source: mainline/uspace/srv/devman/devman.c@ fe2333d

/*
 * Copyright (c) 2010 Lenka Trochtova
 * 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 devman
 * @{
 */

#include <errno.h>
#include <fcntl.h>
#include <sys/stat.h>
#include <ipc/driver.h>
#include <ipc/devman.h>
#include <devmap.h>
#include <str_error.h>

#include "devman.h"

/* hash table operations */

static hash_index_t devices_hash(unsigned long key[])
{
        return key[0] % DEVICE_BUCKETS;
}

static int devman_devices_compare(unsigned long key[], hash_count_t keys,
    link_t *item)
{
        node_t *dev = hash_table_get_instance(item, node_t, devman_link);
        return (dev->handle == (devman_handle_t) key[0]);
}

static int devmap_devices_compare(unsigned long key[], hash_count_t keys,
    link_t *item)
{
        node_t *dev = hash_table_get_instance(item, node_t, devmap_link);
        return (dev->devmap_handle == (devmap_handle_t) key[0]);
}

static void devices_remove_callback(link_t *item)
{
}

static hash_table_operations_t devman_devices_ops = {
        .hash = devices_hash,
        .compare = devman_devices_compare,
        .remove_callback = devices_remove_callback
};

static hash_table_operations_t devmap_devices_ops = {
        .hash = devices_hash,
        .compare = devmap_devices_compare,
        .remove_callback = devices_remove_callback
};

/**
 * Initialize the list of device driver's.
 *
 * @param drv_list the list of device driver's.
 *
 */
void init_driver_list(driver_list_t *drv_list)
{
        assert(drv_list != NULL);
        
        list_initialize(&drv_list->drivers);
        fibril_mutex_initialize(&drv_list->drivers_mutex);
}

/** Allocate and initialize a new driver structure.
 *
 * @return      Driver structure.
 */
driver_t *create_driver(void)
{
        driver_t *res = malloc(sizeof(driver_t));
        if (res != NULL)
                init_driver(res);
        return res;
}

/** Add a driver to the list of drivers.
 *
 * @param drivers_list  List of drivers.
 * @param drv           Driver structure.
 */
void add_driver(driver_list_t *drivers_list, driver_t *drv)
{
        fibril_mutex_lock(&drivers_list->drivers_mutex);
        list_prepend(&drv->drivers, &drivers_list->drivers);
        fibril_mutex_unlock(&drivers_list->drivers_mutex);

        printf(NAME": the '%s' driver was added to the list of available "
            "drivers.\n", drv->name);

        printf(NAME ": match ids:");
        link_t *cur;
        for (cur = drv->match_ids.ids.next; cur != &drv->match_ids.ids; cur = cur->next) {
                match_id_t *match_id = list_get_instance(cur, match_id_t, link);
                printf(" %d:%s", match_id->score, match_id->id);
        }
        printf("\n");
}

/** Read match id at the specified position of a string and set the position in
 * the string to the first character following the id.
 *
 * @param buf           The position in the input string.
 * @return              The match id.
 */
char *read_match_id(char **buf)
{
        char *res = NULL;
        size_t len = get_nonspace_len(*buf);
        
        if (len > 0) {
                res = malloc(len + 1);
                if (res != NULL) {
                        str_ncpy(res, len + 1, *buf, len);
                        *buf += len;
                }
        }
        
        return res;
}

/**
 * Read match ids and associated match scores from a string.
 *
 * Each match score in the string is followed by its match id.
 * The match ids and match scores are separated by whitespaces.
 * Neither match ids nor match scores can contain whitespaces.
 *
 * @param buf           The string from which the match ids are read.
 * @param ids           The list of match ids into which the match ids and
 *                      scores are added.
 * @return              True if at least one match id and associated match score
 *                      was successfully read, false otherwise.
 */
bool parse_match_ids(char *buf, match_id_list_t *ids)
{
        int score = 0;
        char *id = NULL;
        int ids_read = 0;
        
        while (true) {
                /* skip spaces */
                if (!skip_spaces(&buf))
                        break;
                
                /* read score */
                score = strtoul(buf, &buf, 10);
                
                /* skip spaces */
                if (!skip_spaces(&buf))
                        break;
                
