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Merge branch 'bba' 

OS X support not impl
This commit is contained in:
sktsqrl 2012-07-21 12:53:46 -07:00
parent 0e1348c839 601b9fc03b
commit c0060f9ef8
6 changed files with 980 additions and 1033 deletions
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39
Source/Core/Core/Src/HW/BBA-TAP/TAP_Apple.cpp
View File

@ -15,33 +15,38 @@
// Official SVN repository and contact information can be found at // Official SVN repository and contact information can be found at
// http://code.google.com/p/dolphin-emu/ // http://code.google.com/p/dolphin-emu/
#include "../Memmap.h"
#include "../EXI_Device.h" #include "../EXI_Device.h"
#include "../EXI_DeviceEthernet.h" #include "../EXI_DeviceEthernet.h"
bool CEXIETHERNET::deactivate() {
return true; bool CEXIETHERNET::Activate()
} {
bool CEXIETHERNET::isActivated() {
return false; return false;
} }
bool CEXIETHERNET::activate() {
void CEXIETHERNET::Deactivate()
{
}
bool CEXIETHERNET::IsActivated()
{
return false; return false;
} }
bool CEXIETHERNET::CheckRecieved() {
bool CEXIETHERNET::SendFrame(u8 *, u32)
{
return false; return false;
} }
bool CEXIETHERNET::resume() {
bool CEXIETHERNET::RecvInit()
{
return false; return false;
} }
bool CEXIETHERNET::startRecv() {
bool CEXIETHERNET::RecvStart()
{
return false; return false;
} }
bool CEXIETHERNET::sendPacket(u8 *etherpckt, int size) {
return false; void CEXIETHERNET::RecvStop()
} {
bool CEXIETHERNET::handleRecvdPacket() {
return false;
}
bool CEXIETHERNET::cbwriteDescriptor(u32 size) {
return false;
} }

394
Source/Core/Core/Src/HW/BBA-TAP/TAP_Unix.cpp
View File

@ -15,305 +15,171 @@
// Official SVN repository and contact information can be found at // Official SVN repository and contact information can be found at
// http://code.google.com/p/dolphin-emu/ // http://code.google.com/p/dolphin-emu/
#include "../Memmap.h" #include "StringUtil.h"
#include "../EXI_Device.h" #include "../EXI_Device.h"
#include "../EXI_DeviceEthernet.h" #include "../EXI_DeviceEthernet.h"
#include <sys/socket.h>
#include <netinet/in.h> #ifdef __linux__
#include <stdio.h>
#include <fcntl.h> #include <fcntl.h>
#include <sys/ioctl.h>
#include <net/if.h>
#ifdef __linux__
#include <linux/if_tun.h> #include <linux/if_tun.h>
#else #include <net/if.h>
#include <net/if_tun.h> #include <netinet/in.h>
#include <sys/ioctl.h>
#include <sys/select.h>
#include <sys/socket.h>
#endif #endif
#include <assert.h>
int fd = -1; #define NOTIMPLEMENTED(Name) \
std::thread cpuThread; NOTICE_LOG(SP1, "CEXIETHERNET::%s not implemented for your UNIX", Name);
bool CEXIETHERNET::deactivate() bool CEXIETHERNET::Activate()
{
close(fd);
fd = -1;
cpuThread.join();
return true;
}
bool CEXIETHERNET::isActivated()
{
return fd != -1 ? true : false;
}
bool CEXIETHERNET::activate()
{ {
#ifdef __linux__ #ifdef __linux__
if(isActivated()) if (IsActivated())
return true; return true;
if( (fd = open("/dev/net/tun", O_RDWR)) < 0)
// Assumes that there is a TAP device named "Dolphin" preconfigured for
// bridge/NAT/whatever the user wants it configured.
if ((fd = open("/dev/net/tun", O_RDWR)) < 0)
{ {
INFO_LOG(SP1, "Couldn't Open device\n"); ERROR_LOG(SP1, "Couldn't open /dev/net/tun, unable to init BBA");
return false; return false;
} }
struct ifreq ifr;
int err; struct ifreq ifr;
memset(&ifr, 0, sizeof(ifr)); memset(&ifr, 0, sizeof(ifr));
ifr.ifr_flags = IFF_TAP | IFF_NO_PI | IFF_ONE_QUEUE; ifr.ifr_flags = IFF_TAP | IFF_NO_PI | IFF_ONE_QUEUE;
strncpy(ifr.ifr_name, "Dolphin", IFNAMSIZ); strncpy(ifr.ifr_name, "Dolphin", IFNAMSIZ);
if( (err = ioctl(fd, TUNSETIFF, (void*) &ifr)) < 0) int err;
if ((err = ioctl(fd, TUNSETIFF, (void*)&ifr)) < 0)
{ {
close(fd); close(fd);
fd = -1; fd = -1;
INFO_LOG(SP1, " Error with IOCTL: 0x%X\n", err); ERROR_LOG(SP1, "TUNSETIFF failed: err=%d", err);
return false; return false;
} }
ioctl( fd, TUNSETNOCSUM, 1 ); ioctl(fd, TUNSETNOCSUM, 1);
/*int flags;
if ((flags = fcntl( fd, F_GETFL)) < 0)
{
INFO_LOG(SP1, "getflags on tun device: %s", strerror (errno));
}
flags |= O_NONBLOCK;
if (fcntl( fd, F_SETFL, flags ) < 0)
{
INFO_LOG(SP1, "set tun device flags: %s", strerror (errno));
}*/
INFO_LOG(SP1, "Returned Socket name is: %s\n", ifr.ifr_name); readEnabled = false;
system("brctl addif pan0 Dolphin");
system("ifconfig Dolphin 0.0.0.0 promisc up"); INFO_LOG(SP1, "BBA initialized with associated tap %s", ifr.ifr_name);
resume();
return true; return true;
#else
NOTIMPLEMENTED("Activate");
return false;
#endif
}
void CEXIETHERNET::Deactivate()
{
#ifdef __linux__
close(fd);
fd = -1;
readEnabled = false;
if (readThread.joinable())
readThread.join();
#else
NOTIMPLEMENTED("Deactivate");
#endif
}
bool CEXIETHERNET::IsActivated()
{
#ifdef __linux__
return fd != -1 ? true : false;
#else #else
return false; return false;
#endif #endif
} }
bool CEXIETHERNET::CheckRecieved() bool CEXIETHERNET::SendFrame(u8* frame, u32 size)
{ {
if(!isActivated()) #ifdef __linux__
INFO_LOG(SP1, "SendFrame %x\n%s", size, ArrayToString(frame, size, 0x10).c_str());
int writtenBytes = write(fd, frame, size);
if ((u32)writtenBytes != size)
{
ERROR_LOG(SP1, "SendFrame(): expected to write %d bytes, instead wrote %d",
size, writtenBytes);
return false; return false;
int maxfd;
int retval;
struct timeval tv;
int timeout = 9999; // 3 seconds will kill him
fd_set mask;
/* Find the largest file descriptor */
maxfd = fd;
/* Check the file descriptors for available data */
errno = 0;
/* Set up the mask of file descriptors */
FD_ZERO(&mask);
FD_SET(fd, &mask);
/* Set up the timeout */
tv.tv_sec = timeout/1000;
tv.tv_usec = (timeout%1000)*1000;
/* Look! */
retval = select(maxfd+1, &mask, NULL, NULL, &tv);
/* Mark all file descriptors ready that have data available */
if ( retval > 0 ) {
if ( FD_ISSET(fd, &mask) )
{
INFO_LOG(SP1, "\t\t\t\tWe have data!\n");
return true;
}
}
return false;
}
bool CEXIETHERNET::resume()
{
if(!isActivated())
return true;
INFO_LOG(SP1, "BBA resume\n");
if(mBbaMem[BBA_NCRA] & NCRA_SR) {
startRecv();
}
INFO_LOG(SP1, "BBA resume complete\n");
return true;
}
void CpuThread(CEXIETHERNET *self)
{
while(1)
{
if(self->CheckRecieved())
{
u8 B[1514];
self->mRecvBufferLength = read(fd, B, 1500);
//INFO_LOG(SP1, "read return of 0x%x\n", self->mRecvBufferLength);
if (self->mRecvBufferLength == 0xffffffff)
{
//Fail Boat
continue;
}
else if(self->mRecvBufferLength > 0)
{
//mRecvBuffer.write(B, BytesRead);
//strncat(mRecvBuffer.p(), B, BytesRead);
memcpy(self->mRecvBuffer, B, self->mRecvBufferLength);
}
else if(self->mRecvBufferLength == -1U)
{
continue;
}
else
{
INFO_LOG(SP1, "Unknown read return of 0x%x\n", self->mRecvBufferLength);
exit(0);
}
INFO_LOG(SP1, "Received %d bytes of data\n", self->mRecvBufferLength);
self->mWaiting = false;
self->handleRecvdPacket();
return;
}
//sleep(1);
}
}
bool CEXIETHERNET::startRecv()
{
INFO_LOG(SP1, "Start Receive!\n");
//exit(0);
INFO_LOG(SP1, "startRecv... ");
if(mWaiting) {
INFO_LOG(SP1, "already waiting\n");
return true;
}
cpuThread = std::thread(CpuThread, this);
mWaiting = true;
return true;
}
bool CEXIETHERNET::sendPacket(u8 *etherpckt, int size)
{
if(!isActivated())
return false;
INFO_LOG(SP1, "Packet: 0x");
for(int a = 0; a < size; ++a)
{
INFO_LOG(SP1, "%02X ", etherpckt[a]);
}
INFO_LOG(SP1, " : Size: %d\n", size);
int numBytesWrit = write(fd, etherpckt, size);
if(numBytesWrit != size)
{
INFO_LOG(SP1, "BBA sendPacket %i only got %i bytes sent!errno: %d\n", size, numBytesWrit, errno);
return false;
}
recordSendComplete();
return true;
}
bool CEXIETHERNET::handleRecvdPacket()
{
int rbwpp = mCbw.p_write() + CB_OFFSET; //read buffer write page pointer
u32 available_bytes_in_cb;
if(rbwpp < mRBRPP)
available_bytes_in_cb = mRBRPP - rbwpp;
else if(rbwpp == mRBRPP)
available_bytes_in_cb = mRBEmpty ? CB_SIZE : 0;
else //rbwpp > mRBRPP
available_bytes_in_cb = CB_SIZE - rbwpp + (mRBRPP - CB_OFFSET);
//DUMPWORD(rbwpp);
//DUMPWORD(mRBRPP);
//DUMPWORD(available_bytes_in_cb);
assert(available_bytes_in_cb <= CB_SIZE);
if(available_bytes_in_cb != CB_SIZE)//< mRecvBufferLength + SIZEOF_RECV_DESCRIPTOR)
return true;
cbwriteDescriptor(mRecvBufferLength);
mCbw.write(mRecvBuffer, mRecvBufferLength);
mCbw.align();
rbwpp = mCbw.p_write() + CB_OFFSET;
//DUMPWORD(rbwpp);
//mPacketsRcvd++;
mRecvBufferLength = 0;
if(mBbaMem[BBA_IMR] & INT_R)
{
if(!(mBbaMem[BBA_IR] & INT_R))
{
mBbaMem[BBA_IR] |= INT_R;
INFO_LOG(SP1, "BBA Recv interrupt raised\n");
m_bInterruptSet = true;
}
}
if(mBbaMem[BBA_NCRA] & NCRA_SR)
{
startRecv();
}
return true;
}
union bba_descr {
struct { u32 next_packet_ptr:12, packet_len:12, status:8; };
u32 word;
};
bool CEXIETHERNET::cbwriteDescriptor(u32 size)
{
if(size < SIZEOF_ETH_HEADER)
{
INFO_LOG(SP1, "Packet too small: %i bytes\n", size);
return false;
}
size += SIZEOF_RECV_DESCRIPTOR; //The descriptor supposed to include the size of itself
//We should probably not implement wraparound here,
//since neither tmbinc, riptool.dol, or libogc does...
