/* * Copyright © 2009 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. * * Authors: * Zhenyu Wang * Wu Fengguang * */ #include #include #include #include #include #include #include "intel_io.h" #include "intel_reg.h" #include "intel_chipset.h" #include "drmtest.h" static uint32_t devid; static int aud_reg_base = 0; /* base address of audio registers */ static int disp_reg_base = 0; /* base address of display registers */ #define IS_HASWELL_PLUS(devid) (IS_HASWELL(devid) || IS_BROADWELL(devid)) #define BITSTO(n) (n >= sizeof(long) * 8 ? ~0 : (1UL << (n)) - 1) #define BITMASK(high, low) (BITSTO(high+1) & ~BITSTO(low)) #define BITS(reg, high, low) (((reg) & (BITMASK(high, low))) >> (low)) #define BIT(reg, n) BITS(reg, n, n) #define min_t(type, x, y) ({ \ type __min1 = (x); \ type __min2 = (y); \ __min1 < __min2 ? __min1 : __min2; }) #define OPNAME(names, index) \ names[min_t(unsigned int, index, ARRAY_SIZE(names) - 1)] #define set_aud_reg_base(base) (aud_reg_base = (base)) #define set_reg_base(base, audio_offset) \ do { \ disp_reg_base = (base); \ set_aud_reg_base((base) + (audio_offset)); \ } while (0) #define dump_reg(reg, desc) \ do { \ dword = INREG(reg); \ printf("%-21s(%#x) 0x%08x %s\n", # reg, reg, dword, desc); \ } while (0) #define dump_disp_reg(reg, desc) \ do { \ dword = INREG(disp_reg_base + reg); \ printf("%-21s(%#x) 0x%08x %s\n", # reg, reg, dword, desc); \ } while (0) #define dump_aud_reg(reg, desc) \ do { \ dword = INREG(aud_reg_base + reg); \ printf("%-21s(%#x) 0x%08x %s\n", # reg, reg, dword, desc); \ } while (0) #define read_aud_reg(reg) INREG(aud_reg_base + (reg)) static int get_num_pipes(void) { int num_pipes; if (IS_VALLEYVIEW(devid)) num_pipes = 2; /* Valleyview is Gen 7 but only has 2 pipes */ else if (IS_G4X(devid) || IS_GEN5(devid)) num_pipes = 2; else num_pipes = 3; return num_pipes; } static const char * const cts_m_value_index[] = { [0] = "CTS", [1] = "M", }; static const char * const pixel_clock[] = { [0] = "25.2 / 1.001 MHz", [1] = "25.2 MHz", [2] = "27 MHz", [3] = "27 * 1.001 MHz", [4] = "54 MHz", [5] = "54 * 1.001 MHz", [6] = "74.25 / 1.001 MHz", [7] = "74.25 MHz", [8] = "148.5 / 1.001 MHz", [9] = "148.5 MHz", [10] = "Reserved", }; static const char * const power_state[] = { [0] = "D0", [1] = "D1", [2] = "D2", [3] = "D3", }; static const char * const stream_type[] = { [0] = "default samples", [1] = "one bit stream", [2] = "DST stream", [3] = "MLP stream", [4] = "Reserved", }; static const char * const dip_port[] = { [0] = "Reserved", [1] = "Digital Port B", [2] = "Digital Port C", [3] = "Digital Port D", }; static const char * const dip_type[] = { [0] = "Audio DIP Disabled", [1] = "Audio DIP Enabled", }; static const char * const dip_gen1_state[] = { [0] = "Generic 1 (ACP) DIP Disabled", [1] = "Generic 1 (ACP) DIP Enabled", }; static const char * const dip_gen2_state[] = { [0] = "Generic 2 DIP Disabled", [1] = "Generic 2 DIP Enabled", }; static const char * const dip_index[] = { [0] = "Audio DIP", [1] = "ACP DIP", [2] = "ISRC1 DIP", [3] = "ISRC2 DIP", [4] = "Reserved", }; static const char * const dip_trans[] = { [0] = "disabled", [1] = "reserved", [2] = "send once", [3] = "best effort", }; static const char * const video_dip_index[] = { [0] = "AVI DIP", [1] = "Vendor-specific DIP", [2] = "Gamut Metadata DIP", [3] = "Source Product Description DIP", }; static const char * const video_dip_trans[] = { [0] = "send once", [1] = "send every vsync", [2] = "send at least every other vsync", [3] = "reserved", }; static const char * const trans_to_port_sel[] = { [0] = "no port", [1] = "Digital Port B", [2] = "Digital Port C", [3] = "Digital Port D", [4] = "reserved", [5] = "reserved", [6] = "reserved", [7] = "reserved", }; static const char * const ddi_mode[] = { [0] = "HDMI mode", [1] = "DVI mode", [2] = "DP SST mode", [3] = "DP MST mode", [4] = "DP FDI mode", [5] = "reserved", [6] = "reserved", [7] = "reserved", }; static const char * const bits_per_color[] = { [0] = "8 bpc", [1] = "10 bpc", [2] = "6 bpc", [3] = "12 bpc", [4] = "reserved", [5] = "reserved", [6] = "reserved", [7] = "reserved", }; static const char * const transcoder_select[] = { [0] = "Transcoder A", [1] = "Transcoder B", [2] = "Transcoder C", [3] = "reserved", }; static const char * const dp_port_width[] = { [0] = "x1 mode", [1] = "x2 mode", [2] = "reserved", [3] = "x4 mode", [4] = "reserved", [5] = "reserved", [6] = "reserved", [7] = "reserved", }; static const char * const sample_base_rate[] = { [0] = "48 kHz", [1] = "44.1 kHz", }; static const char * const sample_base_rate_mult[] = { [0] = "x1 (48 kHz, 44.1 kHz or less)", [1] = "x2 (96 kHz, 88.2 kHz, 32 kHz)", [2] = "x3 (144 kHz)", [3] = "x4 (192 kHz, 176.4 kHz)", [4] = "Reserved", }; static const char * const sample_base_rate_divisor[] = { [0] = "Divided by 1 (48 kHz, 44.1 kHz)", [1] = "Divided by 2 (24 kHz, 22.05 kHz)", [2] = "Divided by 3 (16 kHz, 32 kHz)", [3] = "Divided by 4 (11.025 kHz)", [4] = "Divided by 5 (9.6 kHz)", [5] = "Divided by 6 (8 kHz)", [6] = "Divided by 7", [7] = "Divided by 8 (6 kHz)", }; static const char * const connect_list_form[] = { [0] = "Short Form", [1] = "Long Form", }; static const char * const bits_per_sample[] = { [0] = "reserved", [1] = "16 bits", [2] = "24 bits", [3] = "32 bits", [4] = "20 bits", [5] = "reserved", }; static const char * const sdvo_hdmi_encoding[] = { [0] = "SDVO", [1] = "reserved", [2] = "TMDS", [3] = "reserved", }; static const char * const n_index_value[] = { [0] = "HDMI", [1] = "DisplayPort", }; static const char * const immed_result_valid[] = { [0] = "No immediate response is available", [1] = "Immediate response is available", }; static const char * const immed_cmd_busy[] = { [0] = "Can accept an immediate command", [1] = "Immediate command is available", }; static const char * const vanilla_dp12_en[] = { [0] = "DP 1.2 features are disabled", [1] = "DP 1.2 features are enabled", }; static const char * const vanilla_3_widgets_en[] = { [0] = "2nd & 3rd pin/convertor widgets are disabled", [1] = "All three pin/convertor widgets are enabled", }; static const char * const block_audio[] = { [0] = "Allow audio data to reach the port", [1] = "Block audio data from reaching the port", }; static const char * const dis_eld_valid_pulse_trans[] = { [0] = "Enable ELD valid pulse transition when unsol is disabled", [1] = "Disable ELD valid pulse transition when unsol is disabled", }; static const char * const dis_pd_pulse_trans[] = { [0] = "Enable Presense Detect pulse transition when unsol is disabled", [1] = "Disable Presense Detect pulse transition when unsol is disabled", }; static const char * const dis_ts_delta_err[] = { [0] = "Enable timestamp delta error for 32/44 KHz", [1] = "Disable timestamp delta error for 32/44 KHz", }; static const char * const dis_ts_fix_dp_hbr[] = { [0] = "Enable timestamp fix for DP HBR", [1] = "Disable timestamp fix for DP HBR", }; static const char * const pattern_gen_8_ch_en[] = { [0] = "Disable 8-channel pattern generator", [1] = "Enable 8-channel pattern generator", }; static const char * const pattern_gen_2_ch_en[] = { [0] = "Disable 2-channel pattern generator", [1] = "Enable 2-channel pattern generator", }; static const char * const fabric_32_44_dis[] = { [0] = "Allow sample fabrication for 32/44 KHz", [1] = "Disable sample fabrication for 32/44 KHz", }; static const char * const epss_dis[] = { [0] = "Allow audio EPSS", [1] = "Disable audio EPSS", }; static const char * const ts_test_mode[] = { [0] = "Default time stamp mode", [1] = "Audio time stamp test mode for audio only feature", }; static const char * const en_mmio_program[] = { [0] = "Programming by HD-Audio Azalia", [1] = "Programming by MMIO debug registers", }; static const char * const sdi_operate_mode[] = { [0] = "2T mode with sdi data held for 2 bit clocks", [1] = "1T mode with sdi data held for 1 bit clock only", }; static const char * const bclk_96mhz[] = { [0] = "iDisplay audio link 96MHz bclk off", [1] = "iDisplay audio link 96MHz bclk on", }; static const char * const bclk_48mhz[] = { [0] = "iDisplay audio link 48MHz bclk off", [1] = "iDisplay audio link 48MHz bclk on", }; static const char * const audio_dp_dip_status[] = { [0] = "audfc dp fifo full", [1] = "audfc dp fifo empty", [2] = "audfc dp fifo overrun", [3] = "audfc dip fifo full", [4] = "audfc dp fifo empty cd", [5] = "audfb dp fifo full", [6] = "audfb dp fifo empty", [7] = "audfb dp fifo overrun", [8] = "audfb dip fifo full", [9] = "audfb dp fifo empty cd", [10] = "audfa dp fifo full", [11] = "audfa dp fifo empty", [12] = "audfa dp fifo overrun", [13] = "audfa dip fifo full", [14] = "audfa dp fifo empty cd", [15] = "Pipe c audio overflow", [16] = "Pipe b audio overflow", [17] = "Pipe a audio overflow", [31] = 0, }; #undef TRANSCODER_A #undef TRANSCODER_B #undef TRANSCODER_C enum { TRANSCODER_A = 0, TRANSCODER_B, TRANSCODER_C, }; enum { PIPE_A = 0, PIPE_B, PIPE_C, }; enum { PORT_A = 0, PORT_B, PORT_C, PORT_D, PORT_E, }; enum { CONVERTER_1 = 0, CONVERTER_2, CONVERTER_3, }; static void do_self_tests(void) { if (BIT(1, 0) != 1) exit(1); if (BIT(0x80000000, 31) != 1) exit(2); if (BITS(0xc0000000, 31, 30) != 3) exit(3); } /* * EagleLake registers */ #define AUD_CONFIG 0x62000 #define AUD_DEBUG 0x62010 #define AUD_VID_DID 0x62020 #define AUD_RID 0x62024 #define AUD_SUBN_CNT 0x62028 #define AUD_FUNC_GRP 0x62040 #define AUD_SUBN_CNT2 0x62044 #define AUD_GRP_CAP 0x62048 #define AUD_PWRST 0x6204c #define AUD_SUPPWR 0x62050 #define AUD_SID 0x62054 #define AUD_OUT_CWCAP 0x62070 #define AUD_OUT_PCMSIZE 0x62074 #define AUD_OUT_STR 0x62078 #define AUD_OUT_DIG_CNVT 0x6207c #define AUD_OUT_CH_STR 0x62080 #define AUD_OUT_STR_DESC 0x62084 #define AUD_PINW_CAP 0x620a0 #define AUD_PIN_CAP 0x620a4 #define AUD_PINW_CONNLNG 0x620a8 #define AUD_PINW_CONNLST 0x620ac #define AUD_PINW_CNTR 0x620b0 #define AUD_PINW_UNSOLRESP 0x620b8 #define AUD_CNTL_ST 0x620b4 #define AUD_PINW_CONFIG 0x620bc #define AUD_HDMIW_STATUS 0x620d4 #define AUD_HDMIW_HDMIEDID 0x6210c #define AUD_HDMIW_INFOFR 0x62118 #define AUD_CONV_CHCNT 0x62120 #define AUD_CTS_ENABLE 0x62128 #define VIDEO_DIP_CTL 0x61170 #define VIDEO_DIP_ENABLE (1<<31) #define VIDEO_DIP_ENABLE_AVI (1<<21) #define VIDEO_DIP_ENABLE_VENDOR (1<<22) #define VIDEO_DIP_ENABLE_SPD (1<<24) #define VIDEO_DIP_BUF_AVI (0<<19) #define VIDEO_DIP_BUF_VENDOR (1<<19) #define VIDEO_DIP_BUF_SPD (3<<19) #define VIDEO_DIP_TRANS_ONCE (0<<16) #define VIDEO_DIP_TRANS_1 (1<<16) #define VIDEO_DIP_TRANS_2 (2<<16) #define AUDIO_HOTPLUG_EN (1<<24) static void dump_eaglelake(void) { uint32_t dword; int i; /* printf("%-18s %8s %s\n\n", "register name", "raw value", "description"); */ dump_reg(VIDEO_DIP_CTL, "Video DIP Control"); dump_reg(SDVOB, "Digital Display Port B Control Register"); dump_reg(SDVOC, "Digital Display Port C Control Register"); dump_reg(PORT_HOTPLUG_EN, "Hot Plug Detect Enable"); dump_reg(AUD_CONFIG, "Audio Configuration"); dump_reg(AUD_DEBUG, "Audio Debug"); dump_reg(AUD_VID_DID, "Audio Vendor ID / Device ID"); dump_reg(AUD_RID, "Audio Revision ID"); dump_reg(AUD_SUBN_CNT, "Audio Subordinate Node Count"); dump_reg(AUD_FUNC_GRP, "Audio Function Group Type"); dump_reg(AUD_SUBN_CNT2, "Audio Subordinate Node Count"); dump_reg(AUD_GRP_CAP, "Audio Function Group Capabilities"); dump_reg(AUD_PWRST, "Audio Power State"); dump_reg(AUD_SUPPWR, "Audio Supported Power States"); dump_reg(AUD_SID, "Audio Root Node Subsystem ID"); dump_reg(AUD_OUT_CWCAP, "Audio Output Converter Widget Capabilities"); dump_reg(AUD_OUT_PCMSIZE, "Audio PCM Size and Rates"); dump_reg(AUD_OUT_STR, "Audio Stream Formats"); dump_reg(AUD_OUT_DIG_CNVT, "Audio Digital Converter"); dump_reg(AUD_OUT_CH_STR, "Audio Channel ID and Stream ID"); dump_reg(AUD_OUT_STR_DESC, "Audio Stream Descriptor Format"); dump_reg(AUD_PINW_CAP, "Audio Pin Complex Widget Capabilities"); dump_reg(AUD_PIN_CAP, "Audio Pin Capabilities"); dump_reg(AUD_PINW_CONNLNG, "Audio Connection List Length"); dump_reg(AUD_PINW_CONNLST, "Audio Connection List Entry"); dump_reg(AUD_PINW_CNTR, "Audio Pin Widget Control"); dump_reg(AUD_PINW_UNSOLRESP, "Audio Unsolicited Response Enable"); dump_reg(AUD_CNTL_ST, "Audio Control State Register"); dump_reg(AUD_PINW_CONFIG, "Audio Configuration Default"); dump_reg(AUD_HDMIW_STATUS, "Audio HDMI Status"); dump_reg(AUD_HDMIW_HDMIEDID, "Audio HDMI Data EDID Block"); dump_reg(AUD_HDMIW_INFOFR, "Audio HDMI Widget Data Island Packet"); dump_reg(AUD_CONV_CHCNT, "Audio Converter Channel Count"); dump_reg(AUD_CTS_ENABLE, "Audio CTS Programming Enable"); printf("\nDetails:\n\n"); dword = INREG(AUD_VID_DID); printf("AUD_VID_DID vendor id\t\t\t0x%x\n", dword >> 16); printf("AUD_VID_DID device id\t\t\t0x%x\n", dword & 0xffff); dword = INREG(AUD_RID); printf("AUD_RID major revision\t\t\t0x%lx\n", BITS(dword, 23, 20)); printf("AUD_RID minor revision\t\t\t0x%lx\n", BITS(dword, 19, 16)); printf("AUD_RID revision id\t\t\t0x%lx\n", BITS(dword, 15, 8)); printf("AUD_RID stepping id\t\t\t0x%lx\n", BITS(dword, 7, 0)); dword = INREG(SDVOB); printf("SDVOB enable\t\t\t\t%u\n", !!