source: mainline/kernel/generic/src/console/cmd.c@ ddf1255

/*
 * Copyright (c) 2005 Jakub Jermar
 * 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 genericconsole
 * @{
 */

/**
 * @file        cmd.c
 * @brief       Kernel console command wrappers.
 *
 * This file is meant to contain all wrapper functions for
 * all kconsole commands. The point is in separating
 * kconsole specific wrappers from kconsole-unaware functions
 * from other subsystems.
 */

#include <console/cmd.h>
#include <console/console.h>
#include <console/kconsole.h>
#include <print.h>
#include <panic.h>
#include <arch/types.h>
#include <adt/list.h>
#include <arch.h>
#include <config.h>
#include <func.h>
#include <macros.h>
#include <debug.h>
#include <symtab.h>
#include <cpu.h>
#include <mm/tlb.h>
#include <arch/mm/tlb.h>
#include <mm/frame.h>
#include <main/version.h>
#include <mm/slab.h>
#include <proc/scheduler.h>
#include <proc/thread.h>
#include <proc/task.h>
#include <ipc/ipc.h>
#include <ipc/irq.h>

#ifdef CONFIG_TEST
#include <test.h>
#endif

/* Data and methods for 'help' command. */
static int cmd_help(cmd_arg_t *argv);
static cmd_info_t help_info = {
        .name = "help",
        .description = "List of supported commands.",
        .func = cmd_help,
        .argc = 0
};

static cmd_info_t exit_info = {
        .name = "exit",
        .description = "Exit kconsole.",
        .argc = 0
};

static int cmd_reboot(cmd_arg_t *argv);
static cmd_info_t reboot_info = {
        .name = "reboot",
        .description = "Reboot.",
        .func = cmd_reboot,
        .argc = 0
};

static int cmd_uptime(cmd_arg_t *argv);
static cmd_info_t uptime_info = {
        .name = "uptime",
        .description = "Print uptime information.",
        .func = cmd_uptime,
        .argc = 0
};

static int cmd_continue(cmd_arg_t *argv);
static cmd_info_t continue_info = {
        .name = "continue",
        .description = "Return console back to userspace.",
        .func = cmd_continue,
        .argc = 0
};

#ifdef CONFIG_TEST
static int cmd_tests(cmd_arg_t *argv);
static cmd_info_t tests_info = {
        .name = "tests",
        .description = "Print available kernel tests.",
        .func = cmd_tests,
        .argc = 0
};

static char test_buf[MAX_CMDLINE + 1];
static int cmd_test(cmd_arg_t *argv);
static cmd_arg_t test_argv[] = {
        {
                .type = ARG_TYPE_STRING,
                .buffer = test_buf,
                .len = sizeof(test_buf)
        }
};
static cmd_info_t test_info = {
        .name = "test",
        .description = "Run kernel test.",
        .func = cmd_test,
        .argc = 1,
        .argv = test_argv
};

static int cmd_bench(cmd_arg_t *argv);
static cmd_arg_t bench_argv[] = {
        {
                .type = ARG_TYPE_STRING,
                .buffer = test_buf,
                .len = sizeof(test_buf)
        },
        {
                .type = ARG_TYPE_INT,
        }
};
static cmd_info_t bench_info = {
        .name = "bench",
        .description = "Run kernel test as benchmark.",
        .func = cmd_bench,
        .argc = 2,
        .argv = bench_argv
};
#endif

/* Data and methods for 'description' command. */
static int cmd_desc(cmd_arg_t *argv);
static void desc_help(void);
static char desc_buf[MAX_CMDLINE+1];
static cmd_arg_t desc_argv = {
        .type = ARG_TYPE_STRING,
        .buffer = desc_buf,
        .len = sizeof(desc_buf)
};
static cmd_info_t desc_info = {
        .name = "describe",
        .description = "Describe specified command.",
        .help = desc_help,
        .func = cmd_desc,
        .argc = 1,
        .argv = &desc_argv
};

