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|
/*
* The MIT License (MIT)
*
* Copyright (c) 2019 Ha Thach (tinyusb.org)
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*
* This file is part of the TinyUSB stack.
*/
#include "host/hcd_attr.h"
#if TUSB_OPT_HOST_ENABLED && defined(HCD_ATTR_OHCI)
//--------------------------------------------------------------------+
// INCLUDE
//--------------------------------------------------------------------+
#include "osal/osal.h"
#include "host/hcd.h"
#include "ohci.h"
// TODO remove
#include "chip.h"
//--------------------------------------------------------------------+
// MACRO CONSTANT TYPEDEF
//--------------------------------------------------------------------+
#define OHCI_REG ((ohci_registers_t *) LPC_USB_BASE)
enum {
OHCI_CONTROL_FUNCSTATE_RESET = 0,
OHCI_CONTROL_FUNCSTATE_RESUME,
OHCI_CONTROL_FUNCSTATE_OPERATIONAL,
OHCI_CONTROL_FUNCSTATE_SUSPEND
};
enum {
OHCI_CONTROL_CONTROL_BULK_RATIO = 3, ///< This specifies the service ratio between Control and Bulk EDs. 0 = 1:1, 3 = 4:1
OHCI_CONTROL_LIST_PERIODIC_ENABLE_MASK = TU_BIT(2),
OHCI_CONTROL_LIST_ISOCHRONOUS_ENABLE_MASK = TU_BIT(3),
OHCI_CONTROL_LIST_CONTROL_ENABLE_MASK = TU_BIT(4),
OHCI_CONTROL_LIST_BULK_ENABLE_MASK = TU_BIT(5),
};
enum {
OHCI_FMINTERVAL_FI = 0x2EDF, // 7.3.1 nominal (reset) value
OHCI_FMINTERVAL_FSMPS = (6*(OHCI_FMINTERVAL_FI-210)) / 7, // 5.4 calculated based on maximum overhead + bit stuffing
};
enum {
OHCI_PERIODIC_START = 0x3E67
};
enum {
OHCI_INT_SCHEDULING_OVERUN_MASK = TU_BIT(0),
OHCI_INT_WRITEBACK_DONEHEAD_MASK = TU_BIT(1),
OHCI_INT_SOF_MASK = TU_BIT(2),
OHCI_INT_RESUME_DETECTED_MASK = TU_BIT(3),
OHCI_INT_UNRECOVERABLE_ERROR_MASK = TU_BIT(4),
OHCI_INT_FRAME_OVERFLOW_MASK = TU_BIT(5),
OHCI_INT_RHPORT_STATUS_CHANGE_MASK = TU_BIT(6),
OHCI_INT_OWNERSHIP_CHANGE_MASK = TU_BIT(30),
OHCI_INT_MASTER_ENABLE_MASK = TU_BIT(31),
};
enum {
RHPORT_CURRENT_CONNECT_STATUS_MASK = TU_BIT(0),
RHPORT_PORT_ENABLE_STATUS_MASK = TU_BIT(1),
RHPORT_PORT_SUSPEND_STATUS_MASK = TU_BIT(2),
RHPORT_PORT_OVER_CURRENT_INDICATOR_MASK = TU_BIT(3),
RHPORT_PORT_RESET_STATUS_MASK = TU_BIT(4), ///< write '1' to reset port
RHPORT_PORT_POWER_STATUS_MASK = TU_BIT(8),
RHPORT_LOW_SPEED_DEVICE_ATTACHED_MASK = TU_BIT(9),
RHPORT_CONNECT_STATUS_CHANGE_MASK = TU_BIT(16),
RHPORT_PORT_ENABLE_CHANGE_MASK = TU_BIT(17),
RHPORT_PORT_SUSPEND_CHANGE_MASK = TU_BIT(18),
RHPORT_OVER_CURRENT_CHANGE_MASK = TU_BIT(19),
RHPORT_PORT_RESET_CHANGE_MASK = TU_BIT(20),
RHPORT_ALL_CHANGE_MASK = RHPORT_CONNECT_STATUS_CHANGE_MASK | RHPORT_PORT_ENABLE_CHANGE_MASK |
RHPORT_PORT_SUSPEND_CHANGE_MASK | RHPORT_OVER_CURRENT_CHANGE_MASK | RHPORT_PORT_RESET_CHANGE_MASK
};
enum {
OHCI_CCODE_NO_ERROR = 0,
OHCI_CCODE_CRC = 1,
OHCI_CCODE_BIT_STUFFING = 2,
OHCI_CCODE_DATA_TOGGLE_MISMATCH = 3,
OHCI_CCODE_STALL = 4,
OHCI_CCODE_DEVICE_NOT_RESPONDING = 5,
OHCI_CCODE_PID_CHECK_FAILURE = 6,
OHCI_CCODE_UNEXPECTED_PID = 7,
OHCI_CCODE_DATA_OVERRUN = 8,
OHCI_CCODE_DATA_UNDERRUN = 9,
OHCI_CCODE_BUFFER_OVERRUN = 12,
OHCI_CCODE_BUFFER_UNDERRUN = 13,
