xhci-mem.c 27.8 KB
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/*
 * xHCI host controller driver
 *
 * Copyright (C) 2008 Intel Corp.
 *
 * Author: Sarah Sharp
 * Some code borrowed from the Linux EHCI driver.
 *
 * This program is free software; you can redistribute it and/or modify
 * it under the terms of the GNU General Public License version 2 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., 675 Mass Ave, Cambridge, MA 02139, USA.
 */

#include <linux/usb.h>
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#include <linux/pci.h>
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#include <linux/dmapool.h>
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#include "xhci.h"

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/*
 * Allocates a generic ring segment from the ring pool, sets the dma address,
 * initializes the segment to zero, and sets the private next pointer to NULL.
 *
 * Section 4.11.1.1:
 * "All components of all Command and Transfer TRBs shall be initialized to '0'"
 */
static struct xhci_segment *xhci_segment_alloc(struct xhci_hcd *xhci, gfp_t flags)
{
	struct xhci_segment *seg;
	dma_addr_t	dma;

	seg = kzalloc(sizeof *seg, flags);
	if (!seg)
		return 0;
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	xhci_dbg(xhci, "Allocating priv segment structure at %p\n", seg);
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	seg->trbs = dma_pool_alloc(xhci->segment_pool, flags, &dma);
	if (!seg->trbs) {
		kfree(seg);
		return 0;
	}
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	xhci_dbg(xhci, "// Allocating segment at %p (virtual) 0x%llx (DMA)\n",
			seg->trbs, (unsigned long long)dma);
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	memset(seg->trbs, 0, SEGMENT_SIZE);
	seg->dma = dma;
	seg->next = NULL;

	return seg;
}

static void xhci_segment_free(struct xhci_hcd *xhci, struct xhci_segment *seg)
{
	if (!seg)
		return;
	if (seg->trbs) {
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		xhci_dbg(xhci, "Freeing DMA segment at %p (virtual) 0x%llx (DMA)\n",
				seg->trbs, (unsigned long long)seg->dma);
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		dma_pool_free(xhci->segment_pool, seg->trbs, seg->dma);
		seg->trbs = NULL;
	}
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	xhci_dbg(xhci, "Freeing priv segment structure at %p\n", seg);
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	kfree(seg);
}

/*
 * Make the prev segment point to the next segment.
 *
 * Change the last TRB in the prev segment to be a Link TRB which points to the
 * DMA address of the next segment.  The caller needs to set any Link TRB
 * related flags, such as End TRB, Toggle Cycle, and no snoop.
 */
static void xhci_link_segments(struct xhci_hcd *xhci, struct xhci_segment *prev,
		struct xhci_segment *next, bool link_trbs)
{
	u32 val;

	if (!prev || !next)
		return;
	prev->next = next;
	if (link_trbs) {
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		prev->trbs[TRBS_PER_SEGMENT-1].link.segment_ptr = next->dma;
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		/* Set the last TRB in the segment to have a TRB type ID of Link TRB */
		val = prev->trbs[TRBS_PER_SEGMENT-1].link.control;
		val &= ~TRB_TYPE_BITMASK;
		val |= TRB_TYPE(TRB_LINK);
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		/* Always set the chain bit with 0.95 hardware */
		if (xhci_link_trb_quirk(xhci))
			val |= TRB_CHAIN;
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		prev->trbs[TRBS_PER_SEGMENT-1].link.control = val;
	}
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	xhci_dbg(xhci, "Linking segment 0x%llx to segment 0x%llx (DMA)\n",
			(unsigned long long)prev->dma,
			(unsigned long long)next->dma);
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}

/* XXX: Do we need the hcd structure in all these functions? */
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void xhci_ring_free(struct xhci_hcd *xhci, struct xhci_ring *ring)
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{
	struct xhci_segment *seg;
	struct xhci_segment *first_seg;

	if (!ring || !ring->first_seg)
		return;
	first_seg = ring->first_seg;
	seg = first_seg->next;
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	xhci_dbg(xhci, "Freeing ring at %p\n", ring);
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	while (seg != first_seg) {
		struct xhci_segment *next = seg->next;
		xhci_segment_free(xhci, seg);
		seg = next;
	}
	xhci_segment_free(xhci, first_seg);
	ring->first_seg = NULL;
	kfree(ring);
}

/**
 * Create a new ring with zero or more segments.
 *
 * Link each segment together into a ring.
 * Set the end flag and the cycle toggle bit on the last segment.
 * See section 4.9.1 and figures 15 and 16.
 */
static struct xhci_ring *xhci_ring_alloc(struct xhci_hcd *xhci,
		unsigned int num_segs, bool link_trbs, gfp_t flags)
{
	struct xhci_ring	*ring;
	struct xhci_segment	*prev;

	ring = kzalloc(sizeof *(ring), flags);
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	xhci_dbg(xhci, "Allocating ring at %p\n", ring);
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	if (!ring)
		return 0;

