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f-stack/dpdk/lib/pipeline/rte_swx_pipeline.c

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/* SPDX-License-Identifier: BSD-3-Clause
* Copyright(c) 2020 Intel Corporation
*/
#include <stdlib.h>
#include <stdio.h>
#include <errno.h>
#include <arpa/inet.h>
#include <dlfcn.h>
#include "rte_swx_pipeline_internal.h"
#define CHECK(condition, err_code) \
do { \
if (!(condition)) \
return -(err_code); \
} while (0)
#define CHECK_NAME(name, err_code) \
CHECK((name) && \
(name)[0] && \
(strnlen((name), RTE_SWX_NAME_SIZE) < RTE_SWX_NAME_SIZE), \
err_code)
#define CHECK_INSTRUCTION(instr, err_code) \
CHECK((instr) && \
(instr)[0] && \
(strnlen((instr), RTE_SWX_INSTRUCTION_SIZE) < \
RTE_SWX_INSTRUCTION_SIZE), \
err_code)
/*
* Environment.
*/
#ifndef RTE_SWX_PIPELINE_HUGE_PAGES_DISABLE
#include <rte_malloc.h>
static void *
env_malloc(size_t size, size_t alignment, int numa_node)
{
return rte_zmalloc_socket(NULL, size, alignment, numa_node);
}
static void
env_free(void *start, size_t size __rte_unused)
{
rte_free(start);
}
#else
#include <numa.h>
static void *
env_malloc(size_t size, size_t alignment __rte_unused, int numa_node)
{
void *start;
if (numa_available() == -1)
return NULL;
start = numa_alloc_onnode(size, numa_node);
if (!start)
return NULL;
memset(start, 0, size);
return start;
}
static void
env_free(void *start, size_t size)
{
if (numa_available() == -1)
return;
numa_free(start, size);
}
#endif
/*
* Struct.
*/
static struct struct_type *
struct_type_find(struct rte_swx_pipeline *p, const char *name)
{
struct struct_type *elem;
TAILQ_FOREACH(elem, &p->struct_types, node)
if (strcmp(elem->name, name) == 0)
return elem;
return NULL;
}
static struct field *
struct_type_field_find(struct struct_type *st, const char *name)
{
uint32_t i;
for (i = 0; i < st->n_fields; i++) {
struct field *f = &st->fields[i];
if (strcmp(f->name, name) == 0)
return f;
}
return NULL;
}
int
rte_swx_pipeline_struct_type_register(struct rte_swx_pipeline *p,
const char *name,
struct rte_swx_field_params *fields,
uint32_t n_fields,
int last_field_has_variable_size)
{
struct struct_type *st;
uint32_t i;
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK(fields, EINVAL);
CHECK(n_fields, EINVAL);
for (i = 0; i < n_fields; i++) {
struct rte_swx_field_params *f = &fields[i];
int var_size = ((i == n_fields - 1) && last_field_has_variable_size) ? 1 : 0;
uint32_t j;
CHECK_NAME(f->name, EINVAL);
CHECK(f->n_bits, EINVAL);
CHECK((f->n_bits <= 64) || var_size, EINVAL);
CHECK((f->n_bits & 7) == 0, EINVAL);
for (j = 0; j < i; j++) {
struct rte_swx_field_params *f_prev = &fields[j];
CHECK(strcmp(f->name, f_prev->name), EINVAL);
}
}
CHECK(!struct_type_find(p, name), EEXIST);
/* Node allocation. */
st = calloc(1, sizeof(struct struct_type));
CHECK(st, ENOMEM);
st->fields = calloc(n_fields, sizeof(struct field));
if (!st->fields) {
free(st);
CHECK(0, ENOMEM);
}
/* Node initialization. */
strcpy(st->name, name);
for (i = 0; i < n_fields; i++) {
struct field *dst = &st->fields[i];
struct rte_swx_field_params *src = &fields[i];
int var_size = ((i == n_fields - 1) && last_field_has_variable_size) ? 1 : 0;
strcpy(dst->name, src->name);
dst->n_bits = src->n_bits;
dst->offset = st->n_bits;
dst->var_size = var_size;
st->n_bits += src->n_bits;
st->n_bits_min += var_size ? 0 : src->n_bits;
}
st->n_fields = n_fields;
st->var_size = last_field_has_variable_size;
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->struct_types, st, node);
return 0;
}
static int
struct_build(struct rte_swx_pipeline *p)
{
uint32_t i;
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
t->structs = calloc(p->n_structs, sizeof(uint8_t *));
CHECK(t->structs, ENOMEM);
}
return 0;
}
static void
struct_build_free(struct rte_swx_pipeline *p)
{
uint32_t i;
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
free(t->structs);
t->structs = NULL;
}
}
static void
struct_free(struct rte_swx_pipeline *p)
{
struct_build_free(p);
/* Struct types. */
for ( ; ; ) {
struct struct_type *elem;
elem = TAILQ_FIRST(&p->struct_types);
if (!elem)
break;
TAILQ_REMOVE(&p->struct_types, elem, node);
free(elem->fields);
free(elem);
}
}
/*
* Input port.
*/
static struct port_in_type *
port_in_type_find(struct rte_swx_pipeline *p, const char *name)
{
struct port_in_type *elem;
if (!name)
return NULL;
TAILQ_FOREACH(elem, &p->port_in_types, node)
if (strcmp(elem->name, name) == 0)
return elem;
return NULL;
}
int
rte_swx_pipeline_port_in_type_register(struct rte_swx_pipeline *p,
const char *name,
struct rte_swx_port_in_ops *ops)
{
struct port_in_type *elem;
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK(ops, EINVAL);
CHECK(ops->create, EINVAL);
CHECK(ops->free, EINVAL);
CHECK(ops->pkt_rx, EINVAL);
CHECK(ops->stats_read, EINVAL);
CHECK(!port_in_type_find(p, name), EEXIST);
/* Node allocation. */
elem = calloc(1, sizeof(struct port_in_type));
CHECK(elem, ENOMEM);
/* Node initialization. */
strcpy(elem->name, name);
memcpy(&elem->ops, ops, sizeof(*ops));
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->port_in_types, elem, node);
return 0;
}
static struct port_in *
port_in_find(struct rte_swx_pipeline *p, uint32_t port_id)
{
struct port_in *port;
TAILQ_FOREACH(port, &p->ports_in, node)
if (port->id == port_id)
return port;
return NULL;
}
int
rte_swx_pipeline_port_in_config(struct rte_swx_pipeline *p,
uint32_t port_id,
const char *port_type_name,
void *args)
{
struct port_in_type *type = NULL;
struct port_in *port = NULL;
void *obj = NULL;
CHECK(p, EINVAL);
CHECK(!port_in_find(p, port_id), EINVAL);
CHECK_NAME(port_type_name, EINVAL);
type = port_in_type_find(p, port_type_name);
CHECK(type, EINVAL);
obj = type->ops.create(args);
CHECK(obj, ENODEV);
/* Node allocation. */
port = calloc(1, sizeof(struct port_in));
CHECK(port, ENOMEM);
/* Node initialization. */
port->type = type;
port->obj = obj;
port->id = port_id;
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->ports_in, port, node);
if (p->n_ports_in < port_id + 1)
p->n_ports_in = port_id + 1;
return 0;
}
static int
port_in_build(struct rte_swx_pipeline *p)
{
struct port_in *port;
uint32_t i;
CHECK(p->n_ports_in, EINVAL);
CHECK(rte_is_power_of_2(p->n_ports_in), EINVAL);
for (i = 0; i < p->n_ports_in; i++)
CHECK(port_in_find(p, i), EINVAL);
p->in = calloc(p->n_ports_in, sizeof(struct port_in_runtime));
CHECK(p->in, ENOMEM);
TAILQ_FOREACH(port, &p->ports_in, node) {
struct port_in_runtime *in = &p->in[port->id];
in->pkt_rx = port->type->ops.pkt_rx;
in->obj = port->obj;
}
return 0;
}
static void
port_in_build_free(struct rte_swx_pipeline *p)
{
free(p->in);
p->in = NULL;
}
static void
port_in_free(struct rte_swx_pipeline *p)
{
port_in_build_free(p);
/* Input ports. */
for ( ; ; ) {
struct port_in *port;
port = TAILQ_FIRST(&p->ports_in);
if (!port)
break;
TAILQ_REMOVE(&p->ports_in, port, node);
port->type->ops.free(port->obj);
free(port);
}
/* Input port types. */
for ( ; ; ) {
struct port_in_type *elem;
elem = TAILQ_FIRST(&p->port_in_types);
if (!elem)
break;
TAILQ_REMOVE(&p->port_in_types, elem, node);
free(elem);
}
}
/*
* Output port.
*/
static struct port_out_type *
port_out_type_find(struct rte_swx_pipeline *p, const char *name)
{
struct port_out_type *elem;
if (!name)
return NULL;
TAILQ_FOREACH(elem, &p->port_out_types, node)
if (!strcmp(elem->name, name))
return elem;
return NULL;
}
int
rte_swx_pipeline_port_out_type_register(struct rte_swx_pipeline *p,
const char *name,
struct rte_swx_port_out_ops *ops)
{
struct port_out_type *elem;
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK(ops, EINVAL);
CHECK(ops->create, EINVAL);
CHECK(ops->free, EINVAL);
CHECK(ops->pkt_tx, EINVAL);
CHECK(ops->stats_read, EINVAL);
CHECK(!port_out_type_find(p, name), EEXIST);
/* Node allocation. */
elem = calloc(1, sizeof(struct port_out_type));
CHECK(elem, ENOMEM);
/* Node initialization. */
strcpy(elem->name, name);
memcpy(&elem->ops, ops, sizeof(*ops));
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->port_out_types, elem, node);
return 0;
}
static struct port_out *
port_out_find(struct rte_swx_pipeline *p, uint32_t port_id)
{
struct port_out *port;
TAILQ_FOREACH(port, &p->ports_out, node)
if (port->id == port_id)
return port;
return NULL;
}
int
rte_swx_pipeline_port_out_config(struct rte_swx_pipeline *p,
uint32_t port_id,
const char *port_type_name,
void *args)
{
struct port_out_type *type = NULL;
struct port_out *port = NULL;
void *obj = NULL;
CHECK(p, EINVAL);
CHECK(!port_out_find(p, port_id), EINVAL);
CHECK_NAME(port_type_name, EINVAL);
type = port_out_type_find(p, port_type_name);
CHECK(type, EINVAL);
obj = type->ops.create(args);
CHECK(obj, ENODEV);
/* Node allocation. */
port = calloc(1, sizeof(struct port_out));
CHECK(port, ENOMEM);
/* Node initialization. */
port->type = type;
port->obj = obj;
port->id = port_id;
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->ports_out, port, node);
if (p->n_ports_out < port_id + 1)
p->n_ports_out = port_id + 1;
return 0;
}
static int
port_out_build(struct rte_swx_pipeline *p)
{
struct port_out *port;
uint32_t i;
CHECK(p->n_ports_out, EINVAL);
for (i = 0; i < p->n_ports_out; i++)
CHECK(port_out_find(p, i), EINVAL);
p->out = calloc(p->n_ports_out, sizeof(struct port_out_runtime));
CHECK(p->out, ENOMEM);
TAILQ_FOREACH(port, &p->ports_out, node) {
struct port_out_runtime *out = &p->out[port->id];
out->pkt_tx = port->type->ops.pkt_tx;
out->flush = port->type->ops.flush;
out->obj = port->obj;
}
return 0;
}
static void
port_out_build_free(struct rte_swx_pipeline *p)
{
free(p->out);
p->out = NULL;
}
static void
port_out_free(struct rte_swx_pipeline *p)
{
port_out_build_free(p);
/* Output ports. */
for ( ; ; ) {
struct port_out *port;
port = TAILQ_FIRST(&p->ports_out);
if (!port)
break;
TAILQ_REMOVE(&p->ports_out, port, node);
port->type->ops.free(port->obj);
free(port);
}
/* Output port types. */
for ( ; ; ) {
struct port_out_type *elem;
elem = TAILQ_FIRST(&p->port_out_types);
if (!elem)
break;
TAILQ_REMOVE(&p->port_out_types, elem, node);
free(elem);
}
}
/*
* Extern object.
*/
static struct extern_type *
extern_type_find(struct rte_swx_pipeline *p, const char *name)
{
struct extern_type *elem;
TAILQ_FOREACH(elem, &p->extern_types, node)
if (strcmp(elem->name, name) == 0)
return elem;
return NULL;
}
static struct extern_type_member_func *
extern_type_member_func_find(struct extern_type *type, const char *name)
{
struct extern_type_member_func *elem;
TAILQ_FOREACH(elem, &type->funcs, node)
if (strcmp(elem->name, name) == 0)
return elem;
return NULL;
}
static struct extern_obj *
extern_obj_find(struct rte_swx_pipeline *p, const char *name)
{
struct extern_obj *elem;
TAILQ_FOREACH(elem, &p->extern_objs, node)
if (strcmp(elem->name, name) == 0)
return elem;
return NULL;
}
static struct extern_type_member_func *
extern_obj_member_func_parse(struct rte_swx_pipeline *p,
const char *name,
struct extern_obj **obj)
{
struct extern_obj *object;
struct extern_type_member_func *func;
char *object_name, *func_name;
if (name[0] != 'e' || name[1] != '.')
return NULL;
object_name = strdup(&name[2]);
if (!object_name)
return NULL;
func_name = strchr(object_name, '.');
if (!func_name) {
free(object_name);
return NULL;
}
*func_name = 0;
func_name++;
object = extern_obj_find(p, object_name);
if (!object) {
free(object_name);
return NULL;
}
func = extern_type_member_func_find(object->type, func_name);
if (!func) {
free(object_name);
return NULL;
}
if (obj)
*obj = object;
free(object_name);
return func;
}
static struct field *
extern_obj_mailbox_field_parse(struct rte_swx_pipeline *p,
const char *name,
struct extern_obj **object)
{
struct extern_obj *obj;
struct field *f;
char *obj_name, *field_name;
if ((name[0] != 'e') || (name[1] != '.'))
return NULL;
obj_name = strdup(&name[2]);
if (!obj_name)
return NULL;
field_name = strchr(obj_name, '.');
if (!field_name) {
free(obj_name);
return NULL;
}
*field_name = 0;
field_name++;
obj = extern_obj_find(p, obj_name);
if (!obj) {
free(obj_name);
return NULL;
}
f = struct_type_field_find(obj->type->mailbox_struct_type, field_name);
if (!f) {
free(obj_name);
return NULL;
}
if (object)
*object = obj;
free(obj_name);
return f;
}
int
rte_swx_pipeline_extern_type_register(struct rte_swx_pipeline *p,
const char *name,
const char *mailbox_struct_type_name,
rte_swx_extern_type_constructor_t constructor,
rte_swx_extern_type_destructor_t destructor)
{
struct extern_type *elem;
struct struct_type *mailbox_struct_type;
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK(!extern_type_find(p, name), EEXIST);
CHECK_NAME(mailbox_struct_type_name, EINVAL);
mailbox_struct_type = struct_type_find(p, mailbox_struct_type_name);
CHECK(mailbox_struct_type, EINVAL);
CHECK(!mailbox_struct_type->var_size, EINVAL);
CHECK(constructor, EINVAL);
CHECK(destructor, EINVAL);
/* Node allocation. */
elem = calloc(1, sizeof(struct extern_type));
CHECK(elem, ENOMEM);
/* Node initialization. */
strcpy(elem->name, name);
elem->mailbox_struct_type = mailbox_struct_type;
elem->constructor = constructor;
elem->destructor = destructor;
TAILQ_INIT(&elem->funcs);
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->extern_types, elem, node);
return 0;
}
int
rte_swx_pipeline_extern_type_member_func_register(struct rte_swx_pipeline *p,
const char *extern_type_name,
const char *name,
rte_swx_extern_type_member_func_t member_func)
{
struct extern_type *type;
struct extern_type_member_func *type_member;
CHECK(p, EINVAL);
CHECK_NAME(extern_type_name, EINVAL);
type = extern_type_find(p, extern_type_name);
CHECK(type, EINVAL);
CHECK(type->n_funcs < RTE_SWX_EXTERN_TYPE_MEMBER_FUNCS_MAX, ENOSPC);
CHECK_NAME(name, EINVAL);
CHECK(!extern_type_member_func_find(type, name), EEXIST);
CHECK(member_func, EINVAL);
/* Node allocation. */
type_member = calloc(1, sizeof(struct extern_type_member_func));
CHECK(type_member, ENOMEM);
/* Node initialization. */
strcpy(type_member->name, name);
type_member->func = member_func;
type_member->id = type->n_funcs;
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&type->funcs, type_member, node);
type->n_funcs++;
return 0;
}
int
rte_swx_pipeline_extern_object_config(struct rte_swx_pipeline *p,
const char *extern_type_name,
const char *name,
const char *args)
{
struct extern_type *type;
struct extern_obj *obj;
void *obj_handle;
CHECK(p, EINVAL);
CHECK_NAME(extern_type_name, EINVAL);
type = extern_type_find(p, extern_type_name);
CHECK(type, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK(!extern_obj_find(p, name), EEXIST);
/* Node allocation. */
obj = calloc(1, sizeof(struct extern_obj));
CHECK(obj, ENOMEM);
/* Object construction. */
obj_handle = type->constructor(args);
if (!obj_handle) {
free(obj);
CHECK(0, ENODEV);
}
/* Node initialization. */
strcpy(obj->name, name);
obj->type = type;
obj->obj = obj_handle;
obj->struct_id = p->n_structs;
obj->id = p->n_extern_objs;
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->extern_objs, obj, node);
p->n_extern_objs++;
p->n_structs++;
return 0;
}
static int
extern_obj_build(struct rte_swx_pipeline *p)
{
uint32_t i;
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
struct extern_obj *obj;
t->extern_objs = calloc(p->n_extern_objs,
sizeof(struct extern_obj_runtime));
CHECK(t->extern_objs, ENOMEM);
TAILQ_FOREACH(obj, &p->extern_objs, node) {
struct extern_obj_runtime *r =
&t->extern_objs[obj->id];
struct extern_type_member_func *func;
uint32_t mailbox_size =
obj->type->mailbox_struct_type->n_bits / 8;
r->obj = obj->obj;
r->mailbox = calloc(1, mailbox_size);
CHECK(r->mailbox, ENOMEM);
TAILQ_FOREACH(func, &obj->type->funcs, node)
r->funcs[func->id] = func->func;
t->structs[obj->struct_id] = r->mailbox;
}
}
return 0;
}
static void
extern_obj_build_free(struct rte_swx_pipeline *p)
{
uint32_t i;
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
uint32_t j;
if (!t->extern_objs)
continue;
for (j = 0; j < p->n_extern_objs; j++) {
struct extern_obj_runtime *r = &t->extern_objs[j];
free(r->mailbox);
}
free(t->extern_objs);
t->extern_objs = NULL;
}
}
static void
extern_obj_free(struct rte_swx_pipeline *p)
{
extern_obj_build_free(p);
/* Extern objects. */
for ( ; ; ) {
struct extern_obj *elem;
elem = TAILQ_FIRST(&p->extern_objs);
if (!elem)
break;
TAILQ_REMOVE(&p->extern_objs, elem, node);
if (elem->obj)
elem->type->destructor(elem->obj);
free(elem);
}
/* Extern types. */
for ( ; ; ) {
struct extern_type *elem;
elem = TAILQ_FIRST(&p->extern_types);
if (!elem)
break;
TAILQ_REMOVE(&p->extern_types, elem, node);
for ( ; ; ) {
struct extern_type_member_func *func;
func = TAILQ_FIRST(&elem->funcs);
if (!func)
break;
TAILQ_REMOVE(&elem->funcs, func, node);
free(func);
}
free(elem);
}
}
/*
* Extern function.
*/
static struct extern_func *
extern_func_find(struct rte_swx_pipeline *p, const char *name)
{
struct extern_func *elem;
TAILQ_FOREACH(elem, &p->extern_funcs, node)
if (strcmp(elem->name, name) == 0)
return elem;
return NULL;
}
static struct extern_func *
extern_func_parse(struct rte_swx_pipeline *p,
const char *name)
{
if (name[0] != 'f' || name[1] != '.')
return NULL;
return extern_func_find(p, &name[2]);
}
static struct field *
extern_func_mailbox_field_parse(struct rte_swx_pipeline *p,
const char *name,
struct extern_func **function)
{
struct extern_func *func;
struct field *f;
char *func_name, *field_name;
if ((name[0] != 'f') || (name[1] != '.'))
return NULL;
func_name = strdup(&name[2]);
if (!func_name)
return NULL;
field_name = strchr(func_name, '.');
if (!field_name) {
free(func_name);
return NULL;
}
*field_name = 0;
field_name++;
func = extern_func_find(p, func_name);
if (!func) {
free(func_name);
return NULL;
}
f = struct_type_field_find(func->mailbox_struct_type, field_name);
if (!f) {
free(func_name);
return NULL;
}
if (function)
*function = func;
free(func_name);
return f;
}
int
rte_swx_pipeline_extern_func_register(struct rte_swx_pipeline *p,
const char *name,
const char *mailbox_struct_type_name,
rte_swx_extern_func_t func)
{
struct extern_func *f;
struct struct_type *mailbox_struct_type;
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK(!extern_func_find(p, name), EEXIST);
CHECK_NAME(mailbox_struct_type_name, EINVAL);
mailbox_struct_type = struct_type_find(p, mailbox_struct_type_name);
CHECK(mailbox_struct_type, EINVAL);
CHECK(!mailbox_struct_type->var_size, EINVAL);
CHECK(func, EINVAL);
/* Node allocation. */
f = calloc(1, sizeof(struct extern_func));
CHECK(func, ENOMEM);
/* Node initialization. */
strcpy(f->name, name);
f->mailbox_struct_type = mailbox_struct_type;
f->func = func;
f->struct_id = p->n_structs;
f->id = p->n_extern_funcs;
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->extern_funcs, f, node);
p->n_extern_funcs++;
p->n_structs++;
return 0;
}
static int
extern_func_build(struct rte_swx_pipeline *p)
{
uint32_t i;
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
struct extern_func *func;
/* Memory allocation. */
t->extern_funcs = calloc(p->n_extern_funcs,
sizeof(struct extern_func_runtime));
CHECK(t->extern_funcs, ENOMEM);
/* Extern function. */
TAILQ_FOREACH(func, &p->extern_funcs, node) {
struct extern_func_runtime *r =
&t->extern_funcs[func->id];
uint32_t mailbox_size =
func->mailbox_struct_type->n_bits / 8;
r->func = func->func;
r->mailbox = calloc(1, mailbox_size);
CHECK(r->mailbox, ENOMEM);
t->structs[func->struct_id] = r->mailbox;
}
}
return 0;
}
static void
extern_func_build_free(struct rte_swx_pipeline *p)
{
uint32_t i;
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
uint32_t j;
if (!t->extern_funcs)
continue;
for (j = 0; j < p->n_extern_funcs; j++) {
struct extern_func_runtime *r = &t->extern_funcs[j];
free(r->mailbox);
}
free(t->extern_funcs);
t->extern_funcs = NULL;
}
}
static void
extern_func_free(struct rte_swx_pipeline *p)
{
extern_func_build_free(p);
for ( ; ; ) {
struct extern_func *elem;
elem = TAILQ_FIRST(&p->extern_funcs);
if (!elem)
break;
TAILQ_REMOVE(&p->extern_funcs, elem, node);
free(elem);
}
}
/*
* Header.
