// SPDX-License-Identifier: MIT /* * Copyright © 2023 Intel Corporation */ #include #include #include #include #include #include #include #include #define to_group(__private_obj) \ container_of(__private_obj, struct drm_dp_tunnel_group, base) #define to_group_state(__private_state) \ container_of(__private_state, struct drm_dp_tunnel_group_state, base) #define is_dp_tunnel_private_obj(__obj) \ ((__obj)->funcs == &tunnel_group_funcs) #define for_each_new_group_in_state(__state, __new_group_state, __i) \ for ((__i) = 0; \ (__i) < (__state)->num_private_objs; \ (__i)++) \ for_each_if ((__state)->private_objs[__i].ptr && \ is_dp_tunnel_private_obj((__state)->private_objs[__i].ptr) && \ ((__new_group_state) = \ to_group_state((__state)->private_objs[__i].new_state), 1)) #define for_each_old_group_in_state(__state, __old_group_state, __i) \ for ((__i) = 0; \ (__i) < (__state)->num_private_objs; \ (__i)++) \ for_each_if ((__state)->private_objs[__i].ptr && \ is_dp_tunnel_private_obj((__state)->private_objs[__i].ptr) && \ ((__old_group_state) = \ to_group_state((__state)->private_objs[__i].old_state), 1)) #define for_each_tunnel_in_group(__group, __tunnel) \ list_for_each_entry(__tunnel, &(__group)->tunnels, node) #define for_each_tunnel_state(__group_state, __tunnel_state) \ list_for_each_entry(__tunnel_state, &(__group_state)->tunnel_states, node) #define for_each_tunnel_state_safe(__group_state, __tunnel_state, __tunnel_state_tmp) \ list_for_each_entry_safe(__tunnel_state, __tunnel_state_tmp, \ &(__group_state)->tunnel_states, node) #define kbytes_to_mbits(__kbytes) \ DIV_ROUND_UP((__kbytes) * 8, 1000) #define DPTUN_BW_ARG(__bw) ((__bw) < 0 ? (__bw) : kbytes_to_mbits(__bw)) #define __tun_prn(__tunnel, __level, __type, __fmt, ...) \ drm_##__level##__type((__tunnel)->group->mgr->dev, \ "[DPTUN %s][%s] " __fmt, \ drm_dp_tunnel_name(__tunnel), \ (__tunnel)->aux->name, ## \ __VA_ARGS__) #define tun_dbg(__tunnel, __fmt, ...) \ __tun_prn(__tunnel, dbg, _kms, __fmt, ## __VA_ARGS__) #define tun_dbg_stat(__tunnel, __err, __fmt, ...) do { \ if (__err) \ __tun_prn(__tunnel, dbg, _kms, __fmt " (Failed, err: %pe)\n", \ ## __VA_ARGS__, ERR_PTR(__err)); \ else \ __tun_prn(__tunnel, dbg, _kms, __fmt " (Ok)\n", \ ## __VA_ARGS__); \ } while (0) #define tun_dbg_atomic(__tunnel, __fmt, ...) \ __tun_prn(__tunnel, dbg, _atomic, __fmt, ## __VA_ARGS__) #define tun_grp_dbg(__group, __fmt, ...) \ drm_dbg_kms((__group)->mgr->dev, \ "[DPTUN %s] " __fmt, \ drm_dp_tunnel_group_name(__group), ## \ __VA_ARGS__) #define DP_TUNNELING_BASE DP_TUNNELING_OUI #define __DPTUN_REG_RANGE(__start, __size) \ GENMASK_ULL((__start) + (__size) - 1, (__start)) #define DPTUN_REG_RANGE(__addr, __size) \ __DPTUN_REG_RANGE((__addr) - DP_TUNNELING_BASE, (__size)) #define DPTUN_REG(__addr) DPTUN_REG_RANGE(__addr, 1) #define DPTUN_INFO_REG_MASK ( \ DPTUN_REG_RANGE(DP_TUNNELING_OUI, DP_TUNNELING_OUI_BYTES) | \ DPTUN_REG_RANGE(DP_TUNNELING_DEV_ID, DP_TUNNELING_DEV_ID_BYTES) | \ DPTUN_REG(DP_TUNNELING_HW_REV) | \ DPTUN_REG(DP_TUNNELING_SW_REV_MAJOR) | \ DPTUN_REG(DP_TUNNELING_SW_REV_MINOR) | \ DPTUN_REG(DP_TUNNELING_CAPABILITIES) | \ DPTUN_REG(DP_IN_ADAPTER_INFO) | \ DPTUN_REG(DP_USB4_DRIVER_ID) | \ DPTUN_REG(DP_USB4_DRIVER_BW_CAPABILITY) | \ DPTUN_REG(DP_IN_ADAPTER_TUNNEL_INFORMATION) | \ DPTUN_REG(DP_BW_GRANULARITY) | \ DPTUN_REG(DP_ESTIMATED_BW) | \ DPTUN_REG(DP_ALLOCATED_BW) | \ DPTUN_REG(DP_TUNNELING_MAX_LINK_RATE) | \ DPTUN_REG(DP_TUNNELING_MAX_LANE_COUNT) | \ DPTUN_REG(DP_DPTX_BW_ALLOCATION_MODE_CONTROL)) static const DECLARE_BITMAP(dptun_info_regs, 64) = { DPTUN_INFO_REG_MASK & -1UL, #if BITS_PER_LONG == 32 DPTUN_INFO_REG_MASK >> 32, #endif }; struct drm_dp_tunnel_regs { u8 buf[HWEIGHT64(DPTUN_INFO_REG_MASK)]; }; struct drm_dp_tunnel_group; struct drm_dp_tunnel { struct drm_dp_tunnel_group *group; struct list_head node; struct kref kref; struct ref_tracker *tracker; struct drm_dp_aux *aux; char name[8]; int bw_granularity; int estimated_bw; int allocated_bw; int max_dprx_rate; u8 max_dprx_lane_count; u8 adapter_id; bool bw_alloc_supported:1; bool bw_alloc_enabled:1; bool has_io_error:1; bool destroyed:1; }; struct drm_dp_tunnel_group_state; struct drm_dp_tunnel_state { struct drm_dp_tunnel_group_state *group_state; struct drm_dp_tunnel_ref tunnel_ref; struct list_head node; u32 stream_mask; int *stream_bw; }; struct drm_dp_tunnel_group_state { struct drm_private_state base; struct list_head tunnel_states; }; struct drm_dp_tunnel_group { struct drm_private_obj base; struct drm_dp_tunnel_mgr *mgr; struct list_head tunnels; /* available BW including the allocated_bw of all tunnels in the group */ int available_bw; u8 drv_group_id; char name[8]; bool active:1; }; struct drm_dp_tunnel_mgr { struct drm_device *dev; int group_count; struct drm_dp_tunnel_group *groups; wait_queue_head_t bw_req_queue; #ifdef CONFIG_DRM_DISPLAY_DEBUG_DP_TUNNEL_STATE struct ref_tracker_dir ref_tracker; #endif }; /* * The following helpers provide a way to read out the tunneling DPCD * registers with a minimal amount of AUX transfers (1 transfer per contiguous * range, as permitted by the 16 byte per transfer AUX limit), not accessing * other registers to avoid any read side-effects. */ static int next_reg_area(int *offset) { *offset = find_next_bit(dptun_info_regs, 64, *offset); return find_next_zero_bit(dptun_info_regs, 64, *offset + 1) - *offset; } #define tunnel_reg_ptr(__regs, __address) ({ \ WARN_ON(!test_bit((__address) - DP_TUNNELING_BASE, dptun_info_regs)); \ &(__regs)->buf[bitmap_weight(dptun_info_regs, (__address) - DP_TUNNELING_BASE)]; \ }) static int read_tunnel_regs(struct drm_dp_aux *aux, struct drm_dp_tunnel_regs *regs) { int offset = 0; int len; while ((len = next_reg_area(&offset))) { int address = DP_TUNNELING_BASE + offset; if (drm_dp_dpcd_read(aux, address, tunnel_reg_ptr(regs, address), len) < 0) return -EIO; offset += len; } return 0; } static u8 tunnel_reg(const struct drm_dp_tunnel_regs *regs, int address) { return *tunnel_reg_ptr(regs, address); } static u8 tunnel_reg_drv_group_id(const struct drm_dp_tunnel_regs *regs) { u8 