CloverBootloader/UefiCpuPkg/Library/CpuTimerLib/CpuTimerLib.c

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/** @file
CPUID Leaf 0x15 for Core Crystal Clock frequency instance of Timer Library.
Copyright (c) 2019 Intel Corporation. All rights reserved.<BR>
SPDX-License-Identifier: BSD-2-Clause-Patent
**/
#include <Base.h>
#include <Library/TimerLib.h>
#include <Library/BaseLib.h>
#include <Library/PcdLib.h>
#include <Library/DebugLib.h>
#include <Register/Cpuid.h>
GUID mCpuCrystalFrequencyHobGuid = { 0xe1ec5ad0, 0x8569, 0x46bd, { 0x8d, 0xcd, 0x3b, 0x9f, 0x6f, 0x45, 0x82, 0x7a } };
/**
Internal function to retrieves the 64-bit frequency in Hz.
Internal function to retrieves the 64-bit frequency in Hz.
@return The frequency in Hz.
**/
UINT64
InternalGetPerformanceCounterFrequency (
VOID
);
/**
CPUID Leaf 0x15 for Core Crystal Clock Frequency.
The TSC counting frequency is determined by using CPUID leaf 0x15. Frequency in MHz = Core XTAL frequency * EBX/EAX.
In newer flavors of the CPU, core xtal frequency is returned in ECX or 0 if not supported.
@return The number of TSC counts per second.
**/
UINT64
CpuidCoreClockCalculateTscFrequency (
VOID
)
{
UINT64 TscFrequency;
UINT64 CoreXtalFrequency;
UINT32 RegEax;
UINT32 RegEbx;
UINT32 RegEcx;
//
// Use CPUID leaf 0x15 Time Stamp Counter and Nominal Core Crystal Clock Information
// EBX returns 0 if not supported. ECX, if non zero, provides Core Xtal Frequency in hertz.
// TSC frequency = (ECX, Core Xtal Frequency) * EBX/EAX.
//
AsmCpuid (CPUID_TIME_STAMP_COUNTER, &RegEax, &RegEbx, &RegEcx, NULL);
//
// If EAX or EBX returns 0, the XTAL ratio is not enumerated.
//
if (RegEax == 0 || RegEbx ==0 ) {
ASSERT (RegEax != 0);
ASSERT (RegEbx != 0);
return 0;
}
//
// If ECX returns 0, the XTAL frequency is not enumerated.
// And PcdCpuCoreCrystalClockFrequency defined should base on processor series.
//
if (RegEcx == 0) {
CoreXtalFrequency = PcdGet64 (PcdCpuCoreCrystalClockFrequency);
} else {
CoreXtalFrequency = (UINT64) RegEcx;
}
//
// Calculate TSC frequency = (ECX, Core Xtal Frequency) * EBX/EAX
//
TscFrequency = DivU64x32 (MultU64x32 (CoreXtalFrequency, RegEbx) + (UINT64)(RegEax >> 1), RegEax);
return TscFrequency;
}
/**
Stalls the CPU for at least the given number of ticks.
Stalls the CPU for at least the given number of ticks. It's invoked by
MicroSecondDelay() and NanoSecondDelay().
@param Delay A period of time to delay in ticks.
**/
VOID
InternalCpuDelay (
IN UINT64 Delay
)
{
UINT64 Ticks;
//
// The target timer count is calculated here
//
Ticks = AsmReadTsc() + Delay;
//
// Wait until time out
// Timer wrap-arounds are NOT handled correctly by this function.
// Thus, this function must be called within 10 years of reset since
// Intel guarantees a minimum of 10 years before the TSC wraps.
//
while (AsmReadTsc() <= Ticks) {
CpuPause();
}
}
/**
Stalls the CPU for at least the given number of microseconds.
Stalls the CPU for the number of microseconds specified by MicroSeconds.
@param[in] MicroSeconds The minimum number of microseconds to delay.
