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/*
* Copyright (c) 2019 ARM Limited
* All rights reserved
*
* The license below extends only to copyright in the software and shall
* not be construed as granting a license to any other intellectual
* property including but not limited to intellectual property relating
* to a hardware implementation of the functionality of the software
* licensed hereunder. You may use the software subject to the license
* terms below provided that you ensure that this notice is replicated
* unmodified and in its entirety in all distributions of the software,
* modified or unmodified, in source code or in binary form.
*
* Copyright (c) 2018 Metempsy Technology Consulting
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met: redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer;
* redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution;
* neither the name of the copyright holders nor the names of its
* contributors may be used to endorse or promote products derived from
* this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
* OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*
* Authors: Jairo Balart
*/
#include "dev/arm/gic_v3_redistributor.hh"
#include "arch/arm/utility.hh"
#include "debug/GIC.hh"
#include "dev/arm/gic_v3_cpu_interface.hh"
#include "dev/arm/gic_v3_distributor.hh"
#include "mem/fs_translating_port_proxy.hh"
const AddrRange Gicv3Redistributor::GICR_IPRIORITYR(SGI_base + 0x0400,
SGI_base + 0x0420);
Gicv3Redistributor::Gicv3Redistributor(Gicv3 * gic, uint32_t cpu_id)
: gic(gic),
distributor(nullptr),
cpuInterface(nullptr),
cpuId(cpu_id),
memProxy(nullptr),
peInLowPowerState(true),
irqGroup(Gicv3::SGI_MAX + Gicv3::PPI_MAX, 0),
irqEnabled(Gicv3::SGI_MAX + Gicv3::PPI_MAX, false),
irqPending(Gicv3::SGI_MAX + Gicv3::PPI_MAX, false),
irqActive(Gicv3::SGI_MAX + Gicv3::PPI_MAX, false),
irqPriority(Gicv3::SGI_MAX + Gicv3::PPI_MAX, 0),
irqConfig(Gicv3::SGI_MAX + Gicv3::PPI_MAX, Gicv3::INT_EDGE_TRIGGERED),
irqGrpmod(Gicv3::SGI_MAX + Gicv3::PPI_MAX, 0),
irqNsacr(Gicv3::SGI_MAX + Gicv3::PPI_MAX, 0),
DPG1S(false),
DPG1NS(false),
DPG0(false),
EnableLPIs(false),
lpiConfigurationTablePtr(0),
lpiIDBits(0),
lpiPendingTablePtr(0),
addrRangeSize(gic->params()->gicv4 ? 0x40000 : 0x20000)
{
}
void
Gicv3Redistributor::init()
{
distributor = gic->getDistributor();
cpuInterface = gic->getCPUInterface(cpuId);
memProxy = &gic->getSystem()->physProxy;
}
uint64_t
Gicv3Redistributor::read(Addr addr, size_t size, bool is_secure_access)
{
if (GICR_IPRIORITYR.contains(addr)) { // Interrupt Priority Registers
uint64_t value = 0;
int first_intid = addr - GICR_IPRIORITYR.start();
for (int i = 0, int_id = first_intid; i < size; i++, int_id++) {
uint8_t prio = irqPriority[int_id];
if (!distributor->DS && !is_secure_access) {
if (getIntGroup(int_id) != Gicv3::G1NS) {
// RAZ/WI for non-secure accesses for secure interrupts
continue;
} else {
// NS view
prio = (prio << 1) & 0xff;
}
}
value |= prio << (i * 8);
}
return value;
}
switch (addr) {
case GICR_CTLR: { // Control Register
