Documentation/PCI/PCIEBUS-HOWTO.txt - pub/scm/linux/kernel/git/davidb/linux-msm - Git at Google

 		The PCI Express Port Bus Driver Guide HOWTO
 	Tom L Nguyen tom.l.nguyen@intel.com
 			11/03/2004

 1. About this guide

 This guide describes the basics of the PCI Express Port Bus driver
 and provides information on how to enable the service drivers to
 register/unregister with the PCI Express Port Bus Driver.

 2. Copyright 2004 Intel Corporation

 3. What is the PCI Express Port Bus Driver

 A PCI Express Port is a logical PCI-PCI Bridge structure. There
 are two types of PCI Express Port: the Root Port and the Switch
 Port. The Root Port originates a PCI Express link from a PCI Express
 Root Complex and the Switch Port connects PCI Express links to
 internal logical PCI buses. The Switch Port, which has its secondary
 bus representing the switch's internal routing logic, is called the
 switch's Upstream Port. The switch's Downstream Port is bridging from
 switch's internal routing bus to a bus representing the downstream
 PCI Express link from the PCI Express Switch.

 A PCI Express Port can provide up to four distinct functions,
 referred to in this document as services, depending on its port type.
 PCI Express Port's services include native hotplug support (HP),
 power management event support (PME), advanced error reporting
 support (AER), and virtual channel support (VC). These services may
 be handled by a single complex driver or be individually distributed
 and handled by corresponding service drivers.

 4. Why use the PCI Express Port Bus Driver?

 In existing Linux kernels, the Linux Device Driver Model allows a
 physical device to be handled by only a single driver. The PCI
 Express Port is a PCI-PCI Bridge device with multiple distinct
 services. To maintain a clean and simple solution each service
 may have its own software service driver. In this case several
 service drivers will compete for a single PCI-PCI Bridge device.
 For example, if the PCI Express Root Port native hotplug service
 driver is loaded first, it claims a PCI-PCI Bridge Root Port. The
 kernel therefore does not load other service drivers for that Root
 Port. In other words, it is impossible to have multiple service
 drivers load and run on a PCI-PCI Bridge device simultaneously
 using the current driver model.

 To enable multiple service drivers running simultaneously requires
 having a PCI Express Port Bus driver, which manages all populated
 PCI Express Ports and distributes all provided service requests
 to the corresponding service drivers as required. Some key
 advantages of using the PCI Express Port Bus driver are listed below:

 	- Allow multiple service drivers to run simultaneously on
 	  a PCI-PCI Bridge Port device.

 	- Allow service drivers implemented in an independent
 	  staged approach.

 	- Allow one service driver to run on multiple PCI-PCI Bridge
 	  Port devices.

 	- Manage and distribute resources of a PCI-PCI Bridge Port
 	  device to requested service drivers.

 5. Configuring the PCI Express Port Bus Driver vs. Service Drivers

 5.1 Including the PCI Express Port Bus Driver Support into the Kernel

 Including the PCI Express Port Bus driver depends on whether the PCI
 Express support is included in the kernel config. The kernel will
 automatically include the PCI Express Port Bus driver as a kernel
 driver when the PCI Express support is enabled in the kernel.

 5.2 Enabling Service Driver Support

 PCI device drivers are implemented based on Linux Device Driver Model.
 All service drivers are PCI device drivers. As discussed above, it is
 impossible to load any service driver once the kernel has loaded the
 PCI Express Port Bus Driver. To meet the PCI Express Port Bus Driver
 Model requires some minimal changes on existing service drivers that
 imposes no impact on the functionality of existing service drivers.

 A service driver is required to use the two APIs shown below to
 register its service with the PCI Express Port Bus driver (see
 section 5.2.1 & 5.2.2). It is important that a service driver
 initializes the pcie_port_service_driver data structure, included in
 header file /include/linux/pcieport_if.h, before calling these APIs.
 Failure to do so will result an identity mismatch, which prevents
 the PCI Express Port Bus driver from loading a service driver.

 5.2.1 pcie_port_service_register

 int pcie_port_service_register(struct pcie_port_service_driver *new)

 This API replaces the Linux Driver Model's pci_register_driver API. A
 service driver should always calls pcie_port_service_register at
 module init. Note that after service driver being loaded, calls
 such as pci_enable_device(dev) and pci_set_master(dev) are no longer
 necessary since these calls are executed by the PCI Port Bus driver.

