MsiCommon.cpp revision 377f1df8d6ec248927bcdf0efabf87ab55c4a615
/* $Id$ */
/** @file
* MSI support routines
*/
/*
* Copyright (C) 2010 Oracle Corporation
*
* This file is part of VirtualBox Open Source Edition (OSE), as
* available from http://www.virtualbox.org. This file is free software;
* you can redistribute it and/or modify it under the terms of the GNU
* General Public License (GPL) as published by the Free Software
* Foundation, in version 2 as it comes in the "COPYING" file of the
* VirtualBox OSE distribution. VirtualBox OSE is distributed in the
* hope that it will be useful, but WITHOUT ANY WARRANTY of any kind.
*/
#define LOG_GROUP LOG_GROUP_DEV_PCI
/* Hack to get PCIDEVICEINT declare at the right point - include "PCIInternal.h". */
#define PCI_INCLUDE_PRIVATE
#include <VBox/pci.h>
#include <VBox/msi.h>
#include <VBox/vmm/pdmdev.h>
#include <VBox/log.h>
#include "MsiCommon.h"
/** @todo: use accessors so that raw PCI devices work correctly with MSI. */
DECLINLINE(uint16_t) msiGetMessageControl(PPCIDEVICE pDev)
{
return PCIDevGetWord(pDev, pDev->Int.s.u8MsiCapOffset + VBOX_MSI_CAP_MESSAGE_CONTROL);
}
DECLINLINE(bool) msiIs64Bit(PPCIDEVICE pDev)
{
return pciDevIsMsi64Capable(pDev);
}
DECLINLINE(uint32_t*) msiGetMaskBits(PPCIDEVICE pDev)
{
uint8_t iOff = msiIs64Bit(pDev) ? VBOX_MSI_CAP_MASK_BITS_64 : VBOX_MSI_CAP_MASK_BITS_32;
iOff += pDev->Int.s.u8MsiCapOffset;
return (uint32_t*)(pDev->config + iOff);
}
DECLINLINE(uint32_t*) msiGetPendingBits(PPCIDEVICE pDev)
{
uint8_t iOff = msiIs64Bit(pDev) ? VBOX_MSI_CAP_PENDING_BITS_64 : VBOX_MSI_CAP_PENDING_BITS_32;
iOff += pDev->Int.s.u8MsiCapOffset;
return (uint32_t*)(pDev->config + iOff);
}
DECLINLINE(bool) msiIsEnabled(PPCIDEVICE pDev)
{
return (msiGetMessageControl(pDev) & VBOX_PCI_MSI_FLAGS_ENABLE) != 0;
}
DECLINLINE(uint8_t) msiGetMme(PPCIDEVICE pDev)
{
return (msiGetMessageControl(pDev) & VBOX_PCI_MSI_FLAGS_QSIZE) >> 4;
}
DECLINLINE(RTGCPHYS) msiGetMsiAddress(PPCIDEVICE pDev)
{
if (msiIs64Bit(pDev))
{
uint32_t lo = PCIDevGetDWord(pDev, pDev->Int.s.u8MsiCapOffset + VBOX_MSI_CAP_MESSAGE_ADDRESS_LO);
uint32_t hi = PCIDevGetDWord(pDev, pDev->Int.s.u8MsiCapOffset + VBOX_MSI_CAP_MESSAGE_ADDRESS_HI);
return RT_MAKE_U64(lo, hi);
}
else
{
return PCIDevGetDWord(pDev, pDev->Int.s.u8MsiCapOffset + VBOX_MSI_CAP_MESSAGE_ADDRESS_32);
}
}
DECLINLINE(uint32_t) msiGetMsiData(PPCIDEVICE pDev, int32_t iVector)
{
int16_t iOff = msiIs64Bit(pDev) ? VBOX_MSI_CAP_MESSAGE_DATA_64 : VBOX_MSI_CAP_MESSAGE_DATA_32;
uint16_t lo = PCIDevGetWord(pDev, pDev->Int.s.u8MsiCapOffset + iOff);
// vector encoding into lower bits of message data
uint8_t bits = msiGetMme(pDev);
uint16_t uMask = ((1 << bits) - 1);
lo &= ~uMask;
