forked from Minki/linux
195567e99b
drivers/gpu/drm/amd/amdgpu/../powerplay/hwmgr/ppatomctrl.c:475:10-11: WARNING: return of 0/1 in function 'atomctrl_lookup_gpio_pin' with return type bool Return statements in functions returning bool should use true/false instead of 1/0. Generated by: scripts/coccinelle/misc/boolreturn.cocci CC: yanyang1 <young.yang@amd.com> Signed-off-by: Fengguang Wu <fengguang.wu@intel.com> Signed-off-by: Alex Deucher <alexander.deucher@amd.com>
1208 lines
38 KiB
C
1208 lines
38 KiB
C
/*
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* Copyright 2015 Advanced Micro Devices, Inc.
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*
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* Permission is hereby granted, free of charge, to any person obtaining a
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* copy of this software and associated documentation files (the "Software"),
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* to deal in the Software without restriction, including without limitation
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* the rights to use, copy, modify, merge, publish, distribute, sublicense,
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* and/or sell copies of the Software, and to permit persons to whom the
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* Software is furnished to do so, subject to the following conditions:
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*
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* The above copyright notice and this permission notice shall be included in
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* all copies or substantial portions of the Software.
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*
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* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
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* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
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* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
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* THE COPYRIGHT HOLDER(S) OR AUTHOR(S) BE LIABLE FOR ANY CLAIM, DAMAGES OR
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* OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
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* ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
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* OTHER DEALINGS IN THE SOFTWARE.
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*
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*/
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#include <linux/module.h>
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#include <linux/slab.h>
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#include <linux/fb.h>
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#include "ppatomctrl.h"
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#include "atombios.h"
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#include "cgs_common.h"
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#include "pp_debug.h"
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#include "ppevvmath.h"
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#define MEM_ID_MASK 0xff000000
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#define MEM_ID_SHIFT 24
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#define CLOCK_RANGE_MASK 0x00ffffff
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#define CLOCK_RANGE_SHIFT 0
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#define LOW_NIBBLE_MASK 0xf
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#define DATA_EQU_PREV 0
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#define DATA_FROM_TABLE 4
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union voltage_object_info {
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struct _ATOM_VOLTAGE_OBJECT_INFO v1;
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struct _ATOM_VOLTAGE_OBJECT_INFO_V2 v2;
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struct _ATOM_VOLTAGE_OBJECT_INFO_V3_1 v3;
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};
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static int atomctrl_retrieve_ac_timing(
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uint8_t index,
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ATOM_INIT_REG_BLOCK *reg_block,
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pp_atomctrl_mc_reg_table *table)
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{
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uint32_t i, j;
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uint8_t tmem_id;
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ATOM_MEMORY_SETTING_DATA_BLOCK *reg_data = (ATOM_MEMORY_SETTING_DATA_BLOCK *)
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((uint8_t *)reg_block + (2 * sizeof(uint16_t)) + le16_to_cpu(reg_block->usRegIndexTblSize));
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uint8_t num_ranges = 0;
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while (*(uint32_t *)reg_data != END_OF_REG_DATA_BLOCK &&
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num_ranges < VBIOS_MAX_AC_TIMING_ENTRIES) {
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tmem_id = (uint8_t)((*(uint32_t *)reg_data & MEM_ID_MASK) >> MEM_ID_SHIFT);
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if (index == tmem_id) {
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table->mc_reg_table_entry[num_ranges].mclk_max =
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(uint32_t)((*(uint32_t *)reg_data & CLOCK_RANGE_MASK) >>
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CLOCK_RANGE_SHIFT);
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for (i = 0, j = 1; i < table->last; i++) {
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if ((table->mc_reg_address[i].uc_pre_reg_data &
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LOW_NIBBLE_MASK) == DATA_FROM_TABLE) {
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table->mc_reg_table_entry[num_ranges].mc_data[i] =
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(uint32_t)*((uint32_t *)reg_data + j);
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j++;
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} else if ((table->mc_reg_address[i].uc_pre_reg_data &
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LOW_NIBBLE_MASK) == DATA_EQU_PREV) {
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table->mc_reg_table_entry[num_ranges].mc_data[i] =
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table->mc_reg_table_entry[num_ranges].mc_data[i-1];
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}
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}
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num_ranges++;
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}
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reg_data = (ATOM_MEMORY_SETTING_DATA_BLOCK *)
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((uint8_t *)reg_data + le16_to_cpu(reg_block->usRegDataBlkSize)) ;
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}
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PP_ASSERT_WITH_CODE((*(uint32_t *)reg_data == END_OF_REG_DATA_BLOCK),
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"Invalid VramInfo table.", return -1);
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table->num_entries = num_ranges;
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return 0;
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}
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/**
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* Get memory clock AC timing registers index from VBIOS table
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* VBIOS set end of memory clock AC timing registers by ucPreRegDataLength bit6 = 1
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* @param reg_block the address ATOM_INIT_REG_BLOCK
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* @param table the address of MCRegTable
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* @return 0
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*/
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static int atomctrl_set_mc_reg_address_table(
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ATOM_INIT_REG_BLOCK *reg_block,
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pp_atomctrl_mc_reg_table *table)
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{
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uint8_t i = 0;
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uint8_t num_entries = (uint8_t)((le16_to_cpu(reg_block->usRegIndexTblSize))
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/ sizeof(ATOM_INIT_REG_INDEX_FORMAT));
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ATOM_INIT_REG_INDEX_FORMAT *format = ®_block->asRegIndexBuf[0];
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num_entries--; /* subtract 1 data end mark entry */
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PP_ASSERT_WITH_CODE((num_entries <= VBIOS_MC_REGISTER_ARRAY_SIZE),
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"Invalid VramInfo table.", return -1);
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/* ucPreRegDataLength bit6 = 1 is the end of memory clock AC timing registers */
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while ((!(format->ucPreRegDataLength & ACCESS_PLACEHOLDER)) &&
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(i < num_entries)) {
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table->mc_reg_address[i].s1 =
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(uint16_t)(le16_to_cpu(format->usRegIndex));
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table->mc_reg_address[i].uc_pre_reg_data =
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format->ucPreRegDataLength;
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i++;
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format = (ATOM_INIT_REG_INDEX_FORMAT *)
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((uint8_t *)format + sizeof(ATOM_INIT_REG_INDEX_FORMAT));
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}
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table->last = i;
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return 0;
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}
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int atomctrl_initialize_mc_reg_table(
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struct pp_hwmgr *hwmgr,
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uint8_t module_index,
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pp_atomctrl_mc_reg_table *table)
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{
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ATOM_VRAM_INFO_HEADER_V2_1 *vram_info;
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ATOM_INIT_REG_BLOCK *reg_block;
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int result = 0;
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u8 frev, crev;
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u16 size;
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vram_info = (ATOM_VRAM_INFO_HEADER_V2_1 *)
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cgs_atom_get_data_table(hwmgr->device,
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GetIndexIntoMasterTable(DATA, VRAM_Info), &size, &frev, &crev);
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if (module_index >= vram_info->ucNumOfVRAMModule) {
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printk(KERN_ERR "[ powerplay ] Invalid VramInfo table.");
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result = -1;
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} else if (vram_info->sHeader.ucTableFormatRevision < 2) {
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printk(KERN_ERR "[ powerplay ] Invalid VramInfo table.");
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result = -1;
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}
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if (0 == result) {
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reg_block = (ATOM_INIT_REG_BLOCK *)
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((uint8_t *)vram_info + le16_to_cpu(vram_info->usMemClkPatchTblOffset));
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result = atomctrl_set_mc_reg_address_table(reg_block, table);
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}
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if (0 == result) {
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result = atomctrl_retrieve_ac_timing(module_index,
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reg_block, table);
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}
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return result;
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}
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/**
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* Set DRAM timings based on engine clock and memory clock.
