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- A series of commits to make the MSR derived CPU and TSC frequency more accurate. It turned out that the frequency tables which have been taken from the SDM are inaccurate because the SDM provides truncated and rounded values, e.g. 83.3Mhz (83.3333...) or 116.7Mhz (116.6666...). This causes time drift in the range of ~1 second per hour (20-30 seconds per day). On some of these SoCs it's not possible to recalibrate the TSC because there is no reference (PIT, HPET) available. With some reverse engineering it was established that the possible frequencies are derived from the base clock with fixed multiplier / divider pairs. For the CPU models which have a known crystal frequency the kernel now uses multiplier / divider pairs which bring the frequencies closer to reality and fix the observed time drift issues. -----BEGIN PGP SIGNATURE----- iQJHBAABCgAxFiEEQp8+kY+LLUocC4bMphj1TA10mKEFAl6CApYTHHRnbHhAbGlu dXRyb25peC5kZQAKCRCmGPVMDXSYoRM4D/9/lgBQQQ+xilpYHLv4lk5ukmkrLEjt NqL0dZKthd2v4VoAViCZqCYUSuxmo9uGPCxC0Ol7MMB2mUHXrwPn5q2wwcHSE830 KQv8Dk9tCVeJMMTMk2s5t4QBYEHD95+ueObKK1sofz0NkQW3ea+cpRCh4jt2lrnw X7uT5rSHk87B1VYMPWzELsBEeqan9kUbvbe9se7My5utesOZumn4gj9rmO/5y9Vc rNuwGEZX8RpQAZZmfEJ00r5iA+VTdWyQ4rhktlQeeIdb4y4axjxMsWQIuaggjdyn oRA2vZnoc4+IqNUUBvj1q1D3RETwyf3WT+nxiYUdb3VuSh1o7he5MTzgznKzThnU s+ViOPXbfzrfUUW8dlk6zd5yovmIuQNb0Xk05USqAB3gVQS1fYPnyy+pb9dFDnnB 0zEq3RAQVCb/bkyWQ0JemgHXda3WTABZRCR812L2e+WZD6KjlqySkdeJJ+kxzQwN 6FRNrdtl+8ULy6SlWIC8y0yuVdSIFfgNSm+5HZMrw8VbqJp1ZVpTvKQ+xczjOunn z9y24IC1IlhtDsTMzIU0LHhgwhVGcohdTNbu3yX4hVQ7EgQOQPVE/XGM5RdjiXzq bD5j+PCntjoE7hnnxsPnuhDs9ZqNptTo4UevMwTL6rKAgJaPMAc9PB5LqdUynAEx hpkkMFGU7BSBDw== =9eX1 -----END PGP SIGNATURE----- Merge tag 'x86-timers-2020-03-30' of git://git.kernel.org/pub/scm/linux/kernel/git/tip/tip Pull x86 timer updates from Thomas Gleixner: "A series of commits to make the MSR derived CPU and TSC frequency more accurate. It turned out that the frequency tables which have been taken from the SDM are inaccurate because the SDM provides truncated and rounded values, e.g. 83.3Mhz (83.3333...) or 116.7Mhz (116.6666...). This causes time drift in the range of ~1 second per hour (20-30 seconds per day). On some of these SoCs it's not possible to recalibrate the TSC because there is no reference (PIT, HPET) available. With some reverse engineering it was established that the possible frequencies are derived from the base clock with fixed multiplier / divider pairs. For the CPU models which have a known crystal frequency the kernel now uses multiplier / divider pairs which bring the frequencies closer to reality and fix the observed time drift issues" * tag 'x86-timers-2020-03-30' of git://git.kernel.org/pub/scm/linux/kernel/git/tip/tip: x86/tsc_msr: Make MSR derived TSC frequency more accurate x86/tsc_msr: Fix MSR_FSB_FREQ mask for Cherry Trail devices x86/tsc_msr: Use named struct initializers
231 lines
6.9 KiB
C
231 lines
6.9 KiB
C
// SPDX-License-Identifier: GPL-2.0
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/*
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* TSC frequency enumeration via MSR
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*
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* Copyright (C) 2013, 2018 Intel Corporation
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* Author: Bin Gao <bin.gao@intel.com>
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*/
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#include <linux/kernel.h>
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#include <asm/apic.h>
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#include <asm/cpu_device_id.h>
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#include <asm/intel-family.h>
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#include <asm/msr.h>
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#include <asm/param.h>
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#include <asm/tsc.h>
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#define MAX_NUM_FREQS 16 /* 4 bits to select the frequency */
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/*
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* The frequency numbers in the SDM are e.g. 83.3 MHz, which does not contain a
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* lot of accuracy which leads to clock drift. As far as we know Bay Trail SoCs
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* use a 25 MHz crystal and Cherry Trail uses a 19.2 MHz crystal, the crystal
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* is the source clk for a root PLL which outputs 1600 and 100 MHz. It is
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* unclear if the root PLL outputs are used directly by the CPU clock PLL or
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* if there is another PLL in between.
