#include <cyg/io/usb/usbs.h>
typedef struct usbs_control_endpoint {
*hellip;
} usbs_control_endpoint; |
The device driver for a USB slave device should supply one
usbs_control_endpoint data structure per USB
device. This corresponds to endpoint 0 which will be used for all
control message interaction between the host and that device. The data
structure is also used for internal management purposes, for example
to keep track of the current state. In a typical USB peripheral there
will only be one such data structure in the entire system, but if
there are multiple USB slave ports, allowing the peripheral to be
connected to multiple hosts, then there will be a separate data
structure for each one. The name or names of the data structures are
determined by the device drivers. For example, the SA11x0 USB device
driver package provides usbs_sa11x0_ep0.
The operations on a control endpoint do not fit cleanly into a conventional open/read/write I/O model. For example, when the host sends a control message to the USB peripheral this may be one of four types: standard, class, vendor and reserved. Some or all of the standard control messages will be handled automatically by the common USB slave package or by the device driver itself. Other standard control messages and the other types of control messages may be handled by a class-specific package or by application code. Although it would be possible to have devtab entries such as /dev/usbs_ep0/standard and /dev/usbs_ep0/class, and then support read and write operations on these devtab entries, this would add significant overhead and code complexity. Instead, all of the fields in the control endpoint data structure are public and can be manipulated directly by higher level code if and when required.
Control endpoints involve a number of callback functions, with higher-level code installing suitable function pointers in the control endpoint data structure. For example, if the peripheral involves vendor-specific control messages then a suitable handler for these messages should be installed. Although the exact details depend on the device driver, typically these callback functions will be invoked at DSR level rather than thread level. Therefore, only certain eCos functions can be invoked; specifically, those functions that are guaranteed not to block. If a potentially blocking function such as a semaphore wait or a mutex lock operation is invoked from inside the callback then the resulting behaviour is undefined, and the system as a whole may fail. In addition, if one of the callback functions involves significant processing effort then this may adversely affect the system's real time characteristics. The eCos kernel documentation should be consulted for more details of DSR handling.
The usbs_control_endpoint data structure
contains the following fields related to initialization.
typedef struct usbs_control_endpoint {
…
const usbs_enumeration_data* enumeration_data;
void (*start_fn)(usbs_control_endpoint*);
…
}; |
It is the responsibility of higher-level code, usually the application, to define the USB enumeration data. This needs to be installed in the control endpoint data structure early on during system startup, before the USB device is actually started and any interaction with the host is possible. Details of the enumeration data are supplied in the section USB Enumeration Data. Typically, the enumeration data is constant for a given peripheral, although it can be constructed dynamically if necessary. However, the enumeration data cannot change while the peripheral is connected to a host: the peripheral cannot easily claim to be a keyboard one second and a printer the next.
The start_fn member is normally accessed
via the utility usbs_start rather
than directly. It is provided by the device driver and should be
invoked once the system is fully initialized and interaction with the
host is possible. A typical implementation would change the USB data
pins from tristated to active. If the peripheral is already plugged
into a host then the latter should detect this change and start
interacting with the peripheral, including requesting the enumeration
data.
There are three usbs_control_endpoint fields
related to the current state of a USB slave device, plus some state
constants and an enumeration of the possible state changes:
typedef struct usbs_control_endpoint {
…
int state;
void (*state_change_fn)(struct usbs_control_endpoint*, void*,
usbs_state_change, int);
void* state_change_data;
…
};
#define USBS_STATE_DETACHED 0x01
#define USBS_STATE_ATTACHED 0x02
#define USBS_STATE_POWERED 0x03
#define USBS_STATE_DEFAULT 0x04
#define USBS_STATE_ADDRESSED 0x05
#define USBS_STATE_CONFIGURED 0x06
#define USBS_STATE_MASK 0x7F
#define USBS_STATE_SUSPENDED (1 << 7)
typedef enum {
USBS_STATE_CHANGE_DETACHED = 1,
USBS_STATE_CHANGE_ATTACHED = 2,
USBS_STATE_CHANGE_POWERED = 3,
USBS_STATE_CHANGE_RESET = 4,
USBS_STATE_CHANGE_ADDRESSED = 5,
USBS_STATE_CHANGE_CONFIGURED = 6,
USBS_STATE_CHANGE_DECONFIGURED = 7,
USBS_STATE_CHANGE_SUSPENDED = 8,
USBS_STATE_CHANGE_RESUMED = 9
} usbs_state_change; |
The USB standard defines a number of states for a given USB peripheral. The initial state is detached, where the peripheral is either not connected to a host at all or, from the host's perspective, the peripheral has not started up yet because the relevant pins are tristated. The peripheral then moves via intermediate attached and powered states to its default or reset state, at which point the host and peripheral can actually start exchanging data. The first message is from host to peripheral and provides a unique 7-bit address within the local USB network, resulting in a state change to addressed. The host then requests enumeration data and performs other initialization. If everything succeeds the host sends a standard set-configuration control message, after which the peripheral is configured and expected to be up and running. Note that some USB device drivers may be unable to distinguish between the detached, attached and powered states but generally this is not important to higher-level code.