lo |= iVector & uMask;
return RT_MAKE_U32(lo, 0);
}
DECLINLINE(bool) msiBitJustCleared(uint32_t uOldValue,
uint32_t uNewValue,
uint32_t uMask)
{
return (!!(uOldValue & uMask) && !(uNewValue & uMask));
}
DECLINLINE(bool) msiBitJustSet(uint32_t uOldValue,
uint32_t uNewValue,
uint32_t uMask)
{
return (!(uOldValue & uMask) && !!(uNewValue & uMask));
}
#ifdef IN_RING3
void MsiPciConfigWrite(PPDMDEVINS pDevIns, PCPDMPCIHLP pPciHlp, PPCIDEVICE pDev,
uint32_t u32Address, uint32_t val, unsigned len)
{
int32_t iOff = u32Address - pDev->Int.s.u8MsiCapOffset;
Assert(iOff >= 0 && (pciDevIsMsiCapable(pDev) && iOff < pDev->Int.s.u8MsiCapSize));
Log2(("MsiPciConfigWrite: %d <- %x (%d)\n", iOff, val, len));
uint32_t uAddr = u32Address;
bool f64Bit = msiIs64Bit(pDev);
for (uint32_t i = 0; i < len; i++)
{
uint32_t reg = i + iOff;
uint8_t u8Val = (uint8_t)val;
switch (reg)
{
case 0: /* Capability ID, ro */
case 1: /* Next pointer, ro */
break;
case VBOX_MSI_CAP_MESSAGE_CONTROL:
/* don't change read-only bits: 1-3,7 */
u8Val &= UINT8_C(~0x8e);
pDev->config[uAddr] = u8Val | (pDev->config[uAddr] & UINT8_C(0x8e));
break;
case VBOX_MSI_CAP_MESSAGE_CONTROL + 1:
/* don't change read-only bit 8, and reserved 9-15 */
break;
default:
if (pDev->config[uAddr] != u8Val)
{
int32_t maskUpdated = -1;
/* If we're enabling masked vector, and have pending messages
for this vector, we have to send this message now */
if ( !f64Bit
&& (reg >= VBOX_MSI_CAP_MASK_BITS_32)
&& (reg < VBOX_MSI_CAP_MASK_BITS_32 + 4)
)
{
maskUpdated = reg - VBOX_MSI_CAP_MASK_BITS_32;
}
if ( f64Bit
&& (reg >= VBOX_MSI_CAP_MASK_BITS_64)
&& (reg < VBOX_MSI_CAP_MASK_BITS_64 + 4)
)
{
maskUpdated = reg - VBOX_MSI_CAP_MASK_BITS_64;
}
if (maskUpdated != -1 && msiIsEnabled(pDev))
{
uint32_t* puPending = msiGetPendingBits(pDev);
for (int iBitNum = 0; iBitNum < 8; iBitNum++)
{
int32_t iBit = 1 << iBitNum;
uint32_t uVector = maskUpdated*8 + iBitNum;
if (msiBitJustCleared(pDev->config[uAddr], u8Val, iBit))
{
Log(("msi: mask updated bit %d@%x (%d)\n", iBitNum, uAddr, maskUpdated));
/* To ensure that we're no longer masked */
pDev->config[uAddr] &= ~iBit;
if ((*puPending & (1 << uVector)) != 0)
{
Log(("msi: notify earlier masked pending vector: %d\n", uVector));
MsiNotify(pDevIns, pPciHlp, pDev, uVector, PDM_IRQ_LEVEL_HIGH, 0 /*uTagSrc*/);
}
}
if (msiBitJustSet(pDev->config[uAddr], u8Val, iBit))
{
Log(("msi: mask vector: %d\n", uVector));
}
}
}
pDev->config[uAddr] = u8Val;
}
}
uAddr++;
val >>= 8;
}
}
uint32_t MsiPciConfigRead (PPDMDEVINS pDevIns, PPCIDEVICE pDev, uint32_t u32Address, unsigned len)
{
int32_t iOff = u32Address - pDev->Int.s.u8MsiCapOffset;
Assert(iOff >= 0 && (pciDevIsMsiCapable(pDev) && iOff < pDev->Int.s.u8MsiCapSize));