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* This does not matter though, we can model the chain of PLLs as a single PLL
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* with a quotient equal to the quotients of all PLLs in the chain multiplied.
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* So we can create a simplified model of the CPU clock setup using a reference
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* clock of 100 MHz plus a quotient which gets us as close to the frequency
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* from the SDM as possible.
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* For the 83.3 MHz example from above this would give us 100 MHz * 5 / 6 =
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* 83 and 1/3 MHz, which matches exactly what has been measured on actual hw.
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*/
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#define TSC_REFERENCE_KHZ 100000
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struct muldiv {
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u32 multiplier;
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u32 divider;
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};
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/*
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* If MSR_PERF_STAT[31] is set, the maximum resolved bus ratio can be
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* read in MSR_PLATFORM_ID[12:8], otherwise in MSR_PERF_STAT[44:40].
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* Unfortunately some Intel Atom SoCs aren't quite compliant to this,
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* so we need manually differentiate SoC families. This is what the
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* field use_msr_plat does.
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*/
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struct freq_desc {
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bool use_msr_plat;
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struct muldiv muldiv[MAX_NUM_FREQS];
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/*
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* Some CPU frequencies in the SDM do not map to known PLL freqs, in
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* that case the muldiv array is empty and the freqs array is used.
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*/
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u32 freqs[MAX_NUM_FREQS];
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u32 mask;
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};
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/*
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* Penwell and Clovertrail use spread spectrum clock,
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* so the freq number is not exactly the same as reported
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* by MSR based on SDM.
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*/
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static const struct freq_desc freq_desc_pnw = {
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.use_msr_plat = false,
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.freqs = { 0, 0, 0, 0, 0, 99840, 0, 83200 },
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.mask = 0x07,
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};
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static const struct freq_desc freq_desc_clv = {
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.use_msr_plat = false,
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.freqs = { 0, 133200, 0, 0, 0, 99840, 0, 83200 },
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.mask = 0x07,
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};
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/*
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* Bay Trail SDM MSR_FSB_FREQ frequencies simplified PLL model:
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* 000: 100 * 5 / 6 = 83.3333 MHz
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* 001: 100 * 1 / 1 = 100.0000 MHz
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* 010: 100 * 4 / 3 = 133.3333 MHz
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* 011: 100 * 7 / 6 = 116.6667 MHz
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* 100: 100 * 4 / 5 = 80.0000 MHz
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*/
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static const struct freq_desc freq_desc_byt = {
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.use_msr_plat = true,
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.muldiv = { { 5, 6 }, { 1, 1 }, { 4, 3 }, { 7, 6 },
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{ 4, 5 } },
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.mask = 0x07,
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};
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/*
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* Cherry Trail SDM MSR_FSB_FREQ frequencies simplified PLL model:
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* 0000: 100 * 5 / 6 = 83.3333 MHz
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* 0001: 100 * 1 / 1 = 100.0000 MHz
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* 0010: 100 * 4 / 3 = 133.3333 MHz
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* 0011: 100 * 7 / 6 = 116.6667 MHz
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* 0100: 100 * 4 / 5 = 80.0000 MHz
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* 0101: 100 * 14 / 15 = 93.3333 MHz
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* 0110: 100 * 9 / 10 = 90.0000 MHz
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* 0111: 100 * 8 / 9 = 88.8889 MHz
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* 1000: 100 * 7 / 8 = 87.5000 MHz
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*/
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static const struct freq_desc freq_desc_cht = {
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.use_msr_plat = true,
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.muldiv = { { 5, 6 }, { 1, 1 }, { 4, 3 }, { 7, 6 },
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{ 4, 5 }, { 14, 15 }, { 9, 10 }, { 8, 9 },
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{ 7, 8 } },
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.mask = 0x0f,
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};
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/*
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* Merriefield SDM MSR_FSB_FREQ frequencies simplified PLL model:
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* 0001: 100 * 1 / 1 = 100.0000 MHz
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* 0010: 100 * 4 / 3 = 133.3333 MHz
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*/
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static const struct freq_desc freq_desc_tng = {
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.use_msr_plat = true,
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.muldiv = { { 0, 0 }, { 1, 1 }, { 4, 3 } },
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.mask = 0x07,
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};
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/*
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* Moorefield SDM MSR_FSB_FREQ frequencies simplified PLL model:
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* 0000: 100 * 5 / 6 = 83.3333 MHz
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* 0001: 100 * 1 / 1 = 100.0000 MHz
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* 0010: 100 * 4 / 3 = 133.3333 MHz