if(mCbw.p_write() + SIZEOF_RECV_DESCRIPTOR >= CB_SIZE)
{
INFO_LOG(SP1, "The descriptor won't fit\n");
return false;
}
if(size >= CB_SIZE)
{
INFO_LOG(SP1, "Packet too big: %i bytes\n", size);
return false;
}
bba_descr descr;
descr.word = 0;
descr.packet_len = size;
descr.status = 0;
u32 npp;
if(mCbw.p_write() + size < CB_SIZE)
{
npp = mCbw.p_write() + size + CB_OFFSET;
} }
else else
{ {
npp = mCbw.p_write() + size + CB_OFFSET - CB_SIZE; SendComplete();
return true;
} }
npp = (npp + 0xff) & ~0xff; #else
if(npp >= CB_SIZE + CB_OFFSET) NOTIMPLEMENTED("SendFrame");
npp -= CB_SIZE; return false;
descr.next_packet_ptr = npp >> 8; #endif
//DWORD swapped = swapw(descr.word); }
//next_packet_ptr:12, packet_len:12, status:8;
INFO_LOG(SP1, "Writing descriptor 0x%08X @ 0x%04lX: next 0x%03X len 0x%03X status 0x%02X\n", void ReadThreadHandler(CEXIETHERNET* self)
descr.word, (unsigned long)mCbw.p_write() + CB_OFFSET, descr.next_packet_ptr, {
descr.packet_len, descr.status); while (true)
mCbw.write(&descr.word, SIZEOF_RECV_DESCRIPTOR); {
if (self->fd < 0)
return true; return;
fd_set rfds;
FD_ZERO(&rfds);
FD_SET(self->fd, &rfds);
struct timeval timeout;
timeout.tv_sec = 0;
timeout.tv_usec = 50000;
if (select(self->fd + 1, &rfds, NULL, NULL, &timeout) <= 0)
continue;
int readBytes = read(self->fd, self->mRecvBuffer, BBA_RECV_SIZE);
if (readBytes < 0)
{
ERROR_LOG(SP1, "Failed to read from BBA, err=%d", readBytes);
}
else if (self->readEnabled)
{
INFO_LOG(SP1, "Read data: %s", ArrayToString(self->mRecvBuffer, readBytes, 0x10).c_str());
self->mRecvBufferLength = readBytes;
self->RecvHandlePacket();
}
}
}
bool CEXIETHERNET::RecvInit()
{
#ifdef __linux__
readThread = std::thread(ReadThreadHandler, this);
return true;
#else
NOTIMPLEMENTED("RecvInit");
return false;
#endif
}
bool CEXIETHERNET::RecvStart()
{
#ifdef __linux__
if (!readThread.joinable())
RecvInit();
readEnabled = true;
return true;
#else
NOTIMPLEMENTED("RecvStart");
return false;
#endif
}
void CEXIETHERNET::RecvStop()
{
#ifdef __linux__
readEnabled = false;
#else
NOTIMPLEMENTED("RecvStop");
#endif
} }

339
Source/Core/Core/Src/HW/BBA-TAP/TAP_Win32.cpp
View File

@ -17,7 +17,6 @@
#include "StringUtil.h" #include "StringUtil.h"
#include "../Memmap.h" #include "../Memmap.h"
//#pragma optimize("",off)
// GROSS CODE ALERT: headers need to be included in the following order // GROSS CODE ALERT: headers need to be included in the following order
#include "TAP_Win32.h" #include "TAP_Win32.h"
#include "../EXI_Device.h" #include "../EXI_Device.h"
@ -187,66 +186,45 @@ bool OpenTAP(HANDLE& adapter, const std::string device_guid)
} // namespace Win32TAPHelper } // namespace Win32TAPHelper
bool CEXIETHERNET::deactivate() bool CEXIETHERNET::Activate()
{ {
INFO_LOG(SP1, "Deactivating BBA..."); if (IsActivated())
if (!isActivated())
return true; return true;
CloseHandle(mHRecvEvent);
mHRecvEvent = INVALID_HANDLE_VALUE;
CloseHandle(mHAdapter);
mHAdapter = INVALID_HANDLE_VALUE;
INFO_LOG(SP1, "Success!");
return true;
}
bool CEXIETHERNET::isActivated()
{
return mHAdapter != INVALID_HANDLE_VALUE;
}
bool CEXIETHERNET::activate()
{
if (isActivated())
return true;
INFO_LOG(SP1, "Activating BBA...");
DWORD len; DWORD len;
std::vector<std::string> device_guids; std::vector<std::string> device_guids;
if (!Win32TAPHelper::GetGUIDs(device_guids)) if (!Win32TAPHelper::GetGUIDs(device_guids))
{ {
INFO_LOG(SP1, "Failed to find a TAP GUID"); ERROR_LOG(SP1, "Failed to find a TAP GUID");
return false; return false;
} }
for (int i = 0; i < device_guids.size(); i++) for (size_t i = 0; i < device_guids.size(); i++)
{ {
if (Win32TAPHelper::OpenTAP(mHAdapter, device_guids.at(i))) if (Win32TAPHelper::OpenTAP(mHAdapter, device_guids.at(i)))
{ {
ERROR_LOG(SP1, "OPENED %s", device_guids.at(i).c_str()); INFO_LOG(SP1, "OPENED %s", device_guids.at(i).c_str());
i = device_guids.size(); i = device_guids.size();
} }
} }
if (mHAdapter == INVALID_HANDLE_VALUE) if (mHAdapter == INVALID_HANDLE_VALUE)
{ {
INFO_LOG(SP1, "Failed to open any TAP"); ERROR_LOG(SP1, "Failed to open any TAP");
return false; return false;
} }
/* get driver version info */ /* get driver version info */
ULONG info[3]; ULONG info[3];
if (DeviceIoControl (mHAdapter, TAP_IOCTL_GET_VERSION, if (DeviceIoControl(mHAdapter, TAP_IOCTL_GET_VERSION,
&info, sizeof (info), &info, sizeof (info), &len, NULL)) &info, sizeof(info), &info, sizeof(info), &len, NULL))
{ {
INFO_LOG(SP1, "TAP-Win32 Driver Version %d.%d %s", INFO_LOG(SP1, "TAP-Win32 Driver Version %d.%d %s",
info[0], info[1], (info[2] ? "(DEBUG)" : "")); info[0], info[1], info[2] ? "(DEBUG)" : "");
} }
if ( !(info[0] > TAP_WIN32_MIN_MAJOR if (!(info[0] > TAP_WIN32_MIN_MAJOR || (info[0] == TAP_WIN32_MIN_MAJOR && info[1] >= TAP_WIN32_MIN_MINOR)))
|| (info[0] == TAP_WIN32_MIN_MAJOR && info[1] >= TAP_WIN32_MIN_MINOR)) )
{ {
PanicAlertT("ERROR: This version of Dolphin requires a TAP-Win32 driver" PanicAlertT("ERROR: This version of Dolphin requires a TAP-Win32 driver"
" that is at least version %d.%d -- If you recently upgraded your Dolphin" " that is at least version %d.%d -- If you recently upgraded your Dolphin"
" distribution, a reboot is probably required at this point to get" " distribution, a reboot is probably required at this point to get"
" Windows to see the new driver.", " Windows to see the new driver.",
@ -254,279 +232,124 @@ bool CEXIETHERNET::activate()
return false; return false;
} }
/* get driver MTU */
if (!DeviceIoControl(mHAdapter, TAP_IOCTL_GET_MTU,
&mMtu, sizeof (mMtu), &mMtu, sizeof (mMtu), &len, NULL))
{
INFO_LOG(SP1, "Couldn't get device MTU");
return false;
}
INFO_LOG(SP1, "TAP-Win32 MTU=%d (ignored)", mMtu);
/* set driver media status to 'connected' */ /* set driver media status to 'connected' */
ULONG status = TRUE; ULONG status = TRUE;
if (!DeviceIoControl(mHAdapter, TAP_IOCTL_SET_MEDIA_STATUS, if (!DeviceIoControl(mHAdapter, TAP_IOCTL_SET_MEDIA_STATUS,
&status, sizeof (status), &status, sizeof (status), &len, NULL)) &status, sizeof(status), &status, sizeof(status), &len, NULL))
{ {
INFO_LOG(SP1, "WARNING: The TAP-Win32 driver rejected a" ERROR_LOG(SP1, "WARNING: The TAP-Win32 driver rejected a"
"TAP_IOCTL_SET_MEDIA_STATUS DeviceIoControl call."); "TAP_IOCTL_SET_MEDIA_STATUS DeviceIoControl call.");
return false; return false;
} }
//set up recv event
if ((mHRecvEvent = CreateEvent(NULL, false, false, NULL)) == NULL)
{
INFO_LOG(SP1, "Failed to create recv event:%x", GetLastError());
return false;
}
ZeroMemory(&mReadOverlapped, sizeof(mReadOverlapped));
resume();
INFO_LOG(SP1, "Success!");
return true; return true;
} }
bool CEXIETHERNET::CheckRecieved() void CEXIETHERNET::Deactivate()
{ {
if (!isActivated()) if (!IsActivated())
return false; return;
return false; RecvStop();
CloseHandle(mHAdapter);
mHAdapter = INVALID_HANDLE_VALUE;
} }
// Required for lwip...not sure why bool CEXIETHERNET::IsActivated()
void fixup_ip_checksum(u16 *dataptr, u16 len)
{ {
u32 acc = 0; return mHAdapter != INVALID_HANDLE_VALUE;
u16 *data = dataptr;
u16 *chksum = &dataptr[5];
*chksum = 0;
while (len > 1) {
u16 s = *data++;
acc += Common::swap16(s);
len -= 2;
}
acc = (acc >> 16) + (acc & 0xffff);
acc += (acc >> 16);
*chksum = Common::swap16(~acc);
} }
bool CEXIETHERNET::sendPacket(u8 *etherpckt, int size) bool CEXIETHERNET::SendFrame(u8 *frame, u32 size)
{ {
fixup_ip_checksum((u16*)etherpckt + 7, 20); DEBUG_LOG(SP1, "SendFrame %x\n%s",
