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qemu / seabios-hppa / refs/heads/devel-btlb / . / src / hw / usb-xhci.c
blob: c35f2211983d4854dd7ae3078676fa3dd19e272d [file] [log] [blame]
// Code for handling XHCI "Super speed" USB controllers.
//
// Copyright (C) 2013 Gerd Hoffmann <kraxel@redhat.com>
// Copyright (C) 2014 Kevin O'Connor <kevin@koconnor.net>
//
// This file may be distributed under the terms of the GNU LGPLv3 license.
#include "config.h" // CONFIG_*
#include "malloc.h" // memalign_low
#include "memmap.h" // PAGE_SIZE
#include "output.h" // dprintf
#include "pcidevice.h" // foreachpci
#include "pci_ids.h" // PCI_CLASS_SERIAL_USB_XHCI
#include "pci_regs.h" // PCI_BASE_ADDRESS_0
#include "string.h" // memcpy
#include "usb.h" // struct usb_s
#include "usb-xhci.h" // struct ehci_qh
#include "util.h" // timer_calc
#include "x86.h" // readl
// --------------------------------------------------------------
// configuration
#define XHCI_RING_ITEMS 16
#define XHCI_RING_SIZE (XHCI_RING_ITEMS*sizeof(struct xhci_trb))
/*
* xhci_ring structs are allocated with XHCI_RING_SIZE alignment,
* then we can get it from a trb pointer (provided by evt ring).
*/
#define XHCI_RING(_trb) \
((struct xhci_ring*)((u32)(_trb) & ~(XHCI_RING_SIZE-1)))
// --------------------------------------------------------------
// bit definitions
#define XHCI_CMD_RS (1<<0)
#define XHCI_CMD_HCRST (1<<1)
#define XHCI_CMD_INTE (1<<2)
#define XHCI_CMD_HSEE (1<<3)
#define XHCI_CMD_LHCRST (1<<7)
#define XHCI_CMD_CSS (1<<8)
#define XHCI_CMD_CRS (1<<9)
#define XHCI_CMD_EWE (1<<10)
#define XHCI_CMD_EU3S (1<<11)
#define XHCI_STS_HCH (1<<0)
#define XHCI_STS_HSE (1<<2)
#define XHCI_STS_EINT (1<<3)
#define XHCI_STS_PCD (1<<4)
#define XHCI_STS_SSS (1<<8)
#define XHCI_STS_RSS (1<<9)
#define XHCI_STS_SRE (1<<10)
#define XHCI_STS_CNR (1<<11)
#define XHCI_STS_HCE (1<<12)
#define XHCI_PORTSC_CCS (1<<0)
#define XHCI_PORTSC_PED (1<<1)
#define XHCI_PORTSC_OCA (1<<3)
#define XHCI_PORTSC_PR (1<<4)
#define XHCI_PORTSC_PLS_SHIFT 5
#define XHCI_PORTSC_PLS_MASK 0xf
#define XHCI_PORTSC_PP (1<<9)
#define XHCI_PORTSC_SPEED_SHIFT 10
#define XHCI_PORTSC_SPEED_MASK 0xf
#define XHCI_PORTSC_SPEED_FULL (1<<10)
#define XHCI_PORTSC_SPEED_LOW (2<<10)
#define XHCI_PORTSC_SPEED_HIGH (3<<10)
#define XHCI_PORTSC_SPEED_SUPER (4<<10)
#define XHCI_PORTSC_PIC_SHIFT 14
#define XHCI_PORTSC_PIC_MASK 0x3
#define XHCI_PORTSC_LWS (1<<16)
#define XHCI_PORTSC_CSC (1<<17)
#define XHCI_PORTSC_PEC (1<<18)
#define XHCI_PORTSC_WRC (1<<19)
#define XHCI_PORTSC_OCC (1<<20)
#define XHCI_PORTSC_PRC (1<<21)
#define XHCI_PORTSC_PLC (1<<22)
#define XHCI_PORTSC_CEC (1<<23)
#define XHCI_PORTSC_CAS (1<<24)
#define XHCI_PORTSC_WCE (1<<25)
#define XHCI_PORTSC_WDE (1<<26)
#define XHCI_PORTSC_WOE (1<<27)
#define XHCI_PORTSC_DR (1<<30)
#define XHCI_PORTSC_WPR (1<<31)
#define TRB_C (1<<0)
#define TRB_TYPE_SHIFT 10
#define TRB_TYPE_MASK 0x3f
#define TRB_TYPE(t) (((t) >> TRB_TYPE_SHIFT) & TRB_TYPE_MASK)
#define TRB_EV_ED (1<<2)
#define TRB_TR_ENT (1<<1)
#define TRB_TR_ISP (1<<2)
#define TRB_TR_NS (1<<3)
#define TRB_TR_CH (1<<4)
#define TRB_TR_IOC (1<<5)
#define TRB_TR_IDT (1<<6)
#define TRB_TR_TBC_SHIFT 7
#define TRB_TR_TBC_MASK 0x3
#define TRB_TR_BEI (1<<9)
#define TRB_TR_TLBPC_SHIFT 16
#define TRB_TR_TLBPC_MASK 0xf
#define TRB_TR_FRAMEID_SHIFT 20
#define TRB_TR_FRAMEID_MASK 0x7ff
#define TRB_TR_SIA (1<<31)
