/* * Copyright © 2014 Intel Corporation * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice (including the next * paragraph) shall be included in all copies or substantial portions of the * Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS * IN THE SOFTWARE. * */ #include #include #include #include #include #include "i915_reg.h" #include "i915_utils.h" #include "intel_crtc.h" #include "intel_de.h" #include "intel_display_power_well.h" #include "intel_display_regs.h" #include "intel_display_rpm.h" #include "intel_display_types.h" #include "intel_dmc.h" #include "intel_dmc_regs.h" #include "intel_flipq.h" #include "intel_step.h" /** * DOC: DMC Firmware Support * * From gen9 onwards we have newly added DMC (Display microcontroller) in display * engine to save and restore the state of display engine when it enter into * low-power state and comes back to normal. */ #define INTEL_DMC_FIRMWARE_URL "https://git.kernel.org/pub/scm/linux/kernel/git/firmware/linux-firmware.git" enum intel_dmc_id { DMC_FW_MAIN = 0, DMC_FW_PIPEA, DMC_FW_PIPEB, DMC_FW_PIPEC, DMC_FW_PIPED, DMC_FW_MAX }; struct intel_dmc { struct intel_display *display; struct work_struct work; const char *fw_path; u32 max_fw_size; /* bytes */ u32 version; struct { u32 dc5_start; u32 count; } dc6_allowed; struct dmc_fw_info { u32 mmio_count; i915_reg_t mmioaddr[20]; u32 mmiodata[20]; u32 dmc_offset; u32 start_mmioaddr; u32 dmc_fw_size; /*dwords */ u32 *payload; bool present; } dmc_info[DMC_FW_MAX]; }; /* Note: This may be NULL. */ static struct intel_dmc *display_to_dmc(struct intel_display *display) { return display->dmc.dmc; } static const char *dmc_firmware_param(struct intel_display *display) { const char *p = display->params.dmc_firmware_path; return p && *p ? p : NULL; } static bool dmc_firmware_param_disabled(struct intel_display *display) { const char *p = dmc_firmware_param(display); /* Magic path to indicate disabled */ return p && !strcmp(p, "/dev/null"); } #define DMC_VERSION(major, minor) ((major) << 16 | (minor)) #define DMC_VERSION_MAJOR(version) ((version) >> 16) #define DMC_VERSION_MINOR(version) ((version) & 0xffff) #define DMC_PATH(platform) \ "i915/" __stringify(platform) "_dmc.bin" /* * New DMC additions should not use this. This is used solely to remain * compatible with systems that have not yet updated DMC blobs to use * unversioned file names. */ #define DMC_LEGACY_PATH(platform, major, minor) \ "i915/" \ __stringify(platform) "_dmc_ver" \ __stringify(major) "_" \ __stringify(minor) ".bin" #define XE2LPD_DMC_MAX_FW_SIZE 0x8000 #define XELPDP_DMC_MAX_FW_SIZE 0x7000 #define DISPLAY_VER13_DMC_MAX_FW_SIZE 0x20000 #define DISPLAY_VER12_DMC_MAX_FW_SIZE ICL_DMC_MAX_FW_SIZE #define XE3LPD_DMC_PATH DMC_PATH(xe3lpd) MODULE_FIRMWARE(XE3LPD_DMC_PATH); #define XE2LPD_DMC_PATH DMC_PATH(xe2lpd) MODULE_FIRMWARE(XE2LPD_DMC_PATH); #define BMG_DMC_PATH DMC_PATH(bmg) MODULE_FIRMWARE(BMG_DMC_PATH); #define MTL_DMC_PATH DMC_PATH(mtl) MODULE_FIRMWARE(MTL_DMC_PATH); #define DG2_DMC_PATH DMC_LEGACY_PATH(dg2, 2, 08) MODULE_FIRMWARE(DG2_DMC_PATH); #define ADLP_DMC_PATH DMC_PATH(adlp) #define ADLP_DMC_FALLBACK_PATH DMC_LEGACY_PATH(adlp, 2, 16) MODULE_FIRMWARE(ADLP_DMC_PATH); MODULE_FIRMWARE(ADLP_DMC_FALLBACK_PATH); #define ADLS_DMC_PATH DMC_LEGACY_PATH(adls, 2, 01) MODULE_FIRMWARE(ADLS_DMC_PATH); #define DG1_DMC_PATH DMC_LEGACY_PATH(dg1, 2, 02) MODULE_FIRMWARE(DG1_DMC_PATH); #define RKL_DMC_PATH DMC_LEGACY_PATH(rkl, 2, 03) MODULE_FIRMWARE(RKL_DMC_PATH); #define TGL_DMC_PATH DMC_LEGACY_PATH(tgl, 2, 12) MODULE_FIRMWARE(TGL_DMC_PATH); #define ICL_DMC_PATH DMC_LEGACY_PATH(icl, 1, 09) #define ICL_DMC_MAX_FW_SIZE 0x6000 MODULE_FIRMWARE(ICL_DMC_PATH); #define GLK_DMC_PATH DMC_LEGACY_PATH(glk, 1, 04) #define GLK_DMC_MAX_FW_SIZE 0x4000 MODULE_FIRMWARE(GLK_DMC_PATH); #define KBL_DMC_PATH DMC_LEGACY_PATH(kbl, 1, 04) #define KBL_DMC_MAX_FW_SIZE BXT_DMC_MAX_FW_SIZE MODULE_FIRMWARE(KBL_DMC_PATH); #define SKL_DMC_PATH DMC_LEGACY_PATH(skl, 1, 27) #define SKL_DMC_MAX_FW_SIZE BXT_DMC_MAX_FW_SIZE MODULE_FIRMWARE(SKL_DMC_PATH); #define BXT_DMC_PATH DMC_LEGACY_PATH(bxt, 1, 07) #define BXT_DMC_MAX_FW_SIZE 0x3000 MODULE_FIRMWARE(BXT_DMC_PATH); static const char *dmc_firmware_default(struct intel_display *display, u32 *size) { const char *fw_path = NULL; u32 max_fw_size = 0; if (DISPLAY_VERx100(display) == 3002 || DISPLAY_VERx100(display) == 3000) { fw_path = XE3LPD_DMC_PATH; max_fw_size = XE2LPD_DMC_MAX_FW_SIZE; } else if (DISPLAY_VERx100(display) == 2000) { fw_path = XE2LPD_DMC_PATH; max_fw_size = XE2LPD_DMC_MAX_FW_SIZE; } else if (DISPLAY_VERx100(display) == 1401) { fw_path = BMG_DMC_PATH; max_fw_size = XELPDP_DMC_MAX_FW_SIZE; } else if (DISPLAY_VERx100(display) == 1400) { fw_path = MTL_DMC_PATH; max_fw_size = XELPDP_DMC_MAX_FW_SIZE; } else if (display->platform.dg2) { fw_path = DG2_DMC_PATH; max_fw_size = DISPLAY_VER13_DMC_MAX_FW_SIZE; } else if (display->platform.alderlake_p) { fw_path = ADLP_DMC_PATH; max_fw_size = DISPLAY_VER13_DMC_MAX_FW_SIZE; } else if (display->platform.alderlake_s) { fw_path = ADLS_DMC_PATH; max_fw_size = DISPLAY_VER12_DMC_MAX_FW_SIZE; } else if (display->platform.dg1) { fw_path = DG1_DMC_PATH; max_fw_size = DISPLAY_VER12_DMC_MAX_FW_SIZE; } else if (display->platform.rocketlake) { fw_path = RKL_DMC_PATH; max_fw_size = DISPLAY_VER12_DMC_MAX_FW_SIZE; } else if (display->platform.tigerlake) { fw_path = TGL_DMC_PATH; max_fw_size = DISPLAY_VER12_DMC_MAX_FW_SIZE; } else if (DISPLAY_VER(display) == 11) { fw_path = ICL_DMC_PATH; max_fw_size = ICL_DMC_MAX_FW_SIZE; } else if (display->platform.geminilake) { fw_path = GLK_DMC_PATH; max_fw_size = GLK_DMC_MAX_FW_SIZE; } else if (display->platform.kabylake || display->platform.coffeelake || display->platform.cometlake) { fw_path = KBL_DMC_PATH; max_fw_size = KBL_DMC_MAX_FW_SIZE; } else if (display->platform.skylake) { fw_path = SKL_DMC_PATH; max_fw_size = SKL_DMC_MAX_FW_SIZE; } else if (display->platform.broxton) { fw_path = BXT_DMC_PATH; max_fw_size = BXT_DMC_MAX_FW_SIZE; } *size = max_fw_size; return fw_path; } #define DMC_DEFAULT_FW_OFFSET 0xFFFFFFFF #define PACKAGE_MAX_FW_INFO_ENTRIES 20 #define PACKAGE_V2_MAX_FW_INFO_ENTRIES 32 #define DMC_V1_MAX_MMIO_COUNT 8 #define DMC_V3_MAX_MMIO_COUNT 20 #define DMC_V1_MMIO_START_RANGE 0x80000 #define PIPE_TO_DMC_ID(pipe) (DMC_FW_PIPEA + ((pipe) - PIPE_A)) struct intel_css_header { /* 0x09 for DMC */ u32 module_type; /* Includes the DMC specific header in dwords */ u32 header_len; /* always value would be 0x10000 */ u32 header_ver; /* Not used */ u32 module_id; /* Not used */ u32 module_vendor; /* in YYYYMMDD format */ u32 date; /* Size in dwords (CSS_Headerlen + PackageHeaderLen + dmc FWsLen)/4 */ u32 size; /* Not used */ u32 key_size; /* Not used */ u32 modulus_size; /* Not used */ u32 exponent_size; /* Not used */ u32 reserved1[12]; /* Major Minor */ u32 version; /* Not used */ u32 reserved2[8]; /* Not used */ u32 kernel_header_info; } __packed; struct intel_fw_info { u8 reserved1; /* reserved on package_header version 1, must be 0 on version 2 */ u8 dmc_id; /* Stepping (A, B, C, ..., *). * is a wildcard */ char stepping; /* Sub-stepping (0, 1, ..., *). * is a wildcard */ char substepping; u32 offset; u32 reserved2; } __packed; struct intel_package_header { /* DMC container header length in dwords */ u8 header_len; /* 0x01, 0x02 */ u8 header_ver; u8 reserved[10]; /* Number of valid entries in the FWInfo array below */ u32 num_entries; } __packed; struct intel_dmc_header_base { /* always value would be 0x40403E3E */ u32 signature; /* DMC binary header length */ u8 header_len; /* 0x01 */ u8 header_ver; /* Reserved */ u16 dmcc_ver; /* Major, Minor */ u32 project; /* Firmware program size (excluding header) in dwords */ u32 fw_size; /* Major Minor version */ u32 fw_version; } __packed; struct intel_dmc_header_v1 { struct intel_dmc_header_base base; /* Number of valid MMIO cycles present. */ u32 mmio_count; /* MMIO address */ u32 mmioaddr[DMC_V1_MAX_MMIO_COUNT]; /* MMIO data */ u32 mmiodata[DMC_V1_MAX_MMIO_COUNT]; /* FW filename */ char dfile[32]; u32 reserved1[2]; } __packed; struct intel_dmc_header_v3 { struct intel_dmc_header_base base; /* DMC RAM start MMIO address */ u32 start_mmioaddr; u32 reserved[9]; /* FW filename */ char dfile[32]; /* Number of valid MMIO cycles present. */ u32 mmio_count; /* MMIO address */ u32 mmioaddr[DMC_V3_MAX_MMIO_COUNT]; /* MMIO data */ u32 mmiodata[DMC_V3_MAX_MMIO_COUNT]; } __packed; struct stepping_info { char stepping; char substepping; }; #define for_each_dmc_id(__dmc_id) \ for ((__dmc_id) = DMC_FW_MAIN; (__dmc_id) < DMC_FW_MAX; (__dmc_id)++) static bool is_valid_dmc_id(enum intel_dmc_id dmc_id) { return dmc_id >= DMC_FW_MAIN && dmc_id < DMC_FW_MAX; } static bool has_dmc_id_fw(struct intel_display *display, enum intel_dmc_id dmc_id) { struct intel_dmc *dmc = display_to_dmc(display); return dmc && dmc->dmc_info[dmc_id].payload; } bool intel_dmc_has_payload(struct intel_display *display) { return has_dmc_id_fw(display, DMC_FW_MAIN); } static const struct stepping_info * intel_get_stepping_info(struct intel_display *display, struct stepping_info *si) { const char *step_name = intel_step_name(INTEL_DISPLAY_STEP(display)); si->stepping = step_name[0]; si->substepping = step_name[1]; return si; } static void gen9_set_dc_state_debugmask(struct intel_display *display) { /* The below bit doesn't need to be cleared ever afterwards */ intel_de_rmw(display, DC_STATE_DEBUG, 0, DC_STATE_DEBUG_MASK_CORES | DC_STATE_DEBUG_MASK_MEMORY_UP); intel_de_posting_read(display, DC_STATE_DEBUG); } static void disable_event_handler(struct intel_display *display, i915_reg_t ctl_reg, i915_reg_t htp_reg) { intel_de_write(display, ctl_reg, REG_FIELD_PREP(DMC_EVT_CTL_TYPE_MASK, DMC_EVT_CTL_TYPE_EDGE_0_1) | REG_FIELD_PREP(DMC_EVT_CTL_EVENT_ID_MASK, DMC_EVENT_FALSE)); intel_de_write(display, htp_reg, 0); } static void disable_all_event_handlers(struct intel_display *display, enum intel_dmc_id dmc_id) { int handler; /* TODO: disable the event handlers on pre-GEN12 platforms as well */ if (DISPLAY_VER(display) < 12) return; if (!has_dmc_id_fw(display, dmc_id)) return; for (handler = 0; handler < DMC_EVENT_HANDLER_COUNT_GEN12; handler++) disable_event_handler(display, DMC_EVT_CTL(display, dmc_id, handler), DMC_EVT_HTP(display, dmc_id, handler)); } static void adlp_pipedmc_clock_gating_wa(struct intel_display *display, bool enable) { enum pipe pipe; /* * Wa_16015201720:adl-p,dg2 * The WA requires clock gating to be disabled all the time * for pipe A and B. * For pipe C and D clock gating needs to be disabled only * during initializing the firmware. */ if (enable) for (pipe = PIPE_A; pipe <= PIPE_D; pipe++) intel_de_rmw(display, CLKGATE_DIS_PSL_EXT(pipe), 0, PIPEDMC_GATING_DIS); else for (pipe = PIPE_C; pipe <= PIPE_D; pipe++) intel_de_rmw(display, CLKGATE_DIS_PSL_EXT(pipe), PIPEDMC_GATING_DIS, 0); } static void mtl_pipedmc_clock_gating_wa(struct intel_display *display) { /* * Wa_16015201720 * The WA requires clock gating to be disabled all the time * for pipe A and B. */ intel_de_rmw(display, GEN9_CLKGATE_DIS_0, 0, MTL_PIPEDMC_GATING_DIS(PIPE_A) | MTL_PIPEDMC_GATING_DIS(PIPE_B)); } static void pipedmc_clock_gating_wa(struct intel_display *display, bool enable) { if (display->platform.meteorlake && enable) mtl_pipedmc_clock_gating_wa(display); else if (DISPLAY_VER(display) == 13) adlp_pipedmc_clock_gating_wa(display, enable); } static u32 pipedmc_interrupt_mask(struct intel_display *display) { /* * FIXME PIPEDMC_ERROR not enabled for now due to LNL pipe B * triggering it during the first DC state transition. Figure * out what is going on... */ return PIPEDMC_FLIPQ_PROG_DONE | PIPEDMC_GTT_FAULT | PIPEDMC_ATS_FAULT; } static u32 dmc_evt_ctl_disable(void) { return REG_FIELD_PREP(DMC_EVT_CTL_TYPE_MASK, DMC_EVT_CTL_TYPE_EDGE_0_1) | REG_FIELD_PREP(DMC_EVT_CTL_EVENT_ID_MASK, DMC_EVENT_FALSE); } static bool is_dmc_evt_ctl_reg(struct intel_display *display, enum intel_dmc_id dmc_id, i915_reg_t reg) { u32 offset = i915_mmio_reg_offset(reg); u32 start = i915_mmio_reg_offset(DMC_EVT_CTL(display, dmc_id, 0)); u32 end = i915_mmio_reg_offset(DMC_EVT_CTL(display, dmc_id, DMC_EVENT_HANDLER_COUNT_GEN12)); return offset >= start && offset < end; } static bool is_dmc_evt_htp_reg(struct intel_display *display, enum intel_dmc_id dmc_id, i915_reg_t reg) { u32 offset = i915_mmio_reg_offset(reg); u32 start = i915_mmio_reg_offset(DMC_EVT_HTP(display, dmc_id, 0)); u32 end = i915_mmio_reg_offset(DMC_EVT_HTP(display, dmc_id, DMC_EVENT_HANDLER_COUNT_GEN12)); return offset >= start && offset < end; } static bool is_event_handler(struct intel_display *display, enum intel_dmc_id dmc_id, unsigned int event_id, i915_reg_t reg, u32 data) { return is_dmc_evt_ctl_reg(display, dmc_id, reg) && REG_FIELD_GET(DMC_EVT_CTL_EVENT_ID_MASK, data) == event_id; } static bool disable_dmc_evt(struct intel_display *display, enum intel_dmc_id dmc_id, i915_reg_t reg, u32 data) { if (!is_dmc_evt_ctl_reg(display, dmc_id, reg)) return false; /* keep all pipe DMC events disabled by default */ if (dmc_id != DMC_FW_MAIN) return true; /* also disable the flip queue event on the main DMC on TGL */ if (display->platform.tigerlake && is_event_handler(display, dmc_id, MAINDMC_EVENT_CLK_MSEC, reg, data)) return true; /* also disable the HRR event on the main DMC on TGL/ADLS */ if ((display->platform.tigerlake || display->platform.alderlake_s) && is_event_handler(display, dmc_id, MAINDMC_EVENT_VBLANK_A, reg, data)) return true; return false; } static u32 dmc_mmiodata(struct intel_display *display, struct intel_dmc *dmc, enum intel_dmc_id dmc_id, int i) { if (disable_dmc_evt(display, dmc_id, dmc->dmc_info[dmc_id].mmioaddr[i], dmc->dmc_info[dmc_id].mmiodata[i])) return dmc_evt_ctl_disable(); else return dmc->dmc_info[dmc_id].mmiodata[i]; } static void dmc_load_mmio(struct intel_display *display, enum intel_dmc_id dmc_id) { struct intel_dmc *dmc = display_to_dmc(display); int i; for (i = 0; i < dmc->dmc_info[dmc_id].mmio_count; i++) { intel_de_write(display, dmc->dmc_info[dmc_id].mmioaddr[i], dmc_mmiodata(display, dmc, dmc_id, i)); } } static void dmc_load_program(struct intel_display *display, enum intel_dmc_id dmc_id) { struct intel_dmc *dmc = display_to_dmc(display); int i; disable_all_event_handlers(display, dmc_id); preempt_disable(); for (i = 0; i < dmc->dmc_info[dmc_id].dmc_fw_size; i++) { intel_de_write_fw(display, DMC_PROGRAM(dmc->dmc_info[dmc_id].start_mmioaddr, i), dmc->dmc_info[dmc_id].payload[i]); } preempt_enable(); dmc_load_mmio(display, dmc_id); } static void assert_dmc_loaded(struct intel_display *display, enum intel_dmc_id dmc_id) { struct intel_dmc *dmc = display_to_dmc(display); u32 expected, found; int i; if (!is_valid_dmc_id(dmc_id) || !has_dmc_id_fw(display, dmc_id)) return; found = intel_de_read(display, DMC_PROGRAM(dmc->dmc_info[dmc_id].start_mmioaddr, 0)); expected = dmc->dmc_info[dmc_id].payload[0]; drm_WARN(display->drm, found != expected, "DMC %d program storage start incorrect (expected 0x%x, current 0x%x)\n", dmc_id, expected, found); for (i = 0; i < dmc->dmc_info[dmc_id].mmio_count; i++) { i915_reg_t reg = dmc->dmc_info[dmc_id].mmioaddr[i]; found = intel_de_read(display, reg); expected = dmc_mmiodata(display, dmc, dmc_id, i); /* once set DMC_EVT_CTL_ENABLE can't be cleared :/ */ if (is_dmc_evt_ctl_reg(display, dmc_id, reg)) { found &= ~DMC_EVT_CTL_ENABLE; expected &= ~DMC_EVT_CTL_ENABLE; } drm_WARN(display->drm, found != expected, "DMC %d mmio[%d]/0x%x incorrect (expected 0x%x, current 0x%x)\n", dmc_id, i, i915_mmio_reg_offset(reg), expected, found); } } void assert_main_dmc_loaded(struct intel_display *display) { assert_dmc_loaded(display, DMC_FW_MAIN); } static bool need_pipedmc_load_program(struct intel_display *display) { /* On TGL/derivatives pipe DMC state is lost when PG1 is disabled */ return DISPLAY_VER(display) == 12; } static bool need_pipedmc_load_mmio(struct intel_display *display, enum pipe pipe) { /* * PTL: * - pipe A/B DMC doesn't need save/restore * - pipe C/D DMC is in PG0, needs manual save/restore */ if (DISPLAY_VER(display) == 30) return pipe >= PIPE_C; /* * FIXME LNL