1
0
mirror of https://github.com/gdsports/USBHost_t36 synced 2024-11-24 01:52:23 -05:00
USBHost_t36/enumeration.cpp
Kurt Eckhardt 4e2ea2d96e String buffers - Devices contribute buffers
instead of having each HUB have 7 buffers, which can eat up space.  We have each main object contribute currently one string buffer, which than when we initialize a Device_t we try to allocate one for it, likewise we release it when the Device is released.

Hopefully less memory needed.

Also updated such that the HIDInput classes can not retrieve these strings.

Changed test program to now also have list of HIDInput objects and when I detect a new one, I again print out info on it...
2017-10-19 14:57:52 -07:00

475 lines
16 KiB
C++

/* USB EHCI Host for Teensy 3.6
* Copyright 2017 Paul Stoffregen (paul@pjrc.com)
*
* 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.
*/
#include <Arduino.h>
#include "USBHost_t36.h" // Read this header first for key info
// USB devices are managed from this file.
// List of all connected devices, regardless of their status. If
// it's connected to the EHCI port or any port on any hub, it needs
// to be linked into this list.
static Device_t *devlist=NULL;
// List of all inactive drivers. At the end of enumeration, when
// drivers claim the device or its interfaces, they are removed
// from this list and linked into the list of active drivers on
// that device. When devices disconnect, the drivers are returned
// to this list, making them again available for enumeration of new
// devices.
static USBDriver *available_drivers = NULL;
// Static buffers used during enumeration. One a single USB device
// may enumerate at once, because USB address zero is used, and
// because this static buffer & state info can't be shared.
static uint8_t enumbuf[256] __attribute__ ((aligned(16)));
static setup_t enumsetup __attribute__ ((aligned(16)));
static uint16_t enumlen;
// True while any device is present but not yet fully configured.
// Only one USB device may be in this state at a time (responding
// to address zero) and using the enumeration static buffer.
volatile bool USBHost::enumeration_busy = false;
static void pipe_set_maxlen(Pipe_t *pipe, uint32_t maxlen);
static void pipe_set_addr(Pipe_t *pipe, uint32_t addr);
#define print USBHost::print_
#define println USBHost::println_
// The main user function to cause internal state to update. Since we do
// almost everything with DMA and interrupts, the only work to do here is
// call all the active driver Task() functions.
void USBHost::Task()
{
for (Device_t *dev = devlist; dev; dev = dev->next) {
for (USBDriver *driver = dev->drivers; driver; driver = driver->next) {
(driver->Task)();
}
}
}
// Drivers call this after they've completed initialization, so get themselves
// added to the list of inactive drivers available for new devices during
// enumeraton. Typically this is called from constructors, so hardware access
// or even printing debug messages should be avoided here. Just initialize
// lists and return.
//
void USBHost::driver_ready_for_device(USBDriver *driver)
{
driver->device = NULL;
driver->next = NULL;
if (available_drivers == NULL) {
available_drivers = driver;
} else {
// append to end of list
USBDriver *last = available_drivers;
while (last->next) last = last->next;
last->next = driver;
}
}
// Create a new device and begin the enumeration process
//
Device_t * USBHost::new_Device(uint32_t speed, uint32_t hub_addr, uint32_t hub_port)
{
Device_t *dev;
print("new_Device: ");
switch (speed) {
case 0: print("12"); break;
case 1: print("1.5"); break;
case 2: print("480"); break;
default: print("??");
}
println(" Mbit/sec");
dev = allocate_Device();
if (!dev) return NULL;
memset(dev, 0, sizeof(Device_t));
dev->speed = speed;
dev->address = 0;
dev->hub_address = hub_addr;
dev->hub_port = hub_port;
dev->control_pipe = new_Pipe(dev, 0, 0, 0, 8);
if (!dev->control_pipe) {
free_Device(dev);
return NULL;
}
dev->strbuf = allocate_string_buffer(); // try to allocate a string buffer;
dev->control_pipe->callback_function = &enumeration;
dev->control_pipe->direction = 1; // 1=IN
// Here is where the enumeration process officially begins.
// Only a single device can enumerate at a time.
