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PaulStoffregen pirms 7 gadiem
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5 mainītis faili ar 143 papildinājumiem un 8 dzēšanām
  1. +27
    -0
      USBHost_t36.h
  2. +45
    -1
      ehci.cpp
  3. +35
    -2
      enumeration.cpp
  4. +31
    -5
      memory.cpp
  5. +5
    -0
      print.cpp

+ 27
- 0
USBHost_t36.h Parādīt failu

@@ -26,6 +26,33 @@

#include <stdint.h>


// Dear inquisitive reader, USB is a complex protocol defined with
// very specific terminology. To have any chance of understand this
// source code, you absolutely must have solid knowledge of specific
// USB terms such as host, device, endpoint, pipe, enumeration....
// You really must also have at least a basic knowledge of the
// different USB transfers: control, bulk, interrupt, isochronous.
//
// The USB 2.0 specification explains these in chapter 4 (pages 15
// to 24), and provides more detail in the first part of chapter 5
// (pages 25 to 55). The USB spec is published for free at
// www.usb.org. Here is a convenient link to just the main PDF:
//
// https://www.pjrc.com/teensy/beta/usb20.pdf
//
// This is a huge file, but chapter 4 is short and easy to read.
// If you're not familiar with the USB lingo, please do yourself
// a favor by reading at least chapter 4 to get up to speed on the
// meaning of these important USB concepts and terminology.
//
// If you wish to ask questions (which belong on the forum, not
// github issues) or discuss development of this library, you
// ABSOLUTELY MUST know the basic USB terminology from chapter 4.
// Please repect other people's valuable time & effort by making
// your best effort to read chapter 4 before asking USB questions!


#define USBHOST_PRINT_DEBUG

/************************************************/

+ 45
- 1
ehci.cpp Parādīt failu

@@ -24,25 +24,69 @@
#include <Arduino.h>
#include "USBHost_t36.h" // Read this header first for key info

// All USB EHCI controller hardware access is done from this file's code.
// Hardware services are made available to the rest of this library by
// three structures:
//
// Pipe_t: Every USB endpoint is accessed by a pipe. new_Pipe()
// sets up the EHCI to support the pipe/endpoint, and delete_Pipe()
// removes this configuration.
//
// Transfer_t: These are used for all communication. Data transfers
// are placed into work queues, to be executed by the EHCI in
// the future. Transfer_t only manages data. The actual data
// is stored in a separate buffer (usually from a device driver)
// which is referenced from Transfer_t. All data transfer is queued,
// never done with blocking functions that wait. When transfers
// complete, a driver-supplied callback function is called to notify
// the driver.
//
// USBDriverTimer: Some drivers require timers. These allow drivers
// to share the hardware timer, with each USBDriverTimer object
// able to schedule a callback function a configurable number of
// microseconds in the future.
//
// In addition to these 3 services, the EHCI interrupt also responds
// to changes on the main port, creating and deleting the root device.
// See enumeration.cpp for all device-level code.

// Size of the periodic list, in milliseconds. This determines the
// slowest rate we can poll interrupt endpoints. Each entry uses
// 12 bytes (4 for a pointer, 8 for bandwidth management).
// may be 8, 16, 32, 64, 128, 256, 512, 1024
// Supported values: 8, 16, 32, 64, 128, 256, 512, 1024
#define PERIODIC_LIST_SIZE 32

// The EHCI periodic schedule, used for interrupt pipes/endpoints
static uint32_t periodictable[PERIODIC_LIST_SIZE] __attribute__ ((aligned(4096), used));
static uint8_t uframe_bandwidth[PERIODIC_LIST_SIZE*8];

// State of the 1 and only physical USB host port on Teensy 3.6
static uint8_t port_state;
#define PORT_STATE_DISCONNECTED 0
#define PORT_STATE_DEBOUNCE 1
#define PORT_STATE_RESET 2
#define PORT_STATE_RECOVERY 3
#define PORT_STATE_ACTIVE 4

