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#ifndef CYGONCE_USBS_H # define CYGONCE_USBS_H //========================================================================== // // include/usbs.h // // The generic USB slave-side support // //========================================================================== //####ECOSGPLCOPYRIGHTBEGIN#### // ------------------------------------------- // This file is part of eCos, the Embedded Configurable Operating System. // Copyright (C) 1998, 1999, 2000, 2001, 2002 Red Hat, Inc. // // eCos is free software; you can redistribute it and/or modify it under // the terms of the GNU General Public License as published by the Free // Software Foundation; either version 2 or (at your option) any later version. // // eCos 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 GNU General Public License // for more details. // // You should have received a copy of the GNU General Public License along // with eCos; if not, write to the Free Software Foundation, Inc., // 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA. // // As a special exception, if other files instantiate templates or use macros // or inline functions from this file, or you compile this file and link it // with other works to produce a work based on this file, this file does not // by itself cause the resulting work to be covered by the GNU General Public // License. However the source code for this file must still be made available // in accordance with section (3) of the GNU General Public License. // // This exception does not invalidate any other reasons why a work based on // this file might be covered by the GNU General Public License. // // Alternative licenses for eCos may be arranged by contacting Red Hat, Inc. // at http://sources.redhat.com/ecos/ecos-license/ // ------------------------------------------- //####ECOSGPLCOPYRIGHTEND#### //========================================================================== //#####DESCRIPTIONBEGIN#### // // Author(s): bartv // Contributors: bartv // Date: 2000-10-04 // Purpose: // Description: USB slave-side support // // //####DESCRIPTIONEND#### //========================================================================== # include <pkgconf/system.h> # include <cyg/infra/cyg_type.h> # include <cyg/io/usb/usb.h> #ifdef __cplusplus extern "C" { #endif // The USB slave-side eCos support involves a number of different // components: // // 1) a hardware-specific package to drive a specific chip implementation. // This provides access to the endpoints. All the hardware-specific // packages implement a common interface. // // 2) a common package (this one). This defines the interface implemented // by the hardware-specific packages. It also provides support for // the various generic control messages, using information provided // by higher-level code and invoking callbacks as appropriate. // // 3) some number of support packages for particular types of // application, for example ethernet or mass-storage. // // Typically there will only be one USB slave device, although the design // does allow for multiple devices. Each device should provide a // usbs_control_endpoint structure and zero or more usbs_data_endpoint // structures. Each usbs_data_endpoint structure supports uni-directional // transfers on a single endpoint. If an endpoint can support multiple // types of transfer then there will be some control operation to switch // between bulk, interrupt and isochronous. // // Access to the USB endpoints can go either via usbs_ calls which // take a usbs_endpoint structure, or via open/read/write calls. The // latter is more likely to be used in application code since it // involves a familiar interface. The former is more appropriate for // eCos packages layered on top of the USB code. The difference is // synchronous vs. asynchronous: the open/read/write model involves // blocking operations, implying a need for extra threads; the usbs_ // calls involve start operations and a completion callback. In // practice the read and write calls are implemented using the // lower-level code. // Enumeration data. This requires information about the hardware, // specifically what endpoints are available and what they get used // for. It also requires information about the application class // packages that are in the configuration, and quite possibly about // things in application space. Some of the enumeration info such as // the vendor id is inherently application-specific. Hence there is no // way of generating part or all of the the enumeration information // automatically, instead it is up to application code to supply this. // // The