#define TRB_TR_DIR (1<<16)
#define TRB_CR_SLOTID_SHIFT 24
#define TRB_CR_SLOTID_MASK 0xff
#define TRB_CR_EPID_SHIFT 16
#define TRB_CR_EPID_MASK 0x1f
#define TRB_CR_BSR (1<<9)
#define TRB_CR_DC (1<<9)
#define TRB_LK_TC (1<<1)
#define TRB_INTR_SHIFT 22
#define TRB_INTR_MASK 0x3ff
#define TRB_INTR(t) (((t).status >> TRB_INTR_SHIFT) & TRB_INTR_MASK)
typedef enum TRBType {
TRB_RESERVED = 0,
TR_NORMAL,
TR_SETUP,
TR_DATA,
TR_STATUS,
TR_ISOCH,
TR_LINK,
TR_EVDATA,
TR_NOOP,
CR_ENABLE_SLOT,
CR_DISABLE_SLOT,
CR_ADDRESS_DEVICE,
CR_CONFIGURE_ENDPOINT,
CR_EVALUATE_CONTEXT,
CR_RESET_ENDPOINT,
CR_STOP_ENDPOINT,
CR_SET_TR_DEQUEUE,
CR_RESET_DEVICE,
CR_FORCE_EVENT,
CR_NEGOTIATE_BW,
CR_SET_LATENCY_TOLERANCE,
CR_GET_PORT_BANDWIDTH,
CR_FORCE_HEADER,
CR_NOOP,
ER_TRANSFER = 32,
ER_COMMAND_COMPLETE,
ER_PORT_STATUS_CHANGE,
ER_BANDWIDTH_REQUEST,
ER_DOORBELL,
ER_HOST_CONTROLLER,
ER_DEVICE_NOTIFICATION,
ER_MFINDEX_WRAP,
} TRBType;
typedef enum TRBCCode {
CC_INVALID = 0,
CC_SUCCESS,
CC_DATA_BUFFER_ERROR,
CC_BABBLE_DETECTED,
CC_USB_TRANSACTION_ERROR,
CC_TRB_ERROR,
CC_STALL_ERROR,
CC_RESOURCE_ERROR,
CC_BANDWIDTH_ERROR,
CC_NO_SLOTS_ERROR,
CC_INVALID_STREAM_TYPE_ERROR,
CC_SLOT_NOT_ENABLED_ERROR,
CC_EP_NOT_ENABLED_ERROR,
CC_SHORT_PACKET,
CC_RING_UNDERRUN,
CC_RING_OVERRUN,
CC_VF_ER_FULL,
CC_PARAMETER_ERROR,
CC_BANDWIDTH_OVERRUN,
CC_CONTEXT_STATE_ERROR,
CC_NO_PING_RESPONSE_ERROR,
CC_EVENT_RING_FULL_ERROR,
CC_INCOMPATIBLE_DEVICE_ERROR,
CC_MISSED_SERVICE_ERROR,
CC_COMMAND_RING_STOPPED,
CC_COMMAND_ABORTED,
CC_STOPPED,
CC_STOPPED_LENGTH_INVALID,
CC_MAX_EXIT_LATENCY_TOO_LARGE_ERROR = 29,
CC_ISOCH_BUFFER_OVERRUN = 31,
CC_EVENT_LOST_ERROR,
CC_UNDEFINED_ERROR,
CC_INVALID_STREAM_ID_ERROR,
CC_SECONDARY_BANDWIDTH_ERROR,
CC_SPLIT_TRANSACTION_ERROR
} TRBCCode;
enum {
PLS_U0 = 0,
PLS_U1 = 1,
PLS_U2 = 2,
PLS_U3 = 3,
PLS_DISABLED = 4,
PLS_RX_DETECT = 5,
PLS_INACTIVE = 6,
PLS_POLLING = 7,
PLS_RECOVERY = 8,
PLS_HOT_RESET = 9,
PLS_COMPILANCE_MODE = 10,
PLS_TEST_MODE = 11,
PLS_RESUME = 15,
};
#define xhci_get_field(data, field) \
(((data) >> field##_SHIFT) & field##_MASK)
// --------------------------------------------------------------
// state structs
struct xhci_ring {
struct xhci_trb ring[XHCI_RING_ITEMS];
struct xhci_trb evt;
u32 eidx;
u32 nidx;
u32 cs;
struct mutex_s lock;
};
struct xhci_portmap {
u8 start;
u8 count;
};
struct usb_xhci_s {
struct usb_s usb;
/* devinfo */
u32 xcap;
u32 ports;
u32 slots;
u8 context64;
struct xhci_portmap usb2;
struct xhci_portmap usb3;
/* xhci registers */
struct xhci_caps *caps;
struct xhci_op *op;
struct xhci_pr *pr;
struct xhci_ir *ir;
struct xhci_db *db;
/* xhci data structures */
struct xhci_devlist *devs;
struct xhci_ring *cmds;
struct xhci_ring *evts;
struct xhci_er_seg *eseg;
};
struct xhci_pipe {
struct xhci_ring reqs;
struct usb_pipe pipe;
u32 slotid;
u32 epid;
void *buf;
int bufused;
};
// --------------------------------------------------------------
// tables
static const char *speed_name[16] = {
[ 0 ] = " - ",
[ 1 ] = "Full",
[ 2 ] = "Low",
[ 3 ] = "High",
[ 4 ] = "Super",
};
static const int speed_from_xhci[16] = {
[ 0 ] = -1,
[ 1 ] = USB_FULLSPEED,
[ 2 ] = USB_LOWSPEED,
[ 3 ] = USB_HIGHSPEED,
[ 4 ] = USB_SUPERSPEED,
[ 5 ... 15 ] = -1,
};
static const int speed_to_xhci[] = {
[ USB_FULLSPEED ] = 1,
[ USB_LOWSPEED ] = 2,
[ USB_HIGHSPEED ] = 3,
[ USB_SUPERSPEED ] = 4,
};
static int wait_bit(u32 *reg, u32 mask, int value, u32 timeout)