OHCI_CCODE_NOT_ACCESSED = 14,
};
enum {
OHCI_INT_ON_COMPLETE_YES = 0,
OHCI_INT_ON_COMPLETE_NO = TU_BIN8(111)
};
enum {
GTD_DT_TOGGLE_CARRY = 0,
GTD_DT_DATA0 = TU_BIT(1) | 0,
GTD_DT_DATA1 = TU_BIT(1) | 1,
};
enum {
PID_SETUP = 0,
PID_OUT,
PID_IN,
};
enum {
PID_FROM_TD = 0,
};
//--------------------------------------------------------------------+
// INTERNAL OBJECT & FUNCTION DECLARATION
//--------------------------------------------------------------------+
CFG_TUSB_MEM_SECTION TU_ATTR_ALIGNED(256) static ohci_data_t ohci_data;
static ohci_ed_t * const p_ed_head[] =
{
[TUSB_XFER_CONTROL] = &ohci_data.control[0].ed,
[TUSB_XFER_BULK ] = &ohci_data.bulk_head_ed,
[TUSB_XFER_INTERRUPT] = &ohci_data.period_head_ed,
[TUSB_XFER_ISOCHRONOUS] = NULL // TODO Isochronous
};
static void ed_list_insert(ohci_ed_t * p_pre, ohci_ed_t * p_ed);
static void ed_list_remove_by_addr(ohci_ed_t * p_head, uint8_t dev_addr);
//--------------------------------------------------------------------+
// USBH-HCD API
//--------------------------------------------------------------------+
// Initialization according to 5.1.1.4
bool hcd_init(uint8_t rhport)
{
(void) rhport;
//------------- Data Structure init -------------//
tu_memclr(&ohci_data, sizeof(ohci_data_t));
for(uint8_t i=0; i<32; i++)
{ // assign all interrupt pointes to period head ed
ohci_data.hcca.interrupt_table[i] = (uint32_t) &ohci_data.period_head_ed;
}
ohci_data.control[0].ed.skip = 1;
ohci_data.bulk_head_ed.skip = 1;
ohci_data.period_head_ed.skip = 1;
// reset controller
OHCI_REG->command_status_bit.controller_reset = 1;
while( OHCI_REG->command_status_bit.controller_reset ) {} // should not take longer than 10 us
//------------- init ohci registers -------------//
OHCI_REG->control_head_ed = (uint32_t) &ohci_data.control[0].ed;
OHCI_REG->bulk_head_ed = (uint32_t) &ohci_data.bulk_head_ed;
OHCI_REG->hcca = (uint32_t) &ohci_data.hcca;
OHCI_REG->interrupt_disable = OHCI_REG->interrupt_enable; // disable all interrupts
OHCI_REG->interrupt_status = OHCI_REG->interrupt_status; // clear current set bits
OHCI_REG->interrupt_enable = OHCI_INT_WRITEBACK_DONEHEAD_MASK | OHCI_INT_RESUME_DETECTED_MASK |
OHCI_INT_UNRECOVERABLE_ERROR_MASK | OHCI_INT_FRAME_OVERFLOW_MASK | OHCI_INT_RHPORT_STATUS_CHANGE_MASK |
OHCI_INT_MASTER_ENABLE_MASK;
OHCI_REG->control |= OHCI_CONTROL_CONTROL_BULK_RATIO | OHCI_CONTROL_LIST_CONTROL_ENABLE_MASK |
OHCI_CONTROL_LIST_BULK_ENABLE_MASK | OHCI_CONTROL_LIST_PERIODIC_ENABLE_MASK; // TODO Isochronous
OHCI_REG->frame_interval = (OHCI_FMINTERVAL_FSMPS << 16) | OHCI_FMINTERVAL_FI;
OHCI_REG->periodic_start = (OHCI_FMINTERVAL_FI * 9) / 10; // Periodic start is 90% of frame interval
OHCI_REG->control_bit.hc_functional_state = OHCI_CONTROL_FUNCSTATE_OPERATIONAL; // make HC's state to operational state TODO use this to suspend (save power)
OHCI_REG->rh_status_bit.local_power_status_change = 1; // set global power for ports
return true;
}
uint32_t hcd_frame_number(uint8_t rhport)
{
(void) rhport;
return (ohci_data.frame_number_hi << 16) | OHCI_REG->frame_number;
}
