Revision 0b250250b7e7298e0001faf76015da4b03b6b1b3 authored by Prasad Singamsetty on 14 November 2017, 23:13:50 UTC, committed by Michael Roth on 21 June 2018, 01:45:05 UTC
The current implementation of Intel IOMMU code only supports 39 bits iova address width. This patch provides a new parameter (x-aw-bits) for intel-iommu to extend its address width to 48 bits but keeping the default the same (39 bits). The reason for not changing the default is to avoid potential compatibility problems with live migration of intel-iommu enabled QEMU guest. The only valid values for 'x-aw-bits' parameter are 39 and 48. After enabling larger address width (48), we should be able to map larger iova addresses in the guest. For example, a QEMU guest that is configured with large memory ( >=1TB ). To check whether 48 bits aw is enabled, we can grep in the guest dmesg output with line: "DMAR: Host address width 48". Signed-off-by: Prasad Singamsetty <prasad.singamsety@oracle.com> Reviewed-by: Peter Xu <peterx@redhat.com> Reviewed-by: Michael S. Tsirkin <mst@redhat.com> Signed-off-by: Michael S. Tsirkin <mst@redhat.com> (cherry picked from commit 37f51384ae05bd50f83308339dbffa3e78404874) Signed-off-by: Michael Roth <mdroth@linux.vnet.ibm.com>
1 parent d45364e
gusemu_hal.c
/*
* GUSEMU32 - bus interface part
*
* Copyright (C) 2000-2007 Tibor "TS" Schütz
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
* THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*/
/*
* TODO: check mixer: see 7.20 of sdk for panning pos (applies to all gus models?)?
*/
#include "qemu/osdep.h"
#include "gustate.h"
#include "gusemu.h"
#define GUSregb(position) (* (gusptr+(position)))
#define GUSregw(position) (*(uint16_t *) (gusptr+(position)))
#define GUSregd(position) (*(uint16_t *)(gusptr+(position)))
/* size given in bytes */
unsigned int gus_read(GUSEmuState * state, int port, int size)
{
int value_read = 0;
uint8_t *gusptr;
gusptr = state->gusdatapos;
GUSregd(portaccesses)++;
switch (port & 0xff0f)
{
/* MixerCtrlReg (read not supported on GUS classic) */
/* case 0x200: return GUSregb(MixerCtrlReg2x0); */
case 0x206: /* IRQstatReg / SB2x6IRQ */
/* adlib/sb bits set in port handlers */
/* timer/voice bits set in gus_irqgen() */
/* dma bit set in gus_dma_transferdata */
/* midi not implemented yet */
return GUSregb(IRQStatReg2x6);
/* case 0x308: */ /* AdLib388 */
case 0x208:
if (GUSregb(GUS45TimerCtrl) & 1)
return GUSregb(TimerStatus2x8);
return GUSregb(AdLibStatus2x8); /* AdLibStatus */
case 0x309: /* AdLib389 */
case 0x209:
return GUSregb(AdLibData2x9); /* AdLibData */
case 0x20A:
return GUSregb(AdLibCommand2xA); /* AdLib2x8_2xA */
#if 0
case 0x20B: /* GUS hidden registers (read not supported on GUS classic) */
switch (GUSregb(RegCtrl_2xF) & 0x07)
{
case 0: /* IRQ/DMA select */
if (GUSregb(MixerCtrlReg2x0) & 0x40)
return GUSregb(IRQ_2xB); /* control register select bit */