                /* read id */
                id = read_match_id(&buf);
                if (NULL == id)
                        break;
                
                /* create new match_id structure */
                match_id_t *mid = create_match_id();
                mid->id = id;
                mid->score = score;
                
                /* add it to the list */
                add_match_id(ids, mid);
                
                ids_read++;
        }
        
        return ids_read > 0;
}

/**
 * Read match ids and associated match scores from a file.
 *
 * Each match score in the file is followed by its match id.
 * The match ids and match scores are separated by whitespaces.
 * Neither match ids nor match scores can contain whitespaces.
 *
 * @param buf           The path to the file from which the match ids are read.
 * @param ids           The list of match ids into which the match ids and
 *                      scores are added.
 * @return              True if at least one match id and associated match score
 *                      was successfully read, false otherwise.
 */
bool read_match_ids(const char *conf_path, match_id_list_t *ids)
{
        printf(NAME ": read_match_ids conf_path = %s.\n", conf_path);
        
        bool suc = false;
        char *buf = NULL;
        bool opened = false;
        int fd;
        size_t len = 0;
        
        fd = open(conf_path, O_RDONLY);
        if (fd < 0) {
                printf(NAME ": unable to open %s\n", conf_path);
                goto cleanup;
        }
        opened = true;
        
        len = lseek(fd, 0, SEEK_END);
        lseek(fd, 0, SEEK_SET);
        if (len == 0) {
                printf(NAME ": configuration file '%s' is empty.\n", conf_path);
                goto cleanup;
        }
        
        buf = malloc(len + 1);
        if (buf == NULL) {
                printf(NAME ": memory allocation failed when parsing file "
                    "'%s'.\n", conf_path);
                goto cleanup;
        }
        
        if (read(fd, buf, len) <= 0) {
                printf(NAME ": unable to read file '%s'.\n", conf_path);
                goto cleanup;
        }
        buf[len] = 0;
        
        suc = parse_match_ids(buf, ids);
        
cleanup:
        free(buf);
        
        if (opened)
                close(fd);
        
        return suc;
}

/**
 * Get information about a driver.
 *
 * Each driver has its own directory in the base directory.
 * The name of the driver's directory is the same as the name of the driver.
 * The driver's directory contains driver's binary (named as the driver without
 * extension) and the configuration file with match ids for device-to-driver
 *  matching (named as the driver with a special extension).
 *
 * This function searches for the driver's directory and containing
 * configuration files. If all the files needed are found, they are parsed and
 * the information about the driver is stored in the driver's structure.
 *
 * @param base_path     The base directory, in which we look for driver's
 *                      subdirectory.
 * @param name          The name of the driver.
 * @param drv           The driver structure to fill information in.
 *
 * @return              True on success, false otherwise.
 */
bool get_driver_info(const char *base_path, const char *name, driver_t *drv)
{
        printf(NAME ": get_driver_info base_path = %s, name = %s.\n",
            base_path, name);
        
        assert(base_path != NULL && name != NULL && drv != NULL);
        
        bool suc = false;
        char *match_path = NULL;
        size_t name_size = 0;
        
        /* Read the list of match ids from the driver's configuration file. */
        match_path = get_abs_path(base_path, name, MATCH_EXT);
        if (match_path == NULL)
                goto cleanup;
        
        if (!read_match_ids(match_path, &drv->match_ids))
                goto cleanup;
        
        /* Allocate and fill driver's name. */
        name_size = str_size(name) + 1;
        drv->name = malloc(name_size);
        if (drv->name == NULL)
                goto cleanup;
        str_cpy(drv->name, name_size, name);
        
        /* Initialize path with driver's binary. */
        drv->binary_path = get_abs_path(base_path, name, "");
        if (drv->binary_path == NULL)
                goto cleanup;
        