/* Data and methods for 'symaddr' command. */
static int cmd_symaddr(cmd_arg_t *argv);
static char symaddr_buf[MAX_CMDLINE+1];
static cmd_arg_t symaddr_argv = {
        .type = ARG_TYPE_STRING,
        .buffer = symaddr_buf,
        .len = sizeof(symaddr_buf)
};
static cmd_info_t symaddr_info = {
        .name = "symaddr",
        .description = "Return symbol address.",
        .func = cmd_symaddr,
        .argc = 1,
        .argv = &symaddr_argv
};

static char set_buf[MAX_CMDLINE+1];
static int cmd_set4(cmd_arg_t *argv);
static cmd_arg_t set4_argv[] = {
        {
                .type = ARG_TYPE_STRING,
                .buffer = set_buf,
                .len = sizeof(set_buf)
        },
        { 
                .type = ARG_TYPE_INT
        }
};
static cmd_info_t set4_info = {
        .name = "set4",
        .description = "set <dest_addr> <value> - 4byte version",
        .func = cmd_set4,
        .argc = 2,
        .argv = set4_argv
};

/* Data and methods for 'call0' command. */
static char call0_buf[MAX_CMDLINE + 1];
static char carg1_buf[MAX_CMDLINE + 1];
static char carg2_buf[MAX_CMDLINE + 1];
static char carg3_buf[MAX_CMDLINE + 1];

static int cmd_call0(cmd_arg_t *argv);
static cmd_arg_t call0_argv = {
        .type = ARG_TYPE_STRING,
        .buffer = call0_buf,
        .len = sizeof(call0_buf)
};
static cmd_info_t call0_info = {
        .name = "call0",
        .description = "call0 <function> -> call function().",
        .func = cmd_call0,
        .argc = 1,
        .argv = &call0_argv
};

/* Data and methods for 'mcall0' command. */
static int cmd_mcall0(cmd_arg_t *argv);
static cmd_arg_t mcall0_argv = {
        .type = ARG_TYPE_STRING,
        .buffer = call0_buf,
        .len = sizeof(call0_buf)
};
static cmd_info_t mcall0_info = {
        .name = "mcall0",
        .description = "mcall0 <function> -> call function() on each CPU.",
        .func = cmd_mcall0,
        .argc = 1,
        .argv = &mcall0_argv
};

/* Data and methods for 'call1' command. */
static int cmd_call1(cmd_arg_t *argv);
static cmd_arg_t call1_argv[] = {
        {
                .type = ARG_TYPE_STRING,
                .buffer = call0_buf,
                .len = sizeof(call0_buf)
        },
        { 
                .type = ARG_TYPE_VAR,
                .buffer = carg1_buf,
                .len = sizeof(carg1_buf)
        }
};
static cmd_info_t call1_info = {
        .name = "call1",
        .description = "call1 <function> <arg1> -> call function(arg1).",
        .func = cmd_call1,
        .argc = 2,
        .argv = call1_argv
};

/* Data and methods for 'call2' command. */
static int cmd_call2(cmd_arg_t *argv);
static cmd_arg_t call2_argv[] = {
        {
                .type = ARG_TYPE_STRING,
                .buffer = call0_buf,
                .len = sizeof(call0_buf)
        },
        { 
                .type = ARG_TYPE_VAR,
                .buffer = carg1_buf,
                .len = sizeof(carg1_buf)
        },
        { 
                .type = ARG_TYPE_VAR,
                .buffer = carg2_buf,
                .len = sizeof(carg2_buf)
        }
};
static cmd_info_t call2_info = {
        .name = "call2",
        .description = "call2 <function> <arg1> <arg2> -> call function(arg1,arg2).",
        .func = cmd_call2,
        .argc = 3,
        .argv = call2_argv
};

/* Data and methods for 'call3' command. */
static int cmd_call3(cmd_arg_t *argv);
static cmd_arg_t call3_argv[] = {
        {
                .type = ARG_TYPE_STRING,
                .buffer = call0_buf,
                .len = sizeof(call0_buf)
        },
        { 
                .type = ARG_TYPE_VAR,
                .buffer = carg1_buf,
                .len = sizeof(carg1_buf)
        },
        { 
                .type = ARG_TYPE_VAR,
                .buffer = carg2_buf,
                .len = sizeof(carg2_buf)
        },
        { 
                .type = ARG_TYPE_VAR,
                .buffer = carg3_buf,
                .len = sizeof(carg3_buf)
        }

};
static cmd_info_t call3_info = {
        .name = "call3",
        .description = "call3 <function> <arg1> <arg2> <arg3> -> call function(arg1,arg2,arg3).",
        .func = cmd_call3,
        .argc = 4,
        .argv = call3_argv
};