//--------------------------------------------------------------------+
// PORT API
//--------------------------------------------------------------------+
void hcd_port_reset(uint8_t hostid)
{
(void) hostid;
OHCI_REG->rhport_status[0] = RHPORT_PORT_RESET_STATUS_MASK;
}
bool hcd_port_connect_status(uint8_t hostid)
{
(void) hostid;
return OHCI_REG->rhport_status_bit[0].current_connect_status;
}
tusb_speed_t hcd_port_speed_get(uint8_t hostid)
{
(void) hostid;
return OHCI_REG->rhport_status_bit[0].low_speed_device_attached ? TUSB_SPEED_LOW : TUSB_SPEED_FULL;
}
// endpoints are tied to an address, which only reclaim after a long delay when enumerating
// thus there is no need to make sure ED is not in HC's cahed as it will not for sure
void hcd_device_close(uint8_t rhport, uint8_t dev_addr)
{
// TODO OHCI
(void) rhport;
// addr0 serves as static head --> only set skip bit
if ( dev_addr == 0 )
{
ohci_data.control[0].ed.skip = 1;
}else
{
// remove control
ed_list_remove_by_addr( p_ed_head[TUSB_XFER_CONTROL], dev_addr);
// remove bulk
ed_list_remove_by_addr(p_ed_head[TUSB_XFER_BULK], dev_addr);
// remove interrupt
ed_list_remove_by_addr(p_ed_head[TUSB_XFER_INTERRUPT], dev_addr);
// TODO remove ISO
}
}
//--------------------------------------------------------------------+
// Controller API
//--------------------------------------------------------------------+
//--------------------------------------------------------------------+
// List Helper
//--------------------------------------------------------------------+
static inline tusb_xfer_type_t ed_get_xfer_type(ohci_ed_t const * const p_ed)
{
return (p_ed->ep_number == 0 ) ? TUSB_XFER_CONTROL :
(p_ed->is_iso ) ? TUSB_XFER_ISOCHRONOUS :
(p_ed->is_interrupt_xfer) ? TUSB_XFER_INTERRUPT : TUSB_XFER_BULK;
}
static void ed_init(ohci_ed_t *p_ed, uint8_t dev_addr, uint16_t ep_size, uint8_t ep_addr, uint8_t xfer_type, uint8_t interval)
{
(void) interval;
// address 0 is used as async head, which always on the list --> cannot be cleared
if (dev_addr != 0)
{
tu_memclr(p_ed, sizeof(ohci_ed_t));
}
hcd_devtree_info_t devtree_info;
hcd_devtree_get_info(dev_addr, &devtree_info);
p_ed->dev_addr = dev_addr;
p_ed->ep_number = ep_addr & 0x0F;
p_ed->pid = (xfer_type == TUSB_XFER_CONTROL) ? PID_FROM_TD : (tu_edpt_dir(ep_addr) ? PID_IN : PID_OUT);
p_ed->speed = devtree_info.speed;
p_ed->is_iso = (xfer_type == TUSB_XFER_ISOCHRONOUS) ? 1 : 0;
p_ed->max_packet_size = ep_size;
p_ed->used = 1;
p_ed->is_interrupt_xfer = (xfer_type == TUSB_XFER_INTERRUPT ? 1 : 0);
}
static void gtd_init(ohci_gtd_t* p_td, uint8_t* data_ptr, uint16_t total_bytes)
{
tu_memclr(p_td, sizeof(ohci_gtd_t));
p_td->used = 1;
p_td->expected_bytes = total_bytes;
p_td->buffer_rounding = 1; // less than queued length is not a error
p_td->delay_interrupt = OHCI_INT_ON_COMPLETE_NO;
p_td->condition_code = OHCI_CCODE_NOT_ACCESSED;
p_td->current_buffer_pointer = data_ptr;
p_td->buffer_end = total_bytes ? (data_ptr + total_bytes-1) : data_ptr;
}
static ohci_ed_t * ed_from_addr(uint8_t dev_addr, uint8_t ep_addr)
{
