rt-thread/bsp/phytium/libraries/standalone/drivers/usb/fxhci/fxhci.c

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/*
* Copyright : (C) 2022 Phytium Information Technology, Inc.
* All Rights Reserved.
*
* This program is OPEN SOURCE software: you can redistribute it and/or modify it
* under the terms of the Phytium Public License as published by the Phytium Technology Co.,Ltd,
* either version 1.0 of the License, or (at your option) any later version.
*
* 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 Phytium Public License for more details.
*
*
* FilePath: fxhci.c
* Date: 2022-02-11 13:33:12
* LastEditTime: 2022-02-18 09:17:20
* Description:  This files is for implmentation of XHCI driver
*
* Modify History:
* Ver   Who        Date         Changes
* ----- ------     --------    --------------------------------------
* 1.0 Zhugengyu 2022/2/7 init commit
*/
#include <string.h>
#include "fsleep.h"
#include "fcache.h"
#include "fparameters.h"
#include "fdebug.h"
#include "fxhci_private.h"
#define FUSB_DEBUG_TAG "FXHCI"
#define FUSB_ERROR(format, ...) FT_DEBUG_PRINT_E(FUSB_DEBUG_TAG, format, ##__VA_ARGS__)
#define FUSB_WARN(format, ...) FT_DEBUG_PRINT_W(FUSB_DEBUG_TAG, format, ##__VA_ARGS__)
#define FUSB_INFO(format, ...) FT_DEBUG_PRINT_I(FUSB_DEBUG_TAG, format, ##__VA_ARGS__)
#define FUSB_DEBUG(format, ...) FT_DEBUG_PRINT_D(FUSB_DEBUG_TAG, format, ##__VA_ARGS__)
typedef enum
{
FXHCI_OP_REG,
} FXhciHandShakeType;
static void FXhciStart(FUsbHc *controller);
static void FXhciStop(FUsbHc *controller);
static FXhciTransCode FXhciReset(FUsbHc *controller);
static void FXhciReinit(FUsbHc *controller);
static void FXhciShutdown(FUsbHc *controller);
static FXhciTransCode FXhciBulk(FUsbEndpoint *ep, int size, u8 *data, int finalize);
static FXhciTransCode FXhciControl(FUsbDev *dev, FUsbDirection dir, int drlen, void *devreq,
int dalen, u8 *data);
static void *FXhciCreateIntrQueue(FUsbEndpoint *ep, int reqsize, int reqcount, int reqtiming);
static void FXhciDestoryIntrQueue(FUsbEndpoint *ep, void *queue);
static u8 *FXhciPollIntrQueue(void *queue);
/*
* Some structures must not cross page boundaries. To get this,
* we align them by their size (or the next greater power of 2).
*/
/**
* @name: FXhciAlign
* @msg: 分配一段对齐的内存
* @return {*}
* @param {FXhci} *xhci, XHCI控制器实例
* @param {size_t} min_align, 对齐方式
* @param {size_t} size, 请求的字节数目
*/
void *FXhciAlign(FXhci *const xhci, const size_t min_align, const size_t size)
{
FASSERT(xhci && xhci->usb);
size_t align;
FUsb *instance = xhci->usb;
if (!(size & (size - 1)))
align = size; /* It's a power of 2 */
else
align = 1 << ((sizeof(unsigned) << 3) - __builtin_clz(size));
if (align < min_align)
align = min_align;
return FUSB_ALLOCATE(instance, size, align);
}
#ifdef FMEMP_TAG_DEBUG
void *FXhciAlignTag(FXhci *const xhci, const size_t min_align, const size_t size, const char *file, unsigned long line, const char *msg)
{
FASSERT(xhci && xhci->usb);
size_t align;
FUsb *instance = xhci->usb;
if (!(size & (size - 1)))
align = size; /* It's a power of 2 */
else
align = 1 << ((sizeof(unsigned) << 3) - __builtin_clz(size));
if (align < min_align)
align = min_align;
return FUsbMempAllocateTag(instance, size, align, file, line, msg);
}
#endif
/**
* @name: FXhciClearTrb
* @msg: 清空TRB反转TRB的Cycle state
* @return {*}
* @param {FXhciTrb} *trb, TRB实例
* @param {int} pcs, TRB ring的Cycle state
*/
void FXhciClearTrb(FXhciTrb *const trb, const int pcs)
{
FASSERT(trb);
trb->ptr_low = 0;
trb->ptr_high = 0;
trb->status = 0;
trb->control = !pcs;
return;
}
/**
* @name: FXhciInitCycleRing
* @msg: 初始化TRB ring
* @return {*}
* @param {FXhciTransRing} *tr, TRB ring实例
* @param {size_t} ring_size, TRB ring中的TRB数目
*/
void FXhciInitCycleRing(FXhciTransRing *const tr, const size_t ring_size)
{
FASSERT(tr && tr->ring);
memset((void *)tr->ring, 0, ring_size * sizeof(*tr->ring));
FXHCI_TRB_SET(TT, &tr->ring[ring_size - 1], FXHCI_TRB_LINK); /* TRB Type */
FXHCI_TRB_SET(TC, &tr->ring[ring_size - 1], 1); /* Toggle Cycle */
/* only one segment that points to itself */
tr->ring[ring_size - 1].ptr_low = (uintptr)(tr->ring);
tr->pcs = 1;
tr->cur = tr->ring;
return;
}
/**
* @name: FXhciHandShake
* @msg: 等待XHCI状态完成握手
* @return {FError} 等待返回值
* @param {FXhci} *xhci, xhci实例
* @param {FXhciHandShakeType} type, 等待类型e.g 等待Op寄存器
* @param {uintptr} reg_off, 寄存器偏移量
* @param {u32} mask, 寄存器掩码位
* @param {u32} wait_for, 等待的状态,如果状态到达,成功退出
* @param {s32} timeout, 等待的tick超时
*/
static FError FXhciHandShake(FXhci *xhci, FXhciHandShakeType type, uintptr reg_off, u32 mask, u32 wait_for, s32 timeout)