unclear, main DMC firmware has the pipe DMC A/B PG0 * save/restore, but so far unable to see the loss of pipe DMC state * in action. Are we just failing to turn off PG0 due to some other * SoC level stuff? */ if (DISPLAY_VER(display) == 20) return false; /* * FIXME BMG untested, main DMC firmware has the * pipe DMC A/B PG0 save/restore... */ if (display->platform.battlemage) return false; /* * DG2: * - Pipe DMCs presumably in PG0? * - No DC6, and even DC9 doesn't seem to result * in loss of DMC state for whatever reason */ if (display->platform.dg2) return false; /* * ADL/MTL: * - pipe A/B DMC is in PG0, saved/restored by the main DMC * - pipe C/D DMC is in PG0, needs manual save/restore */ if (IS_DISPLAY_VER(display, 13, 14)) return pipe >= PIPE_C; return false; } static bool can_enable_pipedmc(const struct intel_crtc_state *crtc_state) { struct intel_display *display = to_intel_display(crtc_state); /* * On TGL/derivatives pipe DMC state is lost when PG1 is disabled. * Do not even enable the pipe DMC when that can happen outside * of driver control (PSR+DC5/6). */ if (DISPLAY_VER(display) == 12 && crtc_state->has_psr) return false; return true; } void intel_dmc_enable_pipe(const struct intel_crtc_state *crtc_state) { struct intel_display *display = to_intel_display(crtc_state); struct intel_crtc *crtc = to_intel_crtc(crtc_state->uapi.crtc); enum pipe pipe = crtc->pipe; enum intel_dmc_id dmc_id = PIPE_TO_DMC_ID(pipe); if (!is_valid_dmc_id(dmc_id) || !has_dmc_id_fw(display, dmc_id)) return; if (!can_enable_pipedmc(crtc_state)) { intel_dmc_disable_pipe(crtc_state); return; } if (need_pipedmc_load_program(display)) dmc_load_program(display, dmc_id); else if (need_pipedmc_load_mmio(display, pipe)) dmc_load_mmio(display, dmc_id); assert_dmc_loaded(display, dmc_id); if (DISPLAY_VER(display) >= 20) { intel_flipq_reset(display, pipe); intel_de_write(display, PIPEDMC_INTERRUPT(pipe), pipedmc_interrupt_mask(display)); intel_de_write(display, PIPEDMC_INTERRUPT_MASK(pipe), ~pipedmc_interrupt_mask(display)); } if (DISPLAY_VER(display) >= 14) intel_de_rmw(display, MTL_PIPEDMC_CONTROL, 0, PIPEDMC_ENABLE_MTL(pipe)); else intel_de_rmw(display, PIPEDMC_CONTROL(pipe), 0, PIPEDMC_ENABLE); } void intel_dmc_disable_pipe(const struct intel_crtc_state *crtc_state) { struct intel_display *display = to_intel_display(crtc_state); struct intel_crtc *crtc = to_intel_crtc(crtc_state->uapi.crtc); enum pipe pipe = crtc->pipe; enum intel_dmc_id dmc_id = PIPE_TO_DMC_ID(pipe); if (!is_valid_dmc_id(dmc_id) || !has_dmc_id_fw(display, dmc_id)) return; if (DISPLAY_VER(display) >= 14) intel_de_rmw(display, MTL_PIPEDMC_CONTROL, PIPEDMC_ENABLE_MTL(pipe), 0); else intel_de_rmw(display, PIPEDMC_CONTROL(pipe), PIPEDMC_ENABLE, 0); if (DISPLAY_VER(display) >= 20) { intel_de_write(display, PIPEDMC_INTERRUPT_MASK(pipe), ~0); intel_de_write(display, PIPEDMC_INTERRUPT(pipe), pipedmc_interrupt_mask(display)); intel_flipq_reset(display, pipe); } } static void dmc_configure_event(struct intel_display *display, enum intel_dmc_id dmc_id, unsigned int event_id, bool enable) { struct intel_dmc *dmc = display_to_dmc(display); int num_handlers = 0; int i; for (i = 0; i < dmc->dmc_info[dmc_id].mmio_count; i++) { i915_reg_t reg = dmc->dmc_info[dmc_id].mmioaddr[i]; u32 data = dmc->dmc_info[dmc_id].mmiodata[i]; if (!is_event_handler(display, dmc_id, event_id, reg, data)) continue; intel_de_write(display, reg, enable ? data : dmc_evt_ctl_disable()); num_handlers++; } drm_WARN_ONCE(display->drm, num_handlers != 1, "DMC %d has %d handlers for event 0x%x\n", dmc_id, num_handlers, event_id); } /** * intel_dmc_block_pkgc() - block PKG C-state * @display: display instance * @pipe: pipe which register use to block * @block: block/unblock * * This interface is target for Wa_16025596647 usage. I.e. to set/clear * PIPEDMC_BLOCK_PKGC_SW_BLOCK_PKGC_ALWAYS bit in PIPEDMC_BLOCK_PKGC_SW register. */ void intel_dmc_block_pkgc(struct intel_display *display, enum pipe pipe, bool block) { intel_de_rmw(display, PIPEDMC_BLOCK_PKGC_SW(pipe), PIPEDMC_BLOCK_PKGC_SW_BLOCK_PKGC_ALWAYS, block ? PIPEDMC_BLOCK_PKGC_SW_BLOCK_PKGC_ALWAYS : 0); } /** * intel_dmc_start_pkgc_exit_at_start_of_undelayed_vblank() - start of PKG * C-state exit * @display: display instance * @pipe: pipe which register use to block * @enable: enable/disable * * This interface is target for Wa_16025596647 usage. I.e. start the package C * exit at the start of the undelayed vblank */ void intel_dmc_start_pkgc_exit_at_start_of_undelayed_vblank(struct intel_display *display, enum pipe pipe, bool enable) { enum intel_dmc_id dmc_id = PIPE_TO_DMC_ID(pipe); dmc_configure_event(display, dmc_id, PIPEDMC_EVENT_VBLANK, enable); } /** * intel_dmc_load_program() - write the firmware from memory to register. * @display: display instance * * DMC firmware is read from a .bin file and kept in internal memory one time. * Everytime display comes back from low power state this function is called to * copy the firmware from internal memory to registers. */ void intel_dmc_load_program(struct intel_display *display) { struct i915_power_domains *power_domains = &display->power.domains; enum intel_dmc_id dmc_id; if (!intel_dmc_has_payload(display)) return; assert_display_rpm_held(display); pipedmc_clock_gating_wa(display, true); for_each_dmc_id(dmc_id) { dmc_load_program(display, dmc_id); assert_dmc_loaded(display, dmc_id); } if (DISPLAY_VER(display) >= 20) intel_de_write(display, DMC_FQ_W2_PTS_CFG_SEL, PIPE_D_DMC_W2_PTS_CONFIG_SELECT(PIPE_D) | PIPE_C_DMC_W2_PTS_CONFIG_SELECT(PIPE_C) | PIPE_B_DMC_W2_PTS_CONFIG_SELECT(PIPE_B) | PIPE_A_DMC_W2_PTS_CONFIG_SELECT(PIPE_A)); power_domains->dc_state = 0; gen9_set_dc_state_debugmask(display); pipedmc_clock_gating_wa(display, false); } /** * intel_dmc_disable_program() - disable the firmware * @display: display instance * * Disable all event handlers in the firmware, making sure the firmware is * inactive after the display is uninitialized. */ void intel_dmc_disable_program(struct intel_display *display) { enum intel_dmc_id dmc_id; if (!intel_dmc_has_payload(display)) return; pipedmc_clock_gating_wa(display, true); for_each_dmc_id(dmc_id) disable_all_event_handlers(display, dmc_id); pipedmc_clock_gating_wa(display, false); } static bool fw_info_matches_stepping(const struct intel_fw_info *fw_info, const struct stepping_info *si) { if ((fw_info->substepping == '*' && si->stepping == fw_info->stepping) || (si->stepping == fw_info->stepping && si->substepping == fw_info->substepping) || /* * If we don't find a more specific one from above two checks, we * then check for the generic one to be sure to work even with * "broken firmware" */ (si->stepping == '*' && si->substepping == fw_info->substepping) || (fw_info->stepping == '*' && fw_info->substepping == '*')) return true; return false; } /* * Search fw_info table for dmc_offset to find firmware binary: num_entries is * already sanitized. */ static void dmc_set_fw_offset(struct intel_dmc *dmc, const struct intel_fw_info *fw_info, unsigned int num_entries, const struct stepping_info *si, u8 package_ver) { struct intel_display *display = dmc->display; enum intel_dmc_id dmc_id; unsigned int i; for (i = 0; i < num_entries; i++) { dmc_id = package_ver <= 1 ? DMC_FW_MAIN : fw_info[i].dmc_id; if (!is_valid_dmc_id(dmc_id)) { drm_dbg(display->drm, "Unsupported firmware id: %u\n", dmc_id); continue; } /* More specific versions come first, so we don't even have to * check for the stepping since we already found a previous FW * for this id. */ if (dmc->dmc_info[dmc_id].present) continue; if (fw_info_matches_stepping(&fw_info[i], si)) { dmc->dmc_info[dmc_id].present = true; dmc->dmc_info[dmc_id].dmc_offset = fw_info[i].offset; } } } static bool dmc_mmio_addr_sanity_check(struct intel_dmc *dmc, const u32 *mmioaddr, u32 mmio_count, int header_ver, enum intel_dmc_id dmc_id) { struct intel_display *display = dmc->display; u32 start_range, end_range; int i; if (header_ver == 1) { start_range = DMC_MMIO_START_RANGE; end_range = DMC_MMIO_END_RANGE; } else if (dmc_id == DMC_FW_MAIN) { start_range = TGL_MAIN_MMIO_START; end_range = TGL_MAIN_MMIO_END; } else if (DISPLAY_VER(display) >= 13) { start_range = ADLP_PIPE_MMIO_START; end_range = ADLP_PIPE_MMIO_END; } else if (DISPLAY_VER(display) >= 12) { start_range = TGL_PIPE_MMIO_START(dmc_id); end_range = TGL_PIPE_MMIO_END(dmc_id); } else { drm_warn(display->drm, "Unknown mmio range for sanity check"); return false; } for (i = 0; i < mmio_count; i++) { if (mmioaddr[i] < start_range || mmioaddr[i] > end_range) return false; } return true; } static u32 parse_dmc_fw_header(struct intel_dmc *dmc, const struct intel_dmc_header_base *dmc_header, size_t rem_size, enum intel_dmc_id dmc_id) { struct intel_display *display = dmc->display; struct dmc_fw_info *dmc_info = &dmc->dmc_info[dmc_id]; unsigned int header_len_bytes, dmc_header_size, payload_size, i; const u32 *mmioaddr, *mmiodata; u32 mmio_count, mmio_count_max, start_mmioaddr; u8 *payload; BUILD_BUG_ON(ARRAY_SIZE(dmc_info->mmioaddr) < DMC_V3_MAX_MMIO_COUNT || ARRAY_SIZE(dmc_info->mmioaddr) < DMC_V1_MAX_MMIO_COUNT); /* * Check if we can access common fields, we will checkc again below * after we have read the version */ if (rem_size < sizeof(struct intel_dmc_header_base)) goto error_truncated; /* Cope with small differences between v1 and v3 */ if (dmc_header->header_ver == 3) { const struct intel_dmc_header_v3 *v3 = (const struct intel_dmc_header_v3 *)dmc_header; if (rem_size < sizeof(struct intel_dmc_header_v3)) goto error_truncated; mmioaddr = v3->mmioaddr; mmiodata = v3->mmiodata; mmio_count = v3->mmio_count; mmio_count_max = DMC_V3_MAX_MMIO_COUNT; /* header_len is in dwords */ header_len_bytes = dmc_header->header_len * 4; start_mmioaddr = v3->start_mmioaddr; dmc_header_size = sizeof(*v3); } else if (dmc_header->header_ver == 1) { const struct intel_dmc_header_v1 *v1 = (const struct intel_dmc_header_v1 *)dmc_header; if (rem_size < sizeof(struct intel_dmc_header_v1)) goto error_truncated; mmioaddr = v1->mmioaddr; mmiodata = v1->mmiodata; mmio_count = v1->mmio_count; mmio_count_max = DMC_V1_MAX_MMIO_COUNT; header_len_bytes = dmc_header->header_len; start_mmioaddr = DMC_V1_MMIO_START_RANGE; dmc_header_size = sizeof(*v1); } else { drm_err(display->drm, "Unknown DMC fw header version: %u\n", dmc_header->header_ver); return 0; } if (header_len_bytes != dmc_header_size) { drm_err(display->drm, "DMC firmware has wrong dmc header length " "(%u bytes)\n", header_len_bytes); return 0; } /* Cache the dmc header info. */ if (mmio_count > mmio_count_max) { drm_err(display->drm, "DMC firmware has wrong mmio count %u\n", mmio_count); return 0; } if (!dmc_mmio_addr_sanity_check(dmc, mmioaddr, mmio_count, dmc_header->header_ver, dmc_id)) { drm_err(display->drm, "DMC