/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2010 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #ifndef _SYS_ROOTNEX_H #define _SYS_ROOTNEX_H /* * x86 root nexus implementation specific state */ #include #include #include #include #include #include #ifdef __cplusplus extern "C" { #endif /* size of buffer used for ctlop reportdev */ #define REPORTDEV_BUFSIZE 1024 /* min and max interrupt vectors */ #define VEC_MIN 1 #define VEC_MAX 255 /* atomic increment/decrement to keep track of outstanding binds, etc */ #ifdef DEBUG #define ROOTNEX_DPROF_INC(addr) atomic_inc_64(addr) #define ROOTNEX_DPROF_DEC(addr) atomic_add_64(addr, -1) #define ROOTNEX_DPROBE1(name, type1, arg1) \ DTRACE_PROBE1(name, type1, arg1) #define ROOTNEX_DPROBE3(name, type1, arg1, type2, arg2, type3, arg3) \ DTRACE_PROBE3(name, type1, arg1, type2, arg2, type3, arg3) #else #define ROOTNEX_DPROF_INC(addr) #define ROOTNEX_DPROF_DEC(addr) #define ROOTNEX_DPROBE1(name, type1, arg1) #define ROOTNEX_DPROBE3(name, type1, arg1, type2, arg2, type3, arg3) #endif #define ROOTNEX_PROF_INC(addr) atomic_inc_64(addr) #define ROOTNEX_PROF_DEC(addr) atomic_add_64(addr, -1) /* set in dmac_type to signify that this cookie uses the copy buffer */ #define ROOTNEX_USES_COPYBUF 0x80000000 /* * integer or boolean property name and value. A few static rootnex properties * are created during rootnex attach from an array of rootnex_intprop_t.. */ typedef struct rootnex_intprop_s { char *prop_name; int prop_value; } rootnex_intprop_t; /* * sgl related information which is visible to rootnex_get_sgl(). Trying to * isolate get_sgl() as much as possible so it can be easily replaced. */ typedef struct rootnex_sglinfo_s { /* * These are passed into rootnex_get_sgl(). * * si_min_addr - the minimum physical address * si_max_addr - the maximum physical address * si_max_cookie_size - the maximum size of a physically contiguous * piece of memory that we can handle in a sgl. * si_segmask - segment mask to determine if we cross a segment boundary * si_max_pages - max number of pages this sgl could occupy (which * is also the maximum number of cookies we might see. */ uint64_t si_min_addr; uint64_t si_max_addr; uint64_t si_max_cookie_size; uint64_t si_segmask; uint_t si_max_pages; /* * these are returned by rootnex_get_sgl() * * si_copybuf_req - amount of copy buffer needed by the buffer. * si_buf_offset - The initial offset into the first page of the buffer. * It's set in get sgl and used in the bind slow path to help * calculate the current page index & offset from the current offset * which is relative to the start of the buffer. * si_asp - address space of buffer passed in. * si_sgl_size - The actual number of cookies in the sgl. This does * not reflect and sharing that we might do on window boundaries. */ size_t si_copybuf_req; off_t si_buf_offset; struct as *si_asp; uint_t si_sgl_size; } rootnex_sglinfo_t; /* * When we have to use the copy buffer, we allocate one of these structures per * buffer page to track which pages need the copy buffer, what the kernel * virtual address is (which the device can't reach), and what the copy buffer * virtual address is (where the device dma's to/from). For 32-bit kernels, * since we can't use seg kpm, we also need to keep the page_t around and state * if we've currently mapped in the page into KVA space for buffers which don't * have kva already and when we have multiple windows because we used up all our * copy buffer space. */ typedef struct rootnex_pgmap_s { boolean_t pm_uses_copybuf; #if !defined(__amd64) boolean_t pm_mapped; page_t *pm_pp; caddr_t pm_vaddr; #endif caddr_t pm_kaddr; caddr_t pm_cbaddr; } rootnex_pgmap_t; /* * We only need to trim a buffer when we have multiple windows. Each window has * trim state. We might have trimmed the end of the previous window, leaving the * first cookie of this window trimmed[tr_trim_first] (which basically means we * won't start with a new cookie), or we might need to trim the end of the * current