uint64_t value = 0;
if (DPG1S) {
value |= GICR_CTLR_DPG1S;
}
if (DPG1NS) {
value |= GICR_CTLR_DPG1NS;
}
if (DPG0) {
value |= GICR_CTLR_DPG0;
}
if (EnableLPIs) {
value |= GICR_CTLR_ENABLE_LPIS;
}
return value;
}
case GICR_IIDR: // Implementer Identification Register
//return 0x43b; // r0p0 GIC-500
return 0;
case GICR_TYPER: { // Type Register
/*
* Affinity_Value [63:32] == X
* (The identity of the PE associated with this Redistributor)
* CommonLPIAff [25:24] == 01
* (All Redistributors with the same Aff3 value must share an
* LPI Configuration table)
* Processor_Number [23:8] == X
* (A unique identifier for the PE)
* DPGS [5] == 1
* (GICR_CTLR.DPG* bits are supported)
* Last [4] == X
* (This Redistributor is the highest-numbered Redistributor in
* a series of contiguous Redistributor pages)
* DirectLPI [3] == 1
* (direct injection of LPIs supported)
* VLPIS [1] == 0
* (virtual LPIs not supported)
* PLPIS [0] == 1
* (physical LPIs supported)
*/
uint64_t affinity = getAffinity();
int last = cpuId == (gic->getSystem()->numContexts() - 1);
return (affinity << 32) | (1 << 24) | (cpuId << 8) |
(1 << 5) | (last << 4) | (1 << 3) | (1 << 0);
}
case GICR_WAKER: // Wake Register
if (!distributor->DS && !is_secure_access) {
// RAZ/WI for non-secure accesses
return 0;
}
if (peInLowPowerState) {
return GICR_WAKER_ChildrenAsleep | GICR_WAKER_ProcessorSleep;
} else {
return 0;
}
case GICR_PIDR0: { // Peripheral ID0 Register
return 0x92; // Part number, bits[7:0]
}
case GICR_PIDR1: { // Peripheral ID1 Register
uint8_t des_0 = 0xB; // JEP106 identification code, bits[3:0]
uint8_t part_1 = 0x4; // Part number, bits[11:8]
return (des_0 << 4) | (part_1 << 0);
}
case GICR_PIDR2: { // Peripheral ID2 Register
uint8_t arch_rev = 0x3; // 0x3 GICv3
uint8_t jedec = 0x1; // JEP code
uint8_t des_1 = 0x3; // JEP106 identification code, bits[6:4]
return (arch_rev << 4) | (jedec << 3) | (des_1 << 0);
}
case GICR_PIDR3: // Peripheral ID3 Register
return 0x0; // Implementation defined
case GICR_PIDR4: { // Peripheral ID4 Register
uint8_t size = 0x4; // 64 KB software visible page
uint8_t des_2 = 0x4; // ARM implementation
return (size << 4) | (des_2 << 0);
}
case GICR_PIDR5: // Peripheral ID5 Register
case GICR_PIDR6: // Peripheral ID6 Register
case GICR_PIDR7: // Peripheral ID7 Register
return 0; // RES0
case GICR_IGROUPR0: { // Interrupt Group Register 0
uint64_t value = 0;
if (!distributor->DS && !is_secure_access) {
// RAZ/WI for non-secure accesses
return 0;
}
for (int int_id = 0; int_id < 8 * size; int_id++) {
value |= (irqGroup[int_id] << int_id);
}
return value;
}
case GICR_ISENABLER0: // Interrupt Set-Enable Register 0
case GICR_ICENABLER0: { // Interrupt Clear-Enable Register 0
uint64_t value = 0;
for (int int_id = 0; int_id < 8 * size; int_id++) {
if (!distributor->DS && !is_secure_access) {
// RAZ/WI for non-secure accesses for secure interrupts
if (getIntGroup(int_id) != Gicv3::G1NS) {
continue;
}
}
if (irqEnabled[int_id]) {
value |= (1 << int_id);
}
}
return value;
}
case GICR_ISPENDR0: // Interrupt Set-Pending Register 0