        /* Check whether the driver's binary exists. */
        struct stat s;
        if (stat(drv->binary_path, &s) == ENOENT) { /* FIXME!! */
                printf(NAME ": driver not found at path %s.", drv->binary_path);
                goto cleanup;
        }
        
        suc = true;
        
cleanup:
        if (!suc) {
                free(drv->binary_path);
                free(drv->name);
                /* Set the driver structure to the default state. */
                init_driver(drv);
        }
        
        free(match_path);
        
        return suc;
}

/** Lookup drivers in the directory.
 *
 * @param drivers_list  The list of available drivers.
 * @param dir_path      The path to the directory where we search for drivers.
 * @return              Number of drivers which were found.
 */
int lookup_available_drivers(driver_list_t *drivers_list, const char *dir_path)
{
        printf(NAME ": lookup_available_drivers, dir = %s \n", dir_path);
        
        int drv_cnt = 0;
        DIR *dir = NULL;
        struct dirent *diren;

        dir = opendir(dir_path);
        
        if (dir != NULL) {
                driver_t *drv = create_driver();
                while ((diren = readdir(dir))) {
                        if (get_driver_info(dir_path, diren->d_name, drv)) {
                                add_driver(drivers_list, drv);
                                drv_cnt++;
                                drv = create_driver();
                        }
                }
                delete_driver(drv);
                closedir(dir);
        }
        
        return drv_cnt;
}

/** Create root device node in the device tree.
 *
 * @param tree  The device tree.
 * @return      True on success, false otherwise.
 */
bool create_root_node(dev_tree_t *tree)
{
        node_t *node;

        printf(NAME ": create_root_node\n");

        node = create_dev_node();
        if (node != NULL) {
                insert_dev_node(tree, node, clone_string(""), NULL);
                match_id_t *id = create_match_id();
                id->id = clone_string("root");
                id->score = 100;
                add_match_id(&node->match_ids, id);
                tree->root_node = node;
        }

        return node != NULL;
}

/** Lookup the best matching driver for the specified device in the list of
 * drivers.
 *
 * A match between a device and a driver is found if one of the driver's match
 * ids match one of the device's match ids. The score of the match is the
 * product of the driver's and device's score associated with the matching id.
 * The best matching driver for a device is the driver with the highest score
 * of the match between the device and the driver.
 *
 * @param drivers_list  The list of drivers, where we look for the driver
 *                      suitable for handling the device.
 * @param node          The device node structure of the device.
 * @return              The best matching driver or NULL if no matching driver
 *                      is found.
 */
driver_t *find_best_match_driver(driver_list_t *drivers_list, node_t *node)
{
        driver_t *best_drv = NULL, *drv = NULL;
        int best_score = 0, score = 0;
        
        fibril_mutex_lock(&drivers_list->drivers_mutex);
        
        link_t *link = drivers_list->drivers.next;
        while (link != &drivers_list->drivers) {
                drv = list_get_instance(link, driver_t, drivers);
                score = get_match_score(drv, node);
                if (score > best_score) {
                        best_score = score;
                        best_drv = drv;
                }
                link = link->next;
        }
        
        fibril_mutex_unlock(&drivers_list->drivers_mutex);
        
        return best_drv;
}

/** Assign a driver to a device.
 *
 * @param node          The device's node in the device tree.
 * @param drv           The driver.
 */
void attach_driver(node_t *node, driver_t *drv)
{
        printf(NAME ": attach_driver %s to device %s\n",
            drv->name, node->pathname);
        
        fibril_mutex_lock(&drv->driver_mutex);
        
        node->drv = drv;
        list_append(&node->driver_devices, &drv->devices);
        
        fibril_mutex_unlock(&drv->driver_mutex);
}

/** Start a driver
 *
 * The driver's mutex is assumed to be locked.
 *
 * @param drv           The driver's structure.
 * @return              True if the driver's task is successfully spawned, false
 *                      otherwise.
 */
bool start_driver(driver_t *drv)
{
        int rc;

        printf(NAME ": start_driver '%s'\n", drv->name);
        
        rc = task_spawnl(NULL, drv->binary_path, drv->binary_path, NULL);
        if (rc != EOK) {
                printf(NAME ": error spawning %s (%s)\n",
                    drv->name, str_error(rc));
                return false;
        }
        
        drv->state = DRIVER_STARTING;
        return true;
}

/** Find device driver in the list of device drivers.
 *
 * @param drv_list      The list of device drivers.
 * @param drv_name      The name of the device driver which is searched.
 * @return              The device driver of the specified name, if it is in the
 *                      list, NULL otherwise.
 */
driver_t *find_driver(driver_list_t *drv_list, const char *drv_name)
{
        driver_t *res = NULL;
        driver_t *drv = NULL;
        link_t *link;
        