if ( tu_edpt_number(ep_addr) == 0 ) return &ohci_data.control[dev_addr].ed;
ohci_ed_t* ed_pool = ohci_data.ed_pool;
for(uint32_t i=0; i<HCD_MAX_ENDPOINT; i++)
{
if ( (ed_pool[i].dev_addr == dev_addr) &&
ep_addr == tu_edpt_addr(ed_pool[i].ep_number, ed_pool[i].pid == PID_IN) )
{
return &ed_pool[i];
}
}
return NULL;
}
static ohci_ed_t * ed_find_free(void)
{
ohci_ed_t* ed_pool = ohci_data.ed_pool;
for(uint8_t i = 0; i < HCD_MAX_ENDPOINT; i++)
{
if ( !ed_pool[i].used ) return &ed_pool[i];
}
return NULL;
}
static void ed_list_insert(ohci_ed_t * p_pre, ohci_ed_t * p_ed)
{
p_ed->next = p_pre->next;
p_pre->next = (uint32_t) p_ed;
}
static void ed_list_remove_by_addr(ohci_ed_t * p_head, uint8_t dev_addr)
{
ohci_ed_t* p_prev = p_head;
while( p_prev->next )
{
ohci_ed_t* ed = (ohci_ed_t*) p_prev->next;
if (ed->dev_addr == dev_addr)
{
// unlink ed
p_prev->next = ed->next;
// point the removed ED's next pointer to list head to make sure HC can always safely move away from this ED
ed->next = (uint32_t) p_head;
ed->used = 0;
}
// check next valid since we could remove it
if (p_prev->next) p_prev = (ohci_ed_t*) p_prev->next;
}
}
static ohci_gtd_t * gtd_find_free(void)
{
for(uint8_t i=0; i < HCD_MAX_XFER; i++)
{
if ( !ohci_data.gtd_pool[i].used ) return &ohci_data.gtd_pool[i];
}
return NULL;
}
static void td_insert_to_ed(ohci_ed_t* p_ed, ohci_gtd_t * p_gtd)
{
// tail is always NULL
if ( tu_align16(p_ed->td_head.address) == 0 )
{ // TD queue is empty --> head = TD
p_ed->td_head.address |= (uint32_t) p_gtd;
}
else
{ // TODO currently only support queue up to 2 TD each endpoint at a time
((ohci_gtd_t*) tu_align16(p_ed->td_head.address))->next = (uint32_t) p_gtd;
}
}
//--------------------------------------------------------------------+
// Endpoint API
//--------------------------------------------------------------------+
bool hcd_edpt_open(uint8_t rhport, uint8_t dev_addr, tusb_desc_endpoint_t const * ep_desc)
{
(void) rhport;
// TODO iso support
TU_ASSERT(ep_desc->bmAttributes.xfer != TUSB_XFER_ISOCHRONOUS);
//------------- Prepare Queue Head -------------//
ohci_ed_t * p_ed;
if ( ep_desc->bEndpointAddress == 0 )
{
p_ed = &ohci_data.control[dev_addr].ed;
}else
{
p_ed = ed_find_free();
}
TU_ASSERT(p_ed);
ed_init( p_ed, dev_addr, ep_desc->wMaxPacketSize.size, ep_desc->bEndpointAddress,
ep_desc->bmAttributes.xfer, ep_desc->bInterval );
// control of dev0 is used as static async head
if ( dev_addr == 0 )
{
p_ed->skip = 0; // only need to clear skip bit
return true;
}
ed_list_insert( p_ed_head[ep_desc->bmAttributes.xfer], p_ed );
return true;
}
bool hcd_setup_send(uint8_t rhport, uint8_t dev_addr, uint8_t const setup_packet[8])
{
(void) rhport;
ohci_ed_t* ed = &ohci_data.control[dev_addr].ed;
ohci_gtd_t *qtd = &ohci_data.control[dev_addr].gtd;
gtd_init(qtd, (uint8_t*) setup_packet, 8);
qtd->index = dev_addr;
qtd->pid = PID_SETUP;
qtd->data_toggle = GTD_DT_DATA0;
qtd->delay_interrupt = 0;
//------------- Attach TDs list to Control Endpoint -------------//
ed->td_head.address = (uint32_t) qtd;
OHCI_REG->command_status_bit.control_list_filled = 1;
