CloverBootloader/ArmPkg/Drivers/ArmGic/ArmGicLib.c
Slice 84f41b2b58 prepare to arm
Signed-off-by: Slice <sergey.slice@gmail.com>
2023-07-04 19:53:11 +03:00

435 lines
12 KiB
C

/** @file
*
* Copyright (c) 2011-2021, Arm Limited. All rights reserved.
*
* SPDX-License-Identifier: BSD-2-Clause-Patent
*
**/
#include <Base.h>
#include <Library/ArmGicLib.h>
#include <Library/ArmLib.h>
#include <Library/DebugLib.h>
#include <Library/IoLib.h>
#include <Library/PcdLib.h>
// In GICv3, there are 2 x 64KB frames:
// Redistributor control frame + SGI Control & Generation frame
#define GIC_V3_REDISTRIBUTOR_GRANULARITY (ARM_GICR_CTLR_FRAME_SIZE \
+ ARM_GICR_SGI_PPI_FRAME_SIZE)
// In GICv4, there are 2 additional 64KB frames:
// VLPI frame + Reserved page frame
#define GIC_V4_REDISTRIBUTOR_GRANULARITY (GIC_V3_REDISTRIBUTOR_GRANULARITY \
+ ARM_GICR_SGI_VLPI_FRAME_SIZE \
+ ARM_GICR_SGI_RESERVED_FRAME_SIZE)
#define ISENABLER_ADDRESS(base, offset) ((base) +\
ARM_GICR_CTLR_FRAME_SIZE + ARM_GICR_ISENABLER + 4 * (offset))
#define ICENABLER_ADDRESS(base, offset) ((base) +\
ARM_GICR_CTLR_FRAME_SIZE + ARM_GICR_ICENABLER + 4 * (offset))
#define IPRIORITY_ADDRESS(base, offset) ((base) +\
ARM_GICR_CTLR_FRAME_SIZE + ARM_GIC_ICDIPR + 4 * (offset))
/**
*
* Return whether the Source interrupt index refers to a shared interrupt (SPI)
*/
STATIC
BOOLEAN
SourceIsSpi (
IN UINTN Source
)
{
return Source >= 32 && Source < 1020;
}
/**
* Return the base address of the GIC redistributor for the current CPU
*
* @param Revision GIC Revision. The GIC redistributor might have a different
* granularity following the GIC revision.
*
* @retval Base address of the associated GIC Redistributor
*/
STATIC
UINTN
GicGetCpuRedistributorBase (
IN UINTN GicRedistributorBase,
IN ARM_GIC_ARCH_REVISION Revision
)
{
UINTN MpId;
UINTN CpuAffinity;
UINTN Affinity;
UINTN GicCpuRedistributorBase;
UINT64 TypeRegister;
MpId = ArmReadMpidr ();
// Define CPU affinity as:
// Affinity0[0:8], Affinity1[9:15], Affinity2[16:23], Affinity3[24:32]
// whereas Affinity3 is defined at [32:39] in MPIDR
CpuAffinity = (MpId & (ARM_CORE_AFF0 | ARM_CORE_AFF1 | ARM_CORE_AFF2)) |
((MpId & ARM_CORE_AFF3) >> 8);
if (Revision < ARM_GIC_ARCH_REVISION_3) {
ASSERT_EFI_ERROR (EFI_UNSUPPORTED);
return 0;
}
GicCpuRedistributorBase = GicRedistributorBase;
do {
TypeRegister = MmioRead64 (GicCpuRedistributorBase + ARM_GICR_TYPER);
Affinity = ARM_GICR_TYPER_GET_AFFINITY (TypeRegister);
if (Affinity == CpuAffinity) {
return GicCpuRedistributorBase;
}
// Move to the next GIC Redistributor frame.
// The GIC specification does not forbid a mixture of redistributors
// with or without support for virtual LPIs, so we test Virtual LPIs
// Support (VLPIS) bit for each frame to decide the granularity.
// Note: The assumption here is that the redistributors are adjacent
// for all CPUs. However this may not be the case for NUMA systems.
GicCpuRedistributorBase += (((ARM_GICR_TYPER_VLPIS & TypeRegister) != 0)
? GIC_V4_REDISTRIBUTOR_GRANULARITY
: GIC_V3_REDISTRIBUTOR_GRANULARITY);
} while ((TypeRegister & ARM_GICR_TYPER_LAST) == 0);
// The Redistributor has not been found for the current CPU
ASSERT_EFI_ERROR (EFI_NOT_FOUND);
return 0;
}
UINTN
EFIAPI
ArmGicGetInterfaceIdentification (
IN INTN GicInterruptInterfaceBase
)
{
// Read the GIC Identification Register
return MmioRead32 (GicInterruptInterfaceBase + ARM_GIC_ICCIIDR);
}
UINTN
EFIAPI
ArmGicGetMaxNumInterrupts (
IN INTN GicDistributorBase
)
{
UINTN ItLines;
ItLines = MmioRead32 (GicDistributorBase + ARM_GIC_ICDICTR) & 0x1F;
//
// Interrupt ID 1020-1023 are reserved.
