freebsd-dev/sys/dev/if_ndis/if_ndis_pci.c

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/*-
* Copyright (c) 2003
* Bill Paul <wpaul@windriver.com>. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. 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.
* 3. All advertising materials mentioning features or use of this software
* must display the following acknowledgement:
* This product includes software developed by Bill Paul.
* 4. Neither the name of the author nor the names of any co-contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY Bill Paul AND CONTRIBUTORS ``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 Bill Paul OR THE VOICES IN HIS HEAD
* 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.
*/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/kernel.h>
#include <sys/module.h>
#include <sys/socket.h>
#include <sys/queue.h>
#include <sys/sysctl.h>
#include <net/if.h>
#include <net/if_arp.h>
#include <net/if_media.h>
#include <machine/bus.h>
#include <machine/resource.h>
#include <sys/bus.h>
#include <sys/rman.h>
#include <net80211/ieee80211_var.h>
#include <dev/pci/pcireg.h>
#include <dev/pci/pcivar.h>
#include <compat/ndis/pe_var.h>
Throw the switch on the new driver generation/loading mechanism. From here on in, if_ndis.ko will be pre-built as a module, and can be built into a static kernel (though it's not part of GENERIC). Drivers are created using the new ndisgen(8) script, which uses ndiscvt(8) under the covers, along with a few other tools. The result is a driver module that can be kldloaded into the kernel. A driver with foo.inf and foo.sys files will be converted into foo_sys.ko (and foo_sys.o, for those who want/need to make static kernels). This module contains all of the necessary info from the .INF file and the driver binary image, converted into an ELF module. You can kldload this module (or add it to /boot/loader.conf) to have it loaded automatically. Any required firmware files can be bundled into the module as well (or converted/loaded separately). Also, add a workaround for a problem in NdisMSleep(). During system bootstrap (cold == 1), msleep() always returns 0 without actually sleeping. The Intel 2200BG driver uses NdisMSleep() to wait for the NIC's firmware to come to life, and fails to load if NdisMSleep() doesn't actually delay. As a workaround, if msleep() (and hence ndis_thsuspend()) returns 0, use a hard DELAY() to sleep instead). This is not really the right thing to do, but we can't really do much else. At the very least, this makes the Intel driver happy. There are probably other drivers that fail in this way during bootstrap. Unfortunately, the only workaround for those is to avoid pre-loading them and kldload them once the system is running instead.
2005-04-24 20:21:22 +00:00
#include <compat/ndis/cfg_var.h>
#include <compat/ndis/resource_var.h>
#include <compat/ndis/ntoskrnl_var.h>
#include <compat/ndis/ndis_var.h>
#include <dev/if_ndis/if_ndisvar.h>
MODULE_DEPEND(ndis, pci, 1, 1, 1);
static int ndis_probe_pci (device_t);
static int ndis_attach_pci (device_t);
static struct resource_list *ndis_get_resource_list
(device_t, device_t);
static int ndis_devcompare (interface_type,
struct ndis_pci_type *, device_t);
Next step on the road to IRPs: create and use an imitation of the Windows DRIVER_OBJECT and DEVICE_OBJECT mechanism so that we can simulate driver stacking. In Windows, each loaded driver image is attached to a DRIVER_OBJECT structure. Windows uses the registry to match up a given vendor/device ID combination with a corresponding DRIVER_OBJECT. When a driver image is first loaded, its DriverEntry() routine is invoked, which sets up the AddDevice() function pointer in the DRIVER_OBJECT and creates a dispatch table (based on IRP major codes). When a Windows bus driver detects a new device, it creates a Physical Device Object (PDO) for it. This is a DEVICE_OBJECT structure, with semantics analagous to that of a device_t in FreeBSD. The Windows PNP manager will invoke the driver's AddDevice() function and pass it pointers to the DRIVER_OBJECT and the PDO. The AddDevice() function then creates a new DRIVER_OBJECT structure of its own. This is known as the Functional Device Object (FDO) and corresponds roughly to a private softc instance. The driver uses IoAttachDeviceToDeviceStack() to add this device object to the driver stack for this PDO. Subsequent drivers (called filter drivers in Windows-speak) can be loaded which add themselves to the stack. When someone issues an IRP to a device, it travel along the stack passing through several possible filter drivers until it reaches the functional driver (which actually knows how to talk to the hardware) at which point it will be completed. This is how Windows achieves driver layering. Project Evil now simulates most of this. if_ndis now has a modevent handler which will use MOD_LOAD and MOD_UNLOAD events to drive the creation and destruction of DRIVER_OBJECTs. (The load event also does the relocation/dynalinking of the image.) We don't have a registry, so the DRIVER_OBJECTS are stored in a linked list for now. Eventually, the list entry will contain the vendor/device ID list extracted from the .INF file. When ndis_probe() is called and detectes a supported device, it will create a PDO for the device instance and attach it to the DRIVER_OBJECT just as in Windows. ndis_attach() will then call our NdisAddDevice() handler to create the FDO. The NDIS miniport block is now a device extension hung off the FDO, just as it is in Windows. The miniport characteristics table is now an extension hung off the DRIVER_OBJECT as well (the characteristics are the same for all devices handled by a given driver, so they don't need to be per-instance.) We also do an IoAttachDeviceToDeviceStack() to put the FDO on the stack for the PDO. There are a couple of fake bus drivers created for the PCI and pccard buses. Eventually, there will be one for USB, which will actually accept USB IRP.s Things should still work just as before, only now we do things in the proper order and maintain the correct framework to support passing IRPs between drivers. Various changes: - corrected the comments about IRQL handling in subr_hal.c to more accurately reflect reality - update ndiscvt to make the drv_data symbol in ndis_driver_data.h a global so that if_ndis_pci.o and/or if_ndis_pccard.o can see it. - Obtain the softc pointer from the miniport block by referencing the PDO rather than a private pointer of our own (nmb_ifp is no longer used) - implement IoAttachDeviceToDeviceStack(), IoDetachDevice(), IoGetAttachedDevice(), IoAllocateDriverObjectExtension(), IoGetDriverObjectExtension(), IoCreateDevice(), IoDeleteDevice(), IoAllocateIrp(), IoReuseIrp(), IoMakeAssociatedIrp(), IoFreeIrp(), IoInitializeIrp() - fix a few mistakes in the driver_object and device_object definitions - add a new module, kern_windrv.c, to handle the driver registration and relocation/dynalinkign duties (which don't really belong in kern_ndis.c). - made ndis_block and ndis_chars in the ndis_softc stucture pointers and modified all references to it - fixed NdisMRegisterMiniport() and NdisInitializeWrapper() so they work correctly with the new driver_object mechanism - changed ndis_attach() to call NdisAddDevice() instead of ndis_load_driver() (which is now deprecated) - used ExAllocatePoolWithTag()/ExFreePool() in lookaside list routines instead of kludged up alloc/free routines - added kern_windrv.c to sys/modules/ndis/Makefile and files.i386.
