/* $Id: pcibr_private.h,v 1.1.1.1 2003/06/23 22:18:40 jharrell Exp $ * * This file is subject to the terms and conditions of the GNU General Public * License. See the file "COPYING" in the main directory of this archive * for more details. * * Copyright (C) 1992 - 1997, 2000 Silicon Graphics, Inc. * Copyright (C) 2000 by Colin Ngam */ #ifndef _ASM_SN_PCI_PCIBR_PRIVATE_H #define _ASM_SN_PCI_PCIBR_PRIVATE_H /* * pcibr_private.h -- private definitions for pcibr * only the pcibr driver (and its closest friends) * should ever peek into this file. */ #include #include /* * convenience typedefs */ typedef uint64_t pcibr_DMattr_t; typedef uint32_t pcibr_ATEattr_t; typedef struct pcibr_info_s *pcibr_info_t, **pcibr_info_h; typedef struct pcibr_soft_s *pcibr_soft_t; typedef struct pcibr_soft_slot_s *pcibr_soft_slot_t; typedef struct pcibr_hints_s *pcibr_hints_t; typedef struct pcibr_intr_list_s *pcibr_intr_list_t; typedef struct pcibr_intr_wrap_s *pcibr_intr_wrap_t; typedef struct pcibr_intr_cbuf_s *pcibr_intr_cbuf_t; /* * Bridge sets up PIO using this information. */ struct pcibr_piomap_s { struct pciio_piomap_s bp_pp; /* generic stuff */ #define bp_flags bp_pp.pp_flags /* PCIBR_PIOMAP flags */ #define bp_dev bp_pp.pp_dev /* associated pci card */ #define bp_slot bp_pp.pp_slot /* which slot the card is in */ #define bp_space bp_pp.pp_space /* which address space */ #define bp_pciaddr bp_pp.pp_pciaddr /* starting offset of mapping */ #define bp_mapsz bp_pp.pp_mapsz /* size of this mapping */ #define bp_kvaddr bp_pp.pp_kvaddr /* kernel virtual address to use */ iopaddr_t bp_xtalk_addr; /* corresponding xtalk address */ xtalk_piomap_t bp_xtalk_pio; /* corresponding xtalk resource */ pcibr_piomap_t bp_next; /* Next piomap on the list */ pcibr_soft_t bp_soft; /* backpointer to bridge soft data */ atomic_t bp_toc[1]; /* PCI timeout counter */ }; /* * Bridge sets up DMA using this information. */ struct pcibr_dmamap_s { struct pciio_dmamap_s bd_pd; #define bd_flags bd_pd.pd_flags /* PCIBR_DMAMAP flags */ #define bd_dev bd_pd.pd_dev /* associated pci card */ #define bd_slot bd_pd.pd_slot /* which slot the card is in */ struct pcibr_soft_s *bd_soft; /* pcibr soft state backptr */ xtalk_dmamap_t bd_xtalk; /* associated xtalk resources */ size_t bd_max_size; /* maximum size of mapping */ xwidgetnum_t bd_xio_port; /* target XIO port */ iopaddr_t bd_xio_addr; /* target XIO address */ iopaddr_t bd_pci_addr; /* via PCI address */ int bd_ate_index; /* Address Translation Entry Index */ int bd_ate_count; /* number of ATE's allocated */ bridge_ate_p bd_ate_ptr; /* where to write first ATE */ bridge_ate_t bd_ate_proto; /* prototype ATE (for xioaddr=0) */ bridge_ate_t bd_ate_prime; /* value of 1st ATE written */ }; #define IBUFSIZE 5 /* size of circular buffer (holds 4) */ /* * Circular buffer used for interrupt processing */ struct pcibr_intr_cbuf_s { spinlock_t ib_lock; /* cbuf 'put' lock */ int ib_in; /* index of next free entry */ int ib_out; /* index of next full entry */ pcibr_intr_wrap_t ib_cbuf[IBUFSIZE]; /* circular buffer of wrap */ }; /* * Bridge sets up interrupts using this information. */ struct pcibr_intr_s { struct pciio_intr_s bi_pi; #define bi_flags bi_pi.pi_flags /* PCIBR_INTR flags */ #define bi_dev bi_pi.pi_dev /* associated pci card */ #define bi_lines bi_pi.pi_lines /* which PCI interrupt line(s) */ #define bi_func bi_pi.pi_func /* handler function (when connected) */ #define bi_arg bi_pi.pi_arg /* handler