@return MicroSeconds
**/
UINTN
EFIAPI
MicroSecondDelay (
IN UINTN MicroSeconds
)
{
InternalCpuDelay (
DivU64x32 (
MultU64x64 (
MicroSeconds,
InternalGetPerformanceCounterFrequency ()
),
1000000u
)
);
return MicroSeconds;
}
/**
Stalls the CPU for at least the given number of nanoseconds.
Stalls the CPU for the number of nanoseconds specified by NanoSeconds.
@param NanoSeconds The minimum number of nanoseconds to delay.
@return NanoSeconds
**/
UINTN
EFIAPI
NanoSecondDelay (
IN UINTN NanoSeconds
)
{
InternalCpuDelay (
DivU64x32 (
MultU64x64 (
NanoSeconds,
InternalGetPerformanceCounterFrequency ()
),
1000000000u
)
);
return NanoSeconds;
}
/**
Retrieves the current value of a 64-bit free running performance counter.
Retrieves the current value of a 64-bit free running performance counter. The
counter can either count up by 1 or count down by 1. If the physical
performance counter counts by a larger increment, then the counter values
must be translated. The properties of the counter can be retrieved from
GetPerformanceCounterProperties().
@return The current value of the free running performance counter.
**/
UINT64
EFIAPI
GetPerformanceCounter (
VOID
)
{
return AsmReadTsc ();
}
/**
Retrieves the 64-bit frequency in Hz and the range of performance counter
values.
If StartValue is not NULL, then the value that the performance counter starts
with immediately after is it rolls over is returned in StartValue. If
EndValue is not NULL, then the value that the performance counter end with
immediately before it rolls over is returned in EndValue. The 64-bit
frequency of the performance counter in Hz is always returned. If StartValue
is less than EndValue, then the performance counter counts up. If StartValue
is greater than EndValue, then the performance counter counts down. For
example, a 64-bit free running counter that counts up would have a StartValue
of 0 and an EndValue of 0xFFFFFFFFFFFFFFFF. A 24-bit free running counter
that counts down would have a StartValue of 0xFFFFFF and an EndValue of 0.
@param StartValue The value the performance counter starts with when it
rolls over.
@param EndValue The value that the performance counter ends with before
it rolls over.
@return The frequency in Hz.
**/
UINT64
EFIAPI
GetPerformanceCounterProperties (
OUT UINT64 *StartValue, OPTIONAL
OUT UINT64 *EndValue OPTIONAL
)
{
if (StartValue != NULL) {
*StartValue = 0;
}
if (EndValue != NULL) {
*EndValue = 0xffffffffffffffffULL;
}
return InternalGetPerformanceCounterFrequency ();
}
/**
Converts elapsed ticks of performance counter to time in nanoseconds.
This function converts the elapsed ticks of running performance counter to
time value in unit of nanoseconds.
@param Ticks The number of elapsed ticks of running performance counter.
@return The elapsed time in nanoseconds.
**/
UINT64
EFIAPI
GetTimeInNanoSecond (
IN UINT64 Ticks
)
{
UINT64 Frequency;
UINT64 NanoSeconds;
UINT64 Remainder;
INTN Shift;
Frequency = GetPerformanceCounterProperties (NULL, NULL);
//
// Ticks
// Time = --------- x 1,000,000,000
// Frequency
//
NanoSeconds = MultU64x32 (DivU64x64Remainder (Ticks, Frequency, &Remainder), 1000000000u);
//
// Ensure (Remainder * 1,000,000,000) will not overflow 64-bit.
// Since 2^29 < 1,000,000,000 = 0x3B9ACA00 < 2^30, Remainder should < 2^(64-30) = 2^34,
// i.e. highest bit set in Remainder should <= 33.
//
Shift = MAX (0, HighBitSet64 (Remainder) - 33);
Remainder = RShiftU64 (Remainder, (UINTN) Shift);
Frequency = RShiftU64 (Frequency, (UINTN) Shift);
NanoSeconds += DivU64x64Remainder (MultU64x32 (Remainder, 1000000000u), Frequency, NULL);
return NanoSeconds;
}