        fibril_mutex_lock(&drv_list->drivers_mutex);
        
        link = drv_list->drivers.next;
        while (link != &drv_list->drivers) {
                drv = list_get_instance(link, driver_t, drivers);
                if (str_cmp(drv->name, drv_name) == 0) {
                        res = drv;
                        break;
                }

                link = link->next;
        }
        
        fibril_mutex_unlock(&drv_list->drivers_mutex);
        
        return res;
}

/** Remember the driver's phone.
 *
 * @param driver        The driver.
 * @param phone         The phone to the driver.
 */
void set_driver_phone(driver_t *driver, ipcarg_t phone)
{
        fibril_mutex_lock(&driver->driver_mutex);
        assert(driver->state == DRIVER_STARTING);
        driver->phone = phone;
        fibril_mutex_unlock(&driver->driver_mutex);
}

/** Notify driver about the devices to which it was assigned.
 *
 * @param driver        The driver to which the devices are passed.
 */
static void pass_devices_to_driver(driver_t *driver, dev_tree_t *tree)
{
        node_t *dev;
        link_t *link;
        int phone;

        printf(NAME ": pass_devices_to_driver(`%s')\n", driver->name);

        fibril_mutex_lock(&driver->driver_mutex);

        phone = async_connect_me_to(driver->phone, DRIVER_DEVMAN, 0, 0);

        if (phone < 0) {
                fibril_mutex_unlock(&driver->driver_mutex);
                return;
        }

        /*
         * Go through devices list as long as there is some device
         * that has not been passed to the driver.
         */
        link = driver->devices.next;
        while (link != &driver->devices) {
                dev = list_get_instance(link, node_t, driver_devices);
                if (dev->passed_to_driver) {
                        link = link->next;
                        continue;
                }

                /*
                 * We remove the device from the list to allow safe adding
                 * of new devices (no one will touch our item this way).
                 */
                list_remove(link);

                /*
                 * Unlock to avoid deadlock when adding device
                 * handled by itself.
                 */
                fibril_mutex_unlock(&driver->driver_mutex);

                add_device(phone, driver, dev, tree);

                /*
                 * Lock again as we will work with driver's
                 * structure.
                 */
                fibril_mutex_lock(&driver->driver_mutex);

                /*
                 * Insert the device back.
                 * The order is not relevant here so no harm is done
                 * (actually, the order would be preserved in most cases).
                 */
                list_append(link, &driver->devices);

                /*
                 * Restart the cycle to go through all devices again.
                 */
                link = driver->devices.next;
        }

        ipc_hangup(phone);

        /*
         * Once we passed all devices to the driver, we need to mark the
         * driver as running.
         * It is vital to do it here and inside critical section.
         *
         * If we would change the state earlier, other devices added to
         * the driver would be added to the device list and started
         * immediately and possibly started here as well.
         */
        printf(NAME ": driver %s goes into running state.\n", driver->name);
        driver->state = DRIVER_RUNNING;

        fibril_mutex_unlock(&driver->driver_mutex);
}

/** Finish the initialization of a driver after it has succesfully started
 * and after it has registered itself by the device manager.
 *
 * Pass devices formerly matched to the driver to the driver and remember the
 * driver is running and fully functional now.
 *
 * @param driver        The driver which registered itself as running by the
 *                      device manager.
 */
void initialize_running_driver(driver_t *driver, dev_tree_t *tree)
{
        printf(NAME ": initialize_running_driver (`%s')\n", driver->name);
        
        /*
         * Pass devices which have been already assigned to the driver to the
         * driver.
         */
        pass_devices_to_driver(driver, tree);
}

/** Initialize device driver structure.
 *
 * @param drv           The device driver structure.
 */
void init_driver(driver_t *drv)
{
        assert(drv != NULL);

        memset(drv, 0, sizeof(driver_t));
        list_initialize(&drv->match_ids.ids);
        list_initialize(&drv->devices);
        fibril_mutex_initialize(&drv->driver_mutex);
}