intention is that application provides all the data via const // static objects, allowing the data to live in ROM. Alternatively the // data structures can go into the .data section as normal, allowing // them to be edited at run-time. // // There can be only one device descriptor, so that is part of the // main enumeration data structure. There can be an unknown number of // configurations so application code has to initialize an array of // these. Ditto for interfaces and endpoints. The first x interfaces // in the array correspond to the first configuration, the next y // interfaces to the second configuration, etc. The endpoints array // works in the same way. // // In the initial implementation multiple languages are not supported // so a simple array of strings suffices. The first entry of these // is still special in that it should define a single supported // LANGID. All strings should be encoded as per the USB standard: // a length field, a type code of USB_STRING_DESCRIPTOR_TYPE, // and data in unicode format. In future multiple language support // may be supported via configury with the default case remaining // a single language, thus avoiding incompatibility problems. typedef struct usbs_enumeration_data { usb_device_descriptor device; int total_number_interfaces; int total_number_endpoints; int total_number_strings; const usb_configuration_descriptor* configurations; const usb_interface_descriptor* interfaces; const usb_endpoint_descriptor* endpoints; const unsigned char** strings; } usbs_enumeration_data; // The current state of a USB device. This involves a bit to mark // whether or not the device has been suspended, plus a state machine. // On some hardware it may not be possible to distinguish between the // detached, attached and powered states. If so then the initial state // will be POWERED. #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) // State changes. Application code or higher-level packages should // install an appropriate state change function which will get // invoked with details of the state change. 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; typedef enum { USBS_CONTROL_RETURN_HANDLED = 0, USBS_CONTROL_RETURN_UNKNOWN = 1, USBS_CONTROL_RETURN_STALL = 2 } usbs_control_return; typedef struct usbs_control_endpoint { // The state is maintained by the USB code and should not be // modified by anything higher up. int state; // The enumeration data should be supplied by higher level code, // usually the application. Often this data will be constant. const usbs_enumeration_data* enumeration_data; // This function pointer is supplied by the USB device driver. // Application code should invoke it directly or via the // usbs_start() function when the system is ready. Typically it // will cause the USB lines to switch from tristate to active, // and the USB host/hub should detect this. void (*start_fn)(struct usbs_control_endpoint*); // This function is used for polled operation when interrupts // are disabled. This can happen in some debugging contexts. // Higher-level code may also need to know about the interrupt // number(s) used. void (*poll_fn)(struct usbs_control_endpoint*); int interrupt_vector; // When a new control message arrives it will be in this buffer // where the appropriate callback functions can examine it. The // USB code will not modify the buffer unless a new control // message arrives. The control_buffer can also be re-used // by handlers to maintain some state information, e.g. // for coping with complicated IN requests, but this is only // allowed if they actually handle the request. unsigned char control_buffer[8]; // This callback will be invoked by the USB code following a // change in USB state, e.g. to SUSPENDED mode. Higher-level code // should install a suitable function. There is some callback data // as well. This gets passed explicitly to the callback function, // in addition to the control endpoint structure. The reason is // that the actual state change callback may be some sort of // multiplexer inside a multifunction peripheral, and this // multiplexer wants to invoke device-specific state change // functions. However in simple devices those device-specific // state change functions could be invoked directly. void (*state_change_fn)(struct usbs_control_endpoint*, void*, usbs_state_change, int /* old state */); void* state_change_data; // When a standard control message arrives, the device driver will // detect some requests such as SET_ADDRESS and handle it // internally. Otherwise if higher-level code has installed a // callback then that will be invoked. If the callback returns // UNKNOWN then the default handler usbs_handle_standard_control() // is used to process the request. usbs_control_return (*standard_control_fn)(struct usbs_control_endpoint*, void*); void* standard_control_data; // These three callbacks are used for other types of control // messages. The generic USB code has no way of knowing what // such control messages are about. 