case GICR_ICPENDR0: { // Interrupt Clear-Pending Register 0
uint64_t value = 0;
for (int int_id = 0; int_id < 8 * size; int_id++) {
if (!distributor->DS && !is_secure_access) {
// RAZ/WI for non-secure accesses for secure interrupts
if (getIntGroup(int_id) != Gicv3::G1NS) {
continue;
}
}
value |= (irqPending[int_id] << int_id);
}
return value;
}
case GICR_ISACTIVER0: // Interrupt Set-Active Register 0
case GICR_ICACTIVER0: { // Interrupt Clear-Active Register 0
uint64_t value = 0;
for (int int_id = 0; int_id < 8 * size; int_id++) {
if (!distributor->DS && !is_secure_access) {
// RAZ/WI for non-secure accesses for secure interrupts
if (getIntGroup(int_id) != Gicv3::G1NS) {
continue;
}
}
value |= irqActive[int_id] << int_id;
}
return value;
}
case GICR_ICFGR0: // SGI Configuration Register
case GICR_ICFGR1: { // PPI Configuration Register
uint64_t value = 0;
uint32_t first_int_id = addr == GICR_ICFGR0 ? 0 : Gicv3::SGI_MAX;
for (int i = 0, int_id = first_int_id; i < 32;
i = i + 2, int_id++) {
if (!distributor->DS && !is_secure_access) {
// RAZ/WI for non-secure accesses for secure interrupts
if (getIntGroup(int_id) != Gicv3::G1NS) {
continue;
}
}
if (irqConfig[int_id] == Gicv3::INT_EDGE_TRIGGERED) {
value |= (0x2) << i;
}
}
return value;
}
case GICR_IGRPMODR0: { // Interrupt Group Modifier Register 0
uint64_t value = 0;
if (distributor->DS) {
value = 0;
} else {
if (!is_secure_access) {
// RAZ/WI for non-secure accesses
value = 0;
} else {
for (int int_id = 0; int_id < 8 * size; int_id++) {
value |= irqGrpmod[int_id] << int_id;
}
}
}
return value;
}
case GICR_NSACR: { // Non-secure Access Control Register
uint64_t value = 0;
if (distributor->DS) {
// RAZ/WI
value = 0;
} else {
if (!is_secure_access) {
// RAZ/WI
value = 0;
} else {
for (int i = 0, int_id = 0; i < 8 * size;
i = i + 2, int_id++) {
value |= irqNsacr[int_id] << i;
}
}
}
return value;
}
case GICR_PROPBASER: // Redistributor Properties Base Address Register
// OuterCache, bits [58:56]
// 000 Memory type defined in InnerCache field
// Physical_Address, bits [51:12]
// Bits [51:12] of the physical address containing the LPI
// Configuration table
// Shareability, bits [11:10]
// 00 Non-shareable
// InnerCache, bits [9:7]
// 000 Device-nGnRnE
// IDbits, bits [4:0]
// limited by GICD_TYPER.IDbits
return lpiConfigurationTablePtr | lpiIDBits;
// Redistributor LPI Pending Table Base Address Register
case GICR_PENDBASER:
// PTZ, bit [62]
// Pending Table Zero
// OuterCache, bits [58:56]
// 000 Memory type defined in InnerCache field
// Physical_Address, bits [51:16]
// Bits [51:16] of the physical address containing the LPI Pending
// table
// Shareability, bits [11:10]
// 00 Non-shareable
// InnerCache, bits [9:7]
// 000 Device-nGnRnE
return lpiPendingTablePtr;
// Redistributor Synchronize Register
case GICR_SYNCR:
return 0;
default:
panic("Gicv3Redistributor::read(): invalid offset %#x\n", addr);
break;
}
}
void
Gicv3Redistributor::write(Addr addr, uint64_t data, size_t size,
bool is_secure_access)
{
if (GICR_IPRIORITYR.contains(addr)) { // Interrupt Priority Registers
