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[/] [openrisc/] [trunk/] [rtos/] [rtems/] [c/] [src/] [lib/] [libbsp/] [shmdr/] [shm_driver.h] - Rev 562
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/* shm_driver.h * * This include file contains all the constants, structures, * and global variables for this RTEMS based shared memory * communications interface driver. * * Processor board dependencies are in other files. * * COPYRIGHT (c) 1989-1999. * On-Line Applications Research Corporation (OAR). * * The license and distribution terms for this file may be * found in the file LICENSE in this distribution or at * http://www.OARcorp.com/rtems/license.html. * * $Id: shm_driver.h,v 1.2 2001-09-27 12:01:13 chris Exp $ */ #ifndef __SHM_h #define __SHM_h #include <clockdrv.h> #ifdef __cplusplus extern "C" { #endif /* The information contained in the Node Status, Locked Queue, and * Envelope Control Blocks must be maintained in a NEUTRAL format. * Currently the neutral format may be selected as big or little * endian by simply defining either NEUTRAL_BIG or NEUTRAL_LITTLE. * * It is CRITICAL to note that the neutral format can ONLY be * changed by modifying this file and recompiling the ENTIRE * SHM driver including ALL target specific support files. * * The following table details the memory contents for the endian * field of the Node Status Control Block in the various * data format configurations (data is in hexadecimal): * * NEUTRAL NATIVE BYTE 0 BYTE 1 BYTE 2 BYTE 3 * ======= ====== ====== ====== ====== ====== * BIG BIG 00 00 00 01 * BIG LITTLE 10 00 00 00 * LITTLE BIG 01 00 00 00 * LITTLE LITTLE 00 00 00 10 * * * NOTE: XXX * PORTABILITY OF LOCKING INSTRUCTIONS * =================================== * The locking mechanism described below is not * general enough. Where the hardware supports * it we should use "atomic swap" instructions * so the values in the lock can be tailored to * support a CPU with only weak atomic memory * instructions. There are combinations of * CPUs with inflexible atomic memory instructions * which appear to be incompatible. For example, * the SPARClite instruction uses a byte which is * 0xFF when locked. The PA-RISC uses 1 to indicate * locked and 0 when unlocked. These CPUs appear to * have incompatible lock instructions. But * they could be used in a heterogenous system * with does not mix SPARCs and PA-RISCs. For * example, the i386 and SPARC or i386 and SPARC * could work together. The bottom line is that * not every CPU will work together using this * locking scheme. There are supposed to be * algorithms to do this without hardware assist * and one of these should be incorporated into * the shared memory driver. * * The most flexible scheme using the instructions * of the various CPUs for efficiency would be to use * "atomic swaps" wherever possible. Make the lock * and unlock configurable much like BIG vs LITTLE * endian use of shared memory is now. The values * of the lock could then reflect the "worst" * CPU in a system. This still results in mixes * of CPUs which are incompatible. * * The current locking mechanism is based upon the MC68020 * "tas" instruction which is atomic. All ports to other CPUs * comply with the restrictive placement of lock bit by this * instruction. The lock bit is the most significant bit in a * big-endian rtems_unsigned32. On other processors, the lock is * typically implemented via an atomic swap or atomic modify * bits type instruction. */ #define NEUTRAL_BIG #ifdef NEUTRAL_BIG #define SHM_BIG 0x00000001 #define SHM_LITTLE 0x10000000 #endif #ifdef NEUTRAL_LITTLE #define SHM_BIG 0x01000000 #define SHM_LITTLE 0x00000010 #endif /* * The following are the values used to fill in the lock field. Some CPUs * are able to write only a single value into field. By making the * lock and unlock values configurable, CPUs which support "atomic swap" * instructions can generally be made to work in any heterogeneous * configuration. However, it is possible for two CPUs to be incompatible * in regards to the lock field values. This occurs when two CPUs * which write only a single value to the field are used in a system * but the two CPUs write different incompatible values. * * NOTE: The following is a first attempt at defining values which * have a chance at working together. The m68k should use * chk2 instead of tas to be less restrictive. Target