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merge of '6100fa1118decc83a309c2ccf8d128db2e9c2ef8'

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and 'd804fb6b50abf7968a0198674912906c60ec9ff0'
This commit is contained in:
z3d
2011-01-13 04:38:38 +00:00
parent 9e2c063465 79bd5f1c11
commit c4445143f9
4 changed files with 196 additions and 73 deletions
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218
core/java/src/freenet/support/CPUInformation/CPUID.java
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@ -1,5 +1,6 @@
/*
* Created on Jul 14, 2004
* Updated on Jan 8, 2011
*/
package freenet.support.CPUInformation;
@ -129,11 +130,26 @@ public class CPUID {
CPUIDResult c = doCPUID(1);
return c.EAX & 0xf;
}
private static int getCPUFlags()
private static int getEDXCPUFlags()
{
CPUIDResult c = doCPUID(1);
return c.EDX;
}
private static int getECXCPUFlags()
{
CPUIDResult c = doCPUID(1);
return c.ECX;
}
private static int getExtendedEDXCPUFlags()
{
CPUIDResult c = doCPUID(0x80000001);
return c.EDX;
}
private static int getExtendedECXCPUFlags()
{
CPUIDResult c = doCPUID(0x80000001);
return c.ECX;
}
//Returns a CPUInfo item for the current type of CPU
//If I could I would declare this method in a interface named
@ -163,13 +179,25 @@ public class CPUID {
return getCPUVendorID();
}
public boolean hasMMX(){
return (getCPUFlags() & 0x800000) >0; //Bit 23
return (getEDXCPUFlags() & 0x800000) >0; //EDX Bit 23
}
public boolean hasSSE(){
return (getCPUFlags() & 0x2000000) >0; //Bit 25
return (getEDXCPUFlags() & 0x2000000) >0; //EDX Bit 25
}
public boolean hasSSE2(){
return (getCPUFlags() & 0x4000000) >0; //Bit 26
return (getEDXCPUFlags() & 0x4000000) >0; //EDX Bit 26
}
public boolean hasSSE3(){
return (getEDXCPUFlags() & 0x1) >0; //ECX Bit 0
}
public boolean hasSSE41(){
return (getEDXCPUFlags() & 0x80000) >0; //ECX Bit 19
}
public boolean hasSSE42(){
return (getEDXCPUFlags() & 0x100000) >0; //ECX Bit 20
}
public boolean hasSSE4A(){
return (getExtendedECXCPUFlags() & 0x40) >0; //Extended ECX Bit 6
}
public boolean IsC3Compatible() { return false; }
}
@ -296,77 +324,119 @@ public class CPUID {
return getCPUFamily() > 6 || (getCPUFamily() == 6 && getCPUModel() >=3);
}
public boolean IsPentium3Compatible()
{
return getCPUFamily() > 6 || (getCPUFamily() == 6 && getCPUModel() >=7);
{
// Atom
if (getCPUExtendedModel() == 1 && (getCPUFamily() == 6 && (getCPUModel() == 10))){
return true;
// ??
} else if (getCPUFamily() > 6 || (getCPUFamily() == 6 && getCPUModel() >=7)){
return true;
} else {
return false;
}
}
public boolean IsPentium4Compatible()
{
return getCPUFamily() >= 15;
{
// P4
if (getCPUFamily() >= 15){
return true;
// Xeon MP (45nm) or Core i7
} else if (getCPUExtendedModel() == 1 && (getCPUFamily() == 6 && (getCPUModel() == 10 || getCPUModel() == 13))){
return true;
// Core 2 Duo
} else if (getCPUExtendedModel() == 0 && getCPUFamily() == 6 && getCPUModel() == 15){
return true;
} else {
return false;
}
}
public String getCPUModelString() throws UnknownCPUException {
if(getCPUFamily() == 4){
switch(getCPUModel()){
case 0:
return "486 DX-25/33";
case 1:
return "486 DX-50";
case 2:
return "486 SX";
case 3:
return "486 DX/2";
case 4:
return "486 SL";
case 5:
return "486 SX/2";
case 7:
return "486 DX/2-WB";
case 8:
return "486 DX/4";
case 9:
return "486 DX/4-WB";
}
}
if(getCPUFamily() == 5){
switch(getCPUModel()){
case 0:
return "Pentium 60/66 A-step";
case 1:
return "Pentium 60/66";
case 2:
return "Pentium 75 - 200";
case 3:
return "OverDrive PODP5V83";
case 4:
return "Pentium MMX";
case 7:
return "Mobile Pentium 75 - 200";
case 8:
return "Mobile Pentium MMX";
}
if (getCPUExtendedModel() == 0){
if(getCPUFamily() == 4){
switch(getCPUModel()){
case 0:
return "486 DX-25/33";
case 1:
return "486 DX-50";
case 2:
return "486 SX";
case 3:
return "486 DX/2";
case 4:
return "486 SL";
case 5:
return "486 SX/2";
case 7:
return "486 DX/2-WB";
case 8:
return "486 DX/4";
case 9:
return "486 DX/4-WB";
}
}
}
if (getCPUExtendedModel() == 0){
if(getCPUFamily() == 5){
switch(getCPUModel()){
case 0:
return "Pentium 60/66 A-step";
case 1:
return "Pentium 60/66";
case 2:
return "Pentium 75 - 200";
case 3:
return "OverDrive PODP5V83";
case 4:
return "Pentium MMX";
case 7:
return "Mobile Pentium 75 - 200";
case 8:
return "Mobile Pentium MMX";
}
}
}
if(getCPUFamily() == 6){
switch(getCPUModel()){
case 0:
return "Pentium Pro A-step";
case 1:
return "Pentium Pro";
case 3:
return "Pentium II (Klamath)";
case 5:
return "Pentium II (Deschutes), Celeron (Covington), Mobile Pentium II (Dixon)";
case 6:
return "Mobile Pentium II, Celeron (Mendocino)";
case 7:
return "Pentium III (Katmai)";
case 8:
return "Pentium III (Coppermine), Celeron w/SSE";
case 9:
return "Mobile Pentium III";
case 10:
return "Pentium III Xeon (Cascades)";
case 11:
return "Pentium III (130 nm)";
}
if (getCPUExtendedModel() == 0){
switch(getCPUModel()){
case 0:
return "Pentium Pro A-step";
case 1:
return "Pentium Pro";
case 3:
return "Pentium II (Klamath)";
case 5:
return "Pentium II (Deschutes), Celeron (Covington), Mobile Pentium II (Dixon)";
case 6:
return "Mobile Pentium II, Celeron (Mendocino)";
case 7:
return "Pentium III (Katmai)";
case 8:
return "Pentium III (Coppermine), Celeron w/SSE";
case 9:
return "Mobile Pentium III (Banias)";
case 10:
return "Pentium III Xeon (Cascades)";
case 11:
return "Pentium III (130 nm)";
case 13:
return "Mobile Pentium III (Dothan)";
case 14:
return "Mobile Core (Yonah)";
case 15:
return "Core 2 (Conroe)";
}
} else {
if (getCPUExtendedModel() == 1){
switch(getCPUModel()){
case 10:
return "Core i7";
case 12:
return "Atom";
case 13:
return "Xeon MP";
}
}
}
}
if(getCPUFamily() == 7){
switch(getCPUModel()){
@ -384,6 +454,10 @@ public class CPUID {
return "Pentium IV (130 nm)";
case 3:
return "Pentium IV (90 nm)";
case 4:
return "Pentium IV (90 nm)";
case 6:
return "Pentium IV (65 nm)";
}
}
if(getCPUExtendedFamily() == 1){
@ -407,7 +481,7 @@ public class CPUID {
System.out.println("CPU Family: " + getCPUFamily());
System.out.println("CPU Model: " + getCPUModel());
System.out.println("CPU Stepping: " + getCPUStepping());
System.out.println("CPU Flags: " + getCPUFlags());
System.out.println("CPU Flags: " + getEDXCPUFlags());
CPUInfo c = getInfo();
System.out.println(" **More CPUInfo**");
@ -415,6 +489,10 @@ public class CPUID {
System.out.println(" CPU has MMX: " + c.hasMMX());
System.out.println(" CPU has SSE: " + c.hasSSE());
System.out.println(" CPU has SSE2: " + c.hasSSE2());
System.out.println(" CPU has SSE3: " + c.hasSSE3());
System.out.println(" CPU has SSE4.1: " + c.hasSSE41());
System.out.println(" CPU has SSE4.2: " + c.hasSSE42());
System.out.println(" CPU has SSE4A: " + c.hasSSE4A());
if(c instanceof IntelCPUInfo){
System.out.println(" **Intel-info**");
System.out.println(" Is pII-compatible: "+((IntelCPUInfo)c).IsPentium2Compatible());