{
FASSERT(xhci);
FError ret = FUSB_SUCCESS;
switch (type)
{
case FXHCI_OP_REG:
ret = FXhciWaitOper32(&xhci->mmio, reg_off, mask, wait_for, timeout);
break;
default:
FASSERT(0);
break;
}
return ret;
}
/**
* @name: FXhciWaitReady
* @msg: 等待XHCI控制器重置完成
* @return {*}
* @param {FXhci} *xhci, xhci实例
*/
static FError FXhciWaitReady(FXhci *const xhci)
{
FASSERT(xhci);
FUSB_INFO("Waiting for controller to be ready... ");
FError ret = FXhciHandShake(xhci, FXHCI_OP_REG, FXHCI_REG_OP_USBSTS, FXHCI_REG_OP_USBSTS_CNR, 0, FXHCI_TIMEOUT);
if (FUSB_SUCCESS == ret)
FUSB_INFO("ok");
else
FUSB_ERROR("timeout.");
return ret;
}
/**
* @name: FXhciHcInit
* @msg: 创建XHCI USB 控制器实例,完成初始化
* @return {FUsbHc *} XHCI控制器实例
* @param {FUsb} *instance, USB实例
* @param {uintptr} base_addr, XHCI控制器基地址
*/
FUsbHc *FXhciHcInit(FUsb *instance, uintptr base_addr)
{
FASSERT(instance);
int i;
FXhciMMIO *mmio = NULL;
u32 reg_val;
u16 hc_version;
uintptr xhci_base_addr = base_addr + FUSB3_XHCI_OFFSET;
FUSB_DEBUG("xhci base addr: 0x%x", xhci_base_addr);
/* First, allocate and initialize static controller structures */
FUsbHc *const controller = FUsbAllocateHc(instance);
if (NULL == controller)
{
FUSB_ERROR("Out of memory ");
return NULL;
}
/* set USB Hc CB according to XHCI */
controller->type = FUSB_HC_XHCI;
controller->start = FXhciStart;
controller->stop = FXhciStop;
controller->reset = FXhciReset;
controller->init = FXhciReinit;
controller->shutdown = FXhciShutdown;
controller->bulk = FXhciBulk;
controller->control = FXhciControl;
controller->set_address = FXhciSetAddress;
controller->finish_device_config = FXhciFinishDevConfig;
controller->destroy_device = FXhciDestoryDev;
controller->create_intr_queue = FXhciCreateIntrQueue;
controller->destroy_intr_queue = FXhciDestoryIntrQueue;
controller->poll_intr_queue = FXhciPollIntrQueue;
/* allocate xhci instance */
controller->reg_base = base_addr;
FASSERT(NULL == controller->instance);
controller->instance = FUSB_ALLOCATE(instance, sizeof(FXhci), FUSB_DEFAULT_ALIGN);
if (NULL == controller->instance)
{
FUSB_INFO("Out of memory ");
goto _free_controller;
}
controller->usb = instance;
FXhci *const xhci = (FXhci *)controller->instance;
xhci->usb = instance;
/* init roothub at slot-0 */
FUsbInitDevEntry(controller, 0);
xhci->roothub = controller->devices[0];
/* allocate command ring and event ring */
FASSERT((NULL == xhci->cr.ring) && (NULL == xhci->er.ring) &&
(NULL == xhci->ev_ring_table));
xhci->cr.ring = FXHCI_ALIGN(xhci, 64, FXHCI_COMMAND_RING_SIZE * sizeof(FXhciTrb));
xhci->er.ring = FXHCI_ALIGN(xhci, 64, FXHCI_EVENT_RING_SIZE * sizeof(FXhciTrb));
xhci->ev_ring_table = FXHCI_ALIGN(xhci, 64, sizeof(FXhciErstEntry));
if ((NULL == xhci->roothub) || (NULL == xhci->cr.ring) ||
(NULL == xhci->er.ring) || (NULL == xhci->ev_ring_table))
{
FUSB_INFO("Out of memory ");
goto _free_xhci;
}
/* setup xhci mmio for register access */
mmio = &xhci->mmio;
FXhciSetupMMIO(mmio, xhci_base_addr);
/* check if XHCI version is supported */
hc_version = FXhciReadHcVersion(mmio);
if (hc_version < FXHCI_HC_VERSION_MIN || hc_version > FXHCI_HC_VERSION_MAX)
{
FUSB_ERROR("xHCI version 0x%x not support", hc_version);
goto _free_xhci;
}
const unsigned pagesize = FXhciReadOper32(mmio, FXHCI_REG_OP_PAGESIZE) << 12;
FUSB_INFO("regbase: 0x%x", mmio->base);
FUSB_INFO("caplen: 0x%x", FXhciReadCaplen(mmio));
FUSB_INFO("rtsoff: 0X%x", mmio->runtime_base - mmio->base);
FUSB_INFO("dboff: 0X%x", mmio->doorbell_base - mmio->base);
FUSB_INFO("hciversion: 0x%x", FXhciReadHcVersion(mmio));
FUSB_INFO("context size: %dB ", FXhciGetCtxSize(mmio));
FUSB_INFO("page size: %dB ", pagesize);
/*
* We haven't touched the hardware yet. So we allocate all dynamic
* structures at first and can still chicken out easily if we run out
* of memory.
*/
reg_val = FXhciReadCap32(&xhci->mmio, FXHCI_REG_CAP_HCSPARAMS1);
xhci->max_slots_en = FXHCI_REG_CAP_HCSPARAMS1_MAX_SLOTS_GET(reg_val); /* record max slot num */
/* allocate device related memory, DCBAA and device info */
FASSERT(NULL == xhci->dcbaa);
xhci->dcbaa = FXHCI_ALIGN(xhci, 64, (xhci->max_slots_en + 1) * sizeof(u64));
FASSERT(NULL == xhci->dev);
xhci->dev = FUSB_ALLOCATE(instance, (xhci->max_slots_en + 1) * sizeof(*xhci->dev), FUSB_DEFAULT_ALIGN);
if ((NULL == xhci->dcbaa) || (NULL == xhci->dev))
{
FUSB_INFO("Out of memory ");
goto _free_xhci;
}
/*
* Let dcbaa[0] point to another array of pointers, sp_ptrs.
* The pointers therein point to scratchpad buffers (pages).