/* Data and methods for 'halt' command. */
static int cmd_halt(cmd_arg_t *argv);
static cmd_info_t halt_info = {
        .name = "halt",
        .description = "Halt the kernel.",
        .func = cmd_halt,
        .argc = 0
};

/* Data and methods for 'tlb' command. */
static int cmd_tlb(cmd_arg_t *argv);
cmd_info_t tlb_info = {
        .name = "tlb",
        .description = "Print TLB of current processor.",
        .help = NULL,
        .func = cmd_tlb,
        .argc = 0,
        .argv = NULL
};

static int cmd_threads(cmd_arg_t *argv);
static cmd_info_t threads_info = {
        .name = "threads",
        .description = "List all threads.",
        .func = cmd_threads,
        .argc = 0
};

static int cmd_tasks(cmd_arg_t *argv);
static cmd_info_t tasks_info = {
        .name = "tasks",
        .description = "List all tasks.",
        .func = cmd_tasks,
        .argc = 0
};


static int cmd_sched(cmd_arg_t *argv);
static cmd_info_t sched_info = {
        .name = "scheduler",
        .description = "List all scheduler information.",
        .func = cmd_sched,
        .argc = 0
};

static int cmd_slabs(cmd_arg_t *argv);
static cmd_info_t slabs_info = {
        .name = "slabs",
        .description = "List slab caches.",
        .func = cmd_slabs,
        .argc = 0
};

/* Data and methods for 'zones' command */
static int cmd_zones(cmd_arg_t *argv);
static cmd_info_t zones_info = {
        .name = "zones",
        .description = "List of memory zones.",
        .func = cmd_zones,
        .argc = 0
};

/* Data and methods for 'ipc_task' command */
static int cmd_ipc_task(cmd_arg_t *argv);
static cmd_arg_t ipc_task_argv = {
        .type = ARG_TYPE_INT,
};
static cmd_info_t ipc_task_info = {
        .name = "ipc_task",
        .description = "ipc_task <taskid> Show IPC information of given task.",
        .func = cmd_ipc_task,
        .argc = 1,
        .argv = &ipc_task_argv
};

/* Data and methods for 'zone' command */
static int cmd_zone(cmd_arg_t *argv);
static cmd_arg_t zone_argv = {
        .type = ARG_TYPE_INT,
};

static cmd_info_t zone_info = {
        .name = "zone",
        .description = "Show memory zone structure.",
        .func = cmd_zone,
        .argc = 1,
        .argv = &zone_argv
};

/* Data and methods for 'cpus' command. */
static int cmd_cpus(cmd_arg_t *argv);
cmd_info_t cpus_info = {
        .name = "cpus",
        .description = "List all processors.",
        .help = NULL,
        .func = cmd_cpus,
        .argc = 0,
        .argv = NULL
};

/* Data and methods for 'version' command. */
static int cmd_version(cmd_arg_t *argv);
cmd_info_t version_info = {
        .name = "version",
        .description = "Print version information.",
        .help = NULL,
        .func = cmd_version,
        .argc = 0,
        .argv = NULL
};

static cmd_info_t *basic_commands[] = {
        &call0_info,
        &mcall0_info,
        &call1_info,
        &call2_info,
        &call3_info,
        &continue_info,
        &cpus_info,
        &desc_info,
        &exit_info,
        &reboot_info,
        &uptime_info,
        &halt_info,
        &help_info,
        &ipc_task_info,
        &set4_info,
        &slabs_info,
        &symaddr_info,
        &sched_info,
        &threads_info,
        &tasks_info,
        &tlb_info,
        &version_info,
        &zones_info,
        &zone_info,
#ifdef CONFIG_TEST
        &tests_info,
        &test_info,
        &bench_info,
#endif
        NULL
};


/** Initialize command info structure.
 *
 * @param cmd Command info structure.
 *
 */
void cmd_initialize(cmd_info_t *cmd)
{
        spinlock_initialize(&cmd->lock, "cmd");
        link_initialize(&cmd->link);
}

/** Initialize and register commands. */
void cmd_init(void)
{
        int i;

        for (i=0;basic_commands[i]; i++) {
                cmd_initialize(basic_commands[i]);
                if (!cmd_register(basic_commands[i]))
                        panic("could not register command %s\n", 
                              basic_commands[i]->name);
        }
}