/** Device driver structure clean-up.
 *
 * @param drv           The device driver structure.
 */
void clean_driver(driver_t *drv)
{
        assert(drv != NULL);

        free_not_null(drv->name);
        free_not_null(drv->binary_path);

        clean_match_ids(&drv->match_ids);

        init_driver(drv);
}

/** Delete device driver structure.
 *
 * @param drv           The device driver structure.
 */
void delete_driver(driver_t *drv)
{
        assert(drv != NULL);
        
        clean_driver(drv);
        free(drv);
}

/** Create devmap path and name for the device. */
static void devmap_register_tree_device(node_t *node, dev_tree_t *tree)
{
        char *devmap_pathname = NULL;
        char *devmap_name = NULL;
        
        asprintf(&devmap_name, "%s", node->pathname);
        if (devmap_name == NULL)
                return;
        
        replace_char(devmap_name, '/', DEVMAP_SEPARATOR);
        
        asprintf(&devmap_pathname, "%s/%s", DEVMAP_DEVICE_NAMESPACE,
            devmap_name);
        if (devmap_pathname == NULL) {
                free(devmap_name);
                return;
        }
        
        devmap_device_register(devmap_pathname, &node->devmap_handle);
        
        tree_add_devmap_device(tree, node);
        
        free(devmap_name);
        free(devmap_pathname);
}

static FIBRIL_MUTEX_INITIALIZE(add_device_guard);

/** Pass a device to running driver.
 *
 * @param drv           The driver's structure.
 * @param node          The device's node in the device tree.
 */
void add_device(int phone, driver_t *drv, node_t *node, dev_tree_t *tree)
{
        fibril_mutex_lock(&add_device_guard);

        /*
         * We do not expect to have driver's mutex locked as we do not
         * access any structures that would affect driver_t.
         */
        printf(NAME ": add_device (driver `%s', device `%s')\n", drv->name,
            node->name);
        
        ipcarg_t rc;
        ipc_call_t answer;
        
        /* Send the device to the driver. */
        devman_handle_t parent_handle;
        if (node->parent) {
                parent_handle = node->parent->handle;
        } else {
                parent_handle = 0;
        }

        aid_t req = async_send_2(phone, DRIVER_ADD_DEVICE, node->handle,
            parent_handle, &answer);
        
        /* Send the device's name to the driver. */
        rc = async_data_write_start(phone, node->name,
            str_size(node->name) + 1);
        if (rc != EOK) {
                /* TODO handle error */
        }

        /* Wait for answer from the driver. */
        async_wait_for(req, &rc);

        fibril_mutex_unlock(&add_device_guard);

        switch(rc) {
        case EOK:
                node->state = DEVICE_USABLE;
                devmap_register_tree_device(node, tree);
                break;
        case ENOENT:
                node->state = DEVICE_NOT_PRESENT;
                break;
        default:
                node->state = DEVICE_INVALID;
        }
        
        node->passed_to_driver = true;

        return;
}

/** Find suitable driver for a device and assign the driver to it.
 *
 * @param node          The device node of the device in the device tree.
 * @param drivers_list  The list of available drivers.
 * @return              True if the suitable driver is found and
 *                      successfully assigned to the device, false otherwise.
 */
bool assign_driver(node_t *node, driver_list_t *drivers_list, dev_tree_t *tree)
{
        /*
         * Find the driver which is the most suitable for handling this device.
         */
        driver_t *drv = find_best_match_driver(drivers_list, node);
        if (drv == NULL) {
                printf(NAME ": no driver found for device '%s'.\n",
                    node->pathname);
                return false;
        }
        
        /* Attach the driver to the device. */
        attach_driver(node, drv);
        
        fibril_mutex_lock(&drv->driver_mutex);
        if (drv->state == DRIVER_NOT_STARTED) {
                /* Start the driver. */
                start_driver(drv);
        }
        bool is_running = drv->state == DRIVER_RUNNING;
        fibril_mutex_unlock(&drv->driver_mutex);

        if (is_running) {
                /* Notify the driver about the new device. */
                int phone = async_connect_me_to(drv->phone, DRIVER_DEVMAN, 0, 0);
                if (phone > 0) {
                        add_device(phone, drv, node, tree);
                        ipc_hangup(phone);
                }
        }
        
