Archipelago » qemu

/*

 *  TAP-Win32 -- A kernel driver to provide virtual tap device functionality

 *               on Windows.  Originally derived from the CIPE-Win32

 *               project by Damion K. Wilson, with extensive modifications by

 *               James Yonan.

 *

 *  All source code which derives from the CIPE-Win32 project is

 *  Copyright (C) Damion K. Wilson, 2003, and is released under the

 *  GPL version 2 (see below).

 *

 *  All other source code is Copyright (C) James Yonan, 2003-2004,

 *  and is released under the GPL version 2 (see below).

 *

 *  This program 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 of the License, or

 *  (at your option) any later version.

 *

 *  This program 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 this program (see the file COPYING included with this

 *  distribution); if not, see <http://www.gnu.org/licenses/>.

 */

#include "net/tap.h"

#include "qemu-common.h"

#include "net.h"

#include "sysemu.h"

#include <stdio.h>

#include <windows.h>

#include <winioctl.h>

//=============

// TAP IOCTLs

//=============

#define TAP_CONTROL_CODE(request,method) \

  CTL_CODE (FILE_DEVICE_UNKNOWN, request, method, FILE_ANY_ACCESS)

#define TAP_IOCTL_GET_MAC               TAP_CONTROL_CODE (1, METHOD_BUFFERED)

#define TAP_IOCTL_GET_VERSION           TAP_CONTROL_CODE (2, METHOD_BUFFERED)

#define TAP_IOCTL_GET_MTU               TAP_CONTROL_CODE (3, METHOD_BUFFERED)

#define TAP_IOCTL_GET_INFO              TAP_CONTROL_CODE (4, METHOD_BUFFERED)

#define TAP_IOCTL_CONFIG_POINT_TO_POINT TAP_CONTROL_CODE (5, METHOD_BUFFERED)

#define TAP_IOCTL_SET_MEDIA_STATUS      TAP_CONTROL_CODE (6, METHOD_BUFFERED)

#define TAP_IOCTL_CONFIG_DHCP_MASQ      TAP_CONTROL_CODE (7, METHOD_BUFFERED)

#define TAP_IOCTL_GET_LOG_LINE          TAP_CONTROL_CODE (8, METHOD_BUFFERED)

#define TAP_IOCTL_CONFIG_DHCP_SET_OPT   TAP_CONTROL_CODE (9, METHOD_BUFFERED)

//=================

// Registry keys

//=================

#define ADAPTER_KEY "SYSTEM\\CurrentControlSet\\Control\\Class\\{4D36E972-E325-11CE-BFC1-08002BE10318}"

#define NETWORK_CONNECTIONS_KEY "SYSTEM\\CurrentControlSet\\Control\\Network\\{4D36E972-E325-11CE-BFC1-08002BE10318}"

//======================

// Filesystem prefixes

//======================

#define USERMODEDEVICEDIR "\\\\.\\Global\\"

#define TAPSUFFIX         ".tap"

//======================

// Compile time configuration

//======================

//#define DEBUG_TAP_WIN32

#define TUN_ASYNCHRONOUS_WRITES 1

#define TUN_BUFFER_SIZE 1560

#define TUN_MAX_BUFFER_COUNT 32

/*

 * The data member "buffer" must be the first element in the tun_buffer

 * structure. See the function, tap_win32_free_buffer.

 */

typedef struct tun_buffer_s {

    unsigned char buffer [TUN_BUFFER_SIZE];

    unsigned long read_size;

    struct tun_buffer_s* next;

} tun_buffer_t;

typedef struct tap_win32_overlapped {

    HANDLE handle;

    HANDLE read_event;

    HANDLE write_event;

    HANDLE output_queue_semaphore;

    HANDLE free_list_semaphore;

    HANDLE tap_semaphore;

    CRITICAL_SECTION output_queue_cs;

    CRITICAL_SECTION free_list_cs;

    OVERLAPPED read_overlapped;

    OVERLAPPED write_overlapped;

    tun_buffer_t buffers[TUN_MAX_BUFFER_COUNT];

    tun_buffer_t* free_list;

    tun_buffer_t* output_queue_front;

    tun_buffer_t* output_queue_back;

} tap_win32_overlapped_t;

static tap_win32_overlapped_t tap_overlapped;

static tun_buffer_t* get_buffer_from_free_list(tap_win32_overlapped_t* const overlapped)

{

    tun_buffer_t* buffer = NULL;

    WaitForSingleObject(overlapped->free_list_semaphore, INFINITE);

    EnterCriticalSection(&overlapped->free_list_cs);

    buffer = overlapped->free_list;