/** List supported commands.
 *
 * @param argv Argument vector.
 *
 * @return 0 on failure, 1 on success.
 */
int cmd_help(cmd_arg_t *argv)
{
        link_t *cur;

        spinlock_lock(&cmd_lock);
        
        for (cur = cmd_head.next; cur != &cmd_head; cur = cur->next) {
                cmd_info_t *hlp;
                
                hlp = list_get_instance(cur, cmd_info_t, link);
                spinlock_lock(&hlp->lock);
                
                printf("%s - %s\n", hlp->name, hlp->description);

                spinlock_unlock(&hlp->lock);
        }
        
        spinlock_unlock(&cmd_lock);     

        return 1;
}


/** Reboot the system.
 *
 * @param argv Argument vector.
 *
 * @return 0 on failure, 1 on success.
 */
int cmd_reboot(cmd_arg_t *argv)
{
        reboot();
        
        /* Not reached */
        return 1;
}


/** Print system uptime information.
 *
 * @param argv Argument vector.
 *
 * @return 0 on failure, 1 on success.
 */
int cmd_uptime(cmd_arg_t *argv)
{
        ASSERT(uptime);
        
        /* This doesn't have to be very accurate */
        unative_t sec = uptime->seconds1;
        
        printf("Up %u days, %u hours, %u minutes, %u seconds\n",
                sec / 86400, (sec % 86400) / 3600, (sec % 3600) / 60, sec % 60);
        
        return 1;
}

/** Describe specified command.
 *
 * @param argv Argument vector.
 *
 * @return 0 on failure, 1 on success.
 */
int cmd_desc(cmd_arg_t *argv)
{
        link_t *cur;

        spinlock_lock(&cmd_lock);
        
        for (cur = cmd_head.next; cur != &cmd_head; cur = cur->next) {
                cmd_info_t *hlp;
                
                hlp = list_get_instance(cur, cmd_info_t, link);
                spinlock_lock(&hlp->lock);

                if (strncmp(hlp->name, (const char *) argv->buffer, strlen(hlp->name)) == 0) {
                        printf("%s - %s\n", hlp->name, hlp->description);
                        if (hlp->help)
                                hlp->help();
                        spinlock_unlock(&hlp->lock);
                        break;
                }

                spinlock_unlock(&hlp->lock);
        }
        
        spinlock_unlock(&cmd_lock);     

        return 1;
}

/** Search symbol table */
int cmd_symaddr(cmd_arg_t *argv)
{
        symtab_print_search((char *) argv->buffer);
        
        return 1;
}

/** Call function with zero parameters */
int cmd_call0(cmd_arg_t *argv)
{
        uintptr_t symaddr;
        char *symbol;
        unative_t (*f)(void);
#ifdef ia64
        struct {
                unative_t f;
                unative_t gp;
        } fptr;
#endif

        symaddr = get_symbol_addr((char *) argv->buffer);
        if (!symaddr)
                printf("Symbol %s not found.\n", argv->buffer);
        else if (symaddr == (uintptr_t) -1) {
                symtab_print_search((char *) argv->buffer);
                printf("Duplicate symbol, be more specific.\n");
        } else {
                symbol = get_symtab_entry(symaddr);
                printf("Calling %s() (%.*p)\n", symbol, sizeof(uintptr_t) * 2, symaddr);
#ifdef ia64
                fptr.f = symaddr;
                fptr.gp = ((unative_t *)cmd_call2)[1];
                f =  (unative_t (*)(void)) &fptr;
#else
                f =  (unative_t (*)(void)) symaddr;
#endif
                printf("Result: %#zx\n", f());
        }
        
        return 1;
}

/** Call function with zero parameters on each CPU */
int cmd_mcall0(cmd_arg_t *argv)
{
        /*
         * For each CPU, create a thread which will
         * call the function.
         */
        
        count_t i;
        for (i = 0; i < config.cpu_count; i++) {
                if (!cpus[i].active)
                        continue;
                
                thread_t *t;
                if ((t = thread_create((void (*)(void *)) cmd_call0, (void *) argv, TASK, THREAD_FLAG_WIRED, "call0", false))) {
                        spinlock_lock(&t->lock);
                        t->cpu = &cpus[i];
                        spinlock_unlock(&t->lock);
                        printf("cpu%u: ", i);
                        thread_ready(t);
                        thread_join(t);
                        thread_detach(t);
                } else
                        printf("Unable to create thread for cpu%u\n", i);
        }
        
