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coreboot-kgpe-d16/payloads/libpayload/drivers/usb/dwc2.c
Julius Werner e8a8a00342 libpayload: usb: dwc2: Always return 'size' transferred bytes for OUT 
Seems like our transferred bytes calculation for OUT transfers that span
more than one packet had been wrong, and we just got lucky that we never
noticed it before. The HCTSIZ.xfersize register field we're reading only
counts bytes transferred by the last packet we sent.

OUT endpoints cannot have short transfers -- every transfer should
either finish all bytes we wanted to send or end in a proper error
condition. Therefore, in the absence of an error we can just conclude
that all input bytes have been transferred.

BRANCH=veyron
BUG=chrome-os-partner:35525
TEST=SMSC95xx netboot on Jerry now works.

Change-Id: I57349e697c428df6b56e2f6f62e87652ef1e7a94
Signed-off-by: Patrick Georgi <patrick@georgi-clan.de>
Original-Commit-Id: 0abee13b6d89dec12c6fff581ece1836393c7703
Original-Change-Id: Id0a127e6919f5786ba05218277705dda1067b8c3
Original-Signed-off-by: Julius Werner <jwerner@chromium.org>
Original-Reviewed-on: https://chromium-review.googlesource.com/293956
Original-Reviewed-by: yunzhi li <lyz@rock-chips.com>
Original-Reviewed-by: David Hendricks <dhendrix@chromium.org>
Reviewed-on: http://review.coreboot.org/11404
Tested-by: build bot (Jenkins)
Reviewed-by: Stefan Reinauer <stefan.reinauer@coreboot.org>
2015-08-28 06:46:19 +00:00

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/*
* This file is part of the coreboot project.
*
* Copyright (C) 2014 Rockchip Electronics
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; version 2 of the License.
*
* 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.
*/
#include <libpayload.h>
#include <arch/cache.h>
#include "dwc2.h"
#include "dwc2_private.h"
static void dummy(hci_t *controller)
{
}
static void dwc2_reinit(hci_t *controller)
{
dwc2_reg_t *reg = DWC2_REG(controller);
gusbcfg_t gusbcfg = { .d32 = 0 };
grstctl_t grstctl = { .d32 = 0 };
gintsts_t gintsts = { .d32 = 0 };
gahbcfg_t gahbcfg = { .d32 = 0 };
grxfsiz_t grxfsiz = { .d32 = 0 };
ghwcfg3_t hwcfg3 = { .d32 = 0 };
hcintmsk_t hcintmsk = { .d32 = 0 };
gtxfsiz_t gnptxfsiz = { .d32 = 0 };
gtxfsiz_t hptxfsiz = { .d32 = 0 };
const int timeout = 10000;
int i, fifo_blocks, tx_blocks;
/* Wait for AHB idle */
for (i = 0; i < timeout; i++) {
udelay(1);
grstctl.d32 = readl(&reg->core.grstctl);
if (grstctl.ahbidle)
break;
}
if (i == timeout)
fatal("DWC2 Init error AHB Idle\n");
/* Restart the Phy Clock */
writel(0x0, &reg->pcgr.pcgcctl);
/* Core soft reset */
grstctl.csftrst = 1;
writel(grstctl.d32, &reg->core.grstctl);
for (i = 0; i < timeout; i++) {
udelay(1);
grstctl.d32 = readl(&reg->core.grstctl);
if (!grstctl.csftrst)
break;
}
if (i == timeout)
fatal("DWC2 Init error reset fail\n");
/* Set 16bit PHY if & Force host mode */
gusbcfg.d32 = readl(&reg->core.gusbcfg);
gusbcfg.phyif = 1;
gusbcfg.forcehstmode = 1;
gusbcfg.forcedevmode = 0;
writel(gusbcfg.d32, &reg->core.gusbcfg);
/* Wait for force host mode effect, it may takes 100ms */
for (i = 0; i < timeout; i++) {
udelay(10);
gintsts.d32 = readl(&reg->core.gintsts);
if (gintsts.curmod)
break;
}
if (i == timeout)
fatal("DWC2 Init error force host mode fail\n");
/*
* Config FIFO
* The non-periodic tx fifo and rx fifo share one continuous
* piece of IP-internal SRAM.