// The device currently connected, or NULL when no device
static Device_t *rootdev=NULL;

// List of all queued transfers in the asychronous schedule (control & bulk).
// When the EHCI completes these transfers, this list is how we locate them
// in memory.
static Transfer_t *async_followup_first=NULL;
static Transfer_t *async_followup_last=NULL;

// List of all queued transfers in the asychronous schedule (interrupt endpoints)
// When the EHCI completes these transfers, this list is how we locate them
// in memory.
static Transfer_t *periodic_followup_first=NULL;
static Transfer_t *periodic_followup_last=NULL;

// List of all pending timers. This double linked list is stored in
// chronological order. Each timer is stored with the number of
// microseconds which need to elapsed from the prior timer on this
// list, to allow efficient servicing from the timer interrupt.
static USBDriverTimer *active_timers=NULL;



+ 35
- 2
enumeration.cpp Parādīt failu

@@ -25,21 +25,43 @@
#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;
static Device_t *devlist=NULL;

// 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);


// 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) {
@@ -49,6 +71,12 @@ void USBHost::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;
@@ -107,7 +135,12 @@ Device_t * USBHost::new_Device(uint32_t speed, uint32_t hub_addr, uint32_t hub_p
}



// 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;

+ 31
- 5
memory.cpp Parādīt failu

@@ -25,16 +25,42 @@
#include "USBHost_t36.h" // Read this header first for key info


// Memory allocation
// Memory allocation for Device_t, Pipe_t and Transfer_t structures.
//
// To provide an Arduino-friendly experience, the memory allocation of
// these item is primarily done by the instances of device driver objects,
// which are typically created as static objects near the beginning of
// the Arduino sketch. Static allocation allows Arduino's memory usage
// summary to accurately show the amount of RAM this library is using.
// Users can choose which devices they wish to support and how many of
// each by creating more object instances.
//
// Device driver objects "contribute" their copies of these structures.
// When ehci.cpp allocates Pipe_t and Transfer_t, or enumeration.cpp
// allocates Device_t, the memory actually comes from these structures
// physically located within the device driver instances. The usage
// model looks like traditional malloc/free dynamic memory on the heap,
// but in fact it's a simple memory pool from the drivers.
//
// Timing is deterministic and fast, because each pool allocates only
// a single fixed size object. In theory, each driver should contribute
// the number of items it will use, so we should not ever end up with
// a situation where an item can't be allocated when it's needed. Well,
// unless there's a bug or oversight...


// Lists of "free" memory
static Device_t * free_Device_list = NULL;
static Pipe_t * free_Pipe_list = NULL;
static Transfer_t * free_Transfer_list = NULL;

// A small amount of non-driver memory, just to get things started
// TODO: is this really necessary? Can these be eliminated, so we
// use only memory from the drivers?
static Device_t memory_Device[1];
static Pipe_t memory_Pipe[1] __attribute__ ((aligned(32)));
static Transfer_t memory_Transfer[4] __attribute__ ((aligned(32)));

static Device_t * free_Device_list = NULL;
static Pipe_t * free_Pipe_list = NULL;
static Transfer_t * free_Transfer_list = NULL;

void USBHost::init_Device_Pipe_Transfer_memory(void)
{
contribute_Devices(memory_Device, sizeof(memory_Device)/sizeof(Device_t));

+ 5
- 0
print.cpp Parādīt failu

@@ -24,6 +24,11 @@
#include <Arduino.h>
#include "USBHost_t36.h" // Read this header first for key info

// Printing of specific data structures. When this is enabled,
// a tremendous amount of debug printing occurs. It's done all
// from interrupt context, so this should never normally be
// enabled for regular programs that print from the Arduino sketch.

#ifdef USBHOST_PRINT_DEBUG

void USBHost::print(const Transfer_t *transfer)

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