{
u32 end = timer_calc(timeout);
while ((readl(reg) & mask) != value) {
if (timer_check(end)) {
warn_timeout();
return -1;
}
yield();
}
return 0;
}
/****************************************************************
* Root hub
****************************************************************/
#define XHCI_TIME_POSTPOWER 20
// Check if device attached to port
static void
xhci_print_port_state(int loglevel, const char *prefix, u32 port, u32 portsc)
{
u32 pls = xhci_get_field(portsc, XHCI_PORTSC_PLS);
u32 speed = xhci_get_field(portsc, XHCI_PORTSC_SPEED);
dprintf(loglevel, "%s port #%d: 0x%08x,%s%s pls %d, speed %d [%s]\n",
prefix, port + 1, portsc,
(portsc & XHCI_PORTSC_PP) ? " powered," : "",
(portsc & XHCI_PORTSC_PED) ? " enabled," : "",
pls, speed, speed_name[speed]);
}
static int
xhci_hub_detect(struct usbhub_s *hub, u32 port)
{
struct usb_xhci_s *xhci = container_of(hub->cntl, struct usb_xhci_s, usb);
u32 portsc = readl(&xhci->pr[port].portsc);
return (portsc & XHCI_PORTSC_CCS) ? 1 : 0;
}
// Reset device on port
static int
xhci_hub_reset(struct usbhub_s *hub, u32 port)
{
struct usb_xhci_s *xhci = container_of(hub->cntl, struct usb_xhci_s, usb);
u32 portsc = readl(&xhci->pr[port].portsc);
if (!(portsc & XHCI_PORTSC_CCS))
// Device no longer connected?!
return -1;
switch (xhci_get_field(portsc, XHCI_PORTSC_PLS)) {
case PLS_U0:
// A USB3 port - controller automatically performs reset
break;
case PLS_POLLING:
// A USB2 port - perform device reset
xhci_print_port_state(3, __func__, port, portsc);
writel(&xhci->pr[port].portsc, portsc | XHCI_PORTSC_PR);
break;
default:
return -1;
}
// Wait for device to complete reset and be enabled
u32 end = timer_calc(100);
for (;;) {
portsc = readl(&xhci->pr[port].portsc);
if (!(portsc & XHCI_PORTSC_CCS))
// Device disconnected during reset
return -1;
if (portsc & XHCI_PORTSC_PED)
// Reset complete
break;
if (timer_check(end)) {
warn_timeout();
return -1;
}
yield();
}
int rc = speed_from_xhci[xhci_get_field(portsc, XHCI_PORTSC_SPEED)];
xhci_print_port_state(1, "XHCI", port, portsc);
return rc;
}
static int
xhci_hub_portmap(struct usbhub_s *hub, u32 vport)
{
struct usb_xhci_s *xhci = container_of(hub->cntl, struct usb_xhci_s, usb);
u32 pport = vport + 1;
if (vport + 1 >= xhci->usb3.start &&
vport + 1 < xhci->usb3.start + xhci->usb3.count)
pport = vport + 2 - xhci->usb3.start;
if (vport + 1 >= xhci->usb2.start &&
vport + 1 < xhci->usb2.start + xhci->usb2.count)
pport = vport + 2 - xhci->usb2.start;
return pport;
}
static void
xhci_hub_disconnect(struct usbhub_s *hub, u32 port)
{
// XXX - should turn the port power off.
}
static struct usbhub_op_s xhci_hub_ops = {
.detect = xhci_hub_detect,
.reset = xhci_hub_reset,
.portmap = xhci_hub_portmap,
.disconnect = xhci_hub_disconnect,
};
// Find any devices connected to the root hub.
static int
xhci_check_ports(struct usb_xhci_s *xhci)
{
// Wait for port power to stabilize.
msleep(XHCI_TIME_POSTPOWER);
struct usbhub_s hub;
memset(&hub, 0, sizeof(hub));
hub.cntl = &xhci->usb;
hub.portcount = xhci->ports;
hub.op = &xhci_hub_ops;
usb_enumerate(&hub);
return hub.devcount;
}
/****************************************************************
* Setup
****************************************************************/
static void
xhci_free_pipes(struct usb_xhci_s *xhci)
{
// XXX - should walk list of pipes and free unused pipes.