//    assert(buffer != NULL);

    overlapped->free_list = buffer->next;

    LeaveCriticalSection(&overlapped->free_list_cs);

    buffer->next = NULL;

    return buffer;

}

static void put_buffer_on_free_list(tap_win32_overlapped_t* const overlapped, tun_buffer_t* const buffer)

{

    EnterCriticalSection(&overlapped->free_list_cs);

    buffer->next = overlapped->free_list;

    overlapped->free_list = buffer;

    LeaveCriticalSection(&overlapped->free_list_cs);

    ReleaseSemaphore(overlapped->free_list_semaphore, 1, NULL);

}

static tun_buffer_t* get_buffer_from_output_queue(tap_win32_overlapped_t* const overlapped, const int block)

{

    tun_buffer_t* buffer = NULL;

    DWORD result, timeout = block ? INFINITE : 0L;

    // Non-blocking call

    result = WaitForSingleObject(overlapped->output_queue_semaphore, timeout);

    switch (result)

    {

        // The semaphore object was signaled.

        case WAIT_OBJECT_0:

            EnterCriticalSection(&overlapped->output_queue_cs);

            buffer = overlapped->output_queue_front;

            overlapped->output_queue_front = buffer->next;

            if(overlapped->output_queue_front == NULL) {

                overlapped->output_queue_back = NULL;

            }

            LeaveCriticalSection(&overlapped->output_queue_cs);

            break;

        // Semaphore was nonsignaled, so a time-out occurred.

        case WAIT_TIMEOUT:

            // Cannot open another window.

            break;

    }

    return buffer;

}

static tun_buffer_t* get_buffer_from_output_queue_immediate (tap_win32_overlapped_t* const overlapped)

{

    return get_buffer_from_output_queue(overlapped, 0);

}

static void put_buffer_on_output_queue(tap_win32_overlapped_t* const overlapped, tun_buffer_t* const buffer)

{

    EnterCriticalSection(&overlapped->output_queue_cs);

    if(overlapped->output_queue_front == NULL && overlapped->output_queue_back == NULL) {

        overlapped->output_queue_front = overlapped->output_queue_back = buffer;

    } else {

        buffer->next = NULL;

        overlapped->output_queue_back->next = buffer;

        overlapped->output_queue_back = buffer;

    }

    LeaveCriticalSection(&overlapped->output_queue_cs);

    ReleaseSemaphore(overlapped->output_queue_semaphore, 1, NULL);

}

static int is_tap_win32_dev(const char *guid)

{

    HKEY netcard_key;

    LONG status;

    DWORD len;

    int i = 0;

    status = RegOpenKeyEx(

        HKEY_LOCAL_MACHINE,

        ADAPTER_KEY,

        0,

        KEY_READ,

        &netcard_key);

    if (status != ERROR_SUCCESS) {

        return FALSE;

    }

    for (;;) {

        char enum_name[256];

        char unit_string[256];

        HKEY unit_key;

        char component_id_string[] = "ComponentId";

        char component_id[256];

        char net_cfg_instance_id_string[] = "NetCfgInstanceId";

        char net_cfg_instance_id[256];

        DWORD data_type;

        len = sizeof (enum_name);

        status = RegEnumKeyEx(

            netcard_key,

            i,

            enum_name,

            &len,

            NULL,

            NULL,

            NULL,

            NULL);

        if (status == ERROR_NO_MORE_ITEMS)

            break;

        else if (status != ERROR_SUCCESS) {

            return FALSE;

        }

        snprintf (unit_string, sizeof(unit_string), "%s\\%s",

                  ADAPTER_KEY, enum_name);

        status = RegOpenKeyEx(

            HKEY_LOCAL_MACHINE,

            unit_string,

            0,

            KEY_READ,

            &unit_key);

        if (status != ERROR_SUCCESS) {

            return FALSE;

        } else {

            len = sizeof (component_id);

            status = RegQueryValueEx(

                unit_key,

                component_id_string,

                NULL,

                &data_type,

                (LPBYTE)component_id,

                &len);

            if (!(status != ERROR_SUCCESS || data_type != REG_SZ)) {

                len = sizeof (net_cfg_instance_id);

                status = RegQueryValueEx(

                    unit_key,

                    net_cfg_instance_id_string,

                    NULL,

                    &data_type,

                    (LPBYTE)net_cfg_instance_id,

                    &len);

                if (status == ERROR_SUCCESS && data_type == REG_SZ) {

                    if (/* !strcmp (component_id, TAP_COMPONENT_ID) &&*/

                        !strcmp (net_cfg_instance_id, guid)) {

                        RegCloseKey (unit_key);

