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1 /** @file
2   The Timer Library implementation which uses the Time Stamp Counter in the processor.
3 
4   For Pentium 4 processors, Intel Xeon processors (family [0FH], models [03H and higher]);
5     for Intel Core Solo and Intel Core Duo processors (family [06H], model [0EH]);
6     for the Intel Xeon processor 5100 series and Intel Core 2 Duo processors (family [06H], model [0FH]);
7     for Intel Core 2 and Intel Xeon processors (family [06H], display_model [17H]);
8     for Intel Atom processors (family [06H], display_model [1CH]):
9   the time-stamp counter increments at a constant rate.
10   That rate may be set by the maximum core-clock to bus-clock ratio of the processor or may be set by
11   the maximum resolved frequency at which the processor is booted. The maximum resolved frequency may
12   differ from the maximum qualified frequency of the processor.
13 
14   The specific processor configuration determines the behavior. Constant TSC behavior ensures that the
15   duration of each clock tick is uniform and supports the use of the TSC as a wall clock timer even if
16   the processor core changes frequency. This is the architectural behavior moving forward.
17 
18   A Processor's support for invariant TSC is indicated by CPUID.0x80000007.EDX[8].
19 
20   Copyright (c) 2009 - 2011, Intel Corporation. All rights reserved.<BR>
21   This program and the accompanying materials
22   are licensed and made available under the terms and conditions of the BSD License
23   which accompanies this distribution. The full text of the license may be found at
24   http://opensource.org/licenses/bsd-license.php
25 
26   THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS,
27   WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED.
28 
29 **/
30 
31 #include "TscTimerLibInternal.h"
32 
33 /**  Calculate TSC frequency.
34 
35   The TSC counting frequency is determined by comparing how far it counts
36   during a 1ms period as determined by the ACPI timer. The ACPI timer is
37   used because it counts at a known frequency.
38   If ACPI I/O space not enabled, this function will enable it. Then the
39   TSC is sampled, followed by waiting for 3579 clocks of the ACPI timer, or 1ms.
40   The TSC is then sampled again. The difference multiplied by 1000 is the TSC
41   frequency. There will be a small error because of the overhead of reading
42   the ACPI timer. An attempt is made to determine and compensate for this error.
43 
44   @return The number of TSC counts per second.
45 
46 **/
47 UINT64
InternalCalculateTscFrequency(VOID)48 InternalCalculateTscFrequency (
49   VOID
50   )
51 {
52   UINT64      StartTSC;
53   UINT64      EndTSC;
54   UINT32      TimerAddr;
55   UINT32      Ticks;
56   UINT64      TscFrequency;
57 
58   //
59   // If ACPI I/O space is not enabled yet, program ACPI I/O base address and enable it.
60   //
61   if ((PciRead8 (PCI_ICH_LPC_ADDRESS (R_ICH_LPC_ACPI_CNT)) & B_ICH_LPC_ACPI_CNT_ACPI_EN) == 0) {
62     PciWrite16 (PCI_ICH_LPC_ADDRESS (R_ICH_LPC_ACPI_BASE), PcdGet16 (PcdPerfPkgAcpiIoPortBaseAddress));
63     PciOr8 (PCI_ICH_LPC_ADDRESS (R_ICH_LPC_ACPI_CNT), B_ICH_LPC_ACPI_CNT_ACPI_EN);
64   }
65 
66   //
67   // ACPI I/O space should be enabled now, locate the ACPI Timer.
68   // ACPI I/O base address maybe have be initialized by other driver with different value,
69   // So get it from PCI space directly.
70   //
71   TimerAddr = ((PciRead16 (PCI_ICH_LPC_ADDRESS (R_ICH_LPC_ACPI_BASE))) & B_ICH_LPC_ACPI_BASE_BAR) + R_ACPI_PM1_TMR;
72   Ticks    = IoRead32 (TimerAddr) + (3579);   // Set Ticks to 1ms in the future
73   StartTSC = AsmReadTsc();                    // Get base value for the TSC
74   //
75   // Wait until the ACPI timer has counted 1ms.
76   // Timer wrap-arounds are handled correctly by this function.
77   // When the current ACPI timer value is greater than 'Ticks', the while loop will exit.
78   //
79   while (((Ticks - IoRead32 (TimerAddr)) & BIT23) == 0) {
80     CpuPause();
81   }
82   EndTSC = AsmReadTsc();    // TSC value 1ms later
83 
84   TscFrequency =   MultU64x32 (
85                       (EndTSC - StartTSC),    // Number of TSC counts in 1ms
86                       1000                    // Number of ms in a second
87                     );
88 
89   return TscFrequency;
90 }
91 
92 /**  Stalls the CPU for at least the given number of ticks.
93 
94   Stalls the CPU for at least the given number of ticks. It's invoked by
95   MicroSecondDelay() and NanoSecondDelay().
96 
97   @param[in]  Delay     A period of time to delay in ticks.
98 
99 **/
100 VOID
InternalX86Delay(IN UINT64 Delay)101 InternalX86Delay (
102   IN      UINT64                    Delay
103   )
104 {
105   UINT64                             Ticks;
106 
107   //
108   // The target timer count is calculated here
109   //
110   Ticks = AsmReadTsc() + Delay;
111 
112   //
113   // Wait until time out
114   // Timer wrap-arounds are NOT handled correctly by this function.
115   // Thus, this function must be called within 10 years of reset since
116   // Intel guarantees a minimum of 10 years before the TSC wraps.