endian * problems (like the Force CPU386 which has (broken) big endian * view of the VMEbus address space) are not addressed yet. */ #if defined(__i960__) #define SHM_LOCK_VALUE 0x00000080 #define SHM_UNLOCK_VALUE 0 #elif defined(__mc68000__) #define SHM_LOCK_VALUE 0x80000000 #define SHM_UNLOCK_VALUE 0 #define SHM_LOCK_VALUE 0x80000000 #define SHM_UNLOCK_VALUE 0 #elif defined(__i386__) #define SHM_LOCK_VALUE 0x80000000 #define SHM_UNLOCK_VALUE 0 #elif defined(__mips__) #define SHM_LOCK_VALUE 0x80000000 #define SHM_UNLOCK_VALUE 0 #elif defined(__hppa__) #define SHM_LOCK_VALUE 0 #define SHM_UNLOCK_VALUE 1 #elif defined(__PPC__) #define SHM_LOCK_VALUE 1 #define SHM_UNLOCK_VALUE 0 #elif defined(__unix__) #define SHM_LOCK_VALUE 0 #define SHM_UNLOCK_VALUE 1 #elif defined(no_cpu) /* for this values are irrelevant */ #define SHM_LOCK_VALUE 1 #define SHM_UNLOCK_VALUE 0 #else #error "shm_driver.h - no SHM_LOCK_VALUE defined for this CPU architecture" #endif #define Shm_Convert( value ) \ ((Shm_Configuration->convert) ? \ (*Shm_Configuration->convert)(value) : (value)) /* constants */ #define SHM_MASTER 1 /* master initialization node */ #define SHM_FIRST_NODE 1 /* size constants */ #define KILOBYTE (1024) #define MEGABYTE (1024*1024) /* inter-node interrupt values */ #define NO_INTERRUPT 0 /* used for polled nodes */ #define BYTE 1 #define WORD 2 #define LONG 4 /* operational mode constants -- used in SHM Configuration Table */ #define POLLED_MODE 0 #define INTR_MODE 1 /* error codes */ #define NO_ERROR 0 #define SHM_NO_FREE_PKTS 0xf0000 /* null pointers of different types */ #define NULL_ENV_CB ((Shm_Envelope_control *) 0) #define NULL_CONVERT 0 /* * size of stuff before preamble in envelope. * It must be a constant since we will use it to generate MAX_PACKET_SIZE */ #define SHM_ENVELOPE_PREFIX_OVERHEAD (4 * sizeof(vol_u32)) /* * The following is adjusted so envelopes are MAX_ENVELOPE_SIZE bytes long. * It must be >= RTEMS_MINIMUM_PACKET_SIZE in mppkt.h. */ #ifndef MAX_ENVELOPE_SIZE #define MAX_ENVELOPE_SIZE 0x180 #endif #define MAX_PACKET_SIZE (MAX_ENVELOPE_SIZE - \ SHM_ENVELOPE_PREFIX_OVERHEAD + \ sizeof(Shm_Envelope_preamble) + \ sizeof(Shm_Envelope_postamble)) /* constants pertinent to Locked Queue routines */ #define LQ_UNLOCKED SHM_UNLOCK_VALUE #define LQ_LOCKED SHM_LOCK_VALUE /* constants related to the Free Envelope Pool */ #define FREE_ENV_POOL 0 #define FREE_ENV_CB (&Shm_Locked_queues[ FREE_ENV_POOL ]) /* The following are important when dealing with * the shared memory communications interface area. * * NOTE: The starting address and length of the shared memory * is defined in a system dependent file. */ #define START_NS_CBS ((void *)Shm_Configuration->base) #define START_LQ_CBS ((START_NS_CBS) + \ ( (sizeof (Shm_Node_status_control)) * (Shm_Maximum_nodes + 1) ) ) #define START_ENVELOPES ( ((void *) START_LQ_CBS) + \ ( (sizeof (Shm_Locked_queue_Control)) * (Shm_Maximum_nodes + 1) ) ) #define END_SHMCI_AREA ( (void *) START_ENVELOPES + \ ( (sizeof (Shm_Envelope_control)) * Shm_Maximum_envelopes ) ) #define END_SHARED_MEM (START_NS_CBS+Shm_Configuration->length) /* macros */ #define Shm_Is_master_node() \ ( SHM_MASTER == Shm_Local_node ) #define Shm_Free_envelope( ecb ) \ Shm_Locked_queue_Add( FREE_ENV_CB, (ecb) ) #define Shm_Allocate_envelope() \ Shm_Locked_queue_Get(FREE_ENV_CB) #define Shm_Initialize_receive_queue(node) \ Shm_Locked_queue_Initialize( &Shm_Locked_queues[node], node ) #define Shm_Append_to_receive_queue(node, ecb) \ Shm_Locked_queue_Add( &Shm_Locked_queues[node], (ecb) ) #define Shm_Envelope_control_to_packet_prefix_pointer(ecb) \ ((void *)(ecb)->packet) #define Shm_Packet_prefix_to_envelope_control_pointer( pkt ) \ ((Shm_Envelope_control *)((rtems_unsigned8 *)(pkt) - \ (sizeof(Shm_Envelope_preamble) + SHM_ENVELOPE_PREFIX_OVERHEAD))) #define Shm_Build_preamble(ecb, node) \ (ecb)->Preamble.endian = Shm_Configuration->format #define Shm_Build_postamble( ecb ) /* volatile types */ typedef volatile rtems_unsigned8 vol_u8; typedef volatile rtems_unsigned32 vol_u32; /* shm control information */ struct shm_info { vol_u32 not_currently_used_0; vol_u32 not_currently_used_1; vol_u32 not_currently_used_2; vol_u32 not_currently_used_3; }; typedef struct { /*byte start_of_text;*/ vol_u32 endian; vol_u32 not_currently_used_0; vol_u32 not_currently_used_1; vol_u32 