INFO_LOG(SP1, "Packet (%zu):\n%s", size, ArrayToString(etherpckt, size, 0, 16).c_str()); size, ArrayToString(frame, size, 0x10).c_str());
DWORD numBytesWrit; DWORD numBytesWrit;
OVERLAPPED overlap; OVERLAPPED overlap;
ZeroMemory(&overlap, sizeof(overlap)); ZeroMemory(&overlap, sizeof(overlap));
//overlap.hEvent = mHRecvEvent;
if (!WriteFile(mHAdapter, etherpckt, size, &numBytesWrit, &overlap)) if (!WriteFile(mHAdapter, frame, size, &numBytesWrit, &overlap))
{ {
// Fail Boat
DWORD res = GetLastError(); DWORD res = GetLastError();
INFO_LOG(SP1, "Failed to send packet with error 0x%X", res); ERROR_LOG(SP1, "Failed to send packet with error 0x%X", res);
} }
if (numBytesWrit != size) if (numBytesWrit != size)
{ {
INFO_LOG(SP1, "BBA sendPacket %i only got %i bytes sent!", size, numBytesWrit); ERROR_LOG(SP1, "BBA SendFrame %i only got %i bytes sent!", size, numBytesWrit);
return false;
}
recordSendComplete();
return true;
}
bool CEXIETHERNET::handleRecvdPacket()
{
static u32 mPacketsRecvd = 0;
INFO_LOG(SP1, "handleRecvdPacket Packet %i (%i):\n%s", mPacketsRecvd, mRecvBufferLength,
ArrayToString(mRecvBuffer, mRecvBufferLength, 0, 16).c_str());
static u8 broadcast[] = { 0xff, 0xff, 0xff, 0xff, 0xff, 0xff };
if (memcmp(mRecvBuffer, broadcast, 6) && memcmp(mRecvBuffer, mac_address, 6))
{
INFO_LOG(SP1, "dropping packet - not for us");
goto wait_for_next;
} }
int rbwpp = (int)(mCbw.p_write() + CB_OFFSET); // read buffer write page pointer // Always report the packet as being sent successfully, even though it might be a lie
u32 available_bytes_in_cb; SendComplete();
if (rbwpp < mRBRPP)
available_bytes_in_cb = mRBRPP - rbwpp;
else if (rbwpp == mRBRPP)
available_bytes_in_cb = mRBEmpty ? CB_SIZE : 0;
else //rbwpp > mRBRPP
available_bytes_in_cb = CB_SIZE - rbwpp + (mRBRPP - CB_OFFSET);
INFO_LOG(SP1, "rbwpp %i mRBRPP %04x available_bytes_in_cb %i",
rbwpp, mRBRPP, available_bytes_in_cb);
_dbg_assert_(SP1, available_bytes_in_cb <= CB_SIZE);
if (available_bytes_in_cb != CB_SIZE)//< mRecvBufferLength + SIZEOF_RECV_DESCRIPTOR)
return true;
cbwriteDescriptor(mRecvBufferLength);
mCbw.write(mRecvBuffer, mRecvBufferLength);
mCbw.align();
rbwpp = (int)(mCbw.p_write() + CB_OFFSET);
INFO_LOG(SP1, "rbwpp %i", rbwpp);
mPacketsRecvd++;
mRecvBufferLength = 0;
if ((mBbaMem[BBA_IMR] & INT_R) && !(mBbaMem[BBA_IR] & INT_R))
{
if (mBbaMem[2])
{
mBbaMem[BBA_IR] |= INT_R;
INFO_LOG(SP1, "BBA Recv interrupt raised");
m_bInterruptSet = true;
}
}
wait_for_next:
if (mBbaMem[BBA_NCRA] & NCRA_SR)
startRecv();
return true;
}
bool CEXIETHERNET::resume()
{
if (!isActivated())
return true;
INFO_LOG(SP1, "BBA resume");
//mStop = false;
RegisterWaitForSingleObject(&mHReadWait, mHRecvEvent, ReadWaitCallback,
this, INFINITE, WT_EXECUTEDEFAULT);//WT_EXECUTEINWAITTHREAD
mReadOverlapped.hEvent = mHRecvEvent;
if (mBbaMem[BBA_NCRA] & NCRA_SR)
startRecv();
INFO_LOG(SP1, "BBA resume complete");
return true;
}
bool CEXIETHERNET::startRecv()
{
if (!isActivated())
return false;// Should actually be an assert
INFO_LOG(SP1, "startRecv... ");
if (mWaiting)
{
INFO_LOG(SP1, "already waiting");
return true;
}
DWORD res = ReadFile(mHAdapter, mRecvBuffer, BBA_RECV_SIZE,
&mRecvBufferLength, &mReadOverlapped);
if (res)
{
// Operation completed immediately
INFO_LOG(SP1, "completed, res %i", res);
mWaiting = true;
}
else
{
res = GetLastError();
if (res == ERROR_IO_PENDING)
{
//'s ok :)
INFO_LOG(SP1, "pending");
// WaitCallback will be called
mWaiting = true;
}
else
{
// error occurred
return false;
}
}
return true; return true;
} }
VOID CALLBACK CEXIETHERNET::ReadWaitCallback(PVOID lpParameter, BOOLEAN TimerFired) VOID CALLBACK CEXIETHERNET::ReadWaitCallback(PVOID lpParameter, BOOLEAN TimerFired)
{ {
static int sNumber = 0;
int cNumber = sNumber++;
INFO_LOG(SP1, "WaitCallback %i", cNumber);
__assume(!TimerFired);
CEXIETHERNET* self = (CEXIETHERNET*)lpParameter; CEXIETHERNET* self = (CEXIETHERNET*)lpParameter;
__assume(self->mHAdapter != INVALID_HANDLE_VALUE);
GetOverlappedResult(self->mHAdapter, &self->mReadOverlapped, GetOverlappedResult(self->mHAdapter, &self->mReadOverlapped,
&self->mRecvBufferLength, false); (LPDWORD)&self->mRecvBufferLength, false);
self->mWaiting = false;
self->handleRecvdPacket(); self->RecvHandlePacket();
INFO_LOG(SP1, "WaitCallback %i done", cNumber);
} }
union bba_descr bool CEXIETHERNET::RecvInit()
{ {
struct { u32 next_packet_ptr:12, packet_len:12, status:8; }; // Set up recv event
u32 word;
};
bool CEXIETHERNET::cbwriteDescriptor(u32 size) if ((mHRecvEvent = CreateEvent(NULL, false, false, NULL)) == NULL)
{
if (size < SIZEOF_ETH_HEADER)
{ {
INFO_LOG(SP1, "Packet too small: %i bytes", size); ERROR_LOG(SP1, "Failed to create recv event:%x", GetLastError());
return false; return false;
} }
// The descriptor supposed to include the size of itself ZeroMemory(&mReadOverlapped, sizeof(mReadOverlapped));
size += SIZEOF_RECV_DESCRIPTOR;
//We should probably not implement wraparound here, RegisterWaitForSingleObject(&mHReadWait, mHRecvEvent, ReadWaitCallback,
//since neither tmbinc, riptool.dol, or libogc does... this, INFINITE, WT_EXECUTEDEFAULT);
if (mCbw.p_write() + SIZEOF_RECV_DESCRIPTOR >= CB_SIZE)
{
INFO_LOG(SP1, "The descriptor won't fit");
return false;
}
if (size >= CB_SIZE)
{
INFO_LOG(SP1, "Packet too big: %i bytes", size);
return false;
}
bba_descr descr; mReadOverlapped.hEvent = mHRecvEvent;
descr.word = 0;
descr.packet_len = size;
descr.status = 0;
u32 npp;
if (mCbw.p_write() + size < CB_SIZE)
{
npp = (u32)(mCbw.p_write() + size + CB_OFFSET);
}
else
{
npp = (u32)(mCbw.p_write() + size + CB_OFFSET - CB_SIZE);
}
npp = (npp + 0xff) & ~0xff;
if (npp >= CB_SIZE + CB_OFFSET)
npp -= CB_SIZE;
descr.next_packet_ptr = npp >> 8;
//DWORD swapped = swapw(descr.word);
//next_packet_ptr:12, packet_len:12, status:8;
INFO_LOG(SP1, "Writing descriptor 0x%08X @ 0x%04X: next 0x%03X len 0x%03X status 0x%02X",
descr.word, mCbw.p_write() + CB_OFFSET, descr.next_packet_ptr,
descr.packet_len, descr.status);
mCbw.write(&descr.word, SIZEOF_RECV_DESCRIPTOR);
return true; return true;
} }
//#pragma optimize("",on)
bool CEXIETHERNET::RecvStart()
{
if (!IsActivated())
return false;
if (mHRecvEvent == INVALID_HANDLE_VALUE)
RecvInit();
DWORD res = ReadFile(mHAdapter, mRecvBuffer, BBA_RECV_SIZE,
(LPDWORD)&mRecvBufferLength, &mReadOverlapped);
if (!res && (GetLastError() != ERROR_IO_PENDING))
{
// error occurred
return false;
}
if (res)
{
// Completed immediately
RecvHandlePacket();
}
return true;
}
void CEXIETHERNET::RecvStop()
{
if (!IsActivated())
return;
UnregisterWaitEx(mHReadWait, INVALID_HANDLE_VALUE);
CloseHandle(mHRecvEvent);
mHRecvEvent = INVALID_HANDLE_VALUE;
}

2
Source/Core/Core/Src/HW/EXI_Device.cpp
View File

@ -129,7 +129,7 @@ IEXIDevice* EXIDevice_Create(TEXIDevices device_type, const int channel_num)
break; break;
case EXIDEVICE_ETH: case EXIDEVICE_ETH:
result = new CEXIETHERNET(SConfig::GetInstance().m_bba_mac); result = new CEXIETHERNET();
break; break;
case EXIDEVICE_AM_BASEBOARD: case EXIDEVICE_AM_BASEBOARD:

904
Source/Core/Core/Src/HW/EXI_DeviceEthernet.cpp
View File

@ -16,87 +16,130 @@
// http://code.google.com/p/dolphin-emu/ // http://code.google.com/p/dolphin-emu/
#include "Memmap.h" #include "Memmap.h"
//#pragma optimize("",off)
#include "EXI_Device.h" #include "EXI_Device.h"
#include "EXI_DeviceEthernet.h" #include "EXI_DeviceEthernet.h"
#include "StringUtil.h"
#include "../ConfigManager.h"
#define MAKE(type, arg) (*(type *)&(arg)) // XXX: The BBA stores multi-byte elements as little endian.