*/
reg_val = FXhciReadCap32(&xhci->mmio, FXHCI_REG_CAP_HCSPARAMS2);
const size_t max_sp_bufs = FXHCI_REG_CAP_HCSPARAMS2_MAX_SCRATCHPAD_BUFS_GET(reg_val);
FUSB_INFO("max scratchpad bufs: 0x%lx reg_val : 0x%x", max_sp_bufs, reg_val);
if (0 < max_sp_bufs)
{
FUSB_INFO("allocate sp_ptrs");
const size_t sp_ptrs_size = max_sp_bufs * sizeof(u64);
/* allocate scratchpad bufs entry to preserve pointers of scratchpad buf */
FASSERT(NULL == xhci->sp_ptrs);
xhci->sp_ptrs = FXHCI_ALIGN(xhci, 64, sp_ptrs_size);
if (NULL == xhci->sp_ptrs)
{
FUSB_INFO("Out of memory ");
goto _free_xhci_structs;
}
for (i = 0; (size_t)i < max_sp_bufs; ++i)
{
/* allocate each scratchpad buf */
void *const page = FUSB_ALLOCATE(instance, pagesize, pagesize);
if (NULL == page)
{
FUSB_INFO("Out of memory ");
goto _free_xhci_structs;
}
xhci->sp_ptrs[i] = (uintptr)(page); /* assign pointer to scratchpad buf*/
}
xhci->dcbaa[0] = (uintptr)(xhci->sp_ptrs); /* assign pointer to scratchpad bufs entry */
}
/* Now start working on the hardware */
if (FUSB_SUCCESS != FXhciWaitReady(xhci))
goto _free_xhci_structs;
/* TODO: Check if BIOS claims ownership (and hand over) */
if (FUSB_CC_SUCCESS != FXhciReset(controller))
{
goto _free_xhci_structs;
}
FXhciReinit(controller);
/* init roothub device instance */
xhci->roothub->controller = controller;
xhci->roothub->init = FXhciRootHubInit;
xhci->roothub->init(xhci->roothub);
FUSB_INFO("init xHc@%p success", controller);
return controller;
_free_xhci_structs:
if (xhci->sp_ptrs)
{
for (i = 0; (size_t)i < max_sp_bufs; ++i)
{
if (xhci->sp_ptrs[i])
FUSB_FREE(instance, (void *)(uintptr)(xhci->sp_ptrs[i]));
}
}
FUSB_FREE(instance, xhci->sp_ptrs);
FUSB_FREE(instance, xhci->dcbaa);
_free_xhci:
FUSB_FREE(instance, (void *)xhci->ev_ring_table);
FUSB_FREE(instance, (void *)xhci->er.ring);
FUSB_FREE(instance, (void *)xhci->cr.ring);
FUSB_FREE(instance, xhci->roothub);
FUSB_FREE(instance, xhci->dev);
FUSB_FREE(instance, xhci);
_free_controller:
FUsbDetachHc(controller);
FUSB_FREE(instance, controller);
return NULL;
}
/**
* @name: FXhciReset
* @msg: 重置XHCI控制器
* @return {*}
* @param {FUsbHc} *controller, USB Hc控制器
*/
static FUsbTransCode FXhciReset(FUsbHc *const controller)
{
FASSERT(controller);
FXhci *const xhci = FXHCI_INST_GET(controller);
FASSERT(xhci);
u32 reg_val;
/* stop xhci if still run */
FXhciStop(controller);
reg_val = FXhciReadOper32(&xhci->mmio, FXHCI_REG_OP_USBCMD);
reg_val |= FXHCI_REG_OP_USBCMD_HCRST;
FXhciWriteOper32(&xhci->mmio, FXHCI_REG_OP_USBCMD, reg_val);
FUSB_INFO("Resetting hc...");
if (FUSB_SUCCESS != FXhciHandShake(xhci, FXHCI_OP_REG, FXHCI_REG_OP_USBCMD, FXHCI_REG_OP_USBCMD_HCRST, 0, FXHCI_TIMEOUT))
{
FUSB_ERROR("Wait hc reset timeout !!!");
return -1;
}
return FUSB_CC_SUCCESS;
}
/**
* @name: FXhciReinit
* @msg: 重新初始化XHCI控制器
* @return {*}
* @param {FUsbHc} *controller, USB Hc控制器
*/
static void FXhciReinit(FUsbHc *controller)
{
FASSERT(controller);
FXhci *const xhci = FXHCI_INST_GET(controller);
FASSERT(xhci);
const FUsbConfig *const config = &controller->usb->config;
u32 reg_val;
u64 reg_val64;
/* wait xhci ready */
if (FUSB_SUCCESS != FXhciWaitReady(xhci))
return;
/* Enable all available slots */
reg_val = FXhciReadOper32(&xhci->mmio, FXHCI_REG_OP_CONFIG);
reg_val &= ~FXHCI_REG_OP_CONFIG_MAX_SLOTS_EN_MASK;
reg_val |= FXHCI_REG_OP_CONFIG_MAX_SLOTS_EN_SET(xhci->max_slots_en);
FXhciWriteOper32(&xhci->mmio, FXHCI_REG_OP_CONFIG, reg_val);
/* Set DCBAA */
FXhciWriteOper64(&xhci->mmio, FXHCI_REG_OP_DCBAAP, (u64)(uintptr)xhci->dcbaa);
FUSB_INFO("dcba at 0x%lx", FXhciReadOper64(&xhci->mmio, FXHCI_REG_OP_DCBAAP));
/* Initialize command ring */
FXhciInitCycleRing(&xhci->cr, FXHCI_COMMAND_RING_SIZE);
FUSB_INFO("command ring @%p", xhci->cr.ring);
reg_val64 = FXhciReadOper64(&xhci->mmio, FXHCI_REG_OP_CRCR);
reg_val64 = FXHCI_REG_OP_CRCR_CR_PTR_MASK & (u64)(uintptr)xhci->cr.ring;
reg_val64 |= FXHCI_REG_OP_CRCR_RCS & xhci->cr.pcs;
FXhciWriteOper64(&xhci->mmio, FXHCI_REG_OP_CRCR, reg_val64);
/* Make sure interrupts are disabled */
reg_val = FXhciReadOper32(&xhci->mmio, FXHCI_REG_OP_USBCMD);
reg_val &= ~FXHCI_REG_OP_USBCMD_INTE;
FXhciWriteOper32(&xhci->mmio, FXHCI_REG_OP_USBCMD, reg_val);
