// SPDX-License-Identifier: MIT /* * Copyright © 2023 Intel Corporation */ #include "xe_gsc_proxy.h" #include #include #include #include #include #include "abi/gsc_proxy_commands_abi.h" #include "regs/xe_gsc_regs.h" #include "xe_bo.h" #include "xe_gsc.h" #include "xe_gsc_submit.h" #include "xe_gt.h" #include "xe_gt_printk.h" #include "xe_map.h" #include "xe_mmio.h" #include "xe_pm.h" /* * GSC proxy: * The GSC uC needs to communicate with the CSME to perform certain operations. * Since the GSC can't perform this communication directly on platforms where it * is integrated in GT, the graphics driver needs to transfer the messages from * GSC to CSME and back. The proxy flow must be manually started after the GSC * is loaded to signal to GSC that we're ready to handle its messages and allow * it to query its init data from CSME; GSC will then trigger an HECI2 interrupt * if it needs to send messages to CSME again. * The proxy flow is as follow: * 1 - Xe submits a request to GSC asking for the message to CSME * 2 - GSC replies with the proxy header + payload for CSME * 3 - Xe sends the reply from GSC as-is to CSME via the mei proxy component * 4 - CSME replies with the proxy header + payload for GSC * 5 - Xe submits a request to GSC with the reply from CSME * 6 - GSC replies either with a new header + payload (same as step 2, so we * restart from there) or with an end message. */ /* * The component should load quite quickly in most cases, but it could take * a bit. Using a very big timeout just to cover the worst case scenario */ #define GSC_PROXY_INIT_TIMEOUT_MS 20000 /* shorthand define for code compactness */ #define PROXY_HDR_SIZE (sizeof(struct xe_gsc_proxy_header)) /* the protocol supports up to 32K in each direction */ #define GSC_PROXY_BUFFER_SIZE SZ_32K #define GSC_PROXY_CHANNEL_SIZE (GSC_PROXY_BUFFER_SIZE * 2) static struct xe_gt * gsc_to_gt(struct xe_gsc *gsc) { return container_of(gsc, struct xe_gt, uc.gsc); } static inline struct xe_device *kdev_to_xe(struct device *kdev) { return dev_get_drvdata(kdev); } static bool gsc_proxy_init_done(struct xe_gsc *gsc) { struct xe_gt *gt = gsc_to_gt(gsc); u32 fwsts1 = xe_mmio_read32(gt, HECI_FWSTS1(MTL_GSC_HECI1_BASE)); return REG_FIELD_GET(HECI1_FWSTS1_CURRENT_STATE, fwsts1) == HECI1_FWSTS1_PROXY_STATE_NORMAL; } static void __gsc_proxy_irq_rmw(struct xe_gsc *gsc, u32 clr, u32 set) { struct xe_gt *gt = gsc_to_gt(gsc); /* make sure we never accidentally write the RST bit */ clr |= HECI_H_CSR_RST; xe_mmio_rmw32(gt, HECI_H_CSR(MTL_GSC_HECI2_BASE), clr, set); } static void gsc_proxy_irq_clear(struct xe_gsc *gsc) { /* The status bit is cleared by writing to it */ __gsc_proxy_irq_rmw(gsc, 0, HECI_H_CSR_IS); } static void gsc_proxy_irq_toggle(struct xe_gsc *gsc, bool enabled) { u32 set = enabled ? HECI_H_CSR_IE : 0; u32 clr = enabled ? 0 : HECI_H_CSR_IE; __gsc_proxy_irq_rmw(gsc, clr, set); } static int proxy_send_to_csme(struct xe_gsc *gsc, u32 size) { struct xe_gt *gt = gsc_to_gt(gsc); struct i915_gsc_proxy_component *comp = gsc->proxy.component; int ret; ret = comp->ops->send(comp->mei_dev, gsc->proxy.to_csme, size); if (ret < 0) { xe_gt_err(gt, "Failed to send CSME proxy message\n"); return ret; } ret = comp->ops->recv(comp->mei_dev, gsc->proxy.from_csme, GSC_PROXY_BUFFER_SIZE); if (ret < 0) { xe_gt_err(gt, "Failed to receive CSME proxy message\n"); return ret; } return