2005-02-08 17:23:25 +00:00
extern int ndisdrv_modevent (module_t, int, void *);
extern int ndis_attach (device_t);
extern int ndis_shutdown (device_t);
extern int ndis_detach (device_t);
extern int ndis_suspend (device_t);
extern int ndis_resume (device_t);
static device_method_t ndis_methods[] = {
/* Device interface */
DEVMETHOD(device_probe, ndis_probe_pci),
DEVMETHOD(device_attach, ndis_attach_pci),
DEVMETHOD(device_detach, ndis_detach),
DEVMETHOD(device_shutdown, ndis_shutdown),
DEVMETHOD(device_suspend, ndis_suspend),
DEVMETHOD(device_resume, ndis_resume),
/* Bus interface */
DEVMETHOD(bus_get_resource_list, ndis_get_resource_list),
{ 0, 0 }
};
static driver_t ndis_driver = {
"ndis",
ndis_methods,
sizeof(struct ndis_softc)
};
static devclass_t ndis_devclass;
Next step on the road to IRPs: create and use an imitation of the Windows DRIVER_OBJECT and DEVICE_OBJECT mechanism so that we can simulate driver stacking. In Windows, each loaded driver image is attached to a DRIVER_OBJECT structure. Windows uses the registry to match up a given vendor/device ID combination with a corresponding DRIVER_OBJECT. When a driver image is first loaded, its DriverEntry() routine is invoked, which sets up the AddDevice() function pointer in the DRIVER_OBJECT and creates a dispatch table (based on IRP major codes). When a Windows bus driver detects a new device, it creates a Physical Device Object (PDO) for it. This is a DEVICE_OBJECT structure, with semantics analagous to that of a device_t in FreeBSD. The Windows PNP manager will invoke the driver's AddDevice() function and pass it pointers to the DRIVER_OBJECT and the PDO. The AddDevice() function then creates a new DRIVER_OBJECT structure of its own. This is known as the Functional Device Object (FDO) and corresponds roughly to a private softc instance. The driver uses IoAttachDeviceToDeviceStack() to add this device object to the driver stack for this PDO. Subsequent drivers (called filter drivers in Windows-speak) can be loaded which add themselves to the stack. When someone issues an IRP to a device, it travel along the stack passing through several possible filter drivers until it reaches the functional driver (which actually knows how to talk to the hardware) at which point it will be completed. This is how Windows achieves driver layering. Project Evil now simulates most of this. if_ndis now has a modevent handler which will use MOD_LOAD and MOD_UNLOAD events to drive the creation and destruction of DRIVER_OBJECTs. (The load event also does the relocation/dynalinking of the image.) We don't have a registry, so the DRIVER_OBJECTS are stored in a linked list for now. Eventually, the list entry will contain the vendor/device ID list extracted from the .INF file. When ndis_probe() is called and detectes a supported device, it will create a PDO for the device instance and attach it to the DRIVER_OBJECT just as in Windows. ndis_attach() will then call our NdisAddDevice() handler to create the FDO. The NDIS miniport block is now a device extension hung off the FDO, just as it is in Windows. The miniport characteristics table is now an extension hung off the DRIVER_OBJECT as well (the characteristics are the same for all devices handled by a given driver, so they don't need to be per-instance.) We also do an IoAttachDeviceToDeviceStack() to put the FDO on the stack for the PDO. There are a couple of fake bus drivers created for the PCI and pccard buses. Eventually, there will be one for USB, which will actually accept USB IRP.s Things should still work just as before, only now we do things in the proper order and maintain the correct framework to support passing IRPs between drivers. Various changes: - corrected the comments about IRQL handling in subr_hal.c to more accurately reflect reality - update ndiscvt to make the drv_data symbol in ndis_driver_data.h a global so that if_ndis_pci.o and/or if_ndis_pccard.o can see it. - Obtain the softc pointer from the miniport block by referencing the PDO rather than a private pointer of our own (nmb_ifp is no longer used) - implement IoAttachDeviceToDeviceStack(), IoDetachDevice(), IoGetAttachedDevice(), IoAllocateDriverObjectExtension(), IoGetDriverObjectExtension(), IoCreateDevice(), IoDeleteDevice(), IoAllocateIrp(), IoReuseIrp(), IoMakeAssociatedIrp(), IoFreeIrp(), IoInitializeIrp() - fix a few mistakes in the driver_object and device_object definitions - add a new module, kern_windrv.c, to handle the driver registration and relocation/dynalinkign duties (which don't really belong in kern_ndis.c). - made ndis_block and ndis_chars in the ndis_softc stucture pointers and modified all references to it - fixed NdisMRegisterMiniport() and NdisInitializeWrapper() so they work correctly with the new driver_object mechanism - changed ndis_attach() to call NdisAddDevice() instead of ndis_load_driver() (which is now deprecated) - used ExAllocatePoolWithTag()/ExFreePool() in lookaside list routines instead of kludged up alloc/free routines - added kern_windrv.c to sys/modules/ndis/Makefile and files.i386.
