/* * GR1553B BC driver, Descriptor LIST handling * * COPYRIGHT (c) 2010. * Cobham Gaisler AB. * * The license and distribution terms for this file may be * found in the file LICENSE in this distribution or at * http://www.rtems.org/license/LICENSE. */ #ifndef __GR1553BC_LIST_H__ #define __GR1553BC_LIST_H__ /*!\file doc/gr1553bc_list.h * \brief GR1553B BC driver * * \section OVERVIEW * * The BC device driver can schedule synchronous and asynchronous lists * of descriptors. The list contains a descriptor table and a software * description to make some operations possible, for example translate * descriptor-address into descriptor-number. * * This is the LIST API. It provides functionality to create and manage * a BC descriptor list. * * A list is built up by the following build blocks: * - Major Frame (Consists of N Minor Frames) * - Minor Frame (Consists of up to 32 1553 Message Slots) * - Message Slot (Transfer/Condition BC descriptor) * * The user can configure lists with different configuration of number of * Major Frames, Minor Frame and messages slots within a Minor Frame. The * List manages a strait descriptor table (may be changed) and a Frame/Slot * tree in order to easily find it's way through all descriptor created. * * Each Minor frame consist of up to 32 message slot and 2 message slots * for time management and descriptor find operations. The list can manage * time slots per minor frame, for example a minor frame may be programmed * to take 8ms and when the user allocate a message slot within that Minor * frame the time spcified will be subtracted from the 8ms, and when the * message slot is freed the time will be returned to the Minor frame again. * * A Major, Minor and Message Slots are identified using a MID (Message-ID). * The MID is a way for the user to avoid using pointers are talk with the * list API in an easier way. For example a condition Slot that should jump * to a transfer slot can be created by knowing "MID and Jump-To-MID". When * allocating a Slot (with or without time) the user may specify a certain * Slot or a Minor frame, when a Minor frame is given then the API will find * a free Slot as early in the Minor Frame as possible and return it to the * user. * * A MID can be created using the macros: * GR1553BC_ID(major,minor,slot) - ID of a SLOT * GR1553BC_MINOR_ID(major,minor) - ID of a MINOR (Slot=0xff) * GR1553BC_MAJOR_ID(major) - ID of a Major (Minor=0xff,Slot=0xff) * * The typical approach create lists is in the following order: * -# gr1553bc_list_alloc(&list, MAJOR_CNT) * -# gr1553bc_list_config(list, &listcfg) * -# Create all Major Frames and Minor frame, for each major frame: * a) gr1553bc_major_alloc_skel(&major, &major_minor_cfg) * b) gr1553bc_list_set_major(list, &major, MAJOR_NUM) * -# link end Major Frames together: * a) gr1553bc_list_set_major(&major7, &major0) // Connect Major frames * -# gr1553bc_list_table_alloc() (Allocate Descriptor Table) * -# gr1553bc_list_table_build() (Build Descriptor Table from Majors/Minors) * -# Allocate and initialize Descriptors pre defined before starting: * -## gr1553bc_slot_alloc(list, &MID, TIME_REQUIRED, ..) * -## gr1553bc_slot_transfer(MID, ...) * -# START BC HARDWARE BY SHCDULING ABOVE LIST * -# Operate on List * * * \section bc_list_update Changing a scheduled BC list (during BC-runtime) * * One can use the INDICATION service to avoid modifying * a descriptor currently in use by the BC core. One can also in most cases * do descriptor initialization in three steps: Init Descriptor as Dummy * with and allocated time (often done before starting/scheduling list), * then modify transfer options and data-pointers, then clear the Dummy * bit in one atomic data store. This approach will avoid potential races * between software has hardware. * * * \section bc_memory_setup Custom Memory Setup * * For designs where dynamically memory is not an option, or the driver * is used on a AMBA-over-PCI bus (where malloc() does not work), the * API allows the user to provide custom addresses for descriptor