(dword & SDVO_ENABLE)); printf("SDVOB HDMI encoding\t\t\t%u\n", !!(dword & SDVO_ENCODING_HDMI)); printf("SDVOB SDVO encoding\t\t\t%u\n", !!(dword & SDVO_ENCODING_SDVO)); printf("SDVOB null packets\t\t\t%u\n", !!(dword & SDVO_NULL_PACKETS_DURING_VSYNC)); printf("SDVOB audio enabled\t\t\t%u\n", !!(dword & SDVO_AUDIO_ENABLE)); dword = INREG(SDVOC); printf("SDVOC enable\t\t\t\t%u\n", !!(dword & SDVO_ENABLE)); printf("SDVOC HDMI encoding\t\t\t%u\n", !!(dword & SDVO_ENCODING_HDMI)); printf("SDVOC SDVO encoding\t\t\t%u\n", !!(dword & SDVO_ENCODING_SDVO)); printf("SDVOC null packets\t\t\t%u\n", !!(dword & SDVO_NULL_PACKETS_DURING_VSYNC)); printf("SDVOC audio enabled\t\t\t%u\n", !!(dword & SDVO_AUDIO_ENABLE)); dword = INREG(PORT_HOTPLUG_EN); printf("PORT_HOTPLUG_EN DisplayPort/HDMI port B\t%ld\n", BIT(dword, 29)), printf("PORT_HOTPLUG_EN DisplayPort/HDMI port C\t%ld\n", BIT(dword, 28)), printf("PORT_HOTPLUG_EN DisplayPort port D\t%ld\n", BIT(dword, 27)), printf("PORT_HOTPLUG_EN SDVOB\t\t\t%ld\n", BIT(dword, 26)), printf("PORT_HOTPLUG_EN SDVOC\t\t\t%ld\n", BIT(dword, 25)), printf("PORT_HOTPLUG_EN audio\t\t\t%ld\n", BIT(dword, 24)), printf("PORT_HOTPLUG_EN TV\t\t\t%ld\n", BIT(dword, 23)), printf("PORT_HOTPLUG_EN CRT\t\t\t%ld\n", BIT(dword, 9)), dword = INREG(VIDEO_DIP_CTL); printf("VIDEO_DIP_CTL enable graphics DIP\t%ld\n", BIT(dword, 31)), printf("VIDEO_DIP_CTL port select\t\t[0x%lx] %s\n", BITS(dword, 30, 29), dip_port[BITS(dword, 30, 29)]); printf("VIDEO_DIP_CTL DIP buffer trans active\t%lu\n", BIT(dword, 28)); printf("VIDEO_DIP_CTL AVI DIP enabled\t\t%lu\n", BIT(dword, 21)); printf("VIDEO_DIP_CTL vendor DIP enabled\t%lu\n", BIT(dword, 22)); printf("VIDEO_DIP_CTL SPD DIP enabled\t\t%lu\n", BIT(dword, 24)); printf("VIDEO_DIP_CTL DIP buffer index\t\t[0x%lx] %s\n", BITS(dword, 20, 19), video_dip_index[BITS(dword, 20, 19)]); printf("VIDEO_DIP_CTL DIP trans freq\t\t[0x%lx] %s\n", BITS(dword, 17, 16), video_dip_trans[BITS(dword, 17, 16)]); printf("VIDEO_DIP_CTL DIP buffer size\t\t%lu\n", BITS(dword, 11, 8)); printf("VIDEO_DIP_CTL DIP address\t\t%lu\n", BITS(dword, 3, 0)); dword = INREG(AUD_CONFIG); printf("AUD_CONFIG pixel clock\t\t\t[0x%lx] %s\n", BITS(dword, 19, 16), OPNAME(pixel_clock, BITS(dword, 19, 16))); printf("AUD_CONFIG fabrication enabled\t\t%lu\n", BITS(dword, 2, 2)); printf("AUD_CONFIG professional use allowed\t%lu\n", BIT(dword, 1)); printf("AUD_CONFIG fuse enabled\t\t\t%lu\n", BIT(dword, 0)); dword = INREG(AUD_DEBUG); printf("AUD_DEBUG function reset\t\t%lu\n", BIT(dword, 0)); dword = INREG(AUD_SUBN_CNT); printf("AUD_SUBN_CNT starting node number\t0x%lx\n", BITS(dword, 23, 16)); printf("AUD_SUBN_CNT total number of nodes\t0x%lx\n", BITS(dword, 7, 0)); dword = INREG(AUD_SUBN_CNT2); printf("AUD_SUBN_CNT2 starting node number\t0x%lx\n", BITS(dword, 24, 16)); printf("AUD_SUBN_CNT2 total number of nodes\t0x%lx\n", BITS(dword, 7, 0)); dword = INREG(AUD_FUNC_GRP); printf("AUD_FUNC_GRP unsol capable\t\t%lu\n", BIT(dword, 8)); printf("AUD_FUNC_GRP node type\t\t\t0x%lx\n", BITS(dword, 7, 0)); dword = INREG(AUD_GRP_CAP); printf("AUD_GRP_CAP beep 0\t\t\t%lu\n", BIT(dword, 16)); printf("AUD_GRP_CAP input delay\t\t\t%lu\n", BITS(dword, 11, 8)); printf("AUD_GRP_CAP output delay\t\t%lu\n", BITS(dword, 3, 0)); dword = INREG(AUD_PWRST); printf("AUD_PWRST device power state\t\t%s\n", power_state[BITS(dword, 5, 4)]); printf("AUD_PWRST device power state setting\t%s\n", power_state[BITS(dword, 1, 0)]); dword = INREG(AUD_SUPPWR); printf("AUD_SUPPWR support D0\t\t\t%lu\n", BIT(dword, 0)); printf("AUD_SUPPWR support D1\t\t\t%lu\n", BIT(dword, 1)); printf("AUD_SUPPWR support D2\t\t\t%lu\n", BIT(dword, 2)); printf("AUD_SUPPWR support D3\t\t\t%lu\n", BIT(dword, 3)); dword = INREG(AUD_OUT_CWCAP); printf("AUD_OUT_CWCAP widget type\t\t0x%lx\n", BITS(dword, 23, 20)); printf("AUD_OUT_CWCAP sample delay\t\t0x%lx\n", BITS(dword, 19, 16)); printf("AUD_OUT_CWCAP channel count\t\t%lu\n", BITS(dword, 15, 13) * 2 + BIT(dword, 0) + 1); printf("AUD_OUT_CWCAP L-R swap\t\t\t%lu\n", BIT(dword, 11)); printf("AUD_OUT_CWCAP power control\t\t%lu\n", BIT(dword, 10)); printf("AUD_OUT_CWCAP digital\t\t\t%lu\n", BIT(dword, 9)); printf("AUD_OUT_CWCAP conn list\t\t\t%lu\n", BIT(dword, 8)); printf("AUD_OUT_CWCAP unsol\t\t\t%lu\n", BIT(dword, 7)); printf("AUD_OUT_CWCAP mute\t\t\t%lu\n", BIT(dword, 5)); printf("AUD_OUT_CWCAP format override\t\t%lu\n", BIT(dword, 4)); printf("AUD_OUT_CWCAP amp param override\t%lu\n", BIT(dword, 3)); printf("AUD_OUT_CWCAP out amp present\t\t%lu\n", BIT(dword, 2)); printf("AUD_OUT_CWCAP in amp present\t\t%lu\n", BIT(dword, 1)); dword = INREG(AUD_OUT_DIG_CNVT); printf("AUD_OUT_DIG_CNVT SPDIF category\t\t0x%lx\n", BITS(dword, 14, 8)); printf("AUD_OUT_DIG_CNVT SPDIF level\t\t%lu\n", BIT(dword, 7)); printf("AUD_OUT_DIG_CNVT professional\t\t%lu\n", BIT(dword, 6)); printf("AUD_OUT_DIG_CNVT non PCM\t\t%lu\n", BIT(dword, 5)); printf("AUD_OUT_DIG_CNVT copyright asserted\t%lu\n", BIT(dword, 4)); printf("AUD_OUT_DIG_CNVT filter preemphasis\t%lu\n", BIT(dword, 3)); printf("AUD_OUT_DIG_CNVT validity config\t%lu\n", BIT(dword, 2)); printf("AUD_OUT_DIG_CNVT validity flag\t\t%lu\n", BIT(dword, 1)); printf("AUD_OUT_DIG_CNVT digital enable\t\t%lu\n", BIT(dword, 0)); dword = INREG(AUD_OUT_CH_STR); printf("AUD_OUT_CH_STR stream id\t\t0x%lx\n", BITS(dword, 7, 4)); printf("AUD_OUT_CH_STR lowest channel\t\t%lu\n", BITS(dword, 3, 0)); dword = INREG(AUD_OUT_STR_DESC); printf("AUD_OUT_STR_DESC stream channels\t%lu\n", BITS(dword, 3, 0) + 1); printf("AUD_OUT_STR_DESC Bits per Sample\t[%#lx] %s\n", BITS(dword, 6, 4), OPNAME(bits_per_sample, BITS(dword, 6, 4))); dword = INREG(AUD_PINW_CAP); printf("AUD_PINW_CAP widget type\t\t0x%lx\n", BITS(dword, 23, 20)); printf("AUD_PINW_CAP sample delay\t\t0x%lx\n", BITS(dword, 19, 16)); printf("AUD_PINW_CAP channel count\t\t%lu\n", BITS(dword, 15, 13) * 2 + BIT(dword, 0) + 1); printf("AUD_PINW_CAP HDCP\t\t\t%lu\n", BIT(dword, 12)); printf("AUD_PINW_CAP L-R swap\t\t\t%lu\n", BIT(dword, 11)); printf("AUD_PINW_CAP power control\t\t%lu\n", BIT(dword, 10)); printf("AUD_PINW_CAP digital\t\t\t%lu\n", BIT(dword, 9)); printf("AUD_PINW_CAP conn list\t\t\t%lu\n", BIT(dword, 8)); printf("AUD_PINW_CAP unsol\t\t\t%lu\n", BIT(dword, 7)); printf("AUD_PINW_CAP mute\t\t\t%lu\n", BIT(dword, 5)); printf("AUD_PINW_CAP format override\t\t%lu\n", BIT(dword, 4)); printf("AUD_PINW_CAP amp param override\t\t%lu\n", BIT(dword, 3)); printf("AUD_PINW_CAP out amp present\t\t%lu\n", BIT(dword, 2)); printf("AUD_PINW_CAP in amp present\t\t%lu\n", BIT(dword, 1)); dword = INREG(AUD_PIN_CAP); printf("AUD_PIN_CAP EAPD\t\t\t%lu\n", BIT(dword, 16)); printf("AUD_PIN_CAP HDMI\t\t\t%lu\n", BIT(dword, 7)); printf("AUD_PIN_CAP output\t\t\t%lu\n", BIT(dword, 4)); printf("AUD_PIN_CAP presence detect\t\t%lu\n", BIT(dword, 2)); dword = INREG(AUD_PINW_CNTR); printf("AUD_PINW_CNTR mute status\t\t%lu\n", BIT(dword, 8)); printf("AUD_PINW_CNTR out enable\t\t%lu\n", BIT(dword, 6)); printf("AUD_PINW_CNTR amp mute status\t\t%lu\n", BIT(dword, 8)); printf("AUD_PINW_CNTR amp mute status\t\t%lu\n", BIT(dword, 8)); printf("AUD_PINW_CNTR stream type\t\t[0x%lx] %s\n", BITS(dword, 2, 0), OPNAME(stream_type, BITS(dword, 2, 0))); dword = INREG(AUD_PINW_UNSOLRESP); printf("AUD_PINW_UNSOLRESP enable unsol resp\t%lu\n", BIT(dword, 31)); dword = INREG(AUD_CNTL_ST); printf("AUD_CNTL_ST DIP audio enabled\t\t%lu\n", BIT(dword, 21)); printf("AUD_CNTL_ST DIP ACP enabled\t\t%lu\n", BIT(dword, 22)); printf("AUD_CNTL_ST DIP ISRCx enabled\t\t%lu\n", BIT(dword, 23)); printf("AUD_CNTL_ST DIP port select\t\t[0x%lx] %s\n", BITS(dword, 30, 29), dip_port[BITS(dword, 30, 29)]); printf("AUD_CNTL_ST DIP buffer index\t\t[0x%lx] %s\n", BITS(dword, 20, 18), OPNAME(dip_index, BITS(dword, 20, 18))); printf("AUD_CNTL_ST DIP trans freq\t\t[0x%lx] %s\n", BITS(dword, 17, 16), dip_trans[BITS(dword, 17, 16)]); printf("AUD_CNTL_ST DIP address\t\t\t%lu\n", BITS(dword, 3, 0)); printf("AUD_CNTL_ST CP ready\t\t\t%lu\n", BIT(dword, 15)); printf("AUD_CNTL_ST ELD valid\t\t\t%lu\n", BIT(dword, 14)); printf("AUD_CNTL_ST ELD ack\t\t\t%lu\n", BIT(dword, 4)); printf("AUD_CNTL_ST ELD bufsize\t\t\t%lu\n", BITS(dword, 13, 9)); printf("AUD_CNTL_ST ELD address\t\t\t%lu\n", BITS(dword, 8, 5)); dword = INREG(AUD_HDMIW_STATUS); printf("AUD_HDMIW_STATUS CDCLK/DOTCLK underrun\t%lu\n", BIT(dword, 31)); printf("AUD_HDMIW_STATUS CDCLK/DOTCLK overrun\t%lu\n", BIT(dword, 30)); printf("AUD_HDMIW_STATUS BCLK/CDCLK underrun\t%lu\n", BIT(dword, 29)); printf("AUD_HDMIW_STATUS BCLK/CDCLK overrun\t%lu\n", BIT(dword, 28)); dword = INREG(AUD_CONV_CHCNT); printf("AUD_CONV_CHCNT HDMI HBR enabled\t\t%lu\n", BITS(dword, 15, 14)); printf("AUD_CONV_CHCNT HDMI channel count\t%lu\n", BITS(dword, 11, 8) + 1); printf("AUD_CONV_CHCNT HDMI channel mapping:\n"); for (i = 0; i < 8; i++) { OUTREG(AUD_CONV_CHCNT, i); dword = INREG(AUD_CONV_CHCNT); printf("\t\t\t\t\t[0x%x] %u => %lu\n", dword, i, BITS(dword, 7, 4)); } printf("AUD_HDMIW_HDMIEDID HDMI ELD:\n\t"); dword = INREG(AUD_CNTL_ST); dword &= ~BITMASK(8, 5); OUTREG(AUD_CNTL_ST, dword); for (i = 0; i < BITS(dword, 14, 10) / 4; i++) printf("%08x ", htonl(INREG(AUD_HDMIW_HDMIEDID))); printf("\n"); printf("AUD_HDMIW_INFOFR HDMI audio Infoframe:\n\t"); dword = INREG(AUD_CNTL_ST); dword &= ~BITMASK(20, 18); dword &= ~BITMASK(3, 0); OUTREG(AUD_CNTL_ST, dword); for (i = 0; i < 8; i++) printf("%08x ", htonl(INREG(AUD_HDMIW_INFOFR))); printf("\n"); } #undef AUD_RID #undef AUD_VID_DID #undef AUD_PWRST #undef AUD_OUT_CH_STR #undef AUD_HDMIW_STATUS /* * CougarPoint registers */ #define DP_CTL_B 0xE4100 #define DP_CTL_C 0xE4200 #define DP_AUX_CTL_C 0xE4210 #define DP_AUX_TST_C 0xE4228 #define SPORT_DDI_CRC_C 0xE4250 #define SPORT_DDI_CRC_R 0xE4264 #define DP_CTL_D 0xE4300 #define DP_AUX_CTL_D 0xE4310 #define DP_AUX_TST_D 0xE4328 #define SPORT_DDI_CRC_CTL_D 0xE4350 #define AUD_CONFIG_A 0xE5000 #define AUD_MISC_CTRL_A 0xE5010 #define AUD_VID_DID 0xE5020 #define AUD_RID 0xE5024 #define AUD_CTS_ENABLE_A 0xE5028 #define AUD_PWRST 0xE504C #define AUD_HDMIW_HDMIEDID_A 0xE5050 #define AUD_HDMIW_INFOFR_A 0xE5054 #define AUD_PORT_EN_HD_CFG 0xE507C #define AUD_OUT_DIG_CNVT_A 0xE5080 #define AUD_OUT_STR_DESC_A 0xE5084 #define AUD_OUT_CH_STR 0xE5088 #define AUD_PINW_CONNLNG_LIST 0xE50A8 #define AUD_PINW_CONNLNG_SEL 0xE50AC #define AUD_CNTL_ST_A 0xE50B4 #define AUD_CNTRL_ST2 0xE50C0 #define AUD_CNTRL_ST3 0xE50C4 #define AUD_HDMIW_STATUS 0xE50D4 #define AUD_CONFIG_B 0xE5100 #define AUD_MISC_CTRL_B 0xE5110 #define AUD_CTS_ENABLE_B 0xE5128 #define AUD_HDMIW_HDMIEDID_B 0xE5150 #define AUD_HDMIW_INFOFR_B 0xE5154 #define AUD_OUT_DIG_CNVT_B 0xE5180 #define AUD_OUT_STR_DESC_B 0xE5184 #define AUD_CNTL_ST_B 0xE51B4 #define AUD_CONFIG_C 0xE5200 #define AUD_MISC_CTRL_C 0xE5210 #define AUD_CTS_ENABLE_C 0xE5228 #define AUD_HDMIW_HDMIEDID_C 0xE5250 #define AUD_HDMIW_INFOFR_C 0xE5254 #define AUD_OUT_DIG_CNVT_C 0xE5280 #define AUD_OUT_STR_DESC_C 0xE5284 #define AUD_CNTL_ST_C 0xE52B4 #define