                        RegCloseKey (netcard_key);

                        return TRUE;

                    }

                }

            }

            RegCloseKey (unit_key);

        }

        ++i;

    }

    RegCloseKey (netcard_key);

    return FALSE;

}

static int get_device_guid(

    char *name,

    int name_size,

    char *actual_name,

    int actual_name_size)

{

    LONG status;

    HKEY control_net_key;

    DWORD len;

    int i = 0;

    int stop = 0;

    status = RegOpenKeyEx(

        HKEY_LOCAL_MACHINE,

        NETWORK_CONNECTIONS_KEY,

        0,

        KEY_READ,

        &control_net_key);

    if (status != ERROR_SUCCESS) {

        return -1;

    }

    while (!stop)

    {

        char enum_name[256];

        char connection_string[256];

        HKEY connection_key;

        char name_data[256];

        DWORD name_type;

        const char name_string[] = "Name";

        len = sizeof (enum_name);

        status = RegEnumKeyEx(

            control_net_key,

            i,

            enum_name,

            &len,

            NULL,

            NULL,

            NULL,

            NULL);

        if (status == ERROR_NO_MORE_ITEMS)

            break;

        else if (status != ERROR_SUCCESS) {

            return -1;

        }

        snprintf(connection_string,

             sizeof(connection_string),

             "%s\\%s\\Connection",

             NETWORK_CONNECTIONS_KEY, enum_name);

        status = RegOpenKeyEx(

            HKEY_LOCAL_MACHINE,

            connection_string,

            0,

            KEY_READ,

            &connection_key);

        if (status == ERROR_SUCCESS) {

            len = sizeof (name_data);

            status = RegQueryValueEx(

                connection_key,

                name_string,

                NULL,

                &name_type,

                (LPBYTE)name_data,

                &len);

            if (status != ERROR_SUCCESS || name_type != REG_SZ) {

                    return -1;

            }

            else {

                if (is_tap_win32_dev(enum_name)) {

                    snprintf(name, name_size, "%s", enum_name);

                    if (actual_name) {

                        if (strcmp(actual_name, "") != 0) {

                            if (strcmp(name_data, actual_name) != 0) {

                                RegCloseKey (connection_key);

                                ++i;

                                continue;

                            }

                        }

                        else {

                            snprintf(actual_name, actual_name_size, "%s", name_data);

                        }

                    }

                    stop = 1;

                }

            }

            RegCloseKey (connection_key);

        }

        ++i;

    }

    RegCloseKey (control_net_key);

    if (stop == 0)

        return -1;

    return 0;

}

static int tap_win32_set_status(HANDLE handle, int status)

{

    unsigned long len = 0;

    return DeviceIoControl(handle, TAP_IOCTL_SET_MEDIA_STATUS,

                &status, sizeof (status),

                &status, sizeof (status), &len, NULL);

}

static void tap_win32_overlapped_init(tap_win32_overlapped_t* const overlapped, const HANDLE handle)

{

    overlapped->handle = handle;

    overlapped->read_event = CreateEvent(NULL, FALSE, FALSE, NULL);

    overlapped->write_event = CreateEvent(NULL, FALSE, FALSE, NULL);

    overlapped->read_overlapped.Offset = 0;

    overlapped->read_overlapped.OffsetHigh = 0;

    overlapped->read_overlapped.hEvent = overlapped->read_event;

    overlapped->write_overlapped.Offset = 0;

    overlapped->write_overlapped.OffsetHigh = 0;

    overlapped->write_overlapped.hEvent = overlapped->write_event;

    InitializeCriticalSection(&overlapped->output_queue_cs);

    InitializeCriticalSection(&overlapped->free_list_cs);

    overlapped->output_queue_semaphore = CreateSemaphore(

        NULL,   // default security attributes

        0,   // initial count

        TUN_MAX_BUFFER_COUNT,   // maximum count

        NULL);  // unnamed semaphore

    if(!overlapped->output_queue_semaphore)  {

        fprintf(stderr, "error creating output queue semaphore!\n");

    }

    overlapped->free_list_semaphore = CreateSemaphore(

        NULL,   // default security attributes

        TUN_MAX_BUFFER_COUNT,   // initial count

        TUN_MAX_BUFFER_COUNT,   // maximum count

        NULL);  // unnamed semaphore

    if(!overlapped->free_list_semaphore)  {

        fprintf(stderr, "error creating free list semaphore!\n");

    }

    overlapped->free_list = overlapped->output_queue_front = overlapped->output_queue_back = NULL;