2005-02-08 17:23:25 +00:00
DRIVER_MODULE(ndis, pci, ndis_driver, ndis_devclass, ndisdrv_modevent, 0);
DRIVER_MODULE(ndis, cardbus, ndis_driver, ndis_devclass, ndisdrv_modevent, 0);
Throw the switch on the new driver generation/loading mechanism. From here on in, if_ndis.ko will be pre-built as a module, and can be built into a static kernel (though it's not part of GENERIC). Drivers are created using the new ndisgen(8) script, which uses ndiscvt(8) under the covers, along with a few other tools. The result is a driver module that can be kldloaded into the kernel. A driver with foo.inf and foo.sys files will be converted into foo_sys.ko (and foo_sys.o, for those who want/need to make static kernels). This module contains all of the necessary info from the .INF file and the driver binary image, converted into an ELF module. You can kldload this module (or add it to /boot/loader.conf) to have it loaded automatically. Any required firmware files can be bundled into the module as well (or converted/loaded separately). Also, add a workaround for a problem in NdisMSleep(). During system bootstrap (cold == 1), msleep() always returns 0 without actually sleeping. The Intel 2200BG driver uses NdisMSleep() to wait for the NIC's firmware to come to life, and fails to load if NdisMSleep() doesn't actually delay. As a workaround, if msleep() (and hence ndis_thsuspend()) returns 0, use a hard DELAY() to sleep instead). This is not really the right thing to do, but we can't really do much else. At the very least, this makes the Intel driver happy. There are probably other drivers that fail in this way during bootstrap. Unfortunately, the only workaround for those is to avoid pre-loading them and kldload them once the system is running instead.
2005-04-24 20:21:22 +00:00
static int
ndis_devcompare(bustype, t, dev)
interface_type bustype;
Throw the switch on the new driver generation/loading mechanism. From here on in, if_ndis.ko will be pre-built as a module, and can be built into a static kernel (though it's not part of GENERIC). Drivers are created using the new ndisgen(8) script, which uses ndiscvt(8) under the covers, along with a few other tools. The result is a driver module that can be kldloaded into the kernel. A driver with foo.inf and foo.sys files will be converted into foo_sys.ko (and foo_sys.o, for those who want/need to make static kernels). This module contains all of the necessary info from the .INF file and the driver binary image, converted into an ELF module. You can kldload this module (or add it to /boot/loader.conf) to have it loaded automatically. Any required firmware files can be bundled into the module as well (or converted/loaded separately). Also, add a workaround for a problem in NdisMSleep(). During system bootstrap (cold == 1), msleep() always returns 0 without actually sleeping. The Intel 2200BG driver uses NdisMSleep() to wait for the NIC's firmware to come to life, and fails to load if NdisMSleep() doesn't actually delay. As a workaround, if msleep() (and hence ndis_thsuspend()) returns 0, use a hard DELAY() to sleep instead). This is not really the right thing to do, but we can't really do much else. At the very least, this makes the Intel driver happy. There are probably other drivers that fail in this way during bootstrap. Unfortunately, the only workaround for those is to avoid pre-loading them and kldload them once the system is running instead.
2005-04-24 20:21:22 +00:00
struct ndis_pci_type *t;
device_t dev;
{
if (bustype != PCIBus)
return(FALSE);
Throw the switch on the new driver generation/loading mechanism. From here on in, if_ndis.ko will be pre-built as a module, and can be built into a static kernel (though it's not part of GENERIC). Drivers are created using the new ndisgen(8) script, which uses ndiscvt(8) under the covers, along with a few other tools. The result is a driver module that can be kldloaded into the kernel. A driver with foo.inf and foo.sys files will be converted into foo_sys.ko (and foo_sys.o, for those who want/need to make static kernels). This module contains all of the necessary info from the .INF file and the driver binary image, converted into an ELF module. You can kldload this module (or add it to /boot/loader.conf) to have it loaded automatically. Any required firmware files can be bundled into the module as well (or converted/loaded separately). Also, add a workaround for a problem in NdisMSleep(). During system bootstrap (cold == 1), msleep() always returns 0 without actually sleeping. The Intel 2200BG driver uses NdisMSleep() to wait for the NIC's firmware to come to life, and fails to load if NdisMSleep() doesn't actually delay. As a workaround, if msleep() (and hence ndis_thsuspend()) returns 0, use a hard DELAY() to sleep instead). This is not really the right thing to do, but we can't really do much else. At the very least, this makes the Intel driver happy. There are probably other drivers that fail in this way during bootstrap. Unfortunately, the only workaround for those is to avoid pre-loading them and kldload them once the system is running instead.
2005-04-24 20:21:22 +00:00
while(t->ndis_name != NULL) {
if ((pci_get_vendor(dev) == t->ndis_vid) &&
(pci_get_device(dev) == t->ndis_did) &&
((pci_read_config(dev, PCIR_SUBVEND_0, 4) ==
t->ndis_subsys) || t->ndis_subsys == 0)) {
device_set_desc(dev, t->ndis_name);
return(TRUE);
}
t++;
}
return(FALSE);
}
/*
* Probe for an NDIS device. Check the PCI vendor and device
* IDs against our list and return a device name if we find a match.