//
return (ItLines == 0x1f) ? 1020 : 32 * (ItLines + 1);
}
VOID
EFIAPI
ArmGicSendSgiTo (
IN INTN GicDistributorBase,
IN INTN TargetListFilter,
IN INTN CPUTargetList,
IN INTN SgiId
)
{
MmioWrite32 (
GicDistributorBase + ARM_GIC_ICDSGIR,
((TargetListFilter & 0x3) << 24) | ((CPUTargetList & 0xFF) << 16) | SgiId
);
}
/*
* Acknowledge and return the value of the Interrupt Acknowledge Register
*
* InterruptId is returned separately from the register value because in
* the GICv2 the register value contains the CpuId and InterruptId while
* in the GICv3 the register value is only the InterruptId.
*
* @param GicInterruptInterfaceBase Base Address of the GIC CPU Interface
* @param InterruptId InterruptId read from the Interrupt
* Acknowledge Register
*
* @retval value returned by the Interrupt Acknowledge Register
*
*/
UINTN
EFIAPI
ArmGicAcknowledgeInterrupt (
IN UINTN GicInterruptInterfaceBase,
OUT UINTN *InterruptId
)
{
UINTN Value;
ARM_GIC_ARCH_REVISION Revision;
Revision = ArmGicGetSupportedArchRevision ();
if (Revision == ARM_GIC_ARCH_REVISION_2) {
Value = ArmGicV2AcknowledgeInterrupt (GicInterruptInterfaceBase);
// InterruptId is required for the caller to know if a valid or spurious
// interrupt has been read
ASSERT (InterruptId != NULL);
if (InterruptId != NULL) {
*InterruptId = Value & ARM_GIC_ICCIAR_ACKINTID;
}
} else if (Revision == ARM_GIC_ARCH_REVISION_3) {
Value = ArmGicV3AcknowledgeInterrupt ();
} else {
ASSERT_EFI_ERROR (EFI_UNSUPPORTED);
// Report Spurious interrupt which is what the above controllers would
// return if no interrupt was available
Value = 1023;
}
return Value;
}
VOID
EFIAPI
ArmGicEndOfInterrupt (
IN UINTN GicInterruptInterfaceBase,
IN UINTN Source
)
{
ARM_GIC_ARCH_REVISION Revision;
Revision = ArmGicGetSupportedArchRevision ();
if (Revision == ARM_GIC_ARCH_REVISION_2) {
ArmGicV2EndOfInterrupt (GicInterruptInterfaceBase, Source);
} else if (Revision == ARM_GIC_ARCH_REVISION_3) {
ArmGicV3EndOfInterrupt (Source);
} else {
ASSERT_EFI_ERROR (EFI_UNSUPPORTED);
}
}
VOID
EFIAPI
ArmGicSetInterruptPriority (
IN UINTN GicDistributorBase,
IN UINTN GicRedistributorBase,
IN UINTN Source,
IN UINTN Priority
)
{
UINT32 RegOffset;
UINTN RegShift;
ARM_GIC_ARCH_REVISION Revision;
UINTN GicCpuRedistributorBase;
// Calculate register offset and bit position
RegOffset = Source / 4;
RegShift = (Source % 4) * 8;
Revision = ArmGicGetSupportedArchRevision ();
if ((Revision == ARM_GIC_ARCH_REVISION_2) ||
FeaturePcdGet (PcdArmGicV3WithV2Legacy) ||
SourceIsSpi (Source))
{
MmioAndThenOr32 (
GicDistributorBase + ARM_GIC_ICDIPR + (4 * RegOffset),
~(0xff << RegShift),
Priority << RegShift
);
} else {
GicCpuRedistributorBase = GicGetCpuRedistributorBase (
GicRedistributorBase,
Revision
);
if (GicCpuRedistributorBase == 0) {
return;
}
MmioAndThenOr32 (
IPRIORITY_ADDRESS (GicCpuRedistributorBase, RegOffset),
~(0xff << RegShift),
Priority << RegShift
);
}
}
VOID
EFIAPI
ArmGicEnableInterrupt (
IN UINTN GicDistributorBase,
IN UINTN GicRedistributorBase,
IN UINTN Source
)
{
UINT32 RegOffset;
UINTN RegShift;
ARM_GIC_ARCH_REVISION Revision;
UINTN GicCpuRedistributorBase;
// Calculate enable register offset and bit position
RegOffset = Source / 32;
RegShift = Source % 32;
Revision = ArmGicGetSupportedArchRevision ();