    {

        unsigned index;

        for(index = 0; index < TUN_MAX_BUFFER_COUNT; index++) {

            tun_buffer_t* element = &overlapped->buffers[index];

            element->next = overlapped->free_list;

            overlapped->free_list = element;

        }

    }

    /* To count buffers, initially no-signal. */

    overlapped->tap_semaphore = CreateSemaphore(NULL, 0, TUN_MAX_BUFFER_COUNT, NULL);

    if(!overlapped->tap_semaphore)

        fprintf(stderr, "error creating tap_semaphore.\n");

}

static int tap_win32_write(tap_win32_overlapped_t *overlapped,

                           const void *buffer, unsigned long size)

{

    unsigned long write_size;

    BOOL result;

    DWORD error;

    result = GetOverlappedResult( overlapped->handle, &overlapped->write_overlapped,

                                  &write_size, FALSE);

    if (!result && GetLastError() == ERROR_IO_INCOMPLETE)

        WaitForSingleObject(overlapped->write_event, INFINITE);

    result = WriteFile(overlapped->handle, buffer, size,

                       &write_size, &overlapped->write_overlapped);

    if (!result) {

        switch (error = GetLastError())

        {

        case ERROR_IO_PENDING:

#ifndef TUN_ASYNCHRONOUS_WRITES

            WaitForSingleObject(overlapped->write_event, INFINITE);

#endif

            break;

        default:

            return -1;

        }

    }

    return 0;

}

static DWORD WINAPI tap_win32_thread_entry(LPVOID param)

{

    tap_win32_overlapped_t *overlapped = (tap_win32_overlapped_t*)param;

    unsigned long read_size;

    BOOL result;

    DWORD dwError;

    tun_buffer_t* buffer = get_buffer_from_free_list(overlapped);

    for (;;) {

        result = ReadFile(overlapped->handle,

                          buffer->buffer,

                          sizeof(buffer->buffer),

                          &read_size,

                          &overlapped->read_overlapped);

        if (!result) {

            dwError = GetLastError();

            if (dwError == ERROR_IO_PENDING) {

                WaitForSingleObject(overlapped->read_event, INFINITE);

                result = GetOverlappedResult( overlapped->handle, &overlapped->read_overlapped,

                                              &read_size, FALSE);

                if (!result) {

#ifdef DEBUG_TAP_WIN32

                    LPVOID lpBuffer;

                    dwError = GetLastError();

                    FormatMessage( FORMAT_MESSAGE_ALLOCATE_BUFFER | FORMAT_MESSAGE_FROM_SYSTEM,

                                   NULL, dwError, MAKELANGID(LANG_NEUTRAL, SUBLANG_DEFAULT),

                                   (LPTSTR) & lpBuffer, 0, NULL );

                    fprintf(stderr, "Tap-Win32: Error GetOverlappedResult %d - %s\n", dwError, lpBuffer);

                    LocalFree( lpBuffer );

#endif

                }

            } else {

#ifdef DEBUG_TAP_WIN32

                LPVOID lpBuffer;

                FormatMessage( FORMAT_MESSAGE_ALLOCATE_BUFFER | FORMAT_MESSAGE_FROM_SYSTEM,

                               NULL, dwError, MAKELANGID(LANG_NEUTRAL, SUBLANG_DEFAULT),

                               (LPTSTR) & lpBuffer, 0, NULL );

                fprintf(stderr, "Tap-Win32: Error ReadFile %d - %s\n", dwError, lpBuffer);

                LocalFree( lpBuffer );

#endif

            }

        }

        if(read_size > 0) {

            buffer->read_size = read_size;

            put_buffer_on_output_queue(overlapped, buffer);

            ReleaseSemaphore(overlapped->tap_semaphore, 1, NULL);

            buffer = get_buffer_from_free_list(overlapped);

        }

    }

    return 0;

}

static int tap_win32_read(tap_win32_overlapped_t *overlapped,

                          uint8_t **pbuf, int max_size)

{

    int size = 0;

    tun_buffer_t* buffer = get_buffer_from_output_queue_immediate(overlapped);

    if(buffer != NULL) {

        *pbuf = buffer->buffer;

        size = (int)buffer->read_size;

        if(size > max_size) {

            size = max_size;

        }

    }

    return size;

}

static void tap_win32_free_buffer(tap_win32_overlapped_t *overlapped,

                                  uint8_t *pbuf)

{

    tun_buffer_t* buffer = (tun_buffer_t*)pbuf;

    put_buffer_on_free_list(overlapped, buffer);

}

static int tap_win32_open(tap_win32_overlapped_t **phandle,

                          const char *prefered_name)