*/
static struct header *
header_find(struct rte_swx_pipeline *p, const char *name)
{
struct header *elem;
TAILQ_FOREACH(elem, &p->headers, node)
if (strcmp(elem->name, name) == 0)
return elem;
return NULL;
}
static struct header *
header_find_by_struct_id(struct rte_swx_pipeline *p, uint32_t struct_id)
{
struct header *elem;
TAILQ_FOREACH(elem, &p->headers, node)
if (elem->struct_id == struct_id)
return elem;
return NULL;
}
static struct header *
header_parse(struct rte_swx_pipeline *p,
const char *name)
{
if (name[0] != 'h' || name[1] != '.')
return NULL;
return header_find(p, &name[2]);
}
static struct field *
header_field_parse(struct rte_swx_pipeline *p,
const char *name,
struct header **header)
{
struct header *h;
struct field *f;
char *header_name, *field_name;
if ((name[0] != 'h') || (name[1] != '.'))
return NULL;
header_name = strdup(&name[2]);
if (!header_name)
return NULL;
field_name = strchr(header_name, '.');
if (!field_name) {
free(header_name);
return NULL;
}
*field_name = 0;
field_name++;
h = header_find(p, header_name);
if (!h) {
free(header_name);
return NULL;
}
f = struct_type_field_find(h->st, field_name);
if (!f) {
free(header_name);
return NULL;
}
if (header)
*header = h;
free(header_name);
return f;
}
int
rte_swx_pipeline_packet_header_register(struct rte_swx_pipeline *p,
const char *name,
const char *struct_type_name)
{
struct struct_type *st;
struct header *h;
size_t n_headers_max;
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK_NAME(struct_type_name, EINVAL);
CHECK(!header_find(p, name), EEXIST);
st = struct_type_find(p, struct_type_name);
CHECK(st, EINVAL);
n_headers_max = RTE_SIZEOF_FIELD(struct thread, valid_headers) * 8;
CHECK(p->n_headers < n_headers_max, ENOSPC);
/* Node allocation. */
h = calloc(1, sizeof(struct header));
CHECK(h, ENOMEM);
/* Node initialization. */
strcpy(h->name, name);
h->st = st;
h->struct_id = p->n_structs;
h->id = p->n_headers;
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->headers, h, node);
p->n_headers++;
p->n_structs++;
return 0;
}
static int
header_build(struct rte_swx_pipeline *p)
{
struct header *h;
uint32_t n_bytes = 0, i;
TAILQ_FOREACH(h, &p->headers, node) {
n_bytes += h->st->n_bits / 8;
}
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
uint32_t offset = 0;
t->headers = calloc(p->n_headers,
sizeof(struct header_runtime));
CHECK(t->headers, ENOMEM);
t->headers_out = calloc(p->n_headers,
sizeof(struct header_out_runtime));
CHECK(t->headers_out, ENOMEM);
t->header_storage = calloc(1, n_bytes);
CHECK(t->header_storage, ENOMEM);
t->header_out_storage = calloc(1, n_bytes);
CHECK(t->header_out_storage, ENOMEM);
TAILQ_FOREACH(h, &p->headers, node) {
uint8_t *header_storage;
uint32_t n_bytes = h->st->n_bits / 8;
header_storage = &t->header_storage[offset];
offset += n_bytes;
t->headers[h->id].ptr0 = header_storage;
t->headers[h->id].n_bytes = n_bytes;
t->structs[h->struct_id] = header_storage;
}
}
return 0;
}
static void
header_build_free(struct rte_swx_pipeline *p)
{
uint32_t i;
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
free(t->headers_out);
t->headers_out = NULL;
free(t->headers);
t->headers = NULL;
free(t->header_out_storage);
t->header_out_storage = NULL;
free(t->header_storage);
t->header_storage = NULL;
}
}
static void
header_free(struct rte_swx_pipeline *p)
{
header_build_free(p);
for ( ; ; ) {
struct header *elem;
elem = TAILQ_FIRST(&p->headers);
if (!elem)
break;
TAILQ_REMOVE(&p->headers, elem, node);
free(elem);
}
}
/*
* Meta-data.
*/
static struct field *
metadata_field_parse(struct rte_swx_pipeline *p, const char *name)
{
if (!p->metadata_st)
return NULL;
if (name[0] != 'm' || name[1] != '.')
return NULL;
return struct_type_field_find(p->metadata_st, &name[2]);
}
int
rte_swx_pipeline_packet_metadata_register(struct rte_swx_pipeline *p,
const char *struct_type_name)
{
struct struct_type *st = NULL;
CHECK(p, EINVAL);
CHECK_NAME(struct_type_name, EINVAL);
st = struct_type_find(p, struct_type_name);
CHECK(st, EINVAL);
CHECK(!st->var_size, EINVAL);
CHECK(!p->metadata_st, EINVAL);
p->metadata_st = st;
p->metadata_struct_id = p->n_structs;
p->n_structs++;
return 0;
}
static int
metadata_build(struct rte_swx_pipeline *p)
{
uint32_t n_bytes = p->metadata_st->n_bits / 8;
uint32_t i;
/* Thread-level initialization. */
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
uint8_t *metadata;
metadata = calloc(1, n_bytes);
CHECK(metadata, ENOMEM);
t->metadata = metadata;
t->structs[p->metadata_struct_id] = metadata;
}
return 0;
}
static void
metadata_build_free(struct rte_swx_pipeline *p)
{
uint32_t i;
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
free(t->metadata);
t->metadata = NULL;
}
}
static void
metadata_free(struct rte_swx_pipeline *p)
{
metadata_build_free(p);
}
/*
* Instruction.
*/
static int
instruction_is_tx(enum instruction_type type)
{
switch (type) {
case INSTR_TX:
case INSTR_TX_I:
return 1;
default:
return 0;
}
}
static int
instruction_does_tx(struct instruction *instr)
{
switch (instr->type) {
case INSTR_TX:
case INSTR_TX_I:
case INSTR_HDR_EMIT_TX:
case INSTR_HDR_EMIT2_TX:
case INSTR_HDR_EMIT3_TX:
case INSTR_HDR_EMIT4_TX:
case INSTR_HDR_EMIT5_TX:
case INSTR_HDR_EMIT6_TX:
case INSTR_HDR_EMIT7_TX:
case INSTR_HDR_EMIT8_TX:
return 1;
default:
return 0;
}
}
static int
instruction_is_jmp(struct instruction *instr)
{
switch (instr->type) {
case INSTR_JMP:
case INSTR_JMP_VALID:
case INSTR_JMP_INVALID:
case INSTR_JMP_HIT:
case INSTR_JMP_MISS:
case INSTR_JMP_ACTION_HIT:
case INSTR_JMP_ACTION_MISS:
case INSTR_JMP_EQ:
case INSTR_JMP_EQ_MH:
case INSTR_JMP_EQ_HM:
case INSTR_JMP_EQ_HH:
case INSTR_JMP_EQ_I:
case INSTR_JMP_NEQ:
case INSTR_JMP_NEQ_MH:
case INSTR_JMP_NEQ_HM:
case INSTR_JMP_NEQ_HH:
case INSTR_JMP_NEQ_I:
case INSTR_JMP_LT:
case INSTR_JMP_LT_MH:
case INSTR_JMP_LT_HM:
case INSTR_JMP_LT_HH:
case INSTR_JMP_LT_MI:
case INSTR_JMP_LT_HI:
case INSTR_JMP_GT:
case INSTR_JMP_GT_MH:
case INSTR_JMP_GT_HM:
case INSTR_JMP_GT_HH:
case INSTR_JMP_GT_MI:
case INSTR_JMP_GT_HI:
return 1;
default:
return 0;
}
}
static int
instruction_does_thread_yield(struct instruction *instr)
{
switch (instr->type) {
case INSTR_RX:
case INSTR_TABLE:
case INSTR_TABLE_AF:
case INSTR_SELECTOR:
case INSTR_LEARNER:
case INSTR_LEARNER_AF:
case INSTR_EXTERN_OBJ:
case INSTR_EXTERN_FUNC:
return 1;
default:
return 0;
}
}
static struct field *
action_field_parse(struct action *action, const char *name);
static struct field *
struct_field_parse(struct rte_swx_pipeline *p,
struct action *action,
const char *name,
uint32_t *struct_id)
{
struct field *f;
switch (name[0]) {
case 'h':
{
struct header *header;
f = header_field_parse(p, name, &header);
if (!f)
return NULL;
*struct_id = header->struct_id;
return f;
}
case 'm':
{
f = metadata_field_parse(p, name);
if (!f)
return NULL;
*struct_id = p->metadata_struct_id;
return f;
}
case 't':
{
if (!action)
return NULL;
f = action_field_parse(action, name);
if (!f)
return NULL;
*struct_id = 0;
return f;
}
case 'e':
{
struct extern_obj *obj;
f = extern_obj_mailbox_field_parse(p, name, &obj);
if (!f)
return NULL;
*struct_id = obj->struct_id;
return f;
}
case 'f':
{
struct extern_func *func;
f = extern_func_mailbox_field_parse(p, name, &func);
if (!f)
return NULL;
*struct_id = func->struct_id;
return f;
}
default:
return NULL;
}
}
/*
* rx.
*/
static int
instr_rx_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
struct field *f;
CHECK(!action, EINVAL);
CHECK(n_tokens == 2, EINVAL);
f = metadata_field_parse(p, tokens[1]);
CHECK(f, EINVAL);
instr->type = INSTR_RX;
instr->io.io.offset = f->offset / 8;
instr->io.io.n_bits = f->n_bits;
return 0;
}
/*
* tx.
*/
static int
instr_tx_translate(struct rte_swx_pipeline *p,
struct action *action __rte_unused,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
char *port = tokens[1];
struct field *f;
uint32_t port_val;
CHECK(n_tokens == 2, EINVAL);
f = metadata_field_parse(p, port);
if (f) {
instr->type = INSTR_TX;
instr->io.io.offset = f->offset / 8;
instr->io.io.n_bits = f->n_bits;
return 0;
}
/* TX_I. */
port_val = strtoul(port, &port, 0);
CHECK(!port[0], EINVAL);
instr->type = INSTR_TX_I;
instr->io.io.val = port_val;
return 0;
}
static int
instr_drop_translate(struct rte_swx_pipeline *p,
struct action *action __rte_unused,
char **tokens __rte_unused,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
CHECK(n_tokens == 1, EINVAL);
/* TX_I. */
instr->type = INSTR_TX_I;
instr->io.io.val = p->n_ports_out - 1;
return 0;
}
static inline void
instr_tx_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_tx_exec(p, t, ip);
/* Thread. */
thread_ip_reset(p, t);
instr_rx_exec(p);
}
static inline void
instr_tx_i_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_tx_i_exec(p, t, ip);
/* Thread. */
thread_ip_reset(p, t);
instr_rx_exec(p);
}
/*
* extract.
*/
static int
instr_hdr_extract_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
struct header *h;
CHECK(!action, EINVAL);
CHECK((n_tokens == 2) || (n_tokens == 3), EINVAL);
h = header_parse(p, tokens[1]);
CHECK(h, EINVAL);
if (n_tokens == 2) {
CHECK(!h->st->var_size, EINVAL);
instr->type = INSTR_HDR_EXTRACT;
instr->io.hdr.header_id[0] = h->id;
instr->io.hdr.struct_id[0] = h->struct_id;
instr->io.hdr.n_bytes[0] = h->st->n_bits / 8;
} else {
struct field *mf;
CHECK(h->st->var_size, EINVAL);
mf = metadata_field_parse(p, tokens[2]);
CHECK(mf, EINVAL);
CHECK(!mf->var_size, EINVAL);
instr->type = INSTR_HDR_EXTRACT_M;
instr->io.io.offset = mf->offset / 8;
instr->io.io.n_bits = mf->n_bits;
instr->io.hdr.header_id[0] = h->id;
instr->io.hdr.struct_id[0] = h->struct_id;
instr->io.hdr.n_bytes[0] = h->st->n_bits_min / 8;
}
return 0;
}
static int
instr_hdr_lookahead_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
struct header *h;
CHECK(!action, EINVAL);
CHECK(n_tokens == 2, EINVAL);
h = header_parse(p, tokens[1]);
CHECK(h, EINVAL);
CHECK(!h->st->var_size, EINVAL);
instr->type = INSTR_HDR_LOOKAHEAD;
instr->io.hdr.header_id[0] = h->id;
instr->io.hdr.struct_id[0] = h->struct_id;
instr->io.hdr.n_bytes[0] = 0; /* Unused. */
return 0;
}
static inline void
instr_hdr_extract_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_hdr_extract_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_hdr_extract2_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_hdr_extract2_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_hdr_extract3_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_hdr_extract3_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_hdr_extract4_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_hdr_extract4_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_hdr_extract5_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_hdr_extract5_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_hdr_extract6_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_hdr_extract6_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_hdr_extract7_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_hdr_extract7_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_hdr_extract8_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_hdr_extract8_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_hdr_extract_m_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_hdr_extract_m_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_hdr_lookahead_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_hdr_lookahead_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
/*
* emit.
*/
static int
instr_hdr_emit_translate(struct rte_swx_pipeline *p,
struct action *action __rte_unused,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
struct header *h;
CHECK(n_tokens == 2, EINVAL);
h = header_parse(p, tokens[1]);
CHECK(h, EINVAL);
instr->type = INSTR_HDR_EMIT;
instr->io.hdr.header_id[0] = h->id;
instr->io.hdr.struct_id[0] = h->struct_id;
instr->io.hdr.n_bytes[0] = h->st->n_bits / 8;
return 0;
}
static inline void
instr_hdr_emit_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_hdr_emit_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_hdr_emit_tx_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_hdr_emit_tx_exec(p, t, ip);
/* Thread. */
thread_ip_reset(p, t);
instr_rx_exec(p);
}
static inline void
instr_hdr_emit2_tx_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_hdr_emit2_tx_exec(p, t, ip);
/* Thread. */
thread_ip_reset(p, t);
instr_rx_exec(p);
}
static inline void
instr_hdr_emit3_tx_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_hdr_emit3_tx_exec(p, t, ip);
/* Thread. */
thread_ip_reset(p, t);
instr_rx_exec(p);
}
static inline void
instr_hdr_emit4_tx_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_hdr_emit4_tx_exec(p, t, ip);
/* Thread. */
thread_ip_reset(p, t);
instr_rx_exec(p);
}
static inline void
instr_hdr_emit5_tx_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_hdr_emit5_tx_exec(p, t, ip);
/* Thread. */
thread_ip_reset(p, t);
instr_rx_exec(p);
}
static inline void
instr_hdr_emit6_tx_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_hdr_emit6_tx_exec(p, t, ip);
/* Thread. */
thread_ip_reset(p, t);
instr_rx_exec(p);
}
static inline void
instr_hdr_emit7_tx_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_hdr_emit7_tx_exec(p, t, ip);
/* Thread. */
thread_ip_reset(p, t);
instr_rx_exec(p);
}
static inline void
instr_hdr_emit8_tx_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_hdr_emit8_tx_exec(p, t, ip);
/* Thread. */
thread_ip_reset(p, t);
instr_rx_exec(p);
}
/*
* validate.
*/
static int
instr_hdr_validate_translate(struct rte_swx_pipeline *p,
struct action *action __rte_unused,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
struct header *h;
CHECK(n_tokens == 2, EINVAL);
h = header_parse(p, tokens[1]);
CHECK(h, EINVAL);
instr->type = INSTR_HDR_VALIDATE;
instr->valid.header_id = h->id;
return 0;
}
static inline void
instr_hdr_validate_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_hdr_validate_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
/*
* invalidate.
*/
static int
instr_hdr_invalidate_translate(struct rte_swx_pipeline *p,
struct action *action __rte_unused,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
struct header *h;
CHECK(n_tokens == 2, EINVAL);
h = header_parse(p, tokens[1]);
CHECK(h, EINVAL);
instr->type = INSTR_HDR_INVALIDATE;
instr->valid.header_id = h->id;
return 0;
}
static inline void
instr_hdr_invalidate_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_hdr_invalidate_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
/*
* table.
*/
static struct table *
table_find(struct rte_swx_pipeline *p, const char *name);
static struct selector *
selector_find(struct rte_swx_pipeline *p, const char *name);
static struct learner *
learner_find(struct rte_swx_pipeline *p, const char *name);
static int
instr_table_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
struct table *t;
struct selector *s;
struct learner *l;
CHECK(!action, EINVAL);
CHECK(n_tokens == 2, EINVAL);
t = table_find(p, tokens[1]);
if (t) {
instr->type = INSTR_TABLE;
instr->table.table_id = t->id;
return 0;
}
s = selector_find(p, tokens[1]);
if (s) {
instr->type = INSTR_SELECTOR;
instr->table.table_id = s->id;
return 0;
}
l = learner_find(p, tokens[1]);
if (l) {
instr->type = INSTR_LEARNER;
instr->table.table_id = l->id;
return 0;
}
CHECK(0, EINVAL);
}
static inline void
instr_table_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
uint32_t table_id = ip->table.table_id;
struct rte_swx_table_state *ts = &t->table_state[table_id];
struct table_runtime *table = &t->tables[table_id];
struct table_statistics *stats = &p->table_stats[table_id];
uint64_t action_id, n_pkts_hit, n_pkts_action;
uint8_t *action_data;
int done, hit;
/* Table. */
done = table->func(ts->obj,
table->mailbox,
table->key,
&action_id,
&action_data,
&hit);
if (!done) {
/* Thread. */
TRACE("[Thread %2u] table %u (not finalized)\n",
p->thread_id,
table_id);
thread_yield(p);
return;
}
action_id = hit ? action_id : ts->default_action_id;
action_data = hit ? action_data : ts->default_action_data;
n_pkts_hit = stats->n_pkts_hit[hit];
n_pkts_action = stats->n_pkts_action[action_id];
TRACE("[Thread %2u] table %u (%s, action %u)\n",
p->thread_id,
table_id,
hit ? "hit" : "miss",
(uint32_t)action_id);
t->action_id = action_id;
t->structs[0] = action_data;
t->hit = hit;
stats->n_pkts_hit[hit] = n_pkts_hit + 1;
stats->n_pkts_action[action_id] = n_pkts_action + 1;
/* Thread. */
thread_ip_action_call(p, t, action_id);
}
static inline void
instr_table_af_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
uint32_t table_id = ip->table.table_id;
struct rte_swx_table_state *ts = &t->table_state[table_id];
struct table_runtime *table = &t->tables[table_id];
struct table_statistics *stats = &p->table_stats[table_id];
uint64_t action_id, n_pkts_hit, n_pkts_action;
uint8_t *action_data;
action_func_t action_func;
int done, hit;
/* Table. */
done = table->func(ts->obj,
table->mailbox,
table->key,
&action_id,
&action_data,
&hit);
if (!done) {
/* Thread. */
TRACE("[Thread %2u] table %u (not finalized)\n",
p->thread_id,
table_id);
thread_yield(p);
return;
}
action_id = hit ? action_id : ts->default_action_id;
action_data = hit ? action_data : ts->default_action_data;
action_func = p->action_funcs[action_id];
n_pkts_hit = stats->n_pkts_hit[hit];
n_pkts_action = stats->n_pkts_action[action_id];
TRACE("[Thread %2u] table %u (%s, action %u)\n",
p->thread_id,
table_id,
hit ? "hit" : "miss",
(uint32_t)action_id);
t->action_id = action_id;
t->structs[0] = action_data;
t->hit = hit;
stats->n_pkts_hit[hit] = n_pkts_hit + 1;
stats->n_pkts_action[action_id] = n_pkts_action + 1;
/* Thread. */
thread_ip_inc(p);
/* Action. */
action_func(p);
}
static inline void
instr_selector_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
uint32_t selector_id = ip->table.table_id;
struct rte_swx_table_state *ts = &t->table_state[p->n_tables + selector_id];
struct selector_runtime *selector = &t->selectors[selector_id];
struct selector_statistics *stats = &p->selector_stats[selector_id];
uint64_t n_pkts = stats->n_pkts;
int done;
/* Table. */
done = rte_swx_table_selector_select(ts->obj,
selector->mailbox,
selector->group_id_buffer,
selector->selector_buffer,
selector->member_id_buffer);
if (!done) {
/* Thread. */
TRACE("[Thread %2u] selector %u (not finalized)\n",
p->thread_id,
selector_id);
thread_yield(p);
return;
}
TRACE("[Thread %2u] selector %u\n",
p->thread_id,
selector_id);
stats->n_pkts = n_pkts + 1;
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_learner_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
uint32_t learner_id = ip->table.table_id;
struct rte_swx_table_state *ts = &t->table_state[p->n_tables +
p->n_selectors + learner_id];
struct learner_runtime *l = &t->learners[learner_id];
struct learner_statistics *stats = &p->learner_stats[learner_id];
uint64_t action_id, n_pkts_hit, n_pkts_action, time;
uint8_t *action_data;
int done, hit;
/* Table. */
time = rte_get_tsc_cycles();
done = rte_swx_table_learner_lookup(ts->obj,
l->mailbox,
time,
l->key,
&action_id,
&action_data,
&hit);
if (!done) {
/* Thread. */
TRACE("[Thread %2u] learner %u (not finalized)\n",
p->thread_id,
learner_id);
thread_yield(p);
return;
}
action_id = hit ? action_id : ts->default_action_id;
action_data = hit ? action_data : ts->default_action_data;
n_pkts_hit = stats->n_pkts_hit[hit];
n_pkts_action = stats->n_pkts_action[action_id];
TRACE("[Thread %2u] learner %u (%s, action %u)\n",
p->thread_id,
learner_id,
hit ? "hit" : "miss",
(uint32_t)action_id);
t->action_id = action_id;
t->structs[0] = action_data;
t->hit = hit;
t->learner_id = learner_id;
t->time = time;
stats->n_pkts_hit[hit] = n_pkts_hit + 1;
stats->n_pkts_action[action_id] = n_pkts_action + 1;
/* Thread. */
thread_ip_action_call(p, t, action_id);
}
static inline void
instr_learner_af_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
uint32_t learner_id = ip->table.table_id;
struct rte_swx_table_state *ts = &t->table_state[p->n_tables +
p->n_selectors + learner_id];
struct learner_runtime *l = &t->learners[learner_id];
struct learner_statistics *stats = &p->learner_stats[learner_id];
uint64_t action_id, n_pkts_hit, n_pkts_action, time;
uint8_t *action_data;
action_func_t action_func;
int done, hit;
/* Table. */
time = rte_get_tsc_cycles();
done = rte_swx_table_learner_lookup(ts->obj,
l->mailbox,
time,
l->key,
&action_id,
&action_data,
&hit);
if (!done) {
/* Thread. */
TRACE("[Thread %2u] learner %u (not finalized)\n",
p->thread_id,
learner_id);
thread_yield(p);
return;
}
action_id = hit ? action_id : ts->default_action_id;
action_data = hit ? action_data : ts->default_action_data;
action_func = p->action_funcs[action_id];
n_pkts_hit = stats->n_pkts_hit[hit];
n_pkts_action = stats->n_pkts_action[action_id];
TRACE("[Thread %2u] learner %u (%s, action %u)\n",
p->thread_id,
learner_id,
hit ? "hit" : "miss",
(uint32_t)action_id);
t->action_id = action_id;
t->structs[0] = action_data;
t->hit = hit;
t->learner_id = learner_id;
t->time = time;
stats->n_pkts_hit[hit] = n_pkts_hit + 1;
stats->n_pkts_action[action_id] = n_pkts_action + 1;
/* Thread. */
thread_ip_action_call(p, t, action_id);
/* Action */
action_func(p);
}
/*
* learn.
*/
static struct action *
action_find(struct rte_swx_pipeline *p, const char *name);
static int
action_has_nbo_args(struct action *a);
static int
learner_action_args_check(struct rte_swx_pipeline *p, struct action *a, const char *mf_name);
static int
instr_learn_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
struct action *a;
const char *mf_name;
uint32_t mf_offset = 0;
CHECK(action, EINVAL);
CHECK((n_tokens == 2) || (n_tokens == 3), EINVAL);
a = action_find(p, tokens[1]);
CHECK(a, EINVAL);
CHECK(!action_has_nbo_args(a), EINVAL);
mf_name = (n_tokens > 2) ? tokens[2] : NULL;
CHECK(!learner_action_args_check(p, a, mf_name), EINVAL);
if (mf_name) {
struct field *mf;
mf = metadata_field_parse(p, mf_name);
CHECK(mf, EINVAL);
mf_offset = mf->offset / 8;
}
instr->type = INSTR_LEARNER_LEARN;
instr->learn.action_id = a->id;
instr->learn.mf_offset = mf_offset;
return 0;
}
static inline void
instr_learn_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_learn_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
/*
* forget.