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*/
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int atomctrl_set_engine_dram_timings_rv770(
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struct pp_hwmgr *hwmgr,
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uint32_t engine_clock,
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uint32_t memory_clock)
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{
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SET_ENGINE_CLOCK_PS_ALLOCATION engine_clock_parameters;
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/* They are both in 10KHz Units. */
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engine_clock_parameters.ulTargetEngineClock =
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(uint32_t) engine_clock & SET_CLOCK_FREQ_MASK;
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engine_clock_parameters.ulTargetEngineClock |=
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(COMPUTE_ENGINE_PLL_PARAM << 24);
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/* in 10 khz units.*/
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engine_clock_parameters.sReserved.ulClock =
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(uint32_t) memory_clock & SET_CLOCK_FREQ_MASK;
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return cgs_atom_exec_cmd_table(hwmgr->device,
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GetIndexIntoMasterTable(COMMAND, DynamicMemorySettings),
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&engine_clock_parameters);
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}
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/**
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* Private Function to get the PowerPlay Table Address.
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* WARNING: The tabled returned by this function is in
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* dynamically allocated memory.
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* The caller has to release if by calling kfree.
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*/
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static ATOM_VOLTAGE_OBJECT_INFO *get_voltage_info_table(void *device)
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{
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int index = GetIndexIntoMasterTable(DATA, VoltageObjectInfo);
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u8 frev, crev;
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u16 size;
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union voltage_object_info *voltage_info;
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voltage_info = (union voltage_object_info *)
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cgs_atom_get_data_table(device, index,
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&size, &frev, &crev);
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if (voltage_info != NULL)
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return (ATOM_VOLTAGE_OBJECT_INFO *) &(voltage_info->v3);
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else
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return NULL;
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}
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static const ATOM_VOLTAGE_OBJECT_V3 *atomctrl_lookup_voltage_type_v3(
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const ATOM_VOLTAGE_OBJECT_INFO_V3_1 * voltage_object_info_table,
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uint8_t voltage_type, uint8_t voltage_mode)
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{
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unsigned int size = le16_to_cpu(voltage_object_info_table->sHeader.usStructureSize);
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unsigned int offset = offsetof(ATOM_VOLTAGE_OBJECT_INFO_V3_1, asVoltageObj[0]);
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uint8_t *start = (uint8_t *)voltage_object_info_table;
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while (offset < size) {
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const ATOM_VOLTAGE_OBJECT_V3 *voltage_object =
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(const ATOM_VOLTAGE_OBJECT_V3 *)(start + offset);
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if (voltage_type == voltage_object->asGpioVoltageObj.sHeader.ucVoltageType &&
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voltage_mode == voltage_object->asGpioVoltageObj.sHeader.ucVoltageMode)
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return voltage_object;
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offset += le16_to_cpu(voltage_object->asGpioVoltageObj.sHeader.usSize);
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}
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return NULL;
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}
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/** atomctrl_get_memory_pll_dividers_si().
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*
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* @param hwmgr input parameter: pointer to HwMgr
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* @param clock_value input parameter: memory clock
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* @param dividers output parameter: memory PLL dividers
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* @param strobe_mode input parameter: 1 for strobe mode, 0 for performance mode
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*/
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int atomctrl_get_memory_pll_dividers_si(
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struct pp_hwmgr *hwmgr,
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uint32_t clock_value,
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pp_atomctrl_memory_clock_param *mpll_param,
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bool strobe_mode)
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{
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COMPUTE_MEMORY_CLOCK_PARAM_PARAMETERS_V2_1 mpll_parameters;
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int result;
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mpll_parameters.ulClock = (uint32_t) clock_value;
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mpll_parameters.ucInputFlag = (uint8_t)((strobe_mode) ? 1 : 0);
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result = cgs_atom_exec_cmd_table
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(hwmgr->device,
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GetIndexIntoMasterTable(COMMAND, ComputeMemoryClockParam),
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&mpll_parameters);
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if (0 == result) {
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mpll_param->mpll_fb_divider.clk_frac =
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mpll_parameters.ulFbDiv.usFbDivFrac;
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mpll_param->mpll_fb_divider.cl_kf =
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mpll_parameters.ulFbDiv.usFbDiv;
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mpll_param->mpll_post_divider =
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(uint32_t)mpll_parameters.ucPostDiv;
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mpll_param->vco_mode =
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(uint32_t)(mpll_parameters.ucPllCntlFlag &
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MPLL_CNTL_FLAG_VCO_MODE_MASK);
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mpll_param->yclk_sel =
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(uint32_t)((mpll_parameters.ucPllCntlFlag &
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MPLL_CNTL_FLAG_BYPASS_DQ_PLL) ? 1 : 0);
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mpll_param->qdr =
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(uint32_t)((mpll_parameters.ucPllCntlFlag &
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MPLL_CNTL_FLAG_QDR_ENABLE) ? 1 : 0);
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mpll_param->half_rate =
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(uint32_t)((mpll_parameters.ucPllCntlFlag &
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MPLL_CNTL_FLAG_AD_HALF_RATE) ? 1 : 0);
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mpll_param->dll_speed =
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(uint32_t)(mpll_parameters.ucDllSpeed);
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mpll_param->bw_ctrl =
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(uint32_t)(mpll_parameters.ucBWCntl);
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}
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return result;
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}
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/** atomctrl_get_memory_pll_dividers_vi().
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*
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* @param hwmgr input parameter: pointer to HwMgr
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* @param clock_value input parameter: memory clock
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* @param dividers output parameter: memory PLL dividers
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*/
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int atomctrl_get_memory_pll_dividers_vi(struct pp_hwmgr *hwmgr,
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uint32_t clock_value, pp_atomctrl_memory_clock_param *mpll_param)
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{
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COMPUTE_MEMORY_CLOCK_PARAM_PARAMETERS_V2_2 mpll_parameters;
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int result;
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mpll_parameters.ulClock.ulClock = (uint32_t)clock_value;
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result = cgs_atom_exec_cmd_table(hwmgr->device,
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GetIndexIntoMasterTable(COMMAND, ComputeMemoryClockParam),
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&mpll_parameters);
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if (!result)
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mpll_param->mpll_post_divider =
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(uint32_t)mpll_parameters.ulClock.ucPostDiv;
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return result;
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}
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int atomctrl_get_engine_pll_dividers_kong(struct pp_hwmgr *hwmgr,
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uint32_t clock_value,
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pp_atomctrl_clock_dividers_kong *dividers)
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{
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COMPUTE_MEMORY_ENGINE_PLL_PARAMETERS_V4 pll_parameters;
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int result;
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pll_parameters.ulClock = clock_value;