parameter (when connected) */ #define bi_tinfo bi_pi.pi_tinfo /* Thread info (when connected) */ #define bi_mustruncpu bi_pi.pi_mustruncpu /* Where we must run. */ #define bi_irq bi_pi.pi_irq /* IRQ assigned. */ #define bi_cpu bi_pi.pi_cpu /* cpu assigned. */ unsigned bi_ibits; /* which Bridge interrupt bit(s) */ pcibr_soft_t bi_soft; /* shortcut to soft info */ struct pcibr_intr_cbuf_s bi_ibuf; /* circular buffer of wrap ptrs */ }; /* * per-connect point pcibr data, including * standard pciio data in-line: */ struct pcibr_info_s { struct pciio_info_s f_c; /* MUST BE FIRST. */ #define f_vertex f_c.c_vertex /* back pointer to vertex */ #define f_bus f_c.c_bus /* which bus the card is in */ #define f_slot f_c.c_slot /* which slot the card is in */ #define f_func f_c.c_func /* which func (on multi-func cards) */ #define f_vendor f_c.c_vendor /* PCI card "vendor" code */ #define f_device f_c.c_device /* PCI card "device" code */ #define f_master f_c.c_master /* PCI bus provider */ #define f_mfast f_c.c_mfast /* cached fastinfo from c_master */ #define f_pops f_c.c_pops /* cached provider from c_master */ #define f_efunc f_c.c_efunc /* error handling function */ #define f_einfo f_c.c_einfo /* first parameter for efunc */ #define f_window f_c.c_window /* state of BASE regs */ #define f_rbase f_c.c_rbase /* expansion rom base */ #define f_rsize f_c.c_rsize /* expansion rom size */ #define f_piospace f_c.c_piospace /* additional I/O spaces allocated */ /* pcibr-specific connection state */ int f_ibit[4]; /* Bridge bit for each INTx */ pcibr_piomap_t f_piomap; int f_att_det_error; }; /* ===================================================================== * Shared Interrupt Information */ struct pcibr_intr_list_s { pcibr_intr_list_t il_next; pcibr_intr_t il_intr; volatile bridgereg_t *il_wrbf; /* ptr to b_wr_req_buf[] */ }; /* ===================================================================== * Interrupt Wrapper Data */ struct pcibr_intr_wrap_s { pcibr_soft_t iw_soft; /* which bridge */ volatile bridgereg_t *iw_stat; /* ptr to b_int_status */ bridgereg_t iw_intr; /* bit in b_int_status */ pcibr_intr_list_t iw_list; /* ghostbusters! */ int iw_hdlrcnt; /* running handler count */ int iw_shared; /* if Bridge bit is shared */ int iw_connected; /* if already connected */ }; #define PCIBR_ISR_ERR_START 8 #define PCIBR_ISR_MAX_ERRS 32 /* ===================================================================== * Bridge Device State structure * * one instance of this structure is kept for each * Bridge ASIC in the system. */ struct pcibr_soft_s { devfs_handle_t bs_conn; /* xtalk connection point */ devfs_handle_t bs_vhdl; /* vertex owned by pcibr */ int bs_int_enable; /* Mask of enabled intrs */ bridge_t *bs_base; /* PIO pointer to Bridge chip */ char *bs_name; /* hw graph name */ xwidgetnum_t bs_xid; /* Bridge's xtalk ID number */ devfs_handle_t bs_master; /* xtalk master vertex */ xwidgetnum_t bs_mxid; /* master's xtalk ID number */ iopaddr_t bs_dir_xbase; /* xtalk address for 32-bit PCI direct map */ xwidgetnum_t bs_dir_xport; /* xtalk port for 32-bit PCI direct map */ struct map *bs_int_ate_map; /* rmalloc map for internal ATEs */ struct map *bs_ext_ate_map; /* rmalloc map for external ATEs */ short bs_int_ate_size; /* number of internal ates */ short bs_xbridge; /* if 1 then xbridge */ int bs_rev_num; /* revision number of Bridge */ unsigned bs_dma_flags; /* revision-implied DMA flags */ l1sc_t *bs_l1sc; /* io