return true;
}
bool hcd_edpt_xfer(uint8_t rhport, uint8_t dev_addr, uint8_t ep_addr, uint8_t * buffer, uint16_t buflen)
{
(void) rhport;
uint8_t const epnum = tu_edpt_number(ep_addr);
uint8_t const dir = tu_edpt_dir(ep_addr);
if ( epnum == 0 )
{
ohci_ed_t* ed = &ohci_data.control[dev_addr].ed;
ohci_gtd_t* gtd = &ohci_data.control[dev_addr].gtd;
gtd_init(gtd, buffer, buflen);
gtd->index = dev_addr;
gtd->pid = dir ? PID_IN : PID_OUT;
gtd->data_toggle = GTD_DT_DATA1; // Both Data and Ack stage start with DATA1
gtd->delay_interrupt = 0;
ed->td_head.address = (uint32_t) gtd;
OHCI_REG->command_status_bit.control_list_filled = 1;
}else
{
ohci_ed_t * ed = ed_from_addr(dev_addr, ep_addr);
ohci_gtd_t* gtd = gtd_find_free();
TU_ASSERT(gtd);
gtd_init(gtd, buffer, buflen);
gtd->index = ed-ohci_data.ed_pool;
gtd->delay_interrupt = 0;
td_insert_to_ed(ed, gtd);
tusb_xfer_type_t xfer_type = ed_get_xfer_type( ed_from_addr(dev_addr, ep_addr) );
if (TUSB_XFER_BULK == xfer_type) OHCI_REG->command_status_bit.bulk_list_filled = 1;
}
return true;
}
bool hcd_edpt_clear_stall(uint8_t dev_addr, uint8_t ep_addr)
{
ohci_ed_t * const p_ed = ed_from_addr(dev_addr, ep_addr);
p_ed->is_stalled = 0;
p_ed->td_tail &= 0x0Ful; // set tail pointer back to NULL
p_ed->td_head.toggle = 0; // reset data toggle
p_ed->td_head.halted = 0;
if ( TUSB_XFER_BULK == ed_get_xfer_type(p_ed) ) OHCI_REG->command_status_bit.bulk_list_filled = 1;
return true;
}
//--------------------------------------------------------------------+
// OHCI Interrupt Handler
//--------------------------------------------------------------------+
static ohci_td_item_t* list_reverse(ohci_td_item_t* td_head)
{
ohci_td_item_t* td_reverse_head = NULL;
while(td_head != NULL)
{
uint32_t next = td_head->next;
// make current's item become reverse's first item
td_head->next = (uint32_t) td_reverse_head;
td_reverse_head = td_head;
td_head = (ohci_td_item_t*) next; // advance to next item
}
return td_reverse_head;
}
static inline bool gtd_is_control(ohci_gtd_t const * const p_qtd)
{
return ((uint32_t) p_qtd) < ((uint32_t) ohci_data.gtd_pool); // check ohci_data_t for memory layout
}
static inline ohci_ed_t* gtd_get_ed(ohci_gtd_t const * const p_qtd)
{
if ( gtd_is_control(p_qtd) )
{
return &ohci_data.control[p_qtd->index].ed;
}else
{
return &ohci_data.ed_pool[p_qtd->index];
}
}
static inline uint32_t gtd_xfer_byte_left(uint32_t buffer_end, uint32_t current_buffer)
{
// 5.2.9 OHCI sample code
// CBP is 0 mean all data is transferred
if (current_buffer == 0) return 0;
return (tu_align4k(buffer_end ^ current_buffer) ? 0x1000 : 0) +
tu_offset4k(buffer_end) - tu_offset4k(current_buffer) + 1;
}
static void done_queue_isr(uint8_t hostid)
{
(void) hostid;
// done head is written in reversed order of completion --> need to reverse the done queue first
ohci_td_item_t* td_head = list_reverse ( (ohci_td_item_t*) tu_align16(ohci_data.hcca.done_head) );
while( td_head != NULL )
{
// TODO check if td_head is iso td
//------------- Non ISO transfer -------------//