USBHost::enumeration_busy = true;
mk_setup(enumsetup, 0x80, 6, 0x0100, 0, 8); // 6=GET_DESCRIPTOR
queue_Control_Transfer(dev, &enumsetup, enumbuf, NULL);
if (devlist == NULL) {
devlist = dev;
} else {
Device_t *p;
for (p = devlist; p->next; p = p->next) ; // walk devlist
p->next = dev;
}
return dev;
}
// Control transfer callback function. ALL control transfers from all
// devices call this function when they complete. When control transfers
// are created by drivers, the driver is called to handle the result.
// Otherwise, the control transfer is part of the enumeration process,
// which is implemented here.
//
void USBHost::enumeration(const Transfer_t *transfer)
{
Device_t *dev;
uint32_t len;
// If a driver created this control transfer, allow it to process the result
if (transfer->driver) {
transfer->driver->control(transfer);
return;
}
println("enumeration:");
//print_hexbytes(transfer->buffer, transfer->length);
//print(transfer);
dev = transfer->pipe->device;
while (1) {
// Within this large switch/case, "break" means we've done
// some work, but more remains to be done in a different
// state. Generally break is used after parsing received
// data, but what happens next could be different states.
// When completed, return is used. Generally, return happens
// only after a new control transfer is queued, or when
// enumeration is complete and no more communication is needed.
switch (dev->enum_state) {
case 0: // read 8 bytes of device desc, set max packet, and send set address
pipe_set_maxlen(dev->control_pipe, enumbuf[7]);
mk_setup(enumsetup, 0, 5, assign_address(), 0, 0); // 5=SET_ADDRESS
queue_Control_Transfer(dev, &enumsetup, NULL, NULL);
dev->enum_state = 1;
return;
case 1: // request all 18 bytes of device descriptor
dev->address = enumsetup.wValue;
pipe_set_addr(dev->control_pipe, enumsetup.wValue);
mk_setup(enumsetup, 0x80, 6, 0x0100, 0, 18); // 6=GET_DESCRIPTOR
queue_Control_Transfer(dev, &enumsetup, enumbuf, NULL);
dev->enum_state = 2;
return;
case 2: // parse 18 device desc bytes
dev->bDeviceClass = enumbuf[4];
dev->bDeviceSubClass = enumbuf[5];
dev->bDeviceProtocol = enumbuf[6];
dev->idVendor = enumbuf[8] | (enumbuf[9] << 8);
dev->idProduct = enumbuf[10] | (enumbuf[11] << 8);
enumbuf[0] = enumbuf[14];
enumbuf[1] = enumbuf[15];
enumbuf[2] = enumbuf[16];
if ((enumbuf[0] | enumbuf[1] | enumbuf[2]) > 0) {
dev->enum_state = 3;
} else {
dev->enum_state = 11;
}
break;
case 3: // request Language ID
len = sizeof(enumbuf) - 4;
mk_setup(enumsetup, 0x80, 6, 0x0300, 0, len); // 6=GET_DESCRIPTOR
queue_Control_Transfer(dev, &enumsetup, enumbuf + 4, NULL);
dev->enum_state = 4;
return;
case 4: // parse Language ID
if (enumbuf[4] < 4 || enumbuf[5] != 3) {
dev->enum_state = 11;
} else {
dev->LanguageID = enumbuf[6] | (enumbuf[7] << 8);
if (enumbuf[0]) dev->enum_state = 5;
else if (enumbuf[1]) dev->enum_state = 7;
else if (enumbuf[2]) dev->enum_state = 9;
else dev->enum_state = 11;
}
break;
case 5: // request Manufacturer string
len = sizeof(enumbuf) - 4;
mk_setup(enumsetup, 0x80, 6, 0x0300 | enumbuf[0], dev->LanguageID, len);
queue_Control_Transfer(dev, &enumsetup, enumbuf + 4, NULL);
dev->enum_state = 6;
return;
case 6: // parse Manufacturer string
convertStringDescriptorToASCIIString(0, dev, transfer);
// TODO: receive the string...