uint32_t rv = 0;
switch (len)
{
case 1:
rv = PCIDevGetByte(pDev, u32Address);
break;
case 2:
rv = PCIDevGetWord(pDev, u32Address);
break;
case 4:
rv = PCIDevGetDWord(pDev, u32Address);
break;
default:
Assert(false);
}
Log2(("MsiPciConfigRead: %d (%d) -> %x\n", iOff, len, rv));
return rv;
}
int MsiInit(PPCIDEVICE pDev, PPDMMSIREG pMsiReg)
{
if (pMsiReg->cMsiVectors == 0)
return VINF_SUCCESS;
/* We cannot init MSI on raw devices yet. */
Assert(!pciDevIsPassthrough(pDev));
uint16_t cVectors = pMsiReg->cMsiVectors;
uint8_t iCapOffset = pMsiReg->iMsiCapOffset;
uint8_t iNextOffset = pMsiReg->iMsiNextOffset;
bool f64bit = pMsiReg->fMsi64bit;
uint16_t iFlags = 0;
int iMmc;
/* Compute multiple-message capable bitfield */
for (iMmc = 0; iMmc < 6; iMmc++)
{
if ((1 << iMmc) >= cVectors)
break;
}
if ((cVectors > VBOX_MSI_MAX_ENTRIES) || (1 << iMmc) < cVectors)
return VERR_TOO_MUCH_DATA;
Assert(iCapOffset != 0 && iCapOffset < 0xff && iNextOffset < 0xff);
/* We always support per-vector masking */
iFlags |= VBOX_PCI_MSI_FLAGS_MASKBIT | iMmc;
if (f64bit)
iFlags |= VBOX_PCI_MSI_FLAGS_64BIT;
/* How many vectors we're capable of */
iFlags |= iMmc;
pDev->Int.s.u8MsiCapOffset = iCapOffset;
pDev->Int.s.u8MsiCapSize = f64bit ? VBOX_MSI_CAP_SIZE_64 : VBOX_MSI_CAP_SIZE_32;
PCIDevSetByte(pDev, iCapOffset + 0, VBOX_PCI_CAP_ID_MSI);
PCIDevSetByte(pDev, iCapOffset + 1, iNextOffset); /* next */
PCIDevSetWord(pDev, iCapOffset + VBOX_MSI_CAP_MESSAGE_CONTROL, iFlags);
*msiGetMaskBits(pDev) = 0;
*msiGetPendingBits(pDev) = 0;
pciDevSetMsiCapable(pDev);
return VINF_SUCCESS;
}
#endif /* IN_RING3 */
bool MsiIsEnabled(PPCIDEVICE pDev)
{
return pciDevIsMsiCapable(pDev) && msiIsEnabled(pDev);
}
void MsiNotify(PPDMDEVINS pDevIns, PCPDMPCIHLP pPciHlp, PPCIDEVICE pDev, int iVector, int iLevel, uint32_t uTagSrc)
{
AssertMsg(msiIsEnabled(pDev), ("Must be enabled to use that"));
uint32_t uMask = *msiGetMaskBits(pDev);
uint32_t* puPending = msiGetPendingBits(pDev);
LogFlow(("MsiNotify: %d pending=%x mask=%x\n", iVector, *puPending, uMask));
/* We only trigger MSI on level up */
if ((iLevel & PDM_IRQ_LEVEL_HIGH) == 0)
{
/* @todo: maybe clear pending interrupts on level down? */
#if 0
*puPending &= ~(1<<iVector);
LogFlow(("msi: clear pending %d, now %x\n", iVector, *puPending));
#endif
return;
}
if ((uMask & (1<<iVector)) != 0)
{
*puPending |= (1<<iVector);
LogFlow(("msi: %d is masked, mark pending, now %x\n", iVector, *puPending));
return;
}
RTGCPHYS GCAddr = msiGetMsiAddress(pDev);
uint32_t u32Value = msiGetMsiData(pDev, iVector);
*puPending &= ~(1<<iVector);
Assert(pPciHlp->pfnIoApicSendMsi != NULL);
pPciHlp->pfnIoApicSendMsi(pDevIns, GCAddr, u32Value, uTagSrc);
}