        return true;
}

/** Initialize the device tree.
 *
 * Create root device node of the tree and assign driver to it.
 *
 * @param tree          The device tree.
 * @param drivers_list  the list of available drivers.
 * @return              True on success, false otherwise.
 */
bool init_device_tree(dev_tree_t *tree, driver_list_t *drivers_list)
{
        printf(NAME ": init_device_tree.\n");
        
        tree->current_handle = 0;
        
        hash_table_create(&tree->devman_devices, DEVICE_BUCKETS, 1,
            &devman_devices_ops);
        hash_table_create(&tree->devmap_devices, DEVICE_BUCKETS, 1,
            &devmap_devices_ops);
        
        fibril_rwlock_initialize(&tree->rwlock);
        
        /* Create root node and add it to the device tree. */
        if (!create_root_node(tree))
                return false;

        /* Find suitable driver and start it. */
        return assign_driver(tree->root_node, drivers_list, tree);
}

/* Device nodes */

/** Create a new device node.
 *
 * @return              A device node structure.
 */
node_t *create_dev_node(void)
{
        node_t *res = malloc(sizeof(node_t));
        
        if (res != NULL) {
                memset(res, 0, sizeof(node_t));
                list_initialize(&res->children);
                list_initialize(&res->match_ids.ids);
                list_initialize(&res->classes);
        }
        
        return res;
}

/** Delete a device node.
 *
 * @param node          The device node structure.
 */
void delete_dev_node(node_t *node)
{
        assert(list_empty(&node->children));
        assert(node->parent == NULL);
        assert(node->drv == NULL);
        
        clean_match_ids(&node->match_ids);
        free_not_null(node->name);
        free_not_null(node->pathname);
        free(node);
}

/** Find the device node structure of the device witch has the specified handle.
 *
 * Device tree's rwlock should be held at least for reading.
 *
 * @param tree          The device tree where we look for the device node.
 * @param handle        The handle of the device.
 * @return              The device node.
 */
node_t *find_dev_node_no_lock(dev_tree_t *tree, devman_handle_t handle)
{
        unsigned long key = handle;
        link_t *link = hash_table_find(&tree->devman_devices, &key);
        return hash_table_get_instance(link, node_t, devman_link);
}

/** Find the device node structure of the device witch has the specified handle.
 *
 * @param tree          The device tree where we look for the device node.
 * @param handle        The handle of the device.
 * @return              The device node.
 */
node_t *find_dev_node(dev_tree_t *tree, devman_handle_t handle)
{
        node_t *node = NULL;
        
        fibril_rwlock_read_lock(&tree->rwlock);
        node = find_dev_node_no_lock(tree, handle);
        fibril_rwlock_read_unlock(&tree->rwlock);
        
        return node;
}


/** Create and set device's full path in device tree.
 *
 * @param node          The device's device node.
 * @param parent        The parent device node.
 * @return              True on success, false otherwise (insufficient
 *                      resources etc.).
 */
static bool set_dev_path(node_t *node, node_t *parent)
{
        assert(node->name != NULL);
        
        size_t pathsize = (str_size(node->name) + 1);
        if (parent != NULL)
                pathsize += str_size(parent->pathname) + 1;
        
        node->pathname = (char *) malloc(pathsize);
        if (node->pathname == NULL) {
                printf(NAME ": failed to allocate device path.\n");
                return false;
        }
        
        if (parent != NULL) {
                str_cpy(node->pathname, pathsize, parent->pathname);
                str_append(node->pathname, pathsize, "/");
                str_append(node->pathname, pathsize, node->name);
        } else {
                str_cpy(node->pathname, pathsize, node->name);
        }
        
        return true;
}

/** Insert new device into device tree.
 *
 * The device tree's rwlock should be already held exclusively when calling this
 * function.
 *
 * @param tree          The device tree.
 * @param node          The newly added device node. 
 * @param dev_name      The name of the newly added device.
 * @param parent        The parent device node.
 *
 * @return              True on success, false otherwise (insufficient resources
 *                      etc.).
 */
bool insert_dev_node(dev_tree_t *tree, node_t *node, char *dev_name,
    node_t *parent)
{
        assert(node != NULL);
        assert(tree != NULL);
        assert(dev_name != NULL);
        
        node->name = dev_name;
        if (!set_dev_path(node, parent)) {
                return false;
        }
        