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	INIT_LIST_HEAD(&ring->td_list);
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	INIT_LIST_HEAD(&ring->cancelled_td_list);
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	if (num_segs == 0)
		return ring;

	ring->first_seg = xhci_segment_alloc(xhci, flags);
	if (!ring->first_seg)
		goto fail;
	num_segs--;

	prev = ring->first_seg;
	while (num_segs > 0) {
		struct xhci_segment	*next;

		next = xhci_segment_alloc(xhci, flags);
		if (!next)
			goto fail;
		xhci_link_segments(xhci, prev, next, link_trbs);

		prev = next;
		num_segs--;
	}
	xhci_link_segments(xhci, prev, ring->first_seg, link_trbs);

	if (link_trbs) {
		/* See section 4.9.2.1 and 6.4.4.1 */
		prev->trbs[TRBS_PER_SEGMENT-1].link.control |= (LINK_TOGGLE);
		xhci_dbg(xhci, "Wrote link toggle flag to"
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				" segment %p (virtual), 0x%llx (DMA)\n",
				prev, (unsigned long long)prev->dma);
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	}
	/* The ring is empty, so the enqueue pointer == dequeue pointer */
	ring->enqueue = ring->first_seg->trbs;
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	ring->enq_seg = ring->first_seg;
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	ring->dequeue = ring->enqueue;
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	ring->deq_seg = ring->first_seg;
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	/* The ring is initialized to 0. The producer must write 1 to the cycle
	 * bit to handover ownership of the TRB, so PCS = 1.  The consumer must
	 * compare CCS to the cycle bit to check ownership, so CCS = 1.
	 */
	ring->cycle_state = 1;

	return ring;

fail:
	xhci_ring_free(xhci, ring);
	return 0;
}

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#define CTX_SIZE(_hcc) (HCC_64BYTE_CONTEXT(_hcc) ? 64 : 32)

struct xhci_container_ctx *xhci_alloc_container_ctx(struct xhci_hcd *xhci,
						    int type, gfp_t flags)
{
	struct xhci_container_ctx *ctx = kzalloc(sizeof(*ctx), flags);
	if (!ctx)
		return NULL;

	BUG_ON((type != XHCI_CTX_TYPE_DEVICE) && (type != XHCI_CTX_TYPE_INPUT));
	ctx->type = type;
	ctx->size = HCC_64BYTE_CONTEXT(xhci->hcc_params) ? 2048 : 1024;
	if (type == XHCI_CTX_TYPE_INPUT)
		ctx->size += CTX_SIZE(xhci->hcc_params);

	ctx->bytes = dma_pool_alloc(xhci->device_pool, flags, &ctx->dma);
	memset(ctx->bytes, 0, ctx->size);
	return ctx;
}

void xhci_free_container_ctx(struct xhci_hcd *xhci,
			     struct xhci_container_ctx *ctx)
{
	dma_pool_free(xhci->device_pool, ctx->bytes, ctx->dma);
	kfree(ctx);
}

struct xhci_input_control_ctx *xhci_get_input_control_ctx(struct xhci_hcd *xhci,
					      struct xhci_container_ctx *ctx)
{
	BUG_ON(ctx->type != XHCI_CTX_TYPE_INPUT);
	return (struct xhci_input_control_ctx *)ctx->bytes;
}

struct xhci_slot_ctx *xhci_get_slot_ctx(struct xhci_hcd *xhci,
					struct xhci_container_ctx *ctx)
{
	if (ctx->type == XHCI_CTX_TYPE_DEVICE)
		return (struct xhci_slot_ctx *)ctx->bytes;

	return (struct xhci_slot_ctx *)
		(ctx->bytes + CTX_SIZE(xhci->hcc_params));
}

struct xhci_ep_ctx *xhci_get_ep_ctx(struct xhci_hcd *xhci,
				    struct xhci_container_ctx *ctx,
				    unsigned int ep_index)
{
	/* increment ep index by offset of start of ep ctx array */
	ep_index++;
	if (ctx->type == XHCI_CTX_TYPE_INPUT)
		ep_index++;

	return (struct xhci_ep_ctx *)
		(ctx->bytes + (ep_index * CTX_SIZE(xhci->hcc_params)));
}

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/* All the xhci_tds in the ring's TD list should be freed at this point */
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void xhci_free_virt_device(struct xhci_hcd *xhci, int slot_id)
{
	struct xhci_virt_device *dev;
	int i;

	/* Slot ID 0 is reserved */
	if (slot_id == 0 || !xhci->devs[slot_id])
		return;

	dev = xhci->devs[slot_id];
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	xhci->dcbaa->dev_context_ptrs[slot_id] = 0;
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	if (!dev)
		return;

	for (i = 0; i < 31; ++i)
		if (dev->ep_rings[i])
			xhci_ring_free(xhci, dev->ep_rings[i]);

	if (dev->in_ctx)
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		xhci_free_container_ctx(xhci, dev->in_ctx);
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	if (dev->out_ctx)
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		xhci_free_container_ctx(xhci, dev->out_ctx);

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	kfree(xhci->devs[slot_id]);
	xhci->devs[slot_id] = 0;
}

int xhci_alloc_virt_device(struct xhci_hcd *xhci, int slot_id,
		struct usb_device *udev, gfp_t flags)
{
	struct xhci_virt_device *dev;