table * and object descriptions (lists, major frames, minor frames). Custom * descriptor table is probably the most interesting thing for most, it * is setup with gr1553bc_list_table_alloc(list, CUSTOM_ADDRESS). * * Object descriptions are normally allocated during initialization * procedure by providing the API with a object configuration, for * example a Major Frame configuration enables the API to allocate * the software description of a Major Frame with all it's Minor frames. * * * \section major Major Frame * * Consists of multiple Minor frames. A Major frame may be connected/linked * with another Major frame, this will result in a Jump Slot from last * Minor frame in the first Major to the first Minor in the second Major. * * * \section minor Minor Frame * * Consists of up to 32 Message Slots. The services are Time-Management and * Slot allocation. * * Time-Management is optional. * * Time-Slot-Management can be enabled per Minor frame. A Minor frame can be * assigned a time in microseconds. The BC will not continue to the next * Minor frame until the time has passed. It is managed by adding an extra * Dummy Message Slot with the total minor frame time. Each time a message * Slot is allocated (with a certain time: Slot-Time) the Slot-Time will * be decremented from the total time of the Minor frame. This way the * sum of the Message Slot will always sum up to the total time of the * Minor configuration. When a message slot is freed, the Dymmy Message * Slot's Slot-Time is incremented with the freed Slot-Time. * * A Message Slot can be allocated by identifying a specific free Slot * by the MID (Message-ID) or by letting the API allocate the first free * Slot in the Minor Frame (Set MID Slot-ID to 0xff to identify Minor * Frame). * * * \section slot Message Slot * * The GR1553B BC core supports two Slot (Descriptor) Types: * - Transfer descriptor * - Condition descriptor (Jump, unconditional-IRQ) * * See the hardware manual for a detail description of a descriptor (Slot). * * The BC Core is unaware of lists, it steps through executing each * descriptor as the encountered, Conditionals resulting in jumps may * let us to create more complex arrangements of buffer descriptos (BDs) * which we call list. * * Transfer BDs (TBDs) may have a time slot assigned, the BC core will wait * until the time has expired before executing the next descriptor. Time * slots are handled by a Minor frame in the list. * * A Message Slot is allocated using the gr1553bc_slot_alloc() function, * and configured by calling one of the below functions: * - gr1553bc_slot_irq_prepare [unconditional IRQ slot] * - gr1553bc_slot_jump [unconditional jump] * - gr1553bc_slot_exttrig [Dummy transfer, wait for EXTERNAL-TRIGGER] * - gr1553bc_slot_transfer [Transfer descriptor] * - gr1553bc_slot_empty [Create Dummy Transfer descriptor] * - gr1553bc_slot_raw [Custom Descriptor handling] * * - gr1553bc_slot_dummy [Set existing Transfer descriptor to Dummy] * - gr1553bc_slot_update [Update DataPointer|Status of a TBD] * * * \section bc_IRQ Interrupt Handling * * There are different types of interrupts, Error IRQs or transfer IRQs. The * Error IRQs are handled by the driver can a callback function is called. * * Transfer Descriptors can be programmed to generate interrupt, and * condition descriptors can be programmed to generate interrupt * unconditionaly (there exists more conditional types). When a Transfer * descriptor causes IRQ the general ISR callback of the BC driver is * called to let the user handle the interrupt. When a condition descriptor * causes an IRQ a custom IRQ handler is called (if assigned). * * Transfers descriptor IRQ is enabled by configuring the descriptor. * * The API provides functions for placing unconditional IRQ points anywhere * in the list. The order: * -# gr1553bc_slot_alloc(&MID, TIME=0, ..) * -# gr1553bc_slot_irq_prepare(MID, funcISR, data) * -# gr1553bc_slot_irq_enable(MID) * * \verbatim * void funcISR(*bd, *data) * { * // HANDLE ONE OR MULTIPLE DESCRIPTORS (MULTIPLE