ceph-csi/vendor/github.com/ceph/go-ceph/rados/operation.go

package rados

// #include <stdlib.h>
import "C"

import (
	"fmt"
	"strings"
	"unsafe"
)

// The file operation.go exists to support both read op and write op types that
// have some pretty common behaviors between them. In C/C++ its assumed that
// the buffer types and other pointers will not be freed between passing them
// to the action setup calls (things like rados_write_op_write or
// rados_read_op_omap_get_vals2) and the call to Operate(...).  Since there's
// nothing stopping one from sleeping for hours between these calls, or passing
// the op to other functions and calling Operate there, we want a mechanism
// that's (fairly) simple to understand and won't run afoul of Go's garbage
// collection.  That's one reason the operation type tracks the steps (the
// parts that track complex inputs and outputs) so that as long as the op
// exists it will have a reference to the step, which will have references
// to the C language types.

type opKind string

const (
	readOp  opKind = "read"
	writeOp opKind = "write"
)

// OperationError is an error type that may be returned by an Operate call.
// It captures the error from the operate call itself and any errors from
// steps that can return an error.
type OperationError struct {
	kind       opKind
	OpError    error
	StepErrors map[int]error
}

func (e OperationError) Error() string {
	subErrors := []string{}
	if e.OpError != nil {
		subErrors = append(subErrors,
			fmt.Sprintf("op=%s", e.OpError))
	}
	for idx, es := range e.StepErrors {
		subErrors = append(subErrors,
			fmt.Sprintf("Step#%d=%s", idx, es))
	}
	return fmt.Sprintf(
		"%s operation error: %s",
		e.kind,
		strings.Join(subErrors, ", "))
}

// opStep provides an interface for types that are tied to the management of
// data being input or output from write ops and read ops. The steps are
// meant to simplify the internals of the ops themselves and be exportable when
// appropriate. If a step is not being exported it should not be returned
// from an ops action function. If the step is exported it should be
// returned from an ops action function.
//
// Not all types implementing opStep are expected to need all the functions
// in the interface. However, for the sake of simplicity on the op side, we use
// the same interface for all cases and expect those implementing opStep
// just embed the without* types that provide no-op implementation of
// functions that make up this interface.
type opStep interface {
	// update the state of the step after the call to Operate.
	// It can be used to convert values from C and cache them and/or
	// communicate a failure of the action associated with the step.  The
	// update call will only be made once. Implementations are not required to
	// handle this call being made more than once.
	update() error
	// free will be called to free any resources, especially C memory, that
	// the step is managing. The behavior of free should be idempotent and
	// handle being called more than once.
	free()
}

// operation represents some of the shared underlying mechanisms for
// both read and write op types.
type operation struct {
	steps []opStep
}

// free will call the free method of all the steps this operation
// contains.
func (o *operation) free() {
	for i := range o.steps {
		o.steps[i].free()
	}
}

// update the operation and the steps it contains. The top-level result
// of the rados call is passed in as ret and used to construct errors.
// The update call of each step is used to update the contents of each
// step and gather any errors from those steps.
func (o *operation) update(kind opKind, ret C.int) error {
	stepErrors := map[int]error{}
	for i := range o.steps {
		if err := o.steps[i].update(); err != nil {
			stepErrors[i] = err
		}
	}
	if ret == 0 && len(stepErrors) == 0 {
		return nil
	}
	return OperationError{
		kind:       kind,
		OpError:    getError(ret),
		StepErrors: stepErrors,
	}
}

func opStepFinalizer(s opStep) {
	if s != nil {
		s.free()
	}
}

// withoutUpdate can be embedded in a struct to help indicate
// the type implements the opStep interface but has a no-op
// update function.
type withoutUpdate struct{}

func (*withoutUpdate) update() error { return nil }

// withoutFree can be embedded in a struct to help indicate
// the type implements the opStep interface but has a no-op
// free function.
type withoutFree struct{}

func (*withoutFree) free() {}

// withRefs is a embeddable type to help track and free C memory.
type withRefs struct {
	refs []unsafe.Pointer
}

func (w *withRefs) free() {
	for i := range w.refs {
		C.free(w.refs[i])
	}
	w.refs = nil
}

func (w *withRefs) add(ptr unsafe.Pointer) {
	w.refs = append(w.refs, ptr)
}
rebase: update go-ceph to v0.8.0 Updating go-ceph to v0.8.0. Signed-off-by: Mudit Agarwal <muagarwa@redhat.com> 2021-02-10 03:38:18 +00:00			`package rados`