not_currently_used_2; } Shm_Envelope_preamble; typedef struct { } Shm_Envelope_postamble; /* WARNING! If you change this structure, don't forget to change * SHM_ENVELOPE_PREFIX_OVERHEAD and * Shm_Packet_prefix_to_envelope_control_pointer() above. */ /* This comment block describes the contents of each field * of the Envelope Control Block: * * next - The index of the next envelope on this queue. * queue - The index of the queue this envelope is on. * index - The index of this envelope. * Preamble - Generic packet preamble. One day this structure * could be enhanced to contain routing information. * packet - RTEMS MPCI packet. Untouched by SHM Driver * other than copying and format conversion as * documented in the RTEMS User's Guide. * Postamble - Generic packet postamble. One day this structure * could be enhanced to contain checksum information. */ typedef struct { vol_u32 next; /* next envelope on queue */ vol_u32 queue; /* queue on which this resides */ vol_u32 index; /* index into array of envelopes*/ vol_u32 pad0; /* insure the next one is aligned */ Shm_Envelope_preamble Preamble; /* header information */ vol_u8 packet[MAX_PACKET_SIZE]; /* RTEMS INFO */ Shm_Envelope_postamble Postamble;/* trailer information */ } Shm_Envelope_control; /* This comment block describes the contents of each field * of the Locked Queue Control Block: * * lock - Lock used to insure mutually exclusive access. * front - Index of first envelope on queue. This field * is used to remove head of queue (receive). * rear - Index of last envelope on queue. This field * is used to add evelope to queue (send). * owner - The node number of the recipient (owning) node. * RTEMS does not use the node number zero (0). * The zero node is used by the SHM Driver for the * Free Envelope Queue shared by all nodes. */ typedef struct { vol_u32 lock; /* lock field for this queue */ vol_u32 front; /* first envelope on queue */ vol_u32 rear; /* last envelope on queue */ vol_u32 owner; /* receiving (i.e. owning) node */ } Shm_Locked_queue_Control; /* This comment block describes the contents of each field * of the Node Status Control Block: * * status - Node status. Current values are Pending Initialization, * Initialization Complete, and Active Node. Other values * could be added to enhance fault tolerance. * error - Zero if the node has not failed. Otherwise, * this field contains a status indicating the * failure reason. * int_address, int_value, and int_length * - These field are the Interrupt Information table * for this node in neutral format. This is how * each node knows how to generate interrupts. */ typedef struct { vol_u32 status; /* node status information */ vol_u32 error; /* fatal error code */ vol_u32 int_address; /* write here for interrupt */ vol_u32 int_value; /* this value causes interrupt */ vol_u32 int_length; /* for this length (0,1,2,4) */ vol_u32 not_currently_used_0; vol_u32 not_currently_used_1; vol_u32 not_currently_used_2; } Shm_Node_status_control; /* This comment block describes the contents of each field * of the Interrupt Information Table. This table describes * how another node can generate an interrupt to this node. * This information is target board dependent. If the * SHM Driver is in POLLED_MODE, then all fields should * be initialized to NO_INTERRUPT. * * address - The address to which another node should * write to cause an interrupt. * value - The value which must be written * length - The size of the value to write. Valid * values are BYTE, WORD, and LONG. * * NOTE: The Node Status Control Block contains this * information in neutral format and not in a * structure to avoid potential alignment problems. */ typedef struct { vol_u32 *address; /* write here for interrupt */ vol_u32 value; /* this value causes interrupt */ vol_u32 length; /* for this length (0,1,2,4) */ } Shm_Interrupt_information; /* SHM Configuration Table * * This comment block describes the contents of each field * of the SHM Configuration Table. * * base - The base address of the shared memory. This * address may be specific to this node. * length - The length of the shared memory in bytes. * format - The natural format for rtems_unsigned32's in the * shared memory. Valid values are currently * only SHM_LITTLE and SHM_BIG. * convert - The address of the routine which converts * between neutral and local format. * poll_intr - The operational mode of the