else
return GUSregb(DMA_2xB);
/* case 1-5: */ /* general purpose emulation regs */
/* return ... */ /* + status reset reg (write only) */
case 6:
return GUSregb(Jumper_2xB); /* Joystick/MIDI enable (JumperReg) */
default:;
}
break;
#endif
case 0x20C: /* SB2xCd */
value_read = GUSregb(SB2xCd);
if (GUSregb(StatRead_2xF) & 0x20)
GUSregb(SB2xCd) ^= 0x80; /* toggle MSB on read */
return value_read;
/* case 0x20D: */ /* SB2xD is write only -> 2xE writes to it*/
case 0x20E:
if (GUSregb(RegCtrl_2xF) & 0x80) /* 2xE read IRQ enabled? */
{
GUSregb(StatRead_2xF) |= 0x80;
GUS_irqrequest(state, state->gusirq, 1);
}
return GUSregb(SB2xE); /* SB2xE */
case 0x20F: /* StatRead_2xF */
/*set/clear fixed bits */
/*value_read = (GUSregb(StatRead_2xF) & 0xf9)|1; */ /*(LSB not set on GUS classic!)*/
value_read = (GUSregb(StatRead_2xF) & 0xf9);
if (GUSregb(MixerCtrlReg2x0) & 0x08)
value_read |= 2; /* DMA/IRQ enabled flag */
return value_read;
/* case 0x300: */ /* MIDI (not implemented) */
/* case 0x301: */ /* MIDI (not implemented) */
case 0x302:
return GUSregb(VoiceSelReg3x2); /* VoiceSelReg */
case 0x303:
return GUSregb(FunkSelReg3x3); /* FunkSelReg */
case 0x304: /* DataRegLoByte3x4 + DataRegWord3x4 */
case 0x305: /* DataRegHiByte3x5 */
switch (GUSregb(FunkSelReg3x3))
{
/* common functions */
case 0x41: /* DramDMAContrReg */
value_read = GUSregb(GUS41DMACtrl); /* &0xfb */
GUSregb(GUS41DMACtrl) &= 0xbb;
if (state->gusdma >= 4)
value_read |= 0x04;
if (GUSregb(IRQStatReg2x6) & 0x80)
{
value_read |= 0x40;
GUSregb(IRQStatReg2x6) &= 0x7f;
if (!GUSregb(IRQStatReg2x6))
GUS_irqclear(state, state->gusirq);
}
return (uint8_t) value_read;
/* DramDMAmemPosReg */
/* case 0x42: value_read=GUSregw(GUS42DMAStart); break;*/
/* 43h+44h write only */
case 0x45:
return GUSregb(GUS45TimerCtrl); /* TimerCtrlReg */
/* 46h+47h write only */
/* 48h: samp freq - write only */
case 0x49:
return GUSregb(GUS49SampCtrl) & 0xbf; /* SampCtrlReg */
/* case 4bh: */ /* joystick trim not supported */
/* case 0x4c: return GUSregb(GUS4cReset); */ /* GUSreset: write only*/
/* voice specific functions */
case 0x80:
case 0x81:
case 0x82:
case 0x83:
case 0x84:
case 0x85:
case 0x86:
case 0x87:
case 0x88:
case 0x89:
case 0x8a:
case 0x8b:
case 0x8c:
case 0x8d:
{
int offset = 2 * (GUSregb(FunkSelReg3x3) & 0x0f);
offset += ((int) GUSregb(VoiceSelReg3x2) & 0x1f) << 5; /* = Voice*32 + Funktion*2 */
value_read = GUSregw(offset);
}
break;
/* voice unspecific functions */
case 0x8e: /* NumVoice */
return GUSregb(NumVoices);
case 0x8f: /* irqstatreg */
/* (pseudo IRQ-FIFO is processed during a gus_write(0x3X3,0x8f)) */
return GUSregb(SynVoiceIRQ8f);
default:
return 0xffff;
}
if (size == 1)
{
if ((port & 0xff0f) == 0x305)
value_read = value_read >> 8;
value_read &= 0xff;
}
return (uint16_t) value_read;
/* case 0x306: */ /* Mixer/Version info */