AUD_CONFIG_D 0xE5300 #define AUD_MISC_CTRL_D 0xE5310 #define AUD_CTS_ENABLE_D 0xE5328 #define AUD_HDMIW_HDMIEDID_D 0xE5350 #define AUD_HDMIW_INFOFR_D 0xE5354 #define AUD_OUT_DIG_CNVT_D 0xE5380 #define AUD_OUT_STR_DESC_D 0xE5384 #define AUD_CNTL_ST_D 0xE53B4 #define VIDEO_DIP_CTL_A 0xE0200 #define VIDEO_DIP_CTL_B 0xE1200 #define VIDEO_DIP_CTL_C 0xE2200 #define VIDEO_DIP_CTL_D 0xE3200 static void dump_cpt(void) { uint32_t dword; int i; dump_reg(HDMIB, "sDVO/HDMI Port B Control"); dump_reg(HDMIC, "HDMI Port C Control"); dump_reg(HDMID, "HDMI Port D Control"); dump_reg(DP_CTL_B, "DisplayPort B Control"); dump_reg(DP_CTL_C, "DisplayPort C Control"); dump_reg(DP_CTL_D, "DisplayPort D Control"); dump_reg(TRANS_DP_CTL_A, "Transcoder A DisplayPort Control"); dump_reg(TRANS_DP_CTL_B, "Transcoder B DisplayPort Control"); dump_reg(TRANS_DP_CTL_C, "Transcoder C DisplayPort Control"); dump_reg(AUD_CONFIG_A, "Audio Configuration - Transcoder A"); dump_reg(AUD_CONFIG_B, "Audio Configuration - Transcoder B"); dump_reg(AUD_CONFIG_C, "Audio Configuration - Transcoder C"); dump_reg(AUD_CTS_ENABLE_A, "Audio CTS Programming Enable - Transcoder A"); dump_reg(AUD_CTS_ENABLE_B, "Audio CTS Programming Enable - Transcoder B"); dump_reg(AUD_CTS_ENABLE_C, "Audio CTS Programming Enable - Transcoder C"); dump_reg(AUD_MISC_CTRL_A, "Audio MISC Control for Transcoder A"); dump_reg(AUD_MISC_CTRL_B, "Audio MISC Control for Transcoder B"); dump_reg(AUD_MISC_CTRL_C, "Audio MISC Control for Transcoder C"); dump_reg(AUD_VID_DID, "Audio Vendor ID / Device ID"); dump_reg(AUD_RID, "Audio Revision ID"); dump_reg(AUD_PWRST, "Audio Power State (Function Group, Convertor, Pin Widget)"); dump_reg(AUD_PORT_EN_HD_CFG, "Audio Port Enable HDAudio Config"); dump_reg(AUD_OUT_DIG_CNVT_A, "Audio Digital Converter - Conv A"); dump_reg(AUD_OUT_DIG_CNVT_B, "Audio Digital Converter - Conv B"); dump_reg(AUD_OUT_DIG_CNVT_C, "Audio Digital Converter - Conv C"); dump_reg(AUD_OUT_CH_STR, "Audio Channel ID and Stream ID"); dump_reg(AUD_OUT_STR_DESC_A, "Audio Stream Descriptor Format - Conv A"); dump_reg(AUD_OUT_STR_DESC_B, "Audio Stream Descriptor Format - Conv B"); dump_reg(AUD_OUT_STR_DESC_C, "Audio Stream Descriptor Format - Conv C"); dump_reg(AUD_PINW_CONNLNG_LIST, "Audio Connection List"); dump_reg(AUD_PINW_CONNLNG_SEL, "Audio Connection Select"); dump_reg(AUD_CNTL_ST_A, "Audio Control State Register - Transcoder A"); dump_reg(AUD_CNTL_ST_B, "Audio Control State Register - Transcoder B"); dump_reg(AUD_CNTL_ST_C, "Audio Control State Register - Transcoder C"); dump_reg(AUD_CNTRL_ST2, "Audio Control State 2"); dump_reg(AUD_CNTRL_ST3, "Audio Control State 3"); dump_reg(AUD_HDMIW_STATUS, "Audio HDMI Status"); dump_reg(AUD_HDMIW_HDMIEDID_A, "HDMI Data EDID Block - Transcoder A"); dump_reg(AUD_HDMIW_HDMIEDID_B, "HDMI Data EDID Block - Transcoder B"); dump_reg(AUD_HDMIW_HDMIEDID_C, "HDMI Data EDID Block - Transcoder C"); dump_reg(AUD_HDMIW_INFOFR_A, "Audio Widget Data Island Packet - Transcoder A"); dump_reg(AUD_HDMIW_INFOFR_B, "Audio Widget Data Island Packet - Transcoder B"); dump_reg(AUD_HDMIW_INFOFR_C, "Audio Widget Data Island Packet - Transcoder C"); printf("\nDetails:\n\n"); dword = INREG(VIDEO_DIP_CTL_A); printf("VIDEO_DIP_CTL_A Enable_Graphics_DIP\t\t\t%ld\n", BIT(dword, 31)), printf("VIDEO_DIP_CTL_A GCP_DIP_enable\t\t\t\t%ld\n", BIT(dword, 25)), printf("VIDEO_DIP_CTL_A Video_DIP_type_enable AVI\t\t%lu\n", BIT(dword, 21)); printf("VIDEO_DIP_CTL_A Video_DIP_type_enable Vendor\t\t%lu\n", BIT(dword, 22)); printf("VIDEO_DIP_CTL_A Video_DIP_type_enable Gamut\t\t%lu\n", BIT(dword, 23)); printf("VIDEO_DIP_CTL_A Video_DIP_type_enable Source \t\t%lu\n", BIT(dword, 24)); printf("VIDEO_DIP_CTL_A Video_DIP_buffer_index\t\t\t[0x%lx] %s\n", BITS(dword, 20, 19), video_dip_index[BITS(dword, 20, 19)]); printf("VIDEO_DIP_CTL_A Video_DIP_frequency\t\t\t[0x%lx] %s\n", BITS(dword, 17, 16), video_dip_trans[BITS(dword, 17, 16)]); printf("VIDEO_DIP_CTL_A Video_DIP_buffer_size\t\t\t%lu\n", BITS(dword, 11, 8)); printf("VIDEO_DIP_CTL_A Video_DIP_access_address\t\t%lu\n", BITS(dword, 3, 0)); dword = INREG(VIDEO_DIP_CTL_B); printf("VIDEO_DIP_CTL_B Enable_Graphics_DIP\t\t\t%ld\n", BIT(dword, 31)), printf("VIDEO_DIP_CTL_B GCP_DIP_enable\t\t\t\t%ld\n", BIT(dword, 25)), printf("VIDEO_DIP_CTL_B Video_DIP_type_enable AVI\t\t%lu\n", BIT(dword, 21)); printf("VIDEO_DIP_CTL_B Video_DIP_type_enable Vendor\t\t%lu\n", BIT(dword, 22)); printf("VIDEO_DIP_CTL_B Video_DIP_type_enable Gamut\t\t%lu\n", BIT(dword, 23)); printf("VIDEO_DIP_CTL_B Video_DIP_type_enable Source \t\t%lu\n", BIT(dword, 24)); printf("VIDEO_DIP_CTL_B Video_DIP_buffer_index\t\t\t[0x%lx] %s\n", BITS(dword, 20, 19), video_dip_index[BITS(dword, 20, 19)]); printf("VIDEO_DIP_CTL_B Video_DIP_frequency\t\t\t[0x%lx] %s\n", BITS(dword, 17, 16), video_dip_trans[BITS(dword, 17, 16)]); printf("VIDEO_DIP_CTL_B Video_DIP_buffer_size\t\t\t%lu\n", BITS(dword, 11, 8)); printf("VIDEO_DIP_CTL_B Video_DIP_access_address\t\t%lu\n", BITS(dword, 3, 0)); dword = INREG(VIDEO_DIP_CTL_C); printf("VIDEO_DIP_CTL_C Enable_Graphics_DIP\t\t\t%ld\n", BIT(dword, 31)), printf("VIDEO_DIP_CTL_C GCP_DIP_enable\t\t\t\t%ld\n", BIT(dword, 25)), printf("VIDEO_DIP_CTL_C Video_DIP_type_enable AVI\t\t%lu\n", BIT(dword, 21)); printf("VIDEO_DIP_CTL_C Video_DIP_type_enable Vendor\t\t%lu\n", BIT(dword, 22)); printf("VIDEO_DIP_CTL_C Video_DIP_type_enable Gamut\t\t%lu\n", BIT(dword, 23)); printf("VIDEO_DIP_CTL_C Video_DIP_type_enable Source \t\t%lu\n", BIT(dword, 24)); printf("VIDEO_DIP_CTL_C Video_DIP_buffer_index\t\t\t[0x%lx] %s\n", BITS(dword, 20, 19), video_dip_index[BITS(dword, 20, 19)]); printf("VIDEO_DIP_CTL_C Video_DIP_frequency\t\t\t[0x%lx] %s\n", BITS(dword, 17, 16), video_dip_trans[BITS(dword, 17, 16)]); printf("VIDEO_DIP_CTL_C Video_DIP_buffer_size\t\t\t%lu\n", BITS(dword, 11, 8)); printf("VIDEO_DIP_CTL_C Video_DIP_access_address\t\t%lu\n", BITS(dword, 3, 0)); dword = INREG(AUD_VID_DID); printf("AUD_VID_DID vendor id\t\t\t\t\t0x%x\n", dword >> 16); printf("AUD_VID_DID device id\t\t\t\t\t0x%x\n", dword & 0xffff); dword = INREG(AUD_RID); printf("AUD_RID Major_Revision\t\t\t\t\t0x%lx\n", BITS(dword, 23, 20)); printf("AUD_RID Minor_Revision\t\t\t\t\t0x%lx\n", BITS(dword, 19, 16)); printf("AUD_RID Revision_Id\t\t\t\t\t0x%lx\n", BITS(dword, 15, 8)); printf("AUD_RID Stepping_Id\t\t\t\t\t0x%lx\n", BITS(dword, 7, 0)); dword = INREG(HDMIB); printf("HDMIB Port_Enable\t\t\t\t\t%u\n", !!(dword & SDVO_ENABLE)); printf("HDMIB Transcoder_Select\t\t\t\t\t[0x%lx] %s\n", BITS(dword, 30, 29), transcoder_select[BITS(dword, 30, 29)]); printf("HDMIB sDVO_Border_Enable\t\t\t\t%lu\n", BIT(dword, 7)); printf("HDMIB HDCP_Port_Select\t\t\t\t\t%lu\n", BIT(dword, 5)); printf("HDMIB SDVO_HPD_Interrupt_Enable\t\t\t\t%lu\n", BIT(dword, 23)); printf("HDMIB Port_Detected\t\t\t\t\t%lu\n", BIT(dword, 2)); printf("HDMIB Encoding\t\t\t\t\t\t[0x%lx] %s\n", BITS(dword, 11, 10), sdvo_hdmi_encoding[BITS(dword, 11, 10)]); printf("HDMIB HDMI_or_DVI_Select\t\t\t\t%s\n", BIT(dword, 9) ? "HDMI" : "DVI"); printf("HDMIB Audio_Output_Enable\t\t\t\t%u\n", !!(dword & SDVO_AUDIO_ENABLE)); dword = INREG(HDMIC); printf("HDMIC Port_Enable\t\t\t\t\t%u\n", !!(dword & SDVO_ENABLE)); printf("HDMIC Transcoder_Select\t\t\t\t\t[0x%lx] %s\n", BITS(dword, 30, 29), transcoder_select[BITS(dword, 30, 29)]); printf("HDMIC sDVO_Border_Enable\t\t\t\t%lu\n", BIT(dword, 7)); printf("HDMIC HDCP_Port_Select\t\t\t\t\t%lu\n", BIT(dword, 5)); printf("HDMIC SDVO_HPD_Interrupt_Enable\t\t\t\t%lu\n", BIT(dword, 23)); printf("HDMIC Port_Detected\t\t\t\t\t%lu\n", BIT(dword, 2)); printf("HDMIC Encoding\t\t\t\t\t\t[0x%lx] %s\n", BITS(dword, 11, 10), sdvo_hdmi_encoding[BITS(dword, 11, 10)]); printf("HDMIC HDMI_or_DVI_Select\t\t\t\t%s\n", BIT(dword, 9) ? "HDMI" : "DVI"); printf("HDMIC Audio_Output_Enable\t\t\t\t%u\n", !!(dword & SDVO_AUDIO_ENABLE)); dword = INREG(HDMID); printf("HDMID Port_Enable\t\t\t\t\t%u\n", !!(dword & SDVO_ENABLE)); printf("HDMID Transcoder_Select\t\t\t\t\t[0x%lx] %s\n", BITS(dword, 30, 29), transcoder_select[BITS(dword, 30, 29)]); printf("HDMID sDVO_Border_Enable\t\t\t\t%lu\n", BIT(dword, 7)); printf("HDMID HDCP_Port_Select\t\t\t\t\t%lu\n", BIT(dword, 5)); printf("HDMID SDVO_HPD_Interrupt_Enable\t\t\t\t%lu\n", BIT(dword, 23)); printf("HDMID Port_Detected\t\t\t\t\t%lu\n", BIT(dword, 2)); printf("HDMID Encoding\t\t\t\t\t\t[0x%lx] %s\n", BITS(dword, 11, 10), sdvo_hdmi_encoding[BITS(dword, 11, 10)]); printf("HDMID HDMI_or_DVI_Select\t\t\t\t%s\n", BIT(dword, 9) ? "HDMI" : "DVI"); printf("HDMID Audio_Output_Enable\t\t\t\t%u\n", !!(dword & SDVO_AUDIO_ENABLE)); dword = INREG(DP_CTL_B); printf("DP_CTL_B DisplayPort_Enable\t\t\t\t%lu\n", BIT(dword, 31)); printf("DP_CTL_B Port_Width_Selection\t\t\t\t[0x%lx] %s\n", BITS(dword, 21, 19), dp_port_width[BITS(dword, 21, 19)]); printf("DP_CTL_B Port_Detected\t\t\t\t\t%lu\n", BIT(dword, 2)); printf("DP_CTL_B HDCP_Port_Select\t\t\t\t%lu\n", BIT(dword, 5)); printf("DP_CTL_B Audio_Output_Enable\t\t\t\t%lu\n", BIT(dword, 6)); dword = INREG(DP_CTL_C); printf("DP_CTL_C DisplayPort_Enable\t\t\t\t%lu\n", BIT(dword, 31)); printf("DP_CTL_C Port_Width_Selection\t\t\t\t[0x%lx] %s\n", BITS(dword, 21, 19), dp_port_width[BITS(dword, 21, 19)]); printf("DP_CTL_C Port_Detected\t\t\t\t\t%lu\n", BIT(dword, 2)); printf("DP_CTL_C HDCP_Port_Select\t\t\t\t%lu\n", BIT(dword, 5)); printf("DP_CTL_C Audio_Output_Enable\t\t\t\t%lu\n", BIT(dword, 6)); dword = INREG(DP_CTL_D); printf("DP_CTL_D DisplayPort_Enable\t\t\t\t%lu\n", BIT(dword, 31)); printf("DP_CTL_D Port_Width_Selection\t\t\t\t[0x%lx] %s\n", BITS(dword, 21, 19), dp_port_width[BITS(dword, 21, 19)]); printf("DP_CTL_D Port_Detected\t\t\t\t\t%lu\n", BIT(dword, 2)); printf("DP_CTL_D HDCP_Port_Select\t\t\t\t%lu\n", BIT(dword, 5)); printf("DP_CTL_D Audio_Output_Enable\t\t\t\t%lu\n", BIT(dword, 6)); dword = INREG(AUD_CONFIG_A); printf("AUD_CONFIG_A N_index_value\t\t\t\t[0x%lx] %s\n", BIT(dword, 29), n_index_value[BIT(dword, 29)]); printf("AUD_CONFIG_A N_programming_enable\t\t\t%lu\n", BIT(dword, 28)); printf("AUD_CONFIG_A Upper_N_value\t\t\t\t0x%02lx\n", BITS(dword, 27, 20)); printf("AUD_CONFIG_A Lower_N_value\t\t\t\t0x%03lx\n", BITS(dword, 15, 4)); printf("AUD_CONFIG_A Pixel_Clock_HDMI\t\t\t\t[0x%lx] %s\n", BITS(dword, 19, 16), OPNAME(pixel_clock, BITS(dword, 19, 16))); printf("AUD_CONFIG_A Disable_NCTS\t\t\t\t%lu\n", BIT(dword, 3)); dword = INREG(AUD_CONFIG_B); printf("AUD_CONFIG_B N_index_value\t\t\t\t[0x%lx] %s\n", BIT(dword, 29), n_index_value[BIT(dword, 29)]); printf("AUD_CONFIG_B N_programming_enable\t\t\t%lu\n", BIT(dword, 28)); printf("AUD_CONFIG_B Upper_N_value\t\t\t\t0x%02lx\n", BITS(dword, 27, 20)); printf("AUD_CONFIG_B Lower_N_value\t\t\t\t0x%03lx\n", BITS(dword, 15, 4)); printf("AUD_CONFIG_B Pixel_Clock_HDMI\t\t\t\t[0x%lx] %s\n", BITS(dword, 19, 16), OPNAME(pixel_clock, BITS(dword, 19, 16))); printf("AUD_CONFIG_B Disable_NCTS\t\t\t\t%lu\n", BIT(dword, 3)); dword = INREG(AUD_CONFIG_C); printf("AUD_CONFIG_C N_index_value\t\t\t\t[0x%lx] %s\n", BIT(dword, 29), n_index_value[BIT(dword, 29)]); printf("AUD_CONFIG_C N_programming_enable\t\t\t%lu\n", BIT(dword, 28)); printf("AUD_CONFIG_C Upper_N_value\t\t\t\t0x%02lx\n", BITS(dword, 27, 20)); printf("AUD_CONFIG_C Lower_N_value\t\t\t\t0x%03lx\n", BITS(dword, 15, 4)); printf("AUD_CONFIG_C Pixel_Clock_HDMI\t\t\t\t[0x%lx] %s\n", BITS(dword, 19, 16), OPNAME(pixel_clock, BITS(dword, 19, 16))); printf("AUD_CONFIG_C Disable_NCTS\t\t\t\t%lu\n", BIT(dword, 3)); dword = INREG(AUD_CTS_ENABLE_A); printf("AUD_CTS_ENABLE_A Enable_CTS_or_M_programming\t\t%lu\n", BIT(dword, 20)); printf("AUD_CTS_ENABLE_A CTS_M value Index\t\t\t%s\n", BIT(dword, 21) ? "CTS" : "M"); printf("AUD_CTS_ENABLE_A CTS_programming\t\t\t%#lx\n", BITS(dword, 19, 0)); dword = INREG(AUD_CTS_ENABLE_B); printf("AUD_CTS_ENABLE_B Enable_CTS_or_M_programming\t\t%lu\n", BIT(dword, 20)); printf("AUD_CTS_ENABLE_B CTS_M value Index\t\t\t%s\n", BIT(dword, 21) ? "CTS" : "M"); printf("AUD_CTS_ENABLE_B CTS_programming\t\t\t%#lx\n", BITS(dword, 