IN THIS EXAMPLE): * int MID; * gr1553bc_mid_from_bd(bd,&MID,NULL); * printf("IRQ ON %06x\n", MID); * } * \endverbatim * * \ingroup GR1553BC */ #include #include /**** CONFIGURATION OPTIONS ****/ /* Define GR1553BC_TIMESLOT to make driver take care of time * management of minor frames. */ #define GR1553BC_TIMESLOT #define GR1553BC_MINOR_MAX 256 #define GR1553BC_SLOT_MAX 32 #ifdef __cplusplus extern "C" { #endif struct gr1553bc_list; struct gr1553bc_major; struct gr1553bc_minor; struct gr1553bc_minor_cfg; struct gr1553bc_major_cfg; struct gr1553bc_minor_cfg { int slot_cnt; int timeslot; /* Total time of minor frame in us */ }; struct gr1553bc_major_cfg { int minor_cnt; /* Number of Minor Frames */ struct gr1553bc_minor_cfg minor_cfgs[1]; }; struct gr1553bc_list_cfg { unsigned char rt_timeout[31]; /* Number of us timeout tolerance per RT */ unsigned char bc_timeout; /* Number of us timeout tolerance of * broadcast transfers */ int tropt_irq_on_err; /* Generate IRQ on transfer error */ int tropt_pause_on_err; /* Pause list on transfer error */ int async_list; /* Set to non-zero if asyncronous list*/ }; /* Default Configuration */ extern struct gr1553bc_list_cfg gr1553bc_def_cfg; /* Complete list of all major frames */ struct gr1553bc_list { void *_table_custom; /* Config option given by user */ void *_table; /* address of allocated bd-table */ unsigned int table_hw; /* Descriptor table base HW-ADR */ unsigned int table_cpu; /* Descriptor table base CPU-ADR */ int table_size; /* Descriptor Table Size */ void *bc; /* BC HW, needed for adr translation */ unsigned char rt_timeout[32]; /* Tolerance per RT, default 20us * Note: 31 is for Broadcast */ uint32_t tropts; /* Transfer descriptor options: * On transfer error the following bits * do affect: * - bit28 1=Generate IRQ * - bit26 1=Pause transfer list * */ int async_list; /* async list or not */ int major_cnt; /* Number of Major frames */ struct gr1553bc_major *majors[1]; /* Var-Array of Major Pointers*/ }; /* Alloc a List with a maximum number of Major frames supported */ extern int gr1553bc_list_alloc(struct gr1553bc_list **list, int max_major); /* Free List if allocated with gr1553bc_list_alloc() */ extern void gr1553bc_list_free(struct gr1553bc_list *list); /* Configure Global List parameters * * \param list List to be configured and initialized. * \param cfg List Configuration * \param bc The BC hardware device description * (only needed for address translation) */ extern int gr1553bc_list_config ( struct gr1553bc_list *list, struct gr1553bc_list_cfg *cfg, void *bc ); /* Link a 'major' Major frame with next major frame * The links affected: * - major->next * - major->minor[LAST]->next */ extern void gr1553bc_list_link_major( struct gr1553bc_major *major, struct gr1553bc_major *next ); /* Link in a Major frame into a BC list. * Calls gr1553bc_list_link_major() to link major frame with major-1 and * major+1. If ending or starting major frame the frame is wrapped around. */ extern int gr1553bc_list_set_major( struct gr1553bc_list *list, struct gr1553bc_major *major, int no); /* Calculate the size required in the descriptor table by one minor frame. */ extern int gr1553bc_minor_table_size(struct gr1553bc_minor *minor); /* Calculate the size required for the descriptor table. */ extern int gr1553bc_list_table_size(struct gr1553bc_list *list); /* Allocate an empty descriptor table from list description suitable for * the BC given by 'bc'. * * \param bdtab_custom Custom Descriptor Allocation options: * ZERO: Dynamically allocated by Driver (CPU near RAM) * Non-Zero: Use provided address as BASE of BD-TABLE * Non-Zero with LSB set: Same as Non-Zero but address * is given as HW address (used with AMBA-over-PCI to * to specify RAM location on PCI board). */ extern int gr1553bc_list_table_alloc ( struct gr1553bc_list *list, void *bdtab_custom ); /* Free descriptor table allocated with gr1553bc_list_table_alloc() */ extern void gr1553bc_list_table_free(struct gr1553bc_list *list); /* Build an empty descriptor table from list