if ((Revision == ARM_GIC_ARCH_REVISION_2) ||
FeaturePcdGet (PcdArmGicV3WithV2Legacy) ||
SourceIsSpi (Source))
{
// Write set-enable register
MmioWrite32 (
GicDistributorBase + ARM_GIC_ICDISER + (4 * RegOffset),
1 << RegShift
);
} else {
GicCpuRedistributorBase = GicGetCpuRedistributorBase (
GicRedistributorBase,
Revision
);
if (GicCpuRedistributorBase == 0) {
ASSERT_EFI_ERROR (EFI_NOT_FOUND);
return;
}
// Write set-enable register
MmioWrite32 (
ISENABLER_ADDRESS (GicCpuRedistributorBase, RegOffset),
1 << RegShift
);
}
}
VOID
EFIAPI
ArmGicDisableInterrupt (
IN UINTN GicDistributorBase,
IN UINTN GicRedistributorBase,
IN UINTN Source
)
{
UINT32 RegOffset;
UINTN RegShift;
ARM_GIC_ARCH_REVISION Revision;
UINTN GicCpuRedistributorBase;
// Calculate enable register offset and bit position
RegOffset = Source / 32;
RegShift = Source % 32;
Revision = ArmGicGetSupportedArchRevision ();
if ((Revision == ARM_GIC_ARCH_REVISION_2) ||
FeaturePcdGet (PcdArmGicV3WithV2Legacy) ||
SourceIsSpi (Source))
{
// Write clear-enable register
MmioWrite32 (
GicDistributorBase + ARM_GIC_ICDICER + (4 * RegOffset),
1 << RegShift
);
} else {
GicCpuRedistributorBase = GicGetCpuRedistributorBase (
GicRedistributorBase,
Revision
);
if (GicCpuRedistributorBase == 0) {
return;
}
// Write clear-enable register
MmioWrite32 (
ICENABLER_ADDRESS (GicCpuRedistributorBase, RegOffset),
1 << RegShift
);
}
}
BOOLEAN
EFIAPI
ArmGicIsInterruptEnabled (
IN UINTN GicDistributorBase,
IN UINTN GicRedistributorBase,
IN UINTN Source
)
{
UINT32 RegOffset;
UINTN RegShift;
ARM_GIC_ARCH_REVISION Revision;
UINTN GicCpuRedistributorBase;
UINT32 Interrupts;
// Calculate enable register offset and bit position
RegOffset = Source / 32;
RegShift = Source % 32;
Revision = ArmGicGetSupportedArchRevision ();
if ((Revision == ARM_GIC_ARCH_REVISION_2) ||
FeaturePcdGet (PcdArmGicV3WithV2Legacy) ||
SourceIsSpi (Source))
{
Interrupts = MmioRead32 (
GicDistributorBase + ARM_GIC_ICDISER + (4 * RegOffset)
);
} else {
GicCpuRedistributorBase = GicGetCpuRedistributorBase (
GicRedistributorBase,
Revision
);
if (GicCpuRedistributorBase == 0) {
return 0;
}
// Read set-enable register
Interrupts = MmioRead32 (
ISENABLER_ADDRESS (GicCpuRedistributorBase, RegOffset)
);
}
return ((Interrupts & (1 << RegShift)) != 0);
}
VOID
EFIAPI
ArmGicDisableDistributor (
IN INTN GicDistributorBase
)
{
// Disable Gic Distributor
MmioWrite32 (GicDistributorBase + ARM_GIC_ICDDCR, 0x0);
}
VOID
EFIAPI
ArmGicEnableInterruptInterface (
IN INTN GicInterruptInterfaceBase
)
{
ARM_GIC_ARCH_REVISION Revision;
Revision = ArmGicGetSupportedArchRevision ();
if (Revision == ARM_GIC_ARCH_REVISION_2) {
ArmGicV2EnableInterruptInterface (GicInterruptInterfaceBase);
} else if (Revision == ARM_GIC_ARCH_REVISION_3) {
ArmGicV3EnableInterruptInterface ();
} else {
ASSERT_EFI_ERROR (EFI_UNSUPPORTED);
}
}
VOID
EFIAPI
ArmGicDisableInterruptInterface (
IN INTN GicInterruptInterfaceBase
)
{
ARM_GIC_ARCH_REVISION Revision;
Revision = ArmGicGetSupportedArchRevision ();
if (Revision == ARM_GIC_ARCH_REVISION_2) {
ArmGicV2DisableInterruptInterface (GicInterruptInterfaceBase);
} else if (Revision == ARM_GIC_ARCH_REVISION_3) {
ArmGicV3DisableInterruptInterface ();
} else {
ASSERT_EFI_ERROR (EFI_UNSUPPORTED);
}
}