window [tr_trim_last] (which basically means we won't end with a * complete cookie). We keep the same state for the first & last cookie in a * window (a window can have one or more cookies). However, when we trim the * last cookie, we keep a pointer to the last cookie in the trim state since we * only need this info when we trim. The pointer to the first cookie in the * window is in the window state since we need to know what the first cookie in * the window is in various places. * * If we do trim a cookie, we save away the physical address and size of the * cookie so that we can over write the cookie when we switch windows (the * space for a cookie which is in two windows is shared between the windows. * We keep around the same information for the last page in a window. * * if we happened to trim on a page that uses the copy buffer, and that page * is also in the middle of a window boundary because we have filled up the * copy buffer, we need to remember the copy buffer address for both windows * since the same page will have different copy buffer addresses in the two * windows. We need to due the same for kaddr in the 32-bit kernel since we * have a limited kva space which we map to. */ typedef struct rootnex_trim_s { boolean_t tr_trim_first; boolean_t tr_trim_last; ddi_dma_cookie_t *tr_last_cookie; uint64_t tr_first_paddr; uint64_t tr_last_paddr; size_t tr_first_size; size_t tr_last_size; boolean_t tr_first_copybuf_win; boolean_t tr_last_copybuf_win; uint_t tr_first_pidx; uint_t tr_last_pidx; caddr_t tr_first_cbaddr; caddr_t tr_last_cbaddr; #if !defined(__amd64) caddr_t tr_first_kaddr; caddr_t tr_last_kaddr; #endif } rootnex_trim_t; /* * per window state. A bound DMA handle can have multiple windows. Each window * will have the following state. We track if this window needs to sync, * the offset into the buffer where the window starts, the size of the window. * a pointer to the first cookie in the window, the number of cookies in the * window, and the trim state for the window. For the 32-bit kernel, we keep * track of if we need to remap the copy buffer when we switch to a this window */ typedef struct rootnex_window_s { boolean_t wd_dosync; uint_t wd_cookie_cnt; off_t wd_offset; size_t wd_size; ddi_dma_cookie_t *wd_first_cookie; rootnex_trim_t wd_trim; #if !defined(__amd64) boolean_t wd_remap_copybuf; #endif } rootnex_window_t; typedef struct dvcookie { uint64_t dvck_dvma; uint64_t dvck_npages; } dvcookie_t; typedef struct dcookie { paddr_t dck_paddr; uint64_t dck_npages; } dcookie_t; /* per dma handle private state */ typedef struct rootnex_dma_s { /* * sgl related state used to build and describe the sgl. * * dp_partial_required - used in the bind slow path to identify if we * need to do a partial mapping or not. * dp_trim_required - used in the bind slow path to identify if we * need to trim when switching to a new window. This should only be * set when partial is set. * dp_granularity_power_2 - set in alloc handle and used in bind slow * path to determine if we & or % to calculate the trim. * dp_dma - copy of dma "object" passed in during bind * dp_maxxfer - trimmed dma_attr_maxxfer so that it is a whole * multiple of granularity * dp_sglinfo - See rootnex_sglinfo_t above. */ boolean_t dp_partial_required; boolean_t dp_trim_required; boolean_t dp_granularity_power_2; uint64_t dp_maxxfer; ddi_dma_obj_t dp_dma; rootnex_sglinfo_t dp_sglinfo; /* * Copy buffer related state * * dp_copybuf_size - the actual size of the copy buffer that we are * using. This can be smaller that dp_copybuf_req, i.e. bind size > * max copy buffer size. * dp_cbaddr - kernel address of copy buffer. Used to determine where * where to copy to/from. * dp_cbsize - the "real" size returned from the copy buffer alloc. * Set in the copybuf alloc and used to free copybuf. * dp_pgmap - page map used in sync to determine which pages in the * buffer use the copy buffer and what addresses to use to copy to/ * from. * dp_cb_remaping - status if this bind causes