drv_id = tunnel_reg(regs, DP_USB4_DRIVER_ID) & DP_USB4_DRIVER_ID_MASK; u8 group_id = tunnel_reg(regs, DP_IN_ADAPTER_TUNNEL_INFORMATION) & DP_GROUP_ID_MASK; if (!group_id) return 0; return (drv_id << DP_GROUP_ID_BITS) | group_id; } /* Return granularity in kB/s units */ static int tunnel_reg_bw_granularity(const struct drm_dp_tunnel_regs *regs) { int gr = tunnel_reg(regs, DP_BW_GRANULARITY) & DP_BW_GRANULARITY_MASK; if (gr > 2) return -1; return (250000 << gr) / 8; } static int tunnel_reg_max_dprx_rate(const struct drm_dp_tunnel_regs *regs) { u8 bw_code = tunnel_reg(regs, DP_TUNNELING_MAX_LINK_RATE); return drm_dp_bw_code_to_link_rate(bw_code); } static int tunnel_reg_max_dprx_lane_count(const struct drm_dp_tunnel_regs *regs) { return tunnel_reg(regs, DP_TUNNELING_MAX_LANE_COUNT) & DP_TUNNELING_MAX_LANE_COUNT_MASK; } static bool tunnel_reg_bw_alloc_supported(const struct drm_dp_tunnel_regs *regs) { u8 cap_mask = DP_TUNNELING_SUPPORT | DP_IN_BW_ALLOCATION_MODE_SUPPORT; if ((tunnel_reg(regs, DP_TUNNELING_CAPABILITIES) & cap_mask) != cap_mask) return false; return tunnel_reg(regs, DP_USB4_DRIVER_BW_CAPABILITY) & DP_USB4_DRIVER_BW_ALLOCATION_MODE_SUPPORT; } static bool tunnel_reg_bw_alloc_enabled(const struct drm_dp_tunnel_regs *regs) { return tunnel_reg(regs, DP_DPTX_BW_ALLOCATION_MODE_CONTROL) & DP_DISPLAY_DRIVER_BW_ALLOCATION_MODE_ENABLE; } static u8 tunnel_group_drv_id(u8 drv_group_id) { return drv_group_id >> DP_GROUP_ID_BITS; } static u8 tunnel_group_id(u8 drv_group_id) { return drv_group_id & DP_GROUP_ID_MASK; } const char *drm_dp_tunnel_name(const struct drm_dp_tunnel *tunnel) { return tunnel->name; } EXPORT_SYMBOL(drm_dp_tunnel_name); static const char *drm_dp_tunnel_group_name(const struct drm_dp_tunnel_group *group) { return group->name; } static struct drm_dp_tunnel_group * lookup_or_alloc_group(struct drm_dp_tunnel_mgr *mgr, u8 drv_group_id) { struct drm_dp_tunnel_group *group = NULL; int i; for (i = 0; i < mgr->group_count; i++) { /* * A tunnel group with 0 group ID shouldn't have more than one * tunnels. */ if (tunnel_group_id(drv_group_id) && mgr->groups[i].drv_group_id == drv_group_id) return &mgr->groups[i]; if (!group && !mgr->groups[i].active) group = &mgr->groups[i]; } if (!group) { drm_dbg_kms(mgr->dev, "DPTUN: Can't allocate more tunnel groups\n"); return NULL; } group->drv_group_id = drv_group_id; group->active = true; /* * The group name format here and elsewhere: Driver-ID:Group-ID:* * (* standing for all DP-Adapters/tunnels in the group). */ snprintf(group->name, sizeof(group->name), "%d:%d:*", tunnel_group_drv_id(drv_group_id) & ((1 << DP_GROUP_ID_BITS) - 1), tunnel_group_id(drv_group_id) & ((1 << DP_USB4_DRIVER_ID_BITS) - 1)); return group; } static void free_group(struct drm_dp_tunnel_group *group) { struct drm_dp_tunnel_mgr *mgr = group->mgr; if (drm_WARN_ON(mgr->dev, !list_empty(&group->tunnels))) return; group->drv_group_id = 0; group->available_bw = -1; group->active = false; } static struct drm_dp_tunnel * tunnel_get(struct drm_dp_tunnel *tunnel) { kref_get(&tunnel->kref); return tunnel; } static void free_tunnel(struct kref *kref) { struct drm_dp_tunnel *tunnel = container_of(kref, typeof(*tunnel), kref); struct drm_dp_tunnel_group *group = tunnel->group; list_del(&tunnel->node); if (list_empty(&group->tunnels)) free_group(group); kfree(tunnel); } static void tunnel_put(struct drm_dp_tunnel *tunnel) { kref_put(&tunnel->kref, free_tunnel); } #ifdef CONFIG_DRM_DISPLAY_DEBUG_DP_TUNNEL_STATE static void track_tunnel_ref(struct drm_dp_tunnel *tunnel, struct ref_tracker **tracker) { ref_tracker_alloc(&tunnel->group->mgr->ref_tracker, tracker, GFP_KERNEL); } static void untrack_tunnel_ref(struct drm_dp_tunnel *tunnel, struct ref_tracker **tracker) { ref_tracker_free(&tunnel->group->mgr->ref_tracker, tracker); } #else static void track_tunnel_ref(struct drm_dp_tunnel *tunnel, struct ref_tracker **tracker) { } static void untrack_tunnel_ref(struct drm_dp_tunnel *tunnel, struct ref_tracker **tracker) { } #endif /** * drm_dp_tunnel_get - Get a reference for a DP tunnel * @tunnel: Tunnel object * @tracker: Debug tracker for the reference * * Get a reference for @tunnel, along with a debug tracker to help locating * the source of a reference leak/double reference put etc. issue. * * The reference must be dropped after use calling drm_dp_tunnel_put() * passing @tunnel and *@tracker returned from here. * * Returns @tunnel - as a convenience - along with *@tracker. */ struct drm_dp_tunnel * drm_dp_tunnel_get(struct drm_dp_tunnel *tunnel, struct ref_tracker **tracker) { track_tunnel_ref(tunnel, tracker); return tunnel_get(tunnel); } EXPORT_SYMBOL(drm_dp_tunnel_get); /** * drm_dp_tunnel_put - Put a reference for a DP tunnel * @tunnel - Tunnel object * @tracker - Debug tracker for the reference * * Put a reference for @tunnel along with its debug *@tracker, which * was obtained with drm_dp_tunnel_get(). */ void drm_dp_tunnel_put(struct drm_dp_tunnel *tunnel, struct ref_tracker **tracker) { untrack_tunnel_ref(tunnel, tracker); tunnel_put(tunnel); } EXPORT_SYMBOL(drm_dp_tunnel_put); static bool add_tunnel_to_group(struct drm_dp_tunnel_mgr *mgr, u8 drv_group_id, struct drm_dp_tunnel *tunnel) { struct drm_dp_tunnel_group *group; group = lookup_or_alloc_group(mgr, drv_group_id); if (!group) return false; tunnel->group = group; list_add(&tunnel->node, &group->tunnels); return true; } static struct drm_dp_tunnel * create_tunnel(struct drm_dp_tunnel_mgr *mgr, struct drm_dp_aux *aux, const struct drm_dp_tunnel_regs *regs) { u8 drv_group_id = tunnel_reg_drv_group_id(regs); struct drm_dp_tunnel *tunnel; tunnel = kzalloc(sizeof(*tunnel), GFP_KERNEL); if (!tunnel) return NULL; INIT_LIST_HEAD(&tunnel->node); kref_init(&tunnel->kref); tunnel->aux = aux; tunnel->adapter_id = tunnel_reg(regs, DP_IN_ADAPTER_INFO) & DP_IN_ADAPTER_NUMBER_MASK; snprintf(tunnel->name, sizeof(tunnel->name), "%d:%d:%d", tunnel_group_drv_id(drv_group_id) & ((1 << DP_GROUP_ID_BITS) - 1), tunnel_group_id(drv_group_id) & ((1 << DP_USB4_DRIVER_ID_BITS) - 1), tunnel->adapter_id & ((1 << DP_IN_ADAPTER_NUMBER_BITS) - 