| The Linux RapidIO Subsystem |
| |
| ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ |
| |
| The RapidIO standard is a packet-based fabric interconnect standard designed for |
| use in embedded systems. Development of the RapidIO standard is directed by the |
| RapidIO Trade Association (RTA). The current version of the RapidIO specification |
| is publicly available for download from the RTA web-site [1]. |
| |
| This document describes the basics of the Linux RapidIO subsystem and provides |
| information on its major components. |
| |
| 1 Overview |
| ---------- |
| |
| Because the RapidIO subsystem follows the Linux device model it is integrated |
| into the kernel similarly to other buses by defining RapidIO-specific device and |
| bus types and registering them within the device model. |
| |
| The Linux RapidIO subsystem is architecture independent and therefore defines |
| architecture-specific interfaces that provide support for common RapidIO |
| subsystem operations. |
| |
| 2. Core Components |
| ------------------ |
| |
| A typical RapidIO network is a combination of endpoints and switches. |
| Each of these components is represented in the subsystem by an associated data |
| structure. The core logical components of the RapidIO subsystem are defined |
| in include/linux/rio.h file. |
| |
| 2.1 Master Port |
| |
| A master port (or mport) is a RapidIO interface controller that is local to the |
| processor executing the Linux code. A master port generates and receives RapidIO |
| packets (transactions). In the RapidIO subsystem each master port is represented |
| by a rio_mport data structure. This structure contains master port specific |
| resources such as mailboxes and doorbells. The rio_mport also includes a unique |
| host device ID that is valid when a master port is configured as an enumerating |
| host. |
| |
| RapidIO master ports are serviced by subsystem specific mport device drivers |
| that provide functionality defined for this subsystem. To provide a hardware |
| independent interface for RapidIO subsystem operations, rio_mport structure |
| includes rio_ops data structure which contains pointers to hardware specific |
| implementations of RapidIO functions. |
| |
| 2.2 Device |
| |
| A RapidIO device is any endpoint (other than mport) or switch in the network. |
| All devices are presented in the RapidIO subsystem by corresponding rio_dev data |
| structure. Devices form one global device list and per-network device lists |
| (depending on number of available mports and networks). |
| |
| 2.3 Switch |
| |
| A RapidIO switch is a special class of device that routes packets between its |
| ports towards their final destination. The packet destination port within a |
| switch is defined by an internal routing table. A switch is presented in the |
| RapidIO subsystem by rio_dev data structure expanded by additional rio_switch |
| data structure, which contains switch specific information such as copy of the |
| routing table and pointers to switch specific functions. |
| |
| The RapidIO subsystem defines the format and initialization method for subsystem |
| specific switch drivers that are designed to provide hardware-specific |
| implementation of common switch management routines. |
| |
| 2.4 Network |
| |
| A RapidIO network is a combination of interconnected endpoint and switch devices. |
| Each RapidIO network known to the system is represented by corresponding rio_net |
| data structure. This structure includes lists of all devices and local master |
| ports that form the same network. It also contains a pointer to the default |
| master port that is used to communicate with devices within the network. |
| |
| 2.5 Device Drivers |
| |
| RapidIO device-specific drivers follow Linux Kernel Driver Model and are |
| intended to support specific RapidIO devices attached to the RapidIO network. |
| |
| 2.6 Subsystem Interfaces |
| |
| RapidIO interconnect specification defines features that may be used to provide |
| one or more common service layers for all participating RapidIO devices. These |
| common services may act separately from device-specific drivers or be used by |
| device-specific drivers. Example of such service provider is the RIONET driver |
| which implements Ethernet-over-RapidIO interface. Because only one driver can be |
| registered for a device, all common RapidIO services have to be registered as |
| subsystem interfaces. This allows to have multiple common services attached to |
| the same device without blocking attachment of a device-specific driver. |
| |
| 3. Subsystem Initialization |
| --------------------------- |
| |