driver. Some * target boards may not provide hardware for * an interprocessor interrupt. If POLLED_MODE * is selected, the SHM driver will install a * wrapper around the Clock_isr() to poll for * incoming packets. Throughput is dependent * on the time between clock interrupts. * Valid values are POLLED_MODE and INTR_MODE. * cause_intr - This is the address of the routine used to * write to a particular address and cause an * interrupt on another node. This routine * may need to be target dependent if something * other than a normal write from C does not work. * Intr - This structure describes the operation required * to cause an interrupt to this node. The actual * contents of this structure are described above. */ struct shm_config_info { vol_u32 *base; /* base address of SHM */ vol_u32 length; /* length (in bytes) of SHM */ vol_u32 format; /* SHM is big or little endian */ vol_u32 (*convert)();/* neutral conversion routine */ vol_u32 poll_intr;/* POLLED or INTR driven mode */ void (*cause_intr)( rtems_unsigned32 ); Shm_Interrupt_information Intr; /* cause intr information */ }; typedef struct shm_config_info shm_config_table; /* global variables */ #ifdef _SHM_INIT #define SHM_EXTERN #else #define SHM_EXTERN extern #endif SHM_EXTERN shm_config_table *Shm_Configuration; SHM_EXTERN Shm_Interrupt_information *Shm_Interrupt_table; SHM_EXTERN Shm_Node_status_control *Shm_Node_statuses; SHM_EXTERN Shm_Locked_queue_Control *Shm_Locked_queues; SHM_EXTERN Shm_Envelope_control *Shm_Envelopes; SHM_EXTERN rtems_configuration_table *Shm_RTEMS_Configuration; SHM_EXTERN rtems_multiprocessing_table *Shm_RTEMS_MP_Configuration; SHM_EXTERN rtems_unsigned32 Shm_Receive_message_count; SHM_EXTERN rtems_unsigned32 Shm_Null_message_count; SHM_EXTERN rtems_unsigned32 Shm_Interrupt_count; SHM_EXTERN rtems_unsigned32 Shm_Local_node; SHM_EXTERN Shm_Locked_queue_Control *Shm_Local_receive_queue; SHM_EXTERN Shm_Node_status_control *Shm_Local_node_status; SHM_EXTERN rtems_unsigned32 Shm_isrstat; /* reported by shmdr */ SHM_EXTERN rtems_unsigned32 Shm_Pending_initialization; SHM_EXTERN rtems_unsigned32 Shm_Initialization_complete; SHM_EXTERN rtems_unsigned32 Shm_Active_node; SHM_EXTERN rtems_unsigned32 Shm_Maximum_nodes; SHM_EXTERN rtems_unsigned32 Shm_Maximum_envelopes; SHM_EXTERN rtems_unsigned32 Shm_Locked_queue_End_of_list; SHM_EXTERN rtems_unsigned32 Shm_Locked_queue_Not_on_list; /* functions */ /* locked queue routines */ void Shm_Locked_queue_Add( Shm_Locked_queue_Control *, Shm_Envelope_control * ); Shm_Envelope_control *Shm_Locked_queue_Get( Shm_Locked_queue_Control * ); void Shm_Locked_queue_Initialize( Shm_Locked_queue_Control *, rtems_unsigned32 ); /* Shm_Initialize_lock is CPU dependent */ /* Shm_Lock is CPU dependent */ /* Shm_Unlock is CPU dependent */ /* portable routines */ void Init_env_pool(); void Shm_Print_statistics( void ); void MPCI_Fatal( Internal_errors_Source, boolean, rtems_unsigned32 ); rtems_task Shm_Cause_interrupt( rtems_unsigned32 ); void Shm_Poll(); void Shm_setclockvec(); void Shm_Convert_packet( rtems_packet_prefix * ); /* CPU specific routines are inlined in shmcpu.h */ /* target specific routines */ void *Shm_Convert_address( void * ); void Shm_Get_configuration( rtems_unsigned32, shm_config_table ** ); void Shm_isr(); void Shm_setvec( void ); void Shm_Initialize_lock( Shm_Locked_queue_Control * ); void Shm_Lock( Shm_Locked_queue_Control * ); void Shm_Unlock( Shm_Locked_queue_Control * ); /* MPCI entry points */ rtems_mpci_entry Shm_Get_packet( rtems_packet_prefix ** ); rtems_mpci_entry Shm_Initialization( void ); rtems_mpci_entry Shm_Receive_packet( rtems_packet_prefix ** ); rtems_mpci_entry Shm_Return_packet( rtems_packet_prefix * ); rtems_mpci_entry Shm_Send_packet( rtems_unsigned32, rtems_packet_prefix * ); extern rtems_mpci_table MPCI_table; #ifdef _SHM_INIT /* multiprocessor communications interface (MPCI) table */ rtems_mpci_table MPCI_table = { 100000, /* default timeout value in ticks */ MAX_PACKET_SIZE, /* maximum packet size */ Shm_Initialization, /* initialization procedure */ Shm_Get_packet, /* get packet procedure */ Shm_Return_packet, /* return packet procedure */ Shm_Send_packet, /* packet send procedure */ Shm_Receive_packet /* packet receive procedure */ }; #endif #ifdef __cplusplus } #endif #endif /* end of include file */
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