brick l1 system cntr */ moduleid_t bs_moduleid; /* io brick moduleid */ /* * Lock used primarily to get mutual exclusion while managing any * bridge resources.. */ spinlock_t bs_lock; devfs_handle_t bs_noslot_conn; /* NO-SLOT connection point */ pcibr_info_t bs_noslot_info; struct pcibr_soft_slot_s { /* information we keep about each CFG slot */ /* some devices (ioc3 in non-slotted * configurations, sometimes) make use * of more than one REQ/GNT/INT* signal * sets. The slot corresponding to the * IDSEL that the device responds to is * called the host slot; the slot * numbers that the device is stealing * REQ/GNT/INT bits from are known as * the guest slots. */ int has_host; pciio_slot_t host_slot; devfs_handle_t slot_conn; int slot_status; /* Potentially several connection points * for this slot. bss_ninfo is how many, * and bss_infos is a pointer to * an array pcibr_info_t values (which are * pointers to pcibr_info structs, stored * as device_info in connection ponts). */ int bss_ninfo; pcibr_info_h bss_infos; /* Temporary Compatibility Macros, for * stuff that has moved out of bs_slot * and into the info structure. These * will go away when their users have * converted over to multifunction- * friendly use of bss_{ninfo,infos}. */ #define bss_vendor_id bss_infos[0]->f_vendor #define bss_device_id bss_infos[0]->f_device #define bss_window bss_infos[0]->f_window #define bssw_space w_space #define bssw_base w_base #define bssw_size w_size /* Where is DevIO(x) pointing? */ /* bssd_space is NONE if it is not assigned. */ struct { pciio_space_t bssd_space; iopaddr_t bssd_base; } bss_devio; /* Shadow value for Device(x) register, * so we don't have to go to the chip. */ bridgereg_t bss_device; /* Number of sets on GBR/REALTIME bit outstanding * Used by Priority I/O for tracking reservations */ int bss_pri_uctr; /* Number of "uses" of PMU, 32-bit direct, * and 64-bit direct DMA (0:none, <0: trans, * >0: how many dmamaps). Device(x) bits * controlling attribute of each kind of * channel can't be changed by dmamap_alloc * or dmatrans if the controlling counter * is nonzero. dmatrans is forever. */ int bss_pmu_uctr; int bss_d32_uctr; int bss_d64_uctr; /* When the contents of mapping configuration * information is locked down by dmatrans, * repeated checks of the same flags should * be shortcircuited for efficiency. */ iopaddr_t bss_d64_base; unsigned bss_d64_flags; iopaddr_t bss_d32_base; unsigned bss_d32_flags; /* Shadow information used for implementing * Bridge Hardware WAR #484930 */ atomic_t bss_ext_ates_active; volatile unsigned *bss_cmd_pointer; unsigned bss_cmd_shadow; } bs_slot[8]; pcibr_intr_bits_f *bs_intr_bits; /* RRB MANAGEMENT * bs_rrb_fixed: bitmap of slots whose RRB * allocations we should not "automatically" change * bs_rrb_avail: number of RRBs that have not * been allocated or reserved for {even,odd} slots * bs_rrb_res: number of RRBs reserved for the * use of the index slot number * bs_rrb_valid: number of RRBs marked valid * for the indexed slot number; indexes 8-15 * are for the virtual channels for slots 0-7. */ int bs_rrb_fixed; int bs_rrb_avail[2]; int bs_rrb_res[8]; int bs_rrb_valid[16]; struct { /* Each Bridge interrupt bit has a single XIO * interrupt channel allocated. */ xtalk_intr_t bsi_xtalk_intr; /* * A wrapper structure is associated with each * Bridge interrupt bit. */ struct pcibr_intr_wrap_s bsi_pcibr_intr_wrap; } bs_intr[8]; xtalk_intr_t bsi_err_intr; /* * We stash