	/* Slot ID 0 is reserved */
	if (slot_id == 0 || xhci->devs[slot_id]) {
		xhci_warn(xhci, "Bad Slot ID %d\n", slot_id);
		return 0;
	}

	xhci->devs[slot_id] = kzalloc(sizeof(*xhci->devs[slot_id]), flags);
	if (!xhci->devs[slot_id])
		return 0;
	dev = xhci->devs[slot_id];

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	/* Allocate the (output) device context that will be used in the HC. */
	dev->out_ctx = xhci_alloc_container_ctx(xhci, XHCI_CTX_TYPE_DEVICE, flags);
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	if (!dev->out_ctx)
		goto fail;
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	xhci_dbg(xhci, "Slot %d output ctx = 0x%llx (dma)\n", slot_id,
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			(unsigned long long)dev->out_ctx->dma);
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	/* Allocate the (input) device context for address device command */
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	dev->in_ctx = xhci_alloc_container_ctx(xhci, XHCI_CTX_TYPE_INPUT, flags);
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	if (!dev->in_ctx)
		goto fail;
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	xhci_dbg(xhci, "Slot %d input ctx = 0x%llx (dma)\n", slot_id,
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			(unsigned long long)dev->in_ctx->dma);
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	/* Allocate endpoint 0 ring */
	dev->ep_rings[0] = xhci_ring_alloc(xhci, 1, true, flags);
	if (!dev->ep_rings[0])
		goto fail;

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	init_completion(&dev->cmd_completion);

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	/* Point to output device context in dcbaa. */
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	xhci->dcbaa->dev_context_ptrs[slot_id] = dev->out_ctx->dma;
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	xhci_dbg(xhci, "Set slot id %d dcbaa entry %p to 0x%llx\n",
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			slot_id,
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			&xhci->dcbaa->dev_context_ptrs[slot_id],
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			(unsigned long long) xhci->dcbaa->dev_context_ptrs[slot_id]);
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	return 1;
fail:
	xhci_free_virt_device(xhci, slot_id);
	return 0;
}

/* Setup an xHCI virtual device for a Set Address command */
int xhci_setup_addressable_virt_dev(struct xhci_hcd *xhci, struct usb_device *udev)
{
	struct xhci_virt_device *dev;
	struct xhci_ep_ctx	*ep0_ctx;
	struct usb_device	*top_dev;
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	struct xhci_slot_ctx    *slot_ctx;
	struct xhci_input_control_ctx *ctrl_ctx;
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	dev = xhci->devs[udev->slot_id];
	/* Slot ID 0 is reserved */
	if (udev->slot_id == 0 || !dev) {
		xhci_warn(xhci, "Slot ID %d is not assigned to this device\n",
				udev->slot_id);
		return -EINVAL;
	}
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	ep0_ctx = xhci_get_ep_ctx(xhci, dev->in_ctx, 0);
	ctrl_ctx = xhci_get_input_control_ctx(xhci, dev->in_ctx);
	slot_ctx = xhci_get_slot_ctx(xhci, dev->in_ctx);
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	/* 2) New slot context and endpoint 0 context are valid*/
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	ctrl_ctx->add_flags = SLOT_FLAG | EP0_FLAG;
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	/* 3) Only the control endpoint is valid - one endpoint context */
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	slot_ctx->dev_info |= LAST_CTX(1);
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	switch (udev->speed) {
	case USB_SPEED_SUPER:
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		slot_ctx->dev_info |= (u32) udev->route;
		slot_ctx->dev_info |= (u32) SLOT_SPEED_SS;
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		break;
	case USB_SPEED_HIGH:
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		slot_ctx->dev_info |= (u32) SLOT_SPEED_HS;
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		break;
	case USB_SPEED_FULL:
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		slot_ctx->dev_info |= (u32) SLOT_SPEED_FS;
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		break;
	case USB_SPEED_LOW:
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		slot_ctx->dev_info |= (u32) SLOT_SPEED_LS;
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		break;
	case USB_SPEED_VARIABLE:
		xhci_dbg(xhci, "FIXME xHCI doesn't support wireless speeds\n");
		return -EINVAL;
		break;
	default:
		/* Speed was set earlier, this shouldn't happen. */
		BUG();
	}
	/* Find the root hub port this device is under */
	for (top_dev = udev; top_dev->parent && top_dev->parent->parent;
			top_dev = top_dev->parent)
		/* Found device below root hub */;
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	slot_ctx->dev_info2 |= (u32) ROOT_HUB_PORT(top_dev->portnum);
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	xhci_dbg(xhci, "Set root hub portnum to %d\n", top_dev->portnum);

	/* Is this a LS/FS device under a HS hub? */
	/*
	 * FIXME: I don't think this is right, where does the TT info for the
	 * roothub or parent hub come from?
	 */
	if ((udev->speed == USB_SPEED_LOW || udev->speed == USB_SPEED_FULL) &&
			udev->tt) {
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		slot_ctx->tt_info = udev->tt->hub->slot_id;
		slot_ctx->tt_info |= udev->ttport << 8;
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	}
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	xhci_dbg(xhci, "udev->tt = %p\n", udev->tt);
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	xhci_dbg(xhci, "udev->ttport = 0x%x\n", udev->ttport);