/* Initialize event ring */
FXhciResetEvtRing(&xhci->er);
FUSB_INFO("event ring @%p (0x%08p) ",
xhci->er.ring, (uintptr)(xhci->er.ring));
reg_val = FXhciReadCap32(&xhci->mmio, FXHCI_REG_CAP_HCSPARAMS2);
FUSB_INFO("ERST Max: %d",
FXHCI_REG_CAP_HCSPARAMS2_ERST_MAX_GET(reg_val));
memset((void *)xhci->ev_ring_table, 0x00, sizeof(FXhciErstEntry));
xhci->ev_ring_table[0].seg_base_lo = (uintptr)(xhci->er.ring);
xhci->ev_ring_table[0].seg_base_hi = 0;
xhci->ev_ring_table[0].seg_size = FXHCI_EVENT_RING_SIZE;
/* pass event ring table to hardware */
WMB();
/* Initialize primary interrupter */
FXhciWriteRt32(&xhci->mmio, 0, FXHCI_REG_RT_IR_ERSTSZ, FXHCI_REG_RT_IR_ERSTSZ_MASK & 1); /* Segment Table Size = 1 */
FXhciUpdateEvtDQ(xhci);
/* erstba has to be written at last */
FXhciWriteRt64(&xhci->mmio, 0, FXHCI_REG_RT_IR_ERSTBA, FXHCI_REG_RT_IR_ERSTBA_MASK & ((u64)(uintptr)xhci->ev_ring_table));
FUSB_INFO("ERST base: 0x%lx == %p",
FXhciReadRt64(&xhci->mmio, 0, FXHCI_REG_RT_IR_ERSTBA),
xhci->ev_ring_table);
FXhciStart(controller);
/* run Cmd Nop to test if command ring okay */
for (int i = 0; i < 3; ++i)
{
FUSB_INFO("NOOP run #%d ", i);
if (FXHCI_CC_SUCCESS != FXhciCmdNop(xhci))
{
FUSB_ERROR("noop command failed. ");
break;
}
}
return;
}
/**
* @name: FXhciShutdown
* @msg: 关闭XHCI控制器
* @return {*}
* @param {FUsbHc} *controller, USB Hc控制器
*/
static void FXhciShutdown(FUsbHc *const controller)
{
int i;
u32 reg_val;
if (controller == NULL)
return;
/* detach the Hc instance */
FUsbDetachHc(controller);
FXhci *const xhci = FXHCI_INST_GET(controller);
FASSERT(xhci && xhci->usb);
FUsb *instance = xhci->usb;
FXhciStop(controller); /* stop xhci instance */
/* free scatchpad bufs */
if (NULL != xhci->sp_ptrs)
{
reg_val = FXhciReadCap32(&xhci->mmio, FXHCI_REG_CAP_HCSPARAMS2);
const size_t max_sp_bufs = FXHCI_REG_CAP_HCSPARAMS2_MAX_SCRATCHPAD_BUFS_GET(reg_val);
for (i = 0; (size_t)i < max_sp_bufs; ++i)
{
if (NULL != (void *)(uintptr)xhci->sp_ptrs[i])
FUSB_FREE(instance, (void *)(uintptr)(xhci->sp_ptrs[i]));
}
}
FUSB_FREE(instance, xhci->sp_ptrs);
FUSB_FREE(instance, xhci->dcbaa);
FUSB_FREE(instance, xhci->dev);
FUSB_FREE(instance, (void *)xhci->ev_ring_table);
FUSB_FREE(instance, (void *)xhci->er.ring);
FUSB_FREE(instance, (void *)xhci->cr.ring);
FUSB_FREE(instance, xhci);
return;
}
/**
* @name: FXhciStart
* @msg: 启动XHCI控制器
* @return {*}
* @param {FUsbHc} *controller, USB Hc控制器
*/
static void FXhciStart(FUsbHc *controller)
{
FASSERT(controller);
FXhci *const xhci = FXHCI_INST_GET(controller);
FASSERT(xhci);
u32 reg_val;
/* setting the USBCMD register Run/Stop (R/S) bit to 1 */
reg_val = FXhciReadOper32(&xhci->mmio, FXHCI_REG_OP_USBCMD);
reg_val |= FXHCI_REG_OP_USBCMD_RUN_STOP;
FXhciWriteOper32(&xhci->mmio, FXHCI_REG_OP_USBCMD, reg_val);
if (FUSB_SUCCESS != FXhciHandShake(xhci, FXHCI_OP_REG, FXHCI_REG_OP_USBSTS, FXHCI_REG_OP_USBSTS_HCH, 0, FXHCI_TIMEOUT))
{
FUSB_ERROR("Wait hc start timeout !!!");
}
return;
}
/**
* @name: FXhciStop
* @msg: 停止XHCI控制器
* @return {*}
* @param {FUsbHc} *controller, USB Hc控制器
*/
static void FXhciStop(FUsbHc *controller)
{
FASSERT(controller);
FXhci *const xhci = FXHCI_INST_GET(controller);
FASSERT(xhci);
u32 reg_val;
/* setting the USBCMD register Run/Stop (R/S) bit to 0 */
reg_val = FXhciReadOper32(&xhci->mmio, FXHCI_REG_OP_USBCMD);
reg_val &= ~FXHCI_REG_OP_USBCMD_RUN_STOP;
FXhciWriteOper32(&xhci->mmio, FXHCI_REG_OP_USBCMD, reg_val);
if (FUSB_SUCCESS != FXhciHandShake(xhci, FXHCI_OP_REG, FXHCI_REG_OP_USBSTS, FXHCI_REG_OP_USBSTS_HCH, FXHCI_REG_OP_USBSTS_HCH, FXHCI_TIMEOUT))
{
FUSB_ERROR("Wait hc stop timeout !!!");
}
return;
}
/**
* @name: FXhciResetEp
* @msg: 重置XHCI端点
* @return {FError} 返回错误码
* @param {FUsbDev} *dev, 端点所在的USB设备实例
* @param {FUsbEndpoint} *ep, 端点实例
*/
static FError FXhciResetEp(FUsbDev *const dev, FUsbEndpoint *const ep)
{
FASSERT(dev && dev->controller);
FXhci *const xhci = FXHCI_INST_GET(dev->controller);
FASSERT(xhci);
const int slot_id = dev->address;
const int ep_id = (NULL != ep) ? FXhciEpId(ep) : FXHCI_EP0_ID; /* ep-0 or normal ep */
FXhciEpCtx *const epctx = xhci->dev[slot_id].ctx.ep[ep_id];