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; // If a control operation involves transferring more data than // just the initial eight-byte packet, the following fields are // used to keep track of the current operation. The original // control request indicates the direction of the transfer (IN or // OUT) and a length field. For OUT this length is exact, for IN // it is an upper bound. The transfer operates mostly as per the // bulk protocol, but if the length requested is an exact multiple // of the control fifo size (typically eight bytes) then there // is no need for an empty packet at the end. // // For an OUT operation the control message handler should supply // a suitable buffer via the "buffer" field below. The only other // field of interest is the complete_fn which must be provided and // will be invoked once all the data has arrived. Alternatively // the OUT operation may get aborted if a new control message // arrives. The second argument is an error code -EPIPE or -EIO, // or zero to indicate success. The return code is used by the // device driver during the status phase. // // IN is more complicated and the defined interface makes it // possible to gather data from multiple locations, eliminating // the need for copying into large buffers in some circumstances. // Basically when an IN request arrives the device driver will // look at the buffer and buffer_size fields, extracting data from // there if possible. If the current buffer has been exhausted // then the the refill function will be invoked, and this can // reset the buffer and size fields to point somewhere else. // This continues until such time that there is no longer // a refill function and the current buffer is empty. The // refill function can use the refill_data and refill_index // to keep track of the current state. The control_buffer // fields are available as well. At the end of the transfer, // if a completion function has been supplied then it will // be invoked. The return code will be ignored. 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; // Data endpoints are a little bit simpler, but not much. From the // perspective of a device driver things a single buffer is most // convenient, but that is quite likely to require a max-size buffer // at a higher level and an additional copy operation. Supplying // a vector of buffers is a bit more general, but in a layered // system it may be desirable to prepend to this vector... // A combination of a current buffer and a refill/empty function // offers flexibility, at the cost of additional function calls // from inside the device driver. // // FIXME: implement support for fill/empty functions. // // Some USB devices may prefer buffers of particular alignment, // e.g. for DMA purposes. This is hard to reconcile with the // current interface. However pushing such alignment restrictions // etc. up into the higher levels is difficult, e.g. it does // not map at all onto a conventional read/write interface. // The device driver will just have to do the best it can. // // The completion function will be invoked at the end of the transfer. // The second argument indicates per-transfer completion data. The // third argument indicates the total amount received, or an error // code: typically -EPIPE to indicate a broken conenction; -EAGAIN to // indicate a stall condition; -EMSGSIZE if the host is sending more // data than the target is expecting; or -EIO to indicate some other // error. Individual device drivers should avoid generating other // errors. typedef struct usbs_rx_endpoint { void (*start_rx_fn)(struct usbs_rx_endpoint*); void (*set_halted_fn)(struct usbs_rx_endpoint*, cyg_bool); void (*complete_fn)(void*, int); void* complete_data; unsigned char* buffer; int buffer_size; cyg_bool halted; } usbs_rx_endpoint; typedef struct usbs_tx_endpoint { void (*start_tx_fn)(struct usbs_tx_endpoint*); void (*set_halted_fn)(struct usbs_tx_endpoint*, cyg_bool); void (*complete_fn)(void*, int); void* complete_data; const unsigned char*buffer; int buffer_size; cyg_bool halted; } usbs_tx_endpoint; // Functions called by device drivers. extern usbs_control_return usbs_handle_standard_control(struct usbs_control_endpoint*); // Utility functions. These just invoke the corresponding function // pointers in the endpoint