gotosocial/vendor/github.com/cilium/ebpf/linker.go
Daniele Sluijters acc333c40b
[feature] Inherit resource limits from cgroups (#1336)
When GTS is running in a container runtime which has configured CPU or
memory limits or under an init system that uses cgroups to impose CPU
and memory limits the values the Go runtime sees for GOMAXPROCS and
GOMEMLIMIT are still based on the host resources, not the cgroup.

At least for the throttling middlewares which use GOMAXPROCS to
configure their queue size, this can result in GTS running with values
too big compared to the resources that will actuall be available to it.

This introduces 2 dependencies which can pick up resource contraints
from the current cgroup and tune the Go runtime accordingly. This should
result in the different queues being appropriately sized and in general
more predictable performance. These dependencies are a no-op on
non-Linux systems or if running in a cgroup that doesn't set a limit on
CPU or memory.

The automatic tuning of GOMEMLIMIT can be disabled by either explicitly
setting GOMEMLIMIT yourself or by setting AUTOMEMLIMIT=off. The
automatic tuning of GOMAXPROCS can similarly be counteracted by setting
GOMAXPROCS yourself.
2023-01-17 20:59:04 +00:00

133 lines
2.9 KiB
Go

package ebpf
import (
"fmt"
"github.com/cilium/ebpf/asm"
"github.com/cilium/ebpf/internal/btf"
)
// link resolves bpf-to-bpf calls.
//
// Each library may contain multiple functions / labels, and is only linked
// if prog references one of these functions.
//
// Libraries also linked.
func link(prog *ProgramSpec, libs []*ProgramSpec) error {
var (
linked = make(map[*ProgramSpec]bool)
pending = []asm.Instructions{prog.Instructions}
insns asm.Instructions
)
for len(pending) > 0 {
insns, pending = pending[0], pending[1:]
for _, lib := range libs {
if linked[lib] {
continue
}
needed, err := needSection(insns, lib.Instructions)
if err != nil {
return fmt.Errorf("linking %s: %w", lib.Name, err)
}
if !needed {
continue
}
linked[lib] = true
prog.Instructions = append(prog.Instructions, lib.Instructions...)
pending = append(pending, lib.Instructions)
if prog.BTF != nil && lib.BTF != nil {
if err := btf.ProgramAppend(prog.BTF, lib.BTF); err != nil {
return fmt.Errorf("linking BTF of %s: %w", lib.Name, err)
}
}
}
}
return nil
}
func needSection(insns, section asm.Instructions) (bool, error) {
// A map of symbols to the libraries which contain them.
symbols, err := section.SymbolOffsets()
if err != nil {
return false, err
}
for _, ins := range insns {
if ins.Reference == "" {
continue
}
if ins.OpCode.JumpOp() != asm.Call || ins.Src != asm.PseudoCall {
continue
}
if ins.Constant != -1 {
// This is already a valid call, no need to link again.
continue
}
if _, ok := symbols[ins.Reference]; !ok {
// Symbol isn't available in this section
continue
}
// At this point we know that at least one function in the
// library is called from insns, so we have to link it.
return true, nil
}
// None of the functions in the section are called.
return false, nil
}
func fixupJumpsAndCalls(insns asm.Instructions) error {
symbolOffsets := make(map[string]asm.RawInstructionOffset)
iter := insns.Iterate()
for iter.Next() {
ins := iter.Ins
if ins.Symbol == "" {
continue
}
if _, ok := symbolOffsets[ins.Symbol]; ok {
return fmt.Errorf("duplicate symbol %s", ins.Symbol)
}
symbolOffsets[ins.Symbol] = iter.Offset
}
iter = insns.Iterate()
for iter.Next() {
i := iter.Index
offset := iter.Offset
ins := iter.Ins
switch {
case ins.IsFunctionCall() && ins.Constant == -1:
// Rewrite bpf to bpf call
callOffset, ok := symbolOffsets[ins.Reference]
if !ok {
return fmt.Errorf("instruction %d: reference to missing symbol %q", i, ins.Reference)
}
ins.Constant = int64(callOffset - offset - 1)
case ins.OpCode.Class() == asm.JumpClass && ins.Offset == -1:
// Rewrite jump to label
jumpOffset, ok := symbolOffsets[ins.Reference]
if !ok {
return fmt.Errorf("instruction %d: reference to missing symbol %q", i, ins.Reference)
}
ins.Offset = int16(jumpOffset - offset - 1)
}
}
return nil
}