        /* Add the node to the handle-to-node map. */
        node->handle = ++tree->current_handle;
        unsigned long key = node->handle;
        hash_table_insert(&tree->devman_devices, &key, &node->devman_link);

        /* Add the node to the list of its parent's children. */
        node->parent = parent;
        if (parent != NULL)
                list_append(&node->sibling, &parent->children);
        
        return true;
}

/** Find device node with a specified path in the device tree.
 * 
 * @param path          The path of the device node in the device tree.
 * @param tree          The device tree.
 * @return              The device node if it is present in the tree, NULL
 *                      otherwise.
 */
node_t *find_dev_node_by_path(dev_tree_t *tree, char *path)
{
        fibril_rwlock_read_lock(&tree->rwlock);
        
        node_t *dev = tree->root_node;
        /*
         * Relative path to the device from its parent (but with '/' at the
         * beginning)
         */
        char *rel_path = path;
        char *next_path_elem = NULL;
        bool cont = (rel_path[0] == '/');
        
        while (cont && dev != NULL) {
                next_path_elem  = get_path_elem_end(rel_path + 1);
                if (next_path_elem[0] == '/') {
                        cont = true;
                        next_path_elem[0] = 0;
                } else {
                        cont = false;
                }
                
                dev = find_node_child(dev, rel_path + 1);
                
                if (cont) {
                        /* Restore the original path. */
                        next_path_elem[0] = '/';
                }
                rel_path = next_path_elem;
        }
        
        fibril_rwlock_read_unlock(&tree->rwlock);
        
        return dev;
}

/** Find child device node with a specified name.
 *
 * Device tree rwlock should be held at least for reading.
 *
 * @param parent        The parent device node.
 * @param name          The name of the child device node.
 * @return              The child device node.
 */
node_t *find_node_child(node_t *parent, const char *name)
{
        node_t *dev;
        link_t *link;
        
        link = parent->children.next;
        
        while (link != &parent->children) {
                dev = list_get_instance(link, node_t, sibling);
                
                if (str_cmp(name, dev->name) == 0)
                        return dev;
                
                link = link->next;
        }
        
        return NULL;
}

/* Device classes */

/** Create device class.
 *
 * @return      Device class.
 */
dev_class_t *create_dev_class(void)
{
        dev_class_t *cl;
        
        cl = (dev_class_t *) malloc(sizeof(dev_class_t));
        if (cl != NULL) {
                memset(cl, 0, sizeof(dev_class_t));
                list_initialize(&cl->devices);
                fibril_mutex_initialize(&cl->mutex);
        }
        
        return cl;
}

/** Create device class info.
 *
 * @return              Device class info.
 */
dev_class_info_t *create_dev_class_info(void)
{
        dev_class_info_t *info;
        
        info = (dev_class_info_t *) malloc(sizeof(dev_class_info_t));
        if (info != NULL)
                memset(info, 0, sizeof(dev_class_info_t));
        
        return info;
}

size_t get_new_class_dev_idx(dev_class_t *cl)
{
        size_t dev_idx;
        
        fibril_mutex_lock(&cl->mutex);
        dev_idx = ++cl->curr_dev_idx;
        fibril_mutex_unlock(&cl->mutex);
        
        return dev_idx;
}


/** Create unique device name within the class.
 *
 * @param cl            The class.
 * @param base_dev_name Contains the base name for the device if it was
 *                      specified by the driver when it registered the device by
 *                      the class; NULL if driver specified no base name.
 * @return              The unique name for the device within the class.
 */
char *create_dev_name_for_class(dev_class_t *cl, const char *base_dev_name)
{
        char *dev_name;
        const char *base_name;
        
        if (base_dev_name != NULL)
                base_name = base_dev_name;
        else
                base_name = cl->base_dev_name;
        
        size_t idx = get_new_class_dev_idx(cl);
        asprintf(&dev_name, "%s%zu", base_name, idx);
        
        return dev_name;
}

/** Add the device to the class.
 *
 * The device may be added to multiple classes and a class may contain multiple
 * devices. The class and the device are associated with each other by the
 * dev_class_info_t structure.
 *
 * @param dev           The device.
 * @param class         The class.
 * @param base_dev_name The base name of the device within the class if
 *                      specified by the driver, NULL otherwise.
 * @return              dev_class_info_t structure which associates the device
 *                      with the class.
 */
dev_class_info_t *add_device_to_class(node_t *dev, dev_class_t *cl,
    const char *base_dev_name)
{
        dev_class_info_t *info = create_dev_class_info();
        
        if (info != NULL) {
                info->dev_class = cl;
                info->dev = dev;
                