FUSB_INFO("Resetting ID %d EP %d (ep state: %d) ",
slot_id, ep_id, FXHCI_EC_GET(STATE, epctx));
/* Run Reset Endpoint Command if the EP is in Halted state */
if (FXHCI_EC_GET(STATE, epctx) == FXHCI_EC_STATE_HALTED)
{
const FXhciTransCode cc = FXhciCmdResetEp(xhci, slot_id, ep_id);
if (cc != FXHCI_CC_SUCCESS)
{
FUSB_INFO("Reset Endpoint Command failed: %d ", cc);
return FUSB_ERR_TRANS_FAIL;
}
}
/* Clear TT buffer for bulk and control endpoints behind a TT */
const int hub = dev->hub;
if (hub && dev->speed < FUSB_HIGH_SPEED &&
dev->controller->devices[hub]->speed == FUSB_HIGH_SPEED)
{
/* TODO */;
}
/* Reset transfer ring if the endpoint is in the right state */
const unsigned ep_state = FXHCI_EC_GET(STATE, epctx);
if (ep_state == FXHCI_EC_STATE_STOPPED || ep_state == FXHCI_EC_STATE_ERROR)
{
FXhciTransRing *const tr =
xhci->dev[slot_id].transfer_rings[ep_id];
const FXhciTransCode cc = FXhciCmdSetTrDq(xhci, slot_id, ep_id,
tr->ring, 1);
if (cc != FXHCI_CC_SUCCESS)
{
FUSB_INFO("Set TR Dequeue Command failed: %d ", cc);
return FUSB_ERR_TRANS_FAIL;
}
FXhciInitCycleRing(tr, FXHCI_TRANSFER_RING_SIZE);
}
FUSB_INFO("Finished resetting ID %d EP %d (ep state: %d) ",
slot_id, ep_id, FXHCI_EC_GET(STATE, epctx));
return FUSB_SUCCESS;
}
/**
* @name: FXhciEnqueueTrb
* @msg: TRB入队向TRB ring加入一条TRB
* @return {*}
* @param {FXhciTransRing} *tr, TRB ring实例
*/
static void FXhciEnqueueTrb(FXhciTransRing *const tr)
{
FASSERT(tr);
const int chain = FXHCI_TRB_GET(CH, tr->cur);
FXHCI_TRB_SET(C, tr->cur, tr->pcs); /* Cycle Bit */
++tr->cur;
while (FXHCI_TRB_GET(TT, tr->cur) == FXHCI_TRB_LINK)
{
FUSB_DEBUG("Handling LINK pointer ");
const int tc = FXHCI_TRB_GET(TC, tr->cur);
FXHCI_TRB_SET(CH, tr->cur, chain); /* Chain Bit */
WMB();
FXHCI_TRB_SET(C, tr->cur, tr->pcs); /* Cycle Bit */
tr->cur = (void *)(uintptr)(tr->cur->ptr_low);
/* toggle cycle state */
if (tc)
tr->pcs ^= 1;
}
return;
}
/**
* @name: FXhciRingDoorbell
* @msg: 提醒Hc处理刚加入的TRB
* @return {*}
* @param {FUsbEndpoint} *ep, 端点实例
*/
static void FXhciRingDoorbell(FUsbEndpoint *const ep)
{
FASSERT(ep);
FXhci *xhci = FXHCI_INST_GET(ep->dev->controller);
/* Ensure all TRB changes are written to memory. */
WMB();
FXhciWriteDb32(&xhci->mmio, ep->dev->address, FXhciEpId(ep));
return;
}
/**
* @name: FXhciEnqueueTD
* @msg: 填充一条TRB
* @return {*}
* @param {FXhciTransRing} *tr, TRB ring实例
* @param {int} ep, 端点实例
* @param {size_t} mps, 最大包长度
* @param {int} dalen, 数据长度
* @param {void} *data, 数据缓冲区
* @param {int} dir, 发送方向
*/
static void FXhciEnqueueTD(FXhciTransRing *const tr, const int ep, const size_t mps,
const int dalen, void *const data, const int dir)
{
FASSERT(tr);
FXhciTrb *trb = NULL; /* cur TRB */
u8 *cur_start = data; /* cur data pointer */
size_t length = dalen; /* remaining bytes */
size_t packets = (length + mps - 1) / mps; /* remaining packets */
size_t residue = 0; /* residue from last TRB */
size_t trb_count = 0; /* TRBs added so far */
while ((length > 0) || (trb_count == 0) /* enqueue at least one */)
{
const size_t cur_end = ((size_t)cur_start + 0x10000) & ~0xffff; /* best guess, send at most 0x1000 bytes */
size_t cur_length = cur_end - (size_t)cur_start;
if (length < cur_length)
{
cur_length = length;
packets = 0;
length = 0;
}
else
{
packets -= (residue + cur_length) / mps;
residue = (residue + cur_length) % mps;
length -= cur_length;
}
trb = tr->cur;
FXhciClearTrb(trb, tr->pcs);
trb->ptr_low = (uintptr)(cur_start);
FXHCI_TRB_SET(TL, trb, cur_length); /* Transfer Length */
FXHCI_TRB_SET(TDS, trb, min((size_t)FXHCI_TRB_MAX_TD_SIZE, packets)); /* TD Size */
FXHCI_TRB_SET(CH, trb, 1); /* associate this TRB with the next TRB on the Ring */
/* Check for first, data stage TRB, only Ep0 can handle */
if ((trb_count == 0) && ep == FXHCI_EP0_ID)
{
FXHCI_TRB_SET(DIR, trb, dir); /* Direction */
FXHCI_TRB_SET(TT, trb, FXHCI_TRB_DATA_STAGE); /* TRB Type */
}
else
{
FXHCI_TRB_SET(TT, trb, FXHCI_TRB_NORMAL); /* TRB Type */
}
/*
* This is a workaround for Synopsys DWC3. If the ENT flag is
* not set for the Normal and Data Stage TRBs. We get Event TRB
* with length 0x20d from the controller when we enqueue a TRB
* for the IN endpoint with length 0x200.
