/* * Copyright (c) 2011 Jan Vesely * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * - Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * - Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * - The name of the author may not be used to endorse or promote products * derived from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ /** @addtogroup drvusbuhcihc * @{ */ /** @file * @brief UHCI driver USB transfer structure */ #include #include #include #include #include "batch.h" #include "transfer_list.h" #include "hw_struct/transfer_descriptor.h" #include "utils/malloc32.h" #define DEFAULT_ERROR_COUNT 3 /** UHCI specific data required for USB transfer */ typedef struct uhci_transfer_batch { /** Queue head * This QH is used to maintain UHCI schedule structure and the element * pointer points to the first TD of this batch. */ qh_t *qh; /** List of TDs needed for the transfer */ td_t *tds; /** Number of TDs used by the transfer */ size_t td_count; /** Data buffer, must be accessible by the UHCI hw */ void *device_buffer; } uhci_transfer_batch_t; /*----------------------------------------------------------------------------*/ static void batch_control(usb_transfer_batch_t *instance, usb_packet_id data_stage, usb_packet_id status_stage); static void batch_data(usb_transfer_batch_t *instance, usb_packet_id pid); /*----------------------------------------------------------------------------*/ /** Safely destructs uhci_transfer_batch_t structure * * @param[in] uhci_batch Instance to destroy. */ static void uhci_transfer_batch_dispose(void *uhci_batch) { uhci_transfer_batch_t *instance = uhci_batch; assert(instance); free32(instance->device_buffer); free(instance); } /*----------------------------------------------------------------------------*/ /** Allocate memory and initialize internal data structure. * * @param[in] fun DDF function to pass to callback. * @param[in] ep Communication target * @param[in] buffer Data source/destination. * @param[in] buffer_size Size of the buffer. * @param[in] setup_buffer Setup data source (if not NULL) * @param[in] setup_size Size of setup_buffer (should be always 8) * @param[in] func_in function to call on inbound transfer completion * @param[in] func_out function to call on outbound transfer completion * @param[in] arg additional parameter to func_in or func_out * @return Valid pointer if all structures were successfully created, * NULL otherwise. * * Determines the number of needed transfer descriptors (TDs). * Prepares a transport buffer (that is accessible by the hardware). * Initializes parameters needed for the transfer and callback. */ usb_transfer_batch_t * batch_get(ddf_fun_t *fun, endpoint_t *ep, char *buffer, size_t buffer_size, const char* setup_buffer, size_t setup_size, usbhc_iface_transfer_in_callback_t func_in, usbhc_iface_transfer_out_callback_t func_out, void *arg) { assert(ep); assert(func_in == NULL || func_out == NULL); assert(func_in != NULL || func_out != NULL); #define CHECK_NULL_DISPOSE_RETURN(ptr, message...) \ if (ptr == NULL) { \ usb_log_error(message); \ if (uhci_data) { \ uhci_transfer_batch_dispose(uhci_data); \ } \ return NULL; \ } else (void)0 uhci_transfer_batch_t *uhci_data = malloc(sizeof(uhci_transfer_batch_t)); CHECK_NULL_DISPOSE_RETURN(uhci_data, "Failed to allocate UHCI batch.\n"); bzero(uhci_data, sizeof(uhci_transfer_batch_t)); uhci_data->td_count = (buffer_size + ep->max_packet_size - 1) / ep->max_packet_size; if (ep->transfer_type == USB_TRANSFER_CONTROL) { uhci_data->td_count += 2; } assert((sizeof(td_t) % 16) == 0); const size_t total_size = (sizeof(td_t) * uhci_data->td_count) + sizeof(qh_t) + setup_size + buffer_size; uhci_data->device_buffer = malloc32(total_size); CHECK_NULL_DISPOSE_RETURN(uhci_data->device_buffer, "Failed to allocate UHCI buffer.\n"); bzero(uhci_data->device_buffer, total_size); uhci_data->tds = uhci_data->device_buffer; uhci_data->qh = (uhci_data->device_buffer + (sizeof(td_t) * uhci_data->td_count)); qh_init(uhci_data->qh); qh_set_element_td(uhci_data->qh, uhci_data->tds); usb_transfer_batch_t *instance = malloc(sizeof(usb_transfer_batch_t)); CHECK_NULL_DISPOSE_RETURN(instance, "Failed to allocate batch instance.