description, * the minor frames will be linked together. */ extern int gr1553bc_list_table_build(struct gr1553bc_list *list); /* Major Frame */ struct gr1553bc_major { struct gr1553bc_major *next; /* Next Major Frame */ struct gr1553bc_major_cfg *cfg; /* User Config of Major frame */ struct gr1553bc_minor *minors[1]; /* Minor frames */ }; /* Minor Frame */ struct gr1553bc_minor { struct gr1553bc_minor *next; /* Next Minor Frame */ struct gr1553bc_minor_cfg *cfg; /* User Config of Minor frame */ uint32_t alloc; /* Descripts allocated */ /* Note: THIS POINTER MUST BE ALIGNED ON A 128-bit BOUNDARY */ union gr1553bc_bd *bds; /* Descriptors for this minor frame (CPU ADRS)*/ }; /* Alloc a Major/Minor frame skeleton according to the configuration structure. * The descriptor table is not allocated. */ extern int gr1553bc_major_alloc_skel ( struct gr1553bc_major **major, struct gr1553bc_major_cfg *cfg ); /* Unique Message/Descriptor ID. Can be used to identify a Major or Minor * Frame, or a Slot. * * - If minor_num is 0xff, the ID identifies a Major Frame * - If slot_num is 0xff, the ID identifies a Minor Frame * - If non of the above is true, the ID identifies a specific Slot */ #define GR1553BC_ID(major_num, minor_num, slot_num) \ ((((major_num)<<16)&0xff0000) | (((minor_num)<<8)&0xff00) | \ ((slot_num) & 0xff)) #define GR1553BC_MINOR_ID(major_num, minor_num) \ GR1553BC_ID(major_num, minor_num, 0xff) #define GR1553BC_MAJOR_ID(major_num) \ GR1553BC_ID(major_num, 0xff, 0xff) #define GR1553BC_MAJID_FROM_ID(mid) (((mid) >> 16) & 0xff) #define GR1553BC_MINID_FROM_ID(mid) (((mid) >> 8) & 0xff) #define GR1553BC_SLOTID_FROM_ID(mid) ((mid) & 0xff) #define GR1553BC_ID_SET_SLOT(mid, slot_num) (((mid) & ~0xff) | ((slot_num) & 0xff)) extern struct gr1553bc_major *gr1553bc_major_from_id ( struct gr1553bc_list *list, int mid ); extern struct gr1553bc_minor *gr1553bc_minor_from_id ( struct gr1553bc_list *list, int mid ); /* Get free time left of minor frame identified by MID 'mid' */ extern int gr1553bc_list_freetime(struct gr1553bc_list *list, int mid); /* Get free time left of minor frame */ extern int gr1553bc_minor_freetime(struct gr1553bc_minor *minor); /* Allocate a time slot on a minor frame, major/minor frame is identified * by MID. The 'mid' is a input/ouput parameter, the resulting slot taken * will be placed in 'mid', a pointer to the allocated descriptor is stored * into bd. * * Major/Minor must be specified by MID, if slot is specified that slot will * be allocated, if slot is 0xff, then the first free slot is allocated. * * The function fails (return negative) if timeslot is longer than remaining * time in minor frame, if no more slots are available in minor frame, if * MID points to a bad major/minor or major/minor/slot. */ extern int gr1553bc_slot_alloc( struct gr1553bc_list *list, int *mid, int timeslot, union gr1553bc_bd **bd ); /* Same as gr1553bc_slot_alloc but identifies a minor instead of list. * The major/minor part of MID is ignored. */ extern int gr1553bc_slot_alloc2( struct gr1553bc_minor *minor, int *mid, int timeslot, union gr1553bc_bd **bd ); /* Free message slot and the time associated with it. The time taken by the * message slot is added to the END TIME descriptor, if managed by the driver * for this minor frame. The descriptor will be */ extern int gr1553bc_slot_free(struct gr1553bc_list *list, int mid); extern int gr1553bc_slot_free2(struct gr1553bc_minor *minor, int mid); /* Find MID from Descriptor pointer * * In the end of each minor frame is a unconditional jump * to next minor frame descriptor. The hardware does not * use the last 8 bytes of conditional descriptors, in the * padding area a MID is stored so that we can lookup the * MID of a descriptor. This function finds the jump * descriptor and subtracs the offset from it. * * A faster way of looking up can be implemented if the * list is symertical, however in the current setup we * allow different numbers of slots in minor frames, and * different number of minor frames in a major frame. * * \param