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result = cgs_atom_exec_cmd_table
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(hwmgr->device,
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GetIndexIntoMasterTable(COMMAND, ComputeMemoryEnginePLL),
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&pll_parameters);
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if (0 == result) {
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dividers->pll_post_divider = pll_parameters.ucPostDiv;
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dividers->real_clock = pll_parameters.ulClock;
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}
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return result;
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}
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int atomctrl_get_engine_pll_dividers_vi(
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struct pp_hwmgr *hwmgr,
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uint32_t clock_value,
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pp_atomctrl_clock_dividers_vi *dividers)
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{
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COMPUTE_GPU_CLOCK_OUTPUT_PARAMETERS_V1_6 pll_patameters;
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int result;
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pll_patameters.ulClock.ulClock = clock_value;
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pll_patameters.ulClock.ucPostDiv = COMPUTE_GPUCLK_INPUT_FLAG_SCLK;
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result = cgs_atom_exec_cmd_table
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(hwmgr->device,
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GetIndexIntoMasterTable(COMMAND, ComputeMemoryEnginePLL),
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&pll_patameters);
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if (0 == result) {
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dividers->pll_post_divider =
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pll_patameters.ulClock.ucPostDiv;
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dividers->real_clock =
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pll_patameters.ulClock.ulClock;
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dividers->ul_fb_div.ul_fb_div_frac =
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pll_patameters.ulFbDiv.usFbDivFrac;
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dividers->ul_fb_div.ul_fb_div =
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pll_patameters.ulFbDiv.usFbDiv;
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dividers->uc_pll_ref_div =
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pll_patameters.ucPllRefDiv;
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dividers->uc_pll_post_div =
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pll_patameters.ucPllPostDiv;
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dividers->uc_pll_cntl_flag =
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pll_patameters.ucPllCntlFlag;
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}
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return result;
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}
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int atomctrl_get_dfs_pll_dividers_vi(
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struct pp_hwmgr *hwmgr,
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uint32_t clock_value,
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pp_atomctrl_clock_dividers_vi *dividers)
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{
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COMPUTE_GPU_CLOCK_OUTPUT_PARAMETERS_V1_6 pll_patameters;
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int result;
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pll_patameters.ulClock.ulClock = clock_value;
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pll_patameters.ulClock.ucPostDiv =
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COMPUTE_GPUCLK_INPUT_FLAG_DEFAULT_GPUCLK;
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result = cgs_atom_exec_cmd_table
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(hwmgr->device,
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GetIndexIntoMasterTable(COMMAND, ComputeMemoryEnginePLL),
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&pll_patameters);
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if (0 == result) {
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dividers->pll_post_divider =
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pll_patameters.ulClock.ucPostDiv;
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dividers->real_clock =
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pll_patameters.ulClock.ulClock;
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dividers->ul_fb_div.ul_fb_div_frac =
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pll_patameters.ulFbDiv.usFbDivFrac;
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dividers->ul_fb_div.ul_fb_div =
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pll_patameters.ulFbDiv.usFbDiv;
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dividers->uc_pll_ref_div =
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pll_patameters.ucPllRefDiv;
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dividers->uc_pll_post_div =
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pll_patameters.ucPllPostDiv;
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dividers->uc_pll_cntl_flag =
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pll_patameters.ucPllCntlFlag;
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}
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return result;
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}
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/**
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* Get the reference clock in 10KHz
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*/
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uint32_t atomctrl_get_reference_clock(struct pp_hwmgr *hwmgr)
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{
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ATOM_FIRMWARE_INFO *fw_info;
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u8 frev, crev;
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u16 size;
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uint32_t clock;
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fw_info = (ATOM_FIRMWARE_INFO *)
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cgs_atom_get_data_table(hwmgr->device,
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GetIndexIntoMasterTable(DATA, FirmwareInfo),
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&size, &frev, &crev);
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if (fw_info == NULL)
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clock = 2700;
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else
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clock = (uint32_t)(le16_to_cpu(fw_info->usReferenceClock));
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return clock;
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}
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/**
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* Returns true if the given voltage type is controlled by GPIO pins.
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* voltage_type is one of SET_VOLTAGE_TYPE_ASIC_VDDC,
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* SET_VOLTAGE_TYPE_ASIC_MVDDC, SET_VOLTAGE_TYPE_ASIC_MVDDQ.
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* voltage_mode is one of ATOM_SET_VOLTAGE, ATOM_SET_VOLTAGE_PHASE
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*/
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bool atomctrl_is_voltage_controled_by_gpio_v3(
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struct pp_hwmgr *hwmgr,
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uint8_t voltage_type,
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uint8_t voltage_mode)
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{
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ATOM_VOLTAGE_OBJECT_INFO_V3_1 *voltage_info =
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(ATOM_VOLTAGE_OBJECT_INFO_V3_1 *)get_voltage_info_table(hwmgr->device);
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bool ret;
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|
|
PP_ASSERT_WITH_CODE((NULL != voltage_info),
|
|
"Could not find Voltage Table in BIOS.", return false;);
|
|
|
|
ret = (NULL != atomctrl_lookup_voltage_type_v3
|
|
(voltage_info, voltage_type, voltage_mode)) ? true : false;
|
|
|
|
return ret;
|
|
}
|
|
|
|
int atomctrl_get_voltage_table_v3(
|
|
struct pp_hwmgr *hwmgr,
|
|
uint8_t voltage_type,
|
|
uint8_t voltage_mode,
|
|
pp_atomctrl_voltage_table *voltage_table)
|
|
{
|
|
ATOM_VOLTAGE_OBJECT_INFO_V3_1 *voltage_info =
|
|
(ATOM_VOLTAGE_OBJECT_INFO_V3_1 *)get_voltage_info_table(hwmgr->device);
|
|
const ATOM_VOLTAGE_OBJECT_V3 *voltage_object;
|
|
unsigned int i;
|
|
|
|
PP_ASSERT_WITH_CODE((NULL != voltage_info),
|
|
"Could not find Voltage Table in BIOS.", return -1;);
|
|
|
|
voltage_object = atomctrl_lookup_voltage_type_v3
|
|
(voltage_info, voltage_type, voltage_mode);
|
|
|
|
if (voltage_object == NULL)
|
|
return -1;
|
|
|
|
PP_ASSERT_WITH_CODE(
|
|
(voltage_object->asGpioVoltageObj.ucGpioEntryNum <=
|
|
PP_ATOMCTRL_MAX_VOLTAGE_ENTRIES),
|
|
"Too many voltage entries!",
|
|
return -1;
|
|
);
|
|
|
|
for (i = 0; i < voltage_object->asGpioVoltageObj.ucGpioEntryNum; i++) {
|
|
voltage_table->entries[i].value =
|
|
voltage_object->asGpioVoltageObj.asVolGpioLut[i].usVoltageValue;
|
|
voltage_table->entries[i].smio_low =
|
|
voltage_object->asGpioVoltageObj.asVolGpioLut[i].ulVoltageId;
|
|
}
|
|
|
|
voltage_table->mask_low =
|
|
voltage_object->asGpioVoltageObj.ulGpioMaskVal;
|
|
voltage_table->count =
|
|
voltage_object->asGpioVoltageObj.ucGpioEntryNum;
|
|
voltage_table->phase_delay =
|
|
voltage_object->asGpioVoltageObj.ucPhaseDelay;
|
|
|
|
return 0;
|
|
}
|
|
|
|
static bool atomctrl_lookup_gpio_pin(
|
|
ATOM_GPIO_PIN_LUT * gpio_lookup_table,
|
|
const uint32_t pinId,
|
|
pp_atomctrl_gpio_pin_assignment *gpio_pin_assignment)
|
|
{
|
|
unsigned int size = le16_to_cpu(gpio_lookup_table->sHeader.usStructureSize);
|
|
unsigned int offset = offsetof(ATOM_GPIO_PIN_LUT, asGPIO_Pin[0]);
|
|
uint8_t *start = (uint8_t *)gpio_lookup_table;
|
|
|
|
while (offset < size) {
|
|
const ATOM_GPIO_PIN_ASSIGNMENT *pin_assignment =
|
|
(const ATOM_GPIO_PIN_ASSIGNMENT *)(start + offset);
|
|
|
|
if (pinId == pin_assignment->ucGPIO_ID) {
|
|
gpio_pin_assignment->uc_gpio_pin_bit_shift =
|
|
pin_assignment->ucGpioPinBitShift;
|
|
gpio_pin_assignment->us_gpio_pin_aindex =
|
|
le16_to_cpu(pin_assignment->usGpioPin_AIndex);
|
|
return false;
|
|
}
|
|
|
|
offset += offsetof(ATOM_GPIO_PIN_ASSIGNMENT, ucGPIO_ID) + 1;
|
|
}
|
|
|
|
return true;
|
|
}
|
|
|
|
/**
|
|
* Private Function to get the PowerPlay Table Address.
|
|
* WARNING: The tabled returned by this function is in
|
|
* dynamically allocated memory.
|
|
* The caller has to release if by calling kfree.