// Multiple parts of this implementation depend on dolphin
// being compiled for a little endian host.
CEXIETHERNET::CEXIETHERNET(const std::string& mac_addr) :
m_uPosition(0), // TODO move this code into Common or something, for IOS to use
m_uCommand(0),
mWriteBuffer(2048), enum MACConsumer
mCbw(mBbaMem + CB_OFFSET, CB_SIZE)
{ {
const u8 mac_address_default[6] = BBA,
{ 0x00, 0x09, 0xbf, 0x01, 0x00, 0xc1 }; IOS
};
memset(mBbaMem, 0, BBA_MEM_SIZE); void GenerateMAC(MACConsumer type, u8 (&mac)[6])
{
memset(mac, 0, 6);
int x = 0; u8 const oui_bba[] = { 0x00, 0x09, 0xbf };
u8 new_addr[6] = { 0 }; u8 const oui_ios[] = { 0x00, 0x17, 0xab };
for (int i = 0; i < (int)mac_addr.size() && x < 12; i++)
switch (type)
{ {
char c = mac_addr.at(i); case BBA:
if (c >= '0' && c <= '9') { memcpy(mac, oui_bba, 3);
new_addr[x / 2] |= (c - '0') << ((x & 1) ? 0 : 4); x++; break;
} else if (c >= 'A' && c <= 'F') { case IOS:
new_addr[x / 2] |= (c - 'A' + 10) << ((x & 1) ? 0 : 4); x++; memcpy(mac, oui_ios, 3);
} else if (c >= 'a' && c <= 'f') { break;
new_addr[x / 2] |= (c - 'a' + 10) << ((x & 1) ? 0 : 4); x++; }
srand((unsigned int)time(nullptr));
u8 id[3] =
{
(u8)rand(),
(u8)rand(),
(u8)rand()
};
memcpy(&mac[3], id, 3);
}
CEXIETHERNET::CEXIETHERNET()
{
tx_fifo = new u8[1518];
mBbaMem = new u8[BBA_MEM_SIZE];
mRecvBuffer = new u8 [BBA_RECV_SIZE];
mRecvBufferLength = 0;
MXHardReset();
// Parse MAC address from config, and generate a new one if it doesn't
// exist or can't be parsed.
auto &mac_addr_setting = SConfig::GetInstance().m_bba_mac;
bool mac_addr_valid = false;
u8 mac_addr[6] = { 0 };
if (!mac_addr_setting.empty())
{
int x = 0;
for (size_t i = 0; i < mac_addr_setting.size() && x < 12; i++)
{
char c = mac_addr_setting.at(i);
if (c >= '0' && c <= '9') {
mac_addr[x / 2] |= (c - '0') << ((x & 1) ? 0 : 4); x++;
} else if (c >= 'A' && c <= 'F') {
mac_addr[x / 2] |= (c - 'A' + 10) << ((x & 1) ? 0 : 4); x++;
} else if (c >= 'a' && c <= 'f') {
mac_addr[x / 2] |= (c - 'a' + 10) << ((x & 1) ? 0 : 4); x++;
}
}
if (x / 2 == 6)
{
memcpy(&mBbaMem[BBA_NAFR_PAR0], mac_addr, 6);
mac_addr_valid = true;
} }
} }
if (x / 2 == 6)
memcpy(mac_address, new_addr, 6);
else
memcpy(mac_address, mac_address_default, 6);
ERROR_LOG(SP1, "BBA MAC %x%x%x%x%x%x", if (!mac_addr_valid)
mac_address[0], mac_address[1], mac_address[2], {
mac_address[3], mac_address[4], mac_address[5]); GenerateMAC(BBA, mac_addr);
mWriteP = INVALID_P; mac_addr_setting = ArrayToString(mac_addr, 6, 10, false);
mReadP = INVALID_P; SConfig::GetInstance().SaveSettings();
mWaiting = false;
mReadyToSend = false;
Activated = false;
m_bInterruptSet = false;
#ifdef _WIN32 memcpy(&mBbaMem[BBA_NAFR_PAR0], mac_addr, 6);
}
// hax .. fully established 100BASE-T link
mBbaMem[BBA_NWAYS] = NWAYS_LS100 | NWAYS_LPNWAY | NWAYS_100TXF | NWAYS_ANCLPT;
#if defined(_WIN32)
mHAdapter = INVALID_HANDLE_VALUE; mHAdapter = INVALID_HANDLE_VALUE;
mHRecvEvent = INVALID_HANDLE_VALUE; mHRecvEvent = INVALID_HANDLE_VALUE;
mHReadWait = INVALID_HANDLE_VALUE; mHReadWait = INVALID_HANDLE_VALUE;
#elif defined(__linux__)
fd = -1;
#endif #endif
mRecvBufferLength = 0;
mExpectSpecialImmRead = false;
mExpectVariableLengthImmWrite = false;
} }
CEXIETHERNET::~CEXIETHERNET() CEXIETHERNET::~CEXIETHERNET()
{ {
/*/ crashy crashy Deactivate();
if (isActivated())
deactivate(); delete tx_fifo;
//*/ delete mBbaMem;
delete mRecvBuffer;
} }
void CEXIETHERNET::SetCS(int cs) void CEXIETHERNET::SetCS(int cs)
{ {
INFO_LOG(SP1, "chip select: %s%s", cs ? "true" : "false", if (cs)
mExpectVariableLengthImmWrite ? ", expecting variable write" : "");
if (!cs)
{ {
if (mExpectVariableLengthImmWrite) // Invalidate the previous transfer
{ transfer.valid = false;
INFO_LOG(SP1, "Variable write complete. Final size: %i bytes",
mWriteBuffer.size());
mExpectVariableLengthImmWrite = false;
mReadyToSend = true;
}
mExpectSpecialImmRead = false;
mWriteP = mReadP = INVALID_P;
} }
} }
@ -105,336 +148,515 @@ bool CEXIETHERNET::IsPresent()
return true; return true;
} }
void CEXIETHERNET::Update()
{
return;
}
bool CEXIETHERNET::IsInterruptSet() bool CEXIETHERNET::IsInterruptSet()
{ {
return m_bInterruptSet; return !!(exi_status.interrupt & exi_status.interrupt_mask);
} }
void CEXIETHERNET::recordSendComplete() void CEXIETHERNET::ImmWrite(u32 data, u32 size)
{ {
mBbaMem[BBA_NCRA] &= ~(NCRA_ST0 | NCRA_ST1); data >>= (4 - size) * 8;
if (mBbaMem[BBA_IMR] & INT_T)
if (!transfer.valid)
{ {
mBbaMem[BBA_IR] |= INT_T; transfer.valid = true;
INFO_LOG(SP1, "\t\tBBA Send interrupt raised"); transfer.region = IsMXCommand(data) ? transfer.MX : transfer.EXI;
m_bInterruptSet = true; if (transfer.region == transfer.EXI)
} transfer.address = ((data & ~0xc000) >> 8) & 0xff;
// TODO why did sonic put this here?
