Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Aurabindo Pillai | 1921 | 84.44% | 1 | 5.88% |
Nicholas Kazlauskas | 288 | 12.66% | 4 | 23.53% |
Alvin lee | 18 | 0.79% | 2 | 11.76% |
Dillon Varone | 13 | 0.57% | 1 | 5.88% |
Eric Yang | 11 | 0.48% | 2 | 11.76% |
Anthony Koo | 9 | 0.40% | 2 | 11.76% |
Wyatt Wood | 6 | 0.26% | 1 | 5.88% |
Ashley Thomas | 4 | 0.18% | 1 | 5.88% |
Martin Leung | 2 | 0.09% | 1 | 5.88% |
Meenakshikumar Somasundaram | 2 | 0.09% | 1 | 5.88% |
Yongqiang Sun | 1 | 0.04% | 1 | 5.88% |
Total | 2275 | 17 |
/* * Copyright 2022 Advanced Micro Devices, Inc. * * 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 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 COPYRIGHT HOLDER(S) OR AUTHOR(S) 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: AMD * */ #include "../dmub_srv.h" #include "dmub_reg.h" #include "dmub_dcn32.h" #include "dcn/dcn_3_2_0_offset.h" #include "dcn/dcn_3_2_0_sh_mask.h" #define DCN_BASE__INST0_SEG2 0x000034C0 #define BASE_INNER(seg) DCN_BASE__INST0_SEG##seg #define CTX dmub #define REGS dmub->regs_dcn32 #define REG_OFFSET_EXP(reg_name) (BASE(reg##reg_name##_BASE_IDX) + reg##reg_name) const struct dmub_srv_dcn32_regs dmub_srv_dcn32_regs = { #define DMUB_SR(reg) REG_OFFSET_EXP(reg), { DMUB_DCN32_REGS() DMCUB_INTERNAL_REGS() }, #undef DMUB_SR #define DMUB_SF(reg, field) FD_MASK(reg, field), { DMUB_DCN32_FIELDS() }, #undef DMUB_SF #define DMUB_SF(reg, field) FD_SHIFT(reg, field), { DMUB_DCN32_FIELDS() }, #undef DMUB_SF }; static void dmub_dcn32_get_fb_base_offset(struct dmub_srv *dmub, uint64_t *fb_base, uint64_t *fb_offset) { uint32_t tmp; if (dmub->fb_base || dmub->fb_offset) { *fb_base = dmub->fb_base; *fb_offset = dmub->fb_offset; return; } REG_GET(DCN_VM_FB_LOCATION_BASE, FB_BASE, &tmp); *fb_base = (uint64_t)tmp << 24; REG_GET(DCN_VM_FB_OFFSET, FB_OFFSET, &tmp); *fb_offset = (uint64_t)tmp << 24; } static inline void dmub_dcn32_translate_addr(const union dmub_addr *addr_in, uint64_t fb_base, uint64_t fb_offset, union dmub_addr *addr_out) { addr_out->quad_part = addr_in->quad_part - fb_base + fb_offset; } void dmub_dcn32_reset(struct dmub_srv *dmub) { union dmub_gpint_data_register cmd; const uint32_t timeout = 30; uint32_t in_reset, scratch, i; REG_GET(DMCUB_CNTL2, DMCUB_SOFT_RESET, &in_reset); if (in_reset == 0) { cmd.bits.status = 1; cmd.bits.command_code = DMUB_GPINT__STOP_FW; cmd.bits.param = 0; dmub->hw_funcs.set_gpint(dmub, cmd); /** * Timeout covers both the ACK and the wait * for remaining work to finish. * * This is mostly bound by the PHY disable sequence. * Each register check will be greater than 1us, so * don't bother using udelay. */ for (i = 0; i < timeout; ++i) { if (dmub->hw_funcs.is_gpint_acked(dmub, cmd)) break; } for (i = 0; i < timeout; ++i) { scratch = dmub->hw_funcs.get_gpint_response(dmub); if (scratch == DMUB_GPINT__STOP_FW_RESPONSE) break; } /* Clear the GPINT command