| In order to initialize the RapidIO subsystem, a platform must initialize and |
| register at least one master port within the RapidIO network. To register mport |
| within the subsystem controller driver's initialization code calls function |
| rio_register_mport() for each available master port. |
| |
| After all active master ports are registered with a RapidIO subsystem, |
| an enumeration and/or discovery routine may be called automatically or |
| by user-space command. |
| |
| RapidIO subsystem can be configured to be built as a statically linked or |
| modular component of the kernel (see details below). |
| |
| 4. Enumeration and Discovery |
| ---------------------------- |
| |
| 4.1 Overview |
| ------------ |
| |
| RapidIO subsystem configuration options allow users to build enumeration and |
| discovery methods as statically linked components or loadable modules. |
| An enumeration/discovery method implementation and available input parameters |
| define how any given method can be attached to available RapidIO mports: |
| simply to all available mports OR individually to the specified mport device. |
| |
| Depending on selected enumeration/discovery build configuration, there are |
| several methods to initiate an enumeration and/or discovery process: |
| |
| (a) Statically linked enumeration and discovery process can be started |
| automatically during kernel initialization time using corresponding module |
| parameters. This was the original method used since introduction of RapidIO |
| subsystem. Now this method relies on enumerator module parameter which is |
| 'rio-scan.scan' for existing basic enumeration/discovery method. |
| When automatic start of enumeration/discovery is used a user has to ensure |
| that all discovering endpoints are started before the enumerating endpoint |
| and are waiting for enumeration to be completed. |
| Configuration option CONFIG_RAPIDIO_DISC_TIMEOUT defines time that discovering |
| endpoint waits for enumeration to be completed. If the specified timeout |
| expires the discovery process is terminated without obtaining RapidIO network |
| information. NOTE: a timed out discovery process may be restarted later using |
| a user-space command as it is described below (if the given endpoint was |
| enumerated successfully). |
| |
| (b) Statically linked enumeration and discovery process can be started by |
| a command from user space. This initiation method provides more flexibility |
| for a system startup compared to the option (a) above. After all participating |
| endpoints have been successfully booted, an enumeration process shall be |
| started first by issuing a user-space command, after an enumeration is |
| completed a discovery process can be started on all remaining endpoints. |
| |
| (c) Modular enumeration and discovery process can be started by a command from |
| user space. After an enumeration/discovery module is loaded, a network scan |
| process can be started by issuing a user-space command. |
| Similar to the option (b) above, an enumerator has to be started first. |
| |
| (d) Modular enumeration and discovery process can be started by a module |
| initialization routine. In this case an enumerating module shall be loaded |
| first. |
| |
| When a network scan process is started it calls an enumeration or discovery |
| routine depending on the configured role of a master port: host or agent. |
| |
| Enumeration is performed by a master port if it is configured as a host port by |
| assigning a host destination ID greater than or equal to zero. The host |
| destination ID can be assigned to a master port using various methods depending |
| on RapidIO subsystem build configuration: |
| |
| (a) For a statically linked RapidIO subsystem core use command line parameter |
| "rapidio.hdid=" with a list of destination ID assignments in order of mport |
| device registration. For example, in a system with two RapidIO controllers |
| the command line parameter "rapidio.hdid=-1,7" will result in assignment of |
| the host destination ID=7 to the second RapidIO controller, while the first |
| one will be assigned destination ID=-1. |
| |
| (b) If the RapidIO subsystem core is built as a loadable module, in addition |
| to the method shown above, the host destination ID(s) can be specified using |
| traditional methods of passing module parameter "hdid=" during its loading: |
| - from command line: "modprobe rapidio hdid=-1,7", or |
| - from modprobe configuration file using configuration command "options", |
| like in this example: "options rapidio hdid=-1,7". An example of modprobe |
| configuration file is provided in the section below. |
| |
| NOTES: |