{

    char device_path[256];

    char device_guid[0x100];

    int rc;

    HANDLE handle;

    BOOL bret;

    char name_buffer[0x100] = {0, };

    struct {

        unsigned long major;

        unsigned long minor;

        unsigned long debug;

    } version;

    DWORD version_len;

    DWORD idThread;

    HANDLE hThread;

    if (prefered_name != NULL)

        snprintf(name_buffer, sizeof(name_buffer), "%s", prefered_name);

    rc = get_device_guid(device_guid, sizeof(device_guid), name_buffer, sizeof(name_buffer));

    if (rc)

        return -1;

    snprintf (device_path, sizeof(device_path), "%s%s%s",

              USERMODEDEVICEDIR,

              device_guid,

              TAPSUFFIX);

    handle = CreateFile (

        device_path,

        GENERIC_READ | GENERIC_WRITE,

        0,

        0,

        OPEN_EXISTING,

        FILE_ATTRIBUTE_SYSTEM | FILE_FLAG_OVERLAPPED,

        0 );

    if (handle == INVALID_HANDLE_VALUE) {

        return -1;

    }

    bret = DeviceIoControl(handle, TAP_IOCTL_GET_VERSION,

                           &version, sizeof (version),

                           &version, sizeof (version), &version_len, NULL);

    if (bret == FALSE) {

        CloseHandle(handle);

        return -1;

    }

    if (!tap_win32_set_status(handle, TRUE)) {

        return -1;

    }

    tap_win32_overlapped_init(&tap_overlapped, handle);

    *phandle = &tap_overlapped;

    hThread = CreateThread(NULL, 0, tap_win32_thread_entry,

                           (LPVOID)&tap_overlapped, 0, &idThread);

    return 0;

}

/********************************************/

 typedef struct TAPState {

     VLANClientState nc;

     tap_win32_overlapped_t *handle;

 } TAPState;

static void tap_cleanup(VLANClientState *nc)

{

    TAPState *s = DO_UPCAST(TAPState, nc, nc);

    qemu_del_wait_object(s->handle->tap_semaphore, NULL, NULL);

    /* FIXME: need to kill thread and close file handle:

       tap_win32_close(s);

    */

}

static ssize_t tap_receive(VLANClientState *nc, const uint8_t *buf, size_t size)

{

    TAPState *s = DO_UPCAST(TAPState, nc, nc);

    return tap_win32_write(s->handle, buf, size);

}

static void tap_win32_send(void *opaque)

{

    TAPState *s = opaque;

    uint8_t *buf;

    int max_size = 4096;

    int size;

    size = tap_win32_read(s->handle, &buf, max_size);

    if (size > 0) {

        qemu_send_packet(&s->nc, buf, size);

        tap_win32_free_buffer(s->handle, buf);

    }

}

static NetClientInfo net_tap_win32_info = {

    .type = NET_CLIENT_TYPE_TAP,

    .size = sizeof(TAPState),

    .receive = tap_receive,

    .cleanup = tap_cleanup,

};

static int tap_win32_init(VLANState *vlan, const char *model,

                          const char *name, const char *ifname)

{

    VLANClientState *nc;

    TAPState *s;

    tap_win32_overlapped_t *handle;

    if (tap_win32_open(&handle, ifname) < 0) {

        printf("tap: Could not open '%s'\n", ifname);

        return -1;

    }

    nc = qemu_new_net_client(&net_tap_win32_info, vlan, NULL, model, name);

    s = DO_UPCAST(TAPState, nc, nc);

    snprintf(s->nc.info_str, sizeof(s->nc.info_str),

             "tap: ifname=%s", ifname);

    s->handle = handle;

    qemu_add_wait_object(s->handle->tap_semaphore, tap_win32_send, s);

    return 0;

}

int net_init_tap(QemuOpts *opts, Monitor *mon, const char *name, VLANState *vlan)

{

    const char *ifname;

    ifname = qemu_opt_get(opts, "ifname");

    if (!ifname) {

        qemu_error("tap: no interface name\n");

        return -1;

    }

    if (tap_win32_init(vlan, "tap", name, ifname) == -1) {

        return -1;

    }

    return 0;

}

int tap_has_ufo(VLANClientState *vc)

{

    return 0;

}

int tap_has_vnet_hdr(VLANClientState *vc)

{

    return 0;

}

void tap_using_vnet_hdr(VLANClientState *vc, int using_vnet_hdr)

{

}

void tap_set_offload(VLANClientState *vc, int csum, int tso4,

                     int tso6, int ecn, int ufo)

{

}