/* return 0xff; */ /* Pre 3.6 boards, ICS mixer NOT present */
case 0x307: /* DRAMaccess */
{
uint8_t *adr;
adr = state->himemaddr + (GUSregd(GUSDRAMPOS24bit) & 0xfffff);
return *adr;
}
default:;
}
return 0xffff;
}
void gus_write(GUSEmuState * state, int port, int size, unsigned int data)
{
uint8_t *gusptr;
gusptr = state->gusdatapos;
GUSregd(portaccesses)++;
switch (port & 0xff0f)
{
case 0x200: /* MixerCtrlReg */
GUSregb(MixerCtrlReg2x0) = (uint8_t) data;
break;
case 0x206: /* IRQstatReg / SB2x6IRQ */
if (GUSregb(GUS45TimerCtrl) & 0x20) /* SB IRQ enabled? -> set 2x6IRQ bit */
{
GUSregb(TimerStatus2x8) |= 0x08;
GUSregb(IRQStatReg2x6) = 0x10;
GUS_irqrequest(state, state->gusirq, 1);
}
break;
case 0x308: /* AdLib 388h */
case 0x208: /* AdLibCommandReg */
GUSregb(AdLibCommand2xA) = (uint8_t) data;
break;
case 0x309: /* AdLib 389h */
case 0x209: /* AdLibDataReg */
if ((GUSregb(AdLibCommand2xA) == 0x04) && (!(GUSregb(GUS45TimerCtrl) & 1))) /* GUS auto timer mode enabled? */
{
if (data & 0x80)
GUSregb(TimerStatus2x8) &= 0x1f; /* AdLib IRQ reset? -> clear maskable adl. timer int regs */
else
GUSregb(TimerDataReg2x9) = (uint8_t) data;
}
else
{
GUSregb(AdLibData2x9) = (uint8_t) data;
if (GUSregb(GUS45TimerCtrl) & 0x02)
{
GUSregb(TimerStatus2x8) |= 0x01;
GUSregb(IRQStatReg2x6) = 0x10;
GUS_irqrequest(state, state->gusirq, 1);
}
}
break;
case 0x20A:
GUSregb(AdLibStatus2x8) = (uint8_t) data;
break; /* AdLibStatus2x8 */
case 0x20B: /* GUS hidden registers */
switch (GUSregb(RegCtrl_2xF) & 0x7)
{
case 0:
if (GUSregb(MixerCtrlReg2x0) & 0x40)
GUSregb(IRQ_2xB) = (uint8_t) data; /* control register select bit */
else
GUSregb(DMA_2xB) = (uint8_t) data;
break;
/* case 1-4: general purpose emulation regs */
case 5: /* clear stat reg 2xF */
GUSregb(StatRead_2xF) = 0; /* ToDo: is this identical with GUS classic? */
if (!GUSregb(IRQStatReg2x6))
GUS_irqclear(state, state->gusirq);
break;
case 6: /* Jumper reg (Joystick/MIDI enable) */
GUSregb(Jumper_2xB) = (uint8_t) data;
break;
default:;
}
break;
case 0x20C: /* SB2xCd */
if (GUSregb(GUS45TimerCtrl) & 0x20)
{
GUSregb(TimerStatus2x8) |= 0x10; /* SB IRQ enabled? -> set 2xCIRQ bit */
GUSregb(IRQStatReg2x6) = 0x10;
GUS_irqrequest(state, state->gusirq, 1);
}
case 0x20D: /* SB2xCd no IRQ */
GUSregb(SB2xCd) = (uint8_t) data;
break;
case 0x20E: /* SB2xE */
GUSregb(SB2xE) = (uint8_t) data;
break;
case 0x20F:
GUSregb(RegCtrl_2xF) = (uint8_t) data;
break; /* CtrlReg2xF */
case 0x302: /* VoiceSelReg */
GUSregb(VoiceSelReg3x2) = (uint8_t) data;
break;
case 0x303: /* FunkSelReg */
GUSregb(FunkSelReg3x3) = (uint8_t) data;
if ((uint8_t) data == 0x8f) /* set irqstatreg, get voicereg and clear IRQ */
{
int voice;
if (GUSregd(voicewavetableirq)) /* WavetableIRQ */
{
for (voice = 0; voice < 31; voice++)
{
if (GUSregd(voicewavetableirq) & (1 << voice))
{
GUSregd(voicewavetableirq) ^= (1 << voice); /* clear IRQ bit */