1)); tunnel->bw_granularity = tunnel_reg_bw_granularity(regs); tunnel->allocated_bw = tunnel_reg(regs, DP_ALLOCATED_BW) * tunnel->bw_granularity; /* * An initial allocated BW of 0 indicates an undefined state: the * actual allocation is determined by the TBT CM, usually following a * legacy allocation policy (based on the max DPRX caps). From the * driver's POV the state becomes defined only after the first * allocation request. */ if (!tunnel->allocated_bw) tunnel->allocated_bw = -1; tunnel->bw_alloc_supported = tunnel_reg_bw_alloc_supported(regs); tunnel->bw_alloc_enabled = tunnel_reg_bw_alloc_enabled(regs); if (!add_tunnel_to_group(mgr, drv_group_id, tunnel)) { kfree(tunnel); return NULL; } track_tunnel_ref(tunnel, &tunnel->tracker); return tunnel; } static void destroy_tunnel(struct drm_dp_tunnel *tunnel) { untrack_tunnel_ref(tunnel, &tunnel->tracker); tunnel_put(tunnel); } /** * drm_dp_tunnel_set_io_error - Set the IO error flag for a DP tunnel * @tunnel: Tunnel object * * Set the IO error flag for @tunnel. Drivers can call this function upon * detecting a failure that affects the tunnel functionality, for instance * after a DP AUX transfer failure on the port @tunnel is connected to. * * This disables further management of @tunnel, including any related * AUX accesses for tunneling DPCD registers, returning error to the * initiators of these. The driver is supposed to drop this tunnel and - * optionally - recreate it. */ void drm_dp_tunnel_set_io_error(struct drm_dp_tunnel *tunnel) { tunnel->has_io_error = true; } EXPORT_SYMBOL(drm_dp_tunnel_set_io_error); #define SKIP_DPRX_CAPS_CHECK BIT(0) #define ALLOW_ALLOCATED_BW_CHANGE BIT(1) static bool tunnel_regs_are_valid(struct drm_dp_tunnel_mgr *mgr, const struct drm_dp_tunnel_regs *regs, unsigned int flags) { u8 drv_group_id = tunnel_reg_drv_group_id(regs); bool check_dprx = !(flags & SKIP_DPRX_CAPS_CHECK); bool ret = true; if (!tunnel_reg_bw_alloc_supported(regs)) { if (tunnel_group_id(drv_group_id)) { drm_dbg_kms(mgr->dev, "DPTUN: A non-zero group ID is only allowed with BWA support\n"); ret = false; } if (tunnel_reg(regs, DP_ALLOCATED_BW)) { drm_dbg_kms(mgr->dev, "DPTUN: BW is allocated without BWA support\n"); ret = false; } return ret; } if (!tunnel_group_id(drv_group_id)) { drm_dbg_kms(mgr->dev, "DPTUN: BWA support requires a non-zero group ID\n"); ret = false; } if (check_dprx && hweight8(tunnel_reg_max_dprx_lane_count(regs)) != 1) { drm_dbg_kms(mgr->dev, "DPTUN: Invalid DPRX lane count: %d\n", tunnel_reg_max_dprx_lane_count(regs)); ret = false; } if (check_dprx && !tunnel_reg_max_dprx_rate(regs)) { drm_dbg_kms(mgr->dev, "DPTUN: DPRX rate is 0\n"); ret = false; } if (tunnel_reg_bw_granularity(regs) < 0) { drm_dbg_kms(mgr->dev, "DPTUN: Invalid BW granularity\n"); ret = false; } if (tunnel_reg(regs, DP_ALLOCATED_BW) > tunnel_reg(regs, DP_ESTIMATED_BW)) { drm_dbg_kms(mgr->dev, "DPTUN: Allocated BW %d > estimated BW %d Mb/s\n", DPTUN_BW_ARG(tunnel_reg(regs, DP_ALLOCATED_BW) * tunnel_reg_bw_granularity(regs)), DPTUN_BW_ARG(tunnel_reg(regs, DP_ESTIMATED_BW) * tunnel_reg_bw_granularity(regs))); ret = false; } return ret; } static int tunnel_allocated_bw(const struct drm_dp_tunnel *tunnel) { return max(tunnel->allocated_bw, 0); } static bool tunnel_info_changes_are_valid(struct drm_dp_tunnel *tunnel, const struct drm_dp_tunnel_regs *regs, unsigned int flags) { u8 new_drv_group_id = tunnel_reg_drv_group_id(regs); bool ret = true; if (tunnel->bw_alloc_supported != tunnel_reg_bw_alloc_supported(regs)) { tun_dbg(tunnel, "BW alloc support has changed %s -> %s\n", str_yes_no(tunnel->bw_alloc_supported), str_yes_no(tunnel_reg_bw_alloc_supported(regs))); ret = false; } if (tunnel->group->drv_group_id != new_drv_group_id) { tun_dbg(tunnel, "Driver/group ID has changed %d:%d:* -> %d:%d:*\n", tunnel_group_drv_id(tunnel->group->drv_group_id), tunnel_group_id(tunnel->group->drv_group_id), tunnel_group_drv_id(new_drv_group_id), tunnel_group_id(new_drv_group_id)); ret = false; } if (!tunnel->bw_alloc_supported) return ret; if (tunnel->bw_granularity != tunnel_reg_bw_granularity(regs)) { tun_dbg(tunnel, "BW granularity has changed: %d -> %d Mb/s\n", DPTUN_BW_ARG(tunnel->bw_granularity), DPTUN_BW_ARG(tunnel_reg_bw_granularity(regs))); ret = false; } /* * On some devices at least the BW alloc mode enabled status is always * reported as 0, so skip checking that here. */ if (!(flags & ALLOW_ALLOCATED_BW_CHANGE) && tunnel_allocated_bw(tunnel) != tunnel_reg(regs, DP_ALLOCATED_BW) * tunnel->bw_granularity) { tun_dbg(tunnel, "Allocated BW has changed: %d -> %d Mb/s\n", DPTUN_BW_ARG(tunnel->allocated_bw), DPTUN_BW_ARG(tunnel_reg(regs, DP_ALLOCATED_BW) * tunnel->bw_granularity)); ret = false; } return ret; } static int read_and_verify_tunnel_regs(struct drm_dp_tunnel *tunnel, struct drm_dp_tunnel_regs *regs, unsigned int flags) { int err; err = read_tunnel_regs(tunnel->aux, regs); if (err < 0) { drm_dp_tunnel_set_io_error(tunnel); return err; } if (!tunnel_regs_are_valid(tunnel->group->mgr, regs, flags)) return -EINVAL; if (!tunnel_info_changes_are_valid(tunnel, regs, flags)) return -EINVAL; return 0; } static bool update_dprx_caps(struct drm_dp_tunnel *tunnel, const struct drm_dp_tunnel_regs *regs) { bool changed = false; if (tunnel_reg_max_dprx_rate(regs) != tunnel->max_dprx_rate) { tunnel->max_dprx_rate = tunnel_reg_max_dprx_rate(regs); changed = true; } if (tunnel_reg_max_dprx_lane_count(regs) != tunnel->max_dprx_lane_count) { tunnel->max_dprx_lane_count = tunnel_reg_max_dprx_lane_count(regs); changed = true; } return changed; } static int dev_id_len(const u8 *dev_id, int max_len) { while (max_len && dev_id[max_len - 1] == '\0') max_len--; return max_len; } static int get_max_dprx_bw(const struct drm_dp_tunnel *tunnel) { int max_dprx_bw = drm_dp_max_dprx_data_rate(tunnel->max_dprx_rate, tunnel->max_dprx_lane_count); /* * A BW request of roundup(max_dprx_bw, tunnel->bw_granularity) results in * an allocation of max_dprx_bw. A BW request above this rounded-up * value will fail. */ return min(roundup(max_dprx_bw, tunnel->bw_granularity), MAX_DP_REQUEST_BW * tunnel->bw_granularity); } static int get_max_tunnel_bw(const struct drm_dp_tunnel *tunnel) { return min(get_max_dprx_bw(tunnel), tunnel->group->available_bw); } /** * drm_dp_tunnel_detect - Detect DP tunnel on the link * @mgr: Tunnel manager * @aux: DP AUX on which the tunnel will be detected * * Detect if there is any DP tunnel on the link and add it to the tunnel * group's tunnel list. * * Returns a pointer to a tunnel on success, or an ERR_PTR() error on * failure. */ struct drm_dp_tunnel * drm_dp_tunnel_detect(struct drm_dp_tunnel_mgr *mgr, struct drm_dp_aux *aux) { struct drm_dp_tunnel_regs regs; struct drm_dp_tunnel *tunnel; int err; err = read_tunnel_regs(aux, ®s); if (err) return ERR_PTR(err); if (!