*/
static int
ndis_probe_pci(dev)
device_t dev;
{
Next step on the road to IRPs: create and use an imitation of the Windows DRIVER_OBJECT and DEVICE_OBJECT mechanism so that we can simulate driver stacking. In Windows, each loaded driver image is attached to a DRIVER_OBJECT structure. Windows uses the registry to match up a given vendor/device ID combination with a corresponding DRIVER_OBJECT. When a driver image is first loaded, its DriverEntry() routine is invoked, which sets up the AddDevice() function pointer in the DRIVER_OBJECT and creates a dispatch table (based on IRP major codes). When a Windows bus driver detects a new device, it creates a Physical Device Object (PDO) for it. This is a DEVICE_OBJECT structure, with semantics analagous to that of a device_t in FreeBSD. The Windows PNP manager will invoke the driver's AddDevice() function and pass it pointers to the DRIVER_OBJECT and the PDO. The AddDevice() function then creates a new DRIVER_OBJECT structure of its own. This is known as the Functional Device Object (FDO) and corresponds roughly to a private softc instance. The driver uses IoAttachDeviceToDeviceStack() to add this device object to the driver stack for this PDO. Subsequent drivers (called filter drivers in Windows-speak) can be loaded which add themselves to the stack. When someone issues an IRP to a device, it travel along the stack passing through several possible filter drivers until it reaches the functional driver (which actually knows how to talk to the hardware) at which point it will be completed. This is how Windows achieves driver layering. Project Evil now simulates most of this. if_ndis now has a modevent handler which will use MOD_LOAD and MOD_UNLOAD events to drive the creation and destruction of DRIVER_OBJECTs. (The load event also does the relocation/dynalinking of the image.) We don't have a registry, so the DRIVER_OBJECTS are stored in a linked list for now. Eventually, the list entry will contain the vendor/device ID list extracted from the .INF file. When ndis_probe() is called and detectes a supported device, it will create a PDO for the device instance and attach it to the DRIVER_OBJECT just as in Windows. ndis_attach() will then call our NdisAddDevice() handler to create the FDO. The NDIS miniport block is now a device extension hung off the FDO, just as it is in Windows. The miniport characteristics table is now an extension hung off the DRIVER_OBJECT as well (the characteristics are the same for all devices handled by a given driver, so they don't need to be per-instance.) We also do an IoAttachDeviceToDeviceStack() to put the FDO on the stack for the PDO. There are a couple of fake bus drivers created for the PCI and pccard buses. Eventually, there will be one for USB, which will actually accept USB IRP.s Things should still work just as before, only now we do things in the proper order and maintain the correct framework to support passing IRPs between drivers. Various changes: - corrected the comments about IRQL handling in subr_hal.c to more accurately reflect reality - update ndiscvt to make the drv_data symbol in ndis_driver_data.h a global so that if_ndis_pci.o and/or if_ndis_pccard.o can see it. - Obtain the softc pointer from the miniport block by referencing the PDO rather than a private pointer of our own (nmb_ifp is no longer used) - implement IoAttachDeviceToDeviceStack(), IoDetachDevice(), IoGetAttachedDevice(), IoAllocateDriverObjectExtension(), IoGetDriverObjectExtension(), IoCreateDevice(), IoDeleteDevice(), IoAllocateIrp(), IoReuseIrp(), IoMakeAssociatedIrp(), IoFreeIrp(), IoInitializeIrp() - fix a few mistakes in the driver_object and device_object definitions - add a new module, kern_windrv.c, to handle the driver registration and relocation/dynalinkign duties (which don't really belong in kern_ndis.c). - made ndis_block and ndis_chars in the ndis_softc stucture pointers and modified all references to it - fixed NdisMRegisterMiniport() and NdisInitializeWrapper() so they work correctly with the new driver_object mechanism - changed ndis_attach() to call NdisAddDevice() instead of ndis_load_driver() (which is now deprecated) - used ExAllocatePoolWithTag()/ExFreePool() in lookaside list routines instead of kludged up alloc/free routines - added kern_windrv.c to sys/modules/ndis/Makefile and files.i386.
2005-02-08 17:23:25 +00:00
driver_object *drv;
Throw the switch on the new driver generation/loading mechanism. From here on in, if_ndis.ko will be pre-built as a module, and can be built into a static kernel (though it's not part of GENERIC). Drivers are created using the new ndisgen(8) script, which uses ndiscvt(8) under the covers, along with a few other tools. The result is a driver module that can be kldloaded into the kernel. A driver with foo.inf and foo.sys files will be converted into foo_sys.ko (and foo_sys.o, for those who want/need to make static kernels). This module contains all of the necessary info from the .INF file and the driver binary image, converted into an ELF module. You can kldload this module (or add it to /boot/loader.conf) to have it loaded automatically. Any required firmware files can be bundled into the module as well (or converted/loaded separately). Also, add a workaround for a problem in NdisMSleep(). During system bootstrap (cold == 1), msleep() always returns 0 without actually sleeping. The Intel 2200BG driver uses NdisMSleep() to wait for the NIC's firmware to come to life, and fails to load if NdisMSleep() doesn't actually delay. As a workaround, if msleep() (and hence ndis_thsuspend()) returns 0, use a hard DELAY() to sleep instead). This is not really the right thing to do, but we can't really do much else. At the very least, this makes the Intel driver happy. There are probably other drivers that fail in this way during bootstrap. Unfortunately, the only workaround for those is to avoid pre-loading them and kldload them once the system is running instead.