*/
/*
* Read total data FIFO depth from HWCFG3
* this value is in terms of 32-bit words
*/
hwcfg3.d32 = readl(&reg->core.ghwcfg3);
/*
* Reserve 2 spaces for the status entries of received packets
* and 2 spaces for bulk and control OUT endpoints. Calculate how
* many blocks can be alloted, assume largest packet size is 512.
* 16 locations reserved for periodic TX .
*/
fifo_blocks = (hwcfg3.dfifodepth - 4 - 16) / (512 / 4);
tx_blocks = fifo_blocks / 2;
grxfsiz.rxfdep = (fifo_blocks - tx_blocks) * (512 / 4) + 4;
writel(grxfsiz.d32, &reg->core.grxfsiz);
gnptxfsiz.txfstaddr = grxfsiz.rxfdep;
gnptxfsiz.txfdep = tx_blocks * (512 / 4);
writel(gnptxfsiz.d32, &reg->core.gnptxfsiz);
hptxfsiz.txfstaddr = gnptxfsiz.txfstaddr + gnptxfsiz.txfdep;
hptxfsiz.txfdep = 16;
writel(hptxfsiz.d32, &reg->core.hptxfsiz);
/* Init host channels */
hcintmsk.xfercomp = 1;
hcintmsk.xacterr = 1;
hcintmsk.stall = 1;
hcintmsk.chhltd = 1;
hcintmsk.bblerr = 1;
for (i = 0; i < MAX_EPS_CHANNELS; i++)
writel(hcintmsk.d32, &reg->host.hchn[i].hcintmaskn);
/* Unmask interrupt and configure DMA mode */
gahbcfg.glblintrmsk = 1;
gahbcfg.hbstlen = DMA_BURST_INCR8;
gahbcfg.dmaen = 1;
writel(gahbcfg.d32, &reg->core.gahbcfg);
DWC2_INST(controller)->hprt0 = &reg->host.hprt;
usb_debug("DWC2 init finished!\n");
}
static void dwc2_shutdown(hci_t *controller)
{
detach_controller(controller);
free(DWC2_INST(controller)->dma_buffer);
free(DWC2_INST(controller));
free(controller);
}
/* Test root port device connect status */
static int dwc2_disconnected(hci_t *controller)
{
dwc2_reg_t *reg = DWC2_REG(controller);
hprt_t hprt;
hprt.d32 = readl(&reg->host.hprt);
return !(hprt.prtena && hprt.prtconnsts);
}
/*
* This function returns the actual transfer length when the transfer succeeded
* or an error code if the transfer failed
*/
static int
wait_for_complete(endpoint_t *ep, uint32_t ch_num)
{
hcint_t hcint;
hcchar_t hcchar;
hctsiz_t hctsiz;
dwc2_reg_t *reg = DWC2_REG(ep->dev->controller);
int timeout = 600000; /* time out after 600000 * 5us == 3s */
/*
* TODO: We should take care of up to three times of transfer error
* retry here, according to the USB 2.0 spec 4.5.2
*/
do {
udelay(5);
hcint.d32 = readl(&reg->host.hchn[ch_num].hcintn);
hctsiz.d32 = readl(&reg->host.hchn[ch_num].hctsizn);
if (hcint.chhltd) {
writel(hcint.d32, &reg->host.hchn[ch_num].hcintn);
if (hcint.xfercomp || hcint.ack)
return hctsiz.xfersize;
else if (hcint.nak || hcint.frmovrun)
return -HCSTAT_NAK;
else if (hcint.xacterr)
return -HCSTAT_XFERERR;
else if (hcint.bblerr)
return -HCSTAT_BABBLE;
else if (hcint.stall)
return -HCSTAT_STALL;
else if (hcint.nyet)
return -HCSTAT_NYET;
else
return -HCSTAT_UNKNOW;
}
if (dwc2_disconnected(ep->dev->controller))
return -HCSTAT_DISCONNECTED;
} while (timeout--);
/* Release the channel when hit timeout condition */
hcchar.d32 = readl(&reg->host.hchn[ch_num].hccharn);
if (hcchar.chen) {
/*
* Programming the HCCHARn register with the chdis and
* chena bits set to 1 at the same time to disable the
* channel and the core will generate a channel halted
* interrupt.