 5.2.2 pcie_port_service_unregister

 void pcie_port_service_unregister(struct pcie_port_service_driver *new)

 pcie_port_service_unregister replaces the Linux Driver Model's
 pci_unregister_driver. It's always called by service driver when a
 module exits.

 5.2.3 Sample Code

 Below is sample service driver code to initialize the port service
 driver data structure.

 static struct pcie_port_service_id service_id[] = { {
 	.vendor = PCI_ANY_ID,
 	.device = PCI_ANY_ID,
 	.port_type = PCIE_RC_PORT,
 	.service_type = PCIE_PORT_SERVICE_AER,
 	}, { /* end: all zeroes */ }
 };

 static struct pcie_port_service_driver root_aerdrv = {
 	.name		= (char *)device_name,
 	.id_table	= &service_id[0],

 	.probe		= aerdrv_load,
 	.remove		= aerdrv_unload,

 	.suspend	= aerdrv_suspend,
 	.resume		= aerdrv_resume,
 };

 Below is a sample code for registering/unregistering a service
 driver.

 static int __init aerdrv_service_init(void)
 {
 	int retval = 0;

 	retval = pcie_port_service_register(&root_aerdrv);
 	if (!retval) {
 		/*
 		 * FIX ME
 		 */
 	}
 	return retval;
 }

 static void __exit aerdrv_service_exit(void)
 {
 	pcie_port_service_unregister(&root_aerdrv);
 }

 module_init(aerdrv_service_init);
 module_exit(aerdrv_service_exit);

 6. Possible Resource Conflicts

 Since all service drivers of a PCI-PCI Bridge Port device are
 allowed to run simultaneously, below lists a few of possible resource
 conflicts with proposed solutions.

 6.1 MSI Vector Resource

 The MSI capability structure enables a device software driver to call
 pci_enable_msi to request MSI based interrupts. Once MSI interrupts
 are enabled on a device, it stays in this mode until a device driver
 calls pci_disable_msi to disable MSI interrupts and revert back to
 INTx emulation mode. Since service drivers of the same PCI-PCI Bridge
 port share the same physical device, if an individual service driver
 calls pci_enable_msi/pci_disable_msi it may result unpredictable
 behavior. For example, two service drivers run simultaneously on the
 same physical Root Port. Both service drivers call pci_enable_msi to
 request MSI based interrupts. A service driver may not know whether
 any other service drivers have run on this Root Port. If either one
 of them calls pci_disable_msi, it puts the other service driver
 in a wrong interrupt mode.

 To avoid this situation all service drivers are not permitted to
 switch interrupt mode on its device. The PCI Express Port Bus driver
 is responsible for determining the interrupt mode and this should be
 transparent to service drivers. Service drivers need to know only
 the vector IRQ assigned to the field irq of struct pcie_device, which
 is passed in when the PCI Express Port Bus driver probes each service
 driver. Service drivers should use (struct pcie_device*)dev->irq to
 call request_irq/free_irq. In addition, the interrupt mode is stored
 in the field interrupt_mode of struct pcie_device.

 6.2 MSI-X Vector Resources

 Similar to the MSI a device driver for an MSI-X capable device can
 call pci_enable_msix to request MSI-X interrupts. All service drivers
 are not permitted to switch interrupt mode on its device. The PCI
 Express Port Bus driver is responsible for determining the interrupt
 mode and this should be transparent to service drivers. Any attempt
 by service driver to call pci_enable_msix/pci_disable_msix may
 result unpredictable behavior. Service drivers should use
 (struct pcie_device*)dev->irq and call request_irq/free_irq.

 6.3 PCI Memory/IO Mapped Regions

 Service drivers for PCI Express Power Management (PME), Advanced
 Error Reporting (AER), Hot-Plug (HP) and Virtual Channel (VC) access
 PCI configuration space on the PCI Express port. In all cases the
 registers accessed are independent of each other. This patch assumes
 that all service drivers will be well behaved and not overwrite
 other service driver's configuration settings.