if (enumbuf[1]) dev->enum_state = 7;
else if (enumbuf[2]) dev->enum_state = 9;
else dev->enum_state = 11;
break;
case 7: // request Product string
len = sizeof(enumbuf) - 4;
mk_setup(enumsetup, 0x80, 6, 0x0300 | enumbuf[1], dev->LanguageID, len);
queue_Control_Transfer(dev, &enumsetup, enumbuf + 4, NULL);
dev->enum_state = 8;
return;
case 8: // parse Product string
convertStringDescriptorToASCIIString(1, dev, transfer);
if (enumbuf[2]) dev->enum_state = 9;
else dev->enum_state = 11;
break;
case 9: // request Serial Number string
len = sizeof(enumbuf) - 4;
mk_setup(enumsetup, 0x80, 6, 0x0300 | enumbuf[2], dev->LanguageID, len);
queue_Control_Transfer(dev, &enumsetup, enumbuf + 4, NULL);
dev->enum_state = 10;
return;
case 10: // parse Serial Number string
convertStringDescriptorToASCIIString(2, dev, transfer);
dev->enum_state = 11;
break;
case 11: // request first 9 bytes of config desc
mk_setup(enumsetup, 0x80, 6, 0x0200, 0, 9); // 6=GET_DESCRIPTOR
queue_Control_Transfer(dev, &enumsetup, enumbuf, NULL);
dev->enum_state = 12;
return;
case 12: // read 9 bytes, request all of config desc
enumlen = enumbuf[2] | (enumbuf[3] << 8);
println("Config data length = ", enumlen);
if (enumlen > sizeof(enumbuf)) {
// TODO: how to handle device with too much config data
}
mk_setup(enumsetup, 0x80, 6, 0x0200, 0, enumlen); // 6=GET_DESCRIPTOR
queue_Control_Transfer(dev, &enumsetup, enumbuf, NULL);
dev->enum_state = 13;
return;
case 13: // read all config desc, send set config
println("bNumInterfaces = ", enumbuf[4]);
println("bConfigurationValue = ", enumbuf[5]);
dev->bmAttributes = enumbuf[7];
dev->bMaxPower = enumbuf[8];
// TODO: actually do something with interface descriptor?
mk_setup(enumsetup, 0, 9, enumbuf[5], 0, 0); // 9=SET_CONFIGURATION
queue_Control_Transfer(dev, &enumsetup, NULL, NULL);
dev->enum_state = 14;
return;
case 14: // device is now configured
claim_drivers(dev);
dev->enum_state = 15;
// unlock exclusive access to enumeration process. If any
// more devices are waiting, the hub driver is responsible
// for resetting their ports and starting their enumeration
// when the port enables.
USBHost::enumeration_busy = false;
return;
case 15: // control transfers for other stuff?
// TODO: handle other standard control: set/clear feature, etc
default:
return;
}
}
}
void USBHost::convertStringDescriptorToASCIIString(uint8_t string_index, Device_t *dev, const Transfer_t *transfer) {
strbuf_t *strbuf = dev->strbuf;
if (!strbuf) return; // don't have a buffer
uint8_t *buffer = (uint8_t*)transfer->buffer;
uint8_t buf_index = string_index? strbuf->iStrings[string_index]+1 : 0;
// Try to verify - The first byte should be length and the 2nd byte should be 0x3
if (!buffer || (buffer[1] != 0x3)) {
return; // No string so can simply return
}
strbuf->iStrings[string_index] = buf_index; // remember our starting positio
uint8_t count_bytes_returned = buffer[0];
if ((buf_index + count_bytes_returned/2) >= DEVICE_STRUCT_STRING_BUF_SIZE)
count_bytes_returned = (DEVICE_STRUCT_STRING_BUF_SIZE - buf_index) * 2;
// Now copy into our storage buffer.
for (uint8_t i = 2; (i < count_bytes_returned) && (buf_index < (DEVICE_STRUCT_STRING_BUF_SIZE -1)); i += 2) {
strbuf->buffer[buf_index++] = buffer[i];
}
strbuf->buffer[buf_index] = 0; // null terminate.