int first_intid = addr - GICR_IPRIORITYR.start();
for (int i = 0, int_id = first_intid; i < size; i++, int_id++) {
uint8_t prio = bits(data, (i + 1) * 8 - 1, (i * 8));
if (!distributor->DS && !is_secure_access) {
if (getIntGroup(int_id) != Gicv3::G1NS) {
// RAZ/WI for non-secure accesses for secure interrupts
continue;
} else {
// NS view
prio = 0x80 | (prio >> 1);
}
}
irqPriority[int_id] = prio;
DPRINTF(GIC, "Gicv3Redistributor::write(): "
"int_id %d priority %d\n", int_id, irqPriority[int_id]);
}
return;
}
switch (addr) {
case GICR_CTLR: {
// GICR_TYPER.LPIS is 0 so EnableLPIs is RES0
EnableLPIs = data & GICR_CTLR_ENABLE_LPIS;
DPG1S = data & GICR_CTLR_DPG1S;
DPG1NS = data & GICR_CTLR_DPG1NS;
DPG0 = data & GICR_CTLR_DPG0;
break;
}
case GICR_WAKER: // Wake Register
if (!distributor->DS && !is_secure_access) {
// RAZ/WI for non-secure accesses
return;
}
if (not peInLowPowerState and
(data & GICR_WAKER_ProcessorSleep)) {
DPRINTF(GIC, "Gicv3Redistributor::write(): "
"PE entering in low power state\n");
} else if (peInLowPowerState and
not(data & GICR_WAKER_ProcessorSleep)) {
DPRINTF(GIC, "Gicv3Redistributor::write(): powering up PE\n");
}
peInLowPowerState = data & GICR_WAKER_ProcessorSleep;
break;
case GICR_IGROUPR0: // Interrupt Group Register 0
if (!distributor->DS && !is_secure_access) {
// RAZ/WI for non-secure accesses
return;
}
for (int int_id = 0; int_id < 8 * size; int_id++) {
irqGroup[int_id] = data & (1 << int_id) ? 1 : 0;
DPRINTF(GIC, "Gicv3Redistributor::write(): "
"int_id %d group %d\n", int_id, irqGroup[int_id]);
}
break;
case GICR_ISENABLER0: // Interrupt Set-Enable Register 0
for (int int_id = 0; int_id < 8 * size; int_id++) {
if (!distributor->DS && !is_secure_access) {
// RAZ/WI for non-secure accesses for secure interrupts
if (getIntGroup(int_id) != Gicv3::G1NS) {
continue;
}
}
bool enable = data & (1 << int_id) ? 1 : 0;
if (enable) {
irqEnabled[int_id] = true;
}
DPRINTF(GIC, "Gicv3Redistributor::write(): "
"int_id %d enable %i\n", int_id, irqEnabled[int_id]);
}
break;
case GICR_ICENABLER0: // Interrupt Clear-Enable Register 0
for (int int_id = 0; int_id < 8 * size; int_id++) {
if (!distributor->DS && !is_secure_access) {
// RAZ/WI for non-secure accesses for secure interrupts
if (getIntGroup(int_id) != Gicv3::G1NS) {
continue;
}
}
bool disable = data & (1 << int_id) ? 1 : 0;
if (disable) {
irqEnabled[int_id] = false;
}
DPRINTF(GIC, "Gicv3Redistributor::write(): "
"int_id %d enable %i\n", int_id, irqEnabled[int_id]);
}
break;
case GICR_ISPENDR0: // Interrupt Set-Pending Register 0
for (int int_id = 0; int_id < 8 * size; int_id++) {
if (!distributor->DS && !is_secure_access) {
// RAZ/WI for non-secure accesses for secure interrupts
if (getIntGroup(int_id) != Gicv3::G1NS) {
continue;
}
}
bool pending = data & (1 << int_id) ? 1 : 0;
if (pending) {
DPRINTF(GIC, "Gicv3Redistributor::write() "
"(GICR_ISPENDR0): int_id %d (PPI) "
"pending bit set\n", int_id);
irqPending[int_id] = true;
}
}
updateDistributor();
break;
case GICR_ICPENDR0:// Interrupt Clear-Pending Register 0
for (int int_id = 0; int_id < 8 * size; int_id++) {