ret; } static int proxy_send_to_gsc(struct xe_gsc *gsc, u32 size) { struct xe_gt *gt = gsc_to_gt(gsc); u64 addr_in = xe_bo_ggtt_addr(gsc->proxy.bo); u64 addr_out = addr_in + GSC_PROXY_BUFFER_SIZE; int err; /* the message must contain at least the gsc and proxy headers */ if (size > GSC_PROXY_BUFFER_SIZE) { xe_gt_err(gt, "Invalid GSC proxy message size: %u\n", size); return -EINVAL; } err = xe_gsc_pkt_submit_kernel(gsc, addr_in, size, addr_out, GSC_PROXY_BUFFER_SIZE); if (err) { xe_gt_err(gt, "Failed to submit gsc proxy rq (%pe)\n", ERR_PTR(err)); return err; } return 0; } static int validate_proxy_header(struct xe_gsc_proxy_header *header, u32 source, u32 dest, u32 max_size) { u32 type = FIELD_GET(GSC_PROXY_TYPE, header->hdr); u32 length = FIELD_GET(GSC_PROXY_PAYLOAD_LENGTH, header->hdr); if (header->destination != dest || header->source != source) return -ENOEXEC; if (length + PROXY_HDR_SIZE > max_size) return -E2BIG; switch (type) { case GSC_PROXY_MSG_TYPE_PROXY_PAYLOAD: if (length > 0) break; fallthrough; case GSC_PROXY_MSG_TYPE_PROXY_INVALID: return -EIO; default: break; } return 0; } #define proxy_header_wr(xe_, map_, offset_, field_, val_) \ xe_map_wr_field(xe_, map_, offset_, struct xe_gsc_proxy_header, field_, val_) #define proxy_header_rd(xe_, map_, offset_, field_) \ xe_map_rd_field(xe_, map_, offset_, struct xe_gsc_proxy_header, field_) static u32 emit_proxy_header(struct xe_device *xe, struct iosys_map *map, u32 offset) { xe_map_memset(xe, map, offset, 0, PROXY_HDR_SIZE); proxy_header_wr(xe, map, offset, hdr, FIELD_PREP(GSC_PROXY_TYPE, GSC_PROXY_MSG_TYPE_PROXY_QUERY) | FIELD_PREP(GSC_PROXY_PAYLOAD_LENGTH, 0)); proxy_header_wr(xe, map, offset, source, GSC_PROXY_ADDRESSING_KMD); proxy_header_wr(xe, map, offset, destination, GSC_PROXY_ADDRESSING_GSC); proxy_header_wr(xe, map, offset, status, 0); return offset + PROXY_HDR_SIZE; } static int proxy_query(struct xe_gsc *gsc) { struct xe_gt *gt = gsc_to_gt(gsc); struct xe_device *xe = gt_to_xe(gt); struct xe_gsc_proxy_header *to_csme_hdr = gsc->proxy.to_csme; void *to_csme_payload = gsc->proxy.to_csme + PROXY_HDR_SIZE; u32 wr_offset; u32 reply_offset; u32 size; int ret; wr_offset = xe_gsc_emit_header(xe, &gsc->proxy.to_gsc, 0, HECI_MEADDRESS_PROXY, 0, PROXY_HDR_SIZE); wr_offset = emit_proxy_header(xe, &gsc->proxy.to_gsc, wr_offset); size = wr_offset; while (1) { /* * Poison the GSC response header space to make sure we don't * read a stale reply. */ xe_gsc_poison_header(xe, &gsc->proxy.from_gsc, 0); /* send proxy message to GSC */ ret = proxy_send_to_gsc(gsc, size); if (ret) goto proxy_error; /* check the reply from GSC */ ret = xe_gsc_read_out_header(xe, &gsc->proxy.from_gsc, 0, PROXY_HDR_SIZE, &reply_offset); if (ret) { xe_gt_err(gt, "Invalid gsc header in proxy reply (%pe)\n", ERR_PTR(ret)); goto proxy_error; } /* copy the proxy header reply from GSC */ xe_map_memcpy_from(xe, to_csme_hdr, &gsc->proxy.from_gsc, reply_offset, PROXY_HDR_SIZE); /* stop if this was the last message */ if (FIELD_GET(GSC_PROXY_TYPE, to_csme_hdr->hdr) == GSC_PROXY_MSG_TYPE_PROXY_END) break; /* make sure the GSC-to-CSME proxy header is sane */ ret = validate_proxy_header(to_csme_hdr, GSC_PROXY_ADDRESSING_GSC, GSC_PROXY_ADDRESSING_CSME, GSC_PROXY_BUFFER_SIZE - reply_offset); if (ret) { xe_gt_err(gt, "invalid GSC to CSME proxy header! (%pe)\n", ERR_PTR(ret)); goto proxy_error; } /* copy