mirror of
https://github.com/cloud-hypervisor/cloud-hypervisor.git
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dcc646f5b1
With the new beta version, clippy complains about redundant allocation when using Arc<Box<dyn T>>, and suggests replacing it simply with Arc<dyn T>. Signed-off-by: Sebastien Boeuf <sebastien.boeuf@intel.com>
537 lines
18 KiB
Rust
537 lines
18 KiB
Rust
// Copyright © 2019 Intel Corporation
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//
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// SPDX-License-Identifier: Apache-2.0 OR BSD-3-Clause
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//
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use crate::{PciCapability, PciCapabilityId};
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use anyhow::anyhow;
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use byteorder::{ByteOrder, LittleEndian};
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use std::io;
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use std::result;
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use std::sync::Arc;
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use versionize::{VersionMap, Versionize, VersionizeResult};
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use versionize_derive::Versionize;
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use vm_device::interrupt::{
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InterruptIndex, InterruptSourceConfig, InterruptSourceGroup, MsiIrqSourceConfig,
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};
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use vm_memory::ByteValued;
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use vm_migration::{MigratableError, Pausable, Snapshot, Snapshottable, VersionMapped};
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const MAX_MSIX_VECTORS_PER_DEVICE: u16 = 2048;
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const MSIX_TABLE_ENTRIES_MODULO: u64 = 16;
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const MSIX_PBA_ENTRIES_MODULO: u64 = 8;
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const BITS_PER_PBA_ENTRY: usize = 64;
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const FUNCTION_MASK_BIT: u8 = 14;
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const MSIX_ENABLE_BIT: u8 = 15;
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const FUNCTION_MASK_MASK: u16 = (1 << FUNCTION_MASK_BIT) as u16;
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const MSIX_ENABLE_MASK: u16 = (1 << MSIX_ENABLE_BIT) as u16;
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pub const MSIX_TABLE_ENTRY_SIZE: usize = 16;
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#[derive(Debug)]
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enum Error {
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/// Failed enabling the interrupt route.
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EnableInterruptRoute(io::Error),
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/// Failed updating the interrupt route.
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UpdateInterruptRoute(io::Error),
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}
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#[derive(Debug, Clone, Versionize)]
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pub struct MsixTableEntry {
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pub msg_addr_lo: u32,
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pub msg_addr_hi: u32,
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pub msg_data: u32,
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pub vector_ctl: u32,
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}
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impl MsixTableEntry {
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pub fn masked(&self) -> bool {
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self.vector_ctl & 0x1 == 0x1
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}
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}
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impl Default for MsixTableEntry {
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fn default() -> Self {
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MsixTableEntry {
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msg_addr_lo: 0,
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msg_addr_hi: 0,
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msg_data: 0,
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vector_ctl: 0x1,
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}
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}
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}
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#[derive(Versionize)]
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struct MsixConfigState {
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table_entries: Vec<MsixTableEntry>,
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pba_entries: Vec<u64>,
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masked: bool,
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enabled: bool,
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}
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impl VersionMapped for MsixConfigState {}
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pub struct MsixConfig {
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pub table_entries: Vec<MsixTableEntry>,
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pub pba_entries: Vec<u64>,
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pub devid: u32,
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interrupt_source_group: Arc<dyn InterruptSourceGroup>,
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masked: bool,
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enabled: bool,
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}
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impl MsixConfig {
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pub fn new(
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msix_vectors: u16,
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interrupt_source_group: Arc<dyn InterruptSourceGroup>,
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devid: u32,
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) -> Self {
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assert!(msix_vectors <= MAX_MSIX_VECTORS_PER_DEVICE);
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let mut table_entries: Vec<MsixTableEntry> = Vec::new();
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table_entries.resize_with(msix_vectors as usize, Default::default);
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let mut pba_entries: Vec<u64> = Vec::new();
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let num_pba_entries: usize = ((msix_vectors as usize) / BITS_PER_PBA_ENTRY) + 1;
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pba_entries.resize_with(num_pba_entries, Default::default);
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MsixConfig {
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table_entries,
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pba_entries,
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devid,
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interrupt_source_group,
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masked: true,
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enabled: false,
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}
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}
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fn state(&self) -> MsixConfigState {
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MsixConfigState {
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table_entries: self.table_entries.clone(),
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pba_entries: self.pba_entries.clone(),
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masked: self.masked,
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enabled: self.enabled,
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}
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}
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fn set_state(&mut self, state: &MsixConfigState) -> result::Result<(), Error> {
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self.table_entries = state.table_entries.clone();
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self.pba_entries = state.pba_entries.clone();
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self.masked = state.masked;
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self.enabled = state.enabled;
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if self.enabled && !self.masked {
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for (idx, table_entry) in self.table_entries.iter().enumerate() {
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if table_entry.masked() {
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continue;
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}
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let config = MsiIrqSourceConfig {
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high_addr: table_entry.msg_addr_hi,
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low_addr: table_entry.msg_addr_lo,
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data: table_entry.msg_data,
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devid: self.devid,
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};
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self.interrupt_source_group
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.update(idx as InterruptIndex, InterruptSourceConfig::MsiIrq(config))
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.map_err(Error::UpdateInterruptRoute)?;
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self.interrupt_source_group
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.enable()
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.map_err(Error::EnableInterruptRoute)?;
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}
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}
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Ok(())
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}
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pub fn masked(&self) -> bool {