|
|
*/
|
|
static ATOM_GPIO_PIN_LUT *get_gpio_lookup_table(void *device)
|
|
{
|
|
u8 frev, crev;
|
|
u16 size;
|
|
void *table_address;
|
|
|
|
table_address = (ATOM_GPIO_PIN_LUT *)
|
|
cgs_atom_get_data_table(device,
|
|
GetIndexIntoMasterTable(DATA, GPIO_Pin_LUT),
|
|
&size, &frev, &crev);
|
|
|
|
PP_ASSERT_WITH_CODE((NULL != table_address),
|
|
"Error retrieving BIOS Table Address!", return NULL;);
|
|
|
|
return (ATOM_GPIO_PIN_LUT *)table_address;
|
|
}
|
|
|
|
/**
|
|
* Returns 1 if the given pin id find in lookup table.
|
|
*/
|
|
bool atomctrl_get_pp_assign_pin(
|
|
struct pp_hwmgr *hwmgr,
|
|
const uint32_t pinId,
|
|
pp_atomctrl_gpio_pin_assignment *gpio_pin_assignment)
|
|
{
|
|
bool bRet = 0;
|
|
ATOM_GPIO_PIN_LUT *gpio_lookup_table =
|
|
get_gpio_lookup_table(hwmgr->device);
|
|
|
|
PP_ASSERT_WITH_CODE((NULL != gpio_lookup_table),
|
|
"Could not find GPIO lookup Table in BIOS.", return -1);
|
|
|
|
bRet = atomctrl_lookup_gpio_pin(gpio_lookup_table, pinId,
|
|
gpio_pin_assignment);
|
|
|
|
return bRet;
|
|
}
|
|
|
|
int atomctrl_calculate_voltage_evv_on_sclk(
|
|
struct pp_hwmgr *hwmgr,
|
|
uint8_t voltage_type,
|
|
uint32_t sclk,
|
|
uint16_t virtual_voltage_Id,
|
|
uint16_t *voltage,
|
|
uint16_t dpm_level,
|
|
bool debug)
|
|
{
|
|
ATOM_ASIC_PROFILING_INFO_V3_4 *getASICProfilingInfo;
|
|
|
|
EFUSE_LINEAR_FUNC_PARAM sRO_fuse;
|
|
EFUSE_LINEAR_FUNC_PARAM sCACm_fuse;
|
|
EFUSE_LINEAR_FUNC_PARAM sCACb_fuse;
|
|
EFUSE_LOGISTIC_FUNC_PARAM sKt_Beta_fuse;
|
|
EFUSE_LOGISTIC_FUNC_PARAM sKv_m_fuse;
|
|
EFUSE_LOGISTIC_FUNC_PARAM sKv_b_fuse;
|
|
EFUSE_INPUT_PARAMETER sInput_FuseValues;
|
|
READ_EFUSE_VALUE_PARAMETER sOutput_FuseValues;
|
|
|
|
uint32_t ul_RO_fused, ul_CACb_fused, ul_CACm_fused, ul_Kt_Beta_fused, ul_Kv_m_fused, ul_Kv_b_fused;
|
|
fInt fSM_A0, fSM_A1, fSM_A2, fSM_A3, fSM_A4, fSM_A5, fSM_A6, fSM_A7;
|
|
fInt fMargin_RO_a, fMargin_RO_b, fMargin_RO_c, fMargin_fixed, fMargin_FMAX_mean, fMargin_Plat_mean, fMargin_FMAX_sigma, fMargin_Plat_sigma, fMargin_DC_sigma;
|
|
fInt fLkg_FT, repeat;
|
|
fInt fMicro_FMAX, fMicro_CR, fSigma_FMAX, fSigma_CR, fSigma_DC, fDC_SCLK, fSquared_Sigma_DC, fSquared_Sigma_CR, fSquared_Sigma_FMAX;
|
|
fInt fRLL_LoadLine, fPowerDPMx, fDerateTDP, fVDDC_base, fA_Term, fC_Term, fB_Term, fRO_DC_margin;
|
|
fInt fRO_fused, fCACm_fused, fCACb_fused, fKv_m_fused, fKv_b_fused, fKt_Beta_fused, fFT_Lkg_V0NORM;
|
|
fInt fSclk_margin, fSclk, fEVV_V;
|
|
fInt fV_min, fV_max, fT_prod, fLKG_Factor, fT_FT, fV_FT, fV_x, fTDP_Power, fTDP_Power_right, fTDP_Power_left, fTDP_Current, fV_NL;
|
|
uint32_t ul_FT_Lkg_V0NORM;
|
|
fInt fLn_MaxDivMin, fMin, fAverage, fRange;
|
|
fInt fRoots[2];
|
|
fInt fStepSize = GetScaledFraction(625, 100000);
|
|
|
|
int result;
|
|
|
|
getASICProfilingInfo = (ATOM_ASIC_PROFILING_INFO_V3_4 *)
|
|
cgs_atom_get_data_table(hwmgr->device,
|
|
GetIndexIntoMasterTable(DATA, ASIC_ProfilingInfo),
|
|
NULL, NULL, NULL);
|
|
|
|
if (!getASICProfilingInfo)
|
|
return -1;
|
|
|
|
if(getASICProfilingInfo->asHeader.ucTableFormatRevision < 3 ||
|
|
(getASICProfilingInfo->asHeader.ucTableFormatRevision == 3 &&
|
|
getASICProfilingInfo->asHeader.ucTableContentRevision < 4))
|
|
return -1;
|
|
|
|
/*-----------------------------------------------------------
|
|
*GETTING MULTI-STEP PARAMETERS RELATED TO CURRENT DPM LEVEL
|
|
*-----------------------------------------------------------
|
|
*/
|
|
fRLL_LoadLine = Divide(getASICProfilingInfo->ulLoadLineSlop, 1000);
|
|
|
|
switch (dpm_level) {
|
|
case 1:
|
|
fPowerDPMx = Convert_ULONG_ToFraction(getASICProfilingInfo->usPowerDpm1);
|
|
fDerateTDP = GetScaledFraction(getASICProfilingInfo->ulTdpDerateDPM1, 1000);
|
|
break;
|
|
case 2:
|
|
fPowerDPMx = Convert_ULONG_ToFraction(getASICProfilingInfo->usPowerDpm2);
|
|
fDerateTDP = GetScaledFraction(getASICProfilingInfo->ulTdpDerateDPM2, 1000);
|
|
break;
|
|
case 3:
|
|
fPowerDPMx = Convert_ULONG_ToFraction(getASICProfilingInfo->usPowerDpm3);
|
|
fDerateTDP = GetScaledFraction(getASICProfilingInfo->ulTdpDerateDPM3, 1000);
|
|
break;
|
|
case 4:
|
|
fPowerDPMx = Convert_ULONG_ToFraction(getASICProfilingInfo->usPowerDpm4);
|
|
fDerateTDP = GetScaledFraction(getASICProfilingInfo->ulTdpDerateDPM4, 1000);
|
|
break;
|
|
case 5:
|
|
fPowerDPMx = Convert_ULONG_ToFraction(getASICProfilingInfo->usPowerDpm5);
|
|
fDerateTDP = GetScaledFraction(getASICProfilingInfo->ulTdpDerateDPM5, 1000);
|
|
break;
|
|
case 6:
|
|
fPowerDPMx = Convert_ULONG_ToFraction(getASICProfilingInfo->usPowerDpm6);
|
|
fDerateTDP = GetScaledFraction(getASICProfilingInfo->ulTdpDerateDPM6, 1000);