}
static void
configure_xhci(void *data)
{
struct usb_xhci_s *xhci = data;
u32 reg;
xhci->devs = memalign_high(64, sizeof(*xhci->devs) * (xhci->slots + 1));
xhci->eseg = memalign_high(64, sizeof(*xhci->eseg));
xhci->cmds = memalign_high(XHCI_RING_SIZE, sizeof(*xhci->cmds));
xhci->evts = memalign_high(XHCI_RING_SIZE, sizeof(*xhci->evts));
if (!xhci->devs || !xhci->cmds || !xhci->evts || !xhci->eseg) {
warn_noalloc();
goto fail;
}
memset(xhci->devs, 0, sizeof(*xhci->devs) * (xhci->slots + 1));
memset(xhci->cmds, 0, sizeof(*xhci->cmds));
memset(xhci->evts, 0, sizeof(*xhci->evts));
memset(xhci->eseg, 0, sizeof(*xhci->eseg));
reg = readl(&xhci->op->usbcmd);
if (reg & XHCI_CMD_RS) {
reg &= ~XHCI_CMD_RS;
writel(&xhci->op->usbcmd, reg);
if (wait_bit(&xhci->op->usbsts, XHCI_STS_HCH, XHCI_STS_HCH, 32) != 0)
goto fail;
}
dprintf(3, "%s: resetting\n", __func__);
writel(&xhci->op->usbcmd, XHCI_CMD_HCRST);
if (wait_bit(&xhci->op->usbcmd, XHCI_CMD_HCRST, 0, 1000) != 0)
goto fail;
if (wait_bit(&xhci->op->usbsts, XHCI_STS_CNR, 0, 1000) != 0)
goto fail;
writel(&xhci->op->config, xhci->slots);
writel(&xhci->op->dcbaap_low, (u32)xhci->devs);
writel(&xhci->op->dcbaap_high, 0);
writel(&xhci->op->crcr_low, (u32)xhci->cmds | 1);
writel(&xhci->op->crcr_high, 0);
xhci->cmds->cs = 1;
xhci->eseg->ptr_low = (u32)xhci->evts;
xhci->eseg->ptr_high = 0;
xhci->eseg->size = XHCI_RING_ITEMS;
writel(&xhci->ir->erstsz, 1);
writel(&xhci->ir->erdp_low, (u32)xhci->evts);
writel(&xhci->ir->erdp_high, 0);
writel(&xhci->ir->erstba_low, (u32)xhci->eseg);
writel(&xhci->ir->erstba_high, 0);
xhci->evts->cs = 1;
reg = readl(&xhci->caps->hcsparams2);
u32 spb = (reg >> 21 & 0x1f) << 5 | reg >> 27;
if (spb) {
dprintf(3, "%s: setup %d scratch pad buffers\n", __func__, spb);
u64 *spba = memalign_high(64, sizeof(*spba) * spb);
void *pad = memalign_high(PAGE_SIZE, PAGE_SIZE * spb);
if (!spba || !pad) {
warn_noalloc();
free(spba);
free(pad);
goto fail;
}
int i;
for (i = 0; i < spb; i++)
spba[i] = (u32)pad + (i * PAGE_SIZE);
xhci->devs[0].ptr_low = (u32)spba;
xhci->devs[0].ptr_high = 0;
}
reg = readl(&xhci->op->usbcmd);
reg |= XHCI_CMD_RS;
writel(&xhci->op->usbcmd, reg);
// Find devices
int count = xhci_check_ports(xhci);
xhci_free_pipes(xhci);
if (count)
// Success
return;
// No devices found - shutdown and free controller.
dprintf(1, "XHCI no devices found\n");
reg = readl(&xhci->op->usbcmd);
reg &= ~XHCI_CMD_RS;
writel(&xhci->op->usbcmd, reg);
wait_bit(&xhci->op->usbsts, XHCI_STS_HCH, XHCI_STS_HCH, 32);
fail:
free(xhci->eseg);
free(xhci->evts);
free(xhci->cmds);
free(xhci->devs);
free(xhci);
}
static struct usb_xhci_s*
xhci_controller_setup(void *baseaddr)
{
struct usb_xhci_s *xhci = malloc_high(sizeof(*xhci));
if (!xhci) {
warn_noalloc();
return NULL;
}
memset(xhci, 0, sizeof(*xhci));
xhci->caps = baseaddr;
xhci->op = baseaddr + readb(&xhci->caps->caplength);
xhci->pr = baseaddr + readb(&xhci->caps->caplength) + 0x400;
xhci->db = baseaddr + readl(&xhci->caps->dboff);
xhci->ir = baseaddr + readl(&xhci->caps->rtsoff) + 0x20;
u32 hcs1 = readl(&xhci->caps->hcsparams1);
u32 hcc = readl(&xhci->caps->hccparams);
xhci->ports = (hcs1 >> 24) & 0xff;
xhci->slots = hcs1 & 0xff;
xhci->xcap = ((hcc >> 16) & 0xffff) << 2;
xhci->context64 = (hcc & 0x04) ? 1 : 0;
xhci->usb.type = USB_TYPE_XHCI;
dprintf(1, "XHCI init: regs @ %p, %d ports, %d slots"
", %d byte contexts\n"
, xhci->caps, xhci->ports, xhci->slots
, xhci->context64 ? 64 : 32);
if (xhci->xcap) {
u32 off;
void *addr = baseaddr + xhci->xcap;
do {
struct xhci_xcap *xcap = addr;
u32 ports, name, cap = readl(&xcap->cap);
switch (cap & 0xff) {
case 0x02:
name = readl(&xcap->data[0]);
ports = readl(&xcap->data[1]);
u8 major = (cap >> 24) & 0xff;
u8 minor = (cap >> 16) & 0xff;
u8 count = (ports >> 8) & 0xff;
u8 start = (ports >> 0) & 0xff;
dprintf(1, "XHCI protocol %c%c%c%c %x.%02x"
", %d ports (offset %d), def %x\n"