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self.masked
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}
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pub fn enabled(&self) -> bool {
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self.enabled
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}
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pub fn set_msg_ctl(&mut self, reg: u16) {
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let old_masked = self.masked;
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let old_enabled = self.enabled;
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self.masked = ((reg >> FUNCTION_MASK_BIT) & 1u16) == 1u16;
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self.enabled = ((reg >> MSIX_ENABLE_BIT) & 1u16) == 1u16;
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// Update interrupt routing
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if old_masked != self.masked || old_enabled != self.enabled {
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if self.enabled && !self.masked {
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for (idx, table_entry) in self.table_entries.iter().enumerate() {
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let config = MsiIrqSourceConfig {
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high_addr: table_entry.msg_addr_hi,
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low_addr: table_entry.msg_addr_lo,
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data: table_entry.msg_data,
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devid: self.devid,
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};
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if let Err(e) = self
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.interrupt_source_group
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.update(idx as InterruptIndex, InterruptSourceConfig::MsiIrq(config))
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{
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error!("Failed updating vector: {:?}", e);
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}
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if table_entry.masked() {
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if let Err(e) = self.interrupt_source_group.mask(idx as InterruptIndex) {
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error!("Failed masking vector: {:?}", e);
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}
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} else if let Err(e) = self.interrupt_source_group.unmask(idx as InterruptIndex)
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{
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error!("Failed unmasking vector: {:?}", e);
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}
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}
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} else if old_enabled || !old_masked {
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if let Err(e) = self.interrupt_source_group.disable() {
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error!("Failed disabling irq_fd: {:?}", e);
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}
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}
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}
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// If the Function Mask bit was set, and has just been cleared, it's
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// important to go through the entire PBA to check if there was any
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// pending MSI-X message to inject, given that the vector is not
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// masked.
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if old_masked && !self.masked {
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for (index, entry) in self.table_entries.clone().iter().enumerate() {
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if !entry.masked() && self.get_pba_bit(index as u16) == 1 {
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self.inject_msix_and_clear_pba(index);
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}
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}
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}
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}
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pub fn read_table(&self, offset: u64, data: &mut [u8]) {
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assert!((data.len() == 4 || data.len() == 8));
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let index: usize = (offset / MSIX_TABLE_ENTRIES_MODULO) as usize;
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let modulo_offset = offset % MSIX_TABLE_ENTRIES_MODULO;
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match data.len() {
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4 => {
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let value = match modulo_offset {
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0x0 => self.table_entries[index].msg_addr_lo,
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0x4 => self.table_entries[index].msg_addr_hi,
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0x8 => self.table_entries[index].msg_data,
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0xc => self.table_entries[index].vector_ctl,
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_ => {
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error!("invalid offset");
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0
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}
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};
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debug!("MSI_R TABLE offset 0x{:x} data 0x{:x}", offset, value);
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LittleEndian::write_u32(data, value);
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}
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8 => {
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let value = match modulo_offset {
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0x0 => {
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(u64::from(self.table_entries[index].msg_addr_hi) << 32)
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| u64::from(self.table_entries[index].msg_addr_lo)
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}
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0x8 => {
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(u64::from(self.table_entries[index].vector_ctl) << 32)
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| u64::from(self.table_entries[index].msg_data)
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}
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_ => {
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error!("invalid offset");
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0
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}
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};
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debug!("MSI_R TABLE offset 0x{:x} data 0x{:x}", offset, value);
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LittleEndian::write_u64(data, value);
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}
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_ => {
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error!("invalid data length");
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}
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}
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}
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pub fn write_table(&mut self, offset: u64, data: &[u8]) {
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assert!((data.len() == 4 || data.len() == 8));
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let index: usize = (offset / MSIX_TABLE_ENTRIES_MODULO) as usize;
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let modulo_offset = offset % MSIX_TABLE_ENTRIES_MODULO;
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// Store the value of the entry before modification
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let mut old_entry: Option<MsixTableEntry> = None;
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match data.len() {
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4 => {
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let value = LittleEndian::read_u32(data);
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match modulo_offset {
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0x0 => self.table_entries[index].msg_addr_lo = value,
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0x4 => self.table_entries[index].msg_addr_hi = value,
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0x8 => self.table_entries[index].msg_data = value,
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0xc => {
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old_entry = Some(self.table_entries[index].clone());
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self.table_entries[index].vector_ctl = value;
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}
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_ => error!("invalid offset"),
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};
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debug!("MSI_W TABLE offset 0x{:x} data 0x{:x}", offset, value);
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}
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8 => {
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let value = LittleEndian::read_u64(data);
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match modulo_offset {
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0x0 => {
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self.table_entries[index].msg_addr_lo = (value & 0xffff_ffffu64) as u32;
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self.table_entries[index].msg_addr_hi = (value >> 32) as u32;
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}
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0x8 => {
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old_entry = Some(self.table_entries[index].clone());
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self.table_entries[index].msg_data = (value & 0xffff_ffffu64) as u32;