|
|
break;
|
|
case 7:
|
|
fPowerDPMx = Convert_ULONG_ToFraction(getASICProfilingInfo->usPowerDpm7);
|
|
fDerateTDP = GetScaledFraction(getASICProfilingInfo->ulTdpDerateDPM7, 1000);
|
|
break;
|
|
default:
|
|
printk(KERN_ERR "DPM Level not supported\n");
|
|
fPowerDPMx = Convert_ULONG_ToFraction(1);
|
|
fDerateTDP = GetScaledFraction(getASICProfilingInfo->ulTdpDerateDPM0, 1000);
|
|
}
|
|
|
|
/*-------------------------
|
|
* DECODING FUSE VALUES
|
|
* ------------------------
|
|
*/
|
|
/*Decode RO_Fused*/
|
|
sRO_fuse = getASICProfilingInfo->sRoFuse;
|
|
|
|
sInput_FuseValues.usEfuseIndex = sRO_fuse.usEfuseIndex;
|
|
sInput_FuseValues.ucBitShift = sRO_fuse.ucEfuseBitLSB;
|
|
sInput_FuseValues.ucBitLength = sRO_fuse.ucEfuseLength;
|
|
|
|
sOutput_FuseValues.sEfuse = sInput_FuseValues;
|
|
|
|
result = cgs_atom_exec_cmd_table(hwmgr->device,
|
|
GetIndexIntoMasterTable(COMMAND, ReadEfuseValue),
|
|
&sOutput_FuseValues);
|
|
|
|
if (result)
|
|
return result;
|
|
|
|
/* Finally, the actual fuse value */
|
|
ul_RO_fused = sOutput_FuseValues.ulEfuseValue;
|
|
fMin = GetScaledFraction(sRO_fuse.ulEfuseMin, 1);
|
|
fRange = GetScaledFraction(sRO_fuse.ulEfuseEncodeRange, 1);
|
|
fRO_fused = fDecodeLinearFuse(ul_RO_fused, fMin, fRange, sRO_fuse.ucEfuseLength);
|
|
|
|
sCACm_fuse = getASICProfilingInfo->sCACm;
|
|
|
|
sInput_FuseValues.usEfuseIndex = sCACm_fuse.usEfuseIndex;
|
|
sInput_FuseValues.ucBitShift = sCACm_fuse.ucEfuseBitLSB;
|
|
sInput_FuseValues.ucBitLength = sCACm_fuse.ucEfuseLength;
|
|
|
|
sOutput_FuseValues.sEfuse = sInput_FuseValues;
|
|
|
|
result = cgs_atom_exec_cmd_table(hwmgr->device,
|
|
GetIndexIntoMasterTable(COMMAND, ReadEfuseValue),
|
|
&sOutput_FuseValues);
|
|
|
|
if (result)
|
|
return result;
|
|
|
|
ul_CACm_fused = sOutput_FuseValues.ulEfuseValue;
|
|
fMin = GetScaledFraction(sCACm_fuse.ulEfuseMin, 1000);
|
|
fRange = GetScaledFraction(sCACm_fuse.ulEfuseEncodeRange, 1000);
|
|
|
|
fCACm_fused = fDecodeLinearFuse(ul_CACm_fused, fMin, fRange, sCACm_fuse.ucEfuseLength);
|
|
|
|
sCACb_fuse = getASICProfilingInfo->sCACb;
|
|
|
|
sInput_FuseValues.usEfuseIndex = sCACb_fuse.usEfuseIndex;
|
|
sInput_FuseValues.ucBitShift = sCACb_fuse.ucEfuseBitLSB;
|
|
sInput_FuseValues.ucBitLength = sCACb_fuse.ucEfuseLength;
|
|
sOutput_FuseValues.sEfuse = sInput_FuseValues;
|
|
|
|
result = cgs_atom_exec_cmd_table(hwmgr->device,
|
|
GetIndexIntoMasterTable(COMMAND, ReadEfuseValue),
|
|
&sOutput_FuseValues);
|
|
|
|
if (result)
|
|
return result;
|
|
|
|
ul_CACb_fused = sOutput_FuseValues.ulEfuseValue;
|
|
fMin = GetScaledFraction(sCACb_fuse.ulEfuseMin, 1000);
|
|
fRange = GetScaledFraction(sCACb_fuse.ulEfuseEncodeRange, 1000);
|
|
|
|
fCACb_fused = fDecodeLinearFuse(ul_CACb_fused, fMin, fRange, sCACb_fuse.ucEfuseLength);
|
|
|
|
sKt_Beta_fuse = getASICProfilingInfo->sKt_b;
|
|
|
|
sInput_FuseValues.usEfuseIndex = sKt_Beta_fuse.usEfuseIndex;
|
|
sInput_FuseValues.ucBitShift = sKt_Beta_fuse.ucEfuseBitLSB;
|
|
sInput_FuseValues.ucBitLength = sKt_Beta_fuse.ucEfuseLength;
|
|
|
|
sOutput_FuseValues.sEfuse = sInput_FuseValues;
|
|
|
|
result = cgs_atom_exec_cmd_table(hwmgr->device,
|
|
GetIndexIntoMasterTable(COMMAND, ReadEfuseValue),
|
|
&sOutput_FuseValues);
|
|
|
|
if (result)
|
|
return result;
|
|
|
|
ul_Kt_Beta_fused = sOutput_FuseValues.ulEfuseValue;
|
|
fAverage = GetScaledFraction(sKt_Beta_fuse.ulEfuseEncodeAverage, 1000);
|
|
fRange = GetScaledFraction(sKt_Beta_fuse.ulEfuseEncodeRange, 1000);
|
|
|
|
fKt_Beta_fused = fDecodeLogisticFuse(ul_Kt_Beta_fused,
|
|
fAverage, fRange, sKt_Beta_fuse.ucEfuseLength);
|
|
|
|
sKv_m_fuse = getASICProfilingInfo->sKv_m;
|
|
|
|
sInput_FuseValues.usEfuseIndex = sKv_m_fuse.usEfuseIndex;
|
|
sInput_FuseValues.ucBitShift = sKv_m_fuse.ucEfuseBitLSB;
|
|
sInput_FuseValues.ucBitLength = sKv_m_fuse.ucEfuseLength;
|
|
|
|
sOutput_FuseValues.sEfuse = sInput_FuseValues;
|
|
|
|
result = cgs_atom_exec_cmd_table(hwmgr->device,
|
|
GetIndexIntoMasterTable(COMMAND, ReadEfuseValue),
|
|
&sOutput_FuseValues);
|
|
if (result)
|
|
return result;
|
|
|
|
ul_Kv_m_fused = sOutput_FuseValues.ulEfuseValue;
|
|
fAverage = GetScaledFraction(sKv_m_fuse.ulEfuseEncodeAverage, 1000);
|
|
fRange = GetScaledFraction((sKv_m_fuse.ulEfuseEncodeRange & 0x7fffffff), 1000);
|
|
fRange = fMultiply(fRange, ConvertToFraction(-1));
|
|
|
|
fKv_m_fused = fDecodeLogisticFuse(ul_Kv_m_fused,
|
|
fAverage, fRange, sKv_m_fuse.ucEfuseLength);
|
|
|
|
sKv_b_fuse = getASICProfilingInfo->sKv_b;
|
|
|
|
sInput_FuseValues.usEfuseIndex = sKv_b_fuse.usEfuseIndex;
|
|