// Update other indexes to point to null character
while (++string_index < 3) {
strbuf->iStrings[string_index] = buf_index; // point to trailing NULL character
}
}
void USBHost::claim_drivers(Device_t *dev)
{
USBDriver *driver, *prev=NULL;
// first check if any driver wishes to claim the entire device
for (driver=available_drivers; driver != NULL; driver = driver->next) {
if (driver->device != NULL) continue;
if (driver->claim(dev, 0, enumbuf + 9, enumlen - 9)) {
if (prev) {
prev->next = driver->next;
} else {
available_drivers = driver->next;
}
driver->device = dev;
driver->next = NULL;
dev->drivers = driver;
return;
}
prev = driver;
}
// parse interfaces from config descriptor
const uint8_t *p = enumbuf + 9;
const uint8_t *end = enumbuf + enumlen;
while (p < end) {
uint8_t desclen = *p;
uint8_t desctype = *(p+1);
print("Descriptor ");
print(desctype);
print(" = ");
if (desctype == 4) println("INTERFACE");
else if (desctype == 5) println("ENDPOINT");
else if (desctype == 6) println("DEV_QUALIFIER");
else if (desctype == 7) println("OTHER_SPEED");
else if (desctype == 11) println("IAD");
else if (desctype == 33) println("HID");
else println(" ???");
if (desctype == 11 && desclen == 8) {
// TODO: parse IAD, ask drivers for claim
// TODO: how to skip over all interfaces IAD represented
}
if (desctype == 4 && desclen == 9) {
// found an interface, ask available drivers if they want it
prev = NULL;
for (driver=available_drivers; driver != NULL; driver = driver->next) {
if (driver->device != NULL) continue;
// TODO: should parse ahead and give claim()
// an accurate length. (end - p) is the rest
// of ALL descriptors, likely more interfaces
// this driver has no business parsing
if (driver->claim(dev, 1, p, end - p)) {
// this driver claims iface
// remove it from available_drivers list
if (prev) {
prev->next = driver->next;
} else {
available_drivers = driver->next;
}
// add to list of drivers using this device
driver->next = dev->drivers;
dev->drivers = driver;
driver->device = dev;
// not done, may be more interface for more drivers
}
prev = driver;
}
}
p += desclen;
}
}
static bool address_in_use(uint32_t addr)
{
for (Device_t *p = devlist; p; p = p->next) {
if (p->address == addr) return true;
}
return false;
}
uint32_t USBHost::assign_address(void)
{
static uint8_t last_assigned_address=0;
uint32_t addr = last_assigned_address;
while (1) {
if (++addr > 127) addr = 1;
if (!address_in_use(addr)) {
last_assigned_address = addr;
return addr;
}
}
}
static void pipe_set_maxlen(Pipe_t *pipe, uint32_t maxlen)
{
pipe->qh.capabilities[0] = (pipe->qh.capabilities[0] & 0x8000FFFF) | (maxlen << 16);
}
static void pipe_set_addr(Pipe_t *pipe, uint32_t addr)
{
pipe->qh.capabilities[0] = (pipe->qh.capabilities[0] & 0xFFFFFF80) | addr;
}
void USBHost::disconnect_Device(Device_t *dev)
{
if (!dev) return;
println("disconnect_Device:");
// Disconnect all drivers using this device. If this device is
// a hub, the hub driver is responsible for recursively calling
// this function to disconnect its downstream devices.
print_driverlist("available_drivers", available_drivers);
print_driverlist("dev->drivers", dev->drivers);
for (USBDriver *p = dev->drivers; p; ) {
println("disconnect driver ", (uint32_t)p, HEX);
p->disconnect();
p->device = NULL;
USBDriver *next = p->next;
p->next = available_drivers;
available_drivers = p;
p = next;
}
print_driverlist("available_drivers", available_drivers);
// delete all the pipes
for (Pipe_t *p = dev->data_pipes; p; ) {
Pipe_t *next = p->next;
delete_Pipe(p);
p = next;
}
delete_Pipe(dev->control_pipe);
// remove device from devlist and free its Device_t
Device_t *prev_dev = NULL;
for (Device_t *p = devlist; p; p = p->next) {
if (p == dev) {
if (prev_dev == NULL) {
devlist = p->next;
} else {
prev_dev->next = p->next;
}
println("removed Device_t from devlist");
if (p->strbuf != nullptr ) {
free_string_buffer(p->strbuf);
}
free_Device(p);
break;
}
prev_dev = p;
}
}