24
core/java/src/freenet/support/CPUInformation/CPUInfo.java
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@ -1,6 +1,6 @@
/*
* Created on Jul 16, 2004
*
* Created on Jul 14, 2004
* Updated on Jan 8, 2011
*/
package freenet.support.CPUInformation;
@ -42,5 +42,25 @@ public interface CPUInfo
*/
public boolean hasSSE2();
/**
* @return true iff the CPU support the SSE3 instruction set.
*/
public boolean hasSSE3();
/**
* @return true iff the CPU support the SSE4.1 instruction set.
*/
public boolean hasSSE41();
/**
* @return true iff the CPU support the SSE4.2 instruction set.
*/
public boolean hasSSE42();
/**
* @return true iff the CPU support the SSE4A instruction set.
*/
public boolean hasSSE4A();
public boolean IsC3Compatible();
}

23
core/java/src/net/i2p/data/PrivateKey.java
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@ -16,6 +16,9 @@ import net.i2p.crypto.KeyGenerator;
* A private key is 256byte Integer. The private key represents only the
* exponent, not the primes, which are constant and defined in the crypto spec.
*
* Note that we use short exponents, so all but the last 28.25 bytes are zero.
* See http://www.i2p2.i2p/how_cryptography for details.
*
* @author jrandom
*/
public class PrivateKey extends SimpleDataStructure {
@ -50,4 +53,24 @@ public class PrivateKey extends SimpleDataStructure {
return KeyGenerator.getPublicKey(this);
}
/**
* We assume the data has enough randomness in it, so use the last 4 bytes for speed.
* Overridden since we use short exponents, so the first 227 bytes are all zero.
* Not that we are storing PrivateKeys in any Sets or Maps anywhere.
*/
@Override
public int hashCode() {
if (_data == null)
return 0;
int rv = _data[KEYSIZE_BYTES - 4];
for (int i = 1; i < 4; i++)
rv ^= (_data[i + (KEYSIZE_BYTES - 4)] << (i*8));
return rv;
}
@Override
public boolean equals(Object obj) {
if ((obj == null) || !(obj instanceof PrivateKey)) return false;
return DataHelper.eq(_data, ((PrivateKey) obj)._data);
}
}

4
core/java/src/net/i2p/util/LogManager.java
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@ -152,7 +152,9 @@ public class LogManager {
if (_writer != null)
return;
_writer = new LogWriter(this);
Thread t = new I2PThread(_writer, "LogWriter", true);
// NOT an I2PThread, as it contains logging and we end up with problems
Thread t = new Thread(_writer, "LogWriter");
t.setDaemon(true);
t.start();
}