, (name >> 0) & 0xff
, (name >> 8) & 0xff
, (name >> 16) & 0xff
, (name >> 24) & 0xff
, major, minor
, count, start
, ports >> 16);
if (name == 0x20425355 /* "USB " */) {
if (major == 2) {
xhci->usb2.start = start;
xhci->usb2.count = count;
}
if (major == 3) {
xhci->usb3.start = start;
xhci->usb3.count = count;
}
}
break;
default:
dprintf(1, "XHCI extcap 0x%x @ %p\n", cap & 0xff, addr);
break;
}
off = (cap >> 8) & 0xff;
addr += off << 2;
} while (off > 0);
}
u32 pagesize = readl(&xhci->op->pagesize);
if (PAGE_SIZE != (pagesize<<12)) {
dprintf(1, "XHCI driver does not support page size code %d\n"
, pagesize<<12);
free(xhci);
return NULL;
}
return xhci;
}
static void
xhci_controller_setup_pci(struct pci_device *pci)
{
struct usb_xhci_s *xhci;
void *baseaddr;
baseaddr = pci_enable_membar(pci, PCI_BASE_ADDRESS_0);
if (!baseaddr)
return;
dprintf(1, "PCI: XHCI at %pP (mmio %p)\n", pci, baseaddr);
pci_enable_busmaster(pci);
xhci = xhci_controller_setup(baseaddr);
if (!xhci)
return;
xhci->usb.pci = pci;
run_thread(configure_xhci, xhci);
}
static void
xhci_controller_setup_acpi(struct acpi_device *dev)
{
struct usb_xhci_s *xhci;
u64 mem, unused;
void *baseaddr;
if (acpi_dsdt_find_mem(dev, &mem, &unused) < 0)
return;
if (mem >= 0x100000000ll)
return;
baseaddr = (void*)(u32)mem;
dprintf(1, "ACPI: XHCI at mmio %p\n", baseaddr);
xhci = xhci_controller_setup(baseaddr);
if (!xhci)
return;
xhci->usb.mmio = baseaddr;
run_thread(configure_xhci, xhci);
}
void
xhci_setup(void)
{
if (! CONFIG_USB_XHCI)
return;
struct pci_device *pci;
foreachpci(pci) {
if (pci_classprog(pci) == PCI_CLASS_SERIAL_USB_XHCI)
xhci_controller_setup_pci(pci);
}
u16 xhci_eisaid = 0x0d10;
struct acpi_device *dev;
for (dev = acpi_dsdt_find_eisaid(NULL, xhci_eisaid);
dev != NULL;
dev = acpi_dsdt_find_eisaid(dev, xhci_eisaid)) {
xhci_controller_setup_acpi(dev);
}
}
/****************************************************************
* End point communication
****************************************************************/
// Signal the hardware to process events on a TRB ring
static void xhci_doorbell(struct usb_xhci_s *xhci, u32 slotid, u32 value)
{
dprintf(5, "%s: slotid %d, epid %d\n", __func__, slotid, value);
struct xhci_db *db = xhci->db;
void *addr = &db[slotid].doorbell;
writel(addr, value);
}
// Dequeue events on the XHCI command ring generated by the hardware
static void xhci_process_events(struct usb_xhci_s *xhci)
{
struct xhci_ring *evts = xhci->evts;
for (;;) {
/* check for event */
u32 nidx = evts->nidx;
u32 cs = evts->cs;
struct xhci_trb *etrb = evts->ring + nidx;
u32 control = etrb->control;
if ((control & TRB_C) != (cs ? 1 : 0))
return;
/* process event */
u32 evt_type = TRB_TYPE(control);
u32 evt_cc = (etrb->status >> 24) & 0xff;
switch (evt_type) {
case ER_TRANSFER:
case ER_COMMAND_COMPLETE:
{
struct xhci_trb *rtrb = (void*)etrb->ptr_low;
struct xhci_ring *ring = XHCI_RING(rtrb);
struct xhci_trb *evt = &ring->evt;
u32 eidx = rtrb - ring->ring + 1;
dprintf(5, "%s: ring %p [trb %p, evt %p, type %d, eidx %d, cc %d]\n",
__func__, ring, rtrb, evt, evt_type, eidx, evt_cc);
memcpy(evt, etrb, sizeof(*etrb));
ring->eidx = eidx;
break;
}
case ER_PORT_STATUS_CHANGE:
{
u32 port = ((etrb->ptr_low >> 24) & 0xff) - 1;
// Read status, and clear port status change bits
u32 portsc = readl(&xhci->pr[port].portsc);
u32 pclear = (((portsc & ~(XHCI_PORTSC_PED|XHCI_PORTSC_PR))
& ~(XHCI_PORTSC_PLS_MASK<<XHCI_PORTSC_PLS_SHIFT))
| (1<<XHCI_PORTSC_PLS_SHIFT));
writel(&xhci->pr[port].portsc, pclear);
xhci_print_port_state(3, __func__, port, portsc);
break;
}
default:
dprintf(1, "%s: unknown event, type %d, cc %d\n",
__func__, evt_type, evt_cc);
break;
}
/* move ring index, notify xhci */
nidx++;
if (nidx == XHCI_RING_ITEMS) {
nidx = 0;
cs = cs ? 0 : 1;
evts->cs = cs;
}
evts->nidx = nidx;
struct xhci_ir *ir = xhci->ir;
u32 erdp = (u32)(evts->ring + nidx);