(tunnel_reg(®s, DP_TUNNELING_CAPABILITIES) & DP_TUNNELING_SUPPORT)) return ERR_PTR(-ENODEV); /* The DPRX caps are valid only after enabling BW alloc mode. */ if (!tunnel_regs_are_valid(mgr, ®s, SKIP_DPRX_CAPS_CHECK)) return ERR_PTR(-EINVAL); tunnel = create_tunnel(mgr, aux, ®s); if (!tunnel) return ERR_PTR(-ENOMEM); tun_dbg(tunnel, "OUI:%*phD DevID:%*pE Rev-HW:%d.%d SW:%d.%d PR-Sup:%s BWA-Sup:%s BWA-En:%s\n", DP_TUNNELING_OUI_BYTES, tunnel_reg_ptr(®s, DP_TUNNELING_OUI), dev_id_len(tunnel_reg_ptr(®s, DP_TUNNELING_DEV_ID), DP_TUNNELING_DEV_ID_BYTES), tunnel_reg_ptr(®s, DP_TUNNELING_DEV_ID), (tunnel_reg(®s, DP_TUNNELING_HW_REV) & DP_TUNNELING_HW_REV_MAJOR_MASK) >> DP_TUNNELING_HW_REV_MAJOR_SHIFT, (tunnel_reg(®s, DP_TUNNELING_HW_REV) & DP_TUNNELING_HW_REV_MINOR_MASK) >> DP_TUNNELING_HW_REV_MINOR_SHIFT, tunnel_reg(®s, DP_TUNNELING_SW_REV_MAJOR), tunnel_reg(®s, DP_TUNNELING_SW_REV_MINOR), str_yes_no(tunnel_reg(®s, DP_TUNNELING_CAPABILITIES) & DP_PANEL_REPLAY_OPTIMIZATION_SUPPORT), str_yes_no(tunnel->bw_alloc_supported), str_yes_no(tunnel->bw_alloc_enabled)); return tunnel; } EXPORT_SYMBOL(drm_dp_tunnel_detect); /** * drm_dp_tunnel_destroy - Destroy tunnel object * @tunnel: Tunnel object * * Remove the tunnel from the tunnel topology and destroy it. * * Returns 0 on success, -ENODEV if the tunnel has been destroyed already. */ int drm_dp_tunnel_destroy(struct drm_dp_tunnel *tunnel) { if (!tunnel) return 0; if (drm_WARN_ON(tunnel->group->mgr->dev, tunnel->destroyed)) return -ENODEV; tun_dbg(tunnel, "destroying\n"); tunnel->destroyed = true; destroy_tunnel(tunnel); return 0; } EXPORT_SYMBOL(drm_dp_tunnel_destroy); static int check_tunnel(const struct drm_dp_tunnel *tunnel) { if (tunnel->destroyed) return -ENODEV; if (tunnel->has_io_error) return -EIO; return 0; } static int group_allocated_bw(struct drm_dp_tunnel_group *group) { struct drm_dp_tunnel *tunnel; int group_allocated_bw = 0; for_each_tunnel_in_group(group, tunnel) { if (check_tunnel(tunnel) == 0 && tunnel->bw_alloc_enabled) group_allocated_bw += tunnel_allocated_bw(tunnel); } return group_allocated_bw; } /* * The estimated BW reported by the TBT Connection Manager for each tunnel in * a group includes the BW already allocated for the given tunnel and the * unallocated BW which is free to be used by any tunnel in the group. */ static int group_free_bw(const struct drm_dp_tunnel *tunnel) { return tunnel->estimated_bw - tunnel_allocated_bw(tunnel); } static int calc_group_available_bw(const struct drm_dp_tunnel *tunnel) { return group_allocated_bw(tunnel->group) + group_free_bw(tunnel); } static int update_group_available_bw(struct drm_dp_tunnel *tunnel, const struct drm_dp_tunnel_regs *regs) { struct drm_dp_tunnel *tunnel_iter; int group_available_bw; bool changed; tunnel->estimated_bw = tunnel_reg(regs, DP_ESTIMATED_BW) * tunnel->bw_granularity; if (calc_group_available_bw(tunnel) == tunnel->group->available_bw) return 0; for_each_tunnel_in_group(tunnel->group, tunnel_iter) { int err; if (tunnel_iter == tunnel) continue; if (check_tunnel(tunnel_iter) != 0 || !tunnel_iter->bw_alloc_enabled) continue; err = drm_dp_dpcd_probe(tunnel_iter->aux, DP_DPCD_REV); if (err) { tun_dbg(tunnel_iter, "Probe failed, assume disconnected (err %pe)\n", ERR_PTR(err)); drm_dp_tunnel_set_io_error(tunnel_iter); } } group_available_bw = calc_group_available_bw(tunnel); tun_dbg(tunnel, "Updated group available BW: %d->%d\n", DPTUN_BW_ARG(tunnel->group->available_bw), DPTUN_BW_ARG(group_available_bw)); changed = tunnel->group->available_bw != group_available_bw; tunnel->group->available_bw = group_available_bw; return changed ? 1 : 0; } static int set_bw_alloc_mode(struct drm_dp_tunnel *tunnel, bool enable) { u8 mask = DP_DISPLAY_DRIVER_BW_ALLOCATION_MODE_ENABLE | DP_UNMASK_BW_ALLOCATION_IRQ; u8 val; if (drm_dp_dpcd_readb(tunnel->aux, DP_DPTX_BW_ALLOCATION_MODE_CONTROL, &val) < 0) goto out_err; if (enable) val |= mask; else val &= ~mask; if (drm_dp_dpcd_writeb(tunnel->aux, DP_DPTX_BW_ALLOCATION_MODE_CONTROL, val) < 0) goto out_err; tunnel->bw_alloc_enabled = enable; return 0; out_err: drm_dp_tunnel_set_io_error(tunnel); return -EIO; } /** * drm_dp_tunnel_enable_bw_alloc - Enable DP tunnel BW allocation mode * @tunnel: Tunnel object * * Enable the DP tunnel BW allocation mode on @tunnel if it supports it. * * Returns 0 in case of success, negative error code otherwise. */ int drm_dp_tunnel_enable_bw_alloc(struct drm_dp_tunnel *tunnel) { struct drm_dp_tunnel_regs regs; int err; err = check_tunnel(tunnel); if (err) return err; if (!tunnel->bw_alloc_supported) return -EOPNOTSUPP; if (!tunnel_group_id(tunnel->group->drv_group_id)) return -EINVAL; err = set_bw_alloc_mode(tunnel, true); if (err) goto out; /* * After a BWA disable/re-enable sequence the allocated BW can either * stay at its last requested value or, for instance after system * suspend/resume, TBT CM can reset back the allocation to the amount * allocated in the legacy/non-BWA mode. Accordingly allow for the * allocation to change wrt. the last SW state. */ err = read_and_verify_tunnel_regs(tunnel, ®s, ALLOW_ALLOCATED_BW_CHANGE); if (err) { set_bw_alloc_mode(tunnel, false); goto out; } if (!tunnel->max_dprx_rate) update_dprx_caps(tunnel, ®s); if (tunnel->group->available_bw == -1) { err = update_group_available_bw(tunnel, ®s); if (err > 0) err = 