firmware has Wrong MMIO Addresses\n"); return 0; } drm_dbg_kms(display->drm, "DMC %d:\n", dmc_id); for (i = 0; i < mmio_count; i++) { dmc_info->mmioaddr[i] = _MMIO(mmioaddr[i]); dmc_info->mmiodata[i] = mmiodata[i]; drm_dbg_kms(display->drm, " mmio[%d]: 0x%x = 0x%x%s%s\n", i, mmioaddr[i], mmiodata[i], is_dmc_evt_ctl_reg(display, dmc_id, dmc_info->mmioaddr[i]) ? " (EVT_CTL)" : is_dmc_evt_htp_reg(display, dmc_id, dmc_info->mmioaddr[i]) ? " (EVT_HTP)" : "", disable_dmc_evt(display, dmc_id, dmc_info->mmioaddr[i], dmc_info->mmiodata[i]) ? " (disabling)" : ""); } dmc_info->mmio_count = mmio_count; dmc_info->start_mmioaddr = start_mmioaddr; rem_size -= header_len_bytes; /* fw_size is in dwords, so multiplied by 4 to convert into bytes. */ payload_size = dmc_header->fw_size * 4; if (rem_size < payload_size) goto error_truncated; if (payload_size > dmc->max_fw_size) { drm_err(display->drm, "DMC FW too big (%u bytes)\n", payload_size); return 0; } dmc_info->dmc_fw_size = dmc_header->fw_size; dmc_info->payload = kmalloc(payload_size, GFP_KERNEL); if (!dmc_info->payload) return 0; payload = (u8 *)(dmc_header) + header_len_bytes; memcpy(dmc_info->payload, payload, payload_size); return header_len_bytes + payload_size; error_truncated: drm_err(display->drm, "Truncated DMC firmware, refusing.\n"); return 0; } static u32 parse_dmc_fw_package(struct intel_dmc *dmc, const struct intel_package_header *package_header, const struct stepping_info *si, size_t rem_size) { struct intel_display *display = dmc->display; u32 package_size = sizeof(struct intel_package_header); u32 num_entries, max_entries; const struct intel_fw_info *fw_info; if (rem_size < package_size) goto error_truncated; if (package_header->header_ver == 1) { max_entries = PACKAGE_MAX_FW_INFO_ENTRIES; } else if (package_header->header_ver == 2) { max_entries = PACKAGE_V2_MAX_FW_INFO_ENTRIES; } else { drm_err(display->drm, "DMC firmware has unknown header version %u\n", package_header->header_ver); return 0; } /* * We should always have space for max_entries, * even if not all are used */ package_size += max_entries * sizeof(struct intel_fw_info); if (rem_size < package_size) goto error_truncated; if (package_header->header_len * 4 != package_size) { drm_err(display->drm, "DMC firmware has wrong package header length " "(%u bytes)\n", package_size); return 0; } num_entries = package_header->num_entries; if (WARN_ON(package_header->num_entries > max_entries)) num_entries = max_entries; fw_info = (const struct intel_fw_info *) ((u8 *)package_header + sizeof(*package_header)); dmc_set_fw_offset(dmc, fw_info, num_entries, si, package_header->header_ver); /* dmc_offset is in dwords */ return package_size; error_truncated: drm_err(display->drm, "Truncated DMC firmware, refusing.\n"); return 0; } /* Return number of bytes parsed or 0 on error */ static u32 parse_dmc_fw_css(struct intel_dmc *dmc, struct intel_css_header *css_header, size_t rem_size) { struct intel_display *display = dmc->display; if (rem_size < sizeof(struct intel_css_header)) { drm_err(display->drm, "Truncated DMC firmware, refusing.\n"); return 0; } if (sizeof(struct intel_css_header) != (css_header->header_len * 4)) { drm_err(display->drm, "DMC firmware has wrong CSS header length " "(%u bytes)\n", (css_header->header_len * 4)); return 0; } dmc->version = css_header->version; return sizeof(struct intel_css_header); } static int parse_dmc_fw(struct intel_dmc *dmc, const struct firmware *fw) { struct intel_display *display = dmc->display; struct intel_css_header *css_header; struct intel_package_header *package_header; struct intel_dmc_header_base *dmc_header; struct stepping_info display_info = { '*', '*'}; const struct stepping_info *si = intel_get_stepping_info(display, &display_info); enum intel_dmc_id dmc_id; u32 readcount = 0; u32 r, offset; if (!fw) return -EINVAL; /* Extract CSS Header information */ css_header = (struct intel_css_header *)fw->data; r = parse_dmc_fw_css(dmc, css_header, fw->size); if (!r) return -EINVAL; readcount += r; /* Extract Package Header information */ package_header = (struct intel_package_header *)&fw->data[readcount]; r = parse_dmc_fw_package(dmc, package_header, si, fw->size - readcount); if (!r) return -EINVAL; readcount += r; for_each_dmc_id(dmc_id) { if (!dmc->dmc_info[dmc_id].present) continue; offset = readcount + dmc->dmc_info[dmc_id].dmc_offset * 4; if (offset > fw->size) { drm_err(display->drm, "Reading beyond the fw_size\n"); continue; } dmc_header = (struct intel_dmc_header_base *)&fw->data[offset]; parse_dmc_fw_header(dmc, dmc_header, fw->size - offset, dmc_id); } if (!intel_dmc_has_payload(display)) { drm_err(display->drm, "DMC firmware main program not found\n"); return -ENOENT; } return 0; } static void intel_dmc_runtime_pm_get(struct intel_display *display) { drm_WARN_ON(display->drm, display->dmc.wakeref); display->dmc.wakeref = intel_display_power_get(display, POWER_DOMAIN_INIT); } static void intel_dmc_runtime_pm_put(struct intel_display *display) { intel_wakeref_t wakeref __maybe_unused = fetch_and_zero(&display->dmc.wakeref); intel_display_power_put(display, POWER_DOMAIN_INIT, wakeref); } static const char *dmc_fallback_path(struct intel_display *display) { if (display->platform.alderlake_p) return ADLP_DMC_FALLBACK_PATH; return NULL; } static void dmc_load_work_fn(struct work_struct *work) { struct intel_dmc *dmc = container_of(work, typeof(*dmc), work); struct intel_display *display = dmc->display; const struct firmware *fw = NULL; const char *fallback_path; int err; err = request_firmware(&fw, dmc->fw_path, display->drm->dev); if (err == -ENOENT && !dmc_firmware_param(display)) { fallback_path = dmc_fallback_path(display); if (fallback_path) { drm_dbg_kms(display->drm, "%s not found, falling back to %s\n", dmc->fw_path, fallback_path); err = request_firmware(&fw, fallback_path, display->drm->dev); if (err == 0) dmc->fw_path = fallback_path; } } if (err) { drm_notice(display->drm, "Failed to load DMC firmware %s (%pe). Disabling runtime power management.