*/
static int
instr_forget_translate(struct rte_swx_pipeline *p __rte_unused,
struct action *action,
char **tokens __rte_unused,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
CHECK(action, EINVAL);
CHECK(n_tokens == 1, EINVAL);
instr->type = INSTR_LEARNER_FORGET;
return 0;
}
static inline void
instr_forget_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_forget_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
/*
* extern.
*/
static int
instr_extern_translate(struct rte_swx_pipeline *p,
struct action *action __rte_unused,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
char *token = tokens[1];
CHECK(n_tokens == 2, EINVAL);
if (token[0] == 'e') {
struct extern_obj *obj;
struct extern_type_member_func *func;
func = extern_obj_member_func_parse(p, token, &obj);
CHECK(func, EINVAL);
instr->type = INSTR_EXTERN_OBJ;
instr->ext_obj.ext_obj_id = obj->id;
instr->ext_obj.func_id = func->id;
return 0;
}
if (token[0] == 'f') {
struct extern_func *func;
func = extern_func_parse(p, token);
CHECK(func, EINVAL);
instr->type = INSTR_EXTERN_FUNC;
instr->ext_func.ext_func_id = func->id;
return 0;
}
CHECK(0, EINVAL);
}
static inline void
instr_extern_obj_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
uint32_t done;
/* Extern object member function execute. */
done = __instr_extern_obj_exec(p, t, ip);
/* Thread. */
thread_ip_inc_cond(t, done);
thread_yield_cond(p, done ^ 1);
}
static inline void
instr_extern_func_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
uint32_t done;
/* Extern function execute. */
done = __instr_extern_func_exec(p, t, ip);
/* Thread. */
thread_ip_inc_cond(t, done);
thread_yield_cond(p, done ^ 1);
}
/*
* mov.
*/
static int
instr_mov_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
char *dst = tokens[1], *src = tokens[2];
struct field *fdst, *fsrc;
uint64_t src_val;
uint32_t dst_struct_id = 0, src_struct_id = 0;
CHECK(n_tokens == 3, EINVAL);
fdst = struct_field_parse(p, NULL, dst, &dst_struct_id);
CHECK(fdst, EINVAL);
CHECK(!fdst->var_size, EINVAL);
/* MOV, MOV_MH, MOV_HM or MOV_HH. */
fsrc = struct_field_parse(p, action, src, &src_struct_id);
if (fsrc) {
CHECK(!fsrc->var_size, EINVAL);
instr->type = INSTR_MOV;
if (dst[0] != 'h' && src[0] == 'h')
instr->type = INSTR_MOV_MH;
if (dst[0] == 'h' && src[0] != 'h')
instr->type = INSTR_MOV_HM;
if (dst[0] == 'h' && src[0] == 'h')
instr->type = INSTR_MOV_HH;
instr->mov.dst.struct_id = (uint8_t)dst_struct_id;
instr->mov.dst.n_bits = fdst->n_bits;
instr->mov.dst.offset = fdst->offset / 8;
instr->mov.src.struct_id = (uint8_t)src_struct_id;
instr->mov.src.n_bits = fsrc->n_bits;
instr->mov.src.offset = fsrc->offset / 8;
return 0;
}
/* MOV_I. */
src_val = strtoull(src, &src, 0);
CHECK(!src[0], EINVAL);
if (dst[0] == 'h')
src_val = hton64(src_val) >> (64 - fdst->n_bits);
instr->type = INSTR_MOV_I;
instr->mov.dst.struct_id = (uint8_t)dst_struct_id;
instr->mov.dst.n_bits = fdst->n_bits;
instr->mov.dst.offset = fdst->offset / 8;
instr->mov.src_val = src_val;
return 0;
}
static inline void
instr_mov_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_mov_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_mov_mh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_mov_mh_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_mov_hm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_mov_hm_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_mov_hh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_mov_hh_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_mov_i_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_mov_i_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
/*
* dma.
*/
static inline void
instr_dma_ht_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_dma_ht_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_dma_ht2_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_dma_ht2_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_dma_ht3_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_dma_ht3_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_dma_ht4_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_dma_ht4_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_dma_ht5_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_dma_ht5_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_dma_ht6_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_dma_ht6_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_dma_ht7_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_dma_ht7_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_dma_ht8_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_dma_ht8_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
/*
* alu.
*/
static int
instr_alu_add_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
char *dst = tokens[1], *src = tokens[2];
struct field *fdst, *fsrc;
uint64_t src_val;
uint32_t dst_struct_id = 0, src_struct_id = 0;
CHECK(n_tokens == 3, EINVAL);
fdst = struct_field_parse(p, NULL, dst, &dst_struct_id);
CHECK(fdst, EINVAL);
CHECK(!fdst->var_size, EINVAL);
/* ADD, ADD_HM, ADD_MH, ADD_HH. */
fsrc = struct_field_parse(p, action, src, &src_struct_id);
if (fsrc) {
CHECK(!fsrc->var_size, EINVAL);
instr->type = INSTR_ALU_ADD;
if (dst[0] == 'h' && src[0] != 'h')
instr->type = INSTR_ALU_ADD_HM;
if (dst[0] != 'h' && src[0] == 'h')
instr->type = INSTR_ALU_ADD_MH;
if (dst[0] == 'h' && src[0] == 'h')
instr->type = INSTR_ALU_ADD_HH;
instr->alu.dst.struct_id = (uint8_t)dst_struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
instr->alu.src.struct_id = (uint8_t)src_struct_id;
instr->alu.src.n_bits = fsrc->n_bits;
instr->alu.src.offset = fsrc->offset / 8;
return 0;
}
/* ADD_MI, ADD_HI. */
src_val = strtoull(src, &src, 0);
CHECK(!src[0], EINVAL);
instr->type = INSTR_ALU_ADD_MI;
if (dst[0] == 'h')
instr->type = INSTR_ALU_ADD_HI;
instr->alu.dst.struct_id = (uint8_t)dst_struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
instr->alu.src_val = src_val;
return 0;
}
static int
instr_alu_sub_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
char *dst = tokens[1], *src = tokens[2];
struct field *fdst, *fsrc;
uint64_t src_val;
uint32_t dst_struct_id = 0, src_struct_id = 0;
CHECK(n_tokens == 3, EINVAL);
fdst = struct_field_parse(p, NULL, dst, &dst_struct_id);
CHECK(fdst, EINVAL);
CHECK(!fdst->var_size, EINVAL);
/* SUB, SUB_HM, SUB_MH, SUB_HH. */
fsrc = struct_field_parse(p, action, src, &src_struct_id);
if (fsrc) {
CHECK(!fsrc->var_size, EINVAL);
instr->type = INSTR_ALU_SUB;
if (dst[0] == 'h' && src[0] != 'h')
instr->type = INSTR_ALU_SUB_HM;
if (dst[0] != 'h' && src[0] == 'h')
instr->type = INSTR_ALU_SUB_MH;
if (dst[0] == 'h' && src[0] == 'h')
instr->type = INSTR_ALU_SUB_HH;
instr->alu.dst.struct_id = (uint8_t)dst_struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
instr->alu.src.struct_id = (uint8_t)src_struct_id;
instr->alu.src.n_bits = fsrc->n_bits;
instr->alu.src.offset = fsrc->offset / 8;
return 0;
}
/* SUB_MI, SUB_HI. */
src_val = strtoull(src, &src, 0);
CHECK(!src[0], EINVAL);
instr->type = INSTR_ALU_SUB_MI;
if (dst[0] == 'h')
instr->type = INSTR_ALU_SUB_HI;
instr->alu.dst.struct_id = (uint8_t)dst_struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
instr->alu.src_val = src_val;
return 0;
}
static int
instr_alu_ckadd_translate(struct rte_swx_pipeline *p,
struct action *action __rte_unused,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
char *dst = tokens[1], *src = tokens[2];
struct header *hdst, *hsrc;
struct field *fdst, *fsrc;
CHECK(n_tokens == 3, EINVAL);
fdst = header_field_parse(p, dst, &hdst);
CHECK(fdst && (fdst->n_bits == 16), EINVAL);
CHECK(!fdst->var_size, EINVAL);
/* CKADD_FIELD. */
fsrc = header_field_parse(p, src, &hsrc);
if (fsrc) {
CHECK(!fsrc->var_size, EINVAL);
instr->type = INSTR_ALU_CKADD_FIELD;
instr->alu.dst.struct_id = (uint8_t)hdst->struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
instr->alu.src.struct_id = (uint8_t)hsrc->struct_id;
instr->alu.src.n_bits = fsrc->n_bits;
instr->alu.src.offset = fsrc->offset / 8;
return 0;
}
/* CKADD_STRUCT, CKADD_STRUCT20. */
hsrc = header_parse(p, src);
CHECK(hsrc, EINVAL);
CHECK(!hsrc->st->var_size, EINVAL);
instr->type = INSTR_ALU_CKADD_STRUCT;
if ((hsrc->st->n_bits / 8) == 20)
instr->type = INSTR_ALU_CKADD_STRUCT20;
instr->alu.dst.struct_id = (uint8_t)hdst->struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
instr->alu.src.struct_id = (uint8_t)hsrc->struct_id;
instr->alu.src.n_bits = hsrc->st->n_bits;
instr->alu.src.offset = 0; /* Unused. */
return 0;
}
static int
instr_alu_cksub_translate(struct rte_swx_pipeline *p,
struct action *action __rte_unused,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
char *dst = tokens[1], *src = tokens[2];
struct header *hdst, *hsrc;
struct field *fdst, *fsrc;
CHECK(n_tokens == 3, EINVAL);
fdst = header_field_parse(p, dst, &hdst);
CHECK(fdst && (fdst->n_bits == 16), EINVAL);
CHECK(!fdst->var_size, EINVAL);
fsrc = header_field_parse(p, src, &hsrc);
CHECK(fsrc, EINVAL);
CHECK(!fsrc->var_size, EINVAL);
instr->type = INSTR_ALU_CKSUB_FIELD;
instr->alu.dst.struct_id = (uint8_t)hdst->struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
instr->alu.src.struct_id = (uint8_t)hsrc->struct_id;
instr->alu.src.n_bits = fsrc->n_bits;
instr->alu.src.offset = fsrc->offset / 8;
return 0;
}
static int
instr_alu_shl_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
char *dst = tokens[1], *src = tokens[2];
struct field *fdst, *fsrc;
uint64_t src_val;
uint32_t dst_struct_id = 0, src_struct_id = 0;
CHECK(n_tokens == 3, EINVAL);
fdst = struct_field_parse(p, NULL, dst, &dst_struct_id);
CHECK(fdst, EINVAL);
CHECK(!fdst->var_size, EINVAL);
/* SHL, SHL_HM, SHL_MH, SHL_HH. */
fsrc = struct_field_parse(p, action, src, &src_struct_id);
if (fsrc) {
CHECK(!fsrc->var_size, EINVAL);
instr->type = INSTR_ALU_SHL;
if (dst[0] == 'h' && src[0] != 'h')
instr->type = INSTR_ALU_SHL_HM;
if (dst[0] != 'h' && src[0] == 'h')
instr->type = INSTR_ALU_SHL_MH;
if (dst[0] == 'h' && src[0] == 'h')
instr->type = INSTR_ALU_SHL_HH;
instr->alu.dst.struct_id = (uint8_t)dst_struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
instr->alu.src.struct_id = (uint8_t)src_struct_id;
instr->alu.src.n_bits = fsrc->n_bits;
instr->alu.src.offset = fsrc->offset / 8;
return 0;
}
/* SHL_MI, SHL_HI. */
src_val = strtoull(src, &src, 0);
CHECK(!src[0], EINVAL);
instr->type = INSTR_ALU_SHL_MI;
if (dst[0] == 'h')
instr->type = INSTR_ALU_SHL_HI;
instr->alu.dst.struct_id = (uint8_t)dst_struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
instr->alu.src_val = src_val;
return 0;
}
static int
instr_alu_shr_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
char *dst = tokens[1], *src = tokens[2];
struct field *fdst, *fsrc;
uint64_t src_val;
uint32_t dst_struct_id = 0, src_struct_id = 0;
CHECK(n_tokens == 3, EINVAL);
fdst = struct_field_parse(p, NULL, dst, &dst_struct_id);
CHECK(fdst, EINVAL);
CHECK(!fdst->var_size, EINVAL);
/* SHR, SHR_HM, SHR_MH, SHR_HH. */
fsrc = struct_field_parse(p, action, src, &src_struct_id);
if (fsrc) {
CHECK(!fsrc->var_size, EINVAL);
instr->type = INSTR_ALU_SHR;
if (dst[0] == 'h' && src[0] != 'h')
instr->type = INSTR_ALU_SHR_HM;
if (dst[0] != 'h' && src[0] == 'h')
instr->type = INSTR_ALU_SHR_MH;
if (dst[0] == 'h' && src[0] == 'h')
instr->type = INSTR_ALU_SHR_HH;
instr->alu.dst.struct_id = (uint8_t)dst_struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
instr->alu.src.struct_id = (uint8_t)src_struct_id;
instr->alu.src.n_bits = fsrc->n_bits;
instr->alu.src.offset = fsrc->offset / 8;
return 0;
}
/* SHR_MI, SHR_HI. */
src_val = strtoull(src, &src, 0);
CHECK(!src[0], EINVAL);
instr->type = INSTR_ALU_SHR_MI;
if (dst[0] == 'h')
instr->type = INSTR_ALU_SHR_HI;
instr->alu.dst.struct_id = (uint8_t)dst_struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
instr->alu.src_val = src_val;
return 0;
}
static int
instr_alu_and_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
char *dst = tokens[1], *src = tokens[2];
struct field *fdst, *fsrc;
uint64_t src_val;
uint32_t dst_struct_id = 0, src_struct_id = 0;
CHECK(n_tokens == 3, EINVAL);
fdst = struct_field_parse(p, NULL, dst, &dst_struct_id);
CHECK(fdst, EINVAL);
CHECK(!fdst->var_size, EINVAL);
/* AND, AND_MH, AND_HM, AND_HH. */
fsrc = struct_field_parse(p, action, src, &src_struct_id);
if (fsrc) {
CHECK(!fsrc->var_size, EINVAL);
instr->type = INSTR_ALU_AND;
if (dst[0] != 'h' && src[0] == 'h')
instr->type = INSTR_ALU_AND_MH;
if (dst[0] == 'h' && src[0] != 'h')
instr->type = INSTR_ALU_AND_HM;
if (dst[0] == 'h' && src[0] == 'h')
instr->type = INSTR_ALU_AND_HH;
instr->alu.dst.struct_id = (uint8_t)dst_struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
instr->alu.src.struct_id = (uint8_t)src_struct_id;
instr->alu.src.n_bits = fsrc->n_bits;
instr->alu.src.offset = fsrc->offset / 8;
return 0;
}
/* AND_I. */
src_val = strtoull(src, &src, 0);
CHECK(!src[0], EINVAL);
if (dst[0] == 'h')
src_val = hton64(src_val) >> (64 - fdst->n_bits);
instr->type = INSTR_ALU_AND_I;
instr->alu.dst.struct_id = (uint8_t)dst_struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
instr->alu.src_val = src_val;
return 0;
}
static int
instr_alu_or_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
char *dst = tokens[1], *src = tokens[2];
struct field *fdst, *fsrc;
uint64_t src_val;
uint32_t dst_struct_id = 0, src_struct_id = 0;
CHECK(n_tokens == 3, EINVAL);
fdst = struct_field_parse(p, NULL, dst, &dst_struct_id);
CHECK(fdst, EINVAL);
CHECK(!fdst->var_size, EINVAL);
/* OR, OR_MH, OR_HM, OR_HH. */
fsrc = struct_field_parse(p, action, src, &src_struct_id);
if (fsrc) {
CHECK(!fsrc->var_size, EINVAL);
instr->type = INSTR_ALU_OR;
if (dst[0] != 'h' && src[0] == 'h')
instr->type = INSTR_ALU_OR_MH;
if (dst[0] == 'h' && src[0] != 'h')
instr->type = INSTR_ALU_OR_HM;
if (dst[0] == 'h' && src[0] == 'h')
instr->type = INSTR_ALU_OR_HH;
instr->alu.dst.struct_id = (uint8_t)dst_struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
instr->alu.src.struct_id = (uint8_t)src_struct_id;
instr->alu.src.n_bits = fsrc->n_bits;
instr->alu.src.offset = fsrc->offset / 8;
return 0;
}
/* OR_I. */
src_val = strtoull(src, &src, 0);
CHECK(!src[0], EINVAL);
if (dst[0] == 'h')
src_val = hton64(src_val) >> (64 - fdst->n_bits);
instr->type = INSTR_ALU_OR_I;
instr->alu.dst.struct_id = (uint8_t)dst_struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
instr->alu.src_val = src_val;
return 0;
}
static int
instr_alu_xor_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
char *dst = tokens[1], *src = tokens[2];
struct field *fdst, *fsrc;
uint64_t src_val;
uint32_t dst_struct_id = 0, src_struct_id = 0;
CHECK(n_tokens == 3, EINVAL);
fdst = struct_field_parse(p, NULL, dst, &dst_struct_id);
CHECK(fdst, EINVAL);
CHECK(!fdst->var_size, EINVAL);
/* XOR, XOR_MH, XOR_HM, XOR_HH. */
fsrc = struct_field_parse(p, action, src, &src_struct_id);
if (fsrc) {
CHECK(!fsrc->var_size, EINVAL);
instr->type = INSTR_ALU_XOR;
if (dst[0] != 'h' && src[0] == 'h')
instr->type = INSTR_ALU_XOR_MH;
if (dst[0] == 'h' && src[0] != 'h')
instr->type = INSTR_ALU_XOR_HM;
if (dst[0] == 'h' && src[0] == 'h')
instr->type = INSTR_ALU_XOR_HH;
instr->alu.dst.struct_id = (uint8_t)dst_struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
instr->alu.src.struct_id = (uint8_t)src_struct_id;
instr->alu.src.n_bits = fsrc->n_bits;
instr->alu.src.offset = fsrc->offset / 8;
return 0;
}
/* XOR_I. */
src_val = strtoull(src, &src, 0);
CHECK(!src[0], EINVAL);
if (dst[0] == 'h')
src_val = hton64(src_val) >> (64 - fdst->n_bits);
instr->type = INSTR_ALU_XOR_I;
instr->alu.dst.struct_id = (uint8_t)dst_struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
instr->alu.src_val = src_val;
return 0;
}
static inline void
instr_alu_add_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs */
__instr_alu_add_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_add_mh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_add_mh_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_add_hm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_add_hm_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_add_hh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_add_hh_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_add_mi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_add_mi_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_add_hi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_add_hi_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_sub_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_sub_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_sub_mh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_sub_mh_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_sub_hm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_sub_hm_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_sub_hh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_sub_hh_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_sub_mi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_sub_mi_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_sub_hi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_sub_hi_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_shl_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_shl_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_shl_mh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_shl_mh_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_shl_hm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_shl_hm_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_shl_hh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_shl_hh_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_shl_mi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_shl_mi_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_shl_hi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_shl_hi_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_shr_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_shr_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_shr_mh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_shr_mh_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_shr_hm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_shr_hm_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_shr_hh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_shr_hh_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_shr_mi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_shr_mi_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_shr_hi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_shr_hi_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_and_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_and_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_and_mh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_and_mh_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_and_hm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_and_hm_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_and_hh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_and_hh_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_and_i_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_and_i_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_or_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_or_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_or_mh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_or_mh_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_or_hm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_or_hm_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_or_hh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_or_hh_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_or_i_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_or_i_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_xor_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_xor_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_xor_mh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_xor_mh_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_xor_hm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_xor_hm_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_xor_hh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_xor_hh_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_xor_i_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_xor_i_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_ckadd_field_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_ckadd_field_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_cksub_field_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_cksub_field_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_ckadd_struct20_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_ckadd_struct20_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_ckadd_struct_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_alu_ckadd_struct_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
/*
* Register array.