0; } out: tun_dbg_stat(tunnel, err, "Enabling BW alloc mode: DPRX:%dx%d Group alloc:%d/%d Mb/s", tunnel->max_dprx_rate / 100, tunnel->max_dprx_lane_count, DPTUN_BW_ARG(group_allocated_bw(tunnel->group)), DPTUN_BW_ARG(tunnel->group->available_bw)); return err; } EXPORT_SYMBOL(drm_dp_tunnel_enable_bw_alloc); /** * drm_dp_tunnel_disable_bw_alloc - Disable DP tunnel BW allocation mode * @tunnel: Tunnel object * * Disable the DP tunnel BW allocation mode on @tunnel. * * Returns 0 in case of success, negative error code otherwise. */ int drm_dp_tunnel_disable_bw_alloc(struct drm_dp_tunnel *tunnel) { int err; err = check_tunnel(tunnel); if (err) return err; tunnel->allocated_bw = -1; err = set_bw_alloc_mode(tunnel, false); tun_dbg_stat(tunnel, err, "Disabling BW alloc mode"); return err; } EXPORT_SYMBOL(drm_dp_tunnel_disable_bw_alloc); /** * drm_dp_tunnel_bw_alloc_is_enabled - Query the BW allocation mode enabled state * @tunnel: Tunnel object * * Query if the BW allocation mode is enabled for @tunnel. * * Returns %true if the BW allocation mode is enabled for @tunnel. */ bool drm_dp_tunnel_bw_alloc_is_enabled(const struct drm_dp_tunnel *tunnel) { return tunnel && tunnel->bw_alloc_enabled; } EXPORT_SYMBOL(drm_dp_tunnel_bw_alloc_is_enabled); static int clear_bw_req_state(struct drm_dp_aux *aux) { u8 bw_req_mask = DP_BW_REQUEST_SUCCEEDED | DP_BW_REQUEST_FAILED; if (drm_dp_dpcd_writeb(aux, DP_TUNNELING_STATUS, bw_req_mask) < 0) return -EIO; return 0; } static int bw_req_complete(struct drm_dp_aux *aux, bool *status_changed) { u8 bw_req_mask = DP_BW_REQUEST_SUCCEEDED | DP_BW_REQUEST_FAILED; u8 status_change_mask = DP_BW_ALLOCATION_CAPABILITY_CHANGED | DP_ESTIMATED_BW_CHANGED; u8 val; int err; if (drm_dp_dpcd_readb(aux, DP_TUNNELING_STATUS, &val) < 0) return -EIO; *status_changed = val & status_change_mask; val &= bw_req_mask; if (!val) return -EAGAIN; err = clear_bw_req_state(aux); if (err < 0) return err; return val == DP_BW_REQUEST_SUCCEEDED ? 0 : -ENOSPC; } static int allocate_tunnel_bw(struct drm_dp_tunnel *tunnel, int bw) { struct drm_dp_tunnel_mgr *mgr = tunnel->group->mgr; int request_bw = DIV_ROUND_UP(bw, tunnel->bw_granularity); DEFINE_WAIT_FUNC(wait, woken_wake_function); long timeout; int err; if (bw < 0) { err = -EINVAL; goto out; } if (request_bw * tunnel->bw_granularity == tunnel->allocated_bw) return 0; /* Atomic check should prevent the following. */ if (drm_WARN_ON(mgr->dev, request_bw > MAX_DP_REQUEST_BW)) { err = -EINVAL; goto out; } err = clear_bw_req_state(tunnel->aux); if (err) goto out; if (drm_dp_dpcd_writeb(tunnel->aux, DP_REQUEST_BW, request_bw) < 0) { err = -EIO; goto out; } timeout = msecs_to_jiffies(3000); add_wait_queue(&mgr->bw_req_queue, &wait); for (;;) { bool status_changed; err = bw_req_complete(tunnel->aux, &status_changed); if (err != -EAGAIN) break; if (status_changed) { struct drm_dp_tunnel_regs regs; err = read_and_verify_tunnel_regs(tunnel, ®s, ALLOW_ALLOCATED_BW_CHANGE); if (err) break; } if (!timeout) { err = -ETIMEDOUT; break; } timeout = wait_woken(&wait, TASK_UNINTERRUPTIBLE, timeout); }; remove_wait_queue(&mgr->bw_req_queue, &wait); if (err) goto out; tunnel->allocated_bw = request_bw * tunnel->bw_granularity; out: tun_dbg_stat(tunnel, err, "Allocating %d/%d Mb/s for tunnel: Group alloc:%d/%d Mb/s", DPTUN_BW_ARG(request_bw * tunnel->bw_granularity), DPTUN_BW_ARG(get_max_tunnel_bw(tunnel)), DPTUN_BW_ARG(group_allocated_bw(tunnel->group)), DPTUN_BW_ARG(tunnel->group->available_bw)); if (err == -EIO) drm_dp_tunnel_set_io_error(tunnel); return err; } /** * drm_dp_tunnel_alloc_bw - Allocate BW for a DP tunnel * @tunnel: Tunnel object * @bw: BW in kB/s units * * Allocate @bw kB/s for @tunnel. The allocated BW must be freed after use by * calling this function for the same tunnel setting @bw to 0. * * Returns 0 in case of success, a negative error code otherwise. */ int drm_dp_tunnel_alloc_bw(struct drm_dp_tunnel *tunnel, int bw) { int err; err = check_tunnel(tunnel); if (err) return err; return allocate_tunnel_bw(tunnel, bw); } EXPORT_SYMBOL(drm_dp_tunnel_alloc_bw); /** * drm_dp_tunnel_atomic_get_allocated_bw - Get the BW allocated for a DP tunnel * @tunnel: Tunnel object * * Get the current BW allocated for @tunnel. After the tunnel is created / * resumed and the BW allocation mode is enabled for it, the allocation * becomes determined only after the first allocation request by the driver * calling drm_dp_tunnel_alloc_bw(). * * Return the BW allocated for the tunnel, or -1 if the allocation is * undetermined. */ int drm_dp_tunnel_get_allocated_bw(struct drm_dp_tunnel *tunnel) { return tunnel->allocated_bw; } EXPORT_SYMBOL(drm_dp_tunnel_get_allocated_bw); /* * Return 0 if the status hasn't changed, 1 if the status has changed, a * negative error code in case of an I/O failure. */ static int check_and_clear_status_change(struct drm_dp_tunnel *tunnel) { u8 mask = DP_BW_ALLOCATION_CAPABILITY_CHANGED | DP_ESTIMATED_BW_CHANGED; u8 val; if (drm_dp_dpcd_readb(tunnel->aux, DP_TUNNELING_STATUS, &val) < 0) goto out_err; val &= mask; if (val) { if (drm_dp_dpcd_writeb(tunnel->aux, DP_TUNNELING_STATUS, val) < 0) goto out_err; return 1; } if (!drm_dp_tunnel_bw_alloc_is_enabled(tunnel)) return 0; /* * Check for estimated BW changes explicitly to account for lost * BW change notifications. */ if (drm_dp_dpcd_readb(tunnel->aux, DP_ESTIMATED_BW, &val) < 0) goto out_err; if (val * tunnel->bw_granularity != tunnel->estimated_bw) return 1; return 0; out_err: drm_dp_tunnel_set_io_error(tunnel); return -EIO; } /** * drm_dp_tunnel_update_state - Update DP tunnel SW state with the HW state * @tunnel: Tunnel object * * Update the SW state of @tunnel with the HW state. * * Returns 0 if the state has not changed, 1 if it has changed and got updated * successfully and a negative error code otherwise. */ int drm_dp_tunnel_update_state(struct drm_dp_tunnel *tunnel) { struct drm_dp_tunnel_regs regs; bool changed = false; int ret; ret = check_tunnel(tunnel); if (ret < 0) return ret; ret = check_and_clear_status_change(tunnel); if (ret < 0) goto out; if (!ret) return 0; ret = read_and_verify_tunnel_regs(tunnel, ®s, 0); if (ret) goto out; if (update_dprx_caps(tunnel, ®s)) changed = true; ret = update_group_available_bw(tunnel, ®s); if (ret == 1) changed = true; out: tun_dbg_stat(tunnel, ret < 0 ? ret : 0, "State update: Changed:%s DPRX:%dx%d Tunnel alloc:%d/%d Group alloc:%d/%d Mb/s", str_yes_no(changed), tunnel->max_dprx_rate / 100, tunnel->max_dprx_lane_count, DPTUN_BW_ARG(tunnel->allocated_bw), DPTUN_BW_ARG(get_max_tunnel_bw(tunnel)), DPTUN_BW_ARG(group_allocated_bw(tunnel->group)), DPTUN_BW_ARG(tunnel->group->available_bw)); if (ret < 0) return ret; if (changed) return 1; return 0; } EXPORT_SYMBOL(drm_dp_tunnel_update_state); /* * drm_dp_tunnel_handle_irq - Handle DP tunnel IRQs * * Handle any pending DP tunnel IRQs, waking up waiters for a completion * event. * * Returns 1 if the state of the tunnel has changed which requires calling * drm_dp_tunnel_update_state(), a negative error code in case of a failure, * 0 otherwise. */ int drm_dp_tunnel_handle_irq(struct drm_dp_tunnel_mgr *mgr, struct drm_dp_aux *aux) { u8 val; if (drm_dp_dpcd_readb(aux, DP_TUNNELING_STATUS, &val) < 0) return -EIO; if (val & (DP_BW_REQUEST_SUCCEEDED | DP_BW_REQUEST_FAILED)) wake_up_all(&mgr->bw_req_queue); if (val & (DP_BW_ALLOCATION_CAPABILITY_CHANGED | DP_ESTIMATED_BW_CHANGED)) return 1; return 0; } EXPORT_SYMBOL(drm_dp_tunnel_handle_irq); /** * drm_dp_tunnel_max_dprx_rate - Query the maximum rate of the tunnel's DPRX * @tunnel: Tunnel object * * The function is used to query the maximum link rate of the DPRX connected * to @tunnel. Note that this rate will not be limited by the BW limit of the * tunnel, as opposed to the standard and extended DP_MAX_LINK_RATE DPCD * registers. * * Returns the maximum link rate in 10 kbit/s units. */ int drm_dp_tunnel_max_dprx_rate(const struct drm_dp_tunnel *tunnel) { return tunnel->max_dprx_rate; } EXPORT_SYMBOL(drm_dp_tunnel_max_dprx_rate); /** * drm_dp_tunnel_max_dprx_lane_count - Query the maximum lane count of the tunnel's DPRX * @tunnel: Tunnel object * * The function is used to query the maximum lane count of the DPRX connected * to @tunnel. Note that this lane count will not be limited by the BW limit of * the tunnel, as opposed to the standard and extended DP_MAX_LANE_COUNT DPCD * registers. * * Returns the maximum lane count. */ int drm_dp_tunnel_max_dprx_lane_count(const struct drm_dp_tunnel *tunnel) { return tunnel->max_dprx_lane_count; } EXPORT_SYMBOL(drm_dp_tunnel_max_dprx_lane_count); /** * drm_dp_tunnel_available_bw - Query the estimated total available BW of the tunnel * @tunnel: Tunnel object * * This function is used to query the estimated total available BW of the * tunnel. This includes the currently allocated and free BW for all the * tunnels in @tunnel's group. The available BW is valid only after the BW * allocation mode has been enabled for the tunnel and its state got updated * calling drm_dp_tunnel_update_state(). * * Returns the @tunnel group's estimated total available bandwidth in kB/s * units, or -1 if the available BW isn't valid (the BW allocation mode is * not enabled or the tunnel's state hasn't been updated). */ int drm_dp_tunnel_available_bw(const struct drm_dp_tunnel *tunnel) { return tunnel->group->available_bw; } EXPORT_SYMBOL(drm_dp_tunnel_available_bw); static struct drm_dp_tunnel_group_state * drm_dp_tunnel_atomic_get_group_state(struct drm_atomic_state *state, const struct drm_dp_tunnel *tunnel) { return (struct drm_dp_tunnel_group_state *) drm_atomic_get_private_obj_state(state, &tunnel->group->base); } static struct drm_dp_tunnel_state * add_tunnel_state(struct drm_dp_tunnel_group_state *group_state, struct drm_dp_tunnel *tunnel) { struct drm_dp_tunnel_state *tunnel_state; tun_dbg_atomic(tunnel, "Adding state for tunnel %p to group state %p\n", tunnel, group_state); tunnel_state = kzalloc(sizeof(*tunnel_state), GFP_KERNEL); if (!tunnel_state) return NULL; tunnel_state->group_state = group_state; drm_dp_tunnel_ref_get(tunnel, &tunnel_state->tunnel_ref); INIT_LIST_HEAD(&tunnel_state->node); list_add(&tunnel_state->node, &group_state->tunnel_states); return tunnel_state; } static void free_tunnel_state(struct drm_dp_tunnel_state *tunnel_state) { tun_dbg_atomic(tunnel_state->tunnel_ref.tunnel, "Freeing state for tunnel %p\n", tunnel_state->tunnel_ref.tunnel); list_del(&tunnel_state->node); kfree(tunnel_state->stream_bw); drm_dp_tunnel_ref_put(&tunnel_state->tunnel_ref); kfree(tunnel_state); } static void free_group_state(struct drm_dp_tunnel_group_state *group_state) { struct drm_dp_tunnel_state *tunnel_state; struct drm_dp_tunnel_state *tunnel_state_tmp; for_each_tunnel_state_safe(group_state, tunnel_state, tunnel_state_tmp) free_tunnel_state(tunnel_state); kfree(group_state); } static struct drm_dp_tunnel_state * get_tunnel_state(struct drm_dp_tunnel_group_state *group_state, const struct drm_dp_tunnel *tunnel) { struct drm_dp_tunnel_state *tunnel_state; for_each_tunnel_state(group_state, tunnel_state) if (tunnel_state->tunnel_ref.tunnel == tunnel) return tunnel_state; return NULL; } static struct drm_dp_tunnel_state * get_or_add_tunnel_state(struct drm_dp_tunnel_group_state *group_state, struct drm_dp_tunnel *tunnel) { struct drm_dp_tunnel_state *tunnel_state; tunnel_state = get_tunnel_state(group_state, tunnel); if (tunnel_state) return tunnel_state; return add_tunnel_state(group_state, tunnel); } static struct drm_private_state * tunnel_group_duplicate_state(struct drm_private_obj *obj) { struct drm_dp_tunnel_group_state *group_state; struct drm_dp_tunnel_state *tunnel_state; group_state = kzalloc(sizeof(*group_state), GFP_KERNEL); if (!group_state) return NULL; INIT_LIST_HEAD(&group_state->tunnel_states); __drm_atomic_helper_private_obj_duplicate_state(obj, &group_state->base); for_each_tunnel_state(to_group_state(obj->state), tunnel_state) { struct drm_dp_tunnel_state *new_tunnel_state; new_tunnel_state = get_or_add_tunnel_state(group_state, tunnel_state->tunnel_ref.tunnel); if (!new_tunnel_state) goto out_free_state; new_tunnel_state->stream_mask = tunnel_state->stream_mask; new_tunnel_state->stream_bw = kmemdup(tunnel_state->stream_bw, sizeof(*tunnel_state->stream_bw) * hweight32(tunnel_state->stream_mask), GFP_KERNEL); if (!new_tunnel_state->stream_bw) goto out_free_state; } return &group_state->base; out_free_state: free_group_state(group_state); return NULL; } static void tunnel_group_destroy_state(struct drm_private_obj *obj, struct drm_private_state *state) { free_group_state(to_group_state(state)); } static const struct drm_private_state_funcs tunnel_group_funcs = { .atomic_duplicate_state = tunnel_group_duplicate_state, .atomic_destroy_state = tunnel_group_destroy_state, }; /** * drm_dp_tunnel_atomic_get_state - get/allocate the new atomic state for a tunnel * @state: Atomic state * @tunnel: Tunnel to get the state for * * Get the new atomic state for @tunnel, duplicating it from the old tunnel * state if not yet allocated. * * Return the state or an ERR_PTR() error on failure. */ struct drm_dp_tunnel_state * drm_dp_tunnel_atomic_get_state(struct drm_atomic_state *state, struct drm_dp_tunnel *tunnel) { struct drm_dp_tunnel_group_state *group_state; struct drm_dp_tunnel_state *tunnel_state; group_state = drm_dp_tunnel_atomic_get_group_state(state, tunnel); if (IS_ERR(group_state)) return ERR_CAST(group_state); tunnel_state = get_or_add_tunnel_state(group_state, tunnel); if (!tunnel_state) return ERR_PTR(-ENOMEM); return tunnel_state; } EXPORT_SYMBOL(drm_dp_tunnel_atomic_get_state); /** * drm_dp_tunnel_atomic_get_old_state - get the old atomic state for a tunnel * @state: Atomic state * @tunnel: Tunnel to get the state for * * Get the old atomic state for @tunnel. * * Return the old state or NULL if the tunnel's atomic state is not in @state. */ struct drm_dp_tunnel_state * drm_dp_tunnel_atomic_get_old_state(struct drm_atomic_state *state, const struct drm_dp_tunnel *tunnel) { struct drm_dp_tunnel_group_state *old_group_state; int i; for_each_old_group_in_state(state, old_group_state, i) if (to_group(old_group_state->base.obj) == tunnel->group) return get_tunnel_state(old_group_state, tunnel); return NULL; } EXPORT_SYMBOL(drm_dp_tunnel_atomic_get_old_state); /** * drm_dp_tunnel_atomic_get_new_state - get the new atomic state for a tunnel * @state: Atomic state * @tunnel: Tunnel to get the state for * * Get the new atomic state for @tunnel. * * Return the new state or NULL if the tunnel's atomic state is not in @state. */ struct drm_dp_tunnel_state * drm_dp_tunnel_atomic_get_new_state(struct drm_atomic_state *state, const struct drm_dp_tunnel *tunnel) { struct drm_dp_tunnel_group_state *new_group_state; int i; for_each_new_group_in_state(state, new_group_state, i) if (to_group(new_group_state->base.obj) == tunnel->group) return get_tunnel_state(new_group_state, tunnel); return NULL; } EXPORT_SYMBOL(drm_dp_tunnel_atomic_get_new_state); static bool init_group(struct drm_dp_tunnel_mgr *mgr, struct drm_dp_tunnel_group *group) { struct drm_dp_tunnel_group_state *group_state; group_state = kzalloc(sizeof(*group_state), GFP_KERNEL); if (!group_state) return false; INIT_LIST_HEAD(&group_state->tunnel_states); group->mgr = mgr; group->available_bw = -1; INIT_LIST_HEAD(&group->tunnels); drm_atomic_private_obj_init(mgr->dev, &group->base, &group_state->base, &tunnel_group_funcs); return true; } static void cleanup_group(struct drm_dp_tunnel_group *group) { drm_atomic_private_obj_fini(&group->base); } #ifdef CONFIG_DRM_DISPLAY_DEBUG_DP_TUNNEL_STATE static void check_unique_stream_ids(const struct drm_dp_tunnel_group_state *group_state) { const struct drm_dp_tunnel_state *tunnel_state; u32 stream_mask = 0; for_each_tunnel_state(group_state, tunnel_state) { drm_WARN(to_group(group_state->base.obj)->mgr->dev, tunnel_state->stream_mask & stream_mask, "[DPTUN %s]: conflicting stream IDs %x (IDs in other tunnels %x)\n", tunnel_state->tunnel_ref.tunnel->name, tunnel_state->stream_mask, stream_mask); stream_mask |= tunnel_state->stream_mask; } } #else static void check_unique_stream_ids(const struct drm_dp_tunnel_group_state *group_state) { } #endif static int stream_id_to_idx(u32 stream_mask, u8 stream_id) { return hweight32(stream_mask & (BIT(stream_id) - 1)); } static int resize_bw_array(struct drm_dp_tunnel_state *tunnel_state, unsigned long old_mask, unsigned long new_mask) { unsigned long move_mask = old_mask & new_mask; int *new_bws = NULL; int id; WARN_ON(!new_mask); if (old_mask == new_mask) return 0; new_bws = kcalloc(hweight32(new_mask), sizeof(*new_bws), GFP_KERNEL); if (!new_bws) return -ENOMEM; for_each_set_bit(id, &move_mask, BITS_PER_TYPE(move_mask)) new_bws[stream_id_to_idx(new_mask, id)] = tunnel_state->stream_bw[stream_id_to_idx(old_mask, id)]; kfree(tunnel_state->stream_bw); tunnel_state->stream_bw = new_bws; tunnel_state->stream_mask = new_mask; return 0; } static int set_stream_bw(struct drm_dp_tunnel_state *tunnel_state, u8 stream_id, int bw) { int err; err = resize_bw_array(tunnel_state, tunnel_state->stream_mask, tunnel_state->stream_mask | BIT(stream_id)); if (err) return err; tunnel_state->stream_bw[stream_id_to_idx(tunnel_state->stream_mask, stream_id)] = bw; return 0; } static int clear_stream_bw(struct drm_dp_tunnel_state *tunnel_state, u8 stream_id) { if (!