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self.table_entries[index].vector_ctl = (value >> 32) as u32;
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}
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_ => error!("invalid offset"),
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};
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debug!("MSI_W TABLE offset 0x{:x} data 0x{:x}", offset, value);
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}
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_ => error!("invalid data length"),
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};
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// Update interrupt routes
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if self.enabled && !self.masked {
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let table_entry = &self.table_entries[index];
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let config = MsiIrqSourceConfig {
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high_addr: table_entry.msg_addr_hi,
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low_addr: table_entry.msg_addr_lo,
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data: table_entry.msg_data,
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devid: self.devid,
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};
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if let Err(e) = self.interrupt_source_group.update(
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index as InterruptIndex,
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InterruptSourceConfig::MsiIrq(config),
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) {
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error!("Failed updating vector: {:?}", e);
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}
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if table_entry.masked() {
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if let Err(e) = self.interrupt_source_group.mask(index as InterruptIndex) {
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error!("Failed masking vector: {:?}", e);
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}
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} else if let Err(e) = self.interrupt_source_group.unmask(index as InterruptIndex) {
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error!("Failed unmasking vector: {:?}", e);
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}
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}
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// After the MSI-X table entry has been updated, it is necessary to
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// check if the vector control masking bit has changed. In case the
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// bit has been flipped from 1 to 0, we need to inject a MSI message
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// if the corresponding pending bit from the PBA is set. Once the MSI
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// has been injected, the pending bit in the PBA needs to be cleared.
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// All of this is valid only if MSI-X has not been masked for the whole
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// device.
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if let Some(old_entry) = old_entry {
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// Check if bit has been flipped
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if !self.masked()
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&& old_entry.masked()
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&& !self.table_entries[index].masked()
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&& self.get_pba_bit(index as u16) == 1
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{
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self.inject_msix_and_clear_pba(index);
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}
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}
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}
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pub fn read_pba(&mut self, offset: u64, data: &mut [u8]) {
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assert!((data.len() == 4 || data.len() == 8));
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let index: usize = (offset / MSIX_PBA_ENTRIES_MODULO) as usize;
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let modulo_offset = offset % MSIX_PBA_ENTRIES_MODULO;
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match data.len() {
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4 => {
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let value: u32 = match modulo_offset {
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0x0 => (self.pba_entries[index] & 0xffff_ffffu64) as u32,
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0x4 => (self.pba_entries[index] >> 32) as u32,
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_ => {
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error!("invalid offset");
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0
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}
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};
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debug!("MSI_R PBA offset 0x{:x} data 0x{:x}", offset, value);
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LittleEndian::write_u32(data, value);
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}
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8 => {
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let value: u64 = match modulo_offset {
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0x0 => self.pba_entries[index],
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_ => {
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error!("invalid offset");
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0
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}
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};
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debug!("MSI_R PBA offset 0x{:x} data 0x{:x}", offset, value);
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LittleEndian::write_u64(data, value);
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}
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_ => {
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error!("invalid data length");
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}
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}
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}
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pub fn write_pba(&mut self, _offset: u64, _data: &[u8]) {
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error!("Pending Bit Array is read only");
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}
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pub fn set_pba_bit(&mut self, vector: u16, reset: bool) {
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assert!(vector < MAX_MSIX_VECTORS_PER_DEVICE);
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let index: usize = (vector as usize) / BITS_PER_PBA_ENTRY;
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let shift: usize = (vector as usize) % BITS_PER_PBA_ENTRY;
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let mut mask: u64 = (1 << shift) as u64;
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if reset {
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mask = !mask;
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self.pba_entries[index] &= mask;
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} else {
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self.pba_entries[index] |= mask;
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}
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}
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fn get_pba_bit(&self, vector: u16) -> u8 {
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assert!(vector < MAX_MSIX_VECTORS_PER_DEVICE);
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let index: usize = (vector as usize) / BITS_PER_PBA_ENTRY;
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let shift: usize = (vector as usize) % BITS_PER_PBA_ENTRY;
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((self.pba_entries[index] >> shift) & 0x0000_0001u64) as u8
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}
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fn inject_msix_and_clear_pba(&mut self, vector: usize) {
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// Inject the MSI message
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match self
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.interrupt_source_group
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.trigger(vector as InterruptIndex)
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{
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Ok(_) => debug!("MSI-X injected on vector control flip"),
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Err(e) => error!("failed to inject MSI-X: {}", e),
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}
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// Clear the bit from PBA
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self.set_pba_bit(vector as u16, true);
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}
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}
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impl Pausable for MsixConfig {}
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impl Snapshottable for MsixConfig {
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fn id(&self) -> String {
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String::from("msix_config")
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}
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fn snapshot(&mut self) -> std::result::Result<Snapshot, MigratableError> {
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Snapshot::new_from_versioned_state(&self.id(), &self.state())
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}
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fn restore(&mut self, snapshot: Snapshot) -> std::result::Result<(), MigratableError> {
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self.set_state(&snapshot.to_versioned_state(&self.id())?)