*/
static struct regarray *
regarray_find(struct rte_swx_pipeline *p, const char *name);
static int
instr_regprefetch_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
char *regarray = tokens[1], *idx = tokens[2];
struct regarray *r;
struct field *fidx;
uint32_t idx_struct_id, idx_val;
CHECK(n_tokens == 3, EINVAL);
r = regarray_find(p, regarray);
CHECK(r, EINVAL);
/* REGPREFETCH_RH, REGPREFETCH_RM. */
fidx = struct_field_parse(p, action, idx, &idx_struct_id);
if (fidx) {
CHECK(!fidx->var_size, EINVAL);
instr->type = INSTR_REGPREFETCH_RM;
if (idx[0] == 'h')
instr->type = INSTR_REGPREFETCH_RH;
instr->regarray.regarray_id = r->id;
instr->regarray.idx.struct_id = (uint8_t)idx_struct_id;
instr->regarray.idx.n_bits = fidx->n_bits;
instr->regarray.idx.offset = fidx->offset / 8;
instr->regarray.dstsrc_val = 0; /* Unused. */
return 0;
}
/* REGPREFETCH_RI. */
idx_val = strtoul(idx, &idx, 0);
CHECK(!idx[0], EINVAL);
instr->type = INSTR_REGPREFETCH_RI;
instr->regarray.regarray_id = r->id;
instr->regarray.idx_val = idx_val;
instr->regarray.dstsrc_val = 0; /* Unused. */
return 0;
}
static int
instr_regrd_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
char *dst = tokens[1], *regarray = tokens[2], *idx = tokens[3];
struct regarray *r;
struct field *fdst, *fidx;
uint32_t dst_struct_id, idx_struct_id, idx_val;
CHECK(n_tokens == 4, EINVAL);
r = regarray_find(p, regarray);
CHECK(r, EINVAL);
fdst = struct_field_parse(p, NULL, dst, &dst_struct_id);
CHECK(fdst, EINVAL);
CHECK(!fdst->var_size, EINVAL);
/* REGRD_HRH, REGRD_HRM, REGRD_MRH, REGRD_MRM. */
fidx = struct_field_parse(p, action, idx, &idx_struct_id);
if (fidx) {
CHECK(!fidx->var_size, EINVAL);
instr->type = INSTR_REGRD_MRM;
if (dst[0] == 'h' && idx[0] != 'h')
instr->type = INSTR_REGRD_HRM;
if (dst[0] != 'h' && idx[0] == 'h')
instr->type = INSTR_REGRD_MRH;
if (dst[0] == 'h' && idx[0] == 'h')
instr->type = INSTR_REGRD_HRH;
instr->regarray.regarray_id = r->id;
instr->regarray.idx.struct_id = (uint8_t)idx_struct_id;
instr->regarray.idx.n_bits = fidx->n_bits;
instr->regarray.idx.offset = fidx->offset / 8;
instr->regarray.dstsrc.struct_id = (uint8_t)dst_struct_id;
instr->regarray.dstsrc.n_bits = fdst->n_bits;
instr->regarray.dstsrc.offset = fdst->offset / 8;
return 0;
}
/* REGRD_MRI, REGRD_HRI. */
idx_val = strtoul(idx, &idx, 0);
CHECK(!idx[0], EINVAL);
instr->type = INSTR_REGRD_MRI;
if (dst[0] == 'h')
instr->type = INSTR_REGRD_HRI;
instr->regarray.regarray_id = r->id;
instr->regarray.idx_val = idx_val;
instr->regarray.dstsrc.struct_id = (uint8_t)dst_struct_id;
instr->regarray.dstsrc.n_bits = fdst->n_bits;
instr->regarray.dstsrc.offset = fdst->offset / 8;
return 0;
}
static int
instr_regwr_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
char *regarray = tokens[1], *idx = tokens[2], *src = tokens[3];
struct regarray *r;
struct field *fidx, *fsrc;
uint64_t src_val;
uint32_t idx_struct_id, idx_val, src_struct_id;
CHECK(n_tokens == 4, EINVAL);
r = regarray_find(p, regarray);
CHECK(r, EINVAL);
/* REGWR_RHH, REGWR_RHM, REGWR_RMH, REGWR_RMM. */
fidx = struct_field_parse(p, action, idx, &idx_struct_id);
fsrc = struct_field_parse(p, action, src, &src_struct_id);
if (fidx && fsrc) {
CHECK(!fidx->var_size, EINVAL);
CHECK(!fsrc->var_size, EINVAL);
instr->type = INSTR_REGWR_RMM;
if (idx[0] == 'h' && src[0] != 'h')
instr->type = INSTR_REGWR_RHM;
if (idx[0] != 'h' && src[0] == 'h')
instr->type = INSTR_REGWR_RMH;
if (idx[0] == 'h' && src[0] == 'h')
instr->type = INSTR_REGWR_RHH;
instr->regarray.regarray_id = r->id;
instr->regarray.idx.struct_id = (uint8_t)idx_struct_id;
instr->regarray.idx.n_bits = fidx->n_bits;
instr->regarray.idx.offset = fidx->offset / 8;
instr->regarray.dstsrc.struct_id = (uint8_t)src_struct_id;
instr->regarray.dstsrc.n_bits = fsrc->n_bits;
instr->regarray.dstsrc.offset = fsrc->offset / 8;
return 0;
}
/* REGWR_RHI, REGWR_RMI. */
if (fidx && !fsrc) {
CHECK(!fidx->var_size, EINVAL);
src_val = strtoull(src, &src, 0);
CHECK(!src[0], EINVAL);
instr->type = INSTR_REGWR_RMI;
if (idx[0] == 'h')
instr->type = INSTR_REGWR_RHI;
instr->regarray.regarray_id = r->id;
instr->regarray.idx.struct_id = (uint8_t)idx_struct_id;
instr->regarray.idx.n_bits = fidx->n_bits;
instr->regarray.idx.offset = fidx->offset / 8;
instr->regarray.dstsrc_val = src_val;
return 0;
}
/* REGWR_RIH, REGWR_RIM. */
if (!fidx && fsrc) {
idx_val = strtoul(idx, &idx, 0);
CHECK(!idx[0], EINVAL);
CHECK(!fsrc->var_size, EINVAL);
instr->type = INSTR_REGWR_RIM;
if (src[0] == 'h')
instr->type = INSTR_REGWR_RIH;
instr->regarray.regarray_id = r->id;
instr->regarray.idx_val = idx_val;
instr->regarray.dstsrc.struct_id = (uint8_t)src_struct_id;
instr->regarray.dstsrc.n_bits = fsrc->n_bits;
instr->regarray.dstsrc.offset = fsrc->offset / 8;
return 0;
}
/* REGWR_RII. */
src_val = strtoull(src, &src, 0);
CHECK(!src[0], EINVAL);
idx_val = strtoul(idx, &idx, 0);
CHECK(!idx[0], EINVAL);
instr->type = INSTR_REGWR_RII;
instr->regarray.idx_val = idx_val;
instr->regarray.dstsrc_val = src_val;
return 0;
}
static int
instr_regadd_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
char *regarray = tokens[1], *idx = tokens[2], *src = tokens[3];
struct regarray *r;
struct field *fidx, *fsrc;
uint64_t src_val;
uint32_t idx_struct_id, idx_val, src_struct_id;
CHECK(n_tokens == 4, EINVAL);
r = regarray_find(p, regarray);
CHECK(r, EINVAL);
/* REGADD_RHH, REGADD_RHM, REGADD_RMH, REGADD_RMM. */
fidx = struct_field_parse(p, action, idx, &idx_struct_id);
fsrc = struct_field_parse(p, action, src, &src_struct_id);
if (fidx && fsrc) {
CHECK(!fidx->var_size, EINVAL);
CHECK(!fsrc->var_size, EINVAL);
instr->type = INSTR_REGADD_RMM;
if (idx[0] == 'h' && src[0] != 'h')
instr->type = INSTR_REGADD_RHM;
if (idx[0] != 'h' && src[0] == 'h')
instr->type = INSTR_REGADD_RMH;
if (idx[0] == 'h' && src[0] == 'h')
instr->type = INSTR_REGADD_RHH;
instr->regarray.regarray_id = r->id;
instr->regarray.idx.struct_id = (uint8_t)idx_struct_id;
instr->regarray.idx.n_bits = fidx->n_bits;
instr->regarray.idx.offset = fidx->offset / 8;
instr->regarray.dstsrc.struct_id = (uint8_t)src_struct_id;
instr->regarray.dstsrc.n_bits = fsrc->n_bits;
instr->regarray.dstsrc.offset = fsrc->offset / 8;
return 0;
}
/* REGADD_RHI, REGADD_RMI. */
if (fidx && !fsrc) {
CHECK(!fidx->var_size, EINVAL);
src_val = strtoull(src, &src, 0);
CHECK(!src[0], EINVAL);
instr->type = INSTR_REGADD_RMI;
if (idx[0] == 'h')
instr->type = INSTR_REGADD_RHI;
instr->regarray.regarray_id = r->id;
instr->regarray.idx.struct_id = (uint8_t)idx_struct_id;
instr->regarray.idx.n_bits = fidx->n_bits;
instr->regarray.idx.offset = fidx->offset / 8;
instr->regarray.dstsrc_val = src_val;
return 0;
}
/* REGADD_RIH, REGADD_RIM. */
if (!fidx && fsrc) {
idx_val = strtoul(idx, &idx, 0);
CHECK(!idx[0], EINVAL);
CHECK(!fsrc->var_size, EINVAL);
instr->type = INSTR_REGADD_RIM;
if (src[0] == 'h')
instr->type = INSTR_REGADD_RIH;
instr->regarray.regarray_id = r->id;
instr->regarray.idx_val = idx_val;
instr->regarray.dstsrc.struct_id = (uint8_t)src_struct_id;
instr->regarray.dstsrc.n_bits = fsrc->n_bits;
instr->regarray.dstsrc.offset = fsrc->offset / 8;
return 0;
}
/* REGADD_RII. */
src_val = strtoull(src, &src, 0);
CHECK(!src[0], EINVAL);
idx_val = strtoul(idx, &idx, 0);
CHECK(!idx[0], EINVAL);
instr->type = INSTR_REGADD_RII;
instr->regarray.idx_val = idx_val;
instr->regarray.dstsrc_val = src_val;
return 0;
}
static inline void
instr_regprefetch_rh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_regprefetch_rh_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regprefetch_rm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_regprefetch_rm_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regprefetch_ri_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_regprefetch_ri_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regrd_hrh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_regrd_hrh_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regrd_hrm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_regrd_hrm_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regrd_mrh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_regrd_mrh_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regrd_mrm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_regrd_mrm_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regrd_hri_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_regrd_hri_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regrd_mri_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_regrd_mri_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regwr_rhh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_regwr_rhh_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regwr_rhm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_regwr_rhm_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regwr_rmh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_regwr_rmh_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regwr_rmm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_regwr_rmm_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regwr_rhi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_regwr_rhi_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regwr_rmi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_regwr_rmi_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regwr_rih_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_regwr_rih_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regwr_rim_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_regwr_rim_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regwr_rii_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_regwr_rii_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regadd_rhh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_regadd_rhh_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regadd_rhm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_regadd_rhm_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regadd_rmh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_regadd_rmh_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regadd_rmm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_regadd_rmm_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regadd_rhi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_regadd_rhi_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regadd_rmi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_regadd_rmi_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regadd_rih_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_regadd_rih_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regadd_rim_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_regadd_rim_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regadd_rii_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_regadd_rii_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
/*
* metarray.
*/
static struct metarray *
metarray_find(struct rte_swx_pipeline *p, const char *name);
static int
instr_metprefetch_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
char *metarray = tokens[1], *idx = tokens[2];
struct metarray *m;
struct field *fidx;
uint32_t idx_struct_id, idx_val;
CHECK(n_tokens == 3, EINVAL);
m = metarray_find(p, metarray);
CHECK(m, EINVAL);
/* METPREFETCH_H, METPREFETCH_M. */
fidx = struct_field_parse(p, action, idx, &idx_struct_id);
if (fidx) {
CHECK(!fidx->var_size, EINVAL);
instr->type = INSTR_METPREFETCH_M;
if (idx[0] == 'h')
instr->type = INSTR_METPREFETCH_H;
instr->meter.metarray_id = m->id;
instr->meter.idx.struct_id = (uint8_t)idx_struct_id;
instr->meter.idx.n_bits = fidx->n_bits;
instr->meter.idx.offset = fidx->offset / 8;
return 0;
}
/* METPREFETCH_I. */
idx_val = strtoul(idx, &idx, 0);
CHECK(!idx[0], EINVAL);
instr->type = INSTR_METPREFETCH_I;
instr->meter.metarray_id = m->id;
instr->meter.idx_val = idx_val;
return 0;
}
static int
instr_meter_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
char *metarray = tokens[1], *idx = tokens[2], *length = tokens[3];
char *color_in = tokens[4], *color_out = tokens[5];
struct metarray *m;
struct field *fidx, *flength, *fcin, *fcout;
uint32_t idx_struct_id, length_struct_id;
uint32_t color_in_struct_id, color_out_struct_id;
CHECK(n_tokens == 6, EINVAL);
m = metarray_find(p, metarray);
CHECK(m, EINVAL);
fidx = struct_field_parse(p, action, idx, &idx_struct_id);
flength = struct_field_parse(p, action, length, &length_struct_id);
CHECK(flength, EINVAL);
CHECK(!flength->var_size, EINVAL);
fcin = struct_field_parse(p, action, color_in, &color_in_struct_id);
fcout = struct_field_parse(p, NULL, color_out, &color_out_struct_id);
CHECK(fcout, EINVAL);
CHECK(!fcout->var_size, EINVAL);
/* index = HMEFT, length = HMEFT, color_in = MEFT, color_out = MEF. */
if (fidx && fcin) {
CHECK(!fidx->var_size, EINVAL);
CHECK(!fcin->var_size, EINVAL);
instr->type = INSTR_METER_MMM;
if (idx[0] == 'h' && length[0] == 'h')
instr->type = INSTR_METER_HHM;
if (idx[0] == 'h' && length[0] != 'h')
instr->type = INSTR_METER_HMM;
if (idx[0] != 'h' && length[0] == 'h')
instr->type = INSTR_METER_MHM;
instr->meter.metarray_id = m->id;
instr->meter.idx.struct_id = (uint8_t)idx_struct_id;
instr->meter.idx.n_bits = fidx->n_bits;
instr->meter.idx.offset = fidx->offset / 8;
instr->meter.length.struct_id = (uint8_t)length_struct_id;
instr->meter.length.n_bits = flength->n_bits;
instr->meter.length.offset = flength->offset / 8;
instr->meter.color_in.struct_id = (uint8_t)color_in_struct_id;
instr->meter.color_in.n_bits = fcin->n_bits;
instr->meter.color_in.offset = fcin->offset / 8;
instr->meter.color_out.struct_id = (uint8_t)color_out_struct_id;
instr->meter.color_out.n_bits = fcout->n_bits;
instr->meter.color_out.offset = fcout->offset / 8;
}
/* index = HMEFT, length = HMEFT, color_in = I, color_out = MEF. */
if (fidx && !fcin) {
uint32_t color_in_val;
CHECK(!fidx->var_size, EINVAL);
color_in_val = strtoul(color_in, &color_in, 0);
CHECK(!color_in[0], EINVAL);
instr->type = INSTR_METER_MMI;
if (idx[0] == 'h' && length[0] == 'h')
instr->type = INSTR_METER_HHI;
if (idx[0] == 'h' && length[0] != 'h')
instr->type = INSTR_METER_HMI;
if (idx[0] != 'h' && length[0] == 'h')
instr->type = INSTR_METER_MHI;
instr->meter.metarray_id = m->id;
instr->meter.idx.struct_id = (uint8_t)idx_struct_id;
instr->meter.idx.n_bits = fidx->n_bits;
instr->meter.idx.offset = fidx->offset / 8;
instr->meter.length.struct_id = (uint8_t)length_struct_id;
instr->meter.length.n_bits = flength->n_bits;
instr->meter.length.offset = flength->offset / 8;
instr->meter.color_in_val = color_in_val;
instr->meter.color_out.struct_id = (uint8_t)color_out_struct_id;
instr->meter.color_out.n_bits = fcout->n_bits;
instr->meter.color_out.offset = fcout->offset / 8;
}
/* index = I, length = HMEFT, color_in = MEFT, color_out = MEF. */
if (!fidx && fcin) {
uint32_t idx_val;
idx_val = strtoul(idx, &idx, 0);
CHECK(!idx[0], EINVAL);
CHECK(!fcin->var_size, EINVAL);
instr->type = INSTR_METER_IMM;
if (length[0] == 'h')
instr->type = INSTR_METER_IHM;
instr->meter.metarray_id = m->id;
instr->meter.idx_val = idx_val;
instr->meter.length.struct_id = (uint8_t)length_struct_id;
instr->meter.length.n_bits = flength->n_bits;
instr->meter.length.offset = flength->offset / 8;
instr->meter.color_in.struct_id = (uint8_t)color_in_struct_id;
instr->meter.color_in.n_bits = fcin->n_bits;
instr->meter.color_in.offset = fcin->offset / 8;
instr->meter.color_out.struct_id = (uint8_t)color_out_struct_id;
instr->meter.color_out.n_bits = fcout->n_bits;
instr->meter.color_out.offset = fcout->offset / 8;
}
/* index = I, length = HMEFT, color_in = I, color_out = MEF. */
if (!fidx && !fcin) {
uint32_t idx_val, color_in_val;
idx_val = strtoul(idx, &idx, 0);
CHECK(!idx[0], EINVAL);
color_in_val = strtoul(color_in, &color_in, 0);
CHECK(!color_in[0], EINVAL);
instr->type = INSTR_METER_IMI;
if (length[0] == 'h')
instr->type = INSTR_METER_IHI;
instr->meter.metarray_id = m->id;
instr->meter.idx_val = idx_val;
instr->meter.length.struct_id = (uint8_t)length_struct_id;
instr->meter.length.n_bits = flength->n_bits;
instr->meter.length.offset = flength->offset / 8;
instr->meter.color_in_val = color_in_val;
instr->meter.color_out.struct_id = (uint8_t)color_out_struct_id;
instr->meter.color_out.n_bits = fcout->n_bits;
instr->meter.color_out.offset = fcout->offset / 8;
}
return 0;
}
static inline void
instr_metprefetch_h_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_metprefetch_h_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_metprefetch_m_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_metprefetch_m_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_metprefetch_i_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_metprefetch_i_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_meter_hhm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_meter_hhm_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_meter_hhi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_meter_hhi_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_meter_hmm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_meter_hmm_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_meter_hmi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_meter_hmi_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_meter_mhm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_meter_mhm_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_meter_mhi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_meter_mhi_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_meter_mmm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_meter_mmm_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_meter_mmi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_meter_mmi_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_meter_ihm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_meter_ihm_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_meter_ihi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_meter_ihi_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_meter_imm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_meter_imm_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_meter_imi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
__instr_meter_imi_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
/*
* jmp.
*/
static int
instr_jmp_translate(struct rte_swx_pipeline *p __rte_unused,
struct action *action __rte_unused,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data)
{
CHECK(n_tokens == 2, EINVAL);
strcpy(data->jmp_label, tokens[1]);
instr->type = INSTR_JMP;
instr->jmp.ip = NULL; /* Resolved later. */
return 0;
}
static int
instr_jmp_valid_translate(struct rte_swx_pipeline *p,
struct action *action __rte_unused,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data)
{
struct header *h;
CHECK(n_tokens == 3, EINVAL);
strcpy(data->jmp_label, tokens[1]);
h = header_parse(p, tokens[2]);
CHECK(h, EINVAL);
instr->type = INSTR_JMP_VALID;
instr->jmp.ip = NULL; /* Resolved later. */
instr->jmp.header_id = h->id;
return 0;
}
static int
instr_jmp_invalid_translate(struct rte_swx_pipeline *p,
struct action *action __rte_unused,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data)
{
struct header *h;
CHECK(n_tokens == 3, EINVAL);
strcpy(data->jmp_label, tokens[1]);
h = header_parse(p, tokens[2]);
CHECK(h, EINVAL);
instr->type = INSTR_JMP_INVALID;
instr->jmp.ip = NULL; /* Resolved later. */
instr->jmp.header_id = h->id;
return 0;
}
static int
instr_jmp_hit_translate(struct rte_swx_pipeline *p __rte_unused,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data)
{
CHECK(!action, EINVAL);
CHECK(n_tokens == 2, EINVAL);
strcpy(data->jmp_label, tokens[1]);
instr->type = INSTR_JMP_HIT;
instr->jmp.ip = NULL; /* Resolved later. */
return 0;
}
static int
instr_jmp_miss_translate(struct rte_swx_pipeline *p __rte_unused,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data)
{
CHECK(!action, EINVAL);
CHECK(n_tokens == 2, EINVAL);
strcpy(data->jmp_label, tokens[1]);
instr->type = INSTR_JMP_MISS;
instr->jmp.ip = NULL; /* Resolved later. */
return 0;
}
static int
instr_jmp_action_hit_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data)
{
struct action *a;
CHECK(!action, EINVAL);
CHECK(n_tokens == 3, EINVAL);
strcpy(data->jmp_label, tokens[1]);
a = action_find(p, tokens[2]);
CHECK(a, EINVAL);
instr->type = INSTR_JMP_ACTION_HIT;
instr->jmp.ip = NULL; /* Resolved later. */
instr->jmp.action_id = a->id;
return 0;
}
static int
instr_jmp_action_miss_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data)
{
struct action *a;
CHECK(!action, EINVAL);
CHECK(n_tokens == 3, EINVAL);
strcpy(data->jmp_label, tokens[1]);
a = action_find(p, tokens[2]);
CHECK(a, EINVAL);
instr->type = INSTR_JMP_ACTION_MISS;
instr->jmp.ip = NULL; /* Resolved later. */
instr->jmp.action_id = a->id;
return 0;
}
static int
instr_jmp_eq_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data)
{
char *a = tokens[2], *b = tokens[3];
struct field *fa, *fb;
uint64_t b_val;
uint32_t a_struct_id, b_struct_id;
CHECK(n_tokens == 4, EINVAL);
strcpy(data->jmp_label, tokens[1]);
fa = struct_field_parse(p, action, a, &a_struct_id);
CHECK(fa, EINVAL);
CHECK(!fa->var_size, EINVAL);
/* JMP_EQ, JMP_EQ_MH, JMP_EQ_HM, JMP_EQ_HH. */
fb = struct_field_parse(p, action, b, &b_struct_id);
if (fb) {
CHECK(!fb->var_size, EINVAL);
instr->type = INSTR_JMP_EQ;
if (a[0] != 'h' && b[0] == 'h')
instr->type = INSTR_JMP_EQ_MH;
if (a[0] == 'h' && b[0] != 'h')
instr->type = INSTR_JMP_EQ_HM;
if (a[0] == 'h' && b[0] == 'h')
instr->type = INSTR_JMP_EQ_HH;
instr->jmp.ip = NULL; /* Resolved later. */
instr->jmp.a.struct_id = (uint8_t)a_struct_id;
instr->jmp.a.n_bits = fa->n_bits;
instr->jmp.a.offset = fa->offset / 8;
instr->jmp.b.struct_id = (uint8_t)b_struct_id;
instr->jmp.b.n_bits = fb->n_bits;
instr->jmp.b.offset = fb->offset / 8;
return 0;
}
/* JMP_EQ_I. */
b_val = strtoull(b, &b, 0);
CHECK(!b[0], EINVAL);
if (a[0] == 'h')
b_val = hton64(b_val) >> (64 - fa->n_bits);
instr->type = INSTR_JMP_EQ_I;
instr->jmp.ip = NULL; /* Resolved later. */
instr->jmp.a.struct_id = (uint8_t)a_struct_id;
instr->jmp.a.n_bits = fa->n_bits;
instr->jmp.a.offset = fa->offset / 8;
instr->jmp.b_val = b_val;
return 0;
}
static int
instr_jmp_neq_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data)
{
char *a = tokens[2], *b = tokens[3];
struct field *fa, *fb;
uint64_t b_val;
uint32_t a_struct_id, b_struct_id;
CHECK(n_tokens == 4, EINVAL);
strcpy(data->jmp_label, tokens[1]);
fa = struct_field_parse(p, action, a, &a_struct_id);
CHECK(fa, EINVAL);
CHECK(!fa->var_size, EINVAL);
/* JMP_NEQ, JMP_NEQ_MH, JMP_NEQ_HM, JMP_NEQ_HH. */
fb = struct_field_parse(p, action, b, &b_struct_id);
if (fb) {
CHECK(!fb->var_size, EINVAL);
instr->type = INSTR_JMP_NEQ;
if (a[0] != 'h' && b[0] == 'h')
instr->type = INSTR_JMP_NEQ_MH;
if (a[0] == 'h' && b[0] != 'h')
instr->type = INSTR_JMP_NEQ_HM;
if (a[0] == 'h' && b[0] == 'h')
instr->type = INSTR_JMP_NEQ_HH;
instr->jmp.ip = NULL; /* Resolved later. */
instr->jmp.a.struct_id = (uint8_t)a_struct_id;
instr->jmp.a.n_bits = fa->n_bits;
instr->jmp.a.offset = fa->offset / 8;
instr->jmp.b.struct_id = (uint8_t)b_struct_id;
instr->jmp.b.n_bits = fb->n_bits;
instr->jmp.b.offset = fb->offset / 8;
return 0;
}
/* JMP_NEQ_I. */
b_val = strtoull(b, &b, 0);
CHECK(!b[0], EINVAL);
if (a[0] == 'h')
b_val = hton64(b_val) >> (64 - fa->n_bits);
instr->type = INSTR_JMP_NEQ_I;
instr->jmp.ip = NULL; /* Resolved later. */
instr->jmp.a.struct_id = (uint8_t)a_struct_id;
instr->jmp.a.n_bits = fa->n_bits;
instr->jmp.a.offset = fa->offset / 8;
instr->jmp.b_val = b_val;
return 0;
}
static int
instr_jmp_lt_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data)
{
char *a = tokens[2], *b = tokens[3];
struct field *fa, *fb;
uint64_t b_val;
uint32_t a_struct_id, b_struct_id;
CHECK(n_tokens == 4, EINVAL);
strcpy(data->jmp_label, tokens[1]);
fa = struct_field_parse(p, action, a, &a_struct_id);
CHECK(fa, EINVAL);
CHECK(!fa->var_size, EINVAL);
/* JMP_LT, JMP_LT_MH, JMP_LT_HM, JMP_LT_HH. */
fb = struct_field_parse(p, action, b, &b_struct_id);
if (fb) {
CHECK(!fb->var_size, EINVAL);
instr->type = INSTR_JMP_LT;
if (a[0] == 'h' && b[0] != 'h')
instr->type = INSTR_JMP_LT_HM;
if (a[0] != 'h' && b[0] == 'h')
instr->type = INSTR_JMP_LT_MH;
if (a[0] == 'h' && b[0] == 'h')
instr->type = INSTR_JMP_LT_HH;
instr->jmp.ip = NULL; /* Resolved later. */
instr->jmp.a.struct_id = (uint8_t)a_struct_id;
instr->jmp.a.n_bits = fa->n_bits;
instr->jmp.a.offset = fa->offset / 8;
instr->jmp.b.struct_id = (uint8_t)b_struct_id;
instr->jmp.b.n_bits = fb->n_bits;
instr->jmp.b.offset = fb->offset / 8;
return 0;
}
/* JMP_LT_MI, JMP_LT_HI. */
b_val = strtoull(b, &b, 0);
CHECK(!b[0], EINVAL);
instr->type = INSTR_JMP_LT_MI;
if (a[0] == 'h')
instr->type = INSTR_JMP_LT_HI;
instr->jmp.ip = NULL; /* Resolved later. */
instr->jmp.a.struct_id = (uint8_t)a_struct_id;
instr->jmp.a.n_bits = fa->n_bits;
instr->jmp.a.offset = fa->offset / 8;
instr->jmp.b_val = b_val;
return 0;
}
static int
instr_jmp_gt_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data)
{
char *a = tokens[2], *b = tokens[3];
struct field *fa, *fb;
uint64_t b_val;
uint32_t a_struct_id, b_struct_id;
CHECK(n_tokens == 4, EINVAL);
strcpy(data->jmp_label, tokens[1]);
fa = struct_field_parse(p, action, a, &a_struct_id);
CHECK(fa, EINVAL);
CHECK(!fa->var_size, EINVAL);
/* JMP_GT, JMP_GT_MH, JMP_GT_HM, JMP_GT_HH. */
fb = struct_field_parse(p, action, b, &b_struct_id);
if (fb) {
CHECK(!fb->var_size, EINVAL);
instr->type = INSTR_JMP_GT;
if (a[0] == 'h' && b[0] != 'h')
instr->type = INSTR_JMP_GT_HM;
if (a[0] != 'h' && b[0] == 'h')
instr->type = INSTR_JMP_GT_MH;
if (a[0] == 'h' && b[0] == 'h')
instr->type = INSTR_JMP_GT_HH;
instr->jmp.ip = NULL; /* Resolved later. */
instr->jmp.a.struct_id = (uint8_t)a_struct_id;
instr->jmp.a.n_bits = fa->n_bits;
instr->jmp.a.offset = fa->offset / 8;
instr->jmp.b.struct_id = (uint8_t)b_struct_id;
instr->jmp.b.n_bits = fb->n_bits;
instr->jmp.b.offset = fb->offset / 8;
return 0;
}
/* JMP_GT_MI, JMP_GT_HI. */
b_val = strtoull(b, &b, 0);
CHECK(!b[0], EINVAL);
instr->type = INSTR_JMP_GT_MI;
if (a[0] == 'h')
instr->type = INSTR_JMP_GT_HI;
instr->jmp.ip = NULL; /* Resolved later. */
instr->jmp.a.struct_id = (uint8_t)a_struct_id;
instr->jmp.a.n_bits = fa->n_bits;
instr->jmp.a.offset = fa->offset / 8;
instr->jmp.b_val = b_val;
return 0;
}
static inline void
instr_jmp_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmp\n", p->thread_id);
thread_ip_set(t, ip->jmp.ip);
}
static inline void
instr_jmp_valid_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
uint32_t header_id = ip->jmp.header_id;
TRACE("[Thread %2u] jmpv\n", p->thread_id);
t->ip = HEADER_VALID(t, header_id) ? ip->jmp.ip : (t->ip + 1);
}
static inline void
instr_jmp_invalid_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
uint32_t header_id = ip->jmp.header_id;
TRACE("[Thread %2u] jmpnv\n", p->thread_id);
t->ip = HEADER_VALID(t, header_id) ? (t->ip + 1) : ip->jmp.ip;
}
static inline void
instr_jmp_hit_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
struct instruction *ip_next[] = {t->ip + 1, ip->jmp.ip};
TRACE("[Thread %2u] jmph\n", p->thread_id);
t->ip = ip_next[t->hit];
}
static inline void
instr_jmp_miss_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
struct instruction *ip_next[] = {ip->jmp.ip, t->ip + 1};
TRACE("[Thread %2u] jmpnh\n", p->thread_id);
t->ip = ip_next[t->hit];
}
static inline void
instr_jmp_action_hit_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpa\n", p->thread_id);
t->ip = (ip->jmp.action_id == t->action_id) ? ip->jmp.ip : (t->ip + 1);
}
static inline void
instr_jmp_action_miss_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpna\n", p->thread_id);
t->ip = (ip->jmp.action_id == t->action_id) ? (t->ip + 1) : ip->jmp.ip;
}
static inline void
instr_jmp_eq_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpeq\n", p->thread_id);
JMP_CMP(t, ip, ==);
}
static inline void
instr_jmp_eq_mh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpeq (mh)\n", p->thread_id);
JMP_CMP_MH(t, ip, ==);
}
static inline void
instr_jmp_eq_hm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpeq (hm)\n", p->thread_id);
JMP_CMP_HM(t, ip, ==);
}
static inline void
instr_jmp_eq_hh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpeq (hh)\n", p->thread_id);
JMP_CMP_HH_FAST(t, ip, ==);
}
static inline void
instr_jmp_eq_i_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpeq (i)\n", p->thread_id);
JMP_CMP_I(t, ip, ==);
}
static inline void
instr_jmp_neq_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpneq\n", p->thread_id);
JMP_CMP(t, ip, !=);
}
static inline void
instr_jmp_neq_mh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpneq (mh)\n", p->thread_id);
JMP_CMP_MH(t, ip, !=);
}
static inline void
instr_jmp_neq_hm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpneq (hm)\n", p->thread_id);
JMP_CMP_HM(t, ip, !=);
}
static inline void
instr_jmp_neq_hh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpneq (hh)\n", p->thread_id);
JMP_CMP_HH_FAST(t, ip, !=);
}
static inline void
instr_jmp_neq_i_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpneq (i)\n", p->thread_id);
JMP_CMP_I(t, ip, !=);
}
static inline void
instr_jmp_lt_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmplt\n", p->thread_id);
JMP_CMP(t, ip, <);
}
static inline void
instr_jmp_lt_mh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmplt (mh)\n", p->thread_id);
JMP_CMP_MH(t, ip, <);
}
static inline void
instr_jmp_lt_hm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmplt (hm)\n", p->thread_id);
JMP_CMP_HM(t, ip, <);
}
static inline void
instr_jmp_lt_hh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmplt (hh)\n", p->thread_id);
JMP_CMP_HH(t, ip, <);
}
static inline void
instr_jmp_lt_mi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmplt (mi)\n", p->thread_id);
JMP_CMP_MI(t, ip, <);
}
static inline void
instr_jmp_lt_hi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmplt (hi)\n", p->thread_id);
JMP_CMP_HI(t, ip, <);
}
static inline void
instr_jmp_gt_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpgt\n", p->thread_id);
JMP_CMP(t, ip, >);
}
static inline void
instr_jmp_gt_mh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpgt (mh)\n", p->thread_id);
JMP_CMP_MH(t, ip, >);
}
static inline void
instr_jmp_gt_hm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpgt (hm)\n", p->thread_id);
JMP_CMP_HM(t, ip, >);
}
static inline void
instr_jmp_gt_hh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpgt (hh)\n", p->thread_id);
JMP_CMP_HH(t, ip, >);
}
static inline void
instr_jmp_gt_mi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpgt (mi)\n", p->thread_id);
JMP_CMP_MI(t, ip, >);
}
static inline void
instr_jmp_gt_hi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpgt (hi)\n", p->thread_id);
JMP_CMP_HI(t, ip, >);
}
/*
* return.