2005-04-24 20:21:22 +00:00
struct drvdb_ent *db;
drv = windrv_lookup(0, "PCI Bus");
Next step on the road to IRPs: create and use an imitation of the Windows DRIVER_OBJECT and DEVICE_OBJECT mechanism so that we can simulate driver stacking. In Windows, each loaded driver image is attached to a DRIVER_OBJECT structure. Windows uses the registry to match up a given vendor/device ID combination with a corresponding DRIVER_OBJECT. When a driver image is first loaded, its DriverEntry() routine is invoked, which sets up the AddDevice() function pointer in the DRIVER_OBJECT and creates a dispatch table (based on IRP major codes). When a Windows bus driver detects a new device, it creates a Physical Device Object (PDO) for it. This is a DEVICE_OBJECT structure, with semantics analagous to that of a device_t in FreeBSD. The Windows PNP manager will invoke the driver's AddDevice() function and pass it pointers to the DRIVER_OBJECT and the PDO. The AddDevice() function then creates a new DRIVER_OBJECT structure of its own. This is known as the Functional Device Object (FDO) and corresponds roughly to a private softc instance. The driver uses IoAttachDeviceToDeviceStack() to add this device object to the driver stack for this PDO. Subsequent drivers (called filter drivers in Windows-speak) can be loaded which add themselves to the stack. When someone issues an IRP to a device, it travel along the stack passing through several possible filter drivers until it reaches the functional driver (which actually knows how to talk to the hardware) at which point it will be completed. This is how Windows achieves driver layering. Project Evil now simulates most of this. if_ndis now has a modevent handler which will use MOD_LOAD and MOD_UNLOAD events to drive the creation and destruction of DRIVER_OBJECTs. (The load event also does the relocation/dynalinking of the image.) We don't have a registry, so the DRIVER_OBJECTS are stored in a linked list for now. Eventually, the list entry will contain the vendor/device ID list extracted from the .INF file. When ndis_probe() is called and detectes a supported device, it will create a PDO for the device instance and attach it to the DRIVER_OBJECT just as in Windows. ndis_attach() will then call our NdisAddDevice() handler to create the FDO. The NDIS miniport block is now a device extension hung off the FDO, just as it is in Windows. The miniport characteristics table is now an extension hung off the DRIVER_OBJECT as well (the characteristics are the same for all devices handled by a given driver, so they don't need to be per-instance.) We also do an IoAttachDeviceToDeviceStack() to put the FDO on the stack for the PDO. There are a couple of fake bus drivers created for the PCI and pccard buses. Eventually, there will be one for USB, which will actually accept USB IRP.s Things should still work just as before, only now we do things in the proper order and maintain the correct framework to support passing IRPs between drivers. Various changes: - corrected the comments about IRQL handling in subr_hal.c to more accurately reflect reality - update ndiscvt to make the drv_data symbol in ndis_driver_data.h a global so that if_ndis_pci.o and/or if_ndis_pccard.o can see it. - Obtain the softc pointer from the miniport block by referencing the PDO rather than a private pointer of our own (nmb_ifp is no longer used) - implement IoAttachDeviceToDeviceStack(), IoDetachDevice(), IoGetAttachedDevice(), IoAllocateDriverObjectExtension(), IoGetDriverObjectExtension(), IoCreateDevice(), IoDeleteDevice(), IoAllocateIrp(), IoReuseIrp(), IoMakeAssociatedIrp(), IoFreeIrp(), IoInitializeIrp() - fix a few mistakes in the driver_object and device_object definitions - add a new module, kern_windrv.c, to handle the driver registration and relocation/dynalinkign duties (which don't really belong in kern_ndis.c). - made ndis_block and ndis_chars in the ndis_softc stucture pointers and modified all references to it - fixed NdisMRegisterMiniport() and NdisInitializeWrapper() so they work correctly with the new driver_object mechanism - changed ndis_attach() to call NdisAddDevice() instead of ndis_load_driver() (which is now deprecated) - used ExAllocatePoolWithTag()/ExFreePool() in lookaside list routines instead of kludged up alloc/free routines - added kern_windrv.c to sys/modules/ndis/Makefile and files.i386.
2005-02-08 17:23:25 +00:00
if (drv == NULL)
return(ENXIO);
Throw the switch on the new driver generation/loading mechanism. From here on in, if_ndis.ko will be pre-built as a module, and can be built into a static kernel (though it's not part of GENERIC). Drivers are created using the new ndisgen(8) script, which uses ndiscvt(8) under the covers, along with a few other tools. The result is a driver module that can be kldloaded into the kernel. A driver with foo.inf and foo.sys files will be converted into foo_sys.ko (and foo_sys.o, for those who want/need to make static kernels). This module contains all of the necessary info from the .INF file and the driver binary image, converted into an ELF module. You can kldload this module (or add it to /boot/loader.conf) to have it loaded automatically. Any required firmware files can be bundled into the module as well (or converted/loaded separately). Also, add a workaround for a problem in NdisMSleep(). During system bootstrap (cold == 1), msleep() always returns 0 without actually sleeping. The Intel 2200BG driver uses NdisMSleep() to wait for the NIC's firmware to come to life, and fails to load if NdisMSleep() doesn't actually delay. As a workaround, if msleep() (and hence ndis_thsuspend()) returns 0, use a hard DELAY() to sleep instead). This is not really the right thing to do, but we can't really do much else. At the very least, this makes the Intel driver happy. There are probably other drivers that fail in this way during bootstrap. Unfortunately, the only workaround for those is to avoid pre-loading them and kldload them once the system is running instead.