//startRecv();
}
bool CEXIETHERNET::checkRecvBuffer()
{
if (mRecvBufferLength)
handleRecvdPacket();
return true;
}
void CEXIETHERNET::ImmWrite(u32 data, u32 size)
{
if (size == 1)
data = (u8)Common::swap32(data);
else if (size == 2)
data >>= 16;
INFO_LOG(SP1, "imm write %0*x writep 0x%x", size * 2, data, mWriteP);
if (mExpectVariableLengthImmWrite)
{
INFO_LOG(SP1, "\tvariable length imm write");
if (size == 4)
data = Common::swap32(data);
else if (size == 2)
data = Common::swap16((u16)data);
mWriteBuffer.write(size, &data);
return;
}
else if (mWriteP != INVALID_P)
{
if (mWriteP + size > BBA_MEM_SIZE)
{
ERROR_LOG(SP1, "write error: writep + size = %04x + %i", mWriteP, size);
return;
}
INFO_LOG(SP1, "\twrite to BBA address %0*x, %i byte%s: %0*x",
mWriteP >= CB_OFFSET ? 4 : 2, mWriteP, size, (size==1?"":"s"), size*2, data);
switch (mWriteP)
{
case BBA_NCRA:
{
INFO_LOG(SP1, "\t\tNCRA");
// TODO is it really necessary to check last value?
u8 NCRA_old = mBbaMem[BBA_NCRA];
mBbaMem[BBA_NCRA] = data;
#define RISE(flags) ((mBbaMem[BBA_NCRA] & flags) && !(NCRA_old & flags))
if (RISE(NCRA_RESET))
{
INFO_LOG(SP1, "\t\treset");
activate();
}
if (RISE(NCRA_SR))
{
INFO_LOG(SP1, "\t\tstart receive");
startRecv();
}
if (RISE(NCRA_ST1))
{
INFO_LOG(SP1, "\t\tstart transmit");
if (!mReadyToSend)
{
INFO_LOG(SP1, "\t\ttramsit without a packet!");
}
sendPacket(mWriteBuffer.p(), mWriteBuffer.size());
mReadyToSend = false;
}
}
break;
case 0x03:
mBbaMem[0x03] = ~data;
if (data & 0x80)
m_bInterruptSet = false;
break;
case BBA_IR:
_dbg_assert_(SP1, size == 1);
INFO_LOG(SP1, "\t\tinterrupt reset %02x & ~(%02x) => %02x",
mBbaMem[BBA_IR], MAKE(u8, data), mBbaMem[BBA_IR] & ~MAKE(u8, data));
mBbaMem[BBA_IR] &= ~MAKE(u8, data);
break;
case BBA_RWP: // RWP - Receive Buffer Write Page Pointer
INFO_LOG(SP1, "\t\tRWP");
_dbg_assert_(SP1, size == 2 || size == 1);
//_dbg_assert_(SP1, data == (u32)((u16)mCbw.p_write() + CB_OFFSET) >> 8);
if (data != (u32)((u16)mCbw.p_write() + CB_OFFSET) >> 8)
{
ERROR_LOG(SP1, "BBA RWP ASSERT data %x p_write %lx",
data, (unsigned long)mCbw.p_write());
}
break;
case BBA_RRP: // RRP - Receive Buffer Read Page Pointer
INFO_LOG(SP1, "\t\tRRP");
_dbg_assert_(SP1, size == 2 || size == 1);
mRBRPP = (u8)data << 8; // Hope this works with both write sizes.
mRBEmpty = mRBRPP == ((u16)mCbw.p_write() + CB_OFFSET);
checkRecvBuffer();
break;
case BBA_NWAYC:
INFO_LOG(SP1, "\t\tNWAYC");
mBbaMem[BBA_NWAYC] = data;
if (mBbaMem[BBA_NWAYC] & (NWAYC_ANE | NWAYC_ANS_RA))
{
// say we've successfully negotiated for 10 Mbit full duplex
// should placate libogc
mBbaMem[BBA_NWAYS] = NWAYS_LS100 | NWAYS_LPNWAY | NWAYS_ANCLPT | NWAYS_100TXF;
}
break;
default:
INFO_LOG(SP1, "\t\tdefault: data: %0*x to %x", size * 2, data, mWriteP);
memcpy(mBbaMem + mWriteP, &data, size);
mWriteP = mWriteP + (u16)size;
}
return;
}
else if (size == 2 && data == 0)
{
INFO_LOG(SP1, "\trequest cid");
mSpecialImmData = EXI_DEVTYPE_ETHER;
mExpectSpecialImmRead = true;
return;
}
else if ((size == 4 && (data & 0xC0000000) == 0xC0000000) ||
(size == 2 && (data & 0x4000) == 0x4000))
{
INFO_LOG(SP1, "\twrite to register");
if (size == 4)
mWriteP = (u8)getbitsw(data, 16, 23);
else //size == 2
mWriteP = (u8)getbitsw(data & ~0x4000, 16, 23); // Dunno about this...
if (mWriteP == BBA_WRTXFIFOD)
{
mWriteBuffer.clear();
mExpectVariableLengthImmWrite = true;
INFO_LOG(SP1, "\t\tprepared for variable length write to address 0x48");
}
else else
transfer.address = (data >> 8) & 0xffff;
transfer.direction = IsWriteCommand(data) ? transfer.WRITE : transfer.READ;
DEBUG_LOG(SP1, "%s %s %s %x",
IsMXCommand(data) ? "mx " : "exi",
IsWriteCommand(data) ? "write" : "read ",
GetRegisterName(),
transfer.address);
if (transfer.address == BBA_IOB && transfer.region == transfer.MX)
{ {
INFO_LOG(SP1, "\t\twritep set to %0*x", size * 2, mWriteP); ERROR_LOG(SP1, "Usage of BBA_IOB indicates that the rx packet descriptor has been corrupted, killing dolphin...");
exit(0);
} }
// transfer has been setup
return; return;
} }
else if ((size == 4 && (data & 0xC0000000) == 0x80000000) ||
(size == 2 && (data & 0x4000) == 0x0000)) // Reach here if we're actually writing data to the EXI or MX region.
DEBUG_LOG(SP1, "%s write %0*x",
transfer.region == transfer.MX ? "mx " : "exi", size * 2, data);
if (transfer.region == transfer.EXI)
{ {
// Read from BBA Register switch (transfer.address)
if (size == 4)
mReadP = (data >> 8) & 0xffff;
else //size == 2
mReadP = (u8)getbitsw(data, 16, 23);
INFO_LOG(SP1, "Read from BBA register 0x%x", mReadP);
switch (mReadP)
{ {
case BBA_NCRA: case INTERRUPT:
// These Two lines were commented out in Whinecube exi_status.interrupt &= data ^ 0xff;
//mBbaMem[mReadP] = 0x00;
//if(!sendInProgress())
mBbaMem[BBA_NCRA] &= ~(NCRA_ST0 | NCRA_ST1);
INFO_LOG(SP1, "\tNCRA %02x", mBbaMem[BBA_NCRA]);
break; break;
case BBA_NCRB: // Revision ID case INTERRUPT_MASK:
INFO_LOG(SP1, "\tNCRB"); exi_status.interrupt_mask = data;
break;
case BBA_NAFR_PAR0:
INFO_LOG(SP1, "\tMac Address");
memcpy(mBbaMem + mReadP, mac_address, 6);
break;
case 0x03: // status TODO more fields
mBbaMem[mReadP] = m_bInterruptSet ? 0x80 : 0;
INFO_LOG(SP1, "\tStatus %x", mBbaMem[mReadP]);
break;
case BBA_LTPS:
INFO_LOG(SP1, "\tLPTS");
break;
case BBA_IMR:
INFO_LOG(SP1, "\tIMR");
break;
case BBA_IR:
INFO_LOG(SP1, "\tIR");
break;
case BBA_RWP:
case BBA_RWP+1:
MAKE(u16, mBbaMem[BBA_RWP]) = Common::swap16((u16)mCbw.p_write() + CB_OFFSET);
INFO_LOG(SP1, "\tRWP 0x%04x", MAKE(u16, mBbaMem[mReadP]));
break;
case BBA_RRP:
case BBA_RRP+1:
MAKE(u16, mBbaMem[BBA_RRP]) = Common::swap16(mRBRPP);
INFO_LOG(SP1, "\tRRP 0x%04x", MAKE(u16, mBbaMem[mReadP]));
break;
case 0x3A: // bit 1 set if no data available
INFO_LOG(SP1, "\tBit 1 set!");
//mBbaMem[mReadP] = !mRBEmpty;
break;
case BBA_TWP:
case BBA_TWP+1:
INFO_LOG(SP1, "\tTWP");
break;
case BBA_NWAYC:
INFO_LOG(SP1, "\tNWAYC");
break;
case BBA_NWAYS:
mBbaMem[BBA_NWAYS] = NWAYS_LS100 | NWAYS_LPNWAY | NWAYS_ANCLPT | NWAYS_100TXF;
INFO_LOG(SP1, "\tNWAYS %02x", mBbaMem[BBA_NWAYS]);
break;
case BBA_SI_ACTRL:
INFO_LOG(SP1, "\tSI_ACTRL");
break;
default:
ERROR_LOG(SP1, "UNKNOWN BBA REG READ %02x", mReadP);
break; break;
} }
return;
} }
else
ERROR_LOG(SP1, "\tNot expecting imm write of size %d", size); {
ERROR_LOG(SP1, "\t\t SKIPPING!"); MXCommandHandler(data, size);
}
} }
u32 CEXIETHERNET::ImmRead(u32 size) u32 CEXIETHERNET::ImmRead(u32 size)
{ {
INFO_LOG(SP1, "imm read %i readp %x", size, mReadP); u32 ret = 0;
if (mExpectSpecialImmRead) if (transfer.region == transfer.EXI)
{ {
INFO_LOG(SP1, "\tspecial imm read %08x", mSpecialImmData); switch (transfer.address)