| (i) if "hdid=" parameter is omitted all available mport will be assigned |
| destination ID = -1; |
| (ii) the "hdid=" parameter in systems with multiple mports can have |
| destination ID assignments omitted from the end of list (default = -1). |
| |
| If the host device ID for a specific master port is set to -1, the discovery |
| process will be performed for it. |
| |
| The enumeration and discovery routines use RapidIO maintenance transactions |
| to access the configuration space of devices. |
| |
| NOTE: If RapidIO switch-specific device drivers are built as loadable modules |
| they must be loaded before enumeration/discovery process starts. |
| This requirement is cased by the fact that enumeration/discovery methods invoke |
| vendor-specific callbacks on early stages. |
| |
| 4.2 Automatic Start of Enumeration and Discovery |
| ------------------------------------------------ |
| |
| Automatic enumeration/discovery start method is applicable only to built-in |
| enumeration/discovery RapidIO configuration selection. To enable automatic |
| enumeration/discovery start by existing basic enumerator method set use boot |
| command line parameter "rio-scan.scan=1". |
| |
| This configuration requires synchronized start of all RapidIO endpoints that |
| form a network which will be enumerated/discovered. Discovering endpoints have |
| to be started before an enumeration starts to ensure that all RapidIO |
| controllers have been initialized and are ready to be discovered. Configuration |
| parameter CONFIG_RAPIDIO_DISC_TIMEOUT defines time (in seconds) which |
| a discovering endpoint will wait for enumeration to be completed. |
| |
| When automatic enumeration/discovery start is selected, basic method's |
| initialization routine calls rio_init_mports() to perform enumeration or |
| discovery for all known mport devices. |
| |
| Depending on RapidIO network size and configuration this automatic |
| enumeration/discovery start method may be difficult to use due to the |
| requirement for synchronized start of all endpoints. |
| |
| 4.3 User-space Start of Enumeration and Discovery |
| ------------------------------------------------- |
| |
| User-space start of enumeration and discovery can be used with built-in and |
| modular build configurations. For user-space controlled start RapidIO subsystem |
| creates the sysfs write-only attribute file '/sys/bus/rapidio/scan'. To initiate |
| an enumeration or discovery process on specific mport device, a user needs to |
| write mport_ID (not RapidIO destination ID) into that file. The mport_ID is a |
| sequential number (0 ... RIO_MAX_MPORTS) assigned during mport device |
| registration. For example for machine with single RapidIO controller, mport_ID |
| for that controller always will be 0. |
| |
| To initiate RapidIO enumeration/discovery on all available mports a user may |
| write '-1' (or RIO_MPORT_ANY) into the scan attribute file. |
| |
| 4.4 Basic Enumeration Method |
| ---------------------------- |
| |
| This is an original enumeration/discovery method which is available since |
| first release of RapidIO subsystem code. The enumeration process is |
| implemented according to the enumeration algorithm outlined in the RapidIO |
| Interconnect Specification: Annex I [1]. |
| |
| This method can be configured as statically linked or loadable module. |
| The method's single parameter "scan" allows to trigger the enumeration/discovery |
| process from module initialization routine. |
| |
| This enumeration/discovery method can be started only once and does not support |
| unloading if it is built as a module. |
| |
| The enumeration process traverses the network using a recursive depth-first |
| algorithm. When a new device is found, the enumerator takes ownership of that |
| device by writing into the Host Device ID Lock CSR. It does this to ensure that |
| the enumerator has exclusive right to enumerate the device. If device ownership |
| is successfully acquired, the enumerator allocates a new rio_dev structure and |
| initializes it according to device capabilities. |
| |
| If the device is an endpoint, a unique device ID is assigned to it and its value |
| is written into the device's Base Device ID CSR. |
| |
| If the device is a switch, the enumerator allocates an additional rio_switch |
| structure to store switch specific information. Then the switch's vendor ID and |
| device ID are queried against a table of known RapidIO switches. Each switch |
| table entry contains a pointer to a switch-specific initialization routine that |
| initializes pointers to the rest of switch specific operations, and performs |