sInput_FuseValues.ucBitShift = sKv_b_fuse.ucEfuseBitLSB;
|
|
sInput_FuseValues.ucBitLength = sKv_b_fuse.ucEfuseLength;
|
|
sOutput_FuseValues.sEfuse = sInput_FuseValues;
|
|
|
|
result = cgs_atom_exec_cmd_table(hwmgr->device,
|
|
GetIndexIntoMasterTable(COMMAND, ReadEfuseValue),
|
|
&sOutput_FuseValues);
|
|
|
|
if (result)
|
|
return result;
|
|
|
|
ul_Kv_b_fused = sOutput_FuseValues.ulEfuseValue;
|
|
fAverage = GetScaledFraction(sKv_b_fuse.ulEfuseEncodeAverage, 1000);
|
|
fRange = GetScaledFraction(sKv_b_fuse.ulEfuseEncodeRange, 1000);
|
|
|
|
fKv_b_fused = fDecodeLogisticFuse(ul_Kv_b_fused,
|
|
fAverage, fRange, sKv_b_fuse.ucEfuseLength);
|
|
|
|
/* Decoding the Leakage - No special struct container */
|
|
/*
|
|
* usLkgEuseIndex=56
|
|
* ucLkgEfuseBitLSB=6
|
|
* ucLkgEfuseLength=10
|
|
* ulLkgEncodeLn_MaxDivMin=69077
|
|
* ulLkgEncodeMax=1000000
|
|
* ulLkgEncodeMin=1000
|
|
* ulEfuseLogisticAlpha=13
|
|
*/
|
|
|
|
sInput_FuseValues.usEfuseIndex = getASICProfilingInfo->usLkgEuseIndex;
|
|
sInput_FuseValues.ucBitShift = getASICProfilingInfo->ucLkgEfuseBitLSB;
|
|
sInput_FuseValues.ucBitLength = getASICProfilingInfo->ucLkgEfuseLength;
|
|
|
|
sOutput_FuseValues.sEfuse = sInput_FuseValues;
|
|
|
|
result = cgs_atom_exec_cmd_table(hwmgr->device,
|
|
GetIndexIntoMasterTable(COMMAND, ReadEfuseValue),
|
|
&sOutput_FuseValues);
|
|
|
|
if (result)
|
|
return result;
|
|
|
|
ul_FT_Lkg_V0NORM = sOutput_FuseValues.ulEfuseValue;
|
|
fLn_MaxDivMin = GetScaledFraction(getASICProfilingInfo->ulLkgEncodeLn_MaxDivMin, 10000);
|
|
fMin = GetScaledFraction(getASICProfilingInfo->ulLkgEncodeMin, 10000);
|
|
|
|
fFT_Lkg_V0NORM = fDecodeLeakageID(ul_FT_Lkg_V0NORM,
|
|
fLn_MaxDivMin, fMin, getASICProfilingInfo->ucLkgEfuseLength);
|
|
fLkg_FT = fFT_Lkg_V0NORM;
|
|
|
|
/*-------------------------------------------
|
|
* PART 2 - Grabbing all required values
|
|
*-------------------------------------------
|
|
*/
|
|
fSM_A0 = fMultiply(GetScaledFraction(getASICProfilingInfo->ulSM_A0, 1000000),
|
|
ConvertToFraction(uPow(-1, getASICProfilingInfo->ucSM_A0_sign)));
|
|
fSM_A1 = fMultiply(GetScaledFraction(getASICProfilingInfo->ulSM_A1, 1000000),
|
|
ConvertToFraction(uPow(-1, getASICProfilingInfo->ucSM_A1_sign)));
|
|
fSM_A2 = fMultiply(GetScaledFraction(getASICProfilingInfo->ulSM_A2, 100000),
|
|
ConvertToFraction(uPow(-1, getASICProfilingInfo->ucSM_A2_sign)));
|
|
fSM_A3 = fMultiply(GetScaledFraction(getASICProfilingInfo->ulSM_A3, 1000000),
|
|
ConvertToFraction(uPow(-1, getASICProfilingInfo->ucSM_A3_sign)));
|
|
fSM_A4 = fMultiply(GetScaledFraction(getASICProfilingInfo->ulSM_A4, 1000000),
|
|
ConvertToFraction(uPow(-1, getASICProfilingInfo->ucSM_A4_sign)));
|
|
fSM_A5 = fMultiply(GetScaledFraction(getASICProfilingInfo->ulSM_A5, 1000),
|
|
ConvertToFraction(uPow(-1, getASICProfilingInfo->ucSM_A5_sign)));
|
|
fSM_A6 = fMultiply(GetScaledFraction(getASICProfilingInfo->ulSM_A6, 1000),
|
|
ConvertToFraction(uPow(-1, getASICProfilingInfo->ucSM_A6_sign)));
|
|
fSM_A7 = fMultiply(GetScaledFraction(getASICProfilingInfo->ulSM_A7, 1000),
|
|
ConvertToFraction(uPow(-1, getASICProfilingInfo->ucSM_A7_sign)));
|
|
|
|
fMargin_RO_a = ConvertToFraction(getASICProfilingInfo->ulMargin_RO_a);
|
|
fMargin_RO_b = ConvertToFraction(getASICProfilingInfo->ulMargin_RO_b);
|
|
fMargin_RO_c = ConvertToFraction(getASICProfilingInfo->ulMargin_RO_c);
|
|
|
|
fMargin_fixed = ConvertToFraction(getASICProfilingInfo->ulMargin_fixed);
|
|
|
|
fMargin_FMAX_mean = GetScaledFraction(
|
|
getASICProfilingInfo->ulMargin_Fmax_mean, 10000);
|
|
fMargin_Plat_mean = GetScaledFraction(
|
|
getASICProfilingInfo->ulMargin_plat_mean, 10000);
|
|
fMargin_FMAX_sigma = GetScaledFraction(
|
|
getASICProfilingInfo->ulMargin_Fmax_sigma, 10000);
|
|
fMargin_Plat_sigma = GetScaledFraction(
|
|
getASICProfilingInfo->ulMargin_plat_sigma, 10000);
|
|
|
|
fMargin_DC_sigma = GetScaledFraction(
|
|
getASICProfilingInfo->ulMargin_DC_sigma, 100);
|
|
fMargin_DC_sigma = fDivide(fMargin_DC_sigma, ConvertToFraction(1000));
|
|
|
|
fCACm_fused = fDivide(fCACm_fused, ConvertToFraction(100));
|
|
fCACb_fused = fDivide(fCACb_fused, ConvertToFraction(100));
|
|
fKt_Beta_fused = fDivide(fKt_Beta_fused, ConvertToFraction(100));
|
|
fKv_m_fused = fNegate(fDivide(fKv_m_fused, ConvertToFraction(100)));
|
|
fKv_b_fused = fDivide(fKv_b_fused, ConvertToFraction(10));
|
|
|
|
fSclk = GetScaledFraction(sclk, 100);
|
|
|
|
fV_max = fDivide(GetScaledFraction(
|
|
getASICProfilingInfo->ulMaxVddc, 1000), ConvertToFraction(4));
|
|
fT_prod = GetScaledFraction(getASICProfilingInfo->ulBoardCoreTemp, 10);
|
|