        return 1;
}

/** Call function with one parameter */
int cmd_call1(cmd_arg_t *argv)
{
        uintptr_t symaddr;
        char *symbol;
        unative_t (*f)(unative_t,...);
        unative_t arg1 = argv[1].intval;
#ifdef ia64
        struct {
                unative_t f;
                unative_t gp;
        }fptr;
#endif

        symaddr = get_symbol_addr((char *) argv->buffer);
        if (!symaddr)
                printf("Symbol %s not found.\n", argv->buffer);
        else if (symaddr == (uintptr_t) -1) {
                symtab_print_search((char *) argv->buffer);
                printf("Duplicate symbol, be more specific.\n");
        } else {
                symbol = get_symtab_entry(symaddr);

                printf("Calling f(%#zx): %.*p: %s\n", arg1, sizeof(uintptr_t) * 2, symaddr, symbol);
#ifdef ia64
                fptr.f = symaddr;
                fptr.gp = ((unative_t *)cmd_call2)[1];
                f =  (unative_t (*)(unative_t,...)) &fptr;
#else
                f =  (unative_t (*)(unative_t,...)) symaddr;
#endif
                printf("Result: %#zx\n", f(arg1));
        }
        
        return 1;
}

/** Call function with two parameters */
int cmd_call2(cmd_arg_t *argv)
{
        uintptr_t symaddr;
        char *symbol;
        unative_t (*f)(unative_t,unative_t,...);
        unative_t arg1 = argv[1].intval;
        unative_t arg2 = argv[2].intval;
#ifdef ia64
        struct {
                unative_t f;
                unative_t gp;
        }fptr;
#endif

        symaddr = get_symbol_addr((char *) argv->buffer);
        if (!symaddr)
                printf("Symbol %s not found.\n", argv->buffer);
        else if (symaddr == (uintptr_t) -1) {
                symtab_print_search((char *) argv->buffer);
                printf("Duplicate symbol, be more specific.\n");
        } else {
                symbol = get_symtab_entry(symaddr);
                printf("Calling f(0x%zx,0x%zx): %.*p: %s\n", 
                       arg1, arg2, sizeof(uintptr_t) * 2, symaddr, symbol);
#ifdef ia64
                fptr.f = symaddr;
                fptr.gp = ((unative_t *)cmd_call2)[1];
                f =  (unative_t (*)(unative_t,unative_t,...)) &fptr;
#else
                f =  (unative_t (*)(unative_t,unative_t,...)) symaddr;
#endif
                printf("Result: %#zx\n", f(arg1, arg2));
        }
        
        return 1;
}

/** Call function with three parameters */
int cmd_call3(cmd_arg_t *argv)
{
        uintptr_t symaddr;
        char *symbol;
        unative_t (*f)(unative_t,unative_t,unative_t,...);
        unative_t arg1 = argv[1].intval;
        unative_t arg2 = argv[2].intval;
        unative_t arg3 = argv[3].intval;
#ifdef ia64
        struct {
                unative_t f;
                unative_t gp;
        }fptr;
#endif

        symaddr = get_symbol_addr((char *) argv->buffer);
        if (!symaddr)
                printf("Symbol %s not found.\n", argv->buffer);
        else if (symaddr == (uintptr_t) -1) {
                symtab_print_search((char *) argv->buffer);
                printf("Duplicate symbol, be more specific.\n");
        } else {
                symbol = get_symtab_entry(symaddr);
                printf("Calling f(0x%zx,0x%zx, 0x%zx): %.*p: %s\n", 
                       arg1, arg2, arg3, sizeof(uintptr_t) * 2, symaddr, symbol);
#ifdef ia64
                fptr.f = symaddr;
                fptr.gp = ((unative_t *)cmd_call2)[1];
                f =  (unative_t (*)(unative_t,unative_t,unative_t,...)) &fptr;
#else
                f =  (unative_t (*)(unative_t,unative_t,unative_t,...)) symaddr;
#endif
                printf("Result: %#zx\n", f(arg1, arg2, arg3));
        }
        
        return 1;
}


/** Print detailed description of 'describe' command. */
void desc_help(void)
{
        printf("Syntax: describe command_name\n");
}