if (!distributor->DS && !is_secure_access) {
// RAZ/WI for non-secure accesses for secure interrupts
if (getIntGroup(int_id) != Gicv3::G1NS) {
continue;
}
}
bool clear = data & (1 << int_id) ? 1 : 0;
if (clear) {
irqPending[int_id] = false;
}
}
break;
case GICR_ISACTIVER0: // Interrupt Set-Active Register 0
for (int int_id = 0; int_id < 8 * size; int_id++) {
if (!distributor->DS && !is_secure_access) {
// RAZ/WI for non-secure accesses for secure interrupts
if (getIntGroup(int_id) != Gicv3::G1NS) {
continue;
}
}
bool activate = data & (1 << int_id) ? 1 : 0;
if (activate) {
if (!irqActive[int_id]) {
DPRINTF(GIC, "Gicv3Redistributor::write(): "
"int_id %d active set\n", int_id);
}
irqActive[int_id] = true;
}
}
break;
case GICR_ICACTIVER0: // Interrupt Clear-Active Register 0
for (int int_id = 0; int_id < 8 * size; int_id++) {
if (!distributor->DS && !is_secure_access) {
// RAZ/WI for non-secure accesses for secure interrupts
if (getIntGroup(int_id) != Gicv3::G1NS) {
continue;
}
}
bool clear = data & (1 << int_id) ? 1 : 0;
if (clear) {
if (irqActive[int_id]) {
DPRINTF(GIC, "Gicv3Redistributor::write(): "
"int_id %d active cleared\n", int_id);
}
irqActive[int_id] = false;
}
}
break;
case GICR_ICFGR0: // SGI Configuration Register
// WI
return;
case GICR_ICFGR1: { // PPI Configuration Register
int first_intid = Gicv3::SGI_MAX;
for (int i = 0, int_id = first_intid; i < 8 * size;
i = i + 2, int_id++) {
if (!distributor->DS && !is_secure_access) {
// RAZ/WI for non-secure accesses for secure interrupts
if (getIntGroup(int_id) != Gicv3::G1NS) {
continue;
}
}
irqConfig[int_id] = data & (0x2 << i) ?
Gicv3::INT_EDGE_TRIGGERED :
Gicv3::INT_LEVEL_SENSITIVE;
DPRINTF(GIC, "Gicv3Redistributor::write(): "
"int_id %d (PPI) config %d\n",
int_id, irqConfig[int_id]);
}
break;
}
case GICR_IGRPMODR0: { // Interrupt Group Modifier Register 0
if (distributor->DS) {
// RAZ/WI if secutiry disabled
} else {
for (int int_id = 0; int_id < 8 * size; int_id++) {
if (!is_secure_access) {
// RAZ/WI for non-secure accesses
continue;
}
irqGrpmod[int_id] = data & (1 << int_id);
}
}
break;
}
case GICR_NSACR: { // Non-secure Access Control Register
if (distributor->DS) {
// RAZ/WI
} else {
if (!is_secure_access) {
// RAZ/WI
} else {
for (int i = 0, int_id = 0; i < 8 * size;
i = i + 2, int_id++) {
irqNsacr[int_id] = (data >> i) & 0x3;
}
}
}
break;
}
case GICR_SETLPIR: // Set LPI Pending Register
setClrLPI(data, true);
break;
case GICR_CLRLPIR: // Clear LPI Pending Register
setClrLPI(data, false);
break;
case GICR_PROPBASER: { // Redistributor Properties Base Address Register
// OuterCache, bits [58:56]
// 000 Memory type defined in InnerCache field
// Physical_Address, bits [51:12]
// Bits [51:12] of the physical address containing the LPI
// Configuration table
// Shareability, bits [11:10]
// 00 Non-shareable
// InnerCache, bits [9:7]
// 000 Device-nGnRnE
// IDbits, bits [4:0]
// limited by GICD_TYPER.IDbits (= 0xf)
lpiConfigurationTablePtr = data & 0xFFFFFFFFFF000;
lpiIDBits = data & 0x1f;
// 0xf here matches the value of GICD_TYPER.IDbits.