fLKG_Factor = GetScaledFraction(getASICProfilingInfo->ulEvvLkgFactor, 100);
|
|
fT_FT = GetScaledFraction(getASICProfilingInfo->ulLeakageTemp, 10);
|
|
fV_FT = fDivide(GetScaledFraction(
|
|
getASICProfilingInfo->ulLeakageVoltage, 1000), ConvertToFraction(4));
|
|
fV_min = fDivide(GetScaledFraction(
|
|
getASICProfilingInfo->ulMinVddc, 1000), ConvertToFraction(4));
|
|
|
|
/*-----------------------
|
|
* PART 3
|
|
*-----------------------
|
|
*/
|
|
|
|
fA_Term = fAdd(fMargin_RO_a, fAdd(fMultiply(fSM_A4,fSclk), fSM_A5));
|
|
fB_Term = fAdd(fAdd(fMultiply(fSM_A2, fSclk), fSM_A6), fMargin_RO_b);
|
|
fC_Term = fAdd(fMargin_RO_c,
|
|
fAdd(fMultiply(fSM_A0,fLkg_FT),
|
|
fAdd(fMultiply(fSM_A1, fMultiply(fLkg_FT,fSclk)),
|
|
fAdd(fMultiply(fSM_A3, fSclk),
|
|
fSubtract(fSM_A7,fRO_fused)))));
|
|
|
|
fVDDC_base = fSubtract(fRO_fused,
|
|
fSubtract(fMargin_RO_c,
|
|
fSubtract(fSM_A3, fMultiply(fSM_A1, fSclk))));
|
|
fVDDC_base = fDivide(fVDDC_base, fAdd(fMultiply(fSM_A0,fSclk), fSM_A2));
|
|
|
|
repeat = fSubtract(fVDDC_base,
|
|
fDivide(fMargin_DC_sigma, ConvertToFraction(1000)));
|
|
|
|
fRO_DC_margin = fAdd(fMultiply(fMargin_RO_a,
|
|
fGetSquare(repeat)),
|
|
fAdd(fMultiply(fMargin_RO_b, repeat),
|
|
fMargin_RO_c));
|
|
|
|
fDC_SCLK = fSubtract(fRO_fused,
|
|
fSubtract(fRO_DC_margin,
|
|
fSubtract(fSM_A3,
|
|
fMultiply(fSM_A2, repeat))));
|
|
fDC_SCLK = fDivide(fDC_SCLK, fAdd(fMultiply(fSM_A0,repeat), fSM_A1));
|
|
|
|
fSigma_DC = fSubtract(fSclk, fDC_SCLK);
|
|
|
|
fMicro_FMAX = fMultiply(fSclk, fMargin_FMAX_mean);
|
|
fMicro_CR = fMultiply(fSclk, fMargin_Plat_mean);
|
|
fSigma_FMAX = fMultiply(fSclk, fMargin_FMAX_sigma);
|
|
fSigma_CR = fMultiply(fSclk, fMargin_Plat_sigma);
|
|
|
|
fSquared_Sigma_DC = fGetSquare(fSigma_DC);
|
|
fSquared_Sigma_CR = fGetSquare(fSigma_CR);
|
|
fSquared_Sigma_FMAX = fGetSquare(fSigma_FMAX);
|
|
|
|
fSclk_margin = fAdd(fMicro_FMAX,
|
|
fAdd(fMicro_CR,
|
|
fAdd(fMargin_fixed,
|
|
fSqrt(fAdd(fSquared_Sigma_FMAX,
|
|
fAdd(fSquared_Sigma_DC, fSquared_Sigma_CR))))));
|
|
/*
|
|
fA_Term = fSM_A4 * (fSclk + fSclk_margin) + fSM_A5;
|
|
fB_Term = fSM_A2 * (fSclk + fSclk_margin) + fSM_A6;
|
|
fC_Term = fRO_DC_margin + fSM_A0 * fLkg_FT + fSM_A1 * fLkg_FT * (fSclk + fSclk_margin) + fSM_A3 * (fSclk + fSclk_margin) + fSM_A7 - fRO_fused;
|
|
*/
|
|
|
|
fA_Term = fAdd(fMultiply(fSM_A4, fAdd(fSclk, fSclk_margin)), fSM_A5);
|
|
fB_Term = fAdd(fMultiply(fSM_A2, fAdd(fSclk, fSclk_margin)), fSM_A6);
|
|
fC_Term = fAdd(fRO_DC_margin,
|
|
fAdd(fMultiply(fSM_A0, fLkg_FT),
|
|
fAdd(fMultiply(fMultiply(fSM_A1, fLkg_FT),
|
|
fAdd(fSclk, fSclk_margin)),
|
|
fAdd(fMultiply(fSM_A3,
|
|
fAdd(fSclk, fSclk_margin)),
|
|
fSubtract(fSM_A7, fRO_fused)))));
|
|
|
|
SolveQuadracticEqn(fA_Term, fB_Term, fC_Term, fRoots);
|
|
|
|
if (GreaterThan(fRoots[0], fRoots[1]))
|
|
fEVV_V = fRoots[1];
|
|
else
|
|
fEVV_V = fRoots[0];
|
|
|
|
if (GreaterThan(fV_min, fEVV_V))
|
|
fEVV_V = fV_min;
|
|
else if (GreaterThan(fEVV_V, fV_max))
|
|
fEVV_V = fSubtract(fV_max, fStepSize);
|
|
|
|
fEVV_V = fRoundUpByStepSize(fEVV_V, fStepSize, 0);
|
|
|
|
/*-----------------
|
|
* PART 4
|
|
*-----------------
|
|
*/
|
|
|
|
fV_x = fV_min;
|
|
|
|
while (GreaterThan(fAdd(fV_max, fStepSize), fV_x)) {
|
|
fTDP_Power_left = fMultiply(fMultiply(fMultiply(fAdd(
|
|
fMultiply(fCACm_fused, fV_x), fCACb_fused), fSclk),
|
|
fGetSquare(fV_x)), fDerateTDP);
|
|
|
|
fTDP_Power_right = fMultiply(fFT_Lkg_V0NORM, fMultiply(fLKG_Factor,
|
|
fMultiply(fExponential(fMultiply(fAdd(fMultiply(fKv_m_fused,
|
|
fT_prod), fKv_b_fused), fV_x)), fV_x)));
|
|
fTDP_Power_right = fMultiply(fTDP_Power_right, fExponential(fMultiply(
|
|
fKt_Beta_fused, fT_prod)));
|
|
fTDP_Power_right = fDivide(fTDP_Power_right, fExponential(fMultiply(
|
|
fAdd(fMultiply(fKv_m_fused, fT_prod), fKv_b_fused), fV_FT)));
|
|
fTDP_Power_right = fDivide(fTDP_Power_right, fExponential(fMultiply(
|
|
fKt_Beta_fused, fT_FT)));
|
|
|
|
fTDP_Power = fAdd(fTDP_Power_left, fTDP_Power_right);
|
|
|
|
fTDP_Current = fDivide(fTDP_Power, fV_x);
|
|
|
|
fV_NL = fAdd(fV_x, fDivide(fMultiply(fTDP_Current, fRLL_LoadLine),
|
|
ConvertToFraction(10)));
|
|
|
|
fV_NL = fRoundUpByStepSize(fV_NL, fStepSize, 0);
|
|
|
|
if (GreaterThan(fV_max, fV_NL) &&
|
|
(GreaterThan(fV_NL,fEVV_V) ||
|
|
Equal(fV_NL, fEVV_V))) {
|
|
fV_NL = fMultiply(fV_NL, ConvertToFraction(1000));
|
|
|
|
*voltage = (uint16_t)fV_NL.partial.real;
|
|
break;
|
|
} else
|
|
fV_x = fAdd(fV_x, fStepSize);
|
|
}
|
|
|
|
return result;
|
|
}
|
|
|
|
/** atomctrl_get_voltage_evv_on_sclk gets voltage via call to ATOM COMMAND table.