                /* Add the device to the class. */
                fibril_mutex_lock(&cl->mutex);
                list_append(&info->link, &cl->devices);
                fibril_mutex_unlock(&cl->mutex);
                
                /* Add the class to the device. */
                list_append(&info->dev_classes, &dev->classes);
                
                /* Create unique name for the device within the class. */
                info->dev_name = create_dev_name_for_class(cl, base_dev_name);
        }
        
        return info;
}

dev_class_t *get_dev_class(class_list_t *class_list, char *class_name)
{
        dev_class_t *cl;
        
        fibril_rwlock_write_lock(&class_list->rwlock);
        cl = find_dev_class_no_lock(class_list, class_name);
        if (cl == NULL) {
                cl = create_dev_class();
                if (cl != NULL) {
                        cl->name = class_name;
                        cl->base_dev_name = "";
                        add_dev_class_no_lock(class_list, cl);
                }
        }

        fibril_rwlock_write_unlock(&class_list->rwlock);
        return cl;
}

dev_class_t *find_dev_class_no_lock(class_list_t *class_list,
    const char *class_name)
{
        dev_class_t *cl;
        link_t *link = class_list->classes.next;
        
        while (link != &class_list->classes) {
                cl = list_get_instance(link, dev_class_t, link);
                if (str_cmp(cl->name, class_name) == 0) {
                        return cl;
                }
                link = link->next;
        }
        
        return NULL;
}

void add_dev_class_no_lock(class_list_t *class_list, dev_class_t *cl)
{
        list_append(&cl->link, &class_list->classes);
}

void init_class_list(class_list_t *class_list)
{
        list_initialize(&class_list->classes);
        fibril_rwlock_initialize(&class_list->rwlock);
        hash_table_create(&class_list->devmap_devices, DEVICE_BUCKETS, 1,
            &devmap_devices_ops);
}


/* Devmap devices */

node_t *find_devmap_tree_device(dev_tree_t *tree, devmap_handle_t devmap_handle)
{
        node_t *dev = NULL;
        link_t *link;
        unsigned long key = (unsigned long) devmap_handle;
        
        fibril_rwlock_read_lock(&tree->rwlock);
        link = hash_table_find(&tree->devmap_devices, &key);
        if (link != NULL)
                dev = hash_table_get_instance(link, node_t, devmap_link);
        fibril_rwlock_read_unlock(&tree->rwlock);
        
        return dev;
}

node_t *find_devmap_class_device(class_list_t *classes,
    devmap_handle_t devmap_handle)
{
        node_t *dev = NULL;
        dev_class_info_t *cli;
        link_t *link;
        unsigned long key = (unsigned long)devmap_handle;
        
        fibril_rwlock_read_lock(&classes->rwlock);
        link = hash_table_find(&classes->devmap_devices, &key);
        if (link != NULL) {
                cli = hash_table_get_instance(link, dev_class_info_t,
                    devmap_link);
                dev = cli->dev;
        }
        fibril_rwlock_read_unlock(&classes->rwlock);
        
        return dev;
}

void class_add_devmap_device(class_list_t *class_list, dev_class_info_t *cli)
{
        unsigned long key = (unsigned long) cli->devmap_handle;
        
        fibril_rwlock_write_lock(&class_list->rwlock);
        hash_table_insert(&class_list->devmap_devices, &key, &cli->devmap_link);
        fibril_rwlock_write_unlock(&class_list->rwlock);
}

void tree_add_devmap_device(dev_tree_t *tree, node_t *node)
{
        unsigned long key = (unsigned long) node->devmap_handle;
        fibril_rwlock_write_lock(&tree->rwlock);
        hash_table_insert(&tree->devmap_devices, &key, &node->devmap_link);
        fibril_rwlock_write_unlock(&tree->rwlock);
}

/** @}
 */