 6.4 PCI Config Registers

 Each service driver runs its PCI config operations on its own
 capability structure except the PCI Express capability structure, in
 which Root Control register and Device Control register are shared
 between PME and AER. This patch assumes that all service drivers
 will be well behaved and not overwrite other service driver's
 configuration settings.
	The PCI Express Port Bus Driver Guide HOWTO
	Tom L Nguyen tom.l.nguyen@intel.com
	11/03/2004

	1. About this guide

	This guide describes the basics of the PCI Express Port Bus driver
	and provides information on how to enable the service drivers to
	register/unregister with the PCI Express Port Bus Driver.

	2. Copyright 2004 Intel Corporation

	3. What is the PCI Express Port Bus Driver

	A PCI Express Port is a logical PCI-PCI Bridge structure. There
	are two types of PCI Express Port: the Root Port and the Switch
	Port. The Root Port originates a PCI Express link from a PCI Express
	Root Complex and the Switch Port connects PCI Express links to
	internal logical PCI buses. The Switch Port, which has its secondary
	bus representing the switch's internal routing logic, is called the
	switch's Upstream Port. The switch's Downstream Port is bridging from
	switch's internal routing bus to a bus representing the downstream
	PCI Express link from the PCI Express Switch.

	A PCI Express Port can provide up to four distinct functions,
	referred to in this document as services, depending on its port type.
	PCI Express Port's services include native hotplug support (HP),
	power management event support (PME), advanced error reporting
	support (AER), and virtual channel support (VC). These services may
	be handled by a single complex driver or be individually distributed
	and handled by corresponding service drivers.

	4. Why use the PCI Express Port Bus Driver?

	In existing Linux kernels, the Linux Device Driver Model allows a
	physical device to be handled by only a single driver. The PCI
	Express Port is a PCI-PCI Bridge device with multiple distinct
	services. To maintain a clean and simple solution each service
	may have its own software service driver. In this case several
	service drivers will compete for a single PCI-PCI Bridge device.
	For example, if the PCI Express Root Port native hotplug service
	driver is loaded first, it claims a PCI-PCI Bridge Root Port. The
	kernel therefore does not load other service drivers for that Root
	Port. In other words, it is impossible to have multiple service
	drivers load and run on a PCI-PCI Bridge device simultaneously
	using the current driver model.

	To enable multiple service drivers running simultaneously requires
	having a PCI Express Port Bus driver, which manages all populated
	PCI Express Ports and distributes all provided service requests
	to the corresponding service drivers as required. Some key
	advantages of using the PCI Express Port Bus driver are listed below:

	- Allow multiple service drivers to run simultaneously on
	a PCI-PCI Bridge Port device.

	- Allow service drivers implemented in an independent
	staged approach.

	- Allow one service driver to run on multiple PCI-PCI Bridge
	Port devices.

	- Manage and distribute resources of a PCI-PCI Bridge Port
	device to requested service drivers.

	5. Configuring the PCI Express Port Bus Driver vs. Service Drivers

	5.1 Including the PCI Express Port Bus Driver Support into the Kernel

	Including the PCI Express Port Bus driver depends on whether the PCI
	Express support is included in the kernel config. The kernel will
	automatically include the PCI Express Port Bus driver as a kernel
	driver when the PCI Express support is enabled in the kernel.

	5.2 Enabling Service Driver Support

	PCI device drivers are implemented based on Linux Device Driver Model.
	All service drivers are PCI device drivers. As discussed above, it is
	impossible to load any service driver once the kernel has loaded the
	PCI Express Port Bus Driver. To meet the PCI Express Port Bus Driver
	Model requires some minimal changes on existing service drivers that
	imposes no impact on the functionality of existing service drivers.

	A service driver is required to use the two APIs shown below to
	register its service with the PCI Express Port Bus driver (see
	section 5.2.1 & 5.2.2). It is important that a service driver
	initializes the pcie_port_service_driver data structure, included in
	header file /include/linux/pcieport_if.h, before calling these APIs.
	Failure to do so will result an identity mismatch, which prevents
	the PCI Express Port Bus driver from loading a service driver.

	5.2.1 pcie_port_service_register

	int pcie_port_service_register(struct pcie_port_service_driver *new)

	This API replaces the Linux Driver Model's pci_register_driver API. A
	service driver should always calls pcie_port_service_register at
	module init. Note that after service driver being loaded, calls
	such as pci_enable_device(dev) and pci_set_master(dev) are no longer
	necessary since these calls are executed by the PCI Port Bus driver.