\n", dmc->fw_path, ERR_PTR(err)); drm_notice(display->drm, "DMC firmware homepage: %s", INTEL_DMC_FIRMWARE_URL); return; } err = parse_dmc_fw(dmc, fw); if (err) { drm_notice(display->drm, "Failed to parse DMC firmware %s (%pe). Disabling runtime power management.\n", dmc->fw_path, ERR_PTR(err)); goto out; } intel_dmc_load_program(display); intel_dmc_runtime_pm_put(display); drm_info(display->drm, "Finished loading DMC firmware %s (v%u.%u)\n", dmc->fw_path, DMC_VERSION_MAJOR(dmc->version), DMC_VERSION_MINOR(dmc->version)); out: release_firmware(fw); } /** * intel_dmc_init() - initialize the firmware loading. * @display: display instance * * This function is called at the time of loading the display driver to read * firmware from a .bin file and copied into a internal memory. */ void intel_dmc_init(struct intel_display *display) { struct intel_dmc *dmc; if (!HAS_DMC(display)) return; /* * Obtain a runtime pm reference, until DMC is loaded, to avoid entering * runtime-suspend. * * On error, we return with the rpm wakeref held to prevent runtime * suspend as runtime suspend *requires* a working DMC for whatever * reason. */ intel_dmc_runtime_pm_get(display); dmc = kzalloc(sizeof(*dmc), GFP_KERNEL); if (!dmc) return; dmc->display = display; INIT_WORK(&dmc->work, dmc_load_work_fn); dmc->fw_path = dmc_firmware_default(display, &dmc->max_fw_size); if (dmc_firmware_param_disabled(display)) { drm_info(display->drm, "Disabling DMC firmware and runtime PM\n"); goto out; } if (dmc_firmware_param(display)) dmc->fw_path = dmc_firmware_param(display); if (!dmc->fw_path) { drm_dbg_kms(display->drm, "No known DMC firmware for platform, disabling runtime PM\n"); goto out; } display->dmc.dmc = dmc; drm_dbg_kms(display->drm, "Loading %s\n", dmc->fw_path); queue_work(display->wq.unordered, &dmc->work); return; out: kfree(dmc); } /** * intel_dmc_suspend() - prepare DMC firmware before system suspend * @display: display instance * * Prepare the DMC firmware before entering system suspend. This includes * flushing pending work items and releasing any resources acquired during * init. */ void intel_dmc_suspend(struct intel_display *display) { struct intel_dmc *dmc = display_to_dmc(display); if (!HAS_DMC(display)) return; if (dmc) flush_work(&dmc->work); /* Drop the reference held in case DMC isn't loaded. */ if (!intel_dmc_has_payload(display)) intel_dmc_runtime_pm_put(display); } void intel_dmc_wait_fw_load(struct intel_display *display) { struct intel_dmc *dmc = display_to_dmc(display); if (!HAS_DMC(display)) return; if (dmc) flush_work(&dmc->work); } /** * intel_dmc_resume() - init DMC firmware during system resume * @display: display instance * * Reinitialize the DMC firmware during system resume, reacquiring any * resources released in intel_dmc_suspend(). */ void intel_dmc_resume(struct intel_display *display) { if (!HAS_DMC(display)) return; /* * Reacquire the reference to keep RPM disabled in case DMC isn't * loaded. */ if (!intel_dmc_has_payload(display)) intel_dmc_runtime_pm_get(display); } /** * intel_dmc_fini() - unload the DMC firmware. * @display: display instance * * Firmmware unloading includes freeing the internal memory and reset the * firmware loading status. */ void intel_dmc_fini(struct intel_display *display) { struct intel_dmc *dmc = display_to_dmc(display); enum intel_dmc_id dmc_id; if (!HAS_DMC(display)) return; intel_dmc_suspend(display); drm_WARN_ON(display->drm, display->dmc.wakeref); if (dmc) { for_each_dmc_id(dmc_id) kfree(dmc->dmc_info[dmc_id].payload); kfree(dmc); display->dmc.dmc = NULL; } } struct intel_dmc_snapshot { bool initialized; bool loaded; u32 version; }; struct intel_dmc_snapshot *intel_dmc_snapshot_capture(struct intel_display *display) { struct intel_dmc *dmc = display_to_dmc(display); struct intel_dmc_snapshot *snapshot; if (!HAS_DMC(display)) return NULL; snapshot = kzalloc(sizeof(*snapshot), GFP_ATOMIC); if (!snapshot) return NULL; snapshot->initialized = dmc; snapshot->loaded = intel_dmc_has_payload(display); if (dmc) snapshot->version = dmc->version; return snapshot; } void intel_dmc_snapshot_print(const struct intel_dmc_snapshot *snapshot, struct drm_printer *p) { if (!snapshot) return; drm_printf(p, "DMC initialized: %s\n", str_yes_no(snapshot->initialized)); drm_printf(p, "DMC loaded: %s\n", str_yes_no(snapshot->loaded)); if (snapshot->initialized) drm_printf(p, "DMC fw version: %d.