*/
static int
instr_return_translate(struct rte_swx_pipeline *p __rte_unused,
struct action *action,
char **tokens __rte_unused,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
CHECK(action, EINVAL);
CHECK(n_tokens == 1, EINVAL);
instr->type = INSTR_RETURN;
return 0;
}
static inline void
instr_return_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
TRACE("[Thread %2u] return\n", p->thread_id);
t->ip = t->ret;
}
static int
instr_translate(struct rte_swx_pipeline *p,
struct action *action,
char *string,
struct instruction *instr,
struct instruction_data *data)
{
char *tokens[RTE_SWX_INSTRUCTION_TOKENS_MAX];
int n_tokens = 0, tpos = 0;
/* Parse the instruction string into tokens. */
for ( ; ; ) {
char *token;
token = strtok_r(string, " \t\v", &string);
if (!token)
break;
CHECK(n_tokens < RTE_SWX_INSTRUCTION_TOKENS_MAX, EINVAL);
CHECK_NAME(token, EINVAL);
tokens[n_tokens] = token;
n_tokens++;
}
CHECK(n_tokens, EINVAL);
/* Handle the optional instruction label. */
if ((n_tokens >= 2) && !strcmp(tokens[1], ":")) {
strcpy(data->label, tokens[0]);
tpos += 2;
CHECK(n_tokens - tpos, EINVAL);
}
/* Identify the instruction type. */
if (!strcmp(tokens[tpos], "rx"))
return instr_rx_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "tx"))
return instr_tx_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "drop"))
return instr_drop_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "extract"))
return instr_hdr_extract_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "lookahead"))
return instr_hdr_lookahead_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "emit"))
return instr_hdr_emit_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "validate"))
return instr_hdr_validate_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "invalidate"))
return instr_hdr_invalidate_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "mov"))
return instr_mov_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "add"))
return instr_alu_add_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "sub"))
return instr_alu_sub_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "ckadd"))
return instr_alu_ckadd_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "cksub"))
return instr_alu_cksub_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "and"))
return instr_alu_and_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "or"))
return instr_alu_or_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "xor"))
return instr_alu_xor_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "shl"))
return instr_alu_shl_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "shr"))
return instr_alu_shr_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "regprefetch"))
return instr_regprefetch_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "regrd"))
return instr_regrd_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "regwr"))
return instr_regwr_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "regadd"))
return instr_regadd_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "metprefetch"))
return instr_metprefetch_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "meter"))
return instr_meter_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "table"))
return instr_table_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "learn"))
return instr_learn_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "forget"))
return instr_forget_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "extern"))
return instr_extern_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "jmp"))
return instr_jmp_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "jmpv"))
return instr_jmp_valid_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "jmpnv"))
return instr_jmp_invalid_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "jmph"))
return instr_jmp_hit_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "jmpnh"))
return instr_jmp_miss_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "jmpa"))
return instr_jmp_action_hit_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "jmpna"))
return instr_jmp_action_miss_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "jmpeq"))
return instr_jmp_eq_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "jmpneq"))
return instr_jmp_neq_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "jmplt"))
return instr_jmp_lt_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "jmpgt"))
return instr_jmp_gt_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "return"))
return instr_return_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
return -EINVAL;
}
static struct instruction_data *
label_find(struct instruction_data *data, uint32_t n, const char *label)
{
uint32_t i;
for (i = 0; i < n; i++)
if (!strcmp(label, data[i].label))
return &data[i];
return NULL;
}
static uint32_t
label_is_used(struct instruction_data *data, uint32_t n, const char *label)
{
uint32_t count = 0, i;
if (!label[0])
return 0;
for (i = 0; i < n; i++)
if (!strcmp(label, data[i].jmp_label))
count++;
return count;
}
static int
instr_label_check(struct instruction_data *instruction_data,
uint32_t n_instructions)
{
uint32_t i;
/* Check that all instruction labels are unique. */
for (i = 0; i < n_instructions; i++) {
struct instruction_data *data = &instruction_data[i];
char *label = data->label;
uint32_t j;
if (!label[0])
continue;
for (j = i + 1; j < n_instructions; j++)
CHECK(strcmp(label, instruction_data[j].label), EINVAL);
}
/* Get users for each instruction label. */
for (i = 0; i < n_instructions; i++) {
struct instruction_data *data = &instruction_data[i];
char *label = data->label;
data->n_users = label_is_used(instruction_data,
n_instructions,
label);
}
return 0;
}
static int
instr_jmp_resolve(struct instruction *instructions,
struct instruction_data *instruction_data,
uint32_t n_instructions)
{
uint32_t i;
for (i = 0; i < n_instructions; i++) {
struct instruction *instr = &instructions[i];
struct instruction_data *data = &instruction_data[i];
struct instruction_data *found;
if (!instruction_is_jmp(instr))
continue;
found = label_find(instruction_data,
n_instructions,
data->jmp_label);
CHECK(found, EINVAL);
instr->jmp.ip = &instructions[found - instruction_data];
}
return 0;
}
static int
instr_verify(struct rte_swx_pipeline *p __rte_unused,
struct action *a,
struct instruction *instr,
struct instruction_data *data __rte_unused,
uint32_t n_instructions)
{
if (!a) {
enum instruction_type type;
uint32_t i;
/* Check that the first instruction is rx. */
CHECK(instr[0].type == INSTR_RX, EINVAL);
/* Check that there is at least one tx instruction. */
for (i = 0; i < n_instructions; i++) {
type = instr[i].type;
if (instruction_is_tx(type))
break;
}
CHECK(i < n_instructions, EINVAL);
/* Check that the last instruction is either tx or unconditional
* jump.
*/
type = instr[n_instructions - 1].type;
CHECK(instruction_is_tx(type) || (type == INSTR_JMP), EINVAL);
}
if (a) {
enum instruction_type type;
uint32_t i;
/* Check that there is at least one return or tx instruction. */
for (i = 0; i < n_instructions; i++) {
type = instr[i].type;
if ((type == INSTR_RETURN) || instruction_is_tx(type))
break;
}
CHECK(i < n_instructions, EINVAL);
}
return 0;
}
static uint32_t
instr_compact(struct instruction *instructions,
struct instruction_data *instruction_data,
uint32_t n_instructions)
{
uint32_t i, pos = 0;
/* Eliminate the invalid instructions that have been optimized out. */
for (i = 0; i < n_instructions; i++) {
struct instruction *instr = &instructions[i];
struct instruction_data *data = &instruction_data[i];
if (data->invalid)
continue;
if (i != pos) {
memcpy(&instructions[pos], instr, sizeof(*instr));
memcpy(&instruction_data[pos], data, sizeof(*data));
}
pos++;
}
return pos;
}
static int
instr_pattern_extract_many_search(struct instruction *instr,
struct instruction_data *data,
uint32_t n_instr,
uint32_t *n_pattern_instr)
{
uint32_t i;
for (i = 0; i < n_instr; i++) {
if (data[i].invalid)
break;
if (instr[i].type != INSTR_HDR_EXTRACT)
break;
if (i == RTE_DIM(instr->io.hdr.header_id))
break;
if (i && data[i].n_users)
break;
}
if (i < 2)
return 0;
*n_pattern_instr = i;
return 1;
}
static void
instr_pattern_extract_many_replace(struct instruction *instr,
struct instruction_data *data,
uint32_t n_instr)
{
uint32_t i;
for (i = 1; i < n_instr; i++) {
instr[0].type++;
instr[0].io.hdr.header_id[i] = instr[i].io.hdr.header_id[0];
instr[0].io.hdr.struct_id[i] = instr[i].io.hdr.struct_id[0];
instr[0].io.hdr.n_bytes[i] = instr[i].io.hdr.n_bytes[0];
data[i].invalid = 1;
}
}
static uint32_t
instr_pattern_extract_many_optimize(struct instruction *instructions,
struct instruction_data *instruction_data,
uint32_t n_instructions)
{
uint32_t i;
for (i = 0; i < n_instructions; ) {
struct instruction *instr = &instructions[i];
struct instruction_data *data = &instruction_data[i];
uint32_t n_instr = 0;
int detected;
/* Extract many. */
detected = instr_pattern_extract_many_search(instr,
data,
n_instructions - i,
&n_instr);
if (detected) {
instr_pattern_extract_many_replace(instr,
data,
n_instr);
i += n_instr;
continue;
}
/* No pattern starting at the current instruction. */
i++;
}
/* Eliminate the invalid instructions that have been optimized out. */
n_instructions = instr_compact(instructions,
instruction_data,
n_instructions);
return n_instructions;
}
static int
instr_pattern_emit_many_tx_search(struct instruction *instr,
struct instruction_data *data,
uint32_t n_instr,
uint32_t *n_pattern_instr)
{
uint32_t i;
for (i = 0; i < n_instr; i++) {
if (data[i].invalid)
break;
if (instr[i].type != INSTR_HDR_EMIT)
break;
if (i == RTE_DIM(instr->io.hdr.header_id))
break;
if (i && data[i].n_users)
break;
}
if (!i)
return 0;
if (!instruction_is_tx(instr[i].type))
return 0;
if (data[i].n_users)
return 0;
i++;
*n_pattern_instr = i;
return 1;
}
static void
instr_pattern_emit_many_tx_replace(struct instruction *instr,
struct instruction_data *data,
uint32_t n_instr)
{
uint32_t i;
/* Any emit instruction in addition to the first one. */
for (i = 1; i < n_instr - 1; i++) {
instr[0].type++;
instr[0].io.hdr.header_id[i] = instr[i].io.hdr.header_id[0];
instr[0].io.hdr.struct_id[i] = instr[i].io.hdr.struct_id[0];
instr[0].io.hdr.n_bytes[i] = instr[i].io.hdr.n_bytes[0];
data[i].invalid = 1;
}
/* The TX instruction is the last one in the pattern. */
instr[0].type++;
instr[0].io.io.offset = instr[i].io.io.offset;
instr[0].io.io.n_bits = instr[i].io.io.n_bits;
data[i].invalid = 1;
}
static uint32_t
instr_pattern_emit_many_tx_optimize(struct instruction *instructions,
struct instruction_data *instruction_data,
uint32_t n_instructions)
{
uint32_t i;
for (i = 0; i < n_instructions; ) {
struct instruction *instr = &instructions[i];
struct instruction_data *data = &instruction_data[i];
uint32_t n_instr = 0;
int detected;
/* Emit many + TX. */
detected = instr_pattern_emit_many_tx_search(instr,
data,
n_instructions - i,
&n_instr);
if (detected) {
instr_pattern_emit_many_tx_replace(instr,
data,
n_instr);
i += n_instr;
continue;
}
/* No pattern starting at the current instruction. */
i++;
}
/* Eliminate the invalid instructions that have been optimized out. */
n_instructions = instr_compact(instructions,
instruction_data,
n_instructions);
return n_instructions;
}
static uint32_t
action_arg_src_mov_count(struct action *a,
uint32_t arg_id,
struct instruction *instructions,
struct instruction_data *instruction_data,
uint32_t n_instructions);
static int
instr_pattern_mov_all_validate_search(struct rte_swx_pipeline *p,
struct action *a,
struct instruction *instr,
struct instruction_data *data,
uint32_t n_instr,
struct instruction *instructions,
struct instruction_data *instruction_data,
uint32_t n_instructions,
uint32_t *n_pattern_instr)
{
struct header *h;
uint32_t src_field_id, i, j;
/* Prerequisites. */
if (!a || !a->st)
return 0;
/* First instruction: MOV_HM. */
if (data[0].invalid || (instr[0].type != INSTR_MOV_HM))
return 0;
h = header_find_by_struct_id(p, instr[0].mov.dst.struct_id);
if (!h || h->st->var_size)
return 0;
for (src_field_id = 0; src_field_id < a->st->n_fields; src_field_id++)
if (instr[0].mov.src.offset == a->st->fields[src_field_id].offset / 8)
break;
if (src_field_id == a->st->n_fields)
return 0;
if (instr[0].mov.dst.offset ||
(instr[0].mov.dst.n_bits != h->st->fields[0].n_bits) ||
instr[0].mov.src.struct_id ||
(instr[0].mov.src.n_bits != a->st->fields[src_field_id].n_bits) ||
(instr[0].mov.dst.n_bits != instr[0].mov.src.n_bits))
return 0;
if ((n_instr < h->st->n_fields + 1) ||
(a->st->n_fields < src_field_id + h->st->n_fields + 1))
return 0;
/* Subsequent instructions: MOV_HM. */
for (i = 1; i < h->st->n_fields; i++)
if (data[i].invalid ||
data[i].n_users ||
(instr[i].type != INSTR_MOV_HM) ||
(instr[i].mov.dst.struct_id != h->struct_id) ||
(instr[i].mov.dst.offset != h->st->fields[i].offset / 8) ||
(instr[i].mov.dst.n_bits != h->st->fields[i].n_bits) ||
instr[i].mov.src.struct_id ||
(instr[i].mov.src.offset != a->st->fields[src_field_id + i].offset / 8) ||
(instr[i].mov.src.n_bits != a->st->fields[src_field_id + i].n_bits) ||
(instr[i].mov.dst.n_bits != instr[i].mov.src.n_bits))
return 0;
/* Last instruction: HDR_VALIDATE. */
if ((instr[i].type != INSTR_HDR_VALIDATE) ||
(instr[i].valid.header_id != h->id))
return 0;
/* Check that none of the action args that are used as source for this
* DMA transfer are not used as source in any other mov instruction.