// TODO - make GICD_TYPER.IDbits a parameter instead of a hardcoded
// value
if (lpiIDBits > 0xf) {
lpiIDBits = 0xf;
}
break;
}
// Redistributor LPI Pending Table Base Address Register
case GICR_PENDBASER:
// PTZ, bit [62]
// Pending Table Zero
// OuterCache, bits [58:56]
// 000 Memory type defined in InnerCache field
// Physical_Address, bits [51:16]
// Bits [51:16] of the physical address containing the LPI Pending
// table
// Shareability, bits [11:10]
// 00 Non-shareable
// InnerCache, bits [9:7]
// 000 Device-nGnRnE
lpiPendingTablePtr = data & 0xFFFFFFFFF0000;
break;
case GICR_INVLPIR: { // Redistributor Invalidate LPI Register
// Do nothing: no caching supported
break;
}
case GICR_INVALLR: { // Redistributor Invalidate All Register
// Do nothing: no caching supported
break;
}
default:
panic("Gicv3Redistributor::write(): invalid offset %#x\n", addr);
break;
}
}
void
Gicv3Redistributor::sendPPInt(uint32_t int_id)
{
assert((int_id >= Gicv3::SGI_MAX) &&
(int_id < Gicv3::SGI_MAX + Gicv3::PPI_MAX));
irqPending[int_id] = true;
DPRINTF(GIC, "Gicv3Redistributor::sendPPInt(): "
"int_id %d (PPI) pending bit set\n", int_id);
updateDistributor();
}
void
Gicv3Redistributor::sendSGI(uint32_t int_id, Gicv3::GroupId group, bool ns)
{
assert(int_id < Gicv3::SGI_MAX);
Gicv3::GroupId int_group = getIntGroup(int_id);
bool forward = false;
if (ns) {
// Non-Secure EL1 and EL2 access
int nsaccess = irqNsacr[int_id];
if (int_group == Gicv3::G0S) {
forward = distributor->DS || (nsaccess >= 1);
} else if (int_group == Gicv3::G1S) {
forward = ((group == Gicv3::G1S || group == Gicv3::G1NS ) &&
nsaccess == 2);
} else {
// G1NS
forward = group == Gicv3::G1NS;
}
} else {
// Secure EL1 and EL3 access
forward = (group == int_group) ||
(group == Gicv3::G1S && int_group == Gicv3::G0S &&
distributor->DS);
}
if (!forward) return;
irqPending[int_id] = true;
DPRINTF(GIC, "Gicv3ReDistributor::sendSGI(): "
"int_id %d (SGI) pending bit set\n", int_id);
updateDistributor();
}
Gicv3::IntStatus
Gicv3Redistributor::intStatus(uint32_t int_id) const
{
assert(int_id < Gicv3::SGI_MAX + Gicv3::PPI_MAX);
if (irqPending[int_id]) {
if (irqActive[int_id]) {
return Gicv3::INT_ACTIVE_PENDING;
}
return Gicv3::INT_PENDING;
} else if (irqActive[int_id]) {
return Gicv3::INT_ACTIVE;
} else {
return Gicv3::INT_INACTIVE;
}
}
void
Gicv3Redistributor::updateDistributor()
{
distributor->update();
}
/*
* Recalculate the highest priority pending interrupt after a
* change to redistributor state.
*/
void
Gicv3Redistributor::update()
{
for (int int_id = 0; int_id < Gicv3::SGI_MAX + Gicv3::PPI_MAX; int_id++) {
Gicv3::GroupId int_group = getIntGroup(int_id);
bool group_enabled = distributor->groupEnabled(int_group);
if (irqPending[int_id] && irqEnabled[int_id] &&
!irqActive[int_id] && group_enabled) {
if ((irqPriority[int_id] < cpuInterface->hppi.prio) ||
/*
* Multiple pending ints with same priority.
* Implementation choice which one to signal.
* Our implementation selects the one with the lower id.
*/
(irqPriority[int_id] == cpuInterface->hppi.prio &&
int_id < cpuInterface->hppi.intid)) {
cpuInterface->hppi.intid = int_id;
cpuInterface->hppi.prio = irqPriority[int_id];
cpuInterface->hppi.group = int_group;
}
}
}
// Check LPIs
if (EnableLPIs) {
const uint32_t largest_lpi_id = 1 << (lpiIDBits + 1);
const uint32_t number_lpis = largest_lpi_id - SMALLEST_LPI_ID + 1;
uint8_t lpi_pending_table[largest_lpi_id / 8];
uint8_t lpi_config_table[number_lpis];
memProxy->readBlob(lpiPendingTablePtr,
lpi_pending_table,
sizeof(lpi_pending_table));
memProxy->readBlob(lpiConfigurationTablePtr,
lpi_config_table,
sizeof(lpi_config_table));
for (int lpi_id = SMALLEST_LPI_ID; lpi_id < largest_lpi_id;
lpi_id++) {
uint32_t lpi_pending_entry_byte = lpi_id / 8;
uint8_t lpi_pending_entry_bit_position = lpi_id % 8;
bool lpi_is_pending = lpi_pending_table[lpi_pending_entry_byte] &
1 << lpi_pending_entry_bit_position;
uint32_t lpi_configuration_entry_index = lpi_id - SMALLEST_LPI_ID;
LPIConfigurationTableEntry config_entry =
lpi_config_table[lpi_configuration_entry_index];
bool lpi_is_enable = config_entry.enable;
// LPIs are always Non-secure Group 1 interrupts,
// in a system where two Security states are enabled.