	/* Step 4 - ring already allocated */
	/* Step 5 */
	ep0_ctx->ep_info2 = EP_TYPE(CTRL_EP);
	/*
	 * See section 4.3 bullet 6:
	 * The default Max Packet size for ep0 is "8 bytes for a USB2
	 * LS/FS/HS device or 512 bytes for a USB3 SS device"
	 * XXX: Not sure about wireless USB devices.
	 */
	if (udev->speed == USB_SPEED_SUPER)
		ep0_ctx->ep_info2 |= MAX_PACKET(512);
	else
		ep0_ctx->ep_info2 |= MAX_PACKET(8);
	/* EP 0 can handle "burst" sizes of 1, so Max Burst Size field is 0 */
	ep0_ctx->ep_info2 |= MAX_BURST(0);
	ep0_ctx->ep_info2 |= ERROR_COUNT(3);

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	ep0_ctx->deq =
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		dev->ep_rings[0]->first_seg->dma;
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	ep0_ctx->deq |= dev->ep_rings[0]->cycle_state;
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	/* Steps 7 and 8 were done in xhci_alloc_virt_device() */

	return 0;
}

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/* Return the polling or NAK interval.
 *
 * The polling interval is expressed in "microframes".  If xHCI's Interval field
 * is set to N, it will service the endpoint every 2^(Interval)*125us.
 *
 * The NAK interval is one NAK per 1 to 255 microframes, or no NAKs if interval
 * is set to 0.
 */
static inline unsigned int xhci_get_endpoint_interval(struct usb_device *udev,
		struct usb_host_endpoint *ep)
{
	unsigned int interval = 0;

	switch (udev->speed) {
	case USB_SPEED_HIGH:
		/* Max NAK rate */
		if (usb_endpoint_xfer_control(&ep->desc) ||
				usb_endpoint_xfer_bulk(&ep->desc))
			interval = ep->desc.bInterval;
		/* Fall through - SS and HS isoc/int have same decoding */
	case USB_SPEED_SUPER:
		if (usb_endpoint_xfer_int(&ep->desc) ||
				usb_endpoint_xfer_isoc(&ep->desc)) {
			if (ep->desc.bInterval == 0)
				interval = 0;
			else
				interval = ep->desc.bInterval - 1;
			if (interval > 15)
				interval = 15;
			if (interval != ep->desc.bInterval + 1)
				dev_warn(&udev->dev, "ep %#x - rounding interval to %d microframes\n",
						ep->desc.bEndpointAddress, 1 << interval);
		}
		break;
	/* Convert bInterval (in 1-255 frames) to microframes and round down to
	 * nearest power of 2.
	 */
	case USB_SPEED_FULL:
	case USB_SPEED_LOW:
		if (usb_endpoint_xfer_int(&ep->desc) ||
				usb_endpoint_xfer_isoc(&ep->desc)) {
			interval = fls(8*ep->desc.bInterval) - 1;
			if (interval > 10)
				interval = 10;
			if (interval < 3)
				interval = 3;
			if ((1 << interval) != 8*ep->desc.bInterval)
				dev_warn(&udev->dev, "ep %#x - rounding interval to %d microframes\n",
						ep->desc.bEndpointAddress, 1 << interval);
		}
		break;
	default:
		BUG();
	}
	return EP_INTERVAL(interval);
}

static inline u32 xhci_get_endpoint_type(struct usb_device *udev,
		struct usb_host_endpoint *ep)
{
	int in;
	u32 type;

	in = usb_endpoint_dir_in(&ep->desc);
	if (usb_endpoint_xfer_control(&ep->desc)) {
		type = EP_TYPE(CTRL_EP);
	} else if (usb_endpoint_xfer_bulk(&ep->desc)) {
		if (in)
			type = EP_TYPE(BULK_IN_EP);
		else
			type = EP_TYPE(BULK_OUT_EP);
	} else if (usb_endpoint_xfer_isoc(&ep->desc)) {
		if (in)
			type = EP_TYPE(ISOC_IN_EP);
		else
			type = EP_TYPE(ISOC_OUT_EP);
	} else if (usb_endpoint_xfer_int(&ep->desc)) {
		if (in)
			type = EP_TYPE(INT_IN_EP);
		else
			type = EP_TYPE(INT_OUT_EP);
	} else {
		BUG();
	}
	return type;
}

int xhci_endpoint_init(struct xhci_hcd *xhci,
		struct xhci_virt_device *virt_dev,
		struct usb_device *udev,
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		struct usb_host_endpoint *ep,
		gfp_t mem_flags)
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{
	unsigned int ep_index;
	struct xhci_ep_ctx *ep_ctx;
	struct xhci_ring *ep_ring;
	unsigned int max_packet;
	unsigned int max_burst;

	ep_index = xhci_get_endpoint_index(&ep->desc);
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	ep_ctx = xhci_get_ep_ctx(xhci, virt_dev->in_ctx, ep_index);
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	/* Set up the endpoint ring */
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	virt_dev->new_ep_rings[ep_index] = xhci_ring_alloc(xhci, 1, true, mem_flags);
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	if (!virt_dev->new_ep_rings[ep_index])
		return -ENOMEM;
	ep_ring = virt_dev->new_ep_rings[ep_index];
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	ep_ctx->deq = ep_ring->first_seg->dma | ep_ring->cycle_state;
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	ep_ctx->ep_info = xhci_get_endpoint_interval(udev, ep);