19, 0)); dword = INREG(AUD_CTS_ENABLE_C); printf("AUD_CTS_ENABLE_C Enable_CTS_or_M_programming\t\t%lu\n", BIT(dword, 20)); printf("AUD_CTS_ENABLE_C CTS_M value Index\t\t\t%s\n", BIT(dword, 21) ? "CTS" : "M"); printf("AUD_CTS_ENABLE_C CTS_programming\t\t\t%#lx\n", BITS(dword, 19, 0)); dword = INREG(AUD_MISC_CTRL_A); printf("AUD_MISC_CTRL_A Sample_Fabrication_EN_bit\t\t%lu\n", BIT(dword, 2)); printf("AUD_MISC_CTRL_A Sample_present_Disable\t\t\t%lu\n", BIT(dword, 8)); printf("AUD_MISC_CTRL_A Output_Delay\t\t\t\t%lu\n", BITS(dword, 7, 4)); printf("AUD_MISC_CTRL_A Pro_Allowed\t\t\t\t%lu\n", BIT(dword, 1)); dword = INREG(AUD_MISC_CTRL_B); printf("AUD_MISC_CTRL_B Sample_Fabrication_EN_bit\t\t%lu\n", BIT(dword, 2)); printf("AUD_MISC_CTRL_B Sample_present_Disable\t\t\t%lu\n", BIT(dword, 8)); printf("AUD_MISC_CTRL_B Output_Delay\t\t\t\t%lu\n", BITS(dword, 7, 4)); printf("AUD_MISC_CTRL_B Pro_Allowed\t\t\t\t%lu\n", BIT(dword, 1)); dword = INREG(AUD_MISC_CTRL_C); printf("AUD_MISC_CTRL_C Sample_Fabrication_EN_bit\t\t%lu\n", BIT(dword, 2)); printf("AUD_MISC_CTRL_C Sample_present_Disable\t\t\t%lu\n", BIT(dword, 8)); printf("AUD_MISC_CTRL_C Output_Delay\t\t\t\t%lu\n", BITS(dword, 7, 4)); printf("AUD_MISC_CTRL_C Pro_Allowed\t\t\t\t%lu\n", BIT(dword, 1)); dword = INREG(AUD_PWRST); printf("AUD_PWRST Func_Grp_Dev_PwrSt_Curr \t%s\n", power_state[BITS(dword, 27, 26)]); printf("AUD_PWRST Func_Grp_Dev_PwrSt_Set \t%s\n", power_state[BITS(dword, 25, 24)]); printf("AUD_PWRST ConvertorA_Widget_Power_State_Current \t%s\n", power_state[BITS(dword, 15, 14)]); printf("AUD_PWRST ConvertorA_Widget_Power_State_Requsted \t%s\n", power_state[BITS(dword, 13, 12)]); printf("AUD_PWRST ConvertorB_Widget_Power_State_Current \t%s\n", power_state[BITS(dword, 19, 18)]); printf("AUD_PWRST ConvertorB_Widget_Power_State_Requested \t%s\n", power_state[BITS(dword, 17, 16)]); printf("AUD_PWRST ConvC_Widget_PwrSt_Curr \t%s\n", power_state[BITS(dword, 23, 22)]); printf("AUD_PWRST ConvC_Widget_PwrSt_Req \t%s\n", power_state[BITS(dword, 21, 20)]); printf("AUD_PWRST PinB_Widget_Power_State_Current \t%s\n", power_state[BITS(dword, 3, 2)]); printf("AUD_PWRST PinB_Widget_Power_State_Set \t%s\n", power_state[BITS(dword, 1, 0)]); printf("AUD_PWRST PinC_Widget_Power_State_Current \t%s\n", power_state[BITS(dword, 7, 6)]); printf("AUD_PWRST PinC_Widget_Power_State_Set \t%s\n", power_state[BITS(dword, 5, 4)]); printf("AUD_PWRST PinD_Widget_Power_State_Current \t%s\n", power_state[BITS(dword, 11, 10)]); printf("AUD_PWRST PinD_Widget_Power_State_Set \t%s\n", power_state[BITS(dword, 9, 8)]); dword = INREG(AUD_PORT_EN_HD_CFG); printf("AUD_PORT_EN_HD_CFG Convertor_A_Digen\t\t\t%lu\n", BIT(dword, 0)); printf("AUD_PORT_EN_HD_CFG Convertor_B_Digen\t\t\t%lu\n", BIT(dword, 1)); printf("AUD_PORT_EN_HD_CFG Convertor_C_Digen\t\t\t%lu\n", BIT(dword, 2)); printf("AUD_PORT_EN_HD_CFG ConvertorA_Stream_ID\t\t%lu\n", BITS(dword, 7, 4)); printf("AUD_PORT_EN_HD_CFG ConvertorB_Stream_ID\t\t%lu\n", BITS(dword, 11, 8)); printf("AUD_PORT_EN_HD_CFG ConvertorC_Stream_ID\t\t%lu\n", BITS(dword, 15, 12)); printf("AUD_PORT_EN_HD_CFG Port_B_Out_Enable\t\t\t%lu\n", BIT(dword, 16)); printf("AUD_PORT_EN_HD_CFG Port_C_Out_Enable\t\t\t%lu\n", BIT(dword, 17)); printf("AUD_PORT_EN_HD_CFG Port_D_Out_Enable\t\t\t%lu\n", BIT(dword, 18)); printf("AUD_PORT_EN_HD_CFG Port_B_Amp_Mute_Status\t\t%lu\n", BIT(dword, 20)); printf("AUD_PORT_EN_HD_CFG Port_C_Amp_Mute_Status\t\t%lu\n", BIT(dword, 21)); printf("AUD_PORT_EN_HD_CFG Port_D_Amp_Mute_Status\t\t%lu\n", BIT(dword, 22)); dword = INREG(AUD_OUT_DIG_CNVT_A); printf("AUD_OUT_DIG_CNVT_A V\t\t\t\t\t%lu\n", BIT(dword, 1)); printf("AUD_OUT_DIG_CNVT_A VCFG\t\t\t\t%lu\n", BIT(dword, 2)); printf("AUD_OUT_DIG_CNVT_A PRE\t\t\t\t\t%lu\n", BIT(dword, 3)); printf("AUD_OUT_DIG_CNVT_A Copy\t\t\t\t%lu\n", BIT(dword, 4)); printf("AUD_OUT_DIG_CNVT_A NonAudio\t\t\t\t%lu\n", BIT(dword, 5)); printf("AUD_OUT_DIG_CNVT_A PRO\t\t\t\t\t%lu\n", BIT(dword, 6)); printf("AUD_OUT_DIG_CNVT_A Level\t\t\t\t%lu\n", BIT(dword, 7)); printf("AUD_OUT_DIG_CNVT_A Category_Code\t\t\t%lu\n", BITS(dword, 14, 8)); printf("AUD_OUT_DIG_CNVT_A Lowest_Channel_Number\t\t%lu\n", BITS(dword, 19, 16)); printf("AUD_OUT_DIG_CNVT_A Stream_ID\t\t\t\t%lu\n", BITS(dword, 23, 20)); dword = INREG(AUD_OUT_DIG_CNVT_B); printf("AUD_OUT_DIG_CNVT_B V\t\t\t\t\t%lu\n", BIT(dword, 1)); printf("AUD_OUT_DIG_CNVT_B VCFG\t\t\t\t%lu\n", BIT(dword, 2)); printf("AUD_OUT_DIG_CNVT_B PRE\t\t\t\t\t%lu\n", BIT(dword, 3)); printf("AUD_OUT_DIG_CNVT_B Copy\t\t\t\t%lu\n", BIT(dword, 4)); printf("AUD_OUT_DIG_CNVT_B NonAudio\t\t\t\t%lu\n", BIT(dword, 5)); printf("AUD_OUT_DIG_CNVT_B PRO\t\t\t\t\t%lu\n", BIT(dword, 6)); printf("AUD_OUT_DIG_CNVT_B Level\t\t\t\t%lu\n", BIT(dword, 7)); printf("AUD_OUT_DIG_CNVT_B Category_Code\t\t\t%lu\n", BITS(dword, 14, 8)); printf("AUD_OUT_DIG_CNVT_B Lowest_Channel_Number\t\t%lu\n", BITS(dword, 19, 16)); printf("AUD_OUT_DIG_CNVT_B Stream_ID\t\t\t\t%lu\n", BITS(dword, 23, 20)); dword = INREG(AUD_OUT_DIG_CNVT_C); printf("AUD_OUT_DIG_CNVT_C V\t\t\t\t\t%lu\n", BIT(dword, 1)); printf("AUD_OUT_DIG_CNVT_C VCFG\t\t\t\t%lu\n", BIT(dword, 2)); printf("AUD_OUT_DIG_CNVT_C PRE\t\t\t\t\t%lu\n", BIT(dword, 3)); printf("AUD_OUT_DIG_CNVT_C Copy\t\t\t\t%lu\n", BIT(dword, 4)); printf("AUD_OUT_DIG_CNVT_C NonAudio\t\t\t\t%lu\n", BIT(dword, 5)); printf("AUD_OUT_DIG_CNVT_C PRO\t\t\t\t\t%lu\n", BIT(dword, 6)); printf("AUD_OUT_DIG_CNVT_C Level\t\t\t\t%lu\n", BIT(dword, 7)); printf("AUD_OUT_DIG_CNVT_C Category_Code\t\t\t%lu\n", BITS(dword, 14, 8)); printf("AUD_OUT_DIG_CNVT_C Lowest_Channel_Number\t\t%lu\n", BITS(dword, 19, 16)); printf("AUD_OUT_DIG_CNVT_C Stream_ID\t\t\t\t%lu\n", BITS(dword, 23, 20)); printf("AUD_OUT_CH_STR Converter_Channel_MAP PORTB PORTC PORTD\n"); for (i = 0; i < 8; i++) { OUTREG(AUD_OUT_CH_STR, i | (i << 8) | (i << 16)); dword = INREG(AUD_OUT_CH_STR); printf("\t\t\t\t%lu\t%lu\t%lu\t%lu\n", 1 + BITS(dword, 3, 0), 1 + BITS(dword, 7, 4), 1 + BITS(dword, 15, 12), 1 + BITS(dword, 23, 20)); } dword = INREG(AUD_OUT_STR_DESC_A); printf("AUD_OUT_STR_DESC_A HBR_enable\t\t\t\t%lu\n", BITS(dword, 28, 27)); printf("AUD_OUT_STR_DESC_A Convertor_Channel_Count\t\t%lu\n", BITS(dword, 20, 16) + 1); printf("AUD_OUT_STR_DESC_A Bits_per_Sample\t\t\t[%#lx] %s\n", BITS(dword, 6, 4), OPNAME(bits_per_sample, BITS(dword, 6, 4))); printf("AUD_OUT_STR_DESC_A Number_of_Channels_in_a_Stream\t%lu\n", 1 + BITS(dword, 3, 0)); dword = INREG(AUD_OUT_STR_DESC_B); printf("AUD_OUT_STR_DESC_B HBR_enable\t\t\t\t%lu\n", BITS(dword, 28, 27)); printf("AUD_OUT_STR_DESC_B Convertor_Channel_Count\t\t%lu\n", BITS(dword, 20, 16) + 1); printf("AUD_OUT_STR_DESC_B Bits_per_Sample\t\t\t[%#lx] %s\n", BITS(dword, 6, 4), OPNAME(bits_per_sample, BITS(dword, 6, 4))); printf("AUD_OUT_STR_DESC_B Number_of_Channels_in_a_Stream\t%lu\n", 1 + BITS(dword, 3, 0)); dword = INREG(AUD_OUT_STR_DESC_C); printf("AUD_OUT_STR_DESC_C HBR_enable\t\t\t\t%lu\n", BITS(dword, 28, 27)); printf("AUD_OUT_STR_DESC_C Convertor_Channel_Count\t\t%lu\n", BITS(dword, 20, 16) + 1); printf("AUD_OUT_STR_DESC_C Bits_per_Sample\t\t\t[%#lx] %s\n", BITS(dword, 6, 4), OPNAME(bits_per_sample, BITS(dword, 6, 4))); printf("AUD_OUT_STR_DESC_C Number_of_Channels_in_a_Stream\t%lu\n", 1 + BITS(dword, 3, 0)); dword = INREG(AUD_PINW_CONNLNG_SEL); printf("AUD_PINW_CONNLNG_SEL Connection_select_Control_B\t%#lx\n", BITS(dword, 7, 0)); printf("AUD_PINW_CONNLNG_SEL Connection_select_Control_C\t%#lx\n", BITS(dword, 15, 8)); printf("AUD_PINW_CONNLNG_SEL Connection_select_Control_D\t%#lx\n", BITS(dword, 23, 16)); dword = INREG(AUD_CNTL_ST_A); printf("AUD_CNTL_ST_A DIP_Port_Select\t\t\t\t[%#lx] %s\n", BITS(dword, 30, 29), dip_port[BITS(dword, 30, 29)]); printf("AUD_CNTL_ST_A DIP_type_enable_status Audio DIP\t\t%lu\n", BIT(dword, 21)); printf("AUD_CNTL_ST_A DIP_type_enable_status ACP DIP\t\t%lu\n", BIT(dword, 22)); printf("AUD_CNTL_ST_A DIP_type_enable_status Generic 2 DIP\t%lu\n", BIT(dword, 23)); printf("AUD_CNTL_ST_A DIP_transmission_frequency\t\t[0x%lx] %s\n", BITS(dword, 17, 16), dip_trans[BITS(dword, 17, 16)]); printf("AUD_CNTL_ST_A ELD_ACK\t\t\t\t\t%lu\n", BIT(dword, 4)); printf("AUD_CNTL_ST_A ELD_buffer_size\t\t\t\t%lu\n", BITS(dword, 14, 10)); dword = INREG(AUD_CNTL_ST_B); printf("AUD_CNTL_ST_B DIP_Port_Select\t\t\t\t[%#lx] %s\n", BITS(dword, 30, 29), dip_port[BITS(dword, 30, 29)]); printf("AUD_CNTL_ST_B DIP_type_enable_status Audio DIP\t\t%lu\n", BIT(dword, 21)); printf("AUD_CNTL_ST_B DIP_type_enable_status ACP DIP\t\t%lu\n", BIT(dword, 22)); printf("AUD_CNTL_ST_B DIP_type_enable_status Generic 2 DIP\t%lu\n", BIT(dword, 23)); printf("AUD_CNTL_ST_B DIP_transmission_frequency\t\t[0x%lx] %s\n", BITS(dword, 17, 16), dip_trans[BITS(dword, 17, 16)]); printf("AUD_CNTL_ST_B ELD_ACK\t\t\t\t\t%lu\n", BIT(dword, 4)); printf("AUD_CNTL_ST_B ELD_buffer_size\t\t\t\t%lu\n", BITS(dword, 14, 10)); dword = INREG(AUD_CNTL_ST_C); printf("AUD_CNTL_ST_C DIP_Port_Select\t\t\t\t[%#lx] %s\n", BITS(dword, 30, 29), dip_port[BITS(dword, 30, 29)]); printf("AUD_CNTL_ST_C DIP_type_enable_status Audio DIP\t\t%lu\n", BIT(dword, 21)); printf("AUD_CNTL_ST_C DIP_type_enable_status ACP DIP\t\t%lu\n", BIT(dword, 22)); printf("AUD_CNTL_ST_C DIP_type_enable_status Generic 2 DIP\t%lu\n", BIT(dword, 23)); printf("AUD_CNTL_ST_C DIP_transmission_frequency\t\t[0x%lx] %s\n", BITS(dword, 17, 16), dip_trans[BITS(dword, 17, 16)]); printf("AUD_CNTL_ST_C ELD_ACK\t\t\t\t\t%lu\n", BIT(dword, 4)); printf("AUD_CNTL_ST_C ELD_buffer_size\t\t\t\t%lu\n", BITS(dword, 14, 10)); dword = INREG(AUD_CNTRL_ST2); printf("AUD_CNTRL_ST2 CP_ReadyB\t\t\t\t%lu\n", BIT(dword, 1)); printf("AUD_CNTRL_ST2 ELD_validB\t\t\t\t%lu\n", BIT(dword, 0)); printf("AUD_CNTRL_ST2 CP_ReadyC\t\t\t\t%lu\n", BIT(dword, 5)); printf("AUD_CNTRL_ST2 ELD_validC\t\t\t\t%lu\n", BIT(dword, 4)); printf("AUD_CNTRL_ST2 CP_ReadyD\t\t\t\t%lu\n", BIT(dword, 9)); printf("AUD_CNTRL_ST2 ELD_validD\t\t\t\t%lu\n", BIT(dword, 8)); dword = INREG(AUD_CNTRL_ST3); printf("AUD_CNTRL_ST3 TransA_DPT_Audio_Output_En\t\t%lu\n", BIT(dword, 3)); printf("AUD_CNTRL_ST3 TransA_to_Port_Sel\t\t\t[%#lx] %s\n", BITS(dword, 2, 0), trans_to_port_sel[BITS(dword, 2, 0)]); printf("AUD_CNTRL_ST3 TransB_DPT_Audio_Output_En\t\t%lu\n", BIT(dword, 7)); printf("AUD_CNTRL_ST3 TransB_to_Port_Sel\t\t\t[%#lx] %s\n", BITS(dword, 6, 4), trans_to_port_sel[BITS(dword, 6, 4)]); printf("AUD_CNTRL_ST3 TransC_DPT_Audio_Output_En\t\t%lu\n", BIT(dword, 11)); printf("AUD_CNTRL_ST3 TransC_to_Port_Sel\t\t\t[%#lx] %s\n", BITS(dword, 10, 8), trans_to_port_sel[BITS(dword, 10, 8)]); dword = INREG(AUD_HDMIW_STATUS); printf("AUD_HDMIW_STATUS Conv_A_CDCLK/DOTCLK_FIFO_Underrun\t%lu\n", BIT(dword, 27)); printf("AUD_HDMIW_STATUS Conv_A_CDCLK/DOTCLK_FIFO_Overrun\t%lu\n", BIT(dword, 26)); printf("AUD_HDMIW_STATUS Conv_B_CDCLK/DOTCLK_FIFO_Underrun\t%lu\n", BIT(dword, 29)); printf("AUD_HDMIW_STATUS Conv_B_CDCLK/DOTCLK_FIFO_Overrun\t%lu\n", BIT(dword, 28)); printf("AUD_HDMIW_STATUS Conv_C_CDCLK/DOTCLK_FIFO_Underrun\t%lu\n", BIT(dword, 31)); printf("AUD_HDMIW_STATUS Conv_C_CDCLK/DOTCLK_FIFO_Overrun\t%lu\n", BIT(dword, 30)); printf("AUD_HDMIW_STATUS BCLK/CDCLK_FIFO_Overrun\t\t%lu\n", BIT(dword, 25)); printf("AUD_HDMIW_STATUS Function_Reset\t\t\t%lu\n", BIT(dword, 24)); printf("AUD_HDMIW_HDMIEDID_A HDMI ELD:\n\t"); dword = INREG(AUD_CNTL_ST_A); dword &= ~BITMASK(9, 5); OUTREG(AUD_CNTL_ST_A, dword); for (i = 0; i < BITS(dword, 14, 10) / 4; i++) printf("%08x ", htonl(INREG(AUD_HDMIW_HDMIEDID_A))); printf("\n"); printf("AUD_HDMIW_HDMIEDID_B HDMI ELD:\n\t"); dword = INREG(AUD_CNTL_ST_B); dword &= ~BITMASK(9, 5); OUTREG(AUD_CNTL_ST_B, dword); for (i = 0; i < BITS(dword, 14, 10) / 4; i++) printf("%08x ", htonl(INREG(AUD_HDMIW_HDMIEDID_B))); printf("\n"); printf("AUD_HDMIW_HDMIEDID_C HDMI ELD:\n\t"); dword = INREG(AUD_CNTL_ST_C); dword &= ~BITMASK(9, 5); OUTREG(AUD_CNTL_ST_C, dword); for (i = 0; i < BITS(dword, 14, 10) / 4; i++) printf("%08x ", htonl(INREG(AUD_HDMIW_HDMIEDID_C))); printf("\n"); printf("AUD_HDMIW_INFOFR_A HDMI audio Infoframe:\n\t"); dword = INREG(AUD_CNTL_ST_A); dword &= ~BITMASK(20, 18); dword &= ~BITMASK(3, 0); OUTREG(AUD_CNTL_ST_A, dword); for (i = 0; i < 8; i++) printf("%08x ", htonl(INREG(AUD_HDMIW_INFOFR_A))); printf("\n"); printf("AUD_HDMIW_INFOFR_B HDMI audio Infoframe:\n\t"); dword = INREG(AUD_CNTL_ST_B); dword &= ~BITMASK(20, 18); dword &= ~BITMASK(3, 0); OUTREG(AUD_CNTL_ST_B, dword); for (i = 0; i < 8; i++) printf("%08x ", htonl(INREG(AUD_HDMIW_INFOFR_B))); printf("\n"); printf("AUD_HDMIW_INFOFR_C HDMI audio Infoframe:\n\t"); dword = INREG(AUD_CNTL_ST_C); dword &= ~BITMASK(20, 18); dword &= ~BITMASK(3, 0); OUTREG(AUD_CNTL_ST_C, dword); for (i = 0; i < 8; i++) printf("%08x ", htonl(INREG(AUD_HDMIW_INFOFR_C))); printf("\n"); } /* Audio config registers of Ironlake */ #undef AUD_CONFIG_A #undef AUD_CONFIG_B #undef AUD_MISC_CTRL_A #undef AUD_MISC_CTRL_B #undef AUD_VID_DID #undef AUD_RID #undef AUD_CTS_ENABLE_A #undef AUD_CTS_ENABLE_B #undef AUD_PWRST #undef AUD_HDMIW_HDMIEDID_A #undef AUD_HDMIW_HDMIEDID_B #undef AUD_HDMIW_INFOFR_A #undef AUD_HDMIW_INFOFR_B #undef AUD_PORT_EN_HD_CFG #undef AUD_OUT_DIG_CNVT_A #undef AUD_OUT_DIG_CNVT_B #undef AUD_OUT_STR_DESC_A #undef AUD_OUT_STR_DESC_B #undef AUD_OUT_CH_STR #undef AUD_PINW_CONNLNG_LIST #undef AUD_PINW_CONNLNG_SEL #undef AUD_CNTL_ST_A #undef AUD_CNTL_ST_B #undef AUD_CNTL_ST2 #undef AUD_HDMIW_STATUS #define PIPE_OFS 0x100 #define AUD_CONFIG_A 0x0 #define AUD_CONFIG_B (AUD_CONFIG_A + PIPE_OFS) #define AUD_MISC_CTRL_A 0x010 #define AUD_MISC_CTRL_B (AUD_MISC_CTRL_A + PIPE_OFS) #define AUD_VID_DID 0x020 #define AUD_RID 0x024 #define AUD_CTS_ENABLE_A 0x028 #define AUD_CTS_ENABLE_B (AUD_CTS_ENABLE_A + PIPE_OFS) #define AUD_PWRST 0x04C #define AUD_HDMIW_HDMIEDID_A 0x050 #define AUD_HDMIW_HDMIEDID_B (AUD_HDMIW_HDMIEDID_A + PIPE_OFS) #define AUD_HDMIW_INFOFR_A 0x054 #define AUD_HDMIW_INFOFR_B (AUD_HDMIW_INFOFR_A + PIPE_OFS) #define AUD_PORT_EN_HD_CFG 0x07c #define AUD_OUT_DIG_CNVT_A 0x080 #define AUD_OUT_DIG_CNVT_B (AUD_OUT_DIG_CNVT_A + PIPE_OFS) #define AUD_OUT_STR_DESC_A 0x084 #define AUD_OUT_STR_DESC_B (AUD_OUT_STR_DESC_A + PIPE_OFS) #define AUD_OUT_CH_STR 0x088 #define AUD_PINW_CONNLNG_LIST 0x0a8 #define AUD_PINW_CONNLNG_SEL 0x0aC #define AUD_CNTL_ST_A 0x0b4 #define AUD_CNTL_ST_B (AUD_CNTL_ST_A + PIPE_OFS) #define AUD_CNTL_ST2 0x0c0 #define AUD_HDMIW_STATUS 0x0d4 #define AUD_FREQ_CNTRL 0x900 /* Audio config registers of Haswell+ */ #define AUD_TCA_CONFIG AUD_CONFIG_A #define AUD_TCB_CONFIG (AUD_TCA_CONFIG + PIPE_OFS) #define AUD_TCC_CONFIG (AUD_TCA_CONFIG + PIPE_OFS * 2) #define AUD_C1_MISC_CTRL AUD_MISC_CTRL_A #define AUD_C2_MISC_CTRL (AUD_MISC_CTRL_A + PIPE_OFS) #define AUD_C3_MISC_CTRL (AUD_MISC_CTRL_A + PIPE_OFS * 2) #define AUD_TCA_M_CTS_ENABLE AUD_CTS_ENABLE_A #define AUD_TCB_M_CTS_ENABLE (AUD_TCA_M_CTS_ENABLE + PIPE_OFS) #define AUD_TCC_M_CTS_ENABLE (AUD_TCA_M_CTS_ENABLE + PIPE_OFS * 2) #define AUD_TCA_EDID_DATA AUD_HDMIW_HDMIEDID_A #define AUD_TCB_EDID_DATA (AUD_TCA_EDID_DATA + PIPE_OFS) #define AUD_TCC_EDID_DATA (AUD_TCA_EDID_DATA + PIPE_OFS * 2) #define AUD_TCA_INFOFR AUD_HDMIW_INFOFR_A #define AUD_TCB_INFOFR (AUD_TCA_INFOFR + PIPE_OFS) #define AUD_TCC_INFOFR (AUD_TCA_INFOFR + PIPE_OFS * 2) #define AUD_PIPE_CONV_CFG AUD_PORT_EN_HD_CFG #define AUD_C1_DIG_CNVT AUD_OUT_DIG_CNVT_A #define AUD_C2_DIG_CNVT (AUD_C1_DIG_CNVT + PIPE_OFS) #define AUD_C3_DIG_CNVT (AUD_C1_DIG_CNVT + PIPE_OFS * 2) #define AUD_C1_STR_DESC AUD_OUT_STR_DESC_A #define AUD_C2_STR_DESC (AUD_C1_STR_DESC + PIPE_OFS) #define AUD_C3_STR_DESC (AUD_C1_STR_DESC + PIPE_OFS * 2) #define AUD_OUT_CHAN_MAP AUD_OUT_CH_STR #define AUD_TCA_PIN_PIPE_CONN_ENTRY_LNGTH AUD_PINW_CONNLNG_LIST #define AUD_TCB_PIN_PIPE_CONN_ENTRY_LNGTH (AUD_TCA_PIN_PIPE_CONN_ENTRY_LNGTH + PIPE_OFS) #define AUD_TCC_PIN_PIPE_CONN_ENTRY_LNGTH (AUD_TCA_PIN_PIPE_CONN_ENTRY_LNGTH + PIPE_OFS * 2) #define AUD_PIPE_CONN_SEL_CTRL AUD_PINW_CONNLNG_SEL #define AUD_TCA_DIP_ELD_CTRL_ST AUD_CNTL_ST_A #define AUD_TCB_DIP_ELD_CTRL_ST (AUD_TCA_DIP_ELD_CTRL_ST + PIPE_OFS) #define AUD_TCC_DIP_ELD_CTRL_ST (AUD_TCA_DIP_ELD_CTRL_ST + PIPE_OFS * 2) #define AUD_PIN_ELD_CP_VLD AUD_CNTL_ST2 #define AUD_HDMI_FIFO_STATUS AUD_HDMIW_STATUS #define AUD_ICOI 0xf00 #define AUD_IRII 0xf04 #define AUD_ICS 0xf08 #define AUD_CHICKENBIT_REG 0xf10 #define AUD_DP_DIP_STATUS 0xf20 #define AUD_TCA_M_CTS 0xf44 #define AUD_TCB_M_CTS 0xf54 #define AUD_TCC_M_CTS 0xf64 #define AUD_HDA_DMA_REG 0xe00 #define AUD_HDA_LPIB0_REG 0xe04 #define AUD_HDA_LPIB1_REG 0xe08 #define AUD_HDA_LPIB2_REG 0xe0c #define AUD_HDA_EXTRA_REG 0xe10 #define AUD_FPGA_CRC_CTL_A 0xf14 #define AUD_FPGA_CRC_CTL_B 0xf24 #define AUD_FPGA_CRC_CTL_C 0xf34 #define AUD_FPGA_CRC_RESULT_A 0xf18 #define AUD_FPGA_CRC_RESULT_B 0xf28 #define AUD_FPGA_CRC_RESULT_C 0xf38 #define AUD_DFT_MVAL_REG 0xe20 #define AUD_DFT_NVAL_REG 0xe24 #define AUD_DFT_LOAD_REG 0xe28 /* Common functions to dump audio registers */ #define MAX_PREFIX_SIZE 128 static void dump_aud_config(int index) { uint32_t dword; char prefix[MAX_PREFIX_SIZE]; if (!IS_HASWELL_PLUS(devid)) { dword = INREG(aud_reg_base + AUD_CONFIG_A + (index - PIPE_A) * 0x100); sprintf(prefix, "AUD_CONFIG_%c ", 'A' + index - PIPE_A); } else { dword = INREG(aud_reg_base + AUD_TCA_CONFIG + (index - TRANSCODER_A) * 0x100); sprintf(prefix, "AUD_TC%c_CONFIG", 'A' + index - TRANSCODER_A); } printf("%s Disable_NCTS\t\t\t\t%lu\n", prefix, BIT(dword, 3)); printf("%s Lower_N_value\t\t\t\t0x%03lx\n", prefix, BITS(dword, 15, 4)); printf("%s Pixel_Clock_HDMI\t\t\t[0x%lx] %s\n", prefix, BITS(dword, 19, 16), OPNAME(pixel_clock, BITS(dword, 19, 16))); printf("%s Upper_N_value\t\t\t\t0x%02lx\n", prefix, BITS(dword, 27, 20)); printf("%s N_programming_enable\t\t\t%lu\n", prefix, BIT(dword, 28)); printf("%s N_index_value\t\t\t\t[0x%lx] %s\n", prefix, BIT(dword, 29), OPNAME(n_index_value, BIT(dword, 29))); } static void dump_aud_misc_control(int index) { uint32_t dword; char prefix[MAX_PREFIX_SIZE]; if (!IS_HASWELL_PLUS(devid)) { dword = INREG(aud_reg_base + AUD_MISC_CTRL_A + (index - PIPE_A) * 0x100); sprintf(prefix, "AUD_MISC_CTRL_%c ", 'A' + index - PIPE_A); } else { dword = INREG(aud_reg_base + AUD_C1_MISC_CTRL + (index - CONVERTER_1) * 0x100); sprintf(prefix, "AUD_C%c_MISC_CTRL", '1' + index - CONVERTER_1); } printf("%s Pro_Allowed\t\t\t\t%lu\n", prefix, BIT(dword, 1)); printf("%s Sample_Fabrication_EN_bit\t\t%lu\n", prefix, BIT(dword, 2)); printf("%s Output_Delay\t\t\t\t%lu\n", prefix, BITS(dword, 7, 4)); printf("%s Sample_present_Disable\t\t%lu\n", prefix, BIT(dword, 8)); } static void dump_aud_vendor_device_id(void) { uint32_t dword; dword = INREG(aud_reg_base + AUD_VID_DID); printf("AUD_VID_DID device id\t\t\t\t\t0x%lx\n", BITS(dword, 15, 0)); printf("AUD_VID_DID vendor id\t\t\t\t\t0x%lx\n", BITS(dword, 31, 16)); } static void dump_aud_revision_id(void) { uint32_t dword; dword = INREG(aud_reg_base + AUD_RID); printf("AUD_RID Stepping_Id\t\t\t\t\t0x%lx\n", BITS(dword, 7, 0)); printf("AUD_RID Revision_Id\t\t\t\t\t0x%lx\n", BITS(dword, 15, 8)); printf("AUD_RID Minor_Revision\t\t\t\t\t0x%lx\n", BITS(dword, 19, 16)); printf("AUD_RID Major_Revision\t\t\t\t\t0x%lx\n", BITS(dword, 23, 20)); } static void dump_aud_m_cts_enable(int index) { uint32_t dword; char prefix[MAX_PREFIX_SIZE]; if (!IS_HASWELL_PLUS(devid)) { dword = INREG(aud_reg_base + AUD_CTS_ENABLE_A + (index - PIPE_A) * 0x100); sprintf(prefix, "AUD_CTS_ENABLE_%c ", 'A' + index - PIPE_A); } else { dword = INREG(aud_reg_base + AUD_TCA_M_CTS_ENABLE + (index - TRANSCODER_A) * 0x100); sprintf(prefix, "AUD_TC%c_M_CTS_ENABLE", 'A' + index - TRANSCODER_A); } printf("%s CTS_programming\t\t\t%#lx\n", prefix, BITS(dword, 19, 0)); printf("%s Enable_CTS_or_M_programming\t%lu\n", prefix, BIT(dword, 20)); printf("%s CTS_M value Index\t\t\t[0x%lx] %s\n",prefix, BIT(dword, 21), OPNAME(cts_m_value_index, BIT(dword, 21))); } static void dump_aud_power_state(void) { uint32_t dword; int num_pipes; dword = INREG(aud_reg_base + AUD_PWRST); printf("AUD_PWRST PinB_Widget_Power_State_Set \t%s\n", power_state[BITS(dword, 1, 0)]); printf("AUD_PWRST PinB_Widget_Power_State_Current \t%s\n", power_state[BITS(dword, 3, 2)]); printf("AUD_PWRST PinC_Widget_Power_State_Set \t%s\n", power_state[BITS(dword, 5, 4)]); printf("AUD_PWRST PinC_Widget_Power_State_Current \t%s\n", power_state[BITS(dword, 7, 6)]); printf("AUD_PWRST PinD_Widget_Power_State_Set \t%s\n", power_state[BITS(dword, 9, 8)]); printf("AUD_PWRST PinD_Widget_Power_State_Current \t%s\n", power_state[BITS(dword, 11, 10)]); if (!IS_HASWELL_PLUS(devid)) { printf("AUD_PWRST ConvertorA_Widget_Power_State_Requsted \t%s\n", power_state[BITS(dword, 13, 12)]); printf("AUD_PWRST ConvertorA_Widget_Power_State_Current \t%s\n", power_state[BITS(dword, 15, 14)]); printf("AUD_PWRST ConvertorB_Widget_Power_State_Requested \t%s\n", power_state[BITS(dword, 17, 16)]); printf("AUD_PWRST ConvertorB_Widget_Power_State_Current \t%s\n", power_state[BITS(dword, 19, 18)]); } else { printf("AUD_PWRST Convertor1_Widget_Power_State_Requsted \t%s\n", power_state[BITS(dword, 13, 12)]); printf("AUD_PWRST Convertor1_Widget_Power_State_Current \t%s\n", power_state[BITS(dword, 15, 14)]); printf("AUD_PWRST Convertor2_Widget_Power_State_Requested \t%s\n", power_state[BITS(dword, 17, 16)]); printf("AUD_PWRST Convertor2_Widget_Power_State_Current \t%s\n", power_state[BITS(dword, 19, 18)]); } num_pipes = get_num_pipes(); if (num_pipes == 2) { printf("AUD_PWRST Func_Grp_Dev_PwrSt_Set \t%s\n", power_state[BITS(dword, 21, 20)]); printf("AUD_PWRST Func_Grp_Dev_PwrSt_Curr \t%s\n", power_state[BITS(dword, 23, 22)]); } else { /* 3 pipes */ if (!IS_HASWELL_PLUS(devid)) { printf("AUD_PWRST ConvertorC_Widget_Power_State_Requested \t%s\n", power_state[BITS(dword, 21, 20)]); printf("AUD_PWRST ConvertorC_Widget_Power_State_Current \t%s\n", power_state[BITS(dword, 23, 22)]); } else { printf("AUD_PWRST Convertor3_Widget_Power_State_Requested \t%s\n", power_state[BITS(dword, 21, 20)]); printf("AUD_PWRST Convertor3_Widget_Power_State_Current \t%s\n", power_state[BITS(dword, 23, 22)]); } printf("AUD_PWRST Func_Grp_Dev_PwrSt_Set \t%s\n", power_state[BITS(dword, 25, 24)]); printf("AUD_PWRST Func_Grp_Dev_PwrSt_Curr \t%s\n", power_state[BITS(dword, 27, 26)]); } } static void dump_aud_edid_data(int index) { uint32_t dword; int i; int offset; int aud_ctrl_st, edid_data; if (IS_HASWELL_PLUS(devid)) { offset = (index - TRANSCODER_A) * 0x100; aud_ctrl_st = aud_reg_base + AUD_TCA_DIP_ELD_CTRL_ST + offset; edid_data = aud_reg_base + AUD_TCA_EDID_DATA + offset; printf("AUD_TC%c_EDID_DATA ELD:\n\t", 'A' + index - TRANSCODER_A); } else { offset = (index - PIPE_A) * 0x100; aud_ctrl_st = aud_reg_base + AUD_CNTL_ST_A + offset; edid_data = aud_reg_base + AUD_HDMIW_HDMIEDID_A + offset; printf("AUD_HDMIW_HDMIEDID_%c HDMI ELD:\n\t", 'A' + index - PIPE_A); } dword = INREG(aud_ctrl_st); dword &= ~BITMASK(9, 5); OUTREG(aud_ctrl_st, dword); for (i = 0; i < BITS(dword, 14, 10) / 4; i++) printf("%08x ", htonl(INREG(edid_data))); printf("\n"); } static void dump_aud_infoframe(int index) { uint32_t dword; int i; int offset; int aud_ctrl_st, info_frm; if (IS_HASWELL_PLUS(devid)) { offset = (index - TRANSCODER_A) * 0x100; aud_ctrl_st = aud_reg_base + AUD_TCA_DIP_ELD_CTRL_ST + offset; info_frm = aud_reg_base + AUD_TCA_INFOFR + offset; printf("AUD_TC%c_INFOFR audio Infoframe:\n\t", 'A' + index - TRANSCODER_A); } else { offset = (index - PIPE_A) * 0x100; aud_ctrl_st = aud_reg_base + AUD_CNTL_ST_A + offset; info_frm = aud_reg_base + AUD_HDMIW_INFOFR_A + offset; printf("AUD_HDMIW_INFOFR_%c HDMI audio Infoframe:\n\t", 'A' + index - PIPE_A); } dword = INREG(aud_ctrl_st); dword &= ~BITMASK(20, 18); dword &= ~BITMASK(3, 0); OUTREG(aud_ctrl_st, dword); for (i = 0; i < 8; i++) printf("%08x ", htonl(INREG(info_frm))); printf("\n"); } static void dump_aud_port_en_hd_cfg(void) { uint32_t dword; int num_pipes = get_num_pipes(); dword = INREG(aud_reg_base + AUD_PORT_EN_HD_CFG); if (num_pipes == 2) { printf("AUD_PORT_EN_HD_CFG Convertor_A_Digen\t\t\t%lu\n", BIT(dword, 0)); printf("AUD_PORT_EN_HD_CFG