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.map_err(|e| {
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MigratableError::Restore(anyhow!(
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"Could not restore state for {}: {:?}",
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self.id(),
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e
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))
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})
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}
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}
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#[allow(dead_code)]
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#[repr(packed)]
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#[derive(Clone, Copy, Default)]
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pub struct MsixCap {
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// Message Control Register
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// 10-0: MSI-X Table size
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// 13-11: Reserved
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// 14: Mask. Mask all MSI-X when set.
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// 15: Enable. Enable all MSI-X when set.
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pub msg_ctl: u16,
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// Table. Contains the offset and the BAR indicator (BIR)
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// 2-0: Table BAR indicator (BIR). Can be 0 to 5.
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// 31-3: Table offset in the BAR pointed by the BIR.
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pub table: u32,
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// Pending Bit Array. Contains the offset and the BAR indicator (BIR)
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// 2-0: PBA BAR indicator (BIR). Can be 0 to 5.
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// 31-3: PBA offset in the BAR pointed by the BIR.
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pub pba: u32,
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}
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// It is safe to implement ByteValued. All members are simple numbers and any value is valid.
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unsafe impl ByteValued for MsixCap {}
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impl PciCapability for MsixCap {
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fn bytes(&self) -> &[u8] {
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self.as_slice()
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}
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fn id(&self) -> PciCapabilityId {
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PciCapabilityId::MsiX
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}
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}
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impl MsixCap {
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pub fn new(
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table_pci_bar: u8,
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table_size: u16,
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table_off: u32,
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pba_pci_bar: u8,
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pba_off: u32,
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) -> Self {
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assert!(table_size < MAX_MSIX_VECTORS_PER_DEVICE);
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// Set the table size and enable MSI-X.
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let msg_ctl: u16 = 0x8000u16 + table_size - 1;
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MsixCap {
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msg_ctl,
|
|
table: (table_off & 0xffff_fff8u32) | u32::from(table_pci_bar & 0x7u8),
|
|
pba: (pba_off & 0xffff_fff8u32) | u32::from(pba_pci_bar & 0x7u8),
|
|
}
|
|
}
|
|
|
|
pub fn set_msg_ctl(&mut self, data: u16) {
|
|
self.msg_ctl = (self.msg_ctl & !(FUNCTION_MASK_MASK | MSIX_ENABLE_MASK))
|
|
| (data & (FUNCTION_MASK_MASK | MSIX_ENABLE_MASK));
|
|
}
|
|
|
|
pub fn masked(&self) -> bool {
|
|
(self.msg_ctl >> FUNCTION_MASK_BIT) & 0x1 == 0x1
|
|
}
|
|
|
|
pub fn enabled(&self) -> bool {
|
|
(self.msg_ctl >> MSIX_ENABLE_BIT) & 0x1 == 0x1
|
|
}
|
|
|
|
pub fn table_offset(&self) -> u32 {
|
|
self.table & 0xffff_fff8
|
|
}
|
|
|
|
pub fn pba_offset(&self) -> u32 {
|
|
self.pba & 0xffff_fff8
|
|
}
|
|
|
|
pub fn table_bir(&self) -> u32 {
|
|
self.table & 0x7
|
|
}
|
|
|
|
pub fn pba_bir(&self) -> u32 {
|
|
self.pba & 0x7
|
|
}
|
|
|
|
pub fn table_size(&self) -> u16 {
|
|
(self.msg_ctl & 0x7ff) + 1
|
|
}
|
|
}
|