	/* FIXME dig Mult and streams info out of ep companion desc */

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	/* Allow 3 retries for everything but isoc;
	 * error count = 0 means infinite retries.
	 */
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	if (!usb_endpoint_xfer_isoc(&ep->desc))
		ep_ctx->ep_info2 = ERROR_COUNT(3);
	else
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		ep_ctx->ep_info2 = ERROR_COUNT(1);
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	ep_ctx->ep_info2 |= xhci_get_endpoint_type(udev, ep);

	/* Set the max packet size and max burst */
	switch (udev->speed) {
	case USB_SPEED_SUPER:
		max_packet = ep->desc.wMaxPacketSize;
		ep_ctx->ep_info2 |= MAX_PACKET(max_packet);
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		/* dig out max burst from ep companion desc */
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		if (!ep->ss_ep_comp) {
			xhci_warn(xhci, "WARN no SS endpoint companion descriptor.\n");
			max_packet = 0;
		} else {
			max_packet = ep->ss_ep_comp->desc.bMaxBurst;
		}
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		ep_ctx->ep_info2 |= MAX_BURST(max_packet);
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		break;
	case USB_SPEED_HIGH:
		/* bits 11:12 specify the number of additional transaction
		 * opportunities per microframe (USB 2.0, section 9.6.6)
		 */
		if (usb_endpoint_xfer_isoc(&ep->desc) ||
				usb_endpoint_xfer_int(&ep->desc)) {
			max_burst = (ep->desc.wMaxPacketSize & 0x1800) >> 11;
			ep_ctx->ep_info2 |= MAX_BURST(max_burst);
		}
		/* Fall through */
	case USB_SPEED_FULL:
	case USB_SPEED_LOW:
		max_packet = ep->desc.wMaxPacketSize & 0x3ff;
		ep_ctx->ep_info2 |= MAX_PACKET(max_packet);
		break;
	default:
		BUG();
	}
	/* FIXME Debug endpoint context */
	return 0;
}

void xhci_endpoint_zero(struct xhci_hcd *xhci,
		struct xhci_virt_device *virt_dev,
		struct usb_host_endpoint *ep)
{
	unsigned int ep_index;
	struct xhci_ep_ctx *ep_ctx;

	ep_index = xhci_get_endpoint_index(&ep->desc);
593
	ep_ctx = xhci_get_ep_ctx(xhci, virt_dev->in_ctx, ep_index);
594 595 596

	ep_ctx->ep_info = 0;
	ep_ctx->ep_info2 = 0;
597
	ep_ctx->deq = 0;
598 599 600 601 602 603
	ep_ctx->tx_info = 0;
	/* Don't free the endpoint ring until the set interface or configuration
	 * request succeeds.
	 */
}

604 605 606 607 608 609 610 611 612 613 614 615 616 617 618 619 620 621 622 623 624 625 626 627 628 629 630 631 632 633 634 635 636 637 638 639 640 641
/* Copy output xhci_ep_ctx to the input xhci_ep_ctx copy.
 * Useful when you want to change one particular aspect of the endpoint and then
 * issue a configure endpoint command.
 */
void xhci_endpoint_copy(struct xhci_hcd *xhci,
		struct xhci_virt_device *vdev, unsigned int ep_index)
{
	struct xhci_ep_ctx *out_ep_ctx;
	struct xhci_ep_ctx *in_ep_ctx;

	out_ep_ctx = xhci_get_ep_ctx(xhci, vdev->out_ctx, ep_index);
	in_ep_ctx = xhci_get_ep_ctx(xhci, vdev->in_ctx, ep_index);

	in_ep_ctx->ep_info = out_ep_ctx->ep_info;
	in_ep_ctx->ep_info2 = out_ep_ctx->ep_info2;
	in_ep_ctx->deq = out_ep_ctx->deq;
	in_ep_ctx->tx_info = out_ep_ctx->tx_info;
}

/* Copy output xhci_slot_ctx to the input xhci_slot_ctx.
 * Useful when you want to change one particular aspect of the endpoint and then
 * issue a configure endpoint command.  Only the context entries field matters,
 * but we'll copy the whole thing anyway.
 */
void xhci_slot_copy(struct xhci_hcd *xhci, struct xhci_virt_device *vdev)
{
	struct xhci_slot_ctx *in_slot_ctx;
	struct xhci_slot_ctx *out_slot_ctx;

	in_slot_ctx = xhci_get_slot_ctx(xhci, vdev->in_ctx);
	out_slot_ctx = xhci_get_slot_ctx(xhci, vdev->out_ctx);

	in_slot_ctx->dev_info = out_slot_ctx->dev_info;
	in_slot_ctx->dev_info2 = out_slot_ctx->dev_info2;
	in_slot_ctx->tt_info = out_slot_ctx->tt_info;
	in_slot_ctx->dev_state = out_slot_ctx->dev_state;
}