Convertor_B_Digen\t\t\t%lu\n", BIT(dword, 1)); printf("AUD_PORT_EN_HD_CFG Convertor_A_Stream_ID\t\t%lu\n", BITS(dword, 7, 4)); printf("AUD_PORT_EN_HD_CFG Convertor_B_Stream_ID\t\t%lu\n", BITS(dword, 11, 8)); printf("AUD_PORT_EN_HD_CFG Port_B_Out_Enable\t\t\t%lu\n", BIT(dword, 12)); printf("AUD_PORT_EN_HD_CFG Port_C_Out_Enable\t\t\t%lu\n", BIT(dword, 13)); printf("AUD_PORT_EN_HD_CFG Port_D_Out_Enable\t\t\t%lu\n", BIT(dword, 14)); printf("AUD_PORT_EN_HD_CFG Port_B_Amp_Mute_Status\t\t%lu\n", BIT(dword, 16)); printf("AUD_PORT_EN_HD_CFG Port_C_Amp_Mute_Status\t\t%lu\n", BIT(dword, 17)); printf("AUD_PORT_EN_HD_CFG Port_D_Amp_Mute_Status\t\t%lu\n", BIT(dword, 18)); } else { /* three pipes */ printf("AUD_PORT_EN_HD_CFG Convertor_A_Digen\t\t\t%lu\n", BIT(dword, 0)); printf("AUD_PORT_EN_HD_CFG Convertor_B_Digen\t\t\t%lu\n", BIT(dword, 1)); printf("AUD_PORT_EN_HD_CFG Convertor_C_Digen\t\t\t%lu\n", BIT(dword, 2)); printf("AUD_PORT_EN_HD_CFG Convertor_A_Stream_ID\t\t%lu\n", BITS(dword, 7, 4)); printf("AUD_PORT_EN_HD_CFG Convertor_B_Stream_ID\t\t%lu\n", BITS(dword, 11, 8)); printf("AUD_PORT_EN_HD_CFG Convertor_C_Stream_ID\t\t%lu\n", BITS(dword, 15, 12)); printf("AUD_PORT_EN_HD_CFG Port_B_Out_Enable\t\t\t%lu\n", BIT(dword, 16)); printf("AUD_PORT_EN_HD_CFG Port_C_Out_Enable\t\t\t%lu\n", BIT(dword, 17)); printf("AUD_PORT_EN_HD_CFG Port_D_Out_Enable\t\t\t%lu\n", BIT(dword, 18)); printf("AUD_PORT_EN_HD_CFG Port_B_Amp_Mute_Status\t\t%lu\n", BIT(dword, 20)); printf("AUD_PORT_EN_HD_CFG Port_C_Amp_Mute_Status\t\t%lu\n", BIT(dword, 21)); printf("AUD_PORT_EN_HD_CFG Port_D_Amp_Mute_Status\t\t%lu\n", BIT(dword, 22)); } } static void dump_aud_pipe_conv_cfg(void) { uint32_t dword; dword = INREG(aud_reg_base + AUD_PIPE_CONV_CFG); printf("AUD_PIPE_CONV_CFG Convertor_1_Digen\t\t\t%lu\n", BIT(dword, 0)); printf("AUD_PIPE_CONV_CFG Convertor_2_Digen\t\t\t%lu\n", BIT(dword, 1)); printf("AUD_PIPE_CONV_CFG Convertor_3_Digen\t\t\t%lu\n", BIT(dword, 2)); printf("AUD_PIPE_CONV_CFG Convertor_1_Stream_ID\t\t%lu\n", BITS(dword, 7, 4)); printf("AUD_PIPE_CONV_CFG Convertor_2_Stream_ID\t\t%lu\n", BITS(dword, 11, 8)); printf("AUD_PIPE_CONV_CFG Convertor_3_Stream_ID\t\t%lu\n", BITS(dword, 15, 12)); printf("AUD_PIPE_CONV_CFG Port_B_Out_Enable\t\t\t%lu\n", BIT(dword, 16)); printf("AUD_PIPE_CONV_CFG Port_C_Out_Enable\t\t\t%lu\n", BIT(dword, 17)); printf("AUD_PIPE_CONV_CFG Port_D_Out_Enable\t\t\t%lu\n", BIT(dword, 18)); printf("AUD_PIPE_CONV_CFG Port_B_Amp_Mute_Status\t\t%lu\n", BIT(dword, 20)); printf("AUD_PIPE_CONV_CFG Port_C_Amp_Mute_Status\t\t%lu\n", BIT(dword, 21)); printf("AUD_PIPE_CONV_CFG Port_D_Amp_Mute_Status\t\t%lu\n", BIT(dword, 22)); } static void dump_aud_dig_cnvt(int index) { uint32_t dword; char prefix[MAX_PREFIX_SIZE]; if (!IS_HASWELL_PLUS(devid)) { dword = INREG(aud_reg_base + AUD_OUT_DIG_CNVT_A + (index - PIPE_A) * 0x100); sprintf(prefix, "AUD_OUT_DIG_CNVT_%c", 'A' + index - PIPE_A); } else { dword = INREG(aud_reg_base + AUD_C1_DIG_CNVT + (index - CONVERTER_1) * 0x100); sprintf(prefix, "AUD_C%c_DIG_CNVT ", '1' + index - CONVERTER_1); } printf("%s V\t\t\t\t\t%lu\n", prefix, BIT(dword, 1)); printf("%s VCFG\t\t\t\t%lu\n", prefix, BIT(dword, 2)); printf("%s PRE\t\t\t\t\t%lu\n", prefix, BIT(dword, 3)); printf("%s Copy\t\t\t\t%lu\n", prefix, BIT(dword, 4)); printf("%s NonAudio\t\t\t\t%lu\n", prefix, BIT(dword, 5)); printf("%s PRO\t\t\t\t\t%lu\n", prefix, BIT(dword, 6)); printf("%s Level\t\t\t\t%lu\n", prefix, BIT(dword, 7)); printf("%s Category_Code\t\t\t%lu\n", prefix, BITS(dword, 14, 8)); printf("%s Lowest_Channel_Number\t\t%lu\n", prefix, BITS(dword, 19, 16)); printf("%s Stream_ID\t\t\t\t%lu\n", prefix, BITS(dword, 23, 20)); } static void dump_aud_str_desc(int index) { uint32_t dword; char prefix[MAX_PREFIX_SIZE]; uint32_t rate; if (!IS_HASWELL_PLUS(devid)) { dword = INREG(aud_reg_base + AUD_OUT_STR_DESC_A + (index - PIPE_A) * 0x100); sprintf(prefix, "AUD_OUT_STR_DESC_%c", 'A' + index - PIPE_A); } else { dword = INREG(aud_reg_base + AUD_C1_STR_DESC + (index - CONVERTER_1) * 0x100); sprintf(prefix, "AUD_C%c_STR_DESC ", '1' + index - CONVERTER_1); } printf("%s Number_of_Channels_in_a_Stream\t%lu\n", prefix, BITS(dword, 3, 0) + 1); printf("%s Bits_per_Sample\t\t\t[%#lx] %s\n", prefix, BITS(dword, 6, 4), OPNAME(bits_per_sample, BITS(dword, 6, 4))); printf("%s Sample_Base_Rate_Divisor\t\t[%#lx] %s\n", prefix, BITS(dword, 10, 8), OPNAME(sample_base_rate_divisor, BITS(dword, 10, 8))); printf("%s Sample_Base_Rate_Mult\t\t[%#lx] %s\n", prefix, BITS(dword, 13, 11), OPNAME(sample_base_rate_mult, BITS(dword, 13, 11))); printf("%s Sample_Base_Rate\t\t\t[%#lx] %s\t", prefix, BIT(dword, 14), OPNAME(sample_base_rate, BIT(dword, 14))); rate = (BIT(dword, 14) ? 44100 : 48000) * (BITS(dword, 13, 11) + 1) /(BITS(dword, 10, 8) + 1); printf("=> Sample Rate %d Hz\n", rate); printf("%s Convertor_Channel_Count\t\t%lu\n", prefix, BITS(dword, 20, 16) + 1); if (!IS_HASWELL_PLUS(devid)) printf("%s HBR_enable\t\t\t\t%lu\n", prefix, BITS(dword, 28, 27)); } #define dump_aud_out_ch_str dump_aud_out_chan_map static void dump_aud_out_chan_map(void) { uint32_t dword; int i; printf("AUD_OUT_CHAN_MAP Converter_Channel_MAP PORTB PORTC PORTD\n"); for (i = 0; i < 8; i++) { OUTREG(aud_reg_base + AUD_OUT_CHAN_MAP, i | (i << 8) | (i << 16)); dword = INREG(aud_reg_base + AUD_OUT_CHAN_MAP); printf("\t\t\t\t%lu\t%lu\t%lu\t%lu\n", 1 + BITS(dword, 3, 0), 1 + BITS(dword, 7, 4), 1 + BITS(dword, 15, 12), 1 + BITS(dword, 23, 20)); } } static void dump_aud_connect_list(void) { uint32_t dword; char prefix[MAX_PREFIX_SIZE]; dword = INREG(aud_reg_base + AUD_PINW_CONNLNG_LIST); sprintf(prefix, "AUD_PINW_CONNLNG_LIST"); printf("%s Connect_List_Length\t\t%lu\n", prefix, BITS(dword, 6, 0)); printf("%s Form \t\t\t\t[%#lx] %s\n", prefix, BIT(dword, 7), OPNAME(connect_list_form, BIT(dword, 7))); printf("%s Connect_List_Entry\t\t%lu, %lu\n", prefix, BITS(dword, 15, 8), BITS(dword, 23, 16)); } static void dump_aud_connect_select(void) { uint32_t dword; char prefix[MAX_PREFIX_SIZE]; if (IS_HASWELL_PLUS(devid)) { dword = INREG(aud_reg_base + AUD_PIPE_CONN_SEL_CTRL); sprintf(prefix, "AUD_PIPE_CONN_SEL_CTRL"); } else { dword = INREG(aud_reg_base + AUD_PINW_CONNLNG_SEL); sprintf(prefix, "AUD_PINW_CONNLNG_SEL "); } printf("%s Connection_select_Port_B\t%#lx\n", prefix, BITS(dword, 7, 0)); printf("%s Connection_select_Port_C\t%#lx\n", prefix, BITS(dword, 15, 8)); printf("%s Connection_select_Port_D\t%#lx\n", prefix, BITS(dword, 23, 16)); } static void dump_aud_ctrl_state(int index) { uint32_t dword; int offset; if (IS_HASWELL_PLUS(devid)) { offset = (index - TRANSCODER_A) * 0x100; dword = INREG(aud_reg_base + AUD_TCA_DIP_ELD_CTRL_ST + offset); printf("Audio DIP and ELD control state for Transcoder %c\n", 'A' + index - TRANSCODER_A); } else { offset = (index - PIPE_A) * 0x100; dword = INREG(aud_reg_base + AUD_CNTL_ST_A + offset); printf("Audio control state - Pipe %c\n", 'A' + index - PIPE_A); } printf("\tELD_ACK\t\t\t\t\t\t%lu\n", BIT(dword, 4)); printf("\tELD_buffer_size\t\t\t\t\t%lu\n", BITS(dword, 14, 10)); printf("\tDIP_transmission_frequency\t\t\t[0x%lx] %s\n", BITS(dword, 17, 16), dip_trans[BITS(dword, 17, 16)]); printf("\tDIP Buffer Index \t\t\t\t[0x%lx] %s\n", BITS(dword, 20, 18), dip_index[BITS(dword, 20, 18)]); printf("\tAudio DIP type enable status\t\t\t[0x%04lx] %s, %s, %s\n", BITS(dword, 24, 21), dip_type[BIT(dword, 21)], dip_gen1_state[BIT(dword, 22)], dip_gen2_state[BIT(dword, 23)]); printf("\tAudio DIP port select\t\t\t\t[0x%lx] %s\n", BITS(dword, 30, 29), dip_port[BITS(dword, 30, 29)]); printf("\n"); } static void dump_aud_ctrl_state2(void) { uint32_t dword; dword = INREG(aud_reg_base + AUD_CNTL_ST2); printf("AUD_CNTL_ST2 ELD_validB\t\t\t\t%lu\n", BIT(dword, 0)); printf("AUD_CNTL_ST2 CP_ReadyB\t\t\t\t\t%lu\n", BIT(dword, 1)); printf("AUD_CNTL_ST2 ELD_validC\t\t\t\t%lu\n", BIT(dword, 4)); printf("AUD_CNTL_ST2 CP_ReadyC\t\t\t\t\t%lu\n", BIT(dword, 5)); printf("AUD_CNTL_ST2 ELD_validD\t\t\t\t%lu\n", BIT(dword, 8)); printf("AUD_CNTL_ST2 CP_ReadyD\t\t\t\t\t%lu\n", BIT(dword, 9)); } /* for hsw+ */ static void dump_aud_eld_cp_vld(void) { uint32_t dword; dword = INREG(aud_reg_base + AUD_PIN_ELD_CP_VLD); printf("AUD_PIN_ELD_CP_VLD Transcoder_A ELD_valid\t\t%lu\n", BIT(dword, 0)); printf("AUD_PIN_ELD_CP_VLD Transcoder_A CP_Ready \t\t%lu\n", BIT(dword, 1)); printf("AUD_PIN_ELD_CP_VLD Transcoder_A Out_enable\t\t%lu\n", BIT(dword, 2)); printf("AUD_PIN_ELD_CP_VLD Transcoder_A Inactive\t\t%lu\n", BIT(dword, 3)); printf("AUD_PIN_ELD_CP_VLD Transcoder_B ELD_valid\t\t%lu\n", BIT(dword, 4)); printf("AUD_PIN_ELD_CP_VLD Transcoder_B CP_Ready\t\t%lu\n", BIT(dword, 5)); printf("AUD_PIN_ELD_CP_VLD Transcoder_B OUT_enable\t\t%lu\n", BIT(dword, 6)); printf("AUD_PIN_ELD_CP_VLD Transcoder_B Inactive\t\t%lu\n", BIT(dword, 7)); printf("AUD_PIN_ELD_CP_VLD Transcoder_C ELD_valid\t\t%lu\n", BIT(dword, 8)); printf("AUD_PIN_ELD_CP_VLD Transcoder_C CP_Ready\t\t%lu\n", BIT(dword, 9)); printf("AUD_PIN_ELD_CP_VLD Transcoder_C OUT_enable\t\t%lu\n", BIT(dword, 10)); printf("AUD_PIN_ELD_CP_VLD Transcoder_C Inactive\t\t%lu\n", BIT(dword, 11)); } static void dump_aud_hdmi_status(void) { uint32_t dword; dword = INREG(aud_reg_base + AUD_HDMIW_STATUS); printf("AUD_HDMIW_STATUS Function_Reset\t\t\t%lu\n", BIT(dword, 24)); printf("AUD_HDMIW_STATUS BCLK/CDCLK_FIFO_Overrun\t\t%lu\n", BIT(dword, 25)); printf("AUD_HDMIW_STATUS Conv_A_CDCLK/DOTCLK_FIFO_Overrun\t%lu\n", BIT(dword, 28)); printf("AUD_HDMIW_STATUS Conv_A_CDCLK/DOTCLK_FIFO_Underrun\t%lu\n", BIT(dword, 29)); printf("AUD_HDMIW_STATUS Conv_B_CDCLK/DOTCLK_FIFO_Overrun\t%lu\n", BIT(dword, 30)); printf("AUD_HDMIW_STATUS Conv_B_CDCLK/DOTCLK_FIFO_Underrun\t%lu\n", BIT(dword, 31)); } /* * Display registers of Ironlake and Valleyview */ #undef DP_CTL_B #undef DP_CTL_C #undef DP_CTL_D #define DP_CTL_B 0x4100 #define DP_CTL_C 0x4200 #define DP_CTL_D 0x4300 /* ILK HDMI port ctrl */ #define HDMI_CTL_B 0x1140 #define HDMI_CTL_C 0x1150 #define HDMI_CTL_D 0x1160 #define BSW_HDMI_CTL_B 0x1140 #define BSW_HDMI_CTL_C 0x1160 #define BSW_HDMI_CTL_D 0x116c /* VLV HDMI port ctrl */ #define SDVO_HDMI_CTL_B 0x1140 #define SDVO_HDMI_CTL_C 0x1160 static void dump_dp_port_ctrl(int port) { uint32_t dword; int port_ctrl; char prefix[MAX_PREFIX_SIZE]; sprintf(prefix, "DP_%c", 'B' + port - PORT_B); port_ctrl = disp_reg_base + DP_CTL_B + (port - PORT_B) * 0x100; dword = INREG(port_ctrl); printf("%s DisplayPort_Enable\t\t\t\t\t%lu\n", prefix, BIT(dword, 31)); printf("%s Transcoder_Select\t\t\t\t\t%s\n", prefix, BIT(dword, 30) ? "Transcoder B" : "Transcoder A"); printf("%s Port_Width_Selection\t\t\t\t[0x%lx] %s\n", prefix, BITS(dword, 21, 19), dp_port_width[BITS(dword, 21, 19)]); printf("%s Port_Detected\t\t\t\t\t%lu\n", prefix, BIT(dword, 2)); printf("%s HDCP_Port_Select\t\t\t\t\t%lu\n", prefix, BIT(dword, 5)); printf("%s Audio_Output_Enable\t\t\t\t%lu\n", prefix, BIT(dword, 6)); } static void dump_hdmi_port_ctrl(int port) { uint32_t dword; int port_ctrl; char prefix[MAX_PREFIX_SIZE]; if (IS_VALLEYVIEW(devid)) { sprintf(prefix, "SDVO/HDMI%c", 'B' + port - PORT_B); port_ctrl = disp_reg_base + SDVO_HDMI_CTL_B + (port - PORT_B) * 0x20; } else { sprintf(prefix, "HDMI%c ", 'B' + port - PORT_B); port_ctrl = disp_reg_base + HDMI_CTL_B + (port - PORT_B) * 0x10; } dword = INREG(port_ctrl); printf("%s HDMI_Enable\t\t\t\t\t%u\n", prefix, !!(dword & SDVO_ENABLE)); printf("%s Transcoder_Select\t\t\t\t%s\n", prefix, BIT(dword, 30) ? "Transcoder B" : "Transcoder A"); printf("%s HDCP_Port_Select\t\t\t\t%lu\n", prefix, BIT(dword, 5)); if (port == PORT_B) /* TODO: check spec, not found in Ibx b-spec, and only for port B? */ printf("%s SDVO Hot Plug Interrupt Detect Enable\t%lu\n", prefix, BIT(dword, 23)); printf("%s Digital_Port_Detected\t\t\t%lu\n", prefix, BIT(dword, 2)); printf("%s Encoding\t\t\t\t\t[0x%lx] %s\n", prefix, BITS(dword, 11, 10), sdvo_hdmi_encoding[BITS(dword, 11, 10)]); printf("%s Null_packets_enabled_during_Vsync\t\t%u\n", prefix, !!