writel(&ir->erdp_low, erdp);
writel(&ir->erdp_high, 0);
}
}
// Check if a ring has any pending TRBs
static int xhci_ring_busy(struct xhci_ring *ring)
{
u32 eidx = ring->eidx;
u32 nidx = ring->nidx;
return (eidx != nidx);
}
// Wait for a ring to empty (all TRBs processed by hardware)
static int xhci_event_wait(struct usb_xhci_s *xhci,
struct xhci_ring *ring,
u32 timeout)
{
u32 end = timer_calc(timeout);
for (;;) {
xhci_process_events(xhci);
if (!xhci_ring_busy(ring)) {
u32 status = ring->evt.status;
return (status >> 24) & 0xff;
}
if (timer_check(end)) {
warn_timeout();
return -1;
}
yield();
}
}
// Add a TRB to the given ring
static void xhci_trb_fill(struct xhci_ring *ring
, void *data, u32 xferlen, u32 flags)
{
struct xhci_trb *dst = &ring->ring[ring->nidx];
if (flags & TRB_TR_IDT) {
memcpy(&dst->ptr_low, data, xferlen);
} else {
dst->ptr_low = (u32)data;
dst->ptr_high = 0;
}
dst->status = xferlen;
dst->control = flags | (ring->cs ? TRB_C : 0);
}
// Queue a TRB onto a ring, wrapping ring as needed
static void xhci_trb_queue(struct xhci_ring *ring,
void *data, u32 xferlen, u32 flags)
{
if (ring->nidx >= ARRAY_SIZE(ring->ring) - 1) {
xhci_trb_fill(ring, ring->ring, 0, (TR_LINK << 10) | TRB_LK_TC);
ring->nidx = 0;
ring->cs ^= 1;
dprintf(5, "%s: ring %p [linked]\n", __func__, ring);
}
xhci_trb_fill(ring, data, xferlen, flags);
ring->nidx++;
dprintf(5, "%s: ring %p [nidx %d, len %d]\n",
__func__, ring, ring->nidx, xferlen);
}
// Submit a command to the xhci controller ring
static int xhci_cmd_submit(struct usb_xhci_s *xhci, struct xhci_inctx *inctx
, u32 flags)
{
if (inctx) {
struct xhci_slotctx *slot = (void*)&inctx[1 << xhci->context64];
u32 port = ((slot->ctx[1] >> 16) & 0xff) - 1;
u32 portsc = readl(&xhci->pr[port].portsc);
if (!(portsc & XHCI_PORTSC_CCS)) {
// Device no longer connected?!
xhci_print_port_state(1, __func__, port, portsc);
return -1;
}
}
mutex_lock(&xhci->cmds->lock);
xhci_trb_queue(xhci->cmds, inctx, 0, flags);
xhci_doorbell(xhci, 0, 0);
int rc = xhci_event_wait(xhci, xhci->cmds, 1000);
mutex_unlock(&xhci->cmds->lock);
return rc;
}
static int xhci_cmd_enable_slot(struct usb_xhci_s *xhci)
{
dprintf(3, "%s:\n", __func__);
int cc = xhci_cmd_submit(xhci, NULL, CR_ENABLE_SLOT << 10);
if (cc != CC_SUCCESS)
return -1;
return (xhci->cmds->evt.control >> 24) & 0xff;
}
static int xhci_cmd_disable_slot(struct usb_xhci_s *xhci, u32 slotid)
{
dprintf(3, "%s: slotid %d\n", __func__, slotid);
return xhci_cmd_submit(xhci, NULL, (CR_DISABLE_SLOT << 10) | (slotid << 24));
}
static int xhci_cmd_address_device(struct usb_xhci_s *xhci, u32 slotid
, struct xhci_inctx *inctx)
{
dprintf(3, "%s: slotid %d\n", __func__, slotid);
return xhci_cmd_submit(xhci, inctx
, (CR_ADDRESS_DEVICE << 10) | (slotid << 24));
}
static int xhci_cmd_configure_endpoint(struct usb_xhci_s *xhci, u32 slotid
, struct xhci_inctx *inctx)
{
dprintf(3, "%s: slotid %d, add 0x%x, del 0x%x\n", __func__,
slotid, inctx->add, inctx->del);
return xhci_cmd_submit(xhci, inctx
, (CR_CONFIGURE_ENDPOINT << 10) | (slotid << 24));
}
static int xhci_cmd_evaluate_context(struct usb_xhci_s *xhci, u32 slotid
, struct xhci_inctx *inctx)
{
dprintf(3, "%s: slotid %d, add 0x%x, del 0x%x\n", __func__,
slotid, inctx->add, inctx->del);
return xhci_cmd_submit(xhci, inctx
, (CR_EVALUATE_CONTEXT << 10) | (slotid << 24));
}
static struct xhci_inctx *
xhci_alloc_inctx(struct usbdevice_s *usbdev, int maxepid)
{
struct usb_xhci_s *xhci = container_of(
usbdev->hub->cntl, struct usb_xhci_s, usb);
int size = (sizeof(struct xhci_inctx) * 33) << xhci->context64;
struct xhci_inctx *in = memalign_tmphigh(2048 << xhci->context64, size);
if (!in) {
warn_noalloc();
return NULL;
}
memset(in, 0, size);
struct xhci_slotctx *slot = (void*)&in[1 << xhci->context64];
slot->ctx[0] |= maxepid << 27; // context entries
slot->ctx[0] |= speed_to_xhci[usbdev->speed] << 20;
// Set high-speed hub flags.