mExpectSpecialImmRead = false;
return mSpecialImmData;
}
if (mReadP != INVALID_P)
{
if (mReadP + size > BBA_MEM_SIZE)
{ {
ERROR_LOG(SP1, "\tRead error: readp + size = %04x + %i", mReadP, size); case EXI_ID:
return 0; ret = EXI_DEVTYPE_ETHER;
break;
case REVISION_ID:
ret = exi_status.revision_id;
break;
case DEVICE_ID:
ret = exi_status.device_id;
break;
case ACSTART:
ret = exi_status.acstart;
break;
case INTERRUPT:
ret = exi_status.interrupt;
break;
} }
u32 uResult = 0;
memcpy(&uResult, mBbaMem + mReadP, size);
uResult = Common::swap32(uResult); transfer.address += size;
INFO_LOG(SP1, "\tRead from BBA address %0*x, %i byte%s: %0*x",
mReadP >= CB_OFFSET ? 4 : 2, mReadP,
size, (size==1?"":"s"),size*2, getbitsw(uResult, 0, size * 8 - 1));
mReadP = mReadP + size;
return uResult;
} }
else else
{ {
ERROR_LOG(SP1, "Unhandled imm read size %d", size); for (int i = size - 1; i >= 0; i--)
return 0; ret |= mBbaMem[transfer.address++] << (i * 8);
} }
DEBUG_LOG(SP1, "imm r%i: %0*x", size, size * 2, ret);
ret <<= (4 - size) * 8;
return ret;
} }
void CEXIETHERNET::DMAWrite(u32 addr, u32 size) void CEXIETHERNET::DMAWrite(u32 addr, u32 size)
{ {
if (mExpectVariableLengthImmWrite) DEBUG_LOG(SP1, "dma w: %08x %x", addr, size);
{
INFO_LOG(SP1, "DMA Write: Address is 0x%x and size is 0x%x", addr, size);
mWriteBuffer.write(size, Memory::GetPointer(addr));
return;
}
ERROR_LOG(SP1, "Unhandled BBA DMA write: %i, %08x", size, addr); if (transfer.region == transfer.MX &&
transfer.direction == transfer.WRITE &&
transfer.address == BBA_WRTXFIFOD)
{
DirectFIFOWrite(Memory::GetPointer(addr), size);
}
else
{
ERROR_LOG(SP1, "dma w in %s %s mode - not implemented",
transfer.region == transfer.EXI ? "exi" : "mx",
transfer.direction == transfer.READ ? "read" : "write");
}
} }
void CEXIETHERNET::DMARead(u32 addr, u32 size) void CEXIETHERNET::DMARead(u32 addr, u32 size)
{ {
if (mReadP != INVALID_P) DEBUG_LOG(SP1, "dma r: %08x %x", addr, size);
{
if (mReadP + size > BBA_MEM_SIZE)
{
INFO_LOG(SP1, "Read error: mReadP + size = %04x + %i", mReadP, size);
return;
}
memcpy(Memory::GetPointer(addr), mBbaMem + mReadP, size);
INFO_LOG(SP1, "DMA Read from BBA address %0*x, %i bytes to %08x",
mReadP >= CB_OFFSET ? 4 : 2, mReadP, size, addr);
mReadP = mReadP + (u16)size;
return;
}
ERROR_LOG(SP1, "Unhandled BBA DMA read: %i, %08x", size, addr); memcpy(Memory::GetPointer(addr), &mBbaMem[transfer.address], size);
transfer.address += size;
} }
void CEXIETHERNET::DoState(PointerWrap &p) void CEXIETHERNET::DoState(PointerWrap &p)
{ {
p.Do(m_uPosition);
p.Do(m_uCommand);
p.Do(m_bInterruptSet);
p.Do(mWriteP);
p.Do(mReadP);
p.Do(mExpectSpecialImmRead);
p.Do(mSpecialImmData);
p.Do(Activated);
p.Do(mRBRPP);
p.Do(mRBEmpty);
p.Do(mBbaMem); p.Do(mBbaMem);
p.Do(mExpectVariableLengthImmWrite); // TODO ... the rest...
p.Do(mReadyToSend); ERROR_LOG(SP1, "CEXIETHERNET::DoState not implemented!");
p.Do(RegisterBlock);
// TODO?
//mWriteBuffer.DoState(p);
//mCbw.DoState(p);
} }
//#pragma optimize("",on) bool CEXIETHERNET::IsMXCommand(u32 const data)
{
return !!(data & (1 << 31));
}
bool CEXIETHERNET::IsWriteCommand(u32 const data)
{
return IsMXCommand(data) ? !!(data & (1 << 30)) : !!(data & (1 << 14));
}
char const * const CEXIETHERNET::GetRegisterName() const
{
#define STR_RETURN(x) case x: return #x;
if (transfer.region == transfer.EXI)
{
switch (transfer.address)
{
STR_RETURN(EXI_ID)
STR_RETURN(REVISION_ID)
STR_RETURN(INTERRUPT)
STR_RETURN(INTERRUPT_MASK)
STR_RETURN(DEVICE_ID)
STR_RETURN(ACSTART)
STR_RETURN(HASH_READ)
STR_RETURN(HASH_WRITE)
STR_RETURN(HASH_STATUS)
STR_RETURN(RESET)
default: return "unknown";
}
}
else
{
switch (transfer.address)
{
STR_RETURN(BBA_NCRA)
STR_RETURN(BBA_NCRB)
STR_RETURN(BBA_LTPS)
STR_RETURN(BBA_LRPS)
STR_RETURN(BBA_IMR)
STR_RETURN(BBA_IR)
STR_RETURN(BBA_BP)
STR_RETURN(BBA_TLBP)
STR_RETURN(BBA_TWP)
STR_RETURN(BBA_IOB)
STR_RETURN(BBA_TRP)
STR_RETURN(BBA_RWP)
STR_RETURN(BBA_RRP)
STR_RETURN(BBA_RHBP)
STR_RETURN(BBA_RXINTT)
STR_RETURN(BBA_NAFR_PAR0)
STR_RETURN(BBA_NAFR_PAR1)
STR_RETURN(BBA_NAFR_PAR2)
STR_RETURN(BBA_NAFR_PAR3)
STR_RETURN(BBA_NAFR_PAR4)
STR_RETURN(BBA_NAFR_PAR5)
STR_RETURN(BBA_NAFR_MAR0)
STR_RETURN(BBA_NAFR_MAR1)
STR_RETURN(BBA_NAFR_MAR2)
STR_RETURN(BBA_NAFR_MAR3)
STR_RETURN(BBA_NAFR_MAR4)
STR_RETURN(BBA_NAFR_MAR5)
STR_RETURN(BBA_NAFR_MAR6)
STR_RETURN(BBA_NAFR_MAR7)
STR_RETURN(BBA_NWAYC)
STR_RETURN(BBA_NWAYS)
STR_RETURN(BBA_GCA)
STR_RETURN(BBA_MISC)
STR_RETURN(BBA_TXFIFOCNT)
STR_RETURN(BBA_WRTXFIFOD)
STR_RETURN(BBA_MISC2)
STR_RETURN(BBA_SI_ACTRL)
STR_RETURN(BBA_SI_STATUS)
STR_RETURN(BBA_SI_ACTRL2)
default:
if (transfer.address >= 0x100 &&
transfer.address <= 0xfff)
return "packet buffer";
else
return "unknown";
}
}
#undef STR_RETURN
}
void CEXIETHERNET::MXHardReset()
{
memset(mBbaMem, 0, BBA_MEM_SIZE);
mBbaMem[BBA_NCRB] = NCRB_PR;
mBbaMem[BBA_NWAYC] = NWAYC_LTE | NWAYC_ANE;
mBbaMem[BBA_MISC] = MISC1_TPF | MISC1_TPH | MISC1_TXF | MISC1_TXH;
}
void CEXIETHERNET::MXCommandHandler(u32 data, u32 size)
{
switch (transfer.address)
{
case BBA_NCRA:
if (data & NCRA_RESET)
{
DEBUG_LOG(SP1, "software reset");
//MXSoftReset();
Activate();
}
if ((mBbaMem[BBA_NCRA] & NCRA_SR) ^ (data & NCRA_SR))
{
DEBUG_LOG(SP1, "%s rx", (data & NCRA_SR) ? "start" : "stop");
if (data & NCRA_SR)
RecvStart();
else
RecvStop();
}
// Only start transfer if there isn't one currently running
if (!(mBbaMem[BBA_NCRA] & (NCRA_ST0 | NCRA_ST1)))
{
// Technically transfer dma status is kept in TXDMA - not implemented
if (data & NCRA_ST0)
{
WARN_LOG(SP1, "start tx - local dma");
SendFromPacketBuffer();
}
else if (data & NCRA_ST1)
{
DEBUG_LOG(SP1, "start tx - direct fifo");
SendFromDirectFIFO();
// Kind of a hack: send completes instantly, so we don't
// actually write the "send in status" bit to the register
data &= ~NCRA_ST1;
}
}
goto write_to_register;
case BBA_WRTXFIFOD:
if (size == 2)
data = Common::swap16(data & 0xffff);
else if (size == 4)
data = Common::swap32(data);
DirectFIFOWrite((u8 *)&data, size);
// Do not increment address
return;
case BBA_IR:
data &= (data & 0xff) ^ 0xff;
goto write_to_register;
write_to_register:
default:
for (int i = size - 1; i >= 0; i--)
{
mBbaMem[transfer.address++] = (data >> (i * 8)) & 0xff;
}
return;
}
}
void CEXIETHERNET::DirectFIFOWrite(u8 *data, u32 size)
{
// In direct mode, the hardware handles creating the state required by the
// GMAC instead of finagling with packet descriptors and such
u16 *tx_fifo_count = (u16 *)&mBbaMem[BBA_TXFIFOCNT];
memcpy(tx_fifo + *tx_fifo_count, data, size);
*tx_fifo_count += size;
// TODO not sure this mask is correct.