			`// #include <stdlib.h>`
			`import "C"`

			`import (`
			`"fmt"`
			`"strings"`
			`"unsafe"`
			`)`

			`// The file operation.go exists to support both read op and write op types that`
			`// have some pretty common behaviors between them. In C/C++ its assumed that`
			`// the buffer types and other pointers will not be freed between passing them`
			`// to the action setup calls (things like rados_write_op_write or`
			`// rados_read_op_omap_get_vals2) and the call to Operate(...). Since there's`
			`// nothing stopping one from sleeping for hours between these calls, or passing`
			`// the op to other functions and calling Operate there, we want a mechanism`
			`// that's (fairly) simple to understand and won't run afoul of Go's garbage`
			`// collection. That's one reason the operation type tracks the steps (the`
			`// parts that track complex inputs and outputs) so that as long as the op`
			`// exists it will have a reference to the step, which will have references`
			`// to the C language types.`

			`type opKind string`

			`const (`
			`readOp opKind = "read"`
			`writeOp opKind = "write"`
			`)`

			`// OperationError is an error type that may be returned by an Operate call.`
			`// It captures the error from the operate call itself and any errors from`
			`// steps that can return an error.`
			`type OperationError struct {`
			`kind opKind`
			`OpError error`
			`StepErrors map[int]error`
			`}`

			`func (e OperationError) Error() string {`
			`subErrors := []string{}`
			`if e.OpError != nil {`
			`subErrors = append(subErrors,`
			`fmt.Sprintf("op=%s", e.OpError))`
			`}`
			`for idx, es := range e.StepErrors {`
			`subErrors = append(subErrors,`
			`fmt.Sprintf("Step#%d=%s", idx, es))`
			`}`
			`return fmt.Sprintf(`
			`"%s operation error: %s",`
			`e.kind,`
			`strings.Join(subErrors, ", "))`
			`}`

			`// opStep provides an interface for types that are tied to the management of`
			`// data being input or output from write ops and read ops. The steps are`
			`// meant to simplify the internals of the ops themselves and be exportable when`
			`// appropriate. If a step is not being exported it should not be returned`
			`// from an ops action function. If the step is exported it should be`
			`// returned from an ops action function.`
			`//`
			`// Not all types implementing opStep are expected to need all the functions`
			`// in the interface. However, for the sake of simplicity on the op side, we use`
			`// the same interface for all cases and expect those implementing opStep`
			`// just embed the without* types that provide no-op implementation of`
			`// functions that make up this interface.`
			`type opStep interface {`
			`// update the state of the step after the call to Operate.`
			`// It can be used to convert values from C and cache them and/or`
			`// communicate a failure of the action associated with the step. The`
			`// update call will only be made once. Implementations are not required to`
			`// handle this call being made more than once.`
			`update() error`
			`// free will be called to free any resources, especially C memory, that`
			`// the step is managing. The behavior of free should be idempotent and`
			`// handle being called more than once.`
			`free()`
			`}`

			`// operation represents some of the shared underlying mechanisms for`
			`// both read and write op types.`
			`type operation struct {`
			`steps []opStep`
			`}`

			`// free will call the free method of all the steps this operation`
			`// contains.`
			`func (o *operation) free() {`
			`for i := range o.steps {`
			`o.steps[i].free()`
			`}`
			`}`

			`// update the operation and the steps it contains. The top-level result`
			`// of the rados call is passed in as ret and used to construct errors.`
			`// The update call of each step is used to update the contents of each`
			`// step and gather any errors from those steps.`
			`func (o *operation) update(kind opKind, ret C.int) error {`
			`stepErrors := map[int]error{}`
			`for i := range o.steps {`
			`if err := o.steps[i].update(); err != nil {`
			`stepErrors[i] = err`
			`}`
			`}`
			`if ret == 0 && len(stepErrors) == 0 {`
			`return nil`
			`}`
			`return OperationError{`
			`kind: kind,`
			`OpError: getError(ret),`
			`StepErrors: stepErrors,`
			`}`
			`}`

			`func opStepFinalizer(s opStep) {`
			`if s != nil {`
			`s.free()`
			`}`
			`}`

			`// withoutUpdate can be embedded in a struct to help indicate`
			`// the type implements the opStep interface but has a no-op`
			`// update function.`
			`type withoutUpdate struct{}`

			`func (*withoutUpdate) update() error { return nil }`

			`// withoutFree can be embedded in a struct to help indicate`
			`// the type implements the opStep interface but has a no-op`
			`// free function.`
			`type withoutFree struct{}`

			`func (*withoutFree) free() {}`

			`// withRefs is a embeddable type to help track and free C memory.`
			`type withRefs struct {`
			`refs []unsafe.Pointer`
			`}`

			`func (w *withRefs) free() {`
			`for i := range w.refs {`
			`C.free(w.refs[i])`
			`}`
			`w.refs = nil`
			`}`

			`func (w *withRefs) add(ptr unsafe.Pointer) {`
			`w.refs = append(w.refs, ptr)`
			`}`