Gicv3::GroupId lpi_group = Gicv3::G1NS;
bool group_enabled = distributor->groupEnabled(lpi_group);
if (lpi_is_pending && lpi_is_enable && group_enabled) {
uint8_t lpi_priority = config_entry.priority << 2;
if ((lpi_priority < cpuInterface->hppi.prio) ||
(lpi_priority == cpuInterface->hppi.prio &&
lpi_id < cpuInterface->hppi.intid)) {
cpuInterface->hppi.intid = lpi_id;
cpuInterface->hppi.prio = lpi_priority;
cpuInterface->hppi.group = lpi_group;
}
}
}
}
cpuInterface->update();
}
uint8_t
Gicv3Redistributor::readEntryLPI(uint32_t lpi_id)
{
Addr lpi_pending_entry_ptr = lpiPendingTablePtr + (lpi_id / 8);
uint8_t lpi_pending_entry;
memProxy->readBlob(lpi_pending_entry_ptr,
&lpi_pending_entry,
sizeof(lpi_pending_entry));
return lpi_pending_entry;
}
void
Gicv3Redistributor::writeEntryLPI(uint32_t lpi_id, uint8_t lpi_pending_entry)
{
Addr lpi_pending_entry_ptr = lpiPendingTablePtr + (lpi_id / 8);
memProxy->writeBlob(lpi_pending_entry_ptr,
&lpi_pending_entry,
sizeof(lpi_pending_entry));
}
bool
Gicv3Redistributor::isPendingLPI(uint32_t lpi_id)
{
// Fetch the LPI pending entry from memory
uint8_t lpi_pending_entry = readEntryLPI(lpi_id);
uint8_t lpi_pending_entry_bit_position = lpi_id % 8;
bool is_set = lpi_pending_entry & (1 << lpi_pending_entry_bit_position);
return is_set;
}
void
Gicv3Redistributor::setClrLPI(uint64_t data, bool set)
{
if (!EnableLPIs) {
// Writes to GICR_SETLPIR or GICR_CLRLPIR have not effect if
// GICR_CTLR.EnableLPIs == 0.
return;
}
uint32_t lpi_id = data & 0xffffffff;
uint32_t largest_lpi_id = 1 << (lpiIDBits + 1);
if (lpi_id > largest_lpi_id) {
// Writes to GICR_SETLPIR or GICR_CLRLPIR have not effect if
// pINTID value specifies an unimplemented LPI.
return;
}
// Fetch the LPI pending entry from memory
uint8_t lpi_pending_entry = readEntryLPI(lpi_id);
uint8_t lpi_pending_entry_bit_position = lpi_id % 8;
bool is_set = lpi_pending_entry & (1 << lpi_pending_entry_bit_position);
if (set) {
if (is_set) {
// Writes to GICR_SETLPIR have not effect if the pINTID field
// corresponds to an LPI that is already pending.
return;
}
lpi_pending_entry |= 1 << (lpi_pending_entry_bit_position);
} else {
if (!is_set) {
// Writes to GICR_SETLPIR have not effect if the pINTID field
// corresponds to an LPI that is not pending.