the rest of the message */ size = FIELD_GET(GSC_PROXY_PAYLOAD_LENGTH, to_csme_hdr->hdr); xe_map_memcpy_from(xe, to_csme_payload, &gsc->proxy.from_gsc, reply_offset + PROXY_HDR_SIZE, size); /* send the GSC message to the CSME */ ret = proxy_send_to_csme(gsc, size + PROXY_HDR_SIZE); if (ret < 0) goto proxy_error; /* reply size from CSME, including the proxy header */ size = ret; if (size < PROXY_HDR_SIZE) { xe_gt_err(gt, "CSME to GSC proxy msg too small: 0x%x\n", size); ret = -EPROTO; goto proxy_error; } /* make sure the CSME-to-GSC proxy header is sane */ ret = validate_proxy_header(gsc->proxy.from_csme, GSC_PROXY_ADDRESSING_CSME, GSC_PROXY_ADDRESSING_GSC, GSC_PROXY_BUFFER_SIZE - reply_offset); if (ret) { xe_gt_err(gt, "invalid CSME to GSC proxy header! %d\n", ret); goto proxy_error; } /* Emit a new header for sending the reply to the GSC */ wr_offset = xe_gsc_emit_header(xe, &gsc->proxy.to_gsc, 0, HECI_MEADDRESS_PROXY, 0, size); /* copy the CSME reply and update the total msg size to include the GSC header */ xe_map_memcpy_to(xe, &gsc->proxy.to_gsc, wr_offset, gsc->proxy.from_csme, size); size += wr_offset; } proxy_error: return ret < 0 ? ret : 0; } int xe_gsc_proxy_request_handler(struct xe_gsc *gsc) { struct xe_gt *gt = gsc_to_gt(gsc); int slept; int err; if (!gsc->proxy.component_added) return -ENODEV; /* when GSC is loaded, we can queue this before the component is bound */ for (slept = 0; slept < GSC_PROXY_INIT_TIMEOUT_MS; slept += 100) { if (gsc->proxy.component) break; msleep(100); } mutex_lock(&gsc->proxy.mutex); if (!gsc->proxy.component) { xe_gt_err(gt, "GSC proxy component not bound!\n"); err = -EIO; } else { /* * clear the pending interrupt and allow new proxy requests to * be generated while we handle the current one */ gsc_proxy_irq_clear(gsc); err = proxy_query(gsc); } mutex_unlock(&gsc->proxy.mutex); return err; } void xe_gsc_proxy_irq_handler(struct xe_gsc *gsc, u32 iir) { struct xe_gt *gt = gsc_to_gt(gsc); if (unlikely(!iir)) return; if (!gsc->proxy.component) { xe_gt_err(gt, "GSC proxy irq received without the component being bound!\n"); return; } spin_lock(&gsc->lock); gsc->work_actions |= GSC_ACTION_SW_PROXY; spin_unlock(&gsc->lock); queue_work(gsc->wq, &gsc->work); } static int xe_gsc_proxy_component_bind(struct device *xe_kdev, struct device *mei_kdev, void *data) { struct xe_device *xe = kdev_to_xe(xe_kdev); struct xe_gt *gt = xe->tiles[0].media_gt; struct xe_gsc *gsc = >->uc.gsc; mutex_lock(&gsc->proxy.mutex); gsc->proxy.component = data; gsc->proxy.component->mei_dev = mei_kdev; mutex_unlock(&gsc->proxy.mutex); return 0; } static void xe_gsc_proxy_component_unbind(struct device *xe_kdev, struct device *mei_kdev, void *data) { struct xe_device *xe = kdev_to_xe(xe_kdev); struct xe_gt *gt = xe->tiles[0].media_gt; struct xe_gsc *gsc = >->uc.gsc; xe_gsc_wait_for_worker_completion(gsc); mutex_lock(&gsc->proxy.mutex); gsc->proxy.component = NULL; mutex_unlock(&gsc->proxy.mutex); } static const struct component_ops xe_gsc_proxy_component_ops = { .bind = xe_gsc_proxy_component_bind, .unbind = xe_gsc_proxy_component_unbind, }; static void proxy_channel_free(struct drm_device *drm, void *arg) { struct xe_gsc *gsc = arg; if (!gsc->proxy.bo) return; if (gsc->proxy.to_csme) { kfree(gsc->proxy.to_csme); gsc->proxy.to_csme = NULL; gsc->proxy.from_csme = NULL; } if (gsc->proxy.bo) { iosys_map_clear(&gsc->proxy.to_gsc); iosys_map_clear(&gsc->proxy.from_gsc); xe_bo_unpin_map_no_vm(gsc->proxy.bo); gsc->proxy.bo = NULL; } } static int proxy_channel_alloc(struct xe_gsc *gsc) { struct xe_gt *gt = gsc_to_gt(gsc); struct xe_tile *tile = gt_to_tile(gt); struct xe_device *xe = gt_to_xe(gt); struct xe_bo *bo; void *csme; int err; csme = kzalloc(GSC_PROXY_CHANNEL_SIZE, GFP_KERNEL); if (!csme) return -ENOMEM; bo = xe_bo_create_pin_map(xe, tile, NULL, GSC_PROXY_CHANNEL_SIZE, ttm_bo_type_kernel, XE_BO_CREATE_SYSTEM_BIT | XE_BO_CREATE_GGTT_BIT); if (IS_ERR(bo)) { kfree(csme); return PTR_ERR(bo); } gsc->proxy.bo = bo; gsc->proxy.to_gsc = IOSYS_MAP_INIT_OFFSET(&bo->vmap, 0); gsc->proxy.from_gsc = IOSYS_MAP_INIT_OFFSET(&bo->vmap, GSC_PROXY_BUFFER_SIZE); gsc->proxy.to_csme = csme; gsc->proxy.from_csme = csme + GSC_PROXY_BUFFER_SIZE; err = drmm_add_action_or_reset(&xe->drm, proxy_channel_free, gsc); if (err) return err; return 0; } /** * xe_gsc_proxy_init() - init objects and MEI component required by GSC proxy * @gsc: the GSC uC * * Return: 0 if the initialization was successful, a negative errno otherwise. */ int xe_gsc_proxy_init(struct xe_gsc *gsc) { int err; struct xe_gt *gt = gsc_to_gt(gsc); struct xe_tile *tile = gt_to_tile(gt); struct xe_device *xe = tile_to_xe(tile); mutex_init(&gsc->proxy.mutex); if (!IS_ENABLED(CONFIG_INTEL_MEI_GSC_PROXY)) { xe_gt_info(gt, "can't init GSC proxy due to missing mei component\n"); return -ENODEV; } /* no multi-tile devices with this feature yet */ if (tile->id > 0) { xe_gt_err(gt, "unexpected GSC proxy init on tile %u\n", tile->id); return -EINVAL; } err = proxy_channel_alloc(gsc); if (err) return err; err = component_add_typed(xe->drm.dev, &xe_gsc_proxy_component_ops, I915_COMPONENT_GSC_PROXY); if (err < 0) { xe_gt_err(gt, "Failed to add GSC_PROXY component (%pe)\n", ERR_PTR(err)); return err; } gsc->proxy.component_added = true; /* the component must be removed before unload, so can't use drmm for cleanup */ return 0; } /** * xe_gsc_proxy_remove() - remove the GSC proxy MEI component * @gsc: the GSC uC */ void xe_gsc_proxy_remove(struct xe_gsc *gsc) { struct xe_gt *gt = gsc_to_gt(gsc); struct xe_device *xe = gt_to_xe(gt); int err = 0; if (!gsc->proxy.component_added) return; /* disable HECI2 IRQs */ xe_pm_runtime_get(xe); err = xe_force_wake_get(gt_to_fw(gt), XE_FW_GSC); if (err) xe_gt_err(gt, "failed to get forcewake to disable GSC interrupts\n"); /* try do disable irq even if forcewake failed */ gsc_proxy_irq_toggle(gsc, false); if (!err) xe_force_wake_put(gt_to_fw(gt), XE_FW_GSC); xe_pm_runtime_put(xe); xe_gsc_wait_for_worker_completion(gsc); component_del(xe->drm.dev, &xe_gsc_proxy_component_ops); gsc->proxy.component_added = false; } /** * xe_gsc_proxy_start() - start the proxy by submitting the first request * @gsc: the GSC uC * * Return: 0 if the proxy are now enabled, a negative errno otherwise. */ int xe_gsc_proxy_start(struct xe_gsc *gsc) { int err; /* enable the proxy interrupt in the GSC shim layer */ gsc_proxy_irq_toggle(gsc, true); /* * The handling of the first proxy request must be manually triggered to * notify the GSC that we're ready to support the proxy flow. */ err = xe_gsc_proxy_request_handler(gsc); if (err) return err; if (!gsc_proxy_init_done(gsc)) { xe_gt_err(gsc_to_gt(gsc), "GSC FW reports proxy init not completed\n"); return -EIO; } return 0; }