*/
if (0 == length)
{
/* xHC shall fetch and evaluate the next TRB before saving the endpoint state */
FXHCI_TRB_SET(ENT, trb, 1); /* Evaluate Next TRB */
}
FXhciEnqueueTrb(tr);
cur_start += cur_length;
++trb_count;
}
trb = tr->cur;
FXhciClearTrb(trb, tr->pcs);
trb->ptr_low = (uintptr)(trb); /* for easier debugging only */
FXHCI_TRB_SET(TT, trb, FXHCI_TRB_EVENT_DATA); /* set transfer type */
FXHCI_TRB_SET(IOC, trb, 1); /* xHc shalle notify the system of the completion by placing an Transfer Event TRB on the Event ring */
FXhciEnqueueTrb(tr);
return;
}
/**
* @name: FXhciControl
* @msg: XHCI控制传输
* @return {FXhciTransCode} 传输返回值
* @param {FUsbDev} *dev, USB设备实例
* @param {FUsbDirection} dir, 控制传输类型, IN, OUT, SETUP
* @param {int} drlen, USB请求长度
* @param {void} *devreq, USB请求参考FUsbDevReq
* @param {int} dalen, 控制传输数据长度
* @param {unsigned char} *src, 控制传输数据
*/
static FXhciTransCode FXhciControl(FUsbDev *const dev, const FUsbDirection dir,
const int drlen, void *const devreq, const int dalen,
unsigned char *const src)
{
FASSERT(dev && dev->controller);
unsigned char *data = src;
FXhci *const xhci = FXHCI_INST_GET(dev->controller);
FASSERT(xhci);
FXhciEpCtx *const epctx = xhci->dev[dev->address].ctx.ep0;
FXhciTransRing *const tr = xhci->dev[dev->address].transfer_rings[1];
FASSERT(epctx && tr);
/* check the transfer data length, less than WORD size, u16 pointer can hold */
const size_t off = (size_t)data & 0xffff;
if ((off + dalen) > ((FXHCI_TRANSFER_RING_SIZE - 4) << 16))
{
FUSB_ERROR("Unsupported transfer size 0x%lx!!!", dalen);
return FXHCI_CC_GENERAL_ERROR;
}
/* Reset endpoint if it's not running and not disabled */
const unsigned ep_state = FXHCI_EC_GET(STATE, epctx);
if (ep_state > FXHCI_EC_STATE_RUNNING)
{
if (FUSB_SUCCESS != FXhciResetEp(dev, NULL))
{
FUSB_ERROR("Reset endpoint failed !!!");
return FXHCI_CC_GENERAL_ERROR;
}
}
/* Fill and enqueue setup TRB */
FXhciTrb *const setup = tr->cur;
FXhciClearTrb(setup, tr->pcs);
setup->ptr_low = ((u32 *)devreq)[0]; /* request data */
setup->ptr_high = ((u32 *)devreq)[1];
FXHCI_TRB_SET(TL, setup, drlen/*8*/); /* Transfer length */
FXHCI_TRB_SET(TRT, setup, (dalen > 0) ? ((dir == FUSB_OUT) ? FXHCI_TRB_TRT_OUT_DATA : FXHCI_TRB_TRT_IN_DATA) : FXHCI_TRB_TRT_NO_DATA);
FXHCI_TRB_SET(TT, setup, FXHCI_TRB_SETUP_STAGE); /* TRB Type */
FXHCI_TRB_SET(IDT, setup, 1); /* Immediate Data (IDT). shall be set to 1 in a Setup Stage TRB */
FXHCI_TRB_SET(IOC, setup, 1); /* Interrupt On Completion (IOC) */
FXhciEnqueueTrb(tr);
/* Fill and enqueue data TRBs (if any) */
if (dalen > 0)
{
const unsigned mps = FXHCI_EC_GET(MPS, epctx);
const unsigned dt_dir = (dir == FUSB_OUT) ? FXHCI_TRB_DIR_OUT : FXHCI_TRB_DIR_IN;
FXhciEnqueueTD(tr, FXHCI_EP0_ID, mps, dalen, data, dt_dir);
}
/* Fill status TRB */
FXhciTrb *const status = tr->cur;
FXhciClearTrb(status, tr->pcs);
FXHCI_TRB_SET(DIR, status, (dir == FUSB_OUT) ? FXHCI_TRB_DIR_IN : FXHCI_TRB_DIR_OUT); /* Direction */
FXHCI_TRB_SET(TT, status, FXHCI_TRB_STATUS_STAGE); /* TRB Type */
FXHCI_TRB_SET(IOC, status, 1); /* Interrupt On Completion */
FXhciEnqueueTrb(tr);
/* Ring doorbell for EP0 */
FXhciRingDoorbell(&dev->endpoints[0]);
/* Wait for transfer events from IN DATA OUT stages */
int i, transferred = 0;
const int n_stages = 2 + !!dalen; /* 2 stage without data */
/* flush cache of request data / transfer data before transfer */
if (dalen > 0)
{
FCacheDCacheInvalidateRange((uintptr)data, dalen);
FCacheDCacheInvalidateRange((uintptr)devreq, drlen);
}
for (i = 0; i < n_stages; ++i)
{
const FXhciTransCode ret = FXhciWaitForTransfer(xhci, dev->address, 1);
transferred += ret; /* record bytes transfered successfully */
if (ret < FXHCI_CC_ZERO_BYTES) /* negative ret means transfer error */
{
if (ret == FXHCI_CC_TIMEOUT)
{
FUSB_ERROR("Stopping ID %d EP 1 ",
dev->address);
FXhciCmdStopEp(xhci, dev->address, FXHCI_EP0_ID);
}
FUSB_ERROR("Stage %d/%d failed: %d \r\n"
" trb ring: @%p \r\n"
" setup trb: @%p \r\n"
" status trb: @%p \r\n"
" ep state: %d -> %d \r\n"
" usbsts: 0x%08x ",
i, n_stages, ret,
tr->ring, setup, status,
ep_state, FXHCI_EC_GET(STATE, epctx),
FXhciReadOper32(&xhci->mmio, FXHCI_REG_OP_USBSTS));
return ret;
}
}
/* flush cache of request data / transfer data after transfer */
if (dalen > 0)
{
FCacheDCacheInvalidateRange((uintptr)data, dalen);
FCacheDCacheInvalidateRange((uintptr)devreq, drlen);
}
return transferred;
}
/**
* @name: FXhciBulk
* @msg: XHCI块传输
* @return {FXhciTransCode}
* @param {FUsbEndpoint} *ep, 端点实例
* @param {int} size,
* @param {u8} *src
* @param {int} finalize
* @note: finalize == 1: if data is of packet aligned size, add a zero length packet
*/
static FXhciTransCode FXhciBulk(FUsbEndpoint *const ep, const int size, u8 *const src,
const int finalize)
{
/* finalize: Hopefully the xHCI controller always does this.