return;
}
lpi_pending_entry &= ~(1 << (lpi_pending_entry_bit_position));
// Remove the pending state from the cpu interface
cpuInterface->resetHppi(lpi_id);
}
writeEntryLPI(lpi_id, lpi_pending_entry);
updateDistributor();
}
Gicv3::GroupId
Gicv3Redistributor::getIntGroup(int int_id) const
{
assert(int_id < (Gicv3::SGI_MAX + Gicv3::PPI_MAX));
if (distributor->DS) {
if (irqGroup[int_id] == 0) {
return Gicv3::G0S;
} else {
return Gicv3::G1NS;
}
} else {
if (irqGrpmod[int_id] == 0 && irqGroup[int_id] == 0) {
return Gicv3::G0S;
} else if (irqGrpmod[int_id] == 0 && irqGroup[int_id] == 1) {
return Gicv3::G1NS;
} else if (irqGrpmod[int_id] == 1 && irqGroup[int_id] == 0) {
return Gicv3::G1S;
} else if (irqGrpmod[int_id] == 1 && irqGroup[int_id] == 1) {
return Gicv3::G1NS;
}
}
M5_UNREACHABLE;
}
void
Gicv3Redistributor::activateIRQ(uint32_t int_id)
{
irqPending[int_id] = false;
irqActive[int_id] = true;
}
void
Gicv3Redistributor::deactivateIRQ(uint32_t int_id)
{
irqActive[int_id] = false;
}
uint32_t
Gicv3Redistributor::getAffinity() const
{
ThreadContext * tc = gic->getSystem()->getThreadContext(cpuId);
uint64_t mpidr = getMPIDR(gic->getSystem(), tc);
/*
* Aff3 = MPIDR[39:32]
* (Note getMPIDR() returns uint32_t so Aff3 is always 0...)
* Aff2 = MPIDR[23:16]
* Aff1 = MPIDR[15:8]
* Aff0 = MPIDR[7:0]
* affinity = Aff3.Aff2.Aff1.Aff0
*/
uint64_t affinity = ((mpidr & 0xff00000000) >> 8) | (mpidr & (0xffffff));
return affinity;
}
bool
Gicv3Redistributor::canBeSelectedFor1toNInterrupt(Gicv3::GroupId group) const
{
if (peInLowPowerState) {
return false;
}
if (!distributor->groupEnabled(group)) {
return false;
}
if ((group == Gicv3::G1S) && DPG1S) {
return false;
}
if ((group == Gicv3::G1NS) && DPG1NS) {
return false;
}
if ((group == Gicv3::G0S) && DPG0) {
return false;
}
return true;
}
void
Gicv3Redistributor::serialize(CheckpointOut & cp) const
{
SERIALIZE_SCALAR(peInLowPowerState);
SERIALIZE_CONTAINER(irqGroup);
SERIALIZE_CONTAINER(irqEnabled);
SERIALIZE_CONTAINER(irqPending);
SERIALIZE_CONTAINER(irqActive);
SERIALIZE_CONTAINER(irqPriority);
SERIALIZE_CONTAINER(irqConfig);
SERIALIZE_CONTAINER(irqGrpmod);
SERIALIZE_CONTAINER(irqNsacr);
SERIALIZE_SCALAR(DPG1S);
SERIALIZE_SCALAR(DPG1NS);
SERIALIZE_SCALAR(DPG0);
SERIALIZE_SCALAR(EnableLPIs);
SERIALIZE_SCALAR(lpiConfigurationTablePtr);
SERIALIZE_SCALAR(lpiIDBits);
SERIALIZE_SCALAR(lpiPendingTablePtr);
}
void
Gicv3Redistributor::unserialize(CheckpointIn & cp)
{
UNSERIALIZE_SCALAR(peInLowPowerState);
UNSERIALIZE_CONTAINER(irqGroup);
UNSERIALIZE_CONTAINER(irqEnabled);
UNSERIALIZE_CONTAINER(irqPending);
UNSERIALIZE_CONTAINER(irqActive);
UNSERIALIZE_CONTAINER(irqPriority);
UNSERIALIZE_CONTAINER(irqConfig);
UNSERIALIZE_CONTAINER(irqGrpmod);
UNSERIALIZE_CONTAINER(irqNsacr);
UNSERIALIZE_SCALAR(DPG1S);
UNSERIALIZE_SCALAR(DPG1NS);
UNSERIALIZE_SCALAR(DPG0);
UNSERIALIZE_SCALAR(EnableLPIs);
UNSERIALIZE_SCALAR(lpiConfigurationTablePtr);
UNSERIALIZE_SCALAR(lpiIDBits);
UNSERIALIZE_SCALAR(lpiPendingTablePtr);
}