GUSregb(voice << 5) &= 0x7f; /* clear voice reg irq bit */
if (!GUSregd(voicewavetableirq))
GUSregb(IRQStatReg2x6) &= 0xdf;
if (!GUSregb(IRQStatReg2x6))
GUS_irqclear(state, state->gusirq);
GUSregb(SynVoiceIRQ8f) = voice | 0x60; /* (bit==0 => IRQ wartend) */
return;
}
}
}
else if (GUSregd(voicevolrampirq)) /* VolRamp IRQ */
{
for (voice = 0; voice < 31; voice++)
{
if (GUSregd(voicevolrampirq) & (1 << voice))
{
GUSregd(voicevolrampirq) ^= (1 << voice); /* clear IRQ bit */
GUSregb((voice << 5) + VSRVolRampControl) &= 0x7f; /* clear voice volume reg irq bit */
if (!GUSregd(voicevolrampirq))
GUSregb(IRQStatReg2x6) &= 0xbf;
if (!GUSregb(IRQStatReg2x6))
GUS_irqclear(state, state->gusirq);
GUSregb(SynVoiceIRQ8f) = voice | 0x80; /* (bit==0 => IRQ wartend) */
return;
}
}
}
GUSregb(SynVoiceIRQ8f) = 0xe8; /* kein IRQ wartet */
}
break;
case 0x304:
case 0x305:
{
uint16_t writedata = (uint16_t) data;
uint16_t readmask = 0x0000;
if (size == 1)
{
readmask = 0xff00;
writedata &= 0xff;
if ((port & 0xff0f) == 0x305)
{
writedata = (uint16_t) (writedata << 8);
readmask = 0x00ff;
}
}
switch (GUSregb(FunkSelReg3x3))
{
/* voice specific functions */
case 0x00:
case 0x01:
case 0x02:
case 0x03:
case 0x04:
case 0x05:
case 0x06:
case 0x07:
case 0x08:
case 0x09:
case 0x0a:
case 0x0b:
case 0x0c:
case 0x0d:
{
int offset;
if (!(GUSregb(GUS4cReset) & 0x01))
break; /* reset flag active? */
offset = 2 * (GUSregb(FunkSelReg3x3) & 0x0f);
offset += (GUSregb(VoiceSelReg3x2) & 0x1f) << 5; /* = Voice*32 + Funktion*2 */
GUSregw(offset) = (uint16_t) ((GUSregw(offset) & readmask) | writedata);
}
break;
/* voice unspecific functions */
case 0x0e: /* NumVoices */
GUSregb(NumVoices) = (uint8_t) data;
break;
/* case 0x0f: */ /* read only */
/* common functions */
case 0x41: /* DramDMAContrReg */
GUSregb(GUS41DMACtrl) = (uint8_t) data;
if (data & 0x01)
GUS_dmarequest(state);
break;
case 0x42: /* DramDMAmemPosReg */
GUSregw(GUS42DMAStart) = (GUSregw(GUS42DMAStart) & readmask) | writedata;
GUSregb(GUS50DMAHigh) &= 0xf; /* compatibility stuff... */
break;
case 0x43: /* DRAMaddrLo */
GUSregd(GUSDRAMPOS24bit) =
(GUSregd(GUSDRAMPOS24bit) & (readmask | 0xff0000)) | writedata;
break;
case 0x44: /* DRAMaddrHi */
GUSregd(GUSDRAMPOS24bit) =
(GUSregd(GUSDRAMPOS24bit) & 0xffff) | ((data & 0x0f) << 16);
break;
case 0x45: /* TCtrlReg */
GUSregb(GUS45TimerCtrl) = (uint8_t) data;
if (!(data & 0x20))
GUSregb(TimerStatus2x8) &= 0xe7; /* sb IRQ dis? -> clear 2x8/2xC sb IRQ flags */
if (!(data & 0x02))
GUSregb(TimerStatus2x8) &= 0xfe; /* adlib data IRQ dis? -> clear 2x8 adlib IRQ flag */
if (!(GUSregb(TimerStatus2x8) & 0x19))
GUSregb(IRQStatReg2x6) &= 0xef; /* 0xe6; $$clear IRQ if both IRQ bits are inactive or cleared */
/* catch up delayed timer IRQs: */
if ((GUSregw(TimerIRQs) > 1) && (GUSregb(TimerDataReg2x9) & 3))
{
if (GUSregb(TimerDataReg2x9) & 1) /* start timer 1 (80us decrement rate) */