/** Halt the kernel.
 *
 * @param argv Argument vector (ignored).
 *
 * @return 0 on failure, 1 on success (never returns).
 */
int cmd_halt(cmd_arg_t *argv)
{
        halt();
        return 1;
}

/** Command for printing TLB contents.
 *
 * @param argv Not used.
 *
 * @return Always returns 1.
 */
int cmd_tlb(cmd_arg_t *argv)
{
        tlb_print();
        return 1;
}

/** Write 4 byte value to address */
int cmd_set4(cmd_arg_t *argv)
{
        uint32_t *addr;
        uint32_t arg1 = argv[1].intval;
        bool pointer = false;

        if (((char *)argv->buffer)[0] == '*') {
                addr = (uint32_t *) get_symbol_addr((char *) argv->buffer + 1);
                pointer = true;
        } else if (((char *) argv->buffer)[0] >= '0' && 
                   ((char *)argv->buffer)[0] <= '9')
                addr = (uint32_t *)atoi((char *)argv->buffer);
        else
                addr = (uint32_t *)get_symbol_addr((char *) argv->buffer);

        if (!addr)
                printf("Symbol %s not found.\n", argv->buffer);
        else if (addr == (uint32_t *) -1) {
                symtab_print_search((char *) argv->buffer);
                printf("Duplicate symbol, be more specific.\n");
        } else {
                if (pointer)
                        addr = (uint32_t *)(*(unative_t *)addr);
                printf("Writing 0x%x -> %.*p\n", arg1, sizeof(uintptr_t) * 2, addr);
                *addr = arg1;
                
        }
        
        return 1;
}

/** Command for listings SLAB caches
 *
 * @param argv Ignores
 *
 * @return Always 1
 */
int cmd_slabs(cmd_arg_t * argv) {
        slab_print_list();
        return 1;
}


/** Command for listings Thread information
 *
 * @param argv Ignores
 *
 * @return Always 1
 */
int cmd_threads(cmd_arg_t * argv) {
        thread_print_list();
        return 1;
}

/** Command for listings Task information
 *
 * @param argv Ignores
 *
 * @return Always 1
 */
int cmd_tasks(cmd_arg_t * argv) {
        task_print_list();
        return 1;
}

/** Command for listings Thread information
 *
 * @param argv Ignores
 *
 * @return Always 1
 */
int cmd_sched(cmd_arg_t * argv) {
        sched_print_list();
        return 1;
}

/** Command for listing memory zones
 *
 * @param argv Ignored
 *
 * return Always 1
 */
int cmd_zones(cmd_arg_t * argv) {
        zone_print_list();
        return 1;
}

/** Command for memory zone details
 *
 * @param argv Integer argument from cmdline expected
 *
 * return Always 1
 */
int cmd_zone(cmd_arg_t * argv) {
        zone_print_one(argv[0].intval);
        return 1;
}

/** Command for printing task ipc details
 *
 * @param argv Integer argument from cmdline expected
 *
 * return Always 1
 */
int cmd_ipc_task(cmd_arg_t * argv) {
        ipc_print_task(argv[0].intval);
        return 1;
}


/** Command for listing processors.
 *
 * @param argv Ignored.
 *
 * return Always 1.
 */
int cmd_cpus(cmd_arg_t *argv)
{
        cpu_list();
        return 1;
}

/** Command for printing kernel version.
 *
 * @param argv Ignored.
 *
 * return Always 1.
 */
int cmd_version(cmd_arg_t *argv)
{
        version_print();
        return 1;
}

/** Command for returning console back to userspace.
 *
 * @param argv Ignored.
 *
 * return Always 1.
 */
int cmd_continue(cmd_arg_t *argv)
{
        printf("The kernel will now relinquish the console.\n");
        printf("Use userspace controls to redraw the screen.\n");
        arch_release_console();
        return 1;
}

#ifdef CONFIG_TEST
/** Command for printing kernel tests list.
 *
 * @param argv Ignored.
 *
 * return Always 1.
 */
int cmd_tests(cmd_arg_t *argv)
{
        test_t *test;
        
        for (test = tests; test->name != NULL; test++)
                printf("%s\t\t%s%s\n", test->name, test->desc, (test->safe ? "" : " (unsafe)"));
        
        printf("*\t\tRun all safe tests\n");
        return 1;
}

static bool run_test(const test_t *test)
{
        printf("%s\t\t%s\n", test->name, test->desc);
        