	5.2.2 pcie_port_service_unregister

	void pcie_port_service_unregister(struct pcie_port_service_driver *new)

	pcie_port_service_unregister replaces the Linux Driver Model's
	pci_unregister_driver. It's always called by service driver when a
	module exits.

	5.2.3 Sample Code

	Below is sample service driver code to initialize the port service
	driver data structure.

	static struct pcie_port_service_id service_id[] = { {
	.vendor = PCI_ANY_ID,
	.device = PCI_ANY_ID,
	.port_type = PCIE_RC_PORT,
	.service_type = PCIE_PORT_SERVICE_AER,
	}, { /* end: all zeroes */ }
	};

	static struct pcie_port_service_driver root_aerdrv = {
	.name = (char *)device_name,
	.id_table = &service_id[0],

	.probe = aerdrv_load,
	.remove = aerdrv_unload,

	.suspend = aerdrv_suspend,
	.resume = aerdrv_resume,
	};

	Below is a sample code for registering/unregistering a service
	driver.

	static int __init aerdrv_service_init(void)
	{
	int retval = 0;

	retval = pcie_port_service_register(&root_aerdrv);
	if (!retval) {
	/*
	* FIX ME
	*/
	}
	return retval;
	}

	static void __exit aerdrv_service_exit(void)
	{
	pcie_port_service_unregister(&root_aerdrv);
	}

	module_init(aerdrv_service_init);
	module_exit(aerdrv_service_exit);

	6. Possible Resource Conflicts

	Since all service drivers of a PCI-PCI Bridge Port device are
	allowed to run simultaneously, below lists a few of possible resource
	conflicts with proposed solutions.

	6.1 MSI Vector Resource

	The MSI capability structure enables a device software driver to call
	pci_enable_msi to request MSI based interrupts. Once MSI interrupts
	are enabled on a device, it stays in this mode until a device driver
	calls pci_disable_msi to disable MSI interrupts and revert back to
	INTx emulation mode. Since service drivers of the same PCI-PCI Bridge
	port share the same physical device, if an individual service driver
	calls pci_enable_msi/pci_disable_msi it may result unpredictable
	behavior. For example, two service drivers run simultaneously on the
	same physical Root Port. Both service drivers call pci_enable_msi to
	request MSI based interrupts. A service driver may not know whether
	any other service drivers have run on this Root Port. If either one
	of them calls pci_disable_msi, it puts the other service driver
	in a wrong interrupt mode.

	To avoid this situation all service drivers are not permitted to
	switch interrupt mode on its device. The PCI Express Port Bus driver
	is responsible for determining the interrupt mode and this should be
	transparent to service drivers. Service drivers need to know only
	the vector IRQ assigned to the field irq of struct pcie_device, which
	is passed in when the PCI Express Port Bus driver probes each service
	driver. Service drivers should use (struct pcie_device*)dev->irq to
	call request_irq/free_irq. In addition, the interrupt mode is stored
	in the field interrupt_mode of struct pcie_device.

	6.2 MSI-X Vector Resources

	Similar to the MSI a device driver for an MSI-X capable device can
	call pci_enable_msix to request MSI-X interrupts. All service drivers
	are not permitted to switch interrupt mode on its device. The PCI
	Express Port Bus driver is responsible for determining the interrupt
	mode and this should be transparent to service drivers. Any attempt
	by service driver to call pci_enable_msix/pci_disable_msix may
	result unpredictable behavior. Service drivers should use
	(struct pcie_device*)dev->irq and call request_irq/free_irq.

	6.3 PCI Memory/IO Mapped Regions

	Service drivers for PCI Express Power Management (PME), Advanced
	Error Reporting (AER), Hot-Plug (HP) and Virtual Channel (VC) access
	PCI configuration space on the PCI Express port. In all cases the
	registers accessed are independent of each other. This patch assumes
	that all service drivers will be well behaved and not overwrite
	other service driver's configuration settings.

	6.4 PCI Config Registers

	Each service driver runs its PCI config operations on its own
	capability structure except the PCI Express capability structure, in
	which Root Control register and Device Control register are shared
	between PME and AER. This patch assumes that all service drivers
	will be well behaved and not overwrite other service driver's
	configuration settings.