We have no control over the packets. */
FASSERT(ep);
u8 *data = src;
FXhci *const xhci = FXHCI_INST_GET(ep->dev->controller);
FASSERT(xhci);
const int slot_id = ep->dev->address;
const int ep_id = FXhciEpId(ep); /* must not for Ep0 */
FXhciEpCtx *const epctx = xhci->dev[slot_id].ctx.ep[ep_id];
FXhciTransRing *const tr = xhci->dev[slot_id].transfer_rings[ep_id];
/* check the transfer data length, less than WORD size, u16 pointer can hold */
const size_t off = (size_t)data & 0xffff;
if ((off + size) > ((FXHCI_TRANSFER_RING_SIZE - 2) << 16))
{
FUSB_INFO("Unsupported transfer size ");
return FXHCI_CC_GENERAL_ERROR;
}
/* Reset endpoint if it's not running */
const unsigned ep_state = FXHCI_EC_GET(STATE, epctx);
if (ep_state > FXHCI_EC_STATE_RUNNING)
{
if (FUSB_SUCCESS != FXhciResetEp(ep->dev, ep))
return FXHCI_CC_GENERAL_ERROR;
}
FCacheDCacheInvalidateRange((uintptr)data, size);
/* Enqueue transfer and ring doorbell */
const unsigned mps = FXHCI_EC_GET(MPS, epctx);
const unsigned dir = (ep->direction == FUSB_OUT) ? FXHCI_TRB_DIR_OUT : FXHCI_TRB_DIR_IN;
FXhciEnqueueTD(tr, ep_id, mps, size, data, dir);
FXhciRingDoorbell(ep);
/* Wait for transfer event */
const FXhciTransCode ret = FXhciWaitForTransfer(xhci, ep->dev->address, ep_id);
if (ret < FXHCI_CC_ZERO_BYTES)
{
if (ret == FXHCI_CC_TIMEOUT)
{
FUSB_INFO("Stopping ID %d EP %d ",
ep->dev->address, ep_id);
FXhciCmdStopEp(xhci, ep->dev->address, ep_id);
}
FUSB_INFO("Bulk transfer failed: %d \r\n"
" ep state: %d -> %d \r\n"
" usbsts: 0x%08x ",
ret, ep_state,
FXHCI_EC_GET(STATE, epctx),
FXhciReadOper32(&xhci->mmio, FXHCI_REG_OP_USBSTS));
return ret;
}
return ret;
}
/**
* @name: FXhciNextTrb
* @msg: 获取下一个可用的TRB
* @return {FXhciTrb*} 可用的TRB
* @param {FXhciTrb} *cur, 当前TRB
* @param {int} *pcs, 传入的待反转的Cycle state
*/
static FXhciTrb *FXhciNextTrb(FXhciTrb *cur, int *const pcs)
{
FASSERT(cur);
++cur;
while (FXHCI_TRB_GET(TT, cur) == FXHCI_TRB_LINK)
{
if (pcs && FXHCI_TRB_GET(TC, cur))
*pcs ^= 1;
cur = (void *)(uintptr)(cur->ptr_low);
}
return cur;
}
/**
* @name: FXhciCreateIntrQueue
* @msg: 创建XHCI的中断队列
* @return {void *} 成功则返回指向中断队列的指针失败返回NULL
* @param {FUsbEndpoint} *ep, 端点实例
* @param {int} reqsize, 中断队列可接受的请求字节数
* @param {int} reqcount, 中断队列可接受的最大请求数目
* @param {int} reqtiming, 请求超时
* @note create and hook-up an intr queue into device schedul
*/
static void *FXhciCreateIntrQueue(FUsbEndpoint *const ep, const int reqsize, const int reqcount,
const int reqtiming)
{
/* reqtiming: We ignore it and use the interval from the
endpoint descriptor configured earlier. */
FASSERT(ep);
FXhci *const xhci = FXHCI_INST_GET(ep->dev->controller);
FASSERT(xhci && xhci->usb);
FUsb *instance = xhci->usb;
const int slot_id = ep->dev->address;
const int ep_id = FXhciEpId(ep);
FXhciTransRing *const tr = xhci->dev[slot_id].transfer_rings[ep_id];
if (reqcount > (FXHCI_TRANSFER_RING_SIZE - 2))
{
FUSB_INFO("reqcount is too high, at most %d supported ",
FXHCI_TRANSFER_RING_SIZE - 2);
return NULL;
}
if (reqsize > 0x10000)
{
FUSB_INFO("reqsize is too large, at most 64KiB supported ");
return NULL;
}
if (xhci->dev[slot_id].interrupt_queues[ep_id])
{
FUSB_INFO("Only one interrupt queue per endpoint supported ");
return NULL;
}
/* Allocate intrq structure and reqdata chunks */
FXhciIntrQ *const intrq = FUSB_ALLOCATE(instance, sizeof(*intrq), FUSB_DEFAULT_ALIGN);
if (NULL == intrq)
{
FUSB_INFO("Out of memory ");
return NULL;
}
int i;
int pcs = tr->pcs;
FXhciTrb *cur = tr->cur;
for (i = 0; i < reqcount; ++i)
{
if (FXHCI_TRB_GET(C, cur) == (unsigned int)pcs)
{
FUSB_INFO("Not enough empty TRBs ");
goto _free_return;
}
/* allocate request buffer for each TRB */
void *const reqdata = FXHCI_ALIGN(xhci, 1, reqsize);
if (NULL == reqdata)
{
FUSB_INFO("Out of memory ");
goto _free_return;
}
FXhciClearTrb(cur, pcs);
cur->ptr_low = (uintptr)(reqdata);
cur->ptr_high = 0;