| hardware initialization if necessary. A RapidIO switch does not have a unique |
| device ID; it relies on hopcount and routing for device ID of an attached |
| endpoint if access to its configuration registers is required. If a switch (or |
| chain of switches) does not have any endpoint (except enumerator) attached to |
| it, a fake device ID will be assigned to configure a route to that switch. |
| In the case of a chain of switches without endpoint, one fake device ID is used |
| to configure a route through the entire chain and switches are differentiated by |
| their hopcount value. |
| |
| For both endpoints and switches the enumerator writes a unique component tag |
| into device's Component Tag CSR. That unique value is used by the error |
| management notification mechanism to identify a device that is reporting an |
| error management event. |
| |
| Enumeration beyond a switch is completed by iterating over each active egress |
| port of that switch. For each active link, a route to a default device ID |
| (0xFF for 8-bit systems and 0xFFFF for 16-bit systems) is temporarily written |
| into the routing table. The algorithm recurs by calling itself with hopcount + 1 |
| and the default device ID in order to access the device on the active port. |
| |
| After the host has completed enumeration of the entire network it releases |
| devices by clearing device ID locks (calls rio_clear_locks()). For each endpoint |
| in the system, it sets the Discovered bit in the Port General Control CSR |
| to indicate that enumeration is completed and agents are allowed to execute |
| passive discovery of the network. |
| |
| The discovery process is performed by agents and is similar to the enumeration |
| process that is described above. However, the discovery process is performed |
| without changes to the existing routing because agents only gather information |
| about RapidIO network structure and are building an internal map of discovered |
| devices. This way each Linux-based component of the RapidIO subsystem has |
| a complete view of the network. The discovery process can be performed |
| simultaneously by several agents. After initializing its RapidIO master port |
| each agent waits for enumeration completion by the host for the configured wait |
| time period. If this wait time period expires before enumeration is completed, |
| an agent skips RapidIO discovery and continues with remaining kernel |
| initialization. |
| |
| 4.5 Adding New Enumeration/Discovery Method |
| ------------------------------------------- |
| |
| RapidIO subsystem code organization allows addition of new enumeration/discovery |
| methods as new configuration options without significant impact to the core |
| RapidIO code. |
| |
| A new enumeration/discovery method has to be attached to one or more mport |
| devices before an enumeration/discovery process can be started. Normally, |
| method's module initialization routine calls rio_register_scan() to attach |
| an enumerator to a specified mport device (or devices). The basic enumerator |
| implementation demonstrates this process. |
| |
| 4.6 Using Loadable RapidIO Switch Drivers |
| ----------------------------------------- |
| |
| In the case when RapidIO switch drivers are built as loadable modules a user |
| must ensure that they are loaded before the enumeration/discovery starts. |
| This process can be automated by specifying pre- or post- dependencies in the |
| RapidIO-specific modprobe configuration file as shown in the example below. |
| |
| File /etc/modprobe.d/rapidio.conf: |
| ---------------------------------- |
| |
| # Configure RapidIO subsystem modules |
| |
| # Set enumerator host destination ID (overrides kernel command line option) |
| options rapidio hdid=-1,2 |
| |
| # Load RapidIO switch drivers immediately after rapidio core module was loaded |
| softdep rapidio post: idt_gen2 idtcps tsi57x |
| |
| # OR : |
| |
| # Load RapidIO switch drivers just before rio-scan enumerator module is loaded |
| softdep rio-scan pre: idt_gen2 idtcps tsi57x |
| |
| -------------------------- |
| |
| NOTE: In the example above, one of "softdep" commands must be removed or |
| commented out to keep required module loading sequence. |
| |
| A. References |
| ------------- |
| |
| [1] RapidIO Trade Association. RapidIO Interconnect Specifications. |
| http://www.rapidio.org. |
| [2] Rapidio TA. Technology Comparisons. |
| http://www.rapidio.org/education/technology_comparisons/ |
| [3] RapidIO support for Linux. |
| http://lwn.net/Articles/139118/ |
| [4] Matt Porter. RapidIO for Linux. Ottawa Linux Symposium, 2005 |
| http://www.kernel.org/doc/ols/2005/ols2005v2-pages-43-56.pdf |