bd IN: Descriptor to lookup MID of (CPU address of BD) * \param mid OUT: Pointer to where Message-ID (Slot-ID) will be stored * \param async OUT: Function will store non-zero value if BD belogs to * async list. */ extern int gr1553bc_mid_from_bd( union gr1553bc_bd *bd, int *mid, int *async ); /********** TRANSFER DESCRIPTOR MANIPULATION **********/ /* Get pointer to descriptor entry from MID. */ extern union gr1553bc_bd *gr1553bc_slot_bd ( struct gr1553bc_list *list, int mid ); /* IRQ function */ typedef void (*bcirq_func_t)(union gr1553bc_bd *bd, void *data); /* Create unconditional IRQ customly defined location. * The IRQ is disabled, enable it with gr1553bc_slot_irq_enable(). */ extern int gr1553bc_slot_irq_prepare ( struct gr1553bc_list *list, int mid, bcirq_func_t func, void *data ); /* Enable previously prepared unconditional IRQ */ extern int gr1553bc_slot_irq_enable(struct gr1553bc_list *list, int mid); /* Disable unconditional IRQ point, changed to unconditional JUMP * to descriptor following. * After disabling it it can be enabled again, or freed. */ extern int gr1553bc_slot_irq_disable(struct gr1553bc_list *list, int mid); /* Create custom jump to descriptor, conditional or unconditional, see * hardware manual for conditions. * * set conditional to GR1553BC_UNCOND_JMP for unconditional jump. */ extern int gr1553bc_slot_jump ( struct gr1553bc_list *list, int mid, uint32_t condition, int to_mid ); /* Create a dummy transfer, paused until external trigger is set. The * Slot is will have the dummy bit set, no transfer will take place. */ extern int gr1553bc_slot_exttrig(struct gr1553bc_list *list, int mid); /* Create a transfer on a previous allocated descriptor. It is assumed * that the descriptor has been initialized empty before calling this * function, this is to avoid races. * * The settings that are controlled on a global level (and not * by this function): * - IRQ after transfer error * - IRQ after transfer (not supported, insert separate IRQ slot after this) * - Pause schedule after transfer error * - Pause schedule after transfer (not supported) * - slot time optional (set when MID allocated), otherwise 0 * - (OPTIONAL) Dummy Bit, set using slot_empty() or ..._TT_DUMMY * - RT timeout tolerance (managed per RT) * * Input Parameters: * - Retry Mode (options) * - Number of retires (options) * - Bus selection (A or B) (options) * - dummy bit (options) * - transfer type (tt) * - rt src/dst address (tt) * - RT subaddress (tt) * - word count (tt) * - mode code (tt) * - data pointer (dptr) * * * See macros defined in this header file for creating transfer types (tt) * and word count etc. * * See macros defined in this header file for creating the mask of options. * * Note that if bit0 (LSB) of dptr is set, then the address is translated into * hardware address, otherwise the dptr is assumed to be accessible from the * 1553 core. This is an option only for AMBA-over-PCI. */ extern int gr1553bc_slot_transfer( struct gr1553bc_list *list, int mid, int options, int tt, uint16_t *dptr); /* Remove or set dummy bit of a transfer descriptor * Bit31 of *dummy is written to the dummy bit, the * old descriptor value is stored into *dummy. */ extern int gr1553bc_slot_dummy( struct gr1553bc_list *list, int mid, unsigned int *dummy); /* Make a slot empty (BC will not generate bus transfers), time slot * allocated is untouched (if assigned). */ extern int gr1553bc_slot_empty(struct gr1553bc_list *list, int mid); /* Transfer descriptor status and/or update Transfer descriptor data pointer. * * Read and/or write Status of a slot. Writing the status word may be * used by software to indicate that result has been handled, or bit 31 * may be written 1 telling software that when it reaches 0, then BC * has executed the request. * * Operation: * bd->status = *stat & (bd->status 0xffffff) | (*stat & 0x80000000); * *stat = Value of bd->status before rewrite. * * Note that the status word is not written when *stat is zero. * * Note that if bit0 (LSB) of dptr is set, then the address