(tunnel_state->stream_mask & ~BIT(stream_id))) { free_tunnel_state(tunnel_state); return 0; } return resize_bw_array(tunnel_state, tunnel_state->stream_mask, tunnel_state->stream_mask & ~BIT(stream_id)); } /** * drm_dp_tunnel_atomic_set_stream_bw - Set the BW for a DP tunnel stream * @state: Atomic state * @tunnel: DP tunnel containing the stream * @stream_id: Stream ID * @bw: BW of the stream * * Set a DP tunnel stream's required BW in the atomic state. * * Returns 0 in case of success, a negative error code otherwise. */ int drm_dp_tunnel_atomic_set_stream_bw(struct drm_atomic_state *state, struct drm_dp_tunnel *tunnel, u8 stream_id, int bw) { struct drm_dp_tunnel_group_state *new_group_state; struct drm_dp_tunnel_state *tunnel_state; int err; if (drm_WARN_ON(tunnel->group->mgr->dev, stream_id > BITS_PER_TYPE(tunnel_state->stream_mask))) return -EINVAL; tun_dbg(tunnel, "Setting %d Mb/s for stream %d\n", DPTUN_BW_ARG(bw), stream_id); new_group_state = drm_dp_tunnel_atomic_get_group_state(state, tunnel); if (IS_ERR(new_group_state)) return PTR_ERR(new_group_state); if (bw == 0) { tunnel_state = get_tunnel_state(new_group_state, tunnel); if (!tunnel_state) return 0; return clear_stream_bw(tunnel_state, stream_id); } tunnel_state = get_or_add_tunnel_state(new_group_state, tunnel); if (drm_WARN_ON(state->dev, !tunnel_state)) return -EINVAL; err = set_stream_bw(tunnel_state, stream_id, bw); if (err) return err; check_unique_stream_ids(new_group_state); return 0; } EXPORT_SYMBOL(drm_dp_tunnel_atomic_set_stream_bw); /** * drm_dp_tunnel_atomic_get_required_bw - Get the BW required by a DP tunnel * @tunnel_state: Atomic state of the queried tunnel * * Calculate the BW required by a tunnel adding up the required BW of all * the streams in the tunnel. * * Return the total BW required by the tunnel. */ int drm_dp_tunnel_atomic_get_required_bw(const struct drm_dp_tunnel_state *tunnel_state) { int tunnel_bw = 0; int i; if (!tunnel_state || !tunnel_state->stream_mask) return 0; for (i = 0; i < hweight32(tunnel_state->stream_mask); i++) tunnel_bw += tunnel_state->stream_bw[i]; return tunnel_bw; } EXPORT_SYMBOL(drm_dp_tunnel_atomic_get_required_bw); /** * drm_dp_tunnel_atomic_get_group_streams_in_state - Get mask of stream IDs in a group * @state: Atomic state * @tunnel: Tunnel object * @stream_mask: Mask of streams in @tunnel's group * * Get the mask of all the stream IDs in the tunnel group of @tunnel. * * Return 0 in case of success - with the stream IDs in @stream_mask - or a * negative error code in case of failure. */ int drm_dp_tunnel_atomic_get_group_streams_in_state(struct drm_atomic_state *state, const struct drm_dp_tunnel *tunnel, u32 *stream_mask) { struct drm_dp_tunnel_group_state *group_state; struct drm_dp_tunnel_state *tunnel_state; group_state = drm_dp_tunnel_atomic_get_group_state(state, tunnel); if (IS_ERR(group_state)) return PTR_ERR(group_state); *stream_mask = 0; for_each_tunnel_state(group_state, tunnel_state) *stream_mask |= tunnel_state->stream_mask; return 0; } EXPORT_SYMBOL(drm_dp_tunnel_atomic_get_group_streams_in_state); static int drm_dp_tunnel_atomic_check_group_bw(struct drm_dp_tunnel_group_state *new_group_state, u32 *failed_stream_mask) { struct drm_dp_tunnel_group *group = to_group(new_group_state->base.obj); struct drm_dp_tunnel_state *new_tunnel_state; u32 group_stream_mask = 0; int group_bw = 0; for_each_tunnel_state(new_group_state, new_tunnel_state) { struct drm_dp_tunnel *tunnel = new_tunnel_state->tunnel_ref.tunnel; int max_dprx_bw = get_max_dprx_bw(tunnel); int tunnel_bw = drm_dp_tunnel_atomic_get_required_bw(new_tunnel_state); tun_dbg(tunnel, "%sRequired %d/%d Mb/s total for tunnel.\n", tunnel_bw > max_dprx_bw ? "Not enough BW: " : "", DPTUN_BW_ARG(tunnel_bw), DPTUN_BW_ARG(max_dprx_bw)); if (tunnel_bw > max_dprx_bw) { *failed_stream_mask = new_tunnel_state->stream_mask; return -ENOSPC; } group_bw += min(roundup(tunnel_bw, tunnel->bw_granularity), max_dprx_bw); group_stream_mask |= new_tunnel_state->stream_mask; } tun_grp_dbg(group, "%sRequired %d/%d Mb/s total for tunnel group.\n", group_bw > group->available_bw ? "Not enough BW: " : "", DPTUN_BW_ARG(group_bw), DPTUN_BW_ARG(group->available_bw)); if (group_bw > group->available_bw) { *failed_stream_mask = group_stream_mask; return -ENOSPC; } return 0; } /** * drm_dp_tunnel_atomic_check_stream_bws - Check BW limit for all streams in state * @state: Atomic state * @failed_stream_mask: Mask of stream IDs with a BW limit failure * * Check the required BW of each DP tunnel in @state against both the DPRX BW * limit of the tunnel and the BW limit of the tunnel group. Return a mask of * stream IDs in @failed_stream_mask once a check fails. The mask will contain * either all the streams in a tunnel (in case a DPRX BW limit check failed) or * all the streams in a tunnel group (in case a group BW limit check failed). * * Return 0 if all the BW limit checks passed, -ENOSPC in case a BW limit * check failed - with @failed_stream_mask containing the streams failing the * check - or a negative error code otherwise. */ int drm_dp_tunnel_atomic_check_stream_bws(struct drm_atomic_state *state, u32 *failed_stream_mask) { struct drm_dp_tunnel_group_state *new_group_state; int i; for_each_new_group_in_state(state, new_group_state, i) { int ret; ret = drm_dp_tunnel_atomic_check_group_bw(new_group_state, failed_stream_mask); if (ret) return ret; } return 0; } EXPORT_SYMBOL(drm_dp_tunnel_atomic_check_stream_bws); static void destroy_mgr(struct drm_dp_tunnel_mgr *mgr) { int i; for (i = 0; i < mgr->group_count; i++) { cleanup_group(&mgr->groups[i]); drm_WARN_ON(mgr->dev, !list_empty(&mgr->groups[i].tunnels)); } #ifdef CONFIG_DRM_DISPLAY_DEBUG_DP_TUNNEL_STATE ref_tracker_dir_exit(&mgr->ref_tracker); #endif kfree(mgr->groups); kfree(mgr); } /** * drm_dp_tunnel_mgr_create - Create a DP tunnel manager * @dev: DRM device object * * Creates a DP tunnel manager for @dev. * * Returns a pointer to the tunnel manager if created successfully or NULL in * case of an error. */ struct drm_dp_tunnel_mgr * drm_dp_tunnel_mgr_create(struct drm_device *dev, int max_group_count) { struct drm_dp_tunnel_mgr *mgr; int i; mgr = kzalloc(sizeof(*mgr), GFP_KERNEL); if (!mgr) return NULL; mgr->dev = dev; init_waitqueue_head(&mgr->bw_req_queue); mgr->groups = kcalloc(max_group_count, sizeof(*mgr->groups), GFP_KERNEL); if (!mgr->groups) { kfree(mgr); return NULL; } #ifdef CONFIG_DRM_DISPLAY_DEBUG_DP_TUNNEL_STATE ref_tracker_dir_init(&mgr->ref_tracker, 16, "dptun"); #endif for (i = 0; i < max_group_count; i++) { if (!init_group(mgr, &mgr->groups[i])) { destroy_mgr(mgr); return NULL; } mgr->group_count++; } return mgr; } EXPORT_SYMBOL(drm_dp_tunnel_mgr_create); /** * drm_dp_tunnel_mgr_destroy - Destroy DP tunnel manager * @mgr: Tunnel manager object * * Destroy the tunnel manager. */ void drm_dp_tunnel_mgr_destroy(struct drm_dp_tunnel_mgr *mgr) { destroy_mgr(mgr); } EXPORT_SYMBOL(drm_dp_tunnel_mgr_destroy);