued to the same 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 frame list, qh->link maintains a list of QHs seen by the HC:
* skel1 --> ep1-qh --> ep2-qh --> ... --> skel2 --> ...
*/
struct uhci_qh {
/* Hardware fields */
__u32 link; /* Next queue */
__u32 element; /* Queue element pointer */
/* Software fields */
dma_addr_t dma_handle;
struct usb_device *dev;
struct urb_priv *urbp;
struct list_head list; /* P: uhci->frame_list_lock */
struct list_head remove_list; /* P: uhci->remove_list_lock */
} __attribute__((aligned(16)));
/*
* for TD <status>:
*/
#define td_status(td) le32_to_cpu((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 TD_CTRL_ANY_ERROR (TD_CTRL_STALLED | TD_CTRL_DBUFERR | \
TD_CTRL_BABBLE | TD_CTRL_CRCTIME | TD_CTRL_BITSTUFF)
#define uhci_maxerr(err) ((err) << TD_CTRL_C_ERR_SHIFT)
#define uhci_status_bits(ctrl_sts) ((ctrl_sts) & 0xFE0000)
#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(td) le32_to_cpu((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) << TD_TOKEN_EXPLEN_SHIFT)
#define uhci_expected_length(token) ((((token) >> 21) + 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 as far as I can tell.
*
* But let's just go with the documentation, at least for 32-bit machines.
* On 64-bit machines we probably want to take advantage of the fact that
* hw doesn't really care about the size of the sw-only area.
*
* Alas, not anymore, we have more than 4 words for software, woops.
* Everything still works tho, surprise! -jerdfelt
*
* 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 (for queued urbs)
*/
struct uhci_td {
/* Hardware fields */
__u32 link;
__u32 status;
__u32 token;
__u32 buffer;
/* Software fields */
dma_addr_t dma_handle;
struct usb_device *dev;
struct urb *urb;
struct list_head list; /* P: urb->lock */
struct list_head remove_list; /* P: uhci->td_remove_list_lock */
int frame; /* for iso: what frame? */
struct list_head fl_list; /* P: uhci->frame_list_lock */
} __attribute__((aligned(16)));
/*
* The UHCI driver places Interrupt, Control and Bulk into QH's both
* to group together TD's for one transfer, and also to faciliate queuing
* of URB's. To make it easy to insert entries into the schedule, we have
* a skeleton of QH's for each predefined Interrupt latency, low speed
* control, high speed control and terminating QH (see explanation for
* the terminating QH below).
*
* When we want to add a new QH, we add it to the end of the list for the
* skeleton QH.
*
* For instance, the queue can look like this:
*
* skel int128 QH
* dev 1 interrupt QH
* dev 5 interrupt QH
* skel int64 QH
* skel int32 QH
* ...
* skel int1 QH
* skel low speed control QH
* dev 5 control QH
* skel high speed control QH
* skel bulk QH
* dev 1 bulk QH
* dev 2 bulk QH
* skel terminating QH
*
* The terminating QH is used for 2 reasons:
* - To place a terminating TD which is used to workaround a PIIX bug
* (see Intel errata for explanation)
* - To loop back to the high speed control queue for full speed bandwidth
* reclamation
*
* Isochronous transfers are stored before the start of the skeleton
* schedule and don't use QH's. While the UHCI spec doesn't forbid the
* use of QH's for Isochronous, it doesn't use them either. Since we don't
* need to use them either, we follow the spec diagrams in hope that it'll
* be more compatible with future UHCI implementations.
*/
#define UHCI_NUM_SKELQH 12
#define skel_int128_qh skelqh[0]
#define skel_int64_qh skelqh[1]
#define skel_int32_qh skelqh[2]
#define skel_int16_qh skelqh[3]
#define skel_int8_qh skelqh[4]
#define skel_int4_qh skelqh[5]
#define skel_int2_qh skelqh[6]
#define skel_int1_qh skelqh[7]
#define skel_ls_control_qh skelqh[8]
#define skel_hs_control_qh skelqh[9]
#define skel_bulk_qh skelqh[10]
#define skel_term_qh skelqh[11]
/*
* Search tree for determining where <interval> fits in the skelqh[]
* skeleton.
*
* An interrupt request should be placed into the slowest skelqh[]
* which meets the interval/period/frequency requirement.
* An interrupt request is allowed to be faster than <interval> but not slower.
*
* For a given <interval>, this function returns the appropriate/matching
* skelqh[] index value.
*/
static inline int __interval_to_skel(int interval)
{
if (interval < 16) {
if (interval < 4) {
if (interval < 2)
return 7; /* int1 for 0-1 ms */
return 6; /* int2 for 2-3 ms */
}
if (interval < 8)
return 5; /* int4 for 4-7 ms */
return 4; /* int8 for 8-15 ms */
}
if (interval < 64) {
if (interval < 32)
return 3; /* int16 for 16-31 ms */
return 2; /* int32 for 32-63 ms */
}
if (interval < 128)
return 1; /* int64 for 64-127 ms */
return 0; /* int128 for 128-255 ms (Max.) */
}
/*
* Device states for the host controller.