A USB host should generate at least one token every millisecond. If a peripheral fails to detect any USB traffic for a period of time then typically this indicates that the host has entered a power-saving mode, and the peripheral should do the same if possible. This corresponds to the suspended bit. The actual state is a combination of suspended and the previous state, for example configured and suspended rather than just suspended. When the peripheral subsequently detects USB traffic it would switch back to the configured state.
The USB device driver and the common USB slave package will maintain
the current state in the control endpoint's
state field. There should be no need for
any other code to change this field, but it can be examined whenever
appropriate. In addition whenever a state change occurs the generic
code can invoke a state change callback function. By default, no such
callback function will be installed. Some class-specific packages such
as the USB-ethernet package will install a suitable function to keep
track of whether or not the host-peripheral connection is up, that is
whether or not ethernet packets can be exchanged. Application code can
also update this field. If multiple parties want to be informed of
state changes, for example both a class-specific package and
application code, then typically the application code will install its
state change handler after the class-specific package and is
responsible for chaining into the package's handler.
The state change callback function is invoked with four arguments. The
first identifies the control endpoint. The second is an arbitrary
pointer: higher-level code can fill in the
state_change_data field to set this. The
third argument specifies the state change that has occurred, and the
last argument supplies the previous state (the new state is readily
available from the control endpoint structure).
eCos does not provide any utility functions for updating or examining
the state_change_fn or
state_change_data fields. Instead, it is
expected that the fields in the
usbs_control_endpoint data structure will be
manipulated directly. Any utility functions would do just this, but
at the cost of increased code and cpu overheads.
typedef struct usbs_control_endpoint {
…
unsigned char control_buffer[8];
usbs_control_return (*standard_control_fn)(struct usbs_control_endpoint*, void*);
void* standard_control_data;
…
} usbs_control_endpoint;
typedef enum {
USBS_CONTROL_RETURN_HANDLED = 0,
USBS_CONTROL_RETURN_UNKNOWN = 1,
USBS_CONTROL_RETURN_STALL = 2
} usbs_control_return;
extern usbs_control_return usbs_handle_standard_control(struct usbs_control_endpoint*); |
When a USB peripheral is connected to the host it must always respond to control messages sent to endpoint 0. Control messages always consist of an initial eight-byte header, containing fields such as a request type. This may be followed by a further data transfer, either from host to peripheral or from peripheral to host. The way this is handled is described in the Buffer Management section below.
The USB device driver will always accept the initial eight-byte
header, storing it in the control_buffer
field. Then it determines the request type: standard, class, vendor,
or reserved. The way in which the last three of these are processed is
described in the section Other
Control Messages. Some
standard control messages will be handled by the device driver itself;
typically the set-address request and the
get-status, set-feature and
clear-feature requests when applied to endpoints.
If a standard control message cannot be handled by the device driver
itself, the driver checks the
standard_control_fn field in the control
endpoint data structure. If higher-level code has installed a suitable
callback function then this will be invoked with two argument, the
control endpoint data structure itself and the
standard_control_data field. The latter
allows the higher level code to associate arbitrary data with the
control endpoint. The callback function can return one of three
values: HANDLED to indicate that the request has
been processed; UNKNOWN if the message should be
handled by the default code; or STALL to indicate
an error condition. If higher level code has not installed a callback
function or if the callback function has returned
UNKNOWN then the device driver will invoke a
default handler, usbs_handle_standard_control
provided by the common USB slave package.
The default handler can cope with all of the standard control messages for a simple USB peripheral. However, if the peripheral involves multiple configurations, multiple interfaces in a configuration, or alternate settings for an interface, then this cannot be handled by generic code. For example, a multimedia peripheral may support various alternate settings for a given data source with different bandwidth requirements, and the host can select a setting that takes into account the current load. Clearly higher-level code needs to be aware when the host changes the current setting, so that it can adjust the rate at which data is fed to or retrieved from the host. Therefore the higher-level code needs to install its own standard control callback and process appropriate messages, rather than leaving these to the default handler.
The default handler will take care of the get-descriptor request used to obtain the enumeration data. It has support for string descriptors but ignores language encoding issues. If language encoding is important for the peripheral then this will have to be handled by an application-specific standard control handler.