structures. It is assumed that the // necessary fields in the endpoint structures will have been // filled in already. extern void usbs_start(usbs_control_endpoint*); extern void usbs_start_rx(usbs_rx_endpoint*); extern void usbs_start_tx(usbs_tx_endpoint*); extern void usbs_start_rx_buffer(usbs_rx_endpoint*, unsigned char*, int, void (*)(void*, int), void*); extern void usbs_start_tx_buffer(usbs_tx_endpoint*, const unsigned char*, int, void (*)(void*, int), void*); extern cyg_bool usbs_rx_endpoint_halted(usbs_rx_endpoint*); extern cyg_bool usbs_tx_endpoint_halted(usbs_tx_endpoint*); extern void usbs_set_rx_endpoint_halted(usbs_rx_endpoint*, cyg_bool); extern void usbs_set_tx_endpoint_halted(usbs_tx_endpoint*, cyg_bool); extern void usbs_start_rx_endpoint_wait(usbs_rx_endpoint*, void (*)(void*, int), void*); extern void usbs_start_tx_endpoint_wait(usbs_tx_endpoint*, void (*)(void*, int), void*); // Functions that can go into devtab entries. These should not be // called directly, they are intended only for use by USB device // drivers. #if defined(CYGPKG_IO) && defined(CYGPKG_ERROR) #include <cyg/io/io.h> extern Cyg_ErrNo usbs_devtab_cwrite(cyg_io_handle_t, const void*, cyg_uint32*); extern Cyg_ErrNo usbs_devtab_cread(cyg_io_handle_t, void*, cyg_uint32*); extern Cyg_ErrNo usbs_devtab_get_config(cyg_io_handle_t, cyg_uint32, void*, cyg_uint32*); extern Cyg_ErrNo usbs_devtab_set_config(cyg_io_handle_t, cyg_uint32, const void*, cyg_uint32*); #endif // Additional support for testing. // Test cases need to have some way of finding out about what support is // actually provided by the USB device driver, for example what endpoints // are available. There is no perfect way of achieving this. One approach // would be to scan through the devtab table looking for devices of the // form /dev/usbs1r. That is not reliable: the devtab entries may have been // configured out if higher-level code uses the usb-specific API; or the // devtab entries may have been renamed. Also having a devtab entry does not // really give the kind of information a general-purpose testcase needs, // for example upper bounds on transfer size. // // An alternative approach is to have a data structure that somehow // defines the USB hardware, and the USB device driver then creates an // instance of this. This is the approach actually taken. The problem // now is how the test code can access this instance. Accessing by // unique name is simple, as long as there is only one USB device in // the system (which of course will usually be the case on the USB // slave side). Alternative approaches such as creating a table at // link time or a list during static construction time are vulnerable // either to selective linking or to having these structures present // in applications other than the test cases. In future it might be // possible to address the latter issue by extending the build system // support, e.g. a new library libtesting.a and a new object file // testing.o. // // Note that a given endpoint could be used for bulk transfers some // of the time, then for isochronous transfers, etc. It is the // responsibility of the host to only perform one type of IN operation // for a given endpoint number, and ditto for OUT. typedef struct usbs_testing_endpoint { int endpoint_type; // One of ATTR_CONTROL, ATTR_BULK, ... int endpoint_number; // Between 0 and 15 int endpoint_direction; // ENDPOINT_IN or ENDPOINT_OUT void* endpoint; // pointer to the usbs_control_endpoint, usbs_rx_endpoint, ... const char* devtab_entry; // e.g. "/dev/usbs1r", or 0 if inaccessible via devtab int min_size; // Minimum transfer size int max_size; // -1 indicates no specific upper bound int max_in_padding; // extra bytes that the target may send, usually 0. // Primarily for SA11x0 hardware. It is assumed // for now that no other hardware will exhibit // comparable problems. int alignment; // Buffer should be aligned to a suitable boundary } usbs_testing_endpoint; // A specific instance provided by the device driver. The end of // the table is indicated by a NULL endpoint field. extern usbs_testing_endpoint usbs_testing_endpoints[]; #define USBS_TESTING_ENDPOINTS_TERMINATOR \ { \ endpoint_type : USB_ENDPOINT_DESCRIPTOR_ATTR_CONTROL, \ endpoint_number : 0, \ endpoint_direction : USB_ENDPOINT_DESCRIPTOR_ENDPOINT_IN, \ endpoint : (void*) 0, \ devtab_entry : (const char*) 0, \ min_size : 0, \ max_size : 0, \ max_in_padding : 0, \ alignment : 0 \ } #define USBS_TESTING_ENDPOINTS_IS_TERMINATOR(_endpoint_) ((void*)0 == (_endpoint_).endpoint) #ifdef __cplusplus } // extern "C" { #endif #endif // CYGONCE_USBS_H
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