2005-04-24 20:21:22 +00:00
db = windrv_match((matchfuncptr)ndis_devcompare, dev);
Next step on the road to IRPs: create and use an imitation of the Windows DRIVER_OBJECT and DEVICE_OBJECT mechanism so that we can simulate driver stacking. In Windows, each loaded driver image is attached to a DRIVER_OBJECT structure. Windows uses the registry to match up a given vendor/device ID combination with a corresponding DRIVER_OBJECT. When a driver image is first loaded, its DriverEntry() routine is invoked, which sets up the AddDevice() function pointer in the DRIVER_OBJECT and creates a dispatch table (based on IRP major codes). When a Windows bus driver detects a new device, it creates a Physical Device Object (PDO) for it. This is a DEVICE_OBJECT structure, with semantics analagous to that of a device_t in FreeBSD. The Windows PNP manager will invoke the driver's AddDevice() function and pass it pointers to the DRIVER_OBJECT and the PDO. The AddDevice() function then creates a new DRIVER_OBJECT structure of its own. This is known as the Functional Device Object (FDO) and corresponds roughly to a private softc instance. The driver uses IoAttachDeviceToDeviceStack() to add this device object to the driver stack for this PDO. Subsequent drivers (called filter drivers in Windows-speak) can be loaded which add themselves to the stack. When someone issues an IRP to a device, it travel along the stack passing through several possible filter drivers until it reaches the functional driver (which actually knows how to talk to the hardware) at which point it will be completed. This is how Windows achieves driver layering. Project Evil now simulates most of this. if_ndis now has a modevent handler which will use MOD_LOAD and MOD_UNLOAD events to drive the creation and destruction of DRIVER_OBJECTs. (The load event also does the relocation/dynalinking of the image.) We don't have a registry, so the DRIVER_OBJECTS are stored in a linked list for now. Eventually, the list entry will contain the vendor/device ID list extracted from the .INF file. When ndis_probe() is called and detectes a supported device, it will create a PDO for the device instance and attach it to the DRIVER_OBJECT just as in Windows. ndis_attach() will then call our NdisAddDevice() handler to create the FDO. The NDIS miniport block is now a device extension hung off the FDO, just as it is in Windows. The miniport characteristics table is now an extension hung off the DRIVER_OBJECT as well (the characteristics are the same for all devices handled by a given driver, so they don't need to be per-instance.) We also do an IoAttachDeviceToDeviceStack() to put the FDO on the stack for the PDO. There are a couple of fake bus drivers created for the PCI and pccard buses. Eventually, there will be one for USB, which will actually accept USB IRP.s Things should still work just as before, only now we do things in the proper order and maintain the correct framework to support passing IRPs between drivers. Various changes: - corrected the comments about IRQL handling in subr_hal.c to more accurately reflect reality - update ndiscvt to make the drv_data symbol in ndis_driver_data.h a global so that if_ndis_pci.o and/or if_ndis_pccard.o can see it. - Obtain the softc pointer from the miniport block by referencing the PDO rather than a private pointer of our own (nmb_ifp is no longer used) - implement IoAttachDeviceToDeviceStack(), IoDetachDevice(), IoGetAttachedDevice(), IoAllocateDriverObjectExtension(), IoGetDriverObjectExtension(), IoCreateDevice(), IoDeleteDevice(), IoAllocateIrp(), IoReuseIrp(), IoMakeAssociatedIrp(), IoFreeIrp(), IoInitializeIrp() - fix a few mistakes in the driver_object and device_object definitions - add a new module, kern_windrv.c, to handle the driver registration and relocation/dynalinkign duties (which don't really belong in kern_ndis.c). - made ndis_block and ndis_chars in the ndis_softc stucture pointers and modified all references to it - fixed NdisMRegisterMiniport() and NdisInitializeWrapper() so they work correctly with the new driver_object mechanism - changed ndis_attach() to call NdisAddDevice() instead of ndis_load_driver() (which is now deprecated) - used ExAllocatePoolWithTag()/ExFreePool() in lookaside list routines instead of kludged up alloc/free routines - added kern_windrv.c to sys/modules/ndis/Makefile and files.i386.
2005-02-08 17:23:25 +00:00
Throw the switch on the new driver generation/loading mechanism. From here on in, if_ndis.ko will be pre-built as a module, and can be built into a static kernel (though it's not part of GENERIC). Drivers are created using the new ndisgen(8) script, which uses ndiscvt(8) under the covers, along with a few other tools. The result is a driver module that can be kldloaded into the kernel. A driver with foo.inf and foo.sys files will be converted into foo_sys.ko (and foo_sys.o, for those who want/need to make static kernels). This module contains all of the necessary info from the .INF file and the driver binary image, converted into an ELF module. You can kldload this module (or add it to /boot/loader.conf) to have it loaded automatically. Any required firmware files can be bundled into the module as well (or converted/loaded separately). Also, add a workaround for a problem in NdisMSleep(). During system bootstrap (cold == 1), msleep() always returns 0 without actually sleeping. The Intel 2200BG driver uses NdisMSleep() to wait for the NIC's firmware to come to life, and fails to load if NdisMSleep() doesn't actually delay. As a workaround, if msleep() (and hence ndis_thsuspend()) returns 0, use a hard DELAY() to sleep instead). This is not really the right thing to do, but we can't really do much else. At the very least, this makes the Intel driver happy. There are probably other drivers that fail in this way during bootstrap. Unfortunately, the only workaround for those is to avoid pre-loading them and kldload them once the system is running instead.
2005-04-24 20:21:22 +00:00
if (db != NULL) {
/* Create PDO for this device instance */
windrv_create_pdo(drv, dev);
return(0);
}
return(ENXIO);
}
/*
* Attach the interface. Allocate softc structures, do ifmedia
* setup and ethernet/BPF attach.
*/
static int
ndis_attach_pci(dev)
device_t dev;
{
struct ndis_softc *sc;
int unit, error = 0, rid;
struct ndis_pci_type *t;
int devidx = 0, defidx = 0;
struct resource_list *rl;
struct resource_list_entry *rle;
Throw the switch on the new driver generation/loading mechanism. From here on in, if_ndis.ko will be pre-built as a module, and can be built into a static kernel (though it's not part of GENERIC). Drivers are created using the new ndisgen(8) script, which uses ndiscvt(8) under the covers, along with a few other tools. The result is a driver module that can be kldloaded into the kernel. A driver with foo.inf and foo.sys files will be converted into foo_sys.ko (and foo_sys.o, for those who want/need to make static kernels). This module contains all of the necessary info from the .INF file and the driver binary image, converted into an ELF module. You can kldload this module (or add it to /boot/loader.conf) to have it loaded automatically. Any required firmware files can be bundled into the module as well (or converted/loaded separately). Also, add a workaround for a problem in NdisMSleep(). During system bootstrap (cold == 1), msleep() always returns 0 without actually sleeping. The Intel 2200BG driver uses NdisMSleep() to wait for the NIC's firmware to come to life, and fails to load if NdisMSleep() doesn't actually delay. As a workaround, if msleep() (and hence ndis_thsuspend()) returns 0, use a hard DELAY() to sleep instead). This is not really the right thing to do, but we can't really do much else. At the very least, this makes the Intel driver happy. There are probably other drivers that fail in this way during bootstrap. Unfortunately, the only workaround for those is to avoid pre-loading them and kldload them once the system is running instead.