*/
for (j = src_field_id; j < src_field_id + h->st->n_fields; j++) {
uint32_t n_users;
n_users = action_arg_src_mov_count(a,
j,
instructions,
instruction_data,
n_instructions);
if (n_users > 1)
return 0;
}
*n_pattern_instr = 1 + i;
return 1;
}
static void
instr_pattern_mov_all_validate_replace(struct rte_swx_pipeline *p,
struct action *a,
struct instruction *instr,
struct instruction_data *data,
uint32_t n_instr)
{
struct header *h;
uint32_t src_field_id, src_offset, i;
/* Read from the instructions before they are modified. */
h = header_find_by_struct_id(p, instr[0].mov.dst.struct_id);
if (!h)
return;
for (src_field_id = 0; src_field_id < a->st->n_fields; src_field_id++)
if (instr[0].mov.src.offset == a->st->fields[src_field_id].offset / 8)
break;
if (src_field_id == a->st->n_fields)
return;
src_offset = instr[0].mov.src.offset;
/* Modify the instructions. */
instr[0].type = INSTR_DMA_HT;
instr[0].dma.dst.header_id[0] = h->id;
instr[0].dma.dst.struct_id[0] = h->struct_id;
instr[0].dma.src.offset[0] = (uint8_t)src_offset;
instr[0].dma.n_bytes[0] = h->st->n_bits / 8;
for (i = 1; i < n_instr; i++)
data[i].invalid = 1;
/* Update the endianness of the action arguments to header endianness. */
for (i = 0; i < h->st->n_fields; i++)
a->args_endianness[src_field_id + i] = 1;
}
static uint32_t
instr_pattern_mov_all_validate_optimize(struct rte_swx_pipeline *p,
struct action *a,
struct instruction *instructions,
struct instruction_data *instruction_data,
uint32_t n_instructions)
{
uint32_t i;
if (!a || !a->st)
return n_instructions;
for (i = 0; i < n_instructions; ) {
struct instruction *instr = &instructions[i];
struct instruction_data *data = &instruction_data[i];
uint32_t n_instr = 0;
int detected;
/* Mov all + validate. */
detected = instr_pattern_mov_all_validate_search(p,
a,
instr,
data,
n_instructions - i,
instructions,
instruction_data,
n_instructions,
&n_instr);
if (detected) {
instr_pattern_mov_all_validate_replace(p, a, instr, data, n_instr);
i += n_instr;
continue;
}
/* No pattern starting at the current instruction. */
i++;
}
/* Eliminate the invalid instructions that have been optimized out. */
n_instructions = instr_compact(instructions,
instruction_data,
n_instructions);
return n_instructions;
}
static int
instr_pattern_dma_many_search(struct instruction *instr,
struct instruction_data *data,
uint32_t n_instr,
uint32_t *n_pattern_instr)
{
uint32_t i;
for (i = 0; i < n_instr; i++) {
if (data[i].invalid)
break;
if (instr[i].type != INSTR_DMA_HT)
break;
if (i == RTE_DIM(instr->dma.dst.header_id))
break;
if (i && data[i].n_users)
break;
}
if (i < 2)
return 0;
*n_pattern_instr = i;
return 1;
}
static void
instr_pattern_dma_many_replace(struct instruction *instr,
struct instruction_data *data,
uint32_t n_instr)
{
uint32_t i;
for (i = 1; i < n_instr; i++) {
instr[0].type++;
instr[0].dma.dst.header_id[i] = instr[i].dma.dst.header_id[0];
instr[0].dma.dst.struct_id[i] = instr[i].dma.dst.struct_id[0];
instr[0].dma.src.offset[i] = instr[i].dma.src.offset[0];
instr[0].dma.n_bytes[i] = instr[i].dma.n_bytes[0];
data[i].invalid = 1;
}
}
static uint32_t
instr_pattern_dma_many_optimize(struct instruction *instructions,
struct instruction_data *instruction_data,
uint32_t n_instructions)
{
uint32_t i;
for (i = 0; i < n_instructions; ) {
struct instruction *instr = &instructions[i];
struct instruction_data *data = &instruction_data[i];
uint32_t n_instr = 0;
int detected;
/* DMA many. */
detected = instr_pattern_dma_many_search(instr,
data,
n_instructions - i,
&n_instr);
if (detected) {
instr_pattern_dma_many_replace(instr, data, n_instr);
i += n_instr;
continue;
}
/* No pattern starting at the current instruction. */
i++;
}
/* Eliminate the invalid instructions that have been optimized out. */
n_instructions = instr_compact(instructions,
instruction_data,
n_instructions);
return n_instructions;
}
static uint32_t
instr_optimize(struct rte_swx_pipeline *p,
struct action *a,
struct instruction *instructions,
struct instruction_data *instruction_data,
uint32_t n_instructions)
{
/* Extract many. */
n_instructions = instr_pattern_extract_many_optimize(instructions,
instruction_data,
n_instructions);
/* Emit many + TX. */
n_instructions = instr_pattern_emit_many_tx_optimize(instructions,
instruction_data,
n_instructions);
/* Mov all + validate. */
n_instructions = instr_pattern_mov_all_validate_optimize(p,
a,
instructions,
instruction_data,
n_instructions);
/* DMA many. */
n_instructions = instr_pattern_dma_many_optimize(instructions,
instruction_data,
n_instructions);
return n_instructions;
}
static int
instruction_config(struct rte_swx_pipeline *p,
struct action *a,
const char **instructions,
uint32_t n_instructions)
{
struct instruction *instr = NULL;
struct instruction_data *data = NULL;
int err = 0;
uint32_t i;
CHECK(n_instructions, EINVAL);
CHECK(instructions, EINVAL);
for (i = 0; i < n_instructions; i++)
CHECK_INSTRUCTION(instructions[i], EINVAL);
/* Memory allocation. */
instr = calloc(n_instructions, sizeof(struct instruction));
if (!instr) {
err = -ENOMEM;
goto error;
}
data = calloc(n_instructions, sizeof(struct instruction_data));
if (!data) {
err = -ENOMEM;
goto error;
}
for (i = 0; i < n_instructions; i++) {
char *string = strdup(instructions[i]);
if (!string) {
err = -ENOMEM;
goto error;
}
err = instr_translate(p, a, string, &instr[i], &data[i]);
if (err) {
free(string);
goto error;
}
free(string);
}
err = instr_label_check(data, n_instructions);
if (err)
goto error;
err = instr_verify(p, a, instr, data, n_instructions);
if (err)
goto error;
n_instructions = instr_optimize(p, a, instr, data, n_instructions);
err = instr_jmp_resolve(instr, data, n_instructions);
if (err)
goto error;
if (a) {
a->instructions = instr;
a->instruction_data = data;
a->n_instructions = n_instructions;
} else {
p->instructions = instr;
p->instruction_data = data;
p->n_instructions = n_instructions;
}
return 0;
error:
free(data);
free(instr);
return err;
}
static instr_exec_t instruction_table[] = {
[INSTR_RX] = instr_rx_exec,
[INSTR_TX] = instr_tx_exec,
[INSTR_TX_I] = instr_tx_i_exec,
[INSTR_HDR_EXTRACT] = instr_hdr_extract_exec,
[INSTR_HDR_EXTRACT2] = instr_hdr_extract2_exec,
[INSTR_HDR_EXTRACT3] = instr_hdr_extract3_exec,
[INSTR_HDR_EXTRACT4] = instr_hdr_extract4_exec,
[INSTR_HDR_EXTRACT5] = instr_hdr_extract5_exec,
[INSTR_HDR_EXTRACT6] = instr_hdr_extract6_exec,
[INSTR_HDR_EXTRACT7] = instr_hdr_extract7_exec,
[INSTR_HDR_EXTRACT8] = instr_hdr_extract8_exec,
[INSTR_HDR_EXTRACT_M] = instr_hdr_extract_m_exec,
[INSTR_HDR_LOOKAHEAD] = instr_hdr_lookahead_exec,
[INSTR_HDR_EMIT] = instr_hdr_emit_exec,
[INSTR_HDR_EMIT_TX] = instr_hdr_emit_tx_exec,
[INSTR_HDR_EMIT2_TX] = instr_hdr_emit2_tx_exec,
[INSTR_HDR_EMIT3_TX] = instr_hdr_emit3_tx_exec,
[INSTR_HDR_EMIT4_TX] = instr_hdr_emit4_tx_exec,
[INSTR_HDR_EMIT5_TX] = instr_hdr_emit5_tx_exec,
[INSTR_HDR_EMIT6_TX] = instr_hdr_emit6_tx_exec,
[INSTR_HDR_EMIT7_TX] = instr_hdr_emit7_tx_exec,
[INSTR_HDR_EMIT8_TX] = instr_hdr_emit8_tx_exec,
[INSTR_HDR_VALIDATE] = instr_hdr_validate_exec,
[INSTR_HDR_INVALIDATE] = instr_hdr_invalidate_exec,
[INSTR_MOV] = instr_mov_exec,
[INSTR_MOV_MH] = instr_mov_mh_exec,
[INSTR_MOV_HM] = instr_mov_hm_exec,
[INSTR_MOV_HH] = instr_mov_hh_exec,
[INSTR_MOV_I] = instr_mov_i_exec,
[INSTR_DMA_HT] = instr_dma_ht_exec,
[INSTR_DMA_HT2] = instr_dma_ht2_exec,
[INSTR_DMA_HT3] = instr_dma_ht3_exec,
[INSTR_DMA_HT4] = instr_dma_ht4_exec,
[INSTR_DMA_HT5] = instr_dma_ht5_exec,
[INSTR_DMA_HT6] = instr_dma_ht6_exec,
[INSTR_DMA_HT7] = instr_dma_ht7_exec,
[INSTR_DMA_HT8] = instr_dma_ht8_exec,
[INSTR_ALU_ADD] = instr_alu_add_exec,
[INSTR_ALU_ADD_MH] = instr_alu_add_mh_exec,
[INSTR_ALU_ADD_HM] = instr_alu_add_hm_exec,
[INSTR_ALU_ADD_HH] = instr_alu_add_hh_exec,
[INSTR_ALU_ADD_MI] = instr_alu_add_mi_exec,
[INSTR_ALU_ADD_HI] = instr_alu_add_hi_exec,
[INSTR_ALU_SUB] = instr_alu_sub_exec,
[INSTR_ALU_SUB_MH] = instr_alu_sub_mh_exec,
[INSTR_ALU_SUB_HM] = instr_alu_sub_hm_exec,
[INSTR_ALU_SUB_HH] = instr_alu_sub_hh_exec,
[INSTR_ALU_SUB_MI] = instr_alu_sub_mi_exec,
[INSTR_ALU_SUB_HI] = instr_alu_sub_hi_exec,
[INSTR_ALU_CKADD_FIELD] = instr_alu_ckadd_field_exec,
[INSTR_ALU_CKADD_STRUCT] = instr_alu_ckadd_struct_exec,
[INSTR_ALU_CKADD_STRUCT20] = instr_alu_ckadd_struct20_exec,
[INSTR_ALU_CKSUB_FIELD] = instr_alu_cksub_field_exec,
[INSTR_ALU_AND] = instr_alu_and_exec,
[INSTR_ALU_AND_MH] = instr_alu_and_mh_exec,
[INSTR_ALU_AND_HM] = instr_alu_and_hm_exec,
[INSTR_ALU_AND_HH] = instr_alu_and_hh_exec,
[INSTR_ALU_AND_I] = instr_alu_and_i_exec,
[INSTR_ALU_OR] = instr_alu_or_exec,
[INSTR_ALU_OR_MH] = instr_alu_or_mh_exec,
[INSTR_ALU_OR_HM] = instr_alu_or_hm_exec,
[INSTR_ALU_OR_HH] = instr_alu_or_hh_exec,
[INSTR_ALU_OR_I] = instr_alu_or_i_exec,
[INSTR_ALU_XOR] = instr_alu_xor_exec,
[INSTR_ALU_XOR_MH] = instr_alu_xor_mh_exec,
[INSTR_ALU_XOR_HM] = instr_alu_xor_hm_exec,
[INSTR_ALU_XOR_HH] = instr_alu_xor_hh_exec,
[INSTR_ALU_XOR_I] = instr_alu_xor_i_exec,
[INSTR_ALU_SHL] = instr_alu_shl_exec,
[INSTR_ALU_SHL_MH] = instr_alu_shl_mh_exec,
[INSTR_ALU_SHL_HM] = instr_alu_shl_hm_exec,
[INSTR_ALU_SHL_HH] = instr_alu_shl_hh_exec,
[INSTR_ALU_SHL_MI] = instr_alu_shl_mi_exec,
[INSTR_ALU_SHL_HI] = instr_alu_shl_hi_exec,
[INSTR_ALU_SHR] = instr_alu_shr_exec,
[INSTR_ALU_SHR_MH] = instr_alu_shr_mh_exec,
[INSTR_ALU_SHR_HM] = instr_alu_shr_hm_exec,
[INSTR_ALU_SHR_HH] = instr_alu_shr_hh_exec,
[INSTR_ALU_SHR_MI] = instr_alu_shr_mi_exec,
[INSTR_ALU_SHR_HI] = instr_alu_shr_hi_exec,
[INSTR_REGPREFETCH_RH] = instr_regprefetch_rh_exec,
[INSTR_REGPREFETCH_RM] = instr_regprefetch_rm_exec,
[INSTR_REGPREFETCH_RI] = instr_regprefetch_ri_exec,
[INSTR_REGRD_HRH] = instr_regrd_hrh_exec,
[INSTR_REGRD_HRM] = instr_regrd_hrm_exec,
[INSTR_REGRD_MRH] = instr_regrd_mrh_exec,
[INSTR_REGRD_MRM] = instr_regrd_mrm_exec,
[INSTR_REGRD_HRI] = instr_regrd_hri_exec,
[INSTR_REGRD_MRI] = instr_regrd_mri_exec,
[INSTR_REGWR_RHH] = instr_regwr_rhh_exec,
[INSTR_REGWR_RHM] = instr_regwr_rhm_exec,
[INSTR_REGWR_RMH] = instr_regwr_rmh_exec,
[INSTR_REGWR_RMM] = instr_regwr_rmm_exec,
[INSTR_REGWR_RHI] = instr_regwr_rhi_exec,
[INSTR_REGWR_RMI] = instr_regwr_rmi_exec,
[INSTR_REGWR_RIH] = instr_regwr_rih_exec,
[INSTR_REGWR_RIM] = instr_regwr_rim_exec,
[INSTR_REGWR_RII] = instr_regwr_rii_exec,
[INSTR_REGADD_RHH] = instr_regadd_rhh_exec,
[INSTR_REGADD_RHM] = instr_regadd_rhm_exec,
[INSTR_REGADD_RMH] = instr_regadd_rmh_exec,
[INSTR_REGADD_RMM] = instr_regadd_rmm_exec,
[INSTR_REGADD_RHI] = instr_regadd_rhi_exec,
[INSTR_REGADD_RMI] = instr_regadd_rmi_exec,
[INSTR_REGADD_RIH] = instr_regadd_rih_exec,
[INSTR_REGADD_RIM] = instr_regadd_rim_exec,
[INSTR_REGADD_RII] = instr_regadd_rii_exec,
[INSTR_METPREFETCH_H] = instr_metprefetch_h_exec,
[INSTR_METPREFETCH_M] = instr_metprefetch_m_exec,
[INSTR_METPREFETCH_I] = instr_metprefetch_i_exec,
[INSTR_METER_HHM] = instr_meter_hhm_exec,
[INSTR_METER_HHI] = instr_meter_hhi_exec,
[INSTR_METER_HMM] = instr_meter_hmm_exec,
[INSTR_METER_HMI] = instr_meter_hmi_exec,
[INSTR_METER_MHM] = instr_meter_mhm_exec,
[INSTR_METER_MHI] = instr_meter_mhi_exec,
[INSTR_METER_MMM] = instr_meter_mmm_exec,
[INSTR_METER_MMI] = instr_meter_mmi_exec,
[INSTR_METER_IHM] = instr_meter_ihm_exec,
[INSTR_METER_IHI] = instr_meter_ihi_exec,
[INSTR_METER_IMM] = instr_meter_imm_exec,
[INSTR_METER_IMI] = instr_meter_imi_exec,
[INSTR_TABLE] = instr_table_exec,
[INSTR_TABLE_AF] = instr_table_af_exec,
[INSTR_SELECTOR] = instr_selector_exec,
[INSTR_LEARNER] = instr_learner_exec,
[INSTR_LEARNER_AF] = instr_learner_af_exec,
[INSTR_LEARNER_LEARN] = instr_learn_exec,
[INSTR_LEARNER_FORGET] = instr_forget_exec,
[INSTR_EXTERN_OBJ] = instr_extern_obj_exec,
[INSTR_EXTERN_FUNC] = instr_extern_func_exec,
[INSTR_JMP] = instr_jmp_exec,
[INSTR_JMP_VALID] = instr_jmp_valid_exec,
[INSTR_JMP_INVALID] = instr_jmp_invalid_exec,
[INSTR_JMP_HIT] = instr_jmp_hit_exec,
[INSTR_JMP_MISS] = instr_jmp_miss_exec,
[INSTR_JMP_ACTION_HIT] = instr_jmp_action_hit_exec,
[INSTR_JMP_ACTION_MISS] = instr_jmp_action_miss_exec,
[INSTR_JMP_EQ] = instr_jmp_eq_exec,
[INSTR_JMP_EQ_MH] = instr_jmp_eq_mh_exec,
[INSTR_JMP_EQ_HM] = instr_jmp_eq_hm_exec,
[INSTR_JMP_EQ_HH] = instr_jmp_eq_hh_exec,
[INSTR_JMP_EQ_I] = instr_jmp_eq_i_exec,
[INSTR_JMP_NEQ] = instr_jmp_neq_exec,
[INSTR_JMP_NEQ_MH] = instr_jmp_neq_mh_exec,
[INSTR_JMP_NEQ_HM] = instr_jmp_neq_hm_exec,
[INSTR_JMP_NEQ_HH] = instr_jmp_neq_hh_exec,
[INSTR_JMP_NEQ_I] = instr_jmp_neq_i_exec,
[INSTR_JMP_LT] = instr_jmp_lt_exec,
[INSTR_JMP_LT_MH] = instr_jmp_lt_mh_exec,
[INSTR_JMP_LT_HM] = instr_jmp_lt_hm_exec,
[INSTR_JMP_LT_HH] = instr_jmp_lt_hh_exec,
[INSTR_JMP_LT_MI] = instr_jmp_lt_mi_exec,
[INSTR_JMP_LT_HI] = instr_jmp_lt_hi_exec,
[INSTR_JMP_GT] = instr_jmp_gt_exec,
[INSTR_JMP_GT_MH] = instr_jmp_gt_mh_exec,
[INSTR_JMP_GT_HM] = instr_jmp_gt_hm_exec,
[INSTR_JMP_GT_HH] = instr_jmp_gt_hh_exec,
[INSTR_JMP_GT_MI] = instr_jmp_gt_mi_exec,
[INSTR_JMP_GT_HI] = instr_jmp_gt_hi_exec,
[INSTR_RETURN] = instr_return_exec,
};
static int
instruction_table_build(struct rte_swx_pipeline *p)
{
p->instruction_table = calloc(RTE_SWX_PIPELINE_INSTRUCTION_TABLE_SIZE_MAX,
sizeof(struct instr_exec_t *));
if (!p->instruction_table)
return -EINVAL;
memcpy(p->instruction_table, instruction_table, sizeof(instruction_table));
return 0;
}
static void
instruction_table_build_free(struct rte_swx_pipeline *p)
{
if (!p->instruction_table)
return;
free(p->instruction_table);
p->instruction_table = NULL;
}
static void
instruction_table_free(struct rte_swx_pipeline *p)
{
instruction_table_build_free(p);
}
static inline void
instr_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
instr_exec_t instr = p->instruction_table[ip->type];
instr(p);
}
/*
* Action.
*/
static struct action *
action_find(struct rte_swx_pipeline *p, const char *name)
{
struct action *elem;
if (!name)
return NULL;
TAILQ_FOREACH(elem, &p->actions, node)
if (strcmp(elem->name, name) == 0)
return elem;
return NULL;
}
static struct action *
action_find_by_id(struct rte_swx_pipeline *p, uint32_t id)
{
struct action *action = NULL;
TAILQ_FOREACH(action, &p->actions, node)
if (action->id == id)
return action;
return NULL;
}
static struct field *
action_field_find(struct action *a, const char *name)
{
return a->st ? struct_type_field_find(a->st, name) : NULL;
}
static struct field *
action_field_parse(struct action *action, const char *name)
{
if (name[0] != 't' || name[1] != '.')
return NULL;
return action_field_find(action, &name[2]);
}
static int
action_has_nbo_args(struct action *a)
{
uint32_t i;
/* Return if the action does not have any args. */
if (!a->st)
return 0; /* FALSE */
for (i = 0; i < a->st->n_fields; i++)
if (a->args_endianness[i])
return 1; /* TRUE */
return 0; /* FALSE */
}
static int
action_does_learning(struct action *a)
{
uint32_t i;
for (i = 0; i < a->n_instructions; i++)
switch (a->instructions[i].type) {
case INSTR_LEARNER_LEARN:
return 1; /* TRUE */
case INSTR_LEARNER_FORGET:
return 1; /* TRUE */
default:
continue;
}
return 0; /* FALSE */
}
int
rte_swx_pipeline_action_config(struct rte_swx_pipeline *p,
const char *name,
const char *args_struct_type_name,
const char **instructions,
uint32_t n_instructions)
{
struct struct_type *args_struct_type = NULL;
struct action *a;
int err;
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK(!action_find(p, name), EEXIST);
if (args_struct_type_name) {
CHECK_NAME(args_struct_type_name, EINVAL);
args_struct_type = struct_type_find(p, args_struct_type_name);
CHECK(args_struct_type, EINVAL);
CHECK(!args_struct_type->var_size, EINVAL);
}
/* Node allocation. */
a = calloc(1, sizeof(struct action));
CHECK(a, ENOMEM);
if (args_struct_type) {
a->args_endianness = calloc(args_struct_type->n_fields, sizeof(int));
if (!a->args_endianness) {
free(a);
CHECK(0, ENOMEM);
}
}
/* Node initialization. */
strcpy(a->name, name);
a->st = args_struct_type;
a->id = p->n_actions;
/* Instruction translation. */
err = instruction_config(p, a, instructions, n_instructions);
if (err) {
free(a->args_endianness);
free(a);
return err;
}
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->actions, a, node);
p->n_actions++;
return 0;
}
static int
action_build(struct rte_swx_pipeline *p)
{
struct action *action;
/* p->action_instructions. */
p->action_instructions = calloc(p->n_actions, sizeof(struct instruction *));
CHECK(p->action_instructions, ENOMEM);
TAILQ_FOREACH(action, &p->actions, node)
p->action_instructions[action->id] = action->instructions;
/* p->action_funcs. */
p->action_funcs = calloc(p->n_actions, sizeof(action_func_t));
CHECK(p->action_funcs, ENOMEM);
return 0;
}
static void
action_build_free(struct rte_swx_pipeline *p)
{
free(p->action_funcs);
p->action_funcs = NULL;
free(p->action_instructions);
p->action_instructions = NULL;
}
static void
action_free(struct rte_swx_pipeline *p)
{
action_build_free(p);
for ( ; ; ) {
struct action *action;
action = TAILQ_FIRST(&p->actions);
if (!action)
break;
TAILQ_REMOVE(&p->actions, action, node);
free(action->instruction_data);
free(action->instructions);
free(action);
}
}
static uint32_t
action_arg_src_mov_count(struct action *a,
uint32_t arg_id,
struct instruction *instructions,
struct instruction_data *instruction_data,
uint32_t n_instructions)
{
uint32_t offset, n_users = 0, i;
if (!a->st ||
(arg_id >= a->st->n_fields) ||
!instructions ||
!instruction_data ||
!n_instructions)
return 0;
offset = a->st->fields[arg_id].offset / 8;
for (i = 0; i < n_instructions; i++) {
struct instruction *instr = &instructions[i];
struct instruction_data *data = &instruction_data[i];
if (data->invalid ||
((instr->type != INSTR_MOV) && (instr->type != INSTR_MOV_HM)) ||
instr->mov.src.struct_id ||
(instr->mov.src.offset != offset))
continue;
n_users++;
}
return n_users;
}
/*
* Table.
*/
static struct table_type *
table_type_find(struct rte_swx_pipeline *p, const char *name)
{
struct table_type *elem;
TAILQ_FOREACH(elem, &p->table_types, node)
if (strcmp(elem->name, name) == 0)
return elem;
return NULL;
}
static struct table_type *
table_type_resolve(struct rte_swx_pipeline *p,
const char *recommended_type_name,
enum rte_swx_table_match_type match_type)
{
struct table_type *elem;
/* Only consider the recommended type if the match type is correct. */
if (recommended_type_name)
TAILQ_FOREACH(elem, &p->table_types, node)
if (!strcmp(elem->name, recommended_type_name) &&
(elem->match_type == match_type))
return elem;
/* Ignore the recommended type and get the first element with this match
* type.
*/
TAILQ_FOREACH(elem, &p->table_types, node)
if (elem->match_type == match_type)
return elem;
return NULL;
}
static struct table *
table_find(struct rte_swx_pipeline *p, const char *name)
{
struct table *elem;
TAILQ_FOREACH(elem, &p->tables, node)
if (strcmp(elem->name, name) == 0)
return elem;
return NULL;
}
static struct table *
table_find_by_id(struct rte_swx_pipeline *p, uint32_t id)
{
struct table *table = NULL;
TAILQ_FOREACH(table, &p->tables, node)
if (table->id == id)
return table;
return NULL;
}
int
rte_swx_pipeline_table_type_register(struct rte_swx_pipeline *p,
const char *name,
enum rte_swx_table_match_type match_type,
struct rte_swx_table_ops *ops)
{
struct table_type *elem;
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK(!table_type_find(p, name), EEXIST);
CHECK(ops, EINVAL);
CHECK(ops->create, EINVAL);
CHECK(ops->lkp, EINVAL);
CHECK(ops->free, EINVAL);
/* Node allocation. */
elem = calloc(1, sizeof(struct table_type));
CHECK(elem, ENOMEM);
/* Node initialization. */
strcpy(elem->name, name);
elem->match_type = match_type;
memcpy(&elem->ops, ops, sizeof(*ops));
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->table_types, elem, node);
return 0;
}
static int
table_match_type_resolve(struct rte_swx_match_field_params *fields,
uint32_t n_fields,
enum rte_swx_table_match_type *match_type)
{
uint32_t n_fields_em = 0, n_fields_lpm = 0, i;
for (i = 0; i < n_fields; i++) {
struct rte_swx_match_field_params *f = &fields[i];
if (f->match_type == RTE_SWX_TABLE_MATCH_EXACT)
n_fields_em++;
if (f->match_type == RTE_SWX_TABLE_MATCH_LPM)
n_fields_lpm++;
}
if ((n_fields_lpm > 1) ||
(n_fields_lpm && (n_fields_em != n_fields - 1)))
return -EINVAL;
*match_type = (n_fields_em == n_fields) ?
RTE_SWX_TABLE_MATCH_EXACT :
RTE_SWX_TABLE_MATCH_WILDCARD;
return 0;
}
static int
table_match_fields_check(struct rte_swx_pipeline *p,
struct rte_swx_pipeline_table_params *params,
struct header **header)
{
struct header *h0 = NULL;
struct field *hf, *mf;
uint32_t *offset = NULL, i;
int status = 0;
/* Return if no match fields. */
if (!params->n_fields) {
if (params->fields) {
status = -EINVAL;
goto end;
}
if (header)
*header = NULL;
return 0;
}
/* Memory allocation. */
offset = calloc(params->n_fields, sizeof(uint32_t));
if (!offset) {
status = -ENOMEM;
goto end;
}
/* Check that all the match fields belong to either the same header or
* to the meta-data.