{
if (!(GUSregb(TimerDataReg2x9) & 0x40))
GUSregb(TimerStatus2x8) |= 0xc0; /* maskable bits */
if (data & 4) /* timer1 irq enable */
{
GUSregb(TimerStatus2x8) |= 4; /* nonmaskable bit */
GUSregb(IRQStatReg2x6) |= 4; /* timer 1 irq pending */
}
}
if (GUSregb(TimerDataReg2x9) & 2) /* start timer 2 (320us decrement rate) */
{
if (!(GUSregb(TimerDataReg2x9) & 0x20))
GUSregb(TimerStatus2x8) |= 0xa0; /* maskable bits */
if (data & 8) /* timer2 irq enable */
{
GUSregb(TimerStatus2x8) |= 2; /* nonmaskable bit */
GUSregb(IRQStatReg2x6) |= 8; /* timer 2 irq pending */
}
}
GUSregw(TimerIRQs)--;
if (GUSregw(BusyTimerIRQs) > 1)
GUSregw(BusyTimerIRQs)--;
else
GUSregw(BusyTimerIRQs) =
GUS_irqrequest(state, state->gusirq, GUSregw(TimerIRQs));
}
else
GUSregw(TimerIRQs) = 0;
if (!(data & 0x04))
{
GUSregb(TimerStatus2x8) &= 0xfb; /* clear non-maskable timer1 bit */
GUSregb(IRQStatReg2x6) &= 0xfb;
}
if (!(data & 0x08))
{
GUSregb(TimerStatus2x8) &= 0xfd; /* clear non-maskable timer2 bit */
GUSregb(IRQStatReg2x6) &= 0xf7;
}
if (!GUSregb(IRQStatReg2x6))
GUS_irqclear(state, state->gusirq);
break;
case 0x46: /* Counter1 */
GUSregb(GUS46Counter1) = (uint8_t) data;
break;
case 0x47: /* Counter2 */
GUSregb(GUS47Counter2) = (uint8_t) data;
break;
/* case 0x48: */ /* sampling freq reg not emulated (same as interwave) */
case 0x49: /* SampCtrlReg */
GUSregb(GUS49SampCtrl) = (uint8_t) data;
break;
/* case 0x4b: */ /* joystick trim not emulated */
case 0x4c: /* GUSreset */
GUSregb(GUS4cReset) = (uint8_t) data;
if (!(GUSregb(GUS4cReset) & 1)) /* reset... */
{
GUSregd(voicewavetableirq) = 0;
GUSregd(voicevolrampirq) = 0;
GUSregw(TimerIRQs) = 0;
GUSregw(BusyTimerIRQs) = 0;
GUSregb(NumVoices) = 0xcd;
GUSregb(IRQStatReg2x6) = 0;
GUSregb(TimerStatus2x8) = 0;
GUSregb(AdLibData2x9) = 0;
GUSregb(TimerDataReg2x9) = 0;
GUSregb(GUS41DMACtrl) = 0;
GUSregb(GUS45TimerCtrl) = 0;
GUSregb(GUS49SampCtrl) = 0;
GUSregb(GUS4cReset) &= 0xf9; /* clear IRQ and DAC enable bits */
GUS_irqclear(state, state->gusirq);
}
/* IRQ enable bit checked elsewhere */
/* EnableDAC bit may be used by external callers */
break;
}
}
break;
case 0x307: /* DRAMaccess */
{
uint8_t *adr;
adr = state->himemaddr + (GUSregd(GUSDRAMPOS24bit) & 0xfffff);
*adr = (uint8_t) data;
}
break;
}
}
/* Attention when breaking up a single DMA transfer to multiple ones:
* it may lead to multiple terminal count interrupts and broken transfers:
*
* 1. Whenever you transfer a piece of data, the gusemu callback is invoked
* 2. The callback may generate a TC irq (if the register was set up to do so)
* 3. The irq may result in the program using the GUS to reprogram the GUS
*
* Some programs also decide to upload by just checking if TC occurs
* (via interrupt or a cleared GUS dma flag)
* and then start the next transfer, without checking DMA state
*
* Thus: Always make sure to set the TC flag correctly!