2005-04-24 20:21:22 +00:00
struct drvdb_ent *db;
sc = device_get_softc(dev);
unit = device_get_unit(dev);
sc->ndis_dev = dev;
Throw the switch on the new driver generation/loading mechanism. From here on in, if_ndis.ko will be pre-built as a module, and can be built into a static kernel (though it's not part of GENERIC). Drivers are created using the new ndisgen(8) script, which uses ndiscvt(8) under the covers, along with a few other tools. The result is a driver module that can be kldloaded into the kernel. A driver with foo.inf and foo.sys files will be converted into foo_sys.ko (and foo_sys.o, for those who want/need to make static kernels). This module contains all of the necessary info from the .INF file and the driver binary image, converted into an ELF module. You can kldload this module (or add it to /boot/loader.conf) to have it loaded automatically. Any required firmware files can be bundled into the module as well (or converted/loaded separately). Also, add a workaround for a problem in NdisMSleep(). During system bootstrap (cold == 1), msleep() always returns 0 without actually sleeping. The Intel 2200BG driver uses NdisMSleep() to wait for the NIC's firmware to come to life, and fails to load if NdisMSleep() doesn't actually delay. As a workaround, if msleep() (and hence ndis_thsuspend()) returns 0, use a hard DELAY() to sleep instead). This is not really the right thing to do, but we can't really do much else. At the very least, this makes the Intel driver happy. There are probably other drivers that fail in this way during bootstrap. Unfortunately, the only workaround for those is to avoid pre-loading them and kldload them once the system is running instead.
2005-04-24 20:21:22 +00:00
db = windrv_match((matchfuncptr)ndis_devcompare, dev);
if (db == NULL)
return (ENXIO);
sc->ndis_dobj = db->windrv_object;
sc->ndis_regvals = db->windrv_regvals;
/*
* Map control/status registers.
*/
pci_enable_busmaster(dev);
rl = BUS_GET_RESOURCE_LIST(device_get_parent(dev), dev);
if (rl != NULL) {
#if __FreeBSD_version < 600022
SLIST_FOREACH(rle, rl, link) {
#else
2005-03-19 19:17:17 +00:00
STAILQ_FOREACH(rle, rl, link) {
#endif
switch (rle->type) {
case SYS_RES_IOPORT:
sc->ndis_io_rid = rle->rid;
sc->ndis_res_io = bus_alloc_resource(dev,
SYS_RES_IOPORT, &sc->ndis_io_rid,
0, ~0, 1, RF_ACTIVE);
if (sc->ndis_res_io == NULL) {
device_printf(dev,
"couldn't map iospace\n");
error = ENXIO;
goto fail;
}
Throw the switch on the new driver generation/loading mechanism. From here on in, if_ndis.ko will be pre-built as a module, and can be built into a static kernel (though it's not part of GENERIC). Drivers are created using the new ndisgen(8) script, which uses ndiscvt(8) under the covers, along with a few other tools. The result is a driver module that can be kldloaded into the kernel. A driver with foo.inf and foo.sys files will be converted into foo_sys.ko (and foo_sys.o, for those who want/need to make static kernels). This module contains all of the necessary info from the .INF file and the driver binary image, converted into an ELF module. You can kldload this module (or add it to /boot/loader.conf) to have it loaded automatically. Any required firmware files can be bundled into the module as well (or converted/loaded separately). Also, add a workaround for a problem in NdisMSleep(). During system bootstrap (cold == 1), msleep() always returns 0 without actually sleeping. The Intel 2200BG driver uses NdisMSleep() to wait for the NIC's firmware to come to life, and fails to load if NdisMSleep() doesn't actually delay. As a workaround, if msleep() (and hence ndis_thsuspend()) returns 0, use a hard DELAY() to sleep instead). This is not really the right thing to do, but we can't really do much else. At the very least, this makes the Intel driver happy. There are probably other drivers that fail in this way during bootstrap. Unfortunately, the only workaround for those is to avoid pre-loading them and kldload them once the system is running instead.