FXHCI_TRB_SET(TL, cur, reqsize); /* Transfer Length */
FXHCI_TRB_SET(TT, cur, FXHCI_TRB_NORMAL); /* TRB Type */
FXHCI_TRB_SET(ISP, cur, 1); /* Interrupt-on Short Packet */
FXHCI_TRB_SET(IOC, cur, 1); /* Interrupt On Completion */
cur = FXhciNextTrb(cur, &pcs);
}
intrq->size = reqsize;
intrq->count = reqcount;
intrq->next = tr->cur;
intrq->ready = NULL;
intrq->ep = ep;
xhci->dev[slot_id].interrupt_queues[ep_id] = intrq;
/* Now enqueue all the prepared TRBs but the last
and ring the doorbell. */
for (i = 0; i < (reqcount - 1); ++i)
FXhciEnqueueTrb(tr);
FXhciRingDoorbell(ep);
return intrq;
_free_return:
cur = tr->cur;
for (--i; i >= 0; --i)
{
FUSB_FREE(instance, (void *)(uintptr)(cur->ptr_low));
cur = FXhciNextTrb(cur, NULL);
}
FUSB_FREE(instance, intrq);
return NULL;
}
/**
* @name: FXhciDestoryIntrQueue
* @msg: 删除中断队列
* @return {*}
* @param {FUsbEndpoint} *ep, 端点实例
* @param {void} *q, 中断队列
* @note remove queue from device schedule, dropping all data that came in
*/
static void FXhciDestoryIntrQueue(FUsbEndpoint *const ep, void *const q)
{
FASSERT(ep && q);
FXhci *const xhci = FXHCI_INST_GET(ep->dev->controller);
FASSERT(xhci);
FUsb *instance = xhci->usb;
const int slot_id = ep->dev->address;
const int ep_id = FXhciEpId(ep);
FXhciTransRing *const tr = xhci->dev[slot_id].transfer_rings[ep_id];
FXhciIntrQ *const intrq = (FXhciIntrQ *)q;
/* Make sure the endpoint is stopped */
if (FXHCI_EC_GET(STATE, xhci->dev[slot_id].ctx.ep[ep_id]) == FXHCI_EC_STATE_RUNNING)
{
const FXhciTransCode cc = FXhciCmdStopEp(xhci, slot_id, ep_id);
if (cc != FXHCI_CC_SUCCESS)
FUSB_INFO("Warning: Failed to stop endpoint ");
}
/* Process all remaining transfer events */
FXhciHandleEvts(xhci);
/* Free all pending transfers and the interrupt queue structure */
int i;
for (i = 0; (size_t)i < intrq->count; ++i)
{
FUSB_FREE(instance, (void *)(uintptr)(intrq->next->ptr_low));
intrq->next = FXhciNextTrb(intrq->next, NULL);
}
xhci->dev[slot_id].interrupt_queues[ep_id] = NULL;
FUSB_FREE(instance, (void *)intrq);
/* Reset the controller's dequeue pointer and reinitialize the ring */
FXhciCmdSetTrDq(xhci, slot_id, ep_id, tr->ring, 1);
FXhciInitCycleRing(tr, FXHCI_TRANSFER_RING_SIZE);
return;
}
/**
* @name: FXhciPollIntrQueue
* @msg: 轮询一次中断队列进行处理
* @return {*}
* @param {void} *q, 中断队列
* @note 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 *FXhciPollIntrQueue(void *const q)
{
if (NULL == q)
return NULL;
FXhciIntrQ *const intrq = (FXhciIntrQ *)q;
FUsbEndpoint *const ep = intrq->ep;
FXhci *const xhci = FXHCI_INST_GET(ep->dev->controller);
FASSERT(xhci);
/* TODO: Reset interrupt queue if it gets halted? */
FXhciHandleEvts(xhci);
u8 *reqdata = NULL;
while (!reqdata && intrq->ready)
{
const int ep_id = FXhciEpId(ep);
FXhciTransRing *const tr =
xhci->dev[ep->dev->address].transfer_rings[ep_id];
/* Fetch the request's buffer */
reqdata = (void *)(uintptr)(intrq->next->ptr_low);
/* Enqueue the last (spare) TRB and ring doorbell */
FXhciEnqueueTrb(tr);
FXhciRingDoorbell(ep);
/* Reuse the current buffer for the next spare TRB */
FXhciClearTrb(tr->cur, tr->pcs);
tr->cur->ptr_low = (uintptr)(reqdata);
tr->cur->ptr_high = 0;
FXHCI_TRB_SET(TL, tr->cur, intrq->size); /* Transfer Length */
FXHCI_TRB_SET(TT, tr->cur, FXHCI_TRB_NORMAL); /* TRB Type */
FXHCI_TRB_SET(ISP, tr->cur, 1); /* Interrupt-on Short Packet */
FXHCI_TRB_SET(IOC, tr->cur, 1); /* Interrupt On Completion */
/* Check if anything was transferred */
const size_t read = FXHCI_TRB_GET(TL, intrq->next);
if (!read)
reqdata = NULL;
else if (read < intrq->size)
/* At least zero it, poll interface is rather limited */
memset(reqdata + read, 0x00, intrq->size - read);
/* Advance the interrupt queue */
if (intrq->ready == intrq->next)
/* This was last TRB being ready */
intrq->ready = NULL;
intrq->next = FXhciNextTrb(intrq->next, NULL);
}
return reqdata;
}