is translated into * hardware address, otherwise the dptr is assumed to be accessible from the * 1553 core. This is an option only for AMBA-over-PCI. */ extern int gr1553bc_slot_update( struct gr1553bc_list *list, int mid, uint16_t *dptr, unsigned int *stat); /* Modify a transfer descriptor in any way, * * flags: * bit[N=0..3]: 1 = set BD wordN according to argument wordN, * 0 = do not modify BD wordN */ extern int gr1553bc_slot_raw ( struct gr1553bc_list *list, int mid, unsigned int flags, uint32_t word0, uint32_t word1, uint32_t word2, uint32_t word3 ); /***** Macros to create BC Transfer Types (tt) for gr1553bc_slot_transfer() *****/ /* WRITE TO RT (BC-to-RT) */ #define GR1553BC_BC2RT(rtadr, subadr, word_count) \ ((rtadr<<11) | (subadr<<5) | (0x1f<<21) | (0<<10) | \ ((word_count>=32) ? 0 : word_count)) /* READ FROM RT (RT-to-BC) */ #define GR1553BC_RT2BC(rtadr, subadr, word_count) \ ((rtadr<<11) | (subadr<<5) | (0x1f<<21) | (1<<10) | \ ((word_count>=32) ? 0 : word_count)) /* RT(TX) WRITE TO RT(RX) (RT-to-RT) */ #define GR1553BC_RT2RT(tx_rtadr, tx_subadr, rx_rtadr, rx_subadr, word_count) \ ((rx_rtadr<<11) | (rx_subadr<<5) | \ (tx_rtadr<<21) | (tx_subadr<<16) | \ (0<<10) | \ ((word_count>=32) ? 0 : word_count)) /* Mode command without data. (BC-to-RT) * Mode code: 0,1,2,3,4,5,6,7 or 8. */ #define GR1553BC_MC_NODATA(rtadr, modecode) \ ((rtadr<<11) | (0x1f<<5) | (0x1f<<21) | \ (modecode<<0) | (1<<10)) /* Mode command with 4 byte data (RT-to-BC) * Mode code: 16, 18 or 19. */ #define GR1553BC_MC_RT2BC(rtadr, modecode) \ ((rtadr<<11) | (0x1f<<5) | (0x1f<<21) | \ (modecode<<0) | (1<<10)) /* Mode command with 4 byte data (BC-to-RT) * Mode code: 17, 20 or 21. */ #define GR1553BC_MC_BC2RT(rtadr, modecode) \ ((rtadr<<11) | (0x1f<<5) | (0x1f<<21) | \ (modecode<<0) | (0<<10)) /* Broadcast to all RTs, to a specific subaddress (BC-to-RTs) */ #define GR1553BC_BC_BC2RT(subadr, word_count) \ ((0x1f<<11) | (subadr<<5) | (0x1f<<21) | \ (0<<10) | \ ((word_count>=32) ? 0 : word_count)) /* Request RT to broadcast to all RTs, to a specific subaddress (RT-to-RTs) */ #define GR1553BC_BC_RT2RT(tx_rtadr, tx_subadr, rx_subadr, word_count) \ ((0x1f<<11) | (rx_subadr<<5) | \ (tx_rtadr<<21) | (tx_subadr<<16) | \ (0<<10) | \ ((word_count>=32) ? 0 : word_count)) /* Broadcast mode command without data (BC-to-RTs) * Mode code: 1,3,4,5,6,7 or 8 */ #define GR1553BC_BC_MC_NODATA(modecode) \ ((0x1f<<11) | (0x1f<<5) | (0x1f<<21) | \ ((modecode)<<0) | (1<<10)) /* Broadcast mode command with 4 byte data (BC-to-RTs) * Mode code: 17, 20 or 21 */ #define GR1553BC_BC_MC_BC2RT(modecode) \ ((0x1f<<11) | (0x1f<<5) | (0x1f<<21) | \ ((modecode)<<0) | (0<<10)) /***** Macros to create BC options (options) for gr1553bc_slot_transfer() *****/ /* Dummy (BC does no bus trasactions) */ #define GR1553BC_OPT_DUMMY (1<<1) /* Retry modes */ #define GR1553BC_RETRY_SAME 0x0 /* Retry on the same bus only */ #define GR1553BC_RETRY_ALTER 0x1 /* Retry alternating on both busses */ #define GR1553BC_RETRY_ATTEMPT 0x2 /* Many attepts first on original * bus then on other bus */ /* Number of retires supported */ #define GR1553BC_RETRY_CNT_MAX 6 /* Dummy bit: No transfer * Bus bit: 0=A, 1=B * Exttrig bit: Wait for external trigger (used for timesync) * Exclusive bit: 1=Don't allow other messages in this time slot. */ #define GR1553BC_OPTIONS(dummy, exttrig, exclusive, retrymode, nretry, bus) \ ((((exttrig) & 0x1) << 30) | (((exclusive) & 0x1) << 29) | \ ((retrymode) << 23) | ((nretry) << 20) | \ ((bus) & 1) | (((dummy) & 0x1) << 1)) #define GR1553BC_OPTIONS_BUSA GR1553BC_OPTIONS(0,0,0,GR1553BC_RETRY_SAME,0,0) #define GR1553BC_OPTIONS_BUSB GR1553BC_OPTIONS(0,0,0,GR1553BC_RETRY_SAME,0,1) #define GR1553BC_OPTIONS_BUSA_DUM GR1553BC_OPTIONS(1,0,0,GR1553BC_RETRY_SAME,0,0) #define GR1553BC_OPTIONS_BUSB_DUM GR1553BC_OPTIONS(1,0,0,GR1553BC_RETRY_SAME,0,1) /* Show parts of a list - this is for debugging only */ extern void gr1553bc_show_list(struct gr1553bc_list *list, int options); #ifdef __cplusplus } #endif #endif /* __GR1553BC_LIST_H__ */