2005-04-24 20:21:22 +00:00
pci_enable_io(dev, SYS_RES_IOPORT);
break;
case SYS_RES_MEMORY:
if (sc->ndis_res_altmem != NULL &&
sc->ndis_res_mem != NULL) {
device_printf(dev,
"too many memory resources\n");
error = ENXIO;
goto fail;
}
if (sc->ndis_res_mem) {
sc->ndis_altmem_rid = rle->rid;
sc->ndis_res_altmem =
bus_alloc_resource(dev,
SYS_RES_MEMORY,
&sc->ndis_altmem_rid,
0, ~0, 1, RF_ACTIVE);
if (sc->ndis_res_altmem == NULL) {
device_printf(dev,
"couldn't map alt "
"memory\n");
error = ENXIO;
goto fail;
}
} else {
sc->ndis_mem_rid = rle->rid;
sc->ndis_res_mem =
bus_alloc_resource(dev,
SYS_RES_MEMORY,
&sc->ndis_mem_rid,
0, ~0, 1, RF_ACTIVE);
if (sc->ndis_res_mem == NULL) {
device_printf(dev,
"couldn't map memory\n");
error = ENXIO;
goto fail;
}
}
Throw the switch on the new driver generation/loading mechanism. From here on in, if_ndis.ko will be pre-built as a module, and can be built into a static kernel (though it's not part of GENERIC). Drivers are created using the new ndisgen(8) script, which uses ndiscvt(8) under the covers, along with a few other tools. The result is a driver module that can be kldloaded into the kernel. A driver with foo.inf and foo.sys files will be converted into foo_sys.ko (and foo_sys.o, for those who want/need to make static kernels). This module contains all of the necessary info from the .INF file and the driver binary image, converted into an ELF module. You can kldload this module (or add it to /boot/loader.conf) to have it loaded automatically. Any required firmware files can be bundled into the module as well (or converted/loaded separately). Also, add a workaround for a problem in NdisMSleep(). During system bootstrap (cold == 1), msleep() always returns 0 without actually sleeping. The Intel 2200BG driver uses NdisMSleep() to wait for the NIC's firmware to come to life, and fails to load if NdisMSleep() doesn't actually delay. As a workaround, if msleep() (and hence ndis_thsuspend()) returns 0, use a hard DELAY() to sleep instead). This is not really the right thing to do, but we can't really do much else. At the very least, this makes the Intel driver happy. There are probably other drivers that fail in this way during bootstrap. Unfortunately, the only workaround for those is to avoid pre-loading them and kldload them once the system is running instead.
2005-04-24 20:21:22 +00:00
pci_enable_io(dev, SYS_RES_MEMORY);
break;
case SYS_RES_IRQ:
rid = rle->rid;
sc->ndis_irq = bus_alloc_resource(dev,
SYS_RES_IRQ, &rid, 0, ~0, 1,
RF_SHAREABLE | RF_ACTIVE);
if (sc->ndis_irq == NULL) {
device_printf(dev,
"couldn't map interrupt\n");
error = ENXIO;
goto fail;
}
break;
default:
break;
}
sc->ndis_rescnt++;
}
}
/*
* If the BIOS did not set up an interrupt for this device,
* the resource traversal code above will fail to set up
* an IRQ resource. This is usually a bad thing, so try to
* force the allocation of an interrupt here. If one was
* not assigned to us by the BIOS, bus_alloc_resource()
* should route one for us.
*/
if (sc->ndis_irq == NULL) {
rid = 0;
sc->ndis_irq = bus_alloc_resource(dev, SYS_RES_IRQ,
&rid, 0, ~0, 1, RF_SHAREABLE | RF_ACTIVE);
if (sc->ndis_irq == NULL) {
device_printf(dev, "couldn't route interrupt\n");
error = ENXIO;
goto fail;
}
sc->ndis_rescnt++;
}
/*
* Allocate the parent bus DMA tag appropriate for PCI.
*/
#define NDIS_NSEG_NEW 32
error = bus_dma_tag_create(NULL, /* parent */
1, 0, /* alignment, boundary */
BUS_SPACE_MAXADDR_32BIT,/* lowaddr */
BUS_SPACE_MAXADDR, /* highaddr */
NULL, NULL, /* filter, filterarg */
MAXBSIZE, NDIS_NSEG_NEW,/* maxsize, nsegments */
BUS_SPACE_MAXSIZE_32BIT,/* maxsegsize */
BUS_DMA_ALLOCNOW, /* flags */
NULL, NULL, /* lockfunc, lockarg */
&sc->ndis_parent_tag);
if (error)
goto fail;
sc->ndis_iftype = PCIBus;
/* Figure out exactly which device we matched. */
Throw the switch on the new driver generation/loading mechanism. From here on in, if_ndis.ko will be pre-built as a module, and can be built into a static kernel (though it's not part of GENERIC). Drivers are created using the new ndisgen(8) script, which uses ndiscvt(8) under the covers, along with a few other tools. The result is a driver module that can be kldloaded into the kernel. A driver with foo.inf and foo.sys files will be converted into foo_sys.ko (and foo_sys.o, for those who want/need to make static kernels). This module contains all of the necessary info from the .INF file and the driver binary image, converted into an ELF module. You can kldload this module (or add it to /boot/loader.conf) to have it loaded automatically. Any required firmware files can be bundled into the module as well (or converted/loaded separately). Also, add a workaround for a problem in NdisMSleep(). During system bootstrap (cold == 1), msleep() always returns 0 without actually sleeping. The Intel 2200BG driver uses NdisMSleep() to wait for the NIC's firmware to come to life, and fails to load if NdisMSleep() doesn't actually delay. As a workaround, if msleep() (and hence ndis_thsuspend()) returns 0, use a hard DELAY() to sleep instead). This is not really the right thing to do, but we can't really do much else. At the very least, this makes the Intel driver happy. There are probably other drivers that fail in this way during bootstrap. Unfortunately, the only workaround for those is to avoid pre-loading them and kldload them once the system is running instead.
2005-04-24 20:21:22 +00:00
t = db->windrv_devlist;
while(t->ndis_name != NULL) {
if ((pci_get_vendor(dev) == t->ndis_vid) &&
(pci_get_device(dev) == t->ndis_did)) {
if (t->ndis_subsys == 0)
defidx = devidx;
else {
if (t->ndis_subsys ==
pci_read_config(dev, PCIR_SUBVEND_0, 4))
break;
}
}
t++;
devidx++;
}
if (t->ndis_name == NULL)
sc->ndis_devidx = defidx;
else
sc->ndis_devidx = devidx;
error = ndis_attach(dev);
fail:
return(error);
}
static struct resource_list *
ndis_get_resource_list(dev, child)
device_t dev;
device_t child;
{
struct ndis_softc *sc;
sc = device_get_softc(dev);
return (BUS_GET_RESOURCE_LIST(device_get_parent(sc->ndis_dev), dev));
}