*/
hcchar.chdis = 1;
writel(hcchar.d32, &reg->host.hchn[ch_num].hccharn);
do {
hcchar.d32 = readl(&reg->host.hchn[ch_num].hccharn);
} while (hcchar.chen);
}
/* Clear all pending interrupt flags */
hcint.d32 = ~0;
writel(hcint.d32, &reg->host.hchn[ch_num].hcintn);
return -HCSTAT_TIMEOUT;
}
static int
dwc2_do_xfer(endpoint_t *ep, int size, int pid, ep_dir_t dir,
uint32_t ch_num, u8 *data_buf, int *short_pkt)
{
uint32_t do_copy;
int ret;
uint32_t packet_cnt;
uint32_t packet_size;
uint32_t transferred = 0;
uint32_t inpkt_length;
hctsiz_t hctsiz = { .d32 = 0 };
hcchar_t hcchar = { .d32 = 0 };
void *aligned_buf;
dwc2_reg_t *reg = DWC2_REG(ep->dev->controller);
packet_size = ep->maxpacketsize;
packet_cnt = ALIGN_UP(size, packet_size) / packet_size;
inpkt_length = packet_cnt * packet_size;
/* At least 1 packet should be programed */
packet_cnt = (packet_cnt == 0) ? 1 : packet_cnt;
/*
* For an IN, this field is the buffer size that the application has
* reserved for the transfer. The application should program this field
* as integer multiple of the maximum packet size for IN transactions.
*/
hctsiz.xfersize = (dir == EPDIR_OUT) ? size : inpkt_length;
hctsiz.pktcnt = packet_cnt;
hctsiz.pid = pid;
hcchar.mps = packet_size;
hcchar.epnum = ep->endpoint & 0xf;
hcchar.epdir = dir;
hcchar.eptype = ep->type;
hcchar.multicnt = 1;
hcchar.devaddr = ep->dev->address;
hcchar.chdis = 0;
hcchar.chen = 1;
if (ep->dev->speed == LOW_SPEED)
hcchar.lspddev = 1;
if (size > DMA_SIZE) {
usb_debug("Transfer too large: %d\n", size);
return -1;
}
/*
* Check the buffer address which should be 4-byte aligned and DMA
* coherent
*/
do_copy = !dma_coherent(data_buf) || ((uintptr_t)data_buf & 0x3);
aligned_buf = do_copy ? DWC2_INST(ep->dev->controller)->dma_buffer :
data_buf;
if (do_copy && (dir == EPDIR_OUT))
memcpy(aligned_buf, data_buf, size);
writel(hctsiz.d32, &reg->host.hchn[ch_num].hctsizn);
writel((uint32_t)virt_to_bus(aligned_buf),
&reg->host.hchn[ch_num].hcdman);
writel(hcchar.d32, &reg->host.hchn[ch_num].hccharn);
ret = wait_for_complete(ep, ch_num);
if (ret >= 0) {
/* Calculate actual transferred length */
transferred = (dir == EPDIR_IN) ? inpkt_length - ret : size;
if (do_copy && (dir == EPDIR_IN))
memcpy(data_buf, aligned_buf, transferred);
if ((short_pkt != NULL) && (dir == EPDIR_IN))
*short_pkt = (ret > 0) ? 1 : 0;
}
/* Save data toggle */
hctsiz.d32 = readl(&reg->host.hchn[ch_num].hctsizn);
ep->toggle = hctsiz.pid;
if (ret < 0) {
usb_debug("%s Transfer stop code: %x\n", __func__, ret);
return ret;
}
return transferred;
}
static int
dwc2_split_transfer(endpoint_t *ep, int size, int pid, ep_dir_t dir,
uint32_t ch_num, u8 *data_buf, split_info_t *split,
int *short_pkt)
{
dwc2_reg_t *reg = DWC2_REG(ep->dev->controller);
hfnum_t hfnum;
hcsplit_t hcsplit = { .d32 = 0 };
int ret, transferred = 0;
hcsplit.hubaddr = split->hubaddr;
hcsplit.prtaddr = split->hubport;
hcsplit.spltena = 1;
writel(hcsplit.d32, &reg->host.hchn[ch_num].hcspltn);
/* Wait for next frame boundary */