642 643 644 645 646 647 648 649 650 651 652 653 654 655 656 657 658 659 660 661 662 663 664 665 666 667 668 669 670 671 672 673 674 675 676 677 678 679 680 681 682 683 684 685 686 687 688 689 690 691 692 693 694 695 696 697 698 699 700 701 702 703 704 705 706 707 708 709 710 711 712 713 714 715 716 717 718 719 720 721 722 723 724 725 726 727 728 729 730 731 732 733 734 735 736 737 738
/* Set up the scratchpad buffer array and scratchpad buffers, if needed. */
static int scratchpad_alloc(struct xhci_hcd *xhci, gfp_t flags)
{
	int i;
	struct device *dev = xhci_to_hcd(xhci)->self.controller;
	int num_sp = HCS_MAX_SCRATCHPAD(xhci->hcs_params2);

	xhci_dbg(xhci, "Allocating %d scratchpad buffers\n", num_sp);

	if (!num_sp)
		return 0;

	xhci->scratchpad = kzalloc(sizeof(*xhci->scratchpad), flags);
	if (!xhci->scratchpad)
		goto fail_sp;

	xhci->scratchpad->sp_array =
		pci_alloc_consistent(to_pci_dev(dev),
				     num_sp * sizeof(u64),
				     &xhci->scratchpad->sp_dma);
	if (!xhci->scratchpad->sp_array)
		goto fail_sp2;

	xhci->scratchpad->sp_buffers = kzalloc(sizeof(void *) * num_sp, flags);
	if (!xhci->scratchpad->sp_buffers)
		goto fail_sp3;

	xhci->scratchpad->sp_dma_buffers =
		kzalloc(sizeof(dma_addr_t) * num_sp, flags);

	if (!xhci->scratchpad->sp_dma_buffers)
		goto fail_sp4;

	xhci->dcbaa->dev_context_ptrs[0] = xhci->scratchpad->sp_dma;
	for (i = 0; i < num_sp; i++) {
		dma_addr_t dma;
		void *buf = pci_alloc_consistent(to_pci_dev(dev),
						 xhci->page_size, &dma);
		if (!buf)
			goto fail_sp5;

		xhci->scratchpad->sp_array[i] = dma;
		xhci->scratchpad->sp_buffers[i] = buf;
		xhci->scratchpad->sp_dma_buffers[i] = dma;
	}

	return 0;

 fail_sp5:
	for (i = i - 1; i >= 0; i--) {
		pci_free_consistent(to_pci_dev(dev), xhci->page_size,
				    xhci->scratchpad->sp_buffers[i],
				    xhci->scratchpad->sp_dma_buffers[i]);
	}
	kfree(xhci->scratchpad->sp_dma_buffers);

 fail_sp4:
	kfree(xhci->scratchpad->sp_buffers);

 fail_sp3:
	pci_free_consistent(to_pci_dev(dev), num_sp * sizeof(u64),
			    xhci->scratchpad->sp_array,
			    xhci->scratchpad->sp_dma);

 fail_sp2:
	kfree(xhci->scratchpad);
	xhci->scratchpad = NULL;

 fail_sp:
	return -ENOMEM;
}

static void scratchpad_free(struct xhci_hcd *xhci)
{
	int num_sp;
	int i;
	struct pci_dev	*pdev = to_pci_dev(xhci_to_hcd(xhci)->self.controller);

	if (!xhci->scratchpad)
		return;

	num_sp = HCS_MAX_SCRATCHPAD(xhci->hcs_params2);

	for (i = 0; i < num_sp; i++) {
		pci_free_consistent(pdev, xhci->page_size,
				    xhci->scratchpad->sp_buffers[i],
				    xhci->scratchpad->sp_dma_buffers[i]);
	}
	kfree(xhci->scratchpad->sp_dma_buffers);
	kfree(xhci->scratchpad->sp_buffers);
	pci_free_consistent(pdev, num_sp * sizeof(u64),
			    xhci->scratchpad->sp_array,
			    xhci->scratchpad->sp_dma);
	kfree(xhci->scratchpad);
	xhci->scratchpad = NULL;
}

739 740
void xhci_mem_cleanup(struct xhci_hcd *xhci)
{
741 742
	struct pci_dev	*pdev = to_pci_dev(xhci_to_hcd(xhci)->self.controller);
	int size;
743
	int i;
744 745 746

	/* Free the Event Ring Segment Table and the actual Event Ring */
	xhci_writel(xhci, 0, &xhci->ir_set->erst_size);
747 748
	xhci_write_64(xhci, 0, &xhci->ir_set->erst_base);
	xhci_write_64(xhci, 0, &xhci->ir_set->erst_dequeue);
749 750 751 752 753 754 755 756 757 758 759
	size = sizeof(struct xhci_erst_entry)*(xhci->erst.num_entries);
	if (xhci->erst.entries)
		pci_free_consistent(pdev, size,
				xhci->erst.entries, xhci->erst.erst_dma_addr);
	xhci->erst.entries = NULL;
	xhci_dbg(xhci, "Freed ERST\n");
	if (xhci->event_ring)
		xhci_ring_free(xhci, xhci->event_ring);
	xhci->event_ring = NULL;
	xhci_dbg(xhci, "Freed event ring\n");