// However, BBA_TXFIFOCNT should never get even close to this amount,
// so it shouldn't matter
*tx_fifo_count &= (1 << 12) - 1;
}
void CEXIETHERNET::SendFromDirectFIFO()
{
SendFrame(tx_fifo, *(u16 *)&mBbaMem[BBA_TXFIFOCNT]);
}
void CEXIETHERNET::SendFromPacketBuffer()
{
ERROR_LOG(SP1, "tx packet buffer not implemented");
}
void CEXIETHERNET::SendComplete()
{
mBbaMem[BBA_NCRA] &= ~(NCRA_ST0 | NCRA_ST1);
*(u16 *)&mBbaMem[BBA_TXFIFOCNT] = 0;
if (mBbaMem[BBA_IMR] & INT_T)
{
mBbaMem[BBA_IR] |= INT_T;
exi_status.interrupt |= exi_status.TRANSFER;
}
mBbaMem[BBA_LTPS] = 0;
}
inline u8 CEXIETHERNET::HashIndex(u8 *dest_eth_addr)
{
// Calculate crc
u32 crc = 0xffffffff;
for (size_t byte_num = 0; byte_num < 6; ++byte_num)
{
u8 cur_byte = dest_eth_addr[byte_num];
for (size_t bit = 0; bit < 8; ++bit)
{
u8 carry = ((crc >> 31) & 1) ^ (cur_byte & 1);
crc <<= 1;
cur_byte >>= 1;
if (carry)
crc = (crc ^ 0x4c11db6) | carry;
}
}
// return bits used as index
return crc >> 26;
}
inline bool CEXIETHERNET::RecvMACFilter()
{
static u8 const broadcast[] = { 0xff, 0xff, 0xff, 0xff, 0xff, 0xff };
// Accept all destination addrs?
if (mBbaMem[BBA_NCRB] & NCRB_PR)
return true;
// Unicast?
if ((mRecvBuffer[0] & 0x01) == 0)
{
return memcmp(mRecvBuffer, &mBbaMem[BBA_NAFR_PAR0], 6) == 0;
}
else if (memcmp(mRecvBuffer, broadcast, 6) == 0)
{
// Accept broadcast?
return !!(mBbaMem[BBA_NCRB] & NCRB_AB);
}
else if (mBbaMem[BBA_NCRB] & NCRB_PM)
{
// Accept all multicast
return true;
}
else
{
// Lookup the dest eth address in the hashmap
u16 index = HashIndex(mRecvBuffer);
return !!(mBbaMem[BBA_NAFR_MAR0 + index / 8] & (1 << (index % 8)));
}
}
inline void CEXIETHERNET::inc_rwp()
{
u16 *rwp = (u16 *)&mBbaMem[BBA_RWP];
if (*rwp + 1 == page_ptr(BBA_RHBP))
*rwp = page_ptr(BBA_BP);
else
(*rwp)++;
}
// This function is on the critical path for recving data.
// Be very careful about calling into the logger and other slow things
bool CEXIETHERNET::RecvHandlePacket()
{
u8 *write_ptr;
u8 *end_ptr;
u8 *read_ptr;
Descriptor *descriptor;
u32 status = 0;
u16 rwp_initial = page_ptr(BBA_RWP);
if (!RecvMACFilter())
goto wait_for_next;
#ifdef BBA_TRACK_PAGE_PTRS
WARN_LOG(SP1, "RecvHandlePacket %x\n%s", mRecvBufferLength,
ArrayToString(mRecvBuffer, mRecvBufferLength, 0x100).c_str());
WARN_LOG(SP1, "%x %x %x %x",
page_ptr(BBA_BP),
page_ptr(BBA_RRP),
page_ptr(BBA_RWP),
page_ptr(BBA_RHBP));
#endif
write_ptr = ptr_from_page_ptr(BBA_RWP);
end_ptr = ptr_from_page_ptr(BBA_RHBP);
read_ptr = ptr_from_page_ptr(BBA_RRP);
descriptor = (Descriptor *)write_ptr;
write_ptr += 4;
for (u32 i = 0, off = 4; i < mRecvBufferLength; ++i, ++off)
{
*write_ptr++ = mRecvBuffer[i];
if (off == 0xff)
{
off = 0;
inc_rwp();
}
if (write_ptr == end_ptr)
write_ptr = ptr_from_page_ptr(BBA_BP);
if (write_ptr == read_ptr)
{
/*
halt copy
if (cur_packet_size >= PAGE_SIZE)
desc.status |= FO | BF
if (RBFIM)
raise RBFI
if (AUTORCVR)
discard bad packet
else
inc MPC instad of recving packets
*/
status |= DESC_FO | DESC_BF;
mBbaMem[BBA_IR] |= mBbaMem[BBA_IMR] & INT_RBF;
break;
}
}
// Align up to next page
if ((mRecvBufferLength + 4) % 256)
inc_rwp();
#ifdef BBA_TRACK_PAGE_PTRS
WARN_LOG(SP1, "%x %x %x %x",
page_ptr(BBA_BP),
page_ptr(BBA_RRP),
page_ptr(BBA_RWP),
page_ptr(BBA_RHBP));
#endif
// Is the current frame multicast?
if (mRecvBuffer[0] & 0x01)
status |= DESC_MF;
if (status & DESC_BF)
{
if (mBbaMem[BBA_MISC2] & MISC2_AUTORCVR)
{
*(u16 *)&mBbaMem[BBA_RWP] = rwp_initial;
}
else
{
ERROR_LOG(SP1, "RBF while AUTORCVR == 0!");
}
}
descriptor->set(*(u16 *)&mBbaMem[BBA_RWP], 4 + mRecvBufferLength, status);
mBbaMem[BBA_LRPS] = status;
// Raise interrupt
if (mBbaMem[BBA_IMR] & INT_R)
{
mBbaMem[BBA_IR] |= INT_R;
exi_status.interrupt |= exi_status.TRANSFER;
}
else
{
// This occurs if software is still processing the last raised recv interrupt
WARN_LOG(SP1, "NOT raising recv interrupt");
}
wait_for_next:
if (mBbaMem[BBA_NCRA] & NCRA_SR)
RecvStart();
return true;
}

353
Source/Core/Core/Src/HW/EXI_DeviceEthernet.h
View File

@ -20,107 +20,16 @@
#include "Thread.h" #include "Thread.h"
inline u8 makemaskb(int start, int end) { // Network Control Register A
return (u8)_rotl((2 << (end - start)) - 1, 7 - end);
}
inline u32 makemaskh(int start, int end) {
return (u32)_rotl((2 << (end - start)) - 1, 15 - end);
}
inline u32 makemaskw(int start, int end) {
return _rotl((2 << (end - start)) - 1, 31 - end);
}
inline u8 getbitsb(u8 byte, int start, int end) {
return (byte & makemaskb(start, end)) >> u8(7 - end);
}
inline u32 getbitsh(u32 hword, int start, int end) {
return (hword & makemaskh(start, end)) >> u32(15 - end);
}
inline u32 getbitsw(u32 dword, int start, int end) {
return (dword & makemaskw(start, end)) >> (31 - end);
}
class WriteBuffer
{
public:
WriteBuffer(u32 s) : _size(0)
{
_buffer = (u8*)malloc(s*sizeof(u8));
ucapacity = s;
}
~WriteBuffer() { free(_buffer); }
u32 size() const { return _size; }
u32 capacity() const { return ucapacity; }
void write(u32 s, const void *src)
{
if (_size + s >= ucapacity)
{
INFO_LOG(SP1, "Write too large!");
exit(0);
}
memcpy(_buffer + _size, src, s);
_size = _size + s;
}
void clear() { _size = 0; }
u8* p() { return _buffer; }
private:
u8* _buffer;
u32 ucapacity;
u32 _size;
};
// Doesn't contain error checks for wraparound writes
class CyclicBufferWriter
{
public:
CyclicBufferWriter(u8 *buffer, size_t cap) {
_buffer = buffer; _capacity = cap; _write = 0;
}
size_t p_write() const { return _write; }
void reset() { _write = 0; }
void write(void *src, size_t size) {
_dbg_assert_(SP1, size < _capacity);
u8* bsrc = (u8*) src;
if (_write + size >= _capacity)
{
// wraparound
memcpy(_buffer + _write, src, _capacity - _write);
memcpy(_buffer, bsrc + (_capacity - _write), size - (_capacity - _write));
_write = size - (_capacity - _write);
} else {
memcpy(_buffer + _write, src, size);
_write += size;
}
//DEBUG_LOG(SP1, "CBWrote %i bytes", size);
}
// Aligns the write pointer to steps of 0x100, like the real BBA
void align() {
_write = (_write + 0xff) & ~0xff;
if(_write >= _capacity)
_write -= _capacity;
}
private:
size_t _write;
size_t _capacity;
u8 *_buffer;
};
#define INVALID_P 0xFFFF
// Network Control Register A, RW
enum NCRA enum NCRA
{ {
NCRA_RESET = 0x01, // RESET NCRA_RESET = 0x01, // RESET
NCRA_ST0 = 0x02, // Start transmit command/status NCRA_ST0 = 0x02, // Start transmit command/status
NCRA_ST1 = 0x04, // " NCRA_ST1 = 0x04, // "
NCRA_SR = 0x08, // Start Receive NCRA_SR = 0x08 // Start Receive
}; };
// Network Control Register B, RW // Network Control Register B
enum NCRB enum NCRB
{ {
NCRB_PR = 0x01, // Promiscuous Mode NCRB_PR = 0x01, // Promiscuous Mode
@ -129,11 +38,11 @@ enum NCRB
NCRB_PB = 0x08, // Pass Bad Frame NCRB_PB = 0x08, // Pass Bad Frame
NCRB_AB = 0x10, // Accept Broadcast NCRB_AB = 0x10, // Accept Broadcast
NCRB_HBD = 0x20, // reserved NCRB_HBD = 0x20, // reserved
NCRB_RXINTC = 0xC0, // Receive Interrupt Counter (mask) NCRB_RXINTC = 0xC0 // Receive Interrupt Counter (mask)
}; };
// Interrupt Mask Register, RW, 00h // Interrupt Mask Register
// Interrupt Register, RW, 00h // Interrupt Register
enum Interrupts enum Interrupts
{ {
INT_FRAG = 0x01, // Fragment Counter INT_FRAG = 0x01, // Fragment Counter
@ -143,17 +52,20 @@ enum Interrupts
INT_T_ERR = 0x10, // Transmit Error INT_T_ERR = 0x10, // Transmit Error
INT_FIFO_ERR = 0x20, // FIFO Error INT_FIFO_ERR = 0x20, // FIFO Error
INT_BUS_ERR = 0x40, // BUS Error INT_BUS_ERR = 0x40, // BUS Error
INT_RBF = 0x80, // RX Buffer Full INT_RBF = 0x80 // RX Buffer Full
}; };
// NWAY Configuration Register, RW, 84h // NWAY Configuration Register
enum NWAYC enum NWAYC
{ {
NWAYC_FD = 0x01, // Full Duplex Mode NWAYC_FD = 0x01, // Full Duplex Mode
NWAYC_PS100 = 0x02, // Port Select 100/10 NWAYC_PS100_10 = 0x02, // Port Select 100/10
NWAYC_ANE = 0x03, // Autonegotiation Enable NWAYC_ANE = 0x04, // Autonegotiate enable
NWAYC_ANS_RA = 0x04, // Restart Autonegotiation
NWAYC_LTE = 0x08, // Link Test Enable // Autonegotiation status bits...