do {
hfnum.d32 = readl(&reg->host.hfnum);
if (dwc2_disconnected(ep->dev->controller))
return -HCSTAT_DISCONNECTED;
} while (hfnum.frnum % 8 != 0);
/* Handle Start-Split */
ret = dwc2_do_xfer(ep, dir == EPDIR_IN ? 0 : size, pid, dir, ch_num,
data_buf, NULL);
if (ret < 0)
goto out;
hcsplit.spltena = 1;
hcsplit.compsplt = 1;
writel(hcsplit.d32, &reg->host.hchn[ch_num].hcspltn);
ep->toggle = pid;
if (dir == EPDIR_OUT)
transferred += ret;
/* Handle Complete-Split */
do {
ret = dwc2_do_xfer(ep, dir == EPDIR_OUT ? 0 : size, ep->toggle,
dir, ch_num, data_buf, short_pkt);
} while (ret == -HCSTAT_NYET);
if (dir == EPDIR_IN)
transferred += ret;
out:
/* Clear hcsplit reg */
hcsplit.spltena = 0;
hcsplit.compsplt = 0;
writel(hcsplit.d32, &reg->host.hchn[ch_num].hcspltn);
if (ret < 0)
return ret;
return transferred;
}
static int dwc2_need_split(usbdev_t *dev, split_info_t *split)
{
if (dev->speed == HIGH_SPEED)
return 0;
if (closest_usb2_hub(dev, &split->hubaddr, &split->hubport))
return 0;
return 1;
}
static int
dwc2_transfer(endpoint_t *ep, int size, int pid, ep_dir_t dir, uint32_t ch_num,
u8 *src, uint8_t skip_nak)
{
split_info_t split;
int ret, short_pkt, transferred = 0, timeout = 3000;
ep->toggle = pid;
do {
short_pkt = 0;
if (dwc2_need_split(ep->dev, &split)) {
nak_retry:
ret = dwc2_split_transfer(ep, MIN(ep->maxpacketsize,
size), ep->toggle, dir, 0, src, &split,
&short_pkt);
/*
* dwc2_split_transfer() waits for the next FullSpeed
* frame boundary, so we have one try per millisecond.
* It's 3s timeout for each split transfer.
*/
if (ret == -HCSTAT_NAK && !skip_nak && --timeout) {
udelay(500);
goto nak_retry;
}
} else {
ret = dwc2_do_xfer(ep, MIN(DMA_SIZE, size), pid, dir, 0,
src, &short_pkt);
}
if (ret < 0)
return ret;
size -= ret;
src += ret;
transferred += ret;
} while (size > 0 && !short_pkt);
return transferred;
}
static int
dwc2_bulk(endpoint_t *ep, int size, u8 *src, int finalize)
{
ep_dir_t data_dir;
if (ep->direction == IN)
data_dir = EPDIR_IN;
else if (ep->direction == OUT)
data_dir = EPDIR_OUT;
else
return -1;
return dwc2_transfer(ep, size, ep->toggle, data_dir, 0, src, 0);
}
static int
dwc2_control(usbdev_t *dev, direction_t dir, int drlen, void *setup,
int dalen, u8 *src)
{
int ret = 0;
ep_dir_t data_dir;
endpoint_t *ep = &dev->endpoints[0];
if (dir == IN)
data_dir = EPDIR_IN;
else if (dir == OUT)
data_dir = EPDIR_OUT;
else
return -1;
/* Setup Phase */
if (dwc2_transfer(ep, drlen, PID_SETUP, EPDIR_OUT, 0, setup, 0) < 0)
return -1;
/* Data Phase */
ep->toggle = PID_DATA1;
if (dalen > 0) {
ret = dwc2_transfer(ep, dalen, ep->toggle, data_dir, 0, src, 0);
if (ret < 0)
return -1;
}
/* Status Phase */
if (dwc2_transfer(ep, 0, PID_DATA1, !data_dir, 0, NULL, 0) < 0)
return -1;
return ret;
}
static int
dwc2_intr(endpoint_t *ep, int size, u8 *src)
{
ep_dir_t data_dir;
if (ep->direction == IN)
data_dir = EPDIR_IN;
else if (ep->direction == OUT)
data_dir = EPDIR_OUT;
else
return -1;
return dwc2_transfer(ep, size, ep->toggle, data_dir, 0, src, 1);
}