*
* To prevent "bouncing" in the presence of electrical noise,
* we insist on a 1-second "grace" period, before switching to
* the RUNNING or SUSPENDED states, during which the state is
* not allowed to change.
*
* The resume process is divided into substates in order to avoid
* potentially length delays during the timer handler.
*
* States in which the host controller is halted must have values <= 0.
*/
enum uhci_state {
UHCI_RESET,
UHCI_RUNNING_GRACE, /* Before RUNNING */
UHCI_RUNNING, /* The normal state */
UHCI_SUSPENDING_GRACE, /* Before SUSPENDED */
UHCI_SUSPENDED = -10, /* When no devices are attached */
UHCI_RESUMING_1,
UHCI_RESUMING_2
};
#define hcd_to_uhci(hcd_ptr) container_of(hcd_ptr, struct uhci_hcd, hcd)
/*
* This describes the full uhci information.
*
* Note how the "proper" USB information is just
* a subset of what the full implementation needs.
*/
struct uhci_hcd {
struct usb_hcd hcd;
#ifdef CONFIG_PROC_FS
/* procfs */
struct proc_dir_entry *proc_entry;
#endif
/* Grabbed from PCI */
unsigned long io_addr;
struct pci_pool *qh_pool;
struct pci_pool *td_pool;
struct usb_bus *bus;
struct uhci_td *term_td; /* Terminating TD, see UHCI bug */
struct uhci_qh *skelqh[UHCI_NUM_SKELQH]; /* Skeleton QH's */
spinlock_t frame_list_lock;
struct uhci_frame_list *fl; /* P: uhci->frame_list_lock */
int fsbr; /* Full speed bandwidth reclamation */
unsigned long fsbrtimeout; /* FSBR delay */
enum uhci_state state; /* FIXME: needs a spinlock */
unsigned long state_end; /* Time of next transition */
int resume_detect; /* Need a Global Resume */
/* Main list of URB's currently controlled by this HC */
spinlock_t urb_list_lock;
struct list_head urb_list; /* P: uhci->urb_list_lock */
/* List of QH's that are done, but waiting to be unlinked (race) */
spinlock_t qh_remove_list_lock;
struct list_head qh_remove_list; /* P: uhci->qh_remove_list_lock */
/* List of TD's that are done, but waiting to be freed (race) */
spinlock_t td_remove_list_lock;
struct list_head td_remove_list; /* P: uhci->td_remove_list_lock */
/* List of asynchronously unlinked URB's */
spinlock_t urb_remove_list_lock;
struct list_head urb_remove_list; /* P: uhci->urb_remove_list_lock */
/* List of URB's awaiting completion callback */
spinlock_t complete_list_lock;
struct list_head complete_list; /* P: uhci->complete_list_lock */
int rh_numports;
struct timer_list stall_timer;
};
struct urb_priv {
struct list_head urb_list;
struct urb *urb;
struct usb_device *dev;
struct uhci_qh *qh; /* QH for this URB */
struct list_head td_list; /* P: urb->lock */
int fsbr : 1; /* URB turned on FSBR */
int fsbr_timeout : 1; /* URB timed out on FSBR */
int queued : 1; /* QH was queued (not linked in) */
int short_control_packet : 1; /* If we get a short packet during */
/* a control transfer, retrigger */
/* the status phase */
int status; /* Final status */
unsigned long inserttime; /* In jiffies */
unsigned long fsbrtime; /* In jiffies */
struct list_head queue_list; /* P: uhci->frame_list_lock */
struct list_head complete_list; /* P: uhci->complete_list_lock */
};
/*
* Locking in uhci.c
*
* spinlocks are used extensively to protect the many lists and data
* structures we have. It's not that pretty, but it's necessary. We
* need to be done with all of the locks (except complete_list_lock) when
* we call urb->complete. I've tried to make it simple enough so I don't
* have to spend hours racking my brain trying to figure out if the
* locking is safe.
*
* Here's the safe locking order to prevent deadlocks:
*
* #1 uhci->urb_list_lock
* #2 urb->lock
* #3 uhci->urb_remove_list_lock, uhci->frame_list_lock,
* uhci->qh_remove_list_lock
* #4 uhci->complete_list_lock
*
* If you're going to grab 2 or more locks at once, ALWAYS grab the lock
* at the lowest level FIRST and NEVER grab locks at the same level at the
* same time.
*
* So, if you need uhci->urb_list_lock, grab it before you grab urb->lock
*/
#endif