760
	xhci_write_64(xhci, 0, &xhci->op_regs->cmd_ring);
761 762 763 764
	if (xhci->cmd_ring)
		xhci_ring_free(xhci, xhci->cmd_ring);
	xhci->cmd_ring = NULL;
	xhci_dbg(xhci, "Freed command ring\n");
765 766 767 768

	for (i = 1; i < MAX_HC_SLOTS; ++i)
		xhci_free_virt_device(xhci, i);

769 770 771 772
	if (xhci->segment_pool)
		dma_pool_destroy(xhci->segment_pool);
	xhci->segment_pool = NULL;
	xhci_dbg(xhci, "Freed segment pool\n");
773 774 775 776 777 778

	if (xhci->device_pool)
		dma_pool_destroy(xhci->device_pool);
	xhci->device_pool = NULL;
	xhci_dbg(xhci, "Freed device context pool\n");

779
	xhci_write_64(xhci, 0, &xhci->op_regs->dcbaa_ptr);
780 781 782 783
	if (xhci->dcbaa)
		pci_free_consistent(pdev, sizeof(*xhci->dcbaa),
				xhci->dcbaa, xhci->dcbaa->dma);
	xhci->dcbaa = NULL;
784

785 786
	xhci->page_size = 0;
	xhci->page_shift = 0;
787
	scratchpad_free(xhci);
788 789 790 791
}

int xhci_mem_init(struct xhci_hcd *xhci, gfp_t flags)
{
792 793
	dma_addr_t	dma;
	struct device	*dev = xhci_to_hcd(xhci)->self.controller;
794
	unsigned int	val, val2;
795
	u64		val_64;
796
	struct xhci_segment	*seg;
797 798 799 800 801 802 803 804 805 806 807 808 809 810 811 812 813 814 815 816 817 818 819 820 821 822 823 824 825 826 827 828
	u32 page_size;
	int i;

	page_size = xhci_readl(xhci, &xhci->op_regs->page_size);
	xhci_dbg(xhci, "Supported page size register = 0x%x\n", page_size);
	for (i = 0; i < 16; i++) {
		if ((0x1 & page_size) != 0)
			break;
		page_size = page_size >> 1;
	}
	if (i < 16)
		xhci_dbg(xhci, "Supported page size of %iK\n", (1 << (i+12)) / 1024);
	else
		xhci_warn(xhci, "WARN: no supported page size\n");
	/* Use 4K pages, since that's common and the minimum the HC supports */
	xhci->page_shift = 12;
	xhci->page_size = 1 << xhci->page_shift;
	xhci_dbg(xhci, "HCD page size set to %iK\n", xhci->page_size / 1024);

	/*
	 * Program the Number of Device Slots Enabled field in the CONFIG
	 * register with the max value of slots the HC can handle.
	 */
	val = HCS_MAX_SLOTS(xhci_readl(xhci, &xhci->cap_regs->hcs_params1));
	xhci_dbg(xhci, "// xHC can handle at most %d device slots.\n",
			(unsigned int) val);
	val2 = xhci_readl(xhci, &xhci->op_regs->config_reg);
	val |= (val2 & ~HCS_SLOTS_MASK);
	xhci_dbg(xhci, "// Setting Max device slots reg = 0x%x.\n",
			(unsigned int) val);
	xhci_writel(xhci, val, &xhci->op_regs->config_reg);

829 830 831 832 833 834 835 836 837 838
	/*
	 * Section 5.4.8 - doorbell array must be
	 * "physically contiguous and 64-byte (cache line) aligned".
	 */
	xhci->dcbaa = pci_alloc_consistent(to_pci_dev(dev),
			sizeof(*xhci->dcbaa), &dma);
	if (!xhci->dcbaa)
		goto fail;
	memset(xhci->dcbaa, 0, sizeof *(xhci->dcbaa));
	xhci->dcbaa->dma = dma;
839 840
	xhci_dbg(xhci, "// Device context base array address = 0x%llx (DMA), %p (virt)\n",
			(unsigned long long)xhci->dcbaa->dma, xhci->dcbaa);
841
	xhci_write_64(xhci, dma, &xhci->op_regs->dcbaa_ptr);
842

843 844 845 846 847 848 849 850
	/*
	 * Initialize the ring segment pool.  The ring must be a contiguous
	 * structure comprised of TRBs.  The TRBs must be 16 byte aligned,
	 * however, the command ring segment needs 64-byte aligned segments,
	 * so we pick the greater alignment need.
	 */
	xhci->segment_pool = dma_pool_create("xHCI ring segments", dev,
			SEGMENT_SIZE, 64, xhci->page_size);
851

852 853
	/* See Table 46 and Note on Figure 55 */
	xhci->device_pool = dma_pool_create("xHCI input/output contexts", dev,
854
			2112, 64, xhci->page_size);
855
	if (!xhci->segment_pool || !xhci->device_pool)
856 857 858 859 860 861
		goto fail;

	/* Set up the command ring to have one segments for now. */
	xhci->cmd_ring = xhci_ring_alloc(xhci, 1, true, flags);
	if (!xhci->cmd_ring)
		goto fail;
862 863 864
	xhci_dbg(xhci, "Allocated command ring at %p\n", xhci->cmd_ring);
	xhci_dbg(xhci, "First segment DMA is 0x%llx\n",
			(unsigned long long)xhci->cmd_ring->first_seg->dma);
865 866