struct usbdevice_s *hubdev = usbdev->hub->usbdev;
if (hubdev) {
if (usbdev->speed == USB_LOWSPEED || usbdev->speed == USB_FULLSPEED) {
struct xhci_pipe *hpipe = container_of(
hubdev->defpipe, struct xhci_pipe, pipe);
if (hubdev->speed == USB_HIGHSPEED) {
slot->ctx[2] |= hpipe->slotid;
slot->ctx[2] |= (usbdev->port+1) << 8;
} else {
struct xhci_slotctx *hslot = (void*)xhci->devs[hpipe->slotid].ptr_low;
slot->ctx[2] = hslot->ctx[2];
}
}
u32 route = 0;
while (usbdev->hub->usbdev) {
route <<= 4;
route |= (usbdev->port+1) & 0xf;
usbdev = usbdev->hub->usbdev;
}
slot->ctx[0] |= route;
}
slot->ctx[1] |= (usbdev->port+1) << 16;
return in;
}
static int xhci_config_hub(struct usbhub_s *hub)
{
struct usb_xhci_s *xhci = container_of(
hub->cntl, struct usb_xhci_s, usb);
struct xhci_pipe *pipe = container_of(
hub->usbdev->defpipe, struct xhci_pipe, pipe);
struct xhci_slotctx *hdslot = (void*)xhci->devs[pipe->slotid].ptr_low;
if ((hdslot->ctx[3] >> 27) == 3)
// Already configured
return 0;
struct xhci_inctx *in = xhci_alloc_inctx(hub->usbdev, 1);
if (!in)
return -1;
in->add = 0x01;
struct xhci_slotctx *slot = (void*)&in[1 << xhci->context64];
slot->ctx[0] |= 1 << 26;
slot->ctx[1] |= hub->portcount << 24;
int cc = xhci_cmd_configure_endpoint(xhci, pipe->slotid, in);
free(in);
if (cc != CC_SUCCESS) {
dprintf(1, "%s: configure hub: failed (cc %d)\n", __func__, cc);
return -1;
}
return 0;
}
static struct usb_pipe *
xhci_alloc_pipe(struct usbdevice_s *usbdev
, struct usb_endpoint_descriptor *epdesc)
{
u8 eptype = epdesc->bmAttributes & USB_ENDPOINT_XFERTYPE_MASK;
struct usb_xhci_s *xhci = container_of(
usbdev->hub->cntl, struct usb_xhci_s, usb);
struct xhci_pipe *pipe;
u32 epid;
if (epdesc->bEndpointAddress == 0) {
epid = 1;
} else {
epid = (epdesc->bEndpointAddress & 0x0f) * 2;
epid += (epdesc->bEndpointAddress & USB_DIR_IN) ? 1 : 0;
}
if (eptype == USB_ENDPOINT_XFER_CONTROL)
pipe = memalign_high(XHCI_RING_SIZE, sizeof(*pipe));
else
pipe = memalign_low(XHCI_RING_SIZE, sizeof(*pipe));
if (!pipe) {
warn_noalloc();
return NULL;
}
memset(pipe, 0, sizeof(*pipe));
usb_desc2pipe(&pipe->pipe, usbdev, epdesc);
pipe->epid = epid;
pipe->reqs.cs = 1;
if (eptype == USB_ENDPOINT_XFER_INT) {
pipe->buf = malloc_high(pipe->pipe.maxpacket);
if (!pipe->buf) {
warn_noalloc();
free(pipe);
return NULL;
}
}
// Allocate input context and initialize endpoint info.
struct xhci_inctx *in = xhci_alloc_inctx(usbdev, epid);
if (!in)
goto fail;
in->add = 0x01 | (1 << epid);
struct xhci_epctx *ep = (void*)&in[(pipe->epid+1) << xhci->context64];
if (eptype == USB_ENDPOINT_XFER_INT)
ep->ctx[0] = (usb_get_period(usbdev, epdesc) + 3) << 16;
ep->ctx[1] |= eptype << 3;
if (epdesc->bEndpointAddress & USB_DIR_IN
|| eptype == USB_ENDPOINT_XFER_CONTROL)
ep->ctx[1] |= 1 << 5;
ep->ctx[1] |= pipe->pipe.maxpacket << 16;
ep->deq_low = (u32)&pipe->reqs.ring[0];
ep->deq_low |= 1; // dcs
ep->length = pipe->pipe.maxpacket;
dprintf(3, "%s: usbdev %p, ring %p, slotid %d, epid %d\n", __func__,
usbdev, &pipe->reqs, pipe->slotid, pipe->epid);
if (pipe->epid == 1) {
if (usbdev->hub->usbdev) {
// Make sure parent hub is configured.
int ret = xhci_config_hub(usbdev->hub);
if (ret)
goto fail;
}
// Enable slot.
u32 size = (sizeof(struct xhci_slotctx) * 32) << xhci->context64;
struct xhci_slotctx *dev = memalign_high(1024 << xhci->context64, size);
if (!dev) {
warn_noalloc();
goto fail;
}
int slotid = xhci_cmd_enable_slot(xhci);
if (slotid < 0) {
dprintf(1, "%s: enable slot: failed\n", __func__);
free(dev);
goto fail;
}
dprintf(3, "%s: enable slot: got slotid %d\n", __func__, slotid);
memset(dev, 0, size);
xhci->devs[slotid].ptr_low = (u32)dev;
xhci->devs[slotid].ptr_high = 0;
// Send set_address command.
int cc = xhci_cmd_address_device(xhci, slotid, in);
if (cc != CC_SUCCESS) {
dprintf(1, "%s: address device: failed (cc %d)\n", __func__, cc);
cc = xhci_cmd_disable_slot(xhci, slotid);
if (cc != CC_SUCCESS) {
dprintf(1, "%s: disable failed (cc %d)\n", __func__, cc);
goto fail;
}
xhci->devs[slotid].ptr_low = 0;
free(dev);
goto fail;
}
pipe->slotid = slotid;
} else {
struct xhci_pipe *defpipe = container_of(
usbdev->defpipe, struct xhci_pipe, pipe);
pipe->slotid = defpipe->slotid;
// Send configure command.