|
|
* @param hwmgr input: pointer to hwManager
|
|
* @param voltage_type input: type of EVV voltage VDDC or VDDGFX
|
|
* @param sclk input: in 10Khz unit. DPM state SCLK frequency
|
|
* which is define in PPTable SCLK/VDDC dependence
|
|
* table associated with this virtual_voltage_Id
|
|
* @param virtual_voltage_Id input: voltage id which match per voltage DPM state: 0xff01, 0xff02.. 0xff08
|
|
* @param voltage output: real voltage level in unit of mv
|
|
*/
|
|
int atomctrl_get_voltage_evv_on_sclk(
|
|
struct pp_hwmgr *hwmgr,
|
|
uint8_t voltage_type,
|
|
uint32_t sclk, uint16_t virtual_voltage_Id,
|
|
uint16_t *voltage)
|
|
{
|
|
int result;
|
|
GET_VOLTAGE_INFO_INPUT_PARAMETER_V1_2 get_voltage_info_param_space;
|
|
|
|
get_voltage_info_param_space.ucVoltageType =
|
|
voltage_type;
|
|
get_voltage_info_param_space.ucVoltageMode =
|
|
ATOM_GET_VOLTAGE_EVV_VOLTAGE;
|
|
get_voltage_info_param_space.usVoltageLevel =
|
|
virtual_voltage_Id;
|
|
get_voltage_info_param_space.ulSCLKFreq =
|
|
sclk;
|
|
|
|
result = cgs_atom_exec_cmd_table(hwmgr->device,
|
|
GetIndexIntoMasterTable(COMMAND, GetVoltageInfo),
|
|
&get_voltage_info_param_space);
|
|
|
|
if (0 != result)
|
|
return result;
|
|
|
|
*voltage = ((GET_EVV_VOLTAGE_INFO_OUTPUT_PARAMETER_V1_2 *)
|
|
(&get_voltage_info_param_space))->usVoltageLevel;
|
|
|
|
return result;
|
|
}
|
|
|
|
/**
|
|
* Get the mpll reference clock in 10KHz
|
|
*/
|
|
uint32_t atomctrl_get_mpll_reference_clock(struct pp_hwmgr *hwmgr)
|
|
{
|
|
ATOM_COMMON_TABLE_HEADER *fw_info;
|
|
uint32_t clock;
|
|
u8 frev, crev;
|
|
u16 size;
|
|
|
|
fw_info = (ATOM_COMMON_TABLE_HEADER *)
|
|
cgs_atom_get_data_table(hwmgr->device,
|
|
GetIndexIntoMasterTable(DATA, FirmwareInfo),
|
|
&size, &frev, &crev);
|
|
|
|
if (fw_info == NULL)
|
|
clock = 2700;
|
|
else {
|
|
if ((fw_info->ucTableFormatRevision == 2) &&
|
|
(le16_to_cpu(fw_info->usStructureSize) >= sizeof(ATOM_FIRMWARE_INFO_V2_1))) {
|
|
ATOM_FIRMWARE_INFO_V2_1 *fwInfo_2_1 =
|
|
(ATOM_FIRMWARE_INFO_V2_1 *)fw_info;
|
|
clock = (uint32_t)(le16_to_cpu(fwInfo_2_1->usMemoryReferenceClock));
|
|
} else {
|
|
ATOM_FIRMWARE_INFO *fwInfo_0_0 =
|
|
(ATOM_FIRMWARE_INFO *)fw_info;
|
|
clock = (uint32_t)(le16_to_cpu(fwInfo_0_0->usReferenceClock));
|
|
}
|
|
}
|
|
|
|
return clock;
|
|
}
|
|
|
|
/**
|
|
* Get the asic internal spread spectrum table
|
|
*/
|
|
static ATOM_ASIC_INTERNAL_SS_INFO *asic_internal_ss_get_ss_table(void *device)
|
|
{
|
|
ATOM_ASIC_INTERNAL_SS_INFO *table = NULL;
|
|
u8 frev, crev;
|
|
u16 size;
|
|
|
|
table = (ATOM_ASIC_INTERNAL_SS_INFO *)
|
|
cgs_atom_get_data_table(device,
|
|
GetIndexIntoMasterTable(DATA, ASIC_InternalSS_Info),
|
|
&size, &frev, &crev);
|
|
|
|
return table;
|
|
}
|
|
|
|
/**
|
|
* Get the asic internal spread spectrum assignment
|
|
*/
|
|
static int asic_internal_ss_get_ss_asignment(struct pp_hwmgr *hwmgr,
|
|
const uint8_t clockSource,
|
|
const uint32_t clockSpeed,
|
|
pp_atomctrl_internal_ss_info *ssEntry)
|
|
{
|
|
ATOM_ASIC_INTERNAL_SS_INFO *table;
|
|
ATOM_ASIC_SS_ASSIGNMENT *ssInfo;
|
|
int entry_found = 0;
|
|
|
|
memset(ssEntry, 0x00, sizeof(pp_atomctrl_internal_ss_info));
|
|
|
|
table = asic_internal_ss_get_ss_table(hwmgr->device);
|
|
|
|
if (NULL == table)
|
|
return -1;
|
|
|
|
ssInfo = &table->asSpreadSpectrum[0];
|
|
|
|
while (((uint8_t *)ssInfo - (uint8_t *)table) <
|
|
le16_to_cpu(table->sHeader.usStructureSize)) {
|
|
if ((clockSource == ssInfo->ucClockIndication) &&
|
|
((uint32_t)clockSpeed <= le32_to_cpu(ssInfo->ulTargetClockRange))) {
|
|
entry_found = 1;
|
|
break;
|
|
}
|
|
|
|
ssInfo = (ATOM_ASIC_SS_ASSIGNMENT *)((uint8_t *)ssInfo +
|
|
sizeof(ATOM_ASIC_SS_ASSIGNMENT));
|
|
}
|
|
|
|
if (entry_found) {
|
|
ssEntry->speed_spectrum_percentage =
|
|
ssInfo->usSpreadSpectrumPercentage;
|
|
ssEntry->speed_spectrum_rate = ssInfo->usSpreadRateInKhz;
|
|
|
|
if (((GET_DATA_TABLE_MAJOR_REVISION(table) == 2) &&
|
|
(GET_DATA_TABLE_MINOR_REVISION(table) >= 2)) ||
|
|
(GET_DATA_TABLE_MAJOR_REVISION(table) == 3)) {
|
|
ssEntry->speed_spectrum_rate /= 100;
|
|
}
|
|
|
|
switch (ssInfo->ucSpreadSpectrumMode) {
|
|
case 0:
|
|
ssEntry->speed_spectrum_mode =
|
|
pp_atomctrl_spread_spectrum_mode_down;
|
|
break;
|
|
case 1:
|
|
ssEntry->speed_spectrum_mode =
|
|
pp_atomctrl_spread_spectrum_mode_center;
|
|
break;
|
|
default:
|
|
ssEntry->speed_spectrum_mode =
|
|
pp_atomctrl_spread_spectrum_mode_down;
|
|
break;
|
|
}
|
|
}
|
|
|
|
return entry_found ? 0 : 1;
|
|
}
|
|
|
|
/**
|
|
* Get the memory clock spread spectrum info
|
|
*/
|
|
int atomctrl_get_memory_clock_spread_spectrum(
|
|
struct pp_hwmgr *hwmgr,
|
|
const uint32_t memory_clock,
|
|
pp_atomctrl_internal_ss_info *ssInfo)
|
|
{
|
|
return asic_internal_ss_get_ss_asignment(hwmgr,
|
|
ASIC_INTERNAL_MEMORY_SS, memory_clock, ssInfo);
|
|
}
|
|
/**
|
|
* Get the engine clock spread spectrum info
|
|
*/
|
|
int atomctrl_get_engine_clock_spread_spectrum(
|
|
struct pp_hwmgr *hwmgr,
|
|
const uint32_t engine_clock,
|
|
pp_atomctrl_internal_ss_info *ssInfo)
|
|
{
|
|
return asic_internal_ss_get_ss_asignment(hwmgr,
|
|
ASIC_INTERNAL_ENGINE_SS, engine_clock, ssInfo);
|
|
}
|
|
|
|
int atomctrl_read_efuse(void *device, uint16_t start_index,
|
|
uint16_t end_index, uint32_t mask, uint32_t *efuse)
|
|
{
|
|
int result;
|
|
READ_EFUSE_VALUE_PARAMETER efuse_param;
|
|
|
|
efuse_param.sEfuse.usEfuseIndex = (start_index / 32) * 4;
|
|
efuse_param.sEfuse.ucBitShift = (uint8_t)
|
|
(start_index - ((start_index / 32) * 32));
|
|
efuse_param.sEfuse.ucBitLength = (uint8_t)
|
|
((end_index - start_index) + 1);
|
|
|
|
result = cgs_atom_exec_cmd_table(device,
|
|
GetIndexIntoMasterTable(COMMAND, ReadEfuseValue),
|
|
&efuse_param);
|
|
if (!result)
|
|
*efuse = efuse_param.ulEfuseValue & mask;
|
|
|
|
return result;
|
|
}
|