(dword & SDVO_NULL_PACKETS_DURING_VSYNC)); printf("%s Audio_Output_Enable\t\t\t\t%u\n", prefix, !!(dword & SDVO_AUDIO_ENABLE)); } static void dump_ironlake(void) { uint32_t dword; if (!IS_VALLEYVIEW(devid)) set_reg_base(0xe0000, 0x2000); /* ironlake */ else set_reg_base(0x60000 + VLV_DISPLAY_BASE, 0x2000); if (!IS_VALLEYVIEW(devid)) { dump_disp_reg(HDMI_CTL_B, "sDVO/HDMI Port B Control"); dump_disp_reg(HDMI_CTL_C, "HDMI Port C Control"); dump_disp_reg(HDMI_CTL_D, "HDMI Port D Control"); } else { dump_disp_reg(SDVO_HDMI_CTL_B, "sDVO/HDMI Port B Control"); dump_disp_reg(SDVO_HDMI_CTL_C, "sDVO/HDMI Port C Control"); } dump_disp_reg(DP_CTL_B, "DisplayPort B Control Register"); dump_disp_reg(DP_CTL_C, "DisplayPort C Control Register"); if (!IS_VALLEYVIEW(devid)) dump_disp_reg(DP_CTL_D, "DisplayPort D Control Register"); dump_aud_reg(AUD_CONFIG_A, "Audio Configuration - Transcoder A"); dump_aud_reg(AUD_CONFIG_B, "Audio Configuration - Transcoder B"); dump_aud_reg(AUD_CTS_ENABLE_A, "Audio CTS Programming Enable - Transcoder A"); dump_aud_reg(AUD_CTS_ENABLE_B, "Audio CTS Programming Enable - Transcoder B"); dump_aud_reg(AUD_MISC_CTRL_A, "Audio MISC Control for Transcoder A"); dump_aud_reg(AUD_MISC_CTRL_B, "Audio MISC Control for Transcoder B"); dump_aud_reg(AUD_VID_DID, "Audio Vendor ID / Device ID"); dump_aud_reg(AUD_RID, "Audio Revision ID"); dump_aud_reg(AUD_PWRST, "Audio Power State (Function Group, Convertor, Pin Widget)"); dump_aud_reg(AUD_PORT_EN_HD_CFG, "Audio Port Enable HDAudio Config"); dump_aud_reg(AUD_OUT_DIG_CNVT_A, "Audio Digital Converter - Conv A"); dump_aud_reg(AUD_OUT_DIG_CNVT_B, "Audio Digital Converter - Conv B"); dump_aud_reg(AUD_OUT_CH_STR, "Audio Channel ID and Stream ID"); dump_aud_reg(AUD_OUT_STR_DESC_A, "Audio Stream Descriptor Format - Conv A"); dump_aud_reg(AUD_OUT_STR_DESC_B, "Audio Stream Descriptor Format - Conv B"); dump_aud_reg(AUD_PINW_CONNLNG_LIST, "Audio Connection List"); dump_aud_reg(AUD_PINW_CONNLNG_SEL, "Audio Connection Select"); dump_aud_reg(AUD_CNTL_ST_A, "Audio Control State Register - Transcoder A"); dump_aud_reg(AUD_CNTL_ST_B, "Audio Control State Register - Transcoder B"); dump_aud_reg(AUD_CNTL_ST2, "Audio Control State 2"); dump_aud_reg(AUD_HDMIW_STATUS, "Audio HDMI Status"); dump_aud_reg(AUD_HDMIW_HDMIEDID_A, "HDMI Data EDID Block - Transcoder A"); dump_aud_reg(AUD_HDMIW_HDMIEDID_B, "HDMI Data EDID Block - Transcoder B"); dump_aud_reg(AUD_HDMIW_INFOFR_A, "Audio Widget Data Island Packet - Transcoder A"); dump_aud_reg(AUD_HDMIW_INFOFR_B, "Audio Widget Data Island Packet - Transcoder B"); printf("\nDetails:\n\n"); dump_aud_vendor_device_id(); dump_aud_revision_id(); dump_hdmi_port_ctrl(PORT_B); dump_hdmi_port_ctrl(PORT_C); if (!IS_VALLEYVIEW(devid)) dump_hdmi_port_ctrl(PORT_D); dump_dp_port_ctrl(PORT_B); dump_dp_port_ctrl(PORT_C); if (!IS_VALLEYVIEW(devid)) dump_dp_port_ctrl(PORT_D); dump_aud_config(PIPE_A); dump_aud_config(PIPE_B); dump_aud_m_cts_enable(PIPE_A); dump_aud_m_cts_enable(PIPE_B); dump_aud_misc_control(PIPE_A); dump_aud_misc_control(PIPE_B); dump_aud_power_state(); dump_aud_port_en_hd_cfg(); dump_aud_dig_cnvt(PIPE_A); dump_aud_dig_cnvt(PIPE_B); dump_aud_out_ch_str(); dump_aud_str_desc(PIPE_A); dump_aud_str_desc(PIPE_B); dump_aud_connect_list(); dump_aud_connect_select(); dump_aud_ctrl_state(PIPE_A); dump_aud_ctrl_state(PIPE_B); dump_aud_ctrl_state2(); dump_aud_hdmi_status(); dump_aud_edid_data(PIPE_A); dump_aud_edid_data(PIPE_B); dump_aud_infoframe(PIPE_A); dump_aud_infoframe(PIPE_B); } #undef VIDEO_DIP_CTL_A #undef VIDEO_DIP_CTL_B #undef VIDEO_DIP_CTL_C #undef VIDEO_DIP_CTL_D #undef VIDEO_DIP_DATA /* * Haswell+ display registers */ /* DisplayPort Transport Control */ #define DP_TP_CTL_A 0x64040 #define DP_TP_CTL_B 0x64140 #define DP_TP_CTL_C 0x64240 #define DP_TP_CTL_D 0x64340 #define DP_TP_CTL_E 0x64440 /* DisplayPort Transport Status */ #define DP_TP_ST_A 0x64044 #define DP_TP_ST_B 0x64144 #define DP_TP_ST_C 0x64244 #define DP_TP_ST_D 0x64344 #define DP_TP_ST_E 0x64444 /* DDI Buffer Control */ #define DDI_BUF_CTL_A 0x64000 #define DDI_BUF_CTL_B 0x64100 #define DDI_BUF_CTL_C 0x64200 #define DDI_BUF_CTL_D 0x64300 #define DDI_BUF_CTL_E 0x64400 /* DDI Buffer Translation */ #define DDI_BUF_TRANS_A 0x64e00 #define DDI_BUF_TRANS_B 0x64e60 #define DDI_BUF_TRANS_C 0x64ec0 #define DDI_BUF_TRANS_D 0x64f20 #define DDI_BUF_TRANS_E 0x64f80 /* DDI Aux Channel */ #define DDI_AUX_CHANNEL_CTRL 0x64010 #define DDI_AUX_DATA 0x64014 #define DDI_AUX_TST 0x64028 /* DDI CRC Control */ #define DDI_CRC_CTL_A 0x64050 #define DDI_CRC_CTL_B 0x64150 #define DDI_CRC_CTL_C 0x64250 #define DDI_CRC_CTL_D 0x64350 #define DDI_CRC_CTL_E 0x64450 /* Pipe DDI Function Control */ #define PIPE_DDI_FUNC_CTL_A 0x60400 #define PIPE_DDI_FUNC_CTL_B 0x61400 #define PIPE_DDI_FUNC_CTL_C 0x62400 #define PIPE_DDI_FUNC_CTL_EDP 0x6F400 /* Pipe Configuration */ #define PIPE_CONF_A 0x70008 #define PIPE_CONF_B 0x71008 #define PIPE_CONF_C 0x72008 #define PIPE_CONF_EDP 0x7F008 /* Video DIP Control */ #define VIDEO_DIP_CTL_A 0x60200 #define VIDEO_DIP_CTL_B 0x61200 #define VIDEO_DIP_CTL_C 0x62200 #define VIDEO_DIP_CTL_D 0x63200 #define VIDEO_DIP_DATA 0x60220 #define VIDEO_DIP_ECC 0x60240 static void dump_ddi_buf_ctl(int port) { uint32_t dword; dword = INREG(DDI_BUF_CTL_A + (port - PORT_A) * 0x100); printf("DDI %c Buffer control\n", 'A' + port - PORT_A); printf("\tDP port width\t\t\t\t\t[0x%lx] %s\n", BITS(dword, 3, 1), OPNAME(dp_port_width, BITS(dword, 3, 1))); printf("\tDDI Buffer Enable\t\t\t\t%ld\n", BIT(dword, 31)); } static void dump_ddi_func_ctl(int pipe) { uint32_t dword; dword = INREG(PIPE_DDI_FUNC_CTL_A + (pipe - PIPE_A) * 0x1000); printf("Pipe %c DDI Function Control\n", 'A' + pipe - PIPE_A); printf("\tBITS per color\t\t\t\t\t[0x%lx] %s\n", BITS(dword, 22, 20), OPNAME(bits_per_color, BITS(dword, 22, 20))); printf("\tPIPE DDI Mode\t\t\t\t\t[0x%lx] %s\n", BITS(dword, 26, 24), OPNAME(ddi_mode, BITS(dword, 26, 24))); printf("\tPIPE DDI selection\t\t\t\t[0x%lx] %s\n", BITS(dword, 30, 28), OPNAME(trans_to_port_sel, BITS(dword, 30, 28))); printf("\tPIPE DDI Function Enable\t\t\t[0x%lx]\n", BIT(dword, 31)); } static void dump_aud_connect_list_entry_length(int transcoder) { uint32_t dword; char prefix[MAX_PREFIX_SIZE]; dword = INREG(aud_reg_base + AUD_TCA_PIN_PIPE_CONN_ENTRY_LNGTH + (transcoder - TRANSCODER_A) * 0x100); sprintf(prefix, "AUD_TC%c_PIN_PIPE_CONN_ENTRY_LNGTH", 'A' + transcoder - TRANSCODER_A); printf("%s Connect_List_Length\t%lu\n", prefix, BITS(dword, 6, 0)); printf("%s Form \t\t[%#lx] %s\n", prefix, BIT(dword, 7), OPNAME(connect_list_form, BIT(dword, 7))); printf("%s Connect_List_Entry\t%lu\n", prefix, BITS(dword, 15, 8)); } static void dump_aud_connect_select_ctrl(void) { uint32_t dword; dword = INREG(aud_reg_base + AUD_PIPE_CONN_SEL_CTRL); printf("AUD_PIPE_CONN_SEL_CTRL Connection_select_Port_B\t%#lx\n", BITS(dword, 7, 0)); printf("AUD_PIPE_CONN_SEL_CTRL Connection_select_Port_C\t%#lx\n", BITS(dword, 15, 8)); printf("AUD_PIPE_CONN_SEL_CTRL Connection_select_Port_D\t%#lx\n", BITS(dword, 23, 16)); } static void dump_aud_dip_eld_ctrl_st(int transcoder) { uint32_t dword; int offset = (transcoder - TRANSCODER_A) * 0x100; dword = INREG(aud_reg_base + AUD_TCA_DIP_ELD_CTRL_ST + offset); printf("Audio DIP and ELD control state for Transcoder %c\n", 'A' + transcoder - TRANSCODER_A); printf("\tELD_ACK\t\t\t\t\t\t%lu\n", BIT(dword, 4)); printf("\tELD_buffer_size\t\t\t\t\t%lu\n", BITS(dword, 14, 10)); printf("\tDIP_transmission_frequency\t\t\t[0x%lx] %s\n", BITS(dword, 17, 16), dip_trans[BITS(dword, 17, 16)]); printf("\tDIP Buffer Index \t\t\t\t[0x%lx] %s\n", BITS(dword, 20, 18), dip_index[BITS(dword, 20, 18)]); printf("\tAudio DIP type enable status\t\t\t[0x%04lx] %s, %s, %s\n", BITS(dword, 24, 21), dip_type[BIT(dword, 21)], dip_gen1_state[BIT(dword, 22)], dip_gen2_state[BIT(dword, 23)]); printf("\tAudio DIP port select\t\t\t\t[0x%lx] %s\n", BITS(dword, 30, 29), dip_port[BITS(dword, 30, 29)]); printf("\n"); } static void dump_aud_hdmi_fifo_status(void) { uint32_t dword; dword = INREG(aud_reg_base + AUD_HDMI_FIFO_STATUS); printf("AUD_HDMI_FIFO_STATUS Function_Reset\t\t\t%lu\n", BIT(dword, 24)); printf("AUD_HDMI_FIFO_STATUS Conv_1_CDCLK/DOTCLK_FIFO_Overrun\t%lu\n", BIT(dword, 26)); printf("AUD_HDMI_FIFO_STATUS Conv_1_CDCLK/DOTCLK_FIFO_Underrun\t%lu\n", BIT(dword, 27)); printf("AUD_HDMI_FIFO_STATUS Conv_2_CDCLK/DOTCLK_FIFO_Overrun\t%lu\n", BIT(dword, 28)); printf("AUD_HDMI_FIFO_STATUS Conv_2_CDCLK/DOTCLK_FIFO_Underrun\t%lu\n", BIT(dword, 29)); printf("AUD_HDMI_FIFO_STATUS Conv_3_CDCLK/DOTCLK_FIFO_Overrun\t%lu\n", BIT(dword, 30)); printf("AUD_HDMI_FIFO_STATUS Conv_3_CDCLK/DOTCLK_FIFO_Underrun\t%lu\n", BIT(dword, 31)); } static void parse_bdw_audio_chicken_bit_reg(uint32_t dword) { printf("\t"); printf("%s\n\t", OPNAME(vanilla_dp12_en, BIT(dword, 31))); printf("%s\n\t", OPNAME(vanilla_3_widgets_en, BIT(dword, 30))); printf("%s\n\t", OPNAME(block_audio, BIT(dword, 10))); printf("%s\n\t", OPNAME(dis_eld_valid_pulse_trans, BIT(dword, 9))); printf("%s\n\t", OPNAME(dis_pd_pulse_trans, BIT(dword, 8))); printf("%s\n\t", OPNAME(dis_ts_delta_err, BIT(dword, 7))); printf("%s\n\t", OPNAME(dis_ts_fix_dp_hbr, BIT(dword, 6))); printf("%s\n\t", OPNAME(pattern_gen_8_ch_en, BIT(dword, 5))); printf("%s\n\t", OPNAME(pattern_gen_2_ch_en, BIT(dword, 4))); printf("%s\n\t", OPNAME(fabric_32_44_dis, BIT(dword, 3))); printf("%s\n\t", OPNAME(epss_dis, BIT(dword, 2))); printf("%s\n\t", OPNAME(ts_test_mode, BIT(dword, 1))); printf("%s\n", OPNAME(en_mmio_program, BIT(dword, 0))); } static void parse_skl_audio_freq_cntrl_reg(uint32_t dword) { printf("\t"); printf("%s\n\t", OPNAME(sdi_operate_mode, BIT(dword, 15))); printf("%s\n\t", OPNAME(bclk_96mhz, BIT(dword, 4))); printf("%s\n", OPNAME(bclk_48mhz, BIT(dword, 3))); } /* Dump audio registers for Haswell and its successors (eg. Broadwell). * Their register layout are same in the north display engine. */ static void dump_hsw_plus(void) { uint32_t dword; int i; set_aud_reg_base(0x65000); dump_reg(PORT_HOTPLUG_EN, "port hotplug enable"); dump_reg(PORT_HOTPLUG_STAT, "port hotplug status"); dump_reg(DISPLAY_HOTPLUG_CTL, "display hotplug control"); /* HSW DDI Buffer */ dump_reg(DDI_BUF_CTL_A, "DDI Buffer Controler A"); dump_reg(DDI_BUF_CTL_B, "DDI Buffer Controler B"); dump_reg(DDI_BUF_CTL_C, "DDI Buffer Controler C"); dump_reg(DDI_BUF_CTL_D, "DDI Buffer Controler D"); dump_reg(DDI_BUF_CTL_E, "DDI Buffer Controler E"); /* HSW Pipe Function */ dump_reg(PIPE_CONF_A, "PIPE Configuration A"); dump_reg(PIPE_CONF_B, "PIPE Configuration B"); dump_reg(PIPE_CONF_C, "PIPE Configuration C"); dump_reg(PIPE_CONF_EDP, "PIPE Configuration EDP"); dump_reg(PIPE_DDI_FUNC_CTL_A, "PIPE DDI Function Control A"); dump_reg(PIPE_DDI_FUNC_CTL_B, "PIPE DDI Function Control B"); dump_reg(PIPE_DDI_FUNC_CTL_C, "PIPE DDI Function Control C"); dump_reg(PIPE_DDI_FUNC_CTL_EDP, "PIPE DDI Function Control EDP"); /* HSW Display port */ dump_reg(DP_TP_CTL_A, "DisplayPort Transport A Control"); dump_reg(DP_TP_CTL_B, "DisplayPort Transport B Control"); dump_reg(DP_TP_CTL_C, "DisplayPort Transport C Control"); dump_reg(DP_TP_CTL_D, "DisplayPort Transport D Control"); dump_reg(DP_TP_CTL_E, "DisplayPort Transport E Control"); dump_reg(DP_TP_ST_A, "DisplayPort Transport A Status"); dump_reg(DP_TP_ST_B, "DisplayPort Transport B Status"); dump_reg(DP_TP_ST_C, "DisplayPort Transport C Status"); dump_reg(DP_TP_ST_D, "DisplayPort Transport D Status"); dump_reg(DP_TP_ST_E, "DisplayPort Transport E Status"); /* HSW North Display Audio */ dump_aud_reg(AUD_TCA_CONFIG, "Audio Configuration - Transcoder A"); dump_aud_reg(AUD_TCB_CONFIG, "Audio Configuration - Transcoder B"); dump_aud_reg(AUD_TCC_CONFIG, "Audio Configuration - Transcoder C"); dump_aud_reg(AUD_C1_MISC_CTRL, "Audio Converter 1 MISC Control"); dump_aud_reg(AUD_C2_MISC_CTRL, "Audio Converter 2 MISC Control"); dump_aud_reg(AUD_C3_MISC_CTRL, "Audio Converter 3 MISC Control"); dump_aud_reg(AUD_VID_DID, "Audio Vendor ID / Device ID"); dump_aud_reg(AUD_RID, "Audio Revision