int cc = xhci_cmd_configure_endpoint(xhci, pipe->slotid, in);
if (cc != CC_SUCCESS) {
dprintf(1, "%s: configure endpoint: failed (cc %d)\n", __func__, cc);
goto fail;
}
}
free(in);
return &pipe->pipe;
fail:
free(pipe->buf);
free(pipe);
free(in);
return NULL;
}
struct usb_pipe *
xhci_realloc_pipe(struct usbdevice_s *usbdev, struct usb_pipe *upipe
, struct usb_endpoint_descriptor *epdesc)
{
if (!CONFIG_USB_XHCI)
return NULL;
if (!epdesc) {
usb_add_freelist(upipe);
return NULL;
}
if (!upipe)
return xhci_alloc_pipe(usbdev, epdesc);
u8 eptype = epdesc->bmAttributes & USB_ENDPOINT_XFERTYPE_MASK;
int oldmaxpacket = upipe->maxpacket;
usb_desc2pipe(upipe, usbdev, epdesc);
struct xhci_pipe *pipe = container_of(upipe, struct xhci_pipe, pipe);
struct usb_xhci_s *xhci = container_of(
pipe->pipe.cntl, struct usb_xhci_s, usb);
dprintf(3, "%s: usbdev %p, ring %p, slotid %d, epid %d\n", __func__,
usbdev, &pipe->reqs, pipe->slotid, pipe->epid);
if (eptype != USB_ENDPOINT_XFER_CONTROL || upipe->maxpacket == oldmaxpacket)
return upipe;
// maxpacket has changed on control endpoint - update controller.
dprintf(1, "%s: reconf ctl endpoint pkt size: %d -> %d\n",
__func__, oldmaxpacket, pipe->pipe.maxpacket);
struct xhci_inctx *in = xhci_alloc_inctx(usbdev, 1);
if (!in)
return upipe;
in->add = (1 << 1);
struct xhci_epctx *ep = (void*)&in[2 << xhci->context64];
ep->ctx[1] |= (pipe->pipe.maxpacket << 16);
int cc = xhci_cmd_evaluate_context(xhci, pipe->slotid, in);
if (cc != CC_SUCCESS) {
dprintf(1, "%s: reconf ctl endpoint: failed (cc %d)\n",
__func__, cc);
}
free(in);
return upipe;
}
// Submit a USB "setup" message request to the pipe's ring
static void xhci_xfer_setup(struct xhci_pipe *pipe, int dir, void *cmd
, void *data, int datalen)
{
struct usb_xhci_s *xhci = container_of(
pipe->pipe.cntl, struct usb_xhci_s, usb);
xhci_trb_queue(&pipe->reqs, cmd, USB_CONTROL_SETUP_SIZE
, (TR_SETUP << 10) | TRB_TR_IDT
| ((datalen ? (dir ? 3 : 2) : 0) << 16));
if (datalen)
xhci_trb_queue(&pipe->reqs, data, datalen, (TR_DATA << 10)
| ((dir ? 1 : 0) << 16));
xhci_trb_queue(&pipe->reqs, NULL, 0, (TR_STATUS << 10) | TRB_TR_IOC
| ((dir ? 0 : 1) << 16));
xhci_doorbell(xhci, pipe->slotid, pipe->epid);
}
// Submit a USB transfer request to the pipe's ring
static void xhci_xfer_normal(struct xhci_pipe *pipe,
void *data, int datalen)
{
struct usb_xhci_s *xhci = container_of(
pipe->pipe.cntl, struct usb_xhci_s, usb);
xhci_trb_queue(&pipe->reqs, data, datalen, (TR_NORMAL << 10) | TRB_TR_IOC);
xhci_doorbell(xhci, pipe->slotid, pipe->epid);
}
int
xhci_send_pipe(struct usb_pipe *p, int dir, const void *cmd
, void *data, int datalen)
{
if (!CONFIG_USB_XHCI)
return -1;
struct xhci_pipe *pipe = container_of(p, struct xhci_pipe, pipe);
struct usb_xhci_s *xhci = container_of(
pipe->pipe.cntl, struct usb_xhci_s, usb);
if (cmd) {
const struct usb_ctrlrequest *req = cmd;
if (req->bRequest == USB_REQ_SET_ADDRESS)
// Set address command sent during xhci_alloc_pipe.
return 0;
xhci_xfer_setup(pipe, dir, (void*)req, data, datalen);
} else {
xhci_xfer_normal(pipe, data, datalen);
}
int cc = xhci_event_wait(xhci, &pipe->reqs, usb_xfer_time(p, datalen));
if (cc != CC_SUCCESS) {
dprintf(1, "%s: xfer failed (cc %d)\n", __func__, cc);
return -1;
}
return 0;
}
int VISIBLE32FLAT
xhci_poll_intr(struct usb_pipe *p, void *data)
{
if (!CONFIG_USB_XHCI)
return -1;
struct xhci_pipe *pipe = container_of(p, struct xhci_pipe, pipe);
struct usb_xhci_s *xhci = container_of(
pipe->pipe.cntl, struct usb_xhci_s, usb);
u32 len = pipe->pipe.maxpacket;
void *buf = pipe->buf;
int bufused = pipe->bufused;
if (!bufused) {
xhci_xfer_normal(pipe, buf, len);
bufused = 1;
pipe->bufused = bufused;
return -1;
}
xhci_process_events(xhci);
if (xhci_ring_busy(&pipe->reqs))
return -1;
dprintf(5, "%s: st %x ct %x [ %p <= %p / %d ]\n", __func__,
pipe->reqs.evt.status,
pipe->reqs.evt.control,
data, buf, len);
memcpy(data, buf, len);
xhci_xfer_normal(pipe, buf, len);
return 0;
}