        /* Update and read thread accounting
           for benchmarking */
        ipl_t ipl = interrupts_disable();
        spinlock_lock(&TASK->lock);
        uint64_t t0 = task_get_accounting(TASK);
        spinlock_unlock(&TASK->lock);
        interrupts_restore(ipl);
        
        /* Execute the test */
        char * ret = test->entry(false);
        
        /* Update and read thread accounting */
        ipl = interrupts_disable();
        spinlock_lock(&TASK->lock);
        uint64_t dt = task_get_accounting(TASK) - t0;
        spinlock_unlock(&TASK->lock);
        interrupts_restore(ipl);
        
        uint64_t cycles;
        char suffix;
        order(dt, &cycles, &suffix);
                
        printf("Time: %llu%c cycles\n", cycles, suffix);
        
        if (ret == NULL) {
                printf("Test passed\n");
                return true;
        }

        printf("%s\n", ret);
        return false;
}

static bool run_bench(const test_t *test, const uint32_t cnt)
{
        uint32_t i;
        bool ret = true;
        uint64_t cycles;
        char suffix;
        
        if (cnt < 1)
                return true;
        
        uint64_t *data = (uint64_t *) malloc(sizeof(uint64_t) * cnt, 0);
        if (data == NULL) {
                printf("Error allocating memory for statistics\n");
                return false;
        }
        
        for (i = 0; i < cnt; i++) {
                printf("%s (%d/%d) ... ", test->name, i + 1, cnt);
                
                /* Update and read thread accounting
                   for benchmarking */
                ipl_t ipl = interrupts_disable();
                spinlock_lock(&TASK->lock);
                uint64_t t0 = task_get_accounting(TASK);
                spinlock_unlock(&TASK->lock);
                interrupts_restore(ipl);
                
                /* Execute the test */
                char * ret = test->entry(true);
                
                /* Update and read thread accounting */
                ipl = interrupts_disable();
                spinlock_lock(&TASK->lock);
                uint64_t dt = task_get_accounting(TASK) - t0;
                spinlock_unlock(&TASK->lock);
                interrupts_restore(ipl);
                
                if (ret != NULL) {
                        printf("%s\n", ret);
                        ret = false;
                        break;
                }
                
                data[i] = dt;
                order(dt, &cycles, &suffix);
                printf("OK (%llu%c cycles)\n", cycles, suffix);
        }
        
        if (ret) {
                printf("\n");
                
                uint64_t sum = 0;
                
                for (i = 0; i < cnt; i++) {
                        sum += data[i];
                }
                
                order(sum / (uint64_t) cnt, &cycles, &suffix);
                printf("Average\t\t%llu%c\n", cycles, suffix);
        }
        
        free(data);
        
        return ret;
}

/** Command for returning kernel tests
 *
 * @param argv Argument vector.
 *
 * return Always 1.
 */
int cmd_test(cmd_arg_t *argv)
{
        test_t *test;
        
        if (strcmp((char *) argv->buffer, "*") == 0) {
                for (test = tests; test->name != NULL; test++) {
                        if (test->safe) {
                                printf("\n");
                                if (!run_test(test))
                                        break;
                        }
                }
        } else {
                bool fnd = false;
                
                for (test = tests; test->name != NULL; test++) {
                        if (strcmp(test->name, (char *) argv->buffer) == 0) {
                                fnd = true;
                                run_test(test);
                                break;
                        }
                }
                
                if (!fnd)
                        printf("Unknown test\n");
        }
        
        return 1;
}

/** Command for returning kernel tests as benchmarks
 *
 * @param argv Argument vector.
 *
 * return Always 1.
 */
int cmd_bench(cmd_arg_t *argv)
{
        test_t *test;
        uint32_t cnt = argv[1].intval;
        
        bool fnd = false;
        
        for (test = tests; test->name != NULL; test++) {
                if (strcmp(test->name, (char *) argv->buffer) == 0) {
                        fnd = true;
                        
                        if (test->safe)
                                run_bench(test, cnt);
                        else
                                printf("Unsafe test\n");
                        
                        break;
                }
        }
                
        if (!fnd)
                printf("Unknown test\n");

        return 1;
}

#endif

/** @}
 */