*/
hf = header_field_parse(p, params->fields[0].name, &h0);
mf = metadata_field_parse(p, params->fields[0].name);
if ((!hf && !mf) || (hf && hf->var_size)) {
status = -EINVAL;
goto end;
}
offset[0] = h0 ? hf->offset : mf->offset;
for (i = 1; i < params->n_fields; i++)
if (h0) {
struct header *h;
hf = header_field_parse(p, params->fields[i].name, &h);
if (!hf || (h->id != h0->id) || hf->var_size) {
status = -EINVAL;
goto end;
}
offset[i] = hf->offset;
} else {
mf = metadata_field_parse(p, params->fields[i].name);
if (!mf) {
status = -EINVAL;
goto end;
}
offset[i] = mf->offset;
}
/* Check that there are no duplicated match fields. */
for (i = 0; i < params->n_fields; i++) {
uint32_t j;
for (j = 0; j < i; j++)
if (offset[j] == offset[i]) {
status = -EINVAL;
goto end;
}
}
/* Return. */
if (header)
*header = h0;
end:
free(offset);
return status;
}
int
rte_swx_pipeline_table_config(struct rte_swx_pipeline *p,
const char *name,
struct rte_swx_pipeline_table_params *params,
const char *recommended_table_type_name,
const char *args,
uint32_t size)
{
struct table_type *type;
struct table *t = NULL;
struct action *default_action;
struct header *header = NULL;
uint32_t action_data_size_max = 0, i;
int status = 0;
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK(!table_find(p, name), EEXIST);
CHECK(!selector_find(p, name), EEXIST);
CHECK(!learner_find(p, name), EEXIST);
CHECK(params, EINVAL);
/* Match checks. */
status = table_match_fields_check(p, params, &header);
if (status)
return status;
/* Action checks. */
CHECK(params->n_actions, EINVAL);
CHECK(params->action_names, EINVAL);
for (i = 0; i < params->n_actions; i++) {
const char *action_name = params->action_names[i];
struct action *a;
uint32_t action_data_size;
int action_is_for_table_entries = 1, action_is_for_default_entry = 1;
CHECK_NAME(action_name, EINVAL);
a = action_find(p, action_name);
CHECK(a, EINVAL);
CHECK(!action_does_learning(a), EINVAL);
action_data_size = a->st ? a->st->n_bits / 8 : 0;
if (action_data_size > action_data_size_max)
action_data_size_max = action_data_size;
if (params->action_is_for_table_entries)
action_is_for_table_entries = params->action_is_for_table_entries[i];
if (params->action_is_for_default_entry)
action_is_for_default_entry = params->action_is_for_default_entry[i];
CHECK(action_is_for_table_entries || action_is_for_default_entry, EINVAL);
}
CHECK_NAME(params->default_action_name, EINVAL);
for (i = 0; i < p->n_actions; i++)
if (!strcmp(params->action_names[i],
params->default_action_name))
break;
CHECK(i < params->n_actions, EINVAL);
CHECK(!params->action_is_for_default_entry || params->action_is_for_default_entry[i],
EINVAL);
default_action = action_find(p, params->default_action_name);
CHECK((default_action->st && params->default_action_data) ||
!params->default_action_data, EINVAL);
/* Table type checks. */
if (recommended_table_type_name)
CHECK_NAME(recommended_table_type_name, EINVAL);
if (params->n_fields) {
enum rte_swx_table_match_type match_type;
status = table_match_type_resolve(params->fields, params->n_fields, &match_type);
if (status)
return status;
type = table_type_resolve(p, recommended_table_type_name, match_type);
CHECK(type, EINVAL);
} else {
type = NULL;
}
/* Memory allocation. */
t = calloc(1, sizeof(struct table));
if (!t)
goto nomem;
t->fields = calloc(params->n_fields, sizeof(struct match_field));
if (!t->fields)
goto nomem;
t->actions = calloc(params->n_actions, sizeof(struct action *));
if (!t->actions)
goto nomem;
if (action_data_size_max) {
t->default_action_data = calloc(1, action_data_size_max);
if (!t->default_action_data)
goto nomem;
}
t->action_is_for_table_entries = calloc(params->n_actions, sizeof(int));
if (!t->action_is_for_table_entries)
goto nomem;
t->action_is_for_default_entry = calloc(params->n_actions, sizeof(int));
if (!t->action_is_for_default_entry)
goto nomem;
/* Node initialization. */
strcpy(t->name, name);
if (args && args[0])
strcpy(t->args, args);
t->type = type;
for (i = 0; i < params->n_fields; i++) {
struct rte_swx_match_field_params *field = &params->fields[i];
struct match_field *f = &t->fields[i];
f->match_type = field->match_type;
f->field = header ?
header_field_parse(p, field->name, NULL) :
metadata_field_parse(p, field->name);
}
t->n_fields = params->n_fields;
t->header = header;
for (i = 0; i < params->n_actions; i++) {
int action_is_for_table_entries = 1, action_is_for_default_entry = 1;
if (params->action_is_for_table_entries)
action_is_for_table_entries = params->action_is_for_table_entries[i];
if (params->action_is_for_default_entry)
action_is_for_default_entry = params->action_is_for_default_entry[i];
t->actions[i] = action_find(p, params->action_names[i]);
t->action_is_for_table_entries[i] = action_is_for_table_entries;
t->action_is_for_default_entry[i] = action_is_for_default_entry;
}
t->default_action = default_action;
if (default_action->st)
memcpy(t->default_action_data,
params->default_action_data,
default_action->st->n_bits / 8);
t->n_actions = params->n_actions;
t->default_action_is_const = params->default_action_is_const;
t->action_data_size_max = action_data_size_max;
t->size = size;
t->id = p->n_tables;
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->tables, t, node);
p->n_tables++;
return 0;
nomem:
if (!t)
return -ENOMEM;
free(t->action_is_for_default_entry);
free(t->action_is_for_table_entries);
free(t->default_action_data);
free(t->actions);
free(t->fields);
free(t);
return -ENOMEM;
}
static struct rte_swx_table_params *
table_params_get(struct table *table)
{
struct rte_swx_table_params *params;
struct field *first, *last;
uint8_t *key_mask;
uint32_t key_size, key_offset, action_data_size, i;
/* Memory allocation. */
params = calloc(1, sizeof(struct rte_swx_table_params));
if (!params)
return NULL;
/* Find first (smallest offset) and last (biggest offset) match fields. */
first = table->fields[0].field;
last = table->fields[0].field;
for (i = 0; i < table->n_fields; i++) {
struct field *f = table->fields[i].field;
if (f->offset < first->offset)
first = f;
if (f->offset > last->offset)
last = f;
}
/* Key offset and size. */
key_offset = first->offset / 8;
key_size = (last->offset + last->n_bits - first->offset) / 8;
/* Memory allocation. */
key_mask = calloc(1, key_size);
if (!key_mask) {
free(params);
return NULL;
}
/* Key mask. */
for (i = 0; i < table->n_fields; i++) {
struct field *f = table->fields[i].field;
uint32_t start = (f->offset - first->offset) / 8;
size_t size = f->n_bits / 8;
memset(&key_mask[start], 0xFF, size);
}
/* Action data size. */
action_data_size = 0;
for (i = 0; i < table->n_actions; i++) {
struct action *action = table->actions[i];
uint32_t ads = action->st ? action->st->n_bits / 8 : 0;
if (ads > action_data_size)
action_data_size = ads;
}
/* Fill in. */
params->match_type = table->type->match_type;
params->key_size = key_size;
params->key_offset = key_offset;
params->key_mask0 = key_mask;
params->action_data_size = action_data_size;
params->n_keys_max = table->size;
return params;
}
static void
table_params_free(struct rte_swx_table_params *params)
{
if (!params)
return;
free(params->key_mask0);
free(params);
}
static int
table_stub_lkp(void *table __rte_unused,
void *mailbox __rte_unused,
uint8_t **key __rte_unused,
uint64_t *action_id __rte_unused,
uint8_t **action_data __rte_unused,
int *hit)
{
*hit = 0;
return 1; /* DONE. */
}
static int
table_build(struct rte_swx_pipeline *p)
{
uint32_t i;
/* Per pipeline: table statistics. */
p->table_stats = calloc(p->n_tables, sizeof(struct table_statistics));
CHECK(p->table_stats, ENOMEM);
for (i = 0; i < p->n_tables; i++) {
p->table_stats[i].n_pkts_action = calloc(p->n_actions, sizeof(uint64_t));
CHECK(p->table_stats[i].n_pkts_action, ENOMEM);
}
/* Per thread: table runt-time. */
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
struct table *table;
t->tables = calloc(p->n_tables, sizeof(struct table_runtime));
CHECK(t->tables, ENOMEM);
TAILQ_FOREACH(table, &p->tables, node) {
struct table_runtime *r = &t->tables[table->id];
if (table->type) {
uint64_t size;
size = table->type->ops.mailbox_size_get();
/* r->func. */
r->func = table->type->ops.lkp;
/* r->mailbox. */
if (size) {
r->mailbox = calloc(1, size);
CHECK(r->mailbox, ENOMEM);
}
/* r->key. */
r->key = table->header ?
&t->structs[table->header->struct_id] :
&t->structs[p->metadata_struct_id];
} else {
r->func = table_stub_lkp;
}
}
}
return 0;
}
static void
table_build_free(struct rte_swx_pipeline *p)
{
uint32_t i;
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
uint32_t j;
if (!t->tables)
continue;
for (j = 0; j < p->n_tables; j++) {
struct table_runtime *r = &t->tables[j];
free(r->mailbox);
}
free(t->tables);
t->tables = NULL;
}
if (p->table_stats) {
for (i = 0; i < p->n_tables; i++)
free(p->table_stats[i].n_pkts_action);
free(p->table_stats);
}
}
static void
table_free(struct rte_swx_pipeline *p)
{
table_build_free(p);
/* Tables. */
for ( ; ; ) {
struct table *elem;
elem = TAILQ_FIRST(&p->tables);
if (!elem)
break;
TAILQ_REMOVE(&p->tables, elem, node);
free(elem->fields);
free(elem->actions);
free(elem->default_action_data);
free(elem);
}
/* Table types. */
for ( ; ; ) {
struct table_type *elem;
elem = TAILQ_FIRST(&p->table_types);
if (!elem)
break;
TAILQ_REMOVE(&p->table_types, elem, node);
free(elem);
}
}
/*
* Selector.
*/
static struct selector *
selector_find(struct rte_swx_pipeline *p, const char *name)
{
struct selector *s;
TAILQ_FOREACH(s, &p->selectors, node)
if (strcmp(s->name, name) == 0)
return s;
return NULL;
}
static struct selector *
selector_find_by_id(struct rte_swx_pipeline *p, uint32_t id)
{
struct selector *s = NULL;
TAILQ_FOREACH(s, &p->selectors, node)
if (s->id == id)
return s;
return NULL;
}
static int
selector_fields_check(struct rte_swx_pipeline *p,
struct rte_swx_pipeline_selector_params *params,
struct header **header)
{
struct header *h0 = NULL;
struct field *hf, *mf;
uint32_t i;
/* Return if no selector fields. */
if (!params->n_selector_fields || !params->selector_field_names)
return -EINVAL;
/* Check that all the selector fields either belong to the same header
* or are all meta-data fields.
*/
hf = header_field_parse(p, params->selector_field_names[0], &h0);
mf = metadata_field_parse(p, params->selector_field_names[0]);
if (!hf && !mf)
return -EINVAL;
for (i = 1; i < params->n_selector_fields; i++)
if (h0) {
struct header *h;
hf = header_field_parse(p, params->selector_field_names[i], &h);
if (!hf || (h->id != h0->id))
return -EINVAL;
} else {
mf = metadata_field_parse(p, params->selector_field_names[i]);
if (!mf)
return -EINVAL;
}
/* Check that there are no duplicated match fields. */
for (i = 0; i < params->n_selector_fields; i++) {
const char *field_name = params->selector_field_names[i];
uint32_t j;
for (j = i + 1; j < params->n_selector_fields; j++)
if (!strcmp(params->selector_field_names[j], field_name))
return -EINVAL;
}
/* Return. */
if (header)
*header = h0;
return 0;
}
int
rte_swx_pipeline_selector_config(struct rte_swx_pipeline *p,
const char *name,
struct rte_swx_pipeline_selector_params *params)
{
struct selector *s;
struct header *selector_header = NULL;
struct field *group_id_field, *member_id_field;
uint32_t i;
int status = 0;
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK(!table_find(p, name), EEXIST);
CHECK(!selector_find(p, name), EEXIST);
CHECK(!learner_find(p, name), EEXIST);
CHECK(params, EINVAL);
CHECK_NAME(params->group_id_field_name, EINVAL);
group_id_field = metadata_field_parse(p, params->group_id_field_name);
CHECK(group_id_field, EINVAL);
for (i = 0; i < params->n_selector_fields; i++) {
const char *field_name = params->selector_field_names[i];
CHECK_NAME(field_name, EINVAL);
}
status = selector_fields_check(p, params, &selector_header);
if (status)
return status;
CHECK_NAME(params->member_id_field_name, EINVAL);
member_id_field = metadata_field_parse(p, params->member_id_field_name);
CHECK(member_id_field, EINVAL);
CHECK(params->n_groups_max, EINVAL);
CHECK(params->n_members_per_group_max, EINVAL);
/* Memory allocation. */
s = calloc(1, sizeof(struct selector));
if (!s) {
status = -ENOMEM;
goto error;
}
s->selector_fields = calloc(params->n_selector_fields, sizeof(struct field *));
if (!s->selector_fields) {
status = -ENOMEM;
goto error;
}
/* Node initialization. */
strcpy(s->name, name);
s->group_id_field = group_id_field;
for (i = 0; i < params->n_selector_fields; i++) {
const char *field_name = params->selector_field_names[i];
s->selector_fields[i] = selector_header ?
header_field_parse(p, field_name, NULL) :
metadata_field_parse(p, field_name);
}
s->n_selector_fields = params->n_selector_fields;
s->selector_header = selector_header;
s->member_id_field = member_id_field;
s->n_groups_max = params->n_groups_max;
s->n_members_per_group_max = params->n_members_per_group_max;
s->id = p->n_selectors;
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->selectors, s, node);
p->n_selectors++;
return 0;
error:
if (!s)
return status;
free(s->selector_fields);
free(s);
return status;
}
static void
selector_params_free(struct rte_swx_table_selector_params *params)
{
if (!params)
return;
free(params->selector_mask);
free(params);
}
static struct rte_swx_table_selector_params *
selector_table_params_get(struct selector *s)
{
struct rte_swx_table_selector_params *params = NULL;
struct field *first, *last;
uint32_t i;
/* Memory allocation. */
params = calloc(1, sizeof(struct rte_swx_table_selector_params));
if (!params)
goto error;
/* Group ID. */
params->group_id_offset = s->group_id_field->offset / 8;
/* Find first (smallest offset) and last (biggest offset) selector fields. */
first = s->selector_fields[0];
last = s->selector_fields[0];
for (i = 0; i < s->n_selector_fields; i++) {
struct field *f = s->selector_fields[i];
if (f->offset < first->offset)
first = f;
if (f->offset > last->offset)
last = f;
}
/* Selector offset and size. */
params->selector_offset = first->offset / 8;
params->selector_size = (last->offset + last->n_bits - first->offset) / 8;
/* Memory allocation. */
params->selector_mask = calloc(1, params->selector_size);
if (!params->selector_mask)
goto error;
/* Selector mask. */
for (i = 0; i < s->n_selector_fields; i++) {
struct field *f = s->selector_fields[i];
uint32_t start = (f->offset - first->offset) / 8;
size_t size = f->n_bits / 8;
memset(&params->selector_mask[start], 0xFF, size);
}
/* Member ID. */
params->member_id_offset = s->member_id_field->offset / 8;
/* Maximum number of groups. */
params->n_groups_max = s->n_groups_max;
/* Maximum number of members per group. */
params->n_members_per_group_max = s->n_members_per_group_max;
return params;
error:
selector_params_free(params);
return NULL;
}
static void
selector_build_free(struct rte_swx_pipeline *p)
{
uint32_t i;
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
uint32_t j;
if (!t->selectors)
continue;
for (j = 0; j < p->n_selectors; j++) {
struct selector_runtime *r = &t->selectors[j];
free(r->mailbox);
}
free(t->selectors);
t->selectors = NULL;
}
free(p->selector_stats);
p->selector_stats = NULL;
}
static int
selector_build(struct rte_swx_pipeline *p)
{
uint32_t i;
int status = 0;
/* Per pipeline: selector statistics. */
p->selector_stats = calloc(p->n_selectors, sizeof(struct selector_statistics));
if (!p->selector_stats) {
status = -ENOMEM;
goto error;
}
/* Per thread: selector run-time. */
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
struct selector *s;
t->selectors = calloc(p->n_selectors, sizeof(struct selector_runtime));
if (!t->selectors) {
status = -ENOMEM;
goto error;
}
TAILQ_FOREACH(s, &p->selectors, node) {
struct selector_runtime *r = &t->selectors[s->id];
uint64_t size;
/* r->mailbox. */
size = rte_swx_table_selector_mailbox_size_get();
if (size) {
r->mailbox = calloc(1, size);
if (!r->mailbox) {
status = -ENOMEM;
goto error;
}
}
/* r->group_id_buffer. */
r->group_id_buffer = &t->structs[p->metadata_struct_id];
/* r->selector_buffer. */
r->selector_buffer = s->selector_header ?
&t->structs[s->selector_header->struct_id] :
&t->structs[p->metadata_struct_id];
/* r->member_id_buffer. */
r->member_id_buffer = &t->structs[p->metadata_struct_id];
}
}
return 0;
error:
selector_build_free(p);
return status;
}
static void
selector_free(struct rte_swx_pipeline *p)
{
selector_build_free(p);
/* Selector tables. */
for ( ; ; ) {
struct selector *elem;
elem = TAILQ_FIRST(&p->selectors);
if (!elem)
break;
TAILQ_REMOVE(&p->selectors, elem, node);
free(elem->selector_fields);
free(elem);
}
}
/*
* Learner table.
*/
static struct learner *
learner_find(struct rte_swx_pipeline *p, const char *name)
{
struct learner *l;
TAILQ_FOREACH(l, &p->learners, node)
if (!strcmp(l->name, name))
return l;
return NULL;
}
static struct learner *
learner_find_by_id(struct rte_swx_pipeline *p, uint32_t id)
{
struct learner *l = NULL;
TAILQ_FOREACH(l, &p->learners, node)
if (l->id == id)
return l;
return NULL;
}
static int
learner_match_fields_check(struct rte_swx_pipeline *p,
struct rte_swx_pipeline_learner_params *params,
struct header **header)
{
struct header *h0 = NULL;
struct field *hf, *mf;
uint32_t i;
/* Return if no match fields. */
if (!params->n_fields || !params->field_names)
return -EINVAL;
/* Check that all the match fields either belong to the same header
* or are all meta-data fields.
*/
hf = header_field_parse(p, params->field_names[0], &h0);
mf = metadata_field_parse(p, params->field_names[0]);
if (!hf && !mf)
return -EINVAL;
for (i = 1; i < params->n_fields; i++)
if (h0) {
struct header *h;
hf = header_field_parse(p, params->field_names[i], &h);
if (!hf || (h->id != h0->id))
return -EINVAL;
} else {
mf = metadata_field_parse(p, params->field_names[i]);
if (!mf)
return -EINVAL;
}
/* Check that there are no duplicated match fields. */
for (i = 0; i < params->n_fields; i++) {
const char *field_name = params->field_names[i];
uint32_t j;
for (j = i + 1; j < params->n_fields; j++)
if (!strcmp(params->field_names[j], field_name))
return -EINVAL;
}
/* Return. */
if (header)
*header = h0;
return 0;
}
static int
learner_action_args_check(struct rte_swx_pipeline *p, struct action *a, const char *mf_name)
{
struct struct_type *mst = p->metadata_st, *ast = a->st;
struct field *mf, *af;
uint32_t mf_pos, i;
if (!ast) {
if (mf_name)
return -EINVAL;
return 0;
}
/* Check that mf_name is the name of a valid meta-data field. */
CHECK_NAME(mf_name, EINVAL);
mf = metadata_field_parse(p, mf_name);
CHECK(mf, EINVAL);
/* Check that there are enough meta-data fields, starting with the mf_name field, to cover
* all the action arguments.
*/
mf_pos = mf - mst->fields;
CHECK(mst->n_fields - mf_pos >= ast->n_fields, EINVAL);
/* Check that the size of each of the identified meta-data fields matches exactly the size
* of the corresponding action argument.
*/
for (i = 0; i < ast->n_fields; i++) {
mf = &mst->fields[mf_pos + i];
af = &ast->fields[i];
CHECK(mf->n_bits == af->n_bits, EINVAL);
}
return 0;
}
static int
learner_action_learning_check(struct rte_swx_pipeline *p,
struct action *action,
const char **action_names,
uint32_t n_actions)
{
uint32_t i;
/* For each "learn" instruction of the current action, check that the learned action (i.e.
* the action passed as argument to the "learn" instruction) is also enabled for the
* current learner table.