*
* Note that the genuine GUS had a granularity of 16 bytes/words for low/high DMA
* while later cards had atomic granularity provided by an additional GUS50DMAHigh register
* GUSemu also uses this register to support byte-granular transfers for better compatibility
* with emulators other than GUSemu32
*/
void gus_dma_transferdata(GUSEmuState * state, char *dma_addr, unsigned int count, int TC)
{
/* this function gets called by the callback function as soon as a DMA transfer is about to start
* dma_addr is a translated address within accessible memory, not the physical one,
* count is (real dma count register)+1
* note that the amount of bytes transferred is fully determined by values in the DMA registers
* do not forget to update DMA states after transferring the entire block:
* DREQ cleared & TC asserted after the _whole_ transfer */
char *srcaddr;
char *destaddr;
char msbmask = 0;
uint8_t *gusptr;
gusptr = state->gusdatapos;
srcaddr = dma_addr; /* system memory address */
{
int offset = (GUSregw(GUS42DMAStart) << 4) + (GUSregb(GUS50DMAHigh) & 0xf);
if (state->gusdma >= 4)
offset = (offset & 0xc0000) + (2 * (offset & 0x1fff0)); /* 16 bit address translation */
destaddr = (char *) state->himemaddr + offset; /* wavetable RAM address */
}
GUSregw(GUS42DMAStart) += (uint16_t) (count >> 4); /* ToDo: add 16bit GUS page limit? */
GUSregb(GUS50DMAHigh) = (uint8_t) ((count + GUSregb(GUS50DMAHigh)) & 0xf); /* ToDo: add 16bit GUS page limit? */
if (GUSregb(GUS41DMACtrl) & 0x02) /* direction, 0 := sysram->gusram */
{
char *tmpaddr = destaddr;
destaddr = srcaddr;
srcaddr = tmpaddr;
}
if ((GUSregb(GUS41DMACtrl) & 0x80) && (!(GUSregb(GUS41DMACtrl) & 0x02)))
msbmask = (const char) 0x80; /* invert MSB */
for (; count > 0; count--)
{
if (GUSregb(GUS41DMACtrl) & 0x40)
*(destaddr++) = *(srcaddr++); /* 16 bit lobyte */
else
*(destaddr++) = (msbmask ^ (*(srcaddr++))); /* 8 bit */
if (state->gusdma >= 4)
*(destaddr++) = (msbmask ^ (*(srcaddr++))); /* 16 bit hibyte */
}
if (TC)
{
(GUSregb(GUS41DMACtrl)) &= 0xfe; /* clear DMA request bit */
if (GUSregb(GUS41DMACtrl) & 0x20) /* DMA terminal count IRQ */
{
GUSregb(IRQStatReg2x6) |= 0x80;
GUS_irqrequest(state, state->gusirq, 1);
}
}
}
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