The header file <cyg/io/usb/usb.h> defines various constants related to control messages, for example the function codes corresponding to the standard request types. This header file is provided by the common USB package, not by the USB slave package, since the information is also relevant to USB hosts.
typedef struct usbs_control_endpoint {
…
usbs_control_return (*class_control_fn)(struct usbs_control_endpoint*, void*);
void* class_control_data;
usbs_control_return (*vendor_control_fn)(struct usbs_control_endpoint*, void*);
void* vendor_control_data;
usbs_control_return (*reserved_control_fn)(struct usbs_control_endpoint*, void*);
void* reserved_control_data;
…
} usbs_control_endpoint; |
Non-standard control messages always have to be processed by
higher-level code. This could be class-specific packages. For example,
the USB-ethernet package will handle requests for getting the MAC
address and for enabling or disabling promiscuous mode. In all cases
the device driver will store the initial request in the
control_buffer field, check for an
appropriate handler, and invoke it with details of the control
endpoint and any handler-specific data that has been installed
alongside the handler itself. The handler should return either
USBS_CONTROL_RETURN_HANDLED to report success or
USBS_CONTROL_RETURN_STALL to report failure. The
device driver will report this to the host.
If there are multiple parties interested in a particular type of control messages, it is the responsibility of application code to install an appropriate handler and process the requests appropriately.
typedef struct usbs_control_endpoint {
…
unsigned char* buffer;
int buffer_size;
void (*fill_buffer_fn)(struct usbs_control_endpoint*);
void* fill_data;
int fill_index;
usbs_control_return (*complete_fn)(struct usbs_control_endpoint*, int);
…
} usbs_control_endpoint; |
Many USB control messages involve transferring more data than just the initial eight-byte header. The header indicates the direction of the transfer, OUT for host to peripheral or IN for peripheral to host. It also specifies a length field, which is exact for an OUT transfer or an upper bound for an IN transfer. Control message handlers can manipulate six fields within the control endpoint data structure to ensure that the transfer happens correctly.
For an OUT transfer, the handler should examine the length field in
the header and provide a single buffer for all the data. A
class-specific protocol would typically impose an upper bound on the
amount of data, allowing the buffer to be allocated statically.
The handler should update the buffer and
complete_fn fields. When all the data has
been transferred the completion callback will be invoked, and its
return value determines the response sent back to the host. The USB
standard allows for a new control message to be sent before the
current transfer has completed, effectively cancelling the current
operation. When this happens the completion function will also be
invoked. The second argument to the completion function specifies what
has happened, with a value of 0 indicating success and an error code
such as -EPIPE or -EIO
indicating that the current transfer has been cancelled.
IN transfers are a little bit more complicated. The required information, for example the enumeration data, may not be in a single contiguous buffer. Instead a mechanism is provided by which the buffer can be refilled, thus allowing the transfer to move from one record to the next. Essentially, the transfer operates as follows:
When the host requests another chunk of data (typically eight bytes),
the USB device driver will examine the
buffer_size field. If non-zero then
buffer contains at least one more byte of
data, and then buffer_size is decremented.
When buffer_size has dropped to 0, the
fill_buffer_fn field will be examined. If
non-null it will be invoked to refill the buffer.
The fill_data and
fill_index fields are not used by the
device driver. Instead these fields are available to the refill
function to keep track of the current state of the transfer.
When buffer_size is 0 and
fill_buffer_fn is NULL, no more data is
available and the transfer has completed.
Optionally a completion function can be installed. This will be invoked with 0 if the transfer completes successfully, or with an error code if the transfer is cancelled because of another control messsage.
If the requested data is contiguous then the only fields that need
to be manipulated are buffer and
buffer_size, and optionally
complete_fn. If the requested data is not
contiguous then the initial control message handler should update
fill_buffer_fn and some or all of the other
fields, as required. An example of this is the handling of the
standard get-descriptor control message by
usbs_handle_standard_control.
typedef struct usbs_control_endpoint {
void (*poll_fn)(struct usbs_control_endpoint*);
int interrupt_vector;
…
} usbs_control_endpoint; |
In nearly all circumstances USB I/O should be interrupt-driven.
However, there are special environments such as RedBoot where polled
operation may be appropriate. If the device driver can operate in
polled mode then it will provide a suitable function via the
poll_fn field, and higher-level code can
invoke this regularly. This polling function will take care of all
endpoints associated with the device, not just the control endpoint.
If the USB hardware involves a single interrupt vector then this will
be identified in the data structure as well.
typedef struct usbs_control_endpoint {
struct usbs_rx_endpoint* (*get_rxep_fn)(struct usbs_control_endpoint*, cyg_uint8);
struct usbs_tx_endpoint* (*get_txep_fn)(struct usbs_control_endpoint*, cyg_uint8);
…
} usbs_control_endpoint; |
USB slave hardware may support multiple USB configurations via
configurable data endpoints. If the device driver can support such
operation, it will provide a pair of functions via the
get_rxep_fn and
get_txep_fn fields which enable retrieval
of the receive and transmit data endpoint structures using the logical
endpoint IDs specified in a USB class descriptor. Access to these
functions from higher-level code is provided by the
usbs_get_rx_endpoint and
usbs_get_tx_endpoint functions.