away some information in this structure on getting * an error interrupt. This information is used during PIO read/ * write error handling. * * As it stands now, we do not re-enable the error interrupt * till the error is resolved. Error resolution happens either at * bus error time for PIO Read errors (~100 microseconds), or at * the scheduled timeout time for PIO write errors (~milliseconds). * If this delay causes problems, we may need to move towards * a different scheme.. * * Note that there is no locking while looking at this data structure. * There should not be any race between bus error code and * error interrupt code.. will look into this if needed. */ struct br_errintr_info { int bserr_toutcnt; #ifdef LATER toid_t bserr_toutid; /* Timeout started by errintr */ #endif iopaddr_t bserr_addr; /* Address where error occurred */ bridgereg_t bserr_intstat; /* interrupts active at error time */ } bs_errinfo; /* * PCI Bus Space allocation data structure. * This info is used to satisfy the callers of pcibr_piospace_alloc * interface. Most of these users need "large" amounts of PIO * space (typically in Megabytes), and they generally tend to * take once and never release.. * For Now use a simple algorithm to manage it. On allocation, * Update the _base field to reflect next free address. * * Freeing does nothing.. So, once allocated, it's gone for good. */ struct br_pcisp_info { iopaddr_t pci_io_base; iopaddr_t pci_io_last; iopaddr_t pci_swin_base; iopaddr_t pci_swin_last; iopaddr_t pci_mem_base; iopaddr_t pci_mem_last; } bs_spinfo; struct bs_errintr_stat_s { uint32_t bs_errcount_total; uint32_t bs_lasterr_timestamp; uint32_t bs_lasterr_snapshot; } bs_errintr_stat[PCIBR_ISR_MAX_ERRS]; /* * Bridge-wide endianness control for * large-window PIO mappings * * These fields are set to PCIIO_BYTE_SWAP * or PCIIO_WORD_VALUES once the swapper * has been configured, one way or the other, * for the direct windows. If they are zero, * nobody has a PIO mapping through that window, * and the swapper can be set either way. */ unsigned bs_pio_end_io; unsigned bs_pio_end_mem; }; #define PCIBR_ERRTIME_THRESHOLD (100) #define PCIBR_ERRRATE_THRESHOLD (100) /* * pcibr will respond to hints dropped in its vertex * using the following structure. */ struct pcibr_hints_s { /* ph_host_slot is actually +1 so "0" means "no host" */ pciio_slot_t ph_host_slot[8]; /* REQ/GNT/INT in use by ... */ unsigned ph_rrb_fixed; /* do not change RRB allocations */ unsigned ph_hands_off; /* prevent further pcibr operations */ rrb_alloc_funct_t rrb_alloc_funct; /* do dynamic rrb allocation */ pcibr_intr_bits_f *ph_intr_bits; /* map PCI INT[ABCD] to Bridge Int(n) */ }; extern int pcibr_prefetch_enable_rev, pcibr_wg_enable_rev; /* * Number of bridge non-fatal error interrupts we can see before * we decide to disable that interrupt. */ #define PCIBR_ERRINTR_DISABLE_LEVEL 10000 /* ===================================================================== * Bridge (pcibr) state management functions * * pcibr_soft_get is here because we do it in a lot * of places and I want to make sure they all stay * in step with each other. * * pcibr_soft_set is here because I want it to be * closely associated with pcibr_soft_get, even * though it is only called in one place. */ #define pcibr_soft_get(v) ((pcibr_soft_t)hwgraph_fastinfo_get((v))) #define pcibr_soft_set(v,i) (hwgraph_fastinfo_set((v), (arbitrary_info_t)(i))) #endif /* _ASM_SN_PCI_PCIBR_PRIVATE_H */