static u32 dwc2_intr_get_timestamp(intr_queue_t *q)
{
hprt_t hprt;
hfnum_t hfnum;
hci_t *controller = q->endp->dev->controller;
dwc_ctrl_t *dwc2 = DWC2_INST(controller);
dwc2_reg_t *reg = DWC2_REG(controller);
hfnum.d32 = readl(&reg->host.hfnum);
hprt.d32 = readl(dwc2->hprt0);
/*
* hfnum.frnum increments when a new SOF is transmitted on
* the USB, and is reset to 0 when it reaches 16'h3FFF
*/
switch (hprt.prtspd) {
case PRTSPD_HIGH:
/* 8 micro-frame per ms for high-speed */
return hfnum.frnum / 8;
case PRTSPD_FULL:
case PRTSPD_LOW:
default:
/* 1 micro-frame per ms for high-speed */
return hfnum.frnum / 1;
}
}
/* create and hook-up an intr queue into device schedule */
static void *
dwc2_create_intr_queue(endpoint_t *ep, const int reqsize,
const int reqcount, const int reqtiming)
{
intr_queue_t *q = (intr_queue_t *)xzalloc(sizeof(intr_queue_t));
q->data = dma_memalign(4, reqsize);
q->endp = ep;
q->reqsize = reqsize;
q->reqtiming = reqtiming;
return q;
}
static void
dwc2_destroy_intr_queue(endpoint_t *ep, void *_q)
{
intr_queue_t *q = (intr_queue_t *)_q;
free(q->data);
free(q);
}
/*
* read one intr-packet from queue, if available. extend the queue for
* new input. Return NULL if nothing new available.
* Recommended use: while (data=poll_intr_queue(q)) process(data);
*/
static u8 *
dwc2_poll_intr_queue(void *_q)
{
intr_queue_t *q = (intr_queue_t *)_q;
int ret = 0;
u32 timestamp = dwc2_intr_get_timestamp(q);
/*
* If hfnum.frnum run overflow it will schedule
* an interrupt transfer immediately
*/
if (timestamp - q->timestamp < q->reqtiming)
return NULL;
q->timestamp = timestamp;
ret = dwc2_intr(q->endp, q->reqsize, q->data);
if (ret > 0)
return q->data;
else
return NULL;
}
hci_t *dwc2_init(void *bar)
{
hci_t *controller = new_controller();
controller->instance = xzalloc(sizeof(dwc_ctrl_t));
DWC2_INST(controller)->dma_buffer = dma_malloc(DMA_SIZE);
if (!DWC2_INST(controller)->dma_buffer) {
usb_debug("Not enough DMA memory for DWC2 bounce buffer\n");
goto free_dwc2;
}
controller->type = DWC2;
controller->start = dummy;
controller->stop = dummy;
controller->reset = dummy;
controller->init = dwc2_reinit;
controller->shutdown = dwc2_shutdown;
controller->bulk = dwc2_bulk;
controller->control = dwc2_control;
controller->set_address = generic_set_address;
controller->finish_device_config = NULL;
controller->destroy_device = NULL;
controller->create_intr_queue = dwc2_create_intr_queue;
controller->destroy_intr_queue = dwc2_destroy_intr_queue;
controller->poll_intr_queue = dwc2_poll_intr_queue;
controller->reg_base = (uintptr_t)bar;
init_device_entry(controller, 0);
/* Init controller */
controller->init(controller);
/* Setup up root hub */
controller->devices[0]->controller = controller;
controller->devices[0]->init = dwc2_rh_init;
controller->devices[0]->init(controller->devices[0]);
return controller;
free_dwc2:
detach_controller(controller);
free(DWC2_INST(controller));
free(controller);
return NULL;
}
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