NWAYC_NTTEST = 0x40, // Reserved
NWAYC_LTE = 0x80 // Link Test Enable
}; };
enum NWAYS enum NWAYS
@ -168,6 +80,30 @@ enum NWAYS
NWAYS_10TXH = 0x80 NWAYS_10TXH = 0x80
}; };
enum MISC1
{
MISC1_BURSTDMA = 0x01,
MISC1_DISLDMA = 0x02,
MISC1_TPF = 0x04,
MISC1_TPH = 0x08,
MISC1_TXF = 0x10,
MISC1_TXH = 0x20,
MISC1_TXFIFORST = 0x40,
MISC1_RXFIFORST = 0x80
};
enum MISC2
{
MISC2_HBRLEN0 = 0x01,
MISC2_HBRLEN1 = 0x02,
MISC2_RUNTSIZE = 0x04,
MISC2_DREQBCTRL = 0x08,
MISC2_RINTSEL = 0x10,
MISC2_ITPSEL = 0x20,
MISC2_A11A8EN = 0x40,
MISC2_AUTORCVR = 0x80
};
enum enum
{ {
BBA_NCRA = 0x00, BBA_NCRA = 0x00,
@ -182,6 +118,7 @@ enum
BBA_BP = 0x0a, BBA_BP = 0x0a,
BBA_TLBP = 0x0c, BBA_TLBP = 0x0c,
BBA_TWP = 0x0e, BBA_TWP = 0x0e,
BBA_IOB = 0x10,
BBA_TRP = 0x12, BBA_TRP = 0x12,
BBA_RWP = 0x16, BBA_RWP = 0x16,
BBA_RRP = 0x18, BBA_RRP = 0x18,
@ -195,6 +132,14 @@ enum
BBA_NAFR_PAR3 = 0x23, BBA_NAFR_PAR3 = 0x23,
BBA_NAFR_PAR4 = 0x24, BBA_NAFR_PAR4 = 0x24,
BBA_NAFR_PAR5 = 0x25, BBA_NAFR_PAR5 = 0x25,
BBA_NAFR_MAR0 = 0x26,
BBA_NAFR_MAR1 = 0x27,
BBA_NAFR_MAR2 = 0x28,
BBA_NAFR_MAR3 = 0x29,
BBA_NAFR_MAR4 = 0x2a,
BBA_NAFR_MAR5 = 0x2b,
BBA_NAFR_MAR6 = 0x2c,
BBA_NAFR_MAR7 = 0x2d,
BBA_NWAYC = 0x30, BBA_NWAYC = 0x30,
BBA_NWAYS = 0x31, BBA_NWAYS = 0x31,
@ -210,37 +155,51 @@ enum
BBA_SI_ACTRL = 0x5c, BBA_SI_ACTRL = 0x5c,
BBA_SI_STATUS = 0x5d, BBA_SI_STATUS = 0x5d,
BBA_SI_ACTRL2 = 0x60, BBA_SI_ACTRL2 = 0x60
}; };
enum enum
{ {
BBA_RECV_SIZE = 0x800, BBA_NUM_PAGES = 0x10,
BBA_MEM_SIZE = 0x1000, BBA_PAGE_SIZE = 0x100,
BBA_MEM_SIZE = BBA_NUM_PAGES * BBA_PAGE_SIZE
CB_OFFSET = 0x100,
CB_SIZE = (BBA_MEM_SIZE - CB_OFFSET),
SIZEOF_ETH_HEADER = 0xe,
SIZEOF_RECV_DESCRIPTOR = 4,
EXI_DEVTYPE_ETHER = 0x04020200,
}; };
enum enum { EXI_DEVTYPE_ETHER = 0x04020200 };
enum SendStatus
{ {
EXPECT_NONE = 0, DESC_CC0 = 0x01,
EXPECT_ID DESC_CC1 = 0x02,
DESC_CC2 = 0x04,
DESC_CC3 = 0x08,
DESC_CRSLOST= 0x10,
DESC_UF = 0x20,
DESC_OWC = 0x40,
DESC_OWN = 0x80
}; };
enum RecvStatus
{
DESC_BF = 0x01,
DESC_CRC = 0x02,
DESC_FAE = 0x04,
DESC_FO = 0x08,
DESC_RW = 0x10,
DESC_MF = 0x20,
DESC_RF = 0x40,
DESC_RERR = 0x80
};
#define BBA_RECV_SIZE 0x800
class CEXIETHERNET : public IEXIDevice class CEXIETHERNET : public IEXIDevice
{ {
public: public:
CEXIETHERNET(const std::string& mac_addr); CEXIETHERNET();
~CEXIETHERNET(); virtual ~CEXIETHERNET();
void SetMAC(u8 *new_addr); void SetCS(int cs);
void SetCS(int _iCS);
bool IsPresent(); bool IsPresent();
void Update();
bool IsInterruptSet(); bool IsInterruptSet();
void ImmWrite(u32 data, u32 size); void ImmWrite(u32 data, u32 size);
u32 ImmRead(u32 size); u32 ImmRead(u32 size);
@ -249,61 +208,133 @@ public:
void DoState(PointerWrap &p); void DoState(PointerWrap &p);
//private: //private:
// STATE_TO_SAVE struct
u32 m_uPosition; {
u32 m_uCommand; enum
{
READ,
WRITE
} direction;
bool m_bInterruptSet; enum
u16 mWriteP, mReadP; {
EXI,
MX
} region;
bool mExpectSpecialImmRead; //reset to false on deselect u16 address;
u32 mSpecialImmData; bool valid;
bool Activated; } transfer;
u16 mRBRPP; //RRP - Receive Buffer Read Page Pointer
bool mRBEmpty;
u8 mBbaMem[BBA_MEM_SIZE];
WriteBuffer mWriteBuffer;
CyclicBufferWriter mCbw;
bool mExpectVariableLengthImmWrite;
bool mReadyToSend;
u8 RegisterBlock[0x1000];
enum enum
{ {
CMD_ID = 0x00, EXI_ID,
CMD_READ_REG = 0x01, REVISION_ID,
INTERRUPT_MASK,
INTERRUPT,
DEVICE_ID,
ACSTART,
HASH_READ = 8,
HASH_WRITE,
HASH_STATUS = 0xb,
RESET = 0xf
}; };
void recordSendComplete(); // exi regs
bool sendPacket(u8 *etherpckt, int size); struct EXIStatus
bool checkRecvBuffer(); {
bool handleRecvdPacket(); enum
{
TRANSFER = 0x80
};
//TAP interface u8 revision_id;
bool activate(); u8 interrupt_mask;
bool CheckRecieved(); u8 interrupt;
bool deactivate(); u16 device_id;
bool isActivated(); u8 acstart;
bool resume(); u32 hash_challenge;
bool startRecv(); u32 hash_response;
bool cbwriteDescriptor(u32 size); u8 hash_status;
EXIStatus()
{
device_id = 0xd107;
revision_id = 0;//0xf0;
acstart = 0x4e;
volatile bool mWaiting; interrupt_mask = 0;
u8 mac_address[6]; interrupt = 0;
u8 mRecvBuffer[BBA_RECV_SIZE]; hash_challenge = 0;
#ifdef _WIN32 hash_response = 0;
hash_status = 0;
}
} exi_status;
struct Descriptor
{
u32 word;
inline void set(u32 const next_page, u32 const packet_length, u32 const status)
{
word = 0;
word |= (status & 0xff) << 24;
word |= (packet_length & 0xfff) << 12;
word |= next_page & 0xfff;
}
};
inline u16 page_ptr(int const index) const
{
return ((u16)mBbaMem[index + 1] << 8) | mBbaMem[index];
}
inline u8 *ptr_from_page_ptr(int const index) const
{
return &mBbaMem[page_ptr(index) << 8];
}
bool IsMXCommand(u32 const data);
bool IsWriteCommand(u32 const data);
char const * const GetRegisterName() const;
void MXHardReset();
void MXCommandHandler(u32 data, u32 size);
void DirectFIFOWrite(u8 *data, u32 size);
void SendFromDirectFIFO();
void SendFromPacketBuffer();
void SendComplete();
u8 HashIndex(u8 *dest_eth_addr);
bool RecvMACFilter();
void inc_rwp();
bool RecvHandlePacket();
u8 *tx_fifo;
u8 *mBbaMem;
// TAP interface
bool Activate();
void Deactivate();
bool IsActivated();
bool SendFrame(u8 *frame, u32 size);
bool RecvInit();
bool RecvStart();
void RecvStop();
u8 *mRecvBuffer;
u32 mRecvBufferLength;
#if defined(_WIN32)
HANDLE mHAdapter, mHRecvEvent, mHReadWait; HANDLE mHAdapter, mHRecvEvent, mHReadWait;
DWORD mMtu; DWORD mMtu;
OVERLAPPED mReadOverlapped; OVERLAPPED mReadOverlapped;
DWORD mRecvBufferLength;
static VOID CALLBACK ReadWaitCallback(PVOID lpParameter, BOOLEAN TimerFired); static VOID CALLBACK ReadWaitCallback(PVOID lpParameter, BOOLEAN TimerFired);
#else #elif defined(__linux__)
u32 mRecvBufferLength; int fd;
std::thread readThread;
volatile bool readEnabled;
#endif #endif
}; };
#endif #endif