ohci_gtd_t * const qtd = (ohci_gtd_t *) td_head;
xfer_result_t const event = (qtd->condition_code == OHCI_CCODE_NO_ERROR) ? XFER_RESULT_SUCCESS :
(qtd->condition_code == OHCI_CCODE_STALL) ? XFER_RESULT_STALLED : XFER_RESULT_FAILED;
qtd->used = 0; // free TD
if ( (qtd->delay_interrupt == OHCI_INT_ON_COMPLETE_YES) || (event != XFER_RESULT_SUCCESS) )
{
ohci_ed_t * const ed = gtd_get_ed(qtd);
uint32_t const xferred_bytes = qtd->expected_bytes - gtd_xfer_byte_left((uint32_t) qtd->buffer_end, (uint32_t) qtd->current_buffer_pointer);
// NOTE Assuming the current list is BULK and there is no other EDs in the list has queued TDs.
// When there is a error resulting this ED is halted, and this EP still has other queued TD
// --> the Bulk list only has this halted EP queueing TDs (remaining)
// --> Bulk list will be considered as not empty by HC !!! while there is no attempt transaction on this list
// --> HC will not process Control list (due to service ratio when Bulk list not empty)
// To walk-around this, the halted ED will have TailP = HeadP (empty list condition), when clearing halt
// the TailP must be set back to NULL for processing remaining TDs
if ((event != XFER_RESULT_SUCCESS))
{
ed->td_tail &= 0x0Ful;
ed->td_tail |= tu_align16(ed->td_head.address); // mark halted EP as empty queue
if ( event == XFER_RESULT_STALLED ) ed->is_stalled = 1;
}
uint8_t dir = (ed->ep_number == 0) ? (qtd->pid == PID_IN) : (ed->pid == PID_IN);
hcd_event_xfer_complete(ed->dev_addr, tu_edpt_addr(ed->ep_number, dir), xferred_bytes, event, true);
}
td_head = (ohci_td_item_t*) td_head->next;
}
}
void hcd_int_handler(uint8_t hostid)
{
uint32_t const int_en = OHCI_REG->interrupt_enable;
uint32_t const int_status = OHCI_REG->interrupt_status & int_en;
if (int_status == 0) return;
// Frame number overflow
if ( int_status & OHCI_INT_FRAME_OVERFLOW_MASK )
{
ohci_data.frame_number_hi++;
}
//------------- RootHub status -------------//
if ( int_status & OHCI_INT_RHPORT_STATUS_CHANGE_MASK )
{
uint32_t const rhport_status = OHCI_REG->rhport_status[0] & RHPORT_ALL_CHANGE_MASK;
// TODO dual port is not yet supported
if ( rhport_status & RHPORT_CONNECT_STATUS_CHANGE_MASK )
{
// TODO check if remote wake-up
if ( OHCI_REG->rhport_status_bit[0].current_connect_status )
{
// TODO reset port immediately, without this controller will got 2-3 (debouncing connection status change)
OHCI_REG->rhport_status[0] = RHPORT_PORT_RESET_STATUS_MASK;
hcd_event_device_attach(hostid, true);
}else
{
hcd_event_device_remove(hostid, true);
}
}
if ( rhport_status & RHPORT_PORT_SUSPEND_CHANGE_MASK)
{
}
OHCI_REG->rhport_status[0] = rhport_status; // acknowledge all interrupt
}
//------------- Transfer Complete -------------//
if (int_status & OHCI_INT_WRITEBACK_DONEHEAD_MASK)
{
done_queue_isr(hostid);
}
OHCI_REG->interrupt_status = int_status; // Acknowledge handled interrupt
}
//--------------------------------------------------------------------+
// HELPER
//--------------------------------------------------------------------+
#endif
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