\n"); void *setup = uhci_data->device_buffer + (sizeof(td_t) * uhci_data->td_count) + sizeof(qh_t); void *data_buffer = setup + setup_size; usb_transfer_batch_init(instance, ep, buffer, data_buffer, buffer_size, setup, setup_size, func_in, func_out, arg, fun, uhci_data, uhci_transfer_batch_dispose); memcpy(instance->setup_buffer, setup_buffer, setup_size); usb_log_debug2("Batch %p " USB_TRANSFER_BATCH_FMT " memory structures ready.\n", instance, USB_TRANSFER_BATCH_ARGS(*instance)); return instance; } /*----------------------------------------------------------------------------*/ /** Check batch TDs for activity. * * @param[in] instance Batch structure to use. * @return False, if there is an active TD, true otherwise. * * Walk all TDs. Stop with false if there is an active one (it is to be * processed). Stop with true if an error is found. Return true if the last TD * is reached. */ bool batch_is_complete(usb_transfer_batch_t *instance) { assert(instance); uhci_transfer_batch_t *data = instance->private_data; assert(data); usb_log_debug2("Batch(%p) checking %zu transfer(s) for completion.\n", instance, data->td_count); instance->transfered_size = 0; size_t i = 0; for (;i < data->td_count; ++i) { if (td_is_active(&data->tds[i])) { return false; } instance->error = td_status(&data->tds[i]); if (instance->error != EOK) { usb_log_debug("Batch(%p) found error TD(%zu):%" PRIx32 ".\n", instance, i, data->tds[i].status); td_print_status(&data->tds[i]); assert(instance->ep != NULL); endpoint_toggle_set(instance->ep, td_toggle(&data->tds[i])); if (i > 0) goto substract_ret; return true; } instance->transfered_size += td_act_size(&data->tds[i]); if (td_is_short(&data->tds[i])) goto substract_ret; } substract_ret: instance->transfered_size -= instance->setup_size; return true; } #define LOG_BATCH_INITIALIZED(batch, name) \ usb_log_debug2("Batch %p %s " USB_TRANSFER_BATCH_FMT " initialized.\n", \ (batch), (name), USB_TRANSFER_BATCH_ARGS(*(batch))) /*----------------------------------------------------------------------------*/ /** Prepares control write transfer. * * @param[in] instance Batch structure to use. * * Uses generic control function with pids OUT and IN. */ void batch_control_write(usb_transfer_batch_t *instance) { assert(instance); /* We are data out, we are supposed to provide data */ memcpy(instance->data_buffer, instance->buffer, instance->buffer_size); batch_control(instance, USB_PID_OUT, USB_PID_IN); instance->next_step = usb_transfer_batch_call_out_and_dispose; LOG_BATCH_INITIALIZED(instance, "control write"); } /*----------------------------------------------------------------------------*/ /** Prepares control read transfer. * * @param[in] instance Batch structure to use. * * Uses generic control with pids IN and OUT. */ void batch_control_read(usb_transfer_batch_t *instance) { assert(instance); batch_control(instance, USB_PID_IN, USB_PID_OUT); instance->next_step = usb_transfer_batch_call_in_and_dispose; LOG_BATCH_INITIALIZED(instance, "control read"); } /*----------------------------------------------------------------------------*/ /** Prepare interrupt in transfer. * * @param[in] instance Batch structure to use. * * Data transfer with PID_IN. */ void batch_interrupt_in(usb_transfer_batch_t *instance) { assert(instance); batch_data(instance, USB_PID_IN); instance->next_step = usb_transfer_batch_call_in_and_dispose; LOG_BATCH_INITIALIZED(instance, "interrupt in"); } /*----------------------------------------------------------------------------*/ /** Prepare interrupt out transfer. * * @param[in] instance Batch structure to use. * * Data transfer with PID_OUT. */ void batch_interrupt_out(usb_transfer_batch_t *instance) { assert(instance); /* We are data out, we are supposed to provide data */ memcpy(instance->data_buffer, instance->buffer, instance->buffer_size); batch_data(instance, USB_PID_OUT); instance->next_step = usb_transfer_batch_call_out_and_dispose; LOG_BATCH_INITIALIZED(instance, "interrupt out"); } /*----------------------------------------------------------------------------*/ /** Prepare bulk in transfer. * * @param[in] instance Batch structure to use. * * Data transfer with PID_IN. */ void batch_bulk_in(usb_transfer_batch_t *instance) { assert(instance); batch_data(instance, USB_PID_IN); instance->next_step = usb_transfer_batch_call_in_and_dispose; LOG_BATCH_INITIALIZED(instance, "bulk in"); } /*----------------------------------------------------------------------------*/ /** Prepare bulk out transfer. * * @param[in] instance Batch structure to use. * * Data transfer with PID_OUT. */ void batch_bulk_out(usb_transfer_batch_t *instance) { assert(instance); /* We are data out, we are supposed to provide data */ memcpy(instance->data_buffer, instance->buffer, instance->buffer_size); batch_data(instance, USB_PID_OUT); instance->next_step = usb_transfer_batch_call_out_and_dispose; LOG_BATCH_INITIALIZED(instance, "bulk out"); } /*----------------------------------------------------------------------------*/ /** Prepare generic data transfer * * @param[in] instance Batch structure to use. * @param[in] pid Pid to use for data transactions. * * Transactions with alternating toggle bit and supplied pid value. * The last transfer is marked with IOC flag. */ void batch_data(usb_transfer_batch_t *instance, usb_packet_id pid) { assert(instance); uhci_transfer_batch_t *data = instance->private_data; assert(data); const bool low_speed = instance->ep->speed == USB_SPEED_LOW; int toggle = endpoint_toggle_get(instance->ep); assert(toggle == 0 || toggle == 1); size_t td = 0; size_t remain_size = instance->buffer_size; char *buffer = instance->data_buffer; while (remain_size > 0) { const size_t packet_size = (instance->ep->max_packet_size > remain_size) ? remain_size : instance->ep->max_packet_size; td_t *next_td = (td + 1 < data->td_count) ? &data->tds[td + 1] : NULL; usb_target_t target = { instance->ep->address, instance->ep->endpoint }; assert(td < data->td_count); td_init( &data->tds[td], DEFAULT_ERROR_COUNT, packet_size, toggle, false, low_speed, target, pid, buffer, next_td); ++td; toggle = 1 - toggle; buffer += packet_size; assert(packet_size <= remain_size); remain_size -= packet_size; } td_set_ioc(&data->tds[td - 1]); endpoint_toggle_set(instance->ep, toggle); } /*----------------------------------------------------------------------------*/ /** Prepare generic control transfer * * @param[in] instance Batch structure to use. * @param[in] data_stage Pid to use for data tds. * @param[in] status_stage Pid to use for data tds. * * Setup stage with toggle 0 and USB_PID_SETUP. * Data stage with alternating toggle and pid supplied by parameter. * Status stage with toggle 1 and pid supplied by parameter. * The last transfer is marked with IOC. */ void batch_control(usb_transfer_batch_t *instance, usb_packet_id data_stage, usb_packet_id status_stage) { assert(instance); uhci_transfer_batch_t *data = instance->private_data; assert(data); assert(data->td_count >= 2); const bool low_speed = instance->ep->speed == USB_SPEED_LOW; const usb_target_t target = { instance->ep->address, instance->ep->endpoint }; /* setup stage */ td_init( data->tds, DEFAULT_ERROR_COUNT, instance->setup_size, 0, false, low_speed, target, USB_PID_SETUP, instance->setup_buffer, &data->tds[1]); /* data stage */ size_t td = 1; unsigned toggle = 1; size_t remain_size = instance->buffer_size; char *buffer = instance->data_buffer; while (remain_size > 0) { const size_t packet_size = (instance->ep->max_packet_size > remain_size) ? remain_size : instance->ep->max_packet_size; td_init( &data->tds[td], DEFAULT_ERROR_COUNT, packet_size, toggle, false, low_speed, target, data_stage, buffer, &data->tds[td + 1]); ++td; toggle = 1 - toggle; buffer += packet_size; assert(td < data->td_count); assert(packet_size <= remain_size); remain_size -= packet_size; } /* status stage */ assert(td == data->td_count - 1); td_init( &data->tds[td], DEFAULT_ERROR_COUNT, 0, 1, false, low_speed, target, status_stage, NULL, NULL); td_set_ioc(&data->tds[td]); usb_log_debug2("Control last TD status: %x.\n", data->tds[td].status); } /*----------------------------------------------------------------------------*/ /** Provides access to QH data structure. * * @param[in] instance Batch pointer to use. * @return Pointer to the QH used by the batch. */ qh_t * batch_qh(usb_transfer_batch_t *instance) { assert(instance); uhci_transfer_batch_t *data = instance->private_data; assert(data); return data->qh; } /** * @} */