	/* Set the address in the Command Ring Control register */
867 868 869
	val_64 = xhci_read_64(xhci, &xhci->op_regs->cmd_ring);
	val_64 = (val_64 & (u64) CMD_RING_RSVD_BITS) |
		(xhci->cmd_ring->first_seg->dma & (u64) ~CMD_RING_RSVD_BITS) |
870
		xhci->cmd_ring->cycle_state;
871 872
	xhci_dbg(xhci, "// Setting command ring address to 0x%x\n", val);
	xhci_write_64(xhci, val_64, &xhci->op_regs->cmd_ring);
873 874 875 876 877 878 879 880 881 882 883 884 885 886 887 888 889 890 891 892 893 894 895 896 897
	xhci_dbg_cmd_ptrs(xhci);

	val = xhci_readl(xhci, &xhci->cap_regs->db_off);
	val &= DBOFF_MASK;
	xhci_dbg(xhci, "// Doorbell array is located at offset 0x%x"
			" from cap regs base addr\n", val);
	xhci->dba = (void *) xhci->cap_regs + val;
	xhci_dbg_regs(xhci);
	xhci_print_run_regs(xhci);
	/* Set ir_set to interrupt register set 0 */
	xhci->ir_set = (void *) xhci->run_regs->ir_set;

	/*
	 * Event ring setup: Allocate a normal ring, but also setup
	 * the event ring segment table (ERST).  Section 4.9.3.
	 */
	xhci_dbg(xhci, "// Allocating event ring\n");
	xhci->event_ring = xhci_ring_alloc(xhci, ERST_NUM_SEGS, false, flags);
	if (!xhci->event_ring)
		goto fail;

	xhci->erst.entries = pci_alloc_consistent(to_pci_dev(dev),
			sizeof(struct xhci_erst_entry)*ERST_NUM_SEGS, &dma);
	if (!xhci->erst.entries)
		goto fail;
898 899
	xhci_dbg(xhci, "// Allocated event ring segment table at 0x%llx\n",
			(unsigned long long)dma);
900 901 902 903

	memset(xhci->erst.entries, 0, sizeof(struct xhci_erst_entry)*ERST_NUM_SEGS);
	xhci->erst.num_entries = ERST_NUM_SEGS;
	xhci->erst.erst_dma_addr = dma;
904
	xhci_dbg(xhci, "Set ERST to 0; private num segs = %i, virt addr = %p, dma addr = 0x%llx\n",
905
			xhci->erst.num_entries,
906 907
			xhci->erst.entries,
			(unsigned long long)xhci->erst.erst_dma_addr);
908 909 910 911

	/* set ring base address and size for each segment table entry */
	for (val = 0, seg = xhci->event_ring->first_seg; val < ERST_NUM_SEGS; val++) {
		struct xhci_erst_entry *entry = &xhci->erst.entries[val];
912
		entry->seg_addr = seg->dma;
913 914 915 916 917 918 919 920 921 922 923 924 925 926 927
		entry->seg_size = TRBS_PER_SEGMENT;
		entry->rsvd = 0;
		seg = seg->next;
	}

	/* set ERST count with the number of entries in the segment table */
	val = xhci_readl(xhci, &xhci->ir_set->erst_size);
	val &= ERST_SIZE_MASK;
	val |= ERST_NUM_SEGS;
	xhci_dbg(xhci, "// Write ERST size = %i to ir_set 0 (some bits preserved)\n",
			val);
	xhci_writel(xhci, val, &xhci->ir_set->erst_size);

	xhci_dbg(xhci, "// Set ERST entries to point to event ring.\n");
	/* set the segment table base address */
928 929
	xhci_dbg(xhci, "// Set ERST base address for ir_set 0 = 0x%llx\n",
			(unsigned long long)xhci->erst.erst_dma_addr);
930 931 932 933
	val_64 = xhci_read_64(xhci, &xhci->ir_set->erst_base);
	val_64 &= ERST_PTR_MASK;
	val_64 |= (xhci->erst.erst_dma_addr & (u64) ~ERST_PTR_MASK);
	xhci_write_64(xhci, val_64, &xhci->ir_set->erst_base);
934 935

	/* Set the event ring dequeue address */
936
	xhci_set_hc_event_deq(xhci);
937 938 939 940 941 942 943 944
	xhci_dbg(xhci, "Wrote ERST address to ir_set 0.\n");
	xhci_print_ir_set(xhci, xhci->ir_set, 0);

	/*
	 * XXX: Might need to set the Interrupter Moderation Register to
	 * something other than the default (~1ms minimum between interrupts).
	 * See section 5.5.1.2.
	 */
945 946 947
	init_completion(&xhci->addr_dev);
	for (i = 0; i < MAX_HC_SLOTS; ++i)
		xhci->devs[i] = 0;
948

949 950 951
	if (scratchpad_alloc(xhci, flags))
		goto fail;

952
	return 0;
953

954 955 956 957 958
fail:
	xhci_warn(xhci, "Couldn't initialize memory\n");
	xhci_mem_cleanup(xhci);
	return -ENOMEM;
}