ID"); dump_aud_reg(AUD_TCA_M_CTS_ENABLE, "Audio M & CTS Programming Enable - Transcoder A"); dump_aud_reg(AUD_TCB_M_CTS_ENABLE, "Audio M & CTS Programming Enable - Transcoder B"); dump_aud_reg(AUD_TCC_M_CTS_ENABLE, "Audio M & CTS Programming Enable - Transcoder C"); dump_aud_reg(AUD_PWRST, "Audio Power State (Function Group, Convertor, Pin Widget)"); dump_aud_reg(AUD_TCA_EDID_DATA, "Audio EDID Data Block - Transcoder A"); dump_aud_reg(AUD_TCB_EDID_DATA, "Audio EDID Data Block - Transcoder B"); dump_aud_reg(AUD_TCC_EDID_DATA, "Audio EDID Data Block - Transcoder C"); if (IS_GEN9(devid)) dump_aud_reg(AUD_FREQ_CNTRL, "Audio BCLK Frequency Control"); dump_aud_reg(AUD_TCA_INFOFR, "Audio Widget Data Island Packet - Transcoder A"); dump_aud_reg(AUD_TCB_INFOFR, "Audio Widget Data Island Packet - Transcoder B"); dump_aud_reg(AUD_TCC_INFOFR, "Audio Widget Data Island Packet - Transcoder C"); dump_aud_reg(AUD_PIPE_CONV_CFG, "Audio Pipe and Converter Configs"); dump_aud_reg(AUD_C1_DIG_CNVT, "Audio Digital Converter - Converter 1"); dump_aud_reg(AUD_C2_DIG_CNVT, "Audio Digital Converter - Converter 2"); dump_aud_reg(AUD_C3_DIG_CNVT, "Audio Digital Converter - Converter 3"); dump_aud_reg(AUD_C1_STR_DESC, "Audio Stream Descriptor Format - Converter 1"); dump_aud_reg(AUD_C2_STR_DESC, "Audio Stream Descriptor Format - Converter 2"); dump_aud_reg(AUD_C3_STR_DESC, "Audio Stream Descriptor Format - Converter 3"); dump_aud_reg(AUD_OUT_CHAN_MAP, "Audio Output Channel Mapping"); dump_aud_reg(AUD_TCA_PIN_PIPE_CONN_ENTRY_LNGTH, "Audio Connection List entry and Length - Transcoder A"); dump_aud_reg(AUD_TCB_PIN_PIPE_CONN_ENTRY_LNGTH, "Audio Connection List entry and Length - Transcoder B"); dump_aud_reg(AUD_TCC_PIN_PIPE_CONN_ENTRY_LNGTH, "Audio Connection List entry and Length - Transcoder C"); dump_aud_reg(AUD_PIPE_CONN_SEL_CTRL, "Audio Pipe Connection Select Control"); dump_aud_reg(AUD_TCA_DIP_ELD_CTRL_ST, "Audio DIP and ELD control state - Transcoder A"); dump_aud_reg(AUD_TCB_DIP_ELD_CTRL_ST, "Audio DIP and ELD control state - Transcoder B"); dump_aud_reg(AUD_TCC_DIP_ELD_CTRL_ST, "Audio DIP and ELD control state - Transcoder C"); dump_aud_reg(AUD_PIN_ELD_CP_VLD, "Audio pin ELD valid and CP ready status"); dump_aud_reg(AUD_HDMI_FIFO_STATUS, "Audio HDMI FIFO Status"); /* Audio debug registers */ dump_aud_reg(AUD_ICOI, "Audio Immediate Command Output Interface"); dump_aud_reg(AUD_IRII, "Audio Immediate Response Input Interface"); dump_aud_reg(AUD_ICS, "Audio Immediate Command Status"); dump_aud_reg(AUD_CHICKENBIT_REG, "Audio Chicken Bit Register"); dump_aud_reg(AUD_DP_DIP_STATUS, "Audio DP and DIP FIFO Debug Status"); dump_aud_reg(AUD_TCA_M_CTS, "Audio M CTS Read Back Transcoder A"); dump_aud_reg(AUD_TCB_M_CTS, "Audio M CTS Read Back Transcoder B"); dump_aud_reg(AUD_TCC_M_CTS, "Audio M CTS Read Back Transcoder C"); if (IS_GEN9(devid)) { dump_aud_reg(AUD_HDA_DMA_REG, "Audio HD Audio DMA Control Register"); dump_aud_reg(AUD_HDA_LPIB0_REG, "Audio HD Audio Stream0 Link Position in Buffer"); dump_aud_reg(AUD_HDA_LPIB1_REG, "Audio HD Audio Stream1 Link Position in Buffer"); dump_aud_reg(AUD_HDA_LPIB2_REG, "Audio HD Audio Stream2 Link Position in Buffer"); dump_aud_reg(AUD_HDA_EXTRA_REG, "Audio HD Audio Extra Register"); dump_aud_reg(AUD_FPGA_CRC_CTL_A, "Audio FPGA Pipe A CRC Control"); dump_aud_reg(AUD_FPGA_CRC_CTL_B, "Audio FPGA Pipe B CRC Control"); dump_aud_reg(AUD_FPGA_CRC_CTL_C, "Audio FPGA Pipe C CRC Control"); dump_aud_reg(AUD_FPGA_CRC_RESULT_A, "Audio FPGA Pipe A CRC Result"); dump_aud_reg(AUD_FPGA_CRC_RESULT_B, "Audio FPGA Pipe B CRC Result"); dump_aud_reg(AUD_FPGA_CRC_RESULT_C, "Audio FPGA Pipe C CRC Result"); dump_aud_reg(AUD_DFT_MVAL_REG, "Audio DFT M Value Register"); dump_aud_reg(AUD_DFT_NVAL_REG, "Audio DFT N Value Register"); dump_aud_reg(AUD_DFT_LOAD_REG, "Audio DFT LOAD Register"); } printf("\nDetails:\n\n"); dump_ddi_buf_ctl(PORT_A); dump_ddi_buf_ctl(PORT_B); dump_ddi_buf_ctl(PORT_C); dump_ddi_buf_ctl(PORT_D); dump_ddi_buf_ctl(PORT_E); dump_ddi_func_ctl(PIPE_A); dump_ddi_func_ctl(PIPE_B); dump_ddi_func_ctl(PIPE_C); /* audio configuration - details */ dump_aud_config(TRANSCODER_A); dump_aud_config(TRANSCODER_B); dump_aud_config(TRANSCODER_C); dump_aud_misc_control(CONVERTER_1); dump_aud_misc_control(CONVERTER_2); dump_aud_misc_control(CONVERTER_3); dump_aud_vendor_device_id(); dump_aud_revision_id(); dump_aud_m_cts_enable(TRANSCODER_A); dump_aud_m_cts_enable(TRANSCODER_B); dump_aud_m_cts_enable(TRANSCODER_C); dump_aud_power_state(); dump_aud_edid_data(TRANSCODER_A); dump_aud_edid_data(TRANSCODER_B); dump_aud_edid_data(TRANSCODER_C); dump_aud_infoframe(TRANSCODER_A); dump_aud_infoframe(TRANSCODER_B); dump_aud_infoframe(TRANSCODER_C); dump_aud_pipe_conv_cfg(); dump_aud_dig_cnvt(CONVERTER_1); dump_aud_dig_cnvt(CONVERTER_2); dump_aud_dig_cnvt(CONVERTER_3); dump_aud_str_desc(CONVERTER_1); dump_aud_str_desc(CONVERTER_2); dump_aud_str_desc(CONVERTER_3); dump_aud_out_chan_map(); dump_aud_connect_list_entry_length(TRANSCODER_A); dump_aud_connect_list_entry_length(TRANSCODER_B); dump_aud_connect_list_entry_length(TRANSCODER_C); dump_aud_connect_select_ctrl(); dump_aud_dip_eld_ctrl_st(TRANSCODER_A); dump_aud_dip_eld_ctrl_st(TRANSCODER_B); dump_aud_dip_eld_ctrl_st(TRANSCODER_C); dump_aud_eld_cp_vld(); dump_aud_hdmi_fifo_status(); dword = read_aud_reg(AUD_ICS); printf("IRV [%1lx] %s\t", BIT(dword, 1), OPNAME(immed_result_valid, BIT(dword, 1))); printf("ICB [%1lx] %s\n", BIT(dword, 1), OPNAME(immed_cmd_busy, BIT(dword, 0))); dword = read_aud_reg(AUD_CHICKENBIT_REG); printf("AUD_CHICKENBIT_REG Audio Chicken Bits: %08x\n", dword); if (IS_BROADWELL(devid)) parse_bdw_audio_chicken_bit_reg(dword); dword = read_aud_reg(AUD_DP_DIP_STATUS); printf("AUD_DP_DIP_STATUS Audio DP & DIP FIFO Status: %08x\n\t", dword); for (i = 31; i >= 0; i--) if (BIT(dword, i)) printf("%s\n\t", audio_dp_dip_status[i]); printf("\n"); dword = read_aud_reg(AUD_FREQ_CNTRL); printf("AUD_FREQ_CNTRL Audio BCLK Frequency Control: %08x\n", dword); if (IS_GEN9(devid)) parse_skl_audio_freq_cntrl_reg(dword); } /* offset of hotplug enable */ #define PORT_HOTPLUG_EN_OFFSET 0x1110 /* offset of hotplug status */ #define PORT_HOTPLUG_STAT_OFFSET 0x1114 /* offset of hotplug control*/ #define DISPLAY_HOTPLUG_CTL_OFFSET 0x1164 /* dump the braswell registers for audio */ static void dump_braswell(void) { uint32_t dword; /* set_aud_reg_base(0x62000 + VLV_DISPLAY_BASE); */ set_reg_base(0x60000 + VLV_DISPLAY_BASE, 0x2000); dump_disp_reg(PORT_HOTPLUG_EN_OFFSET, "port hotplug enable"); dump_disp_reg(PORT_HOTPLUG_STAT_OFFSET, "port hotplug status"); dump_disp_reg(DISPLAY_HOTPLUG_CTL_OFFSET, "display hotplug control"); dump_disp_reg(BSW_HDMI_CTL_B, "sDVO/HDMI Port B Control"); dump_disp_reg(BSW_HDMI_CTL_C, "HDMI Port C Control"); // The address is wrong? dump_disp_reg(BSW_HDMI_CTL_D, "HDMI Port D Control"); dump_disp_reg(DP_CTL_B, "DisplayPort B Control Register"); dump_disp_reg(DP_CTL_C, "DisplayPort C Control Register"); dump_disp_reg(DP_CTL_D, "DisplayPort D Control Register"); /* HSW North Display Audio */ dump_aud_reg(AUD_TCA_CONFIG, "Audio Configuration - Transcoder A"); dump_aud_reg(AUD_TCB_CONFIG, "Audio Configuration - Transcoder B"); dump_aud_reg(AUD_TCC_CONFIG, "Audio Configuration - Transcoder C"); dump_aud_reg(AUD_C1_MISC_CTRL, "Audio Converter 1 MISC Control"); dump_aud_reg(AUD_C2_MISC_CTRL, "Audio Converter 2 MISC Control"); dump_aud_reg(AUD_C3_MISC_CTRL, "Audio Converter 3 MISC Control"); dump_aud_reg(AUD_VID_DID, "Audio Vendor ID / Device ID"); dump_aud_reg(AUD_RID, "Audio Revision ID"); dump_aud_reg(AUD_TCA_M_CTS_ENABLE, "Audio M & CTS Programming Enable - Transcoder A"); dump_aud_reg(AUD_TCB_M_CTS_ENABLE, "Audio M & CTS Programming Enable - Transcoder B"); dump_aud_reg(AUD_TCC_M_CTS_ENABLE, "Audio M & CTS Programming Enable - Transcoder C"); dump_aud_reg(AUD_PWRST, "Audio Power State (Function Group, Convertor, Pin Widget)"); dump_aud_reg(AUD_TCA_EDID_DATA, "Audio EDID Data Block - Transcoder A"); dump_aud_reg(AUD_TCB_EDID_DATA, "Audio EDID Data Block - Transcoder B"); dump_aud_reg(AUD_TCC_EDID_DATA, "Audio EDID Data Block - Transcoder C"); dump_aud_reg(AUD_TCA_INFOFR, "Audio Widget Data Island Packet - Transcoder A"); dump_aud_reg(AUD_TCB_INFOFR, "Audio Widget Data Island Packet - Transcoder B"); dump_aud_reg(AUD_TCC_INFOFR, "Audio Widget Data Island Packet - Transcoder C"); dump_aud_reg(AUD_PIPE_CONV_CFG, "Audio Pipe and Converter Configs"); dump_aud_reg(AUD_C1_DIG_CNVT, "Audio Digital Converter - Converter 1"); dump_aud_reg(AUD_C2_DIG_CNVT, "Audio Digital Converter - Converter 2"); dump_aud_reg(AUD_C3_DIG_CNVT, "Audio Digital Converter - Converter 3"); dump_aud_reg(AUD_C1_STR_DESC, "Audio Stream Descriptor Format - Converter 1"); dump_aud_reg(AUD_C2_STR_DESC, "Audio Stream Descriptor Format - Converter 2"); dump_aud_reg(AUD_C3_STR_DESC, "Audio Stream Descriptor Format - Converter 3"); dump_aud_reg(AUD_OUT_CHAN_MAP, "Audio Output Channel Mapping"); dump_aud_reg(AUD_TCA_PIN_PIPE_CONN_ENTRY_LNGTH, "Audio Connection List entry and Length - Transcoder A"); dump_aud_reg(AUD_TCB_PIN_PIPE_CONN_ENTRY_LNGTH, "Audio Connection List entry and Length - Transcoder B"); dump_aud_reg(AUD_TCC_PIN_PIPE_CONN_ENTRY_LNGTH, "Audio Connection List entry and Length - Transcoder C"); dump_aud_reg(AUD_PIPE_CONN_SEL_CTRL, "Audio Pipe Connection Select Control"); dump_aud_reg(AUD_TCA_DIP_ELD_CTRL_ST, "Audio DIP and ELD control state - Transcoder A"); dump_aud_reg(AUD_TCB_DIP_ELD_CTRL_ST, "Audio DIP and ELD control state - Transcoder B"); dump_aud_reg(AUD_TCC_DIP_ELD_CTRL_ST, "Audio DIP and ELD control state - Transcoder C"); dump_aud_reg(AUD_PIN_ELD_CP_VLD, "Audio pin ELD valid and CP ready status"); dump_aud_reg(AUD_HDMI_FIFO_STATUS, "Audio HDMI FIFO Status"); /* Audio debug registers */ dump_aud_reg(AUD_ICOI, "Audio Immediate Command Output Interface"); dump_aud_reg(AUD_IRII, "Audio Immediate Response Input Interface"); dump_aud_reg(AUD_ICS, "Audio Immediate Command Status"); dump_aud_reg(AUD_CHICKENBIT_REG, "Audio Chicken Bit Register"); dump_aud_reg(AUD_DP_DIP_STATUS, "Audio DP and DIP FIFO Debug Status"); dump_aud_reg(AUD_TCA_M_CTS, "Audio M CTS Read Back Transcoder A"); dump_aud_reg(AUD_TCB_M_CTS, "Audio M CTS Read Back Transcoder B"); dump_aud_reg(AUD_TCC_M_CTS, "Audio M CTS Read Back Transcoder C"); printf("\n"); printf("\nDetails:\n\n"); dump_aud_vendor_device_id(); dump_aud_revision_id(); dump_hdmi_port_ctrl(PORT_B); dump_hdmi_port_ctrl(PORT_C); if (!IS_VALLEYVIEW(devid)) dump_hdmi_port_ctrl(PORT_D); dump_dp_port_ctrl(PORT_B); dump_dp_port_ctrl(PORT_C); if (!IS_VALLEYVIEW(devid)) dump_dp_port_ctrl(PORT_D); dump_aud_config(PIPE_A); dump_aud_config(PIPE_B); dump_aud_m_cts_enable(PIPE_A); dump_aud_m_cts_enable(PIPE_B); dump_aud_misc_control(PIPE_A); dump_aud_misc_control(PIPE_B); dump_aud_power_state(); dump_aud_port_en_hd_cfg(); dump_aud_dig_cnvt(PIPE_A); dump_aud_dig_cnvt(PIPE_B); dump_aud_out_ch_str(); dump_aud_str_desc(PIPE_A); dump_aud_str_desc(PIPE_B); dump_aud_connect_list(); dump_aud_connect_select(); dump_aud_ctrl_state(PIPE_A); dump_aud_ctrl_state(PIPE_B); dump_aud_ctrl_state2(); dump_aud_hdmi_status(); dump_aud_edid_data(PIPE_A); dump_aud_edid_data(PIPE_B); dump_aud_infoframe(PIPE_A); dump_aud_infoframe(PIPE_B); } int main(int argc, char **argv) { struct pci_device *pci_dev; pci_dev = intel_get_pci_device(); devid = pci_dev->device_id; /* XXX not true when mapping! */ do_self_tests(); if (argc == 2) intel_mmio_use_dump_file(argv[1]); else intel_mmio_use_pci_bar(pci_dev); printf("%s audio registers:\n\n", intel_get_device_info(devid)->codename); if (IS_VALLEYVIEW(devid)) { dump_ironlake(); } else if (IS_CHERRYVIEW(devid)) { dump_braswell(); } else if (IS_GEN9(devid) || IS_BROADWELL(devid) || IS_HASWELL(devid)) { dump_hsw_plus(); } else if (IS_GEN6(devid) || IS_GEN7(devid) || getenv("HAS_PCH_SPLIT")) { intel_check_pch(); dump_cpt(); } else if (IS_GEN5(devid)) { dump_ironlake(); } else if (IS_G4X(devid)) { dump_eaglelake(); } return 0; }