manually so we don't reset again. */ cmd.all = 0; dmub->hw_funcs.set_gpint(dmub, cmd); /* Force reset in case we timed out, DMCUB is likely hung. */ } REG_UPDATE(DMCUB_CNTL2, DMCUB_SOFT_RESET, 1); REG_UPDATE(DMCUB_CNTL, DMCUB_ENABLE, 0); REG_UPDATE(MMHUBBUB_SOFT_RESET, DMUIF_SOFT_RESET, 1); REG_WRITE(DMCUB_INBOX1_RPTR, 0); REG_WRITE(DMCUB_INBOX1_WPTR, 0); REG_WRITE(DMCUB_OUTBOX1_RPTR, 0); REG_WRITE(DMCUB_OUTBOX1_WPTR, 0); REG_WRITE(DMCUB_SCRATCH0, 0); } void dmub_dcn32_reset_release(struct dmub_srv *dmub) { REG_WRITE(DMCUB_GPINT_DATAIN1, 0); REG_UPDATE(MMHUBBUB_SOFT_RESET, DMUIF_SOFT_RESET, 0); REG_WRITE(DMCUB_SCRATCH15, dmub->psp_version & 0x001100FF); REG_UPDATE_2(DMCUB_CNTL, DMCUB_ENABLE, 1, DMCUB_TRACEPORT_EN, 1); REG_UPDATE(DMCUB_CNTL2, DMCUB_SOFT_RESET, 0); } void dmub_dcn32_backdoor_load(struct dmub_srv *dmub, const struct dmub_window *cw0, const struct dmub_window *cw1) { union dmub_addr offset; uint64_t fb_base, fb_offset; dmub_dcn32_get_fb_base_offset(dmub, &fb_base, &fb_offset); REG_UPDATE(DMCUB_SEC_CNTL, DMCUB_SEC_RESET, 1); dmub_dcn32_translate_addr(&cw0->offset, fb_base, fb_offset, &offset); REG_WRITE(DMCUB_REGION3_CW0_OFFSET, offset.u.low_part); REG_WRITE(DMCUB_REGION3_CW0_OFFSET_HIGH, offset.u.high_part); REG_WRITE(DMCUB_REGION3_CW0_BASE_ADDRESS, cw0->region.base); REG_SET_2(DMCUB_REGION3_CW0_TOP_ADDRESS, 0, DMCUB_REGION3_CW0_TOP_ADDRESS, cw0->region.top, DMCUB_REGION3_CW0_ENABLE, 1); dmub_dcn32_translate_addr(&cw1->offset, fb_base, fb_offset, &offset); REG_WRITE(DMCUB_REGION3_CW1_OFFSET, offset.u.low_part); REG_WRITE(DMCUB_REGION3_CW1_OFFSET_HIGH, offset.u.high_part); REG_WRITE(DMCUB_REGION3_CW1_BASE_ADDRESS, cw1->region.base); REG_SET_2(DMCUB_REGION3_CW1_TOP_ADDRESS, 0, DMCUB_REGION3_CW1_TOP_ADDRESS, cw1->region.top, DMCUB_REGION3_CW1_ENABLE, 1); REG_UPDATE_2(DMCUB_SEC_CNTL, DMCUB_SEC_RESET, 0, DMCUB_MEM_UNIT_ID, 0x20); } void dmub_dcn32_backdoor_load_zfb_mode(struct dmub_srv *dmub, const struct dmub_window *cw0, const struct dmub_window *cw1) { union dmub_addr offset; REG_UPDATE(DMCUB_SEC_CNTL, DMCUB_SEC_RESET, 1); offset = cw0->offset; REG_WRITE(DMCUB_REGION3_CW0_OFFSET, offset.u.low_part); REG_WRITE(DMCUB_REGION3_CW0_OFFSET_HIGH, offset.u.high_part); REG_WRITE(DMCUB_REGION3_CW0_BASE_ADDRESS, cw0->region.base); REG_SET_2(DMCUB_REGION3_CW0_TOP_ADDRESS, 0, DMCUB_REGION3_CW0_TOP_ADDRESS, cw0->region.top, DMCUB_REGION3_CW0_ENABLE, 1); offset = cw1->offset; REG_WRITE(DMCUB_REGION3_CW1_OFFSET, offset.u.low_part); REG_WRITE(DMCUB_REGION3_CW1_OFFSET_HIGH, offset.u.high_part); REG_WRITE(DMCUB_REGION3_CW1_BASE_ADDRESS, cw1->region.base); REG_SET_2(DMCUB_REGION3_CW1_TOP_ADDRESS, 0, DMCUB_REGION3_CW1_TOP_ADDRESS, cw1->region.top, DMCUB_REGION3_CW1_ENABLE, 1); REG_UPDATE_2(DMCUB_SEC_CNTL, DMCUB_SEC_RESET, 0, DMCUB_MEM_UNIT_ID, 0x20); } void dmub_dcn32_setup_windows(struct dmub_srv *dmub, const struct dmub_window *cw2, const struct dmub_window *cw3, const struct dmub_window *cw4, const struct dmub_window *cw5, const struct dmub_window *cw6) { union dmub_addr offset; offset = cw3->offset; REG_WRITE(DMCUB_REGION3_CW3_OFFSET, offset.u.low_part); REG_WRITE(DMCUB_REGION3_CW3_OFFSET_HIGH, offset.u.high_part); REG_WRITE(DMCUB_REGION3_CW3_BASE_ADDRESS, cw3->region.base); REG_SET_2(DMCUB_REGION3_CW3_TOP_ADDRESS, 0, DMCUB_REGION3_CW3_TOP_ADDRESS, cw3->region.top, DMCUB_REGION3_CW3_ENABLE, 1); offset = cw4->offset; REG_WRITE(DMCUB_REGION3_CW4_OFFSET, offset.u.low_part); REG_WRITE(DMCUB_REGION3_CW4_OFFSET_HIGH, offset.u.high_part); REG_WRITE(DMCUB_REGION3_CW4_BASE_ADDRESS, cw4->region.base); REG_SET_2(DMCUB_REGION3_CW4_TOP_ADDRESS, 0, DMCUB_REGION3_CW4_TOP_ADDRESS, cw4->region.top, DMCUB_REGION3_CW4_ENABLE, 1); offset = cw5->offset; REG_WRITE(DMCUB_REGION3_CW5_OFFSET, offset.u.low_part); REG_WRITE(DMCUB_REGION3_CW5_OFFSET_HIGH, offset.u.high_part); REG_WRITE(DMCUB_REGION3_CW5_BASE_ADDRESS, cw5->region.base); REG_SET_2(DMCUB_REGION3_CW5_TOP_ADDRESS, 0, DMCUB_REGION3_CW5_TOP_ADDRESS, cw5->region.top, DMCUB_REGION3_CW5_ENABLE, 1); REG_WRITE(DMCUB_REGION5_OFFSET, offset.u.low_part); REG_WRITE(DMCUB_REGION5_OFFSET_HIGH, offset.u.high_part); REG_SET_2(DMCUB_REGION5_TOP_ADDRESS, 0, DMCUB_REGION5_TOP_ADDRESS, cw5->region.top - cw5->region.base - 1, DMCUB_REGION5_ENABLE, 1); offset = cw6->offset; REG_WRITE(DMCUB_REGION3_CW6_OFFSET, offset.u.low_part); REG_WRITE(DMCUB_REGION3_CW6_OFFSET_HIGH, offset.u.high_part); REG_WRITE(DMCUB_REGION3_CW6_BASE_ADDRESS, cw6->region.base); REG_SET_2(DMCUB_REGION3_CW6_TOP_ADDRESS, 0, DMCUB_REGION3_CW6_TOP_ADDRESS, cw6->region.top, DMCUB_REGION3_CW6_ENABLE, 1); } void dmub_dcn32_setup_mailbox(struct dmub_srv *dmub, const struct dmub_region *inbox1) { REG_WRITE(DMCUB_INBOX1_BASE_ADDRESS, inbox1->base); REG_WRITE(DMCUB_INBOX1_SIZE, inbox1->top - inbox1->base); } uint32_t dmub_dcn32_get_inbox1_rptr(struct dmub_srv *dmub) { return REG_READ(DMCUB_INBOX1_RPTR); } void dmub_dcn32_set_inbox1_wptr(struct dmub_srv *dmub, uint32_t wptr_offset) { REG_WRITE(DMCUB_INBOX1_WPTR, wptr_offset); } void dmub_dcn32_setup_out_mailbox(struct dmub_srv *dmub, const struct dmub_region *outbox1) { REG_WRITE(DMCUB_OUTBOX1_BASE_ADDRESS, outbox1->base); REG_WRITE(DMCUB_OUTBOX1_SIZE, outbox1->top - outbox1->base); } uint32_t dmub_dcn32_get_outbox1_wptr(struct dmub_srv *dmub) { /** * outbox1 wptr register is accessed without locks (dal & dc) * and to be called only by dmub_srv_stat_get_notification() */ return REG_READ(DMCUB_OUTBOX1_WPTR); } void dmub_dcn32_set_outbox1_rptr(struct dmub_srv *dmub, uint32_t rptr_offset) { /** * outbox1 rptr register is accessed without locks (dal & dc) * and to be called only by dmub_srv_stat_get_notification() */ REG_WRITE(DMCUB_OUTBOX1_RPTR, rptr_offset); } bool dmub_dcn32_is_hw_init(struct dmub_srv *dmub) { union dmub_fw_boot_status status; uint32_t is_hw_init; status.all = REG_READ(DMCUB_SCRATCH0); REG_GET(DMCUB_CNTL, DMCUB_ENABLE, &is_hw_init); return is_hw_init != 0 && status.bits.dal_fw; } bool dmub_dcn32_is_supported(struct dmub_srv *dmub) { uint32_t supported = 0; REG_GET(CC_DC_PIPE_DIS, DC_DMCUB_ENABLE, &supported); return supported; } void dmub_dcn32_set_gpint(struct dmub_srv *dmub, union dmub_gpint_data_register reg) { REG_WRITE(DMCUB_GPINT_DATAIN1, reg.all); } bool dmub_dcn32_is_gpint_acked(struct dmub_srv *dmub, union dmub_gpint_data_register reg) { union dmub_gpint_data_register test; reg.bits.status = 0; test.all = REG_READ(DMCUB_GPINT_DATAIN1); return test.all == reg.all; } uint32_t dmub_dcn32_get_gpint_response(struct dmub_srv *dmub) { return REG_READ(DMCUB_SCRATCH7); } uint32_t dmub_dcn32_get_gpint_dataout(struct dmub_srv *dmub) { uint32_t dataout = REG_READ(DMCUB_GPINT_DATAOUT); REG_UPDATE(DMCUB_INTERRUPT_ENABLE, DMCUB_GPINT_IH_INT_EN, 0); REG_WRITE(DMCUB_GPINT_DATAOUT, 0); REG_UPDATE(DMCUB_INTERRUPT_ACK, DMCUB_GPINT_IH_INT_ACK, 1); REG_UPDATE(DMCUB_INTERRUPT_ACK, DMCUB_GPINT_IH_INT_ACK, 0); REG_UPDATE(DMCUB_INTERRUPT_ENABLE, DMCUB_GPINT_IH_INT_EN, 1); return dataout; } union dmub_fw_boot_status dmub_dcn32_get_fw_boot_status(struct dmub_srv *dmub) { union dmub_fw_boot_status status; status.all = REG_READ(DMCUB_SCRATCH0); return status; } void dmub_dcn32_enable_dmub_boot_options(struct dmub_srv *dmub, const struct dmub_srv_hw_params *params) { union dmub_fw_boot_options boot_options = {0}; boot_options.bits.z10_disable = params->disable_z10; REG_WRITE(DMCUB_SCRATCH14, boot_options.all); } void dmub_dcn32_skip_dmub_panel_power_sequence(struct dmub_srv *dmub, bool skip) { union dmub_fw_boot_options boot_options; boot_options.all = REG_READ(DMCUB_SCRATCH14); boot_options.bits.skip_phy_init_panel_sequence = skip; REG_WRITE(DMCUB_SCRATCH14, boot_options.all); } void dmub_dcn32_setup_outbox0(struct dmub_srv *dmub, const struct dmub_region *outbox0) { REG_WRITE(DMCUB_OUTBOX0_BASE_ADDRESS, outbox0->base); REG_WRITE(DMCUB_OUTBOX0_SIZE, outbox0->top - outbox0->base); } uint32_t dmub_dcn32_get_outbox0_wptr(struct dmub_srv *dmub) { return REG_READ(DMCUB_OUTBOX0_WPTR); } void dmub_dcn32_set_outbox0_rptr(struct dmub_srv *dmub, uint32_t rptr_offset) { REG_WRITE(DMCUB_OUTBOX0_RPTR, rptr_offset); } uint32_t dmub_dcn32_get_current_time(struct dmub_srv *dmub) { return REG_READ(DMCUB_TIMER_CURRENT); } void dmub_dcn32_get_diagnostic_data(struct dmub_srv *dmub, struct dmub_diagnostic_data *diag_data) { uint32_t is_dmub_enabled, is_soft_reset, is_sec_reset; uint32_t is_traceport_enabled, is_cw0_enabled, is_cw6_enabled; if (!dmub || !diag_data) return; memset(diag_data, 0, sizeof(*diag_data)); diag_data->dmcub_version = dmub->fw_version; diag_data->scratch[0] = REG_READ(DMCUB_SCRATCH0); diag_data->scratch[1] = REG_READ(DMCUB_SCRATCH1); diag_data->scratch[2] = REG_READ(DMCUB_SCRATCH2); diag_data->scratch[3] = REG_READ(DMCUB_SCRATCH3); diag_data->scratch[4] = REG_READ(DMCUB_SCRATCH4); diag_data->scratch[5] = REG_READ(DMCUB_SCRATCH5); diag_data->scratch[6] = REG_READ(DMCUB_SCRATCH6); diag_data->scratch[7] = REG_READ(DMCUB_SCRATCH7); diag_data->scratch[8] = REG_READ(DMCUB_SCRATCH8); diag_data->scratch[9] = REG_READ(DMCUB_SCRATCH9); diag_data->scratch[10] = REG_READ(DMCUB_SCRATCH10); diag_data->scratch[11] = REG_READ(DMCUB_SCRATCH11); diag_data->scratch[12] = REG_READ(DMCUB_SCRATCH12); diag_data->scratch[13] = REG_READ(DMCUB_SCRATCH13); diag_data->scratch[14] = REG_READ(DMCUB_SCRATCH14); diag_data->scratch[15] = REG_READ(DMCUB_SCRATCH15); diag_data->undefined_address_fault_addr = REG_READ(DMCUB_UNDEFINED_ADDRESS_FAULT_ADDR); diag_data->inst_fetch_fault_addr = REG_READ(DMCUB_INST_FETCH_FAULT_ADDR); diag_data->data_write_fault_addr = REG_READ(DMCUB_DATA_WRITE_FAULT_ADDR); diag_data->inbox1_rptr = REG_READ(DMCUB_INBOX1_RPTR); diag_data->inbox1_wptr = REG_READ(DMCUB_INBOX1_WPTR); diag_data->inbox1_size = REG_READ(DMCUB_INBOX1_SIZE); diag_data->inbox0_rptr = REG_READ(DMCUB_INBOX0_RPTR); diag_data->inbox0_wptr = REG_READ(DMCUB_INBOX0_WPTR); diag_data->inbox0_size = REG_READ(DMCUB_INBOX0_SIZE); REG_GET(DMCUB_CNTL, DMCUB_ENABLE, &is_dmub_enabled); diag_data->is_dmcub_enabled = is_dmub_enabled; REG_GET(DMCUB_CNTL2, DMCUB_SOFT_RESET, &is_soft_reset); diag_data->is_dmcub_soft_reset = is_soft_reset; REG_GET(DMCUB_SEC_CNTL, DMCUB_SEC_RESET_STATUS, &is_sec_reset); diag_data->is_dmcub_secure_reset = is_sec_reset; REG_GET(DMCUB_CNTL, DMCUB_TRACEPORT_EN, &is_traceport_enabled); diag_data->is_traceport_en = is_traceport_enabled; REG_GET(DMCUB_REGION3_CW0_TOP_ADDRESS, DMCUB_REGION3_CW0_ENABLE, &is_cw0_enabled); diag_data->is_cw0_enabled = is_cw0_enabled; REG_GET(DMCUB_REGION3_CW6_TOP_ADDRESS, DMCUB_REGION3_CW6_ENABLE, &is_cw6_enabled); diag_data->is_cw6_enabled = is_cw6_enabled; } void dmub_dcn32_configure_dmub_in_system_memory(struct dmub_srv *dmub) { /* DMCUB_REGION3_TMR_AXI_SPACE values: * 0b011 (0x3) - FB physical address * 0b100 (0x4) - GPU virtual address * * Default value is 0x3 (FB Physical address for TMR). When programming * DMUB to be in system memory, change to 0x4. The system memory allocated * is accessible by both GPU and CPU, so we use GPU virtual address. */ REG_WRITE(DMCUB_REGION3_TMR_AXI_SPACE, 0x4); } void dmub_dcn32_send_inbox0_cmd(struct dmub_srv *dmub, union dmub_inbox0_data_register data) { REG_WRITE(DMCUB_INBOX0_WPTR, data.inbox0_cmd_common.all); } void dmub_dcn32_clear_inbox0_ack_register(struct dmub_srv *dmub) { REG_WRITE(DMCUB_SCRATCH17, 0); } uint32_t dmub_dcn32_read_inbox0_ack_register(struct dmub_srv *dmub) { return REG_READ(DMCUB_SCRATCH17); }
Information contained on this website is for historical information purposes only and does not indicate or represent copyright ownership.
Created with Cregit http://github.com/cregit/cregit
Version 2.0-RC1