us to have to remap * the copybuf when switching to new windows. This is only used in * the 32-bit kernel since we use seg kpm in the 64-bit kernel for * this case. * dp_kva - kernel heap arena vmem space for mapping to buffers which * we don't have a kernel VA to bcopy to/from. This is only used in * the 32-bit kernel since we use seg kpm in the 64-bit kernel for * this case. */ size_t dp_copybuf_size; caddr_t dp_cbaddr; size_t dp_cbsize; rootnex_pgmap_t *dp_pgmap; #if !defined(__amd64) boolean_t dp_cb_remaping; caddr_t dp_kva; #endif /* * window related state. The pointer to the window state array which may * be a pointer into the pre allocated state, or we may have had to * allocate the window array on the fly because it wouldn't fit. If * we allocate it, we'll use dp_need_to_free_window and dp_window_size * during cleanup. dp_current_win keeps track of the current window. * dp_max_win is the maximum number of windows we could have. */ uint_t dp_current_win; rootnex_window_t *dp_window; boolean_t dp_need_to_free_window; uint_t dp_window_size; uint_t dp_max_win; /* dip of driver which "owns" handle. set to rdip in alloc_handle() */ dev_info_t *dp_dip; /* * dp_mutex and dp_inuse are only used to see if a driver is trying to * bind to an already bound dma handle. dp_mutex only used for dp_inuse */ kmutex_t dp_mutex; boolean_t dp_inuse; /* * cookie related state. The pointer to the cookies (dp_cookies) may * be a pointer into the pre allocated state, or we may have had to * allocate the cookie array on the fly because it wouldn't fit. If * we allocate it, we'll use dp_need_to_free_cookie and dp_cookie_size * during cleanup. dp_current_cookie is only used in the obsoleted * interfaces to determine when we've used up all the cookies in a * window during nextseg().. */ size_t dp_cookie_size; ddi_dma_cookie_t *dp_cookies; boolean_t dp_need_to_free_cookie; uint_t dp_current_cookie; /* for obsoleted I/Fs */ ddi_dma_cookie_t *dp_saved_cookies; boolean_t dp_need_to_switch_cookies; /* * pre allocated space for the bind state, allocated during alloc * handle. For a lot of devices, this will save us from having to do * kmem_alloc's during the bind most of the time. kmem_alloc's can be * expensive on x86 when the cpu count goes up since xcalls are * expensive on x86. */ uchar_t *dp_prealloc_buffer; /* * Intel IOMMU (immu) related state * dv_cookies saves the dvma allocated for this handler * max index of dvcookies in dvmax */ dvcookie_t *dp_dvcookies; uint64_t dp_dvmax; dcookie_t *dp_dcookies; uint64_t dp_dmax; uint64_t dp_max_cookies; uint64_t dp_max_dcookies; /* * sleep flags set on bind and unset on unbind */ int dp_sleep_flags; } rootnex_dma_t; /* * profile/performance counters. Most things will be dtrace probes, but there * are a couple of things we want to keep track all the time. We track the * total number of active handles and binds (i.e. an alloc without a free or * a bind without an unbind) since rootnex attach. We also track the total * number of binds which have failed since rootnex attach. */ typedef enum { ROOTNEX_CNT_ACTIVE_HDLS = 0, ROOTNEX_CNT_ACTIVE_BINDS = 1, ROOTNEX_CNT_ALLOC_FAIL = 2, ROOTNEX_CNT_BIND_FAIL = 3, ROOTNEX_CNT_SYNC_FAIL = 4, ROOTNEX_CNT_GETWIN_FAIL = 5, /* This one must be last */ ROOTNEX_CNT_LAST } rootnex_cnt_t; /* * global driver state. * r_dmahdl_cache - dma_handle kmem_cache * r_dvma_call_list_id - ddi_set_callback() id * r_peekpoke_mutex - serialize peeks and pokes. * r_dip - rootnex dip * r_reserved_msg_printed - ctlops reserve message threshold * r_counters - profile/performance counters */ typedef struct rootnex_state_s { uint_t r_prealloc_cookies; uint_t r_prealloc_size; kmem_cache_t *r_dmahdl_cache; uintptr_t r_dvma_call_list_id; kmutex_t r_peekpoke_mutex; dev_info_t *r_dip; ddi_iblock_cookie_t r_err_ibc; boolean_t r_reserved_msg_printed; uint64_t r_counters[ROOTNEX_CNT_LAST]; iommulib_nexhandle_t r_iommulib_handle; } rootnex_state_t; #ifdef __cplusplus } #endif #endif /* _SYS_ROOTNEX_H */