%d\n", DMC_VERSION_MAJOR(snapshot->version), DMC_VERSION_MINOR(snapshot->version)); } void intel_dmc_update_dc6_allowed_count(struct intel_display *display, bool start_tracking) { struct intel_dmc *dmc = display_to_dmc(display); u32 dc5_cur_count; if (DISPLAY_VER(dmc->display) < 14) return; dc5_cur_count = intel_de_read(dmc->display, DG1_DMC_DEBUG_DC5_COUNT); if (!start_tracking) dmc->dc6_allowed.count += dc5_cur_count - dmc->dc6_allowed.dc5_start; dmc->dc6_allowed.dc5_start = dc5_cur_count; } static bool intel_dmc_get_dc6_allowed_count(struct intel_display *display, u32 *count) { struct i915_power_domains *power_domains = &display->power.domains; struct intel_dmc *dmc = display_to_dmc(display); bool dc6_enabled; if (DISPLAY_VER(display) < 14) return false; mutex_lock(&power_domains->lock); dc6_enabled = intel_de_read(display, DC_STATE_EN) & DC_STATE_EN_UPTO_DC6; if (dc6_enabled) intel_dmc_update_dc6_allowed_count(display, false); *count = dmc->dc6_allowed.count; mutex_unlock(&power_domains->lock); return true; } static int intel_dmc_debugfs_status_show(struct seq_file *m, void *unused) { struct intel_display *display = m->private; struct intel_dmc *dmc = display_to_dmc(display); struct ref_tracker *wakeref; i915_reg_t dc5_reg, dc6_reg = INVALID_MMIO_REG; u32 dc6_allowed_count; if (!HAS_DMC(display)) return -ENODEV; wakeref = intel_display_rpm_get(display); seq_printf(m, "DMC initialized: %s\n", str_yes_no(dmc)); seq_printf(m, "fw loaded: %s\n", str_yes_no(intel_dmc_has_payload(display))); seq_printf(m, "path: %s\n", dmc ? dmc->fw_path : "N/A"); seq_printf(m, "Pipe A fw needed: %s\n", str_yes_no(DISPLAY_VER(display) >= 12)); seq_printf(m, "Pipe A fw loaded: %s\n", str_yes_no(has_dmc_id_fw(display, DMC_FW_PIPEA))); seq_printf(m, "Pipe B fw needed: %s\n", str_yes_no(display->platform.alderlake_p || DISPLAY_VER(display) >= 14)); seq_printf(m, "Pipe B fw loaded: %s\n", str_yes_no(has_dmc_id_fw(display, DMC_FW_PIPEB))); if (!intel_dmc_has_payload(display)) goto out; seq_printf(m, "version: %d.%d\n", DMC_VERSION_MAJOR(dmc->version), DMC_VERSION_MINOR(dmc->version)); if (DISPLAY_VER(display) >= 12) { i915_reg_t dc3co_reg; if (display->platform.dgfx || DISPLAY_VER(display) >= 14) { dc3co_reg = DG1_DMC_DEBUG3; dc5_reg = DG1_DMC_DEBUG_DC5_COUNT; } else { dc3co_reg = TGL_DMC_DEBUG3; dc5_reg = TGL_DMC_DEBUG_DC5_COUNT; dc6_reg = TGL_DMC_DEBUG_DC6_COUNT; } seq_printf(m, "DC3CO count: %d\n", intel_de_read(display, dc3co_reg)); } else { dc5_reg = display->platform.broxton ? BXT_DMC_DC3_DC5_COUNT : SKL_DMC_DC3_DC5_COUNT; if (!display->platform.geminilake && !display->platform.broxton) dc6_reg = SKL_DMC_DC5_DC6_COUNT; } seq_printf(m, "DC3 -> DC5 count: %d\n", intel_de_read(display, dc5_reg)); if (intel_dmc_get_dc6_allowed_count(display, &dc6_allowed_count)) seq_printf(m, "DC5 -> DC6 allowed count: %d\n", dc6_allowed_count); else if (i915_mmio_reg_valid(dc6_reg)) seq_printf(m, "DC5 -> DC6 count: %d\n", intel_de_read(display, dc6_reg)); seq_printf(m, "program base: 0x%08x\n", intel_de_read(display, DMC_PROGRAM(dmc->dmc_info[DMC_FW_MAIN].start_mmioaddr, 0))); out: seq_printf(m, "ssp base: 0x%08x\n", intel_de_read(display, DMC_SSP_BASE)); seq_printf(m, "htp: 0x%08x\n", intel_de_read(display, DMC_HTP_SKL)); intel_display_rpm_put(display, wakeref); return 0; } DEFINE_SHOW_ATTRIBUTE(intel_dmc_debugfs_status); void intel_dmc_debugfs_register(struct intel_display *display) { struct drm_minor *minor = display->drm->primary; debugfs_create_file("i915_dmc_info", 0444, minor->debugfs_root, display, &intel_dmc_debugfs_status_fops); } void intel_pipedmc_irq_handler(struct intel_display *display, enum pipe pipe) { struct intel_crtc *crtc = intel_crtc_for_pipe(display, pipe); u32 tmp = 0, int_vector; if (DISPLAY_VER(display) >= 20) { tmp = intel_de_read(display, PIPEDMC_INTERRUPT(pipe)); intel_de_write(display, PIPEDMC_INTERRUPT(pipe), tmp); if (tmp & PIPEDMC_FLIPQ_PROG_DONE) { spin_lock(&display->drm->event_lock); if (crtc->flipq_event) { /* * Update vblank counter/timestamp in case it * hasn't been done yet for this frame. */ drm_crtc_accurate_vblank_count(&crtc->base); drm_crtc_send_vblank_event(&crtc->base, crtc->flipq_event); crtc->flipq_event = NULL; } spin_unlock(&display->drm->event_lock); } if (tmp & PIPEDMC_ATS_FAULT) drm_err_ratelimited(display->drm, "[CRTC:%d:%s] PIPEDMC ATS fault\n", crtc->base.base.id, crtc->base.name); if (tmp & PIPEDMC_GTT_FAULT) drm_err_ratelimited(display->drm, "[CRTC:%d:%s] PIPEDMC GTT fault\n", crtc->base.base.id, crtc->base.name); if (tmp & PIPEDMC_ERROR) drm_err(display->drm, "[CRTC:%d:%s]] PIPEDMC error\n", crtc->base.base.id, crtc->base.name); } int_vector = intel_de_read(display, PIPEDMC_STATUS(pipe)) & PIPEDMC_INT_VECTOR_MASK; if (tmp == 0 && int_vector != 0) drm_err(display->drm, "[CRTC:%d:%s]] PIPEDMC interrupt vector 0x%x\n", crtc->base.base.id, crtc->base.name, tmp); } void intel_pipedmc_enable_event(struct intel_crtc *crtc, enum pipedmc_event_id event) { struct intel_display *display = to_intel_display(crtc); enum intel_dmc_id dmc_id = PIPE_TO_DMC_ID(crtc->pipe); dmc_configure_event(display, dmc_id, event, true); } void intel_pipedmc_disable_event(struct intel_crtc *crtc, enum pipedmc_event_id event) { struct intel_display *display = to_intel_display(crtc); enum intel_dmc_id dmc_id = PIPE_TO_DMC_ID(crtc->pipe); dmc_configure_event(display, dmc_id, event, false); } u32 intel_pipedmc_start_mmioaddr(struct intel_crtc *crtc) { struct intel_display *display = to_intel_display(crtc); struct intel_dmc *dmc = display_to_dmc(display); enum intel_dmc_id dmc_id = PIPE_TO_DMC_ID(crtc->pipe); return dmc ? dmc->dmc_info[dmc_id].start_mmioaddr : 0; }