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* 0011: 100 * 1 / 1 = 100.0000 MHz
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*/
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static const struct freq_desc freq_desc_ann = {
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.use_msr_plat = true,
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.muldiv = { { 5, 6 }, { 1, 1 }, { 4, 3 }, { 1, 1 } },
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.mask = 0x0f,
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};
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/* 24 MHz crystal? : 24 * 13 / 4 = 78 MHz */
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static const struct freq_desc freq_desc_lgm = {
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.use_msr_plat = true,
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.freqs = { 78000, 78000, 78000, 78000, 78000, 78000, 78000, 78000 },
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.mask = 0x0f,
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};
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static const struct x86_cpu_id tsc_msr_cpu_ids[] = {
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X86_MATCH_INTEL_FAM6_MODEL(ATOM_SALTWELL_MID, &freq_desc_pnw),
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X86_MATCH_INTEL_FAM6_MODEL(ATOM_SALTWELL_TABLET,&freq_desc_clv),
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X86_MATCH_INTEL_FAM6_MODEL(ATOM_SILVERMONT, &freq_desc_byt),
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X86_MATCH_INTEL_FAM6_MODEL(ATOM_SILVERMONT_MID, &freq_desc_tng),
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X86_MATCH_INTEL_FAM6_MODEL(ATOM_AIRMONT, &freq_desc_cht),
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X86_MATCH_INTEL_FAM6_MODEL(ATOM_AIRMONT_MID, &freq_desc_ann),
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X86_MATCH_INTEL_FAM6_MODEL(ATOM_AIRMONT_NP, &freq_desc_lgm),
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{}
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};
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/*
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* MSR-based CPU/TSC frequency discovery for certain CPUs.
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*
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* Set global "lapic_timer_period" to bus_clock_cycles/jiffy
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* Return processor base frequency in KHz, or 0 on failure.
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*/
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unsigned long cpu_khz_from_msr(void)
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{
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u32 lo, hi, ratio, freq, tscref;
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const struct freq_desc *freq_desc;
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const struct x86_cpu_id *id;
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const struct muldiv *md;
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unsigned long res;
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int index;
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id = x86_match_cpu(tsc_msr_cpu_ids);
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if (!id)
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return 0;
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freq_desc = (struct freq_desc *)id->driver_data;
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if (freq_desc->use_msr_plat) {
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rdmsr(MSR_PLATFORM_INFO, lo, hi);
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ratio = (lo >> 8) & 0xff;
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} else {
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rdmsr(MSR_IA32_PERF_STATUS, lo, hi);
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ratio = (hi >> 8) & 0x1f;
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}
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/* Get FSB FREQ ID */
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rdmsr(MSR_FSB_FREQ, lo, hi);
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index = lo & freq_desc->mask;
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md = &freq_desc->muldiv[index];
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/*
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* Note this also catches cases where the index points to an unpopulated
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* part of muldiv, in that case the else will set freq and res to 0.
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*/
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if (md->divider) {
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tscref = TSC_REFERENCE_KHZ * md->multiplier;
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freq = DIV_ROUND_CLOSEST(tscref, md->divider);
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/*
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* Multiplying by ratio before the division has better
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* accuracy than just calculating freq * ratio.
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*/
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res = DIV_ROUND_CLOSEST(tscref * ratio, md->divider);
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} else {
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freq = freq_desc->freqs[index];
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res = freq * ratio;
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}
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if (freq == 0)
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pr_err("Error MSR_FSB_FREQ index %d is unknown\n", index);
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#ifdef CONFIG_X86_LOCAL_APIC
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lapic_timer_period = (freq * 1000) / HZ;
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#endif
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/*
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* TSC frequency determined by MSR is always considered "known"
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* because it is reported by HW.
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* Another fact is that on MSR capable platforms, PIT/HPET is
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* generally not available so calibration won't work at all.
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*/
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setup_force_cpu_cap(X86_FEATURE_TSC_KNOWN_FREQ);
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/*
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* Unfortunately there is no way for hardware to tell whether the
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* TSC is reliable. We were told by silicon design team that TSC
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* on Atom SoCs are always "reliable". TSC is also the only
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* reliable clocksource on these SoCs (HPET is either not present
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* or not functional) so mark TSC reliable which removes the
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* requirement for a watchdog clocksource.
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*/
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setup_force_cpu_cap(X86_FEATURE_TSC_RELIABLE);
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return res;
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}
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