117   //
118   while (AsmReadTsc() <= Ticks) CpuPause();
119 }
120 
121 /**  Stalls the CPU for at least the specified number of MicroSeconds.
122 
123   @param[in]  MicroSeconds  The minimum number of microseconds to delay.
124 
125   @return The value of MicroSeconds input.
126 
127 **/
128 UINTN
129 EFIAPI
MicroSecondDelay(IN UINTN MicroSeconds)130 MicroSecondDelay (
131   IN      UINTN                     MicroSeconds
132   )
133 {
134   InternalX86Delay (
135     DivU64x32 (
136       MultU64x64 (
137         InternalGetTscFrequency (),
138         MicroSeconds
139       ),
140       1000000u
141     )
142   );
143   return MicroSeconds;
144 }
145 
146 /**  Stalls the CPU for at least the specified number of NanoSeconds.
147 
148   @param[in]  NanoSeconds The minimum number of nanoseconds to delay.
149 
150   @return The value of NanoSeconds input.
151 
152 **/
153 UINTN
154 EFIAPI
NanoSecondDelay(IN UINTN NanoSeconds)155 NanoSecondDelay (
156   IN      UINTN                     NanoSeconds
157   )
158 {
159   InternalX86Delay (
160     DivU64x32 (
161       MultU64x32 (
162         InternalGetTscFrequency (),
163         (UINT32)NanoSeconds
164       ),
165     1000000000u
166     )
167   );
168   return NanoSeconds;
169 }
170 
171 /**  Retrieves the current value of the 64-bit free running Time-Stamp counter.
172 
173   The time-stamp counter (as implemented in the P6 family, Pentium, Pentium M,
174   Pentium 4, Intel Xeon, Intel Core Solo and Intel Core Duo processors and
175   later processors) is a 64-bit counter that is set to 0 following a RESET of
176   the processor.  Following a RESET, the counter increments even when the
177   processor is halted by the HLT instruction or the external STPCLK# pin. Note
178   that the assertion of the external DPSLP# pin may cause the time-stamp
179   counter to stop.
180 
181   The properties of the counter can be retrieved by the
182   GetPerformanceCounterProperties() function.
183 
184   @return The current value of the free running performance counter.
185 
186 **/
187 UINT64
188 EFIAPI
GetPerformanceCounter(VOID)189 GetPerformanceCounter (
190   VOID
191   )
192 {
193   return AsmReadTsc();
194 }
195 
196 /**  Retrieves the 64-bit frequency in Hz and the range of performance counter
197   values.
198 
199   If StartValue is not NULL, then the value that the performance counter starts
200   with, 0x0, is returned in StartValue. If EndValue is not NULL, then the value
201   that the performance counter end with, 0xFFFFFFFFFFFFFFFF, is returned in
202   EndValue.
203 
204   The 64-bit frequency of the performance counter, in Hz, is always returned.
205   To determine average processor clock frequency, Intel recommends the use of
206   EMON logic to count processor core clocks over the period of time for which
207   the average is required.
208 
209 
210   @param[out]   StartValue  Pointer to where the performance counter's starting value is saved, or NULL.
211   @param[out]   EndValue    Pointer to where the performance counter's ending value is saved, or NULL.
212 
213   @return The frequency in Hz.
214 
215 **/
216 UINT64
217 EFIAPI
GetPerformanceCounterProperties(OUT UINT64 * StartValue,OPTIONAL OUT UINT64 * EndValue OPTIONAL)218 GetPerformanceCounterProperties (
219   OUT      UINT64                    *StartValue,  OPTIONAL
220   OUT      UINT64                    *EndValue     OPTIONAL
221   )
222 {
223   if (StartValue != NULL) {
224     *StartValue = 0;
225   }
226   if (EndValue != NULL) {
227     *EndValue = 0xFFFFFFFFFFFFFFFFull;
228   }
229 
230   return InternalGetTscFrequency ();
231 }
232 
233 /**
234   Converts elapsed ticks of performance counter to time in nanoseconds.
235 
236   This function converts the elapsed ticks of running performance counter to
237   time value in unit of nanoseconds.
238 
239   @param  Ticks     The number of elapsed ticks of running performance counter.
240 
241   @return The elapsed time in nanoseconds.
242 
243 **/
244 UINT64
245 EFIAPI
GetTimeInNanoSecond(IN UINT64 Ticks)246 GetTimeInNanoSecond (
247   IN      UINT64                     Ticks
248   )
249 {
250   UINT64  Frequency;
251   UINT64  NanoSeconds;
252   UINT64  Remainder;
253   INTN    Shift;
254 
255   Frequency = GetPerformanceCounterProperties (NULL, NULL);
256 
257   //
258   //          Ticks
259   // Time = --------- x 1,000,000,000
260   //        Frequency
261   //
262   NanoSeconds = MultU64x32 (DivU64x64Remainder (Ticks, Frequency, &Remainder), 1000000000u);
263 
264   //
265   // Ensure (Remainder * 1,000,000,000) will not overflow 64-bit.
266   // Since 2^29 < 1,000,000,000 = 0x3B9ACA00 < 2^30, Remainder should < 2^(64-30) = 2^34,
267   // i.e. highest bit set in Remainder should <= 33.
268   //
269   Shift = MAX (0, HighBitSet64 (Remainder) - 33);
270   Remainder = RShiftU64 (Remainder, (UINTN) Shift);
271   Frequency = RShiftU64 (Frequency, (UINTN) Shift);
272   NanoSeconds += DivU64x64Remainder (MultU64x32 (Remainder, 1000000000u), Frequency, NULL);
273 
274   return NanoSeconds;
275 }
276