*/
for (i = 0; i < action->n_instructions; i++) {
struct instruction *instr = &action->instructions[i];
uint32_t found = 0, j;
if (instr->type != INSTR_LEARNER_LEARN)
continue;
for (j = 0; j < n_actions; j++) {
struct action *a;
a = action_find(p, action_names[j]);
if (!a)
return -EINVAL;
if (a->id == instr->learn.action_id)
found = 1;
}
if (!found)
return -EINVAL;
}
return 0;
}
int
rte_swx_pipeline_learner_config(struct rte_swx_pipeline *p,
const char *name,
struct rte_swx_pipeline_learner_params *params,
uint32_t size,
uint32_t timeout)
{
struct learner *l = NULL;
struct action *default_action;
struct header *header = NULL;
uint32_t action_data_size_max = 0, i;
int status = 0;
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK(!table_find(p, name), EEXIST);
CHECK(!selector_find(p, name), EEXIST);
CHECK(!learner_find(p, name), EEXIST);
CHECK(params, EINVAL);
/* Match checks. */
status = learner_match_fields_check(p, params, &header);
if (status)
return status;
/* Action checks. */
CHECK(params->n_actions, EINVAL);
CHECK(params->action_names, EINVAL);
for (i = 0; i < params->n_actions; i++) {
const char *action_name = params->action_names[i];
struct action *a;
uint32_t action_data_size;
int action_is_for_table_entries = 1, action_is_for_default_entry = 1;
CHECK_NAME(action_name, EINVAL);
a = action_find(p, action_name);
CHECK(a, EINVAL);
status = learner_action_learning_check(p,
a,
params->action_names,
params->n_actions);
if (status)
return status;
action_data_size = a->st ? a->st->n_bits / 8 : 0;
if (action_data_size > action_data_size_max)
action_data_size_max = action_data_size;
if (params->action_is_for_table_entries)
action_is_for_table_entries = params->action_is_for_table_entries[i];
if (params->action_is_for_default_entry)
action_is_for_default_entry = params->action_is_for_default_entry[i];
CHECK(action_is_for_table_entries || action_is_for_default_entry, EINVAL);
}
CHECK_NAME(params->default_action_name, EINVAL);
for (i = 0; i < p->n_actions; i++)
if (!strcmp(params->action_names[i],
params->default_action_name))
break;
CHECK(i < params->n_actions, EINVAL);
CHECK(!params->action_is_for_default_entry || params->action_is_for_default_entry[i],
EINVAL);
default_action = action_find(p, params->default_action_name);
CHECK((default_action->st && params->default_action_data) ||
!params->default_action_data, EINVAL);
/* Any other checks. */
CHECK(size, EINVAL);
CHECK(timeout, EINVAL);
/* Memory allocation. */
l = calloc(1, sizeof(struct learner));
if (!l)
goto nomem;
l->fields = calloc(params->n_fields, sizeof(struct field *));
if (!l->fields)
goto nomem;
l->actions = calloc(params->n_actions, sizeof(struct action *));
if (!l->actions)
goto nomem;
if (action_data_size_max) {
l->default_action_data = calloc(1, action_data_size_max);
if (!l->default_action_data)
goto nomem;
}
l->action_is_for_table_entries = calloc(params->n_actions, sizeof(int));
if (!l->action_is_for_table_entries)
goto nomem;
l->action_is_for_default_entry = calloc(params->n_actions, sizeof(int));
if (!l->action_is_for_default_entry)
goto nomem;
/* Node initialization. */
strcpy(l->name, name);
for (i = 0; i < params->n_fields; i++) {
const char *field_name = params->field_names[i];
l->fields[i] = header ?
header_field_parse(p, field_name, NULL) :
metadata_field_parse(p, field_name);
}
l->n_fields = params->n_fields;
l->header = header;
for (i = 0; i < params->n_actions; i++) {
int action_is_for_table_entries = 1, action_is_for_default_entry = 1;
if (params->action_is_for_table_entries)
action_is_for_table_entries = params->action_is_for_table_entries[i];
if (params->action_is_for_default_entry)
action_is_for_default_entry = params->action_is_for_default_entry[i];
l->actions[i] = action_find(p, params->action_names[i]);
l->action_is_for_table_entries[i] = action_is_for_table_entries;
l->action_is_for_default_entry[i] = action_is_for_default_entry;
}
l->default_action = default_action;
if (default_action->st)
memcpy(l->default_action_data,
params->default_action_data,
default_action->st->n_bits / 8);
l->n_actions = params->n_actions;
l->default_action_is_const = params->default_action_is_const;
l->action_data_size_max = action_data_size_max;
l->size = size;
l->timeout = timeout;
l->id = p->n_learners;
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->learners, l, node);
p->n_learners++;
return 0;
nomem:
if (!l)
return -ENOMEM;
free(l->action_is_for_default_entry);
free(l->action_is_for_table_entries);
free(l->default_action_data);
free(l->actions);
free(l->fields);
free(l);
return -ENOMEM;
}
static void
learner_params_free(struct rte_swx_table_learner_params *params)
{
if (!params)
return;
free(params->key_mask0);
free(params);
}
static struct rte_swx_table_learner_params *
learner_params_get(struct learner *l)
{
struct rte_swx_table_learner_params *params = NULL;
struct field *first, *last;
uint32_t i;
/* Memory allocation. */
params = calloc(1, sizeof(struct rte_swx_table_learner_params));
if (!params)
goto error;
/* Find first (smallest offset) and last (biggest offset) match fields. */
first = l->fields[0];
last = l->fields[0];
for (i = 0; i < l->n_fields; i++) {
struct field *f = l->fields[i];
if (f->offset < first->offset)
first = f;
if (f->offset > last->offset)
last = f;
}
/* Key offset and size. */
params->key_offset = first->offset / 8;
params->key_size = (last->offset + last->n_bits - first->offset) / 8;
/* Memory allocation. */
params->key_mask0 = calloc(1, params->key_size);
if (!params->key_mask0)
goto error;
/* Key mask. */
for (i = 0; i < l->n_fields; i++) {
struct field *f = l->fields[i];
uint32_t start = (f->offset - first->offset) / 8;
size_t size = f->n_bits / 8;
memset(&params->key_mask0[start], 0xFF, size);
}
/* Action data size. */
params->action_data_size = l->action_data_size_max;
/* Maximum number of keys. */
params->n_keys_max = l->size;
/* Timeout. */
params->key_timeout = l->timeout;
return params;
error:
learner_params_free(params);
return NULL;
}
static void
learner_build_free(struct rte_swx_pipeline *p)
{
uint32_t i;
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
uint32_t j;
if (!t->learners)
continue;
for (j = 0; j < p->n_learners; j++) {
struct learner_runtime *r = &t->learners[j];
free(r->mailbox);
}
free(t->learners);
t->learners = NULL;
}
if (p->learner_stats) {
for (i = 0; i < p->n_learners; i++)
free(p->learner_stats[i].n_pkts_action);
free(p->learner_stats);
}
}
static int
learner_build(struct rte_swx_pipeline *p)
{
uint32_t i;
int status = 0;
/* Per pipeline: learner statistics. */
p->learner_stats = calloc(p->n_learners, sizeof(struct learner_statistics));
CHECK(p->learner_stats, ENOMEM);
for (i = 0; i < p->n_learners; i++) {
p->learner_stats[i].n_pkts_action = calloc(p->n_actions, sizeof(uint64_t));
CHECK(p->learner_stats[i].n_pkts_action, ENOMEM);
}
/* Per thread: learner run-time. */
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
struct learner *l;
t->learners = calloc(p->n_learners, sizeof(struct learner_runtime));
if (!t->learners) {
status = -ENOMEM;
goto error;
}
TAILQ_FOREACH(l, &p->learners, node) {
struct learner_runtime *r = &t->learners[l->id];
uint64_t size;
/* r->mailbox. */
size = rte_swx_table_learner_mailbox_size_get();
if (size) {
r->mailbox = calloc(1, size);
if (!r->mailbox) {
status = -ENOMEM;
goto error;
}
}
/* r->key. */
r->key = l->header ?
&t->structs[l->header->struct_id] :
&t->structs[p->metadata_struct_id];
}
}
return 0;
error:
learner_build_free(p);
return status;
}
static void
learner_free(struct rte_swx_pipeline *p)
{
learner_build_free(p);
/* Learner tables. */
for ( ; ; ) {
struct learner *l;
l = TAILQ_FIRST(&p->learners);
if (!l)
break;
TAILQ_REMOVE(&p->learners, l, node);
free(l->fields);
free(l->actions);
free(l->default_action_data);
free(l);
}
}
/*
* Table state.
*/
static int
table_state_build(struct rte_swx_pipeline *p)
{
struct table *table;
struct selector *s;
struct learner *l;
p->table_state = calloc(p->n_tables + p->n_selectors + p->n_learners,
sizeof(struct rte_swx_table_state));
CHECK(p->table_state, ENOMEM);
TAILQ_FOREACH(table, &p->tables, node) {
struct rte_swx_table_state *ts = &p->table_state[table->id];
if (table->type) {
struct rte_swx_table_params *params;
/* ts->obj. */
params = table_params_get(table);
CHECK(params, ENOMEM);
ts->obj = table->type->ops.create(params,
NULL,
table->args,
p->numa_node);
table_params_free(params);
CHECK(ts->obj, ENODEV);
}
/* ts->default_action_data. */
if (table->action_data_size_max) {
ts->default_action_data =
malloc(table->action_data_size_max);
CHECK(ts->default_action_data, ENOMEM);
memcpy(ts->default_action_data,
table->default_action_data,
table->action_data_size_max);
}
/* ts->default_action_id. */
ts->default_action_id = table->default_action->id;
}
TAILQ_FOREACH(s, &p->selectors, node) {
struct rte_swx_table_state *ts = &p->table_state[p->n_tables + s->id];
struct rte_swx_table_selector_params *params;
/* ts->obj. */
params = selector_table_params_get(s);
CHECK(params, ENOMEM);
ts->obj = rte_swx_table_selector_create(params, NULL, p->numa_node);
selector_params_free(params);
CHECK(ts->obj, ENODEV);
}
TAILQ_FOREACH(l, &p->learners, node) {
struct rte_swx_table_state *ts = &p->table_state[p->n_tables +
p->n_selectors + l->id];
struct rte_swx_table_learner_params *params;
/* ts->obj. */
params = learner_params_get(l);
CHECK(params, ENOMEM);
ts->obj = rte_swx_table_learner_create(params, p->numa_node);
learner_params_free(params);
CHECK(ts->obj, ENODEV);
/* ts->default_action_data. */
if (l->action_data_size_max) {
ts->default_action_data = malloc(l->action_data_size_max);
CHECK(ts->default_action_data, ENOMEM);
memcpy(ts->default_action_data,
l->default_action_data,
l->action_data_size_max);
}
/* ts->default_action_id. */
ts->default_action_id = l->default_action->id;
}
return 0;
}
static void
table_state_build_free(struct rte_swx_pipeline *p)
{
uint32_t i;
if (!p->table_state)
return;
for (i = 0; i < p->n_tables; i++) {
struct rte_swx_table_state *ts = &p->table_state[i];
struct table *table = table_find_by_id(p, i);
/* ts->obj. */
if (table->type && ts->obj)
table->type->ops.free(ts->obj);
/* ts->default_action_data. */
free(ts->default_action_data);
}
for (i = 0; i < p->n_selectors; i++) {
struct rte_swx_table_state *ts = &p->table_state[p->n_tables + i];
/* ts->obj. */
if (ts->obj)
rte_swx_table_selector_free(ts->obj);
}
for (i = 0; i < p->n_learners; i++) {
struct rte_swx_table_state *ts = &p->table_state[p->n_tables + p->n_selectors + i];
/* ts->obj. */
if (ts->obj)
rte_swx_table_learner_free(ts->obj);
/* ts->default_action_data. */
free(ts->default_action_data);
}
free(p->table_state);
p->table_state = NULL;
}
static void
table_state_free(struct rte_swx_pipeline *p)
{
table_state_build_free(p);
}
/*
* Register array.
*/
static struct regarray *
regarray_find(struct rte_swx_pipeline *p, const char *name)
{
struct regarray *elem;
TAILQ_FOREACH(elem, &p->regarrays, node)
if (!strcmp(elem->name, name))
return elem;
return NULL;
}
static struct regarray *
regarray_find_by_id(struct rte_swx_pipeline *p, uint32_t id)
{
struct regarray *elem = NULL;
TAILQ_FOREACH(elem, &p->regarrays, node)
if (elem->id == id)
return elem;
return NULL;
}
int
rte_swx_pipeline_regarray_config(struct rte_swx_pipeline *p,
const char *name,
uint32_t size,
uint64_t init_val)
{
struct regarray *r;
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK(!regarray_find(p, name), EEXIST);
CHECK(size, EINVAL);
size = rte_align32pow2(size);
/* Memory allocation. */
r = calloc(1, sizeof(struct regarray));
CHECK(r, ENOMEM);
/* Node initialization. */
strcpy(r->name, name);
r->init_val = init_val;
r->size = size;
r->id = p->n_regarrays;
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->regarrays, r, node);
p->n_regarrays++;
return 0;
}
static int
regarray_build(struct rte_swx_pipeline *p)
{
struct regarray *regarray;
if (!p->n_regarrays)
return 0;
p->regarray_runtime = calloc(p->n_regarrays, sizeof(struct regarray_runtime));
CHECK(p->regarray_runtime, ENOMEM);
TAILQ_FOREACH(regarray, &p->regarrays, node) {
struct regarray_runtime *r = &p->regarray_runtime[regarray->id];
uint32_t i;
r->regarray = env_malloc(regarray->size * sizeof(uint64_t),
RTE_CACHE_LINE_SIZE,
p->numa_node);
CHECK(r->regarray, ENOMEM);
if (regarray->init_val)
for (i = 0; i < regarray->size; i++)
r->regarray[i] = regarray->init_val;
r->size_mask = regarray->size - 1;
}
return 0;
}
static void
regarray_build_free(struct rte_swx_pipeline *p)
{
uint32_t i;
if (!p->regarray_runtime)
return;
for (i = 0; i < p->n_regarrays; i++) {
struct regarray *regarray = regarray_find_by_id(p, i);
struct regarray_runtime *r = &p->regarray_runtime[i];
env_free(r->regarray, regarray->size * sizeof(uint64_t));
}
free(p->regarray_runtime);
p->regarray_runtime = NULL;
}
static void
regarray_free(struct rte_swx_pipeline *p)
{
regarray_build_free(p);
for ( ; ; ) {
struct regarray *elem;
elem = TAILQ_FIRST(&p->regarrays);
if (!elem)
break;
TAILQ_REMOVE(&p->regarrays, elem, node);
free(elem);
}
}
/*
* Meter array.
*/
static struct meter_profile *
meter_profile_find(struct rte_swx_pipeline *p, const char *name)
{
struct meter_profile *elem;
TAILQ_FOREACH(elem, &p->meter_profiles, node)
if (!strcmp(elem->name, name))
return elem;
return NULL;
}
static struct metarray *
metarray_find(struct rte_swx_pipeline *p, const char *name)
{
struct metarray *elem;
TAILQ_FOREACH(elem, &p->metarrays, node)
if (!strcmp(elem->name, name))
return elem;
return NULL;
}
static struct metarray *
metarray_find_by_id(struct rte_swx_pipeline *p, uint32_t id)
{
struct metarray *elem = NULL;
TAILQ_FOREACH(elem, &p->metarrays, node)
if (elem->id == id)
return elem;
return NULL;
}
int
rte_swx_pipeline_metarray_config(struct rte_swx_pipeline *p,
const char *name,
uint32_t size)
{
struct metarray *m;
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK(!metarray_find(p, name), EEXIST);
CHECK(size, EINVAL);
size = rte_align32pow2(size);
/* Memory allocation. */
m = calloc(1, sizeof(struct metarray));
CHECK(m, ENOMEM);
/* Node initialization. */
strcpy(m->name, name);
m->size = size;
m->id = p->n_metarrays;
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->metarrays, m, node);
p->n_metarrays++;
return 0;
}
struct meter_profile meter_profile_default = {
.node = {0},
.name = "",
.params = {0},
.profile = {
.cbs = 10000,
.pbs = 10000,
.cir_period = 1,
.cir_bytes_per_period = 1,
.pir_period = 1,
.pir_bytes_per_period = 1,
},
.n_users = 0,
};
static void
meter_init(struct meter *m)
{
memset(m, 0, sizeof(struct meter));
rte_meter_trtcm_config(&m->m, &meter_profile_default.profile);
m->profile = &meter_profile_default;
m->color_mask = RTE_COLOR_GREEN;
meter_profile_default.n_users++;
}
static int
metarray_build(struct rte_swx_pipeline *p)
{
struct metarray *m;
if (!p->n_metarrays)
return 0;
p->metarray_runtime = calloc(p->n_metarrays, sizeof(struct metarray_runtime));
CHECK(p->metarray_runtime, ENOMEM);
TAILQ_FOREACH(m, &p->metarrays, node) {
struct metarray_runtime *r = &p->metarray_runtime[m->id];
uint32_t i;
r->metarray = env_malloc(m->size * sizeof(struct meter),
RTE_CACHE_LINE_SIZE,
p->numa_node);
CHECK(r->metarray, ENOMEM);
for (i = 0; i < m->size; i++)
meter_init(&r->metarray[i]);
r->size_mask = m->size - 1;
}
return 0;
}
static void
metarray_build_free(struct rte_swx_pipeline *p)
{
uint32_t i;
if (!p->metarray_runtime)
return;
for (i = 0; i < p->n_metarrays; i++) {
struct metarray *m = metarray_find_by_id(p, i);
struct metarray_runtime *r = &p->metarray_runtime[i];
env_free(r->metarray, m->size * sizeof(struct meter));
}
free(p->metarray_runtime);
p->metarray_runtime = NULL;
}
static void
metarray_free(struct rte_swx_pipeline *p)
{
metarray_build_free(p);
/* Meter arrays. */
for ( ; ; ) {
struct metarray *elem;
elem = TAILQ_FIRST(&p->metarrays);
if (!elem)
break;
TAILQ_REMOVE(&p->metarrays, elem, node);
free(elem);
}
/* Meter profiles. */
for ( ; ; ) {
struct meter_profile *elem;
elem = TAILQ_FIRST(&p->meter_profiles);
if (!elem)
break;
TAILQ_REMOVE(&p->meter_profiles, elem, node);
free(elem);
}
}
/*
* Pipeline.
*/
int
rte_swx_pipeline_config(struct rte_swx_pipeline **p, int numa_node)
{
struct rte_swx_pipeline *pipeline;
/* Check input parameters. */
CHECK(p, EINVAL);
/* Memory allocation. */
pipeline = calloc(1, sizeof(struct rte_swx_pipeline));
CHECK(pipeline, ENOMEM);
/* Initialization. */
TAILQ_INIT(&pipeline->struct_types);
TAILQ_INIT(&pipeline->port_in_types);
TAILQ_INIT(&pipeline->ports_in);
TAILQ_INIT(&pipeline->port_out_types);
TAILQ_INIT(&pipeline->ports_out);
TAILQ_INIT(&pipeline->extern_types);
TAILQ_INIT(&pipeline->extern_objs);
TAILQ_INIT(&pipeline->extern_funcs);
TAILQ_INIT(&pipeline->headers);
TAILQ_INIT(&pipeline->actions);
TAILQ_INIT(&pipeline->table_types);
TAILQ_INIT(&pipeline->tables);
TAILQ_INIT(&pipeline->selectors);
TAILQ_INIT(&pipeline->learners);
TAILQ_INIT(&pipeline->regarrays);
TAILQ_INIT(&pipeline->meter_profiles);
TAILQ_INIT(&pipeline->metarrays);
pipeline->n_structs = 1; /* Struct 0 is reserved for action_data. */
pipeline->numa_node = numa_node;
*p = pipeline;
return 0;
}
void
rte_swx_pipeline_free(struct rte_swx_pipeline *p)
{
void *lib;
if (!p)
return;
lib = p->lib;
free(p->instruction_data);
free(p->instructions);
metarray_free(p);
regarray_free(p);
table_state_free(p);
learner_free(p);
selector_free(p);
table_free(p);
action_free(p);
instruction_table_free(p);
metadata_free(p);
header_free(p);
extern_func_free(p);
extern_obj_free(p);
port_out_free(p);
port_in_free(p);
struct_free(p);
free(p);
if (lib)
dlclose(lib);
}
int
rte_swx_pipeline_instructions_config(struct rte_swx_pipeline *p,
const char **instructions,
uint32_t n_instructions)
{
int err;
uint32_t i;
err = instruction_config(p, NULL, instructions, n_instructions);
if (err)
return err;
/* Thread instruction pointer reset. */
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
thread_ip_reset(p, t);
}
return 0;
}
static int
pipeline_compile(struct rte_swx_pipeline *p);
int
rte_swx_pipeline_build(struct rte_swx_pipeline *p)
{
int status;
CHECK(p, EINVAL);
CHECK(p->build_done == 0, EEXIST);
status = port_in_build(p);
if (status)
goto error;
status = port_out_build(p);
if (status)
goto error;
status = struct_build(p);
if (status)
goto error;
status = extern_obj_build(p);
if (status)
goto error;
status = extern_func_build(p);
if (status)
goto error;
status = header_build(p);
if (status)
goto error;
status = metadata_build(p);
if (status)
goto error;
status = instruction_table_build(p);
if (status)
goto error;
status = action_build(p);
if (status)
goto error;
status = table_build(p);
if (status)
goto error;
status = selector_build(p);
if (status)
goto error;
status = learner_build(p);
if (status)
goto error;
status = table_state_build(p);
if (status)
goto error;
status = regarray_build(p);
if (status)
goto error;
status = metarray_build(p);
if (status)
goto error;
p->build_done = 1;
pipeline_compile(p);
return 0;
error:
metarray_build_free(p);
regarray_build_free(p);
table_state_build_free(p);
learner_build_free(p);
selector_build_free(p);
table_build_free(p);
action_build_free(p);
instruction_table_build_free(p);
metadata_build_free(p);
header_build_free(p);
extern_func_build_free(p);
extern_obj_build_free(p);
port_out_build_free(p);
port_in_build_free(p);
struct_build_free(p);
return status;
}
void
rte_swx_pipeline_run(struct rte_swx_pipeline *p, uint32_t n_instructions)
{
uint32_t i;
for (i = 0; i < n_instructions; i++)
instr_exec(p);
}
void
rte_swx_pipeline_flush(struct rte_swx_pipeline *p)
{
uint32_t i;
for (i = 0; i < p->n_ports_out; i++) {
struct port_out_runtime *port = &p->out[i];
if (port->flush)
port->flush(port->obj);
}
}
/*
* Control.
*/
int
rte_swx_ctl_pipeline_info_get(struct rte_swx_pipeline *p,
struct rte_swx_ctl_pipeline_info *pipeline)
{
struct action *action;
struct table *table;
uint32_t n_actions = 0, n_tables = 0;
if (!p || !pipeline)
return -EINVAL;
TAILQ_FOREACH(action, &p->actions, node)
n_actions++;
TAILQ_FOREACH(table, &p->tables, node)
n_tables++;
pipeline->n_ports_in = p->n_ports_in;
pipeline->n_ports_out = p->n_ports_out;
pipeline->n_actions = n_actions;
pipeline->n_tables = n_tables;
pipeline->n_selectors = p->n_selectors;
pipeline->n_learners = p->n_learners;
pipeline->n_regarrays = p->n_regarrays;
pipeline->n_metarrays = p->n_metarrays;
return 0;
}
int
rte_swx_ctl_pipeline_numa_node_get(struct rte_swx_pipeline *p, int *numa_node)
{
if (!p || !numa_node)
return -EINVAL;
*numa_node = p->numa_node;
return 0;
}
int
rte_swx_ctl_action_info_get(struct rte_swx_pipeline *p,
uint32_t action_id,
struct rte_swx_ctl_action_info *action)
{
struct action *a = NULL;
if (!p || (action_id >= p->n_actions) || !action)
return -EINVAL;
a = action_find_by_id(p, action_id);
if (!a)
return -EINVAL;
strcpy(action->name, a->name);
action->n_args = a->st ? a->st->n_fields : 0;
return 0;
}
int
rte_swx_ctl_action_arg_info_get(struct rte_swx_pipeline *p,
uint32_t action_id,
uint32_t action_arg_id,
struct rte_swx_ctl_action_arg_info *action_arg)
{
struct action *a = NULL;
struct field *arg = NULL;
if (!p || (action_id >= p->n_actions) || !action_arg)
return -EINVAL;
a = action_find_by_id(p, action_id);
if (!a || !a->st || (action_arg_id >= a->st->n_fields))
return -EINVAL;
arg = &a->st->fields[action_arg_id];
strcpy(action_arg->name, arg->name);
action_arg->n_bits = arg->n_bits;
action_arg->is_network_byte_order = a->args_endianness[action_arg_id];
return 0;
}
int
rte_swx_ctl_table_info_get(struct rte_swx_pipeline *p,
uint32_t table_id,
struct rte_swx_ctl_table_info *table)
{
struct table *t = NULL;
if (!p || !table)
return -EINVAL;
t = table_find_by_id(p, table_id);
if (!t)
return -EINVAL;
strcpy(table->name, t->name);
strcpy(table->args, t->args);
table->n_match_fields = t->n_fields;
table->n_actions = t->n_actions;
table->default_action_is_const = t->default_action_is_const;
table->size = t->size;
return 0;
}
int
rte_swx_ctl_table_match_field_info_get(struct rte_swx_pipeline *p,
uint32_t table_id,
uint32_t match_field_id,
struct rte_swx_ctl_table_match_field_info *match_field)
{
struct table *t;
struct match_field *f;
if (!p || (table_id >= p->n_tables) || !match_field)
return -EINVAL;
t = table_find_by_id(p, table_id);
if (!t || (match_field_id >= t->n_fields))
return -EINVAL;
f = &t->fields[match_field_id];
match_field->match_type = f->match_type;
match_field->is_header = t->header ? 1 : 0;
match_field->n_bits = f->field->n_bits;
match_field->offset = f->field->offset;
return 0;
}
int
rte_swx_ctl_table_action_info_get(struct rte_swx_pipeline *p,
uint32_t table_id,
uint32_t table_action_id,
struct rte_swx_ctl_table_action_info *table_action)
{
struct table *t;
if (!p || (table_id >= p->n_tables) || !table_action)
return -EINVAL;
t = table_find_by_id(p, table_id);
if (!t || (table_action_id >= t->n_actions))
return -EINVAL;
table_action->action_id = t->actions[table_action_id]->id;
table_action->action_is_for_table_entries = t->action_is_for_table_entries[table_action_id];
table_action->action_is_for_default_entry = t->action_is_for_default_entry[table_action_id];
return 0;
}
int
rte_swx_ctl_table_ops_get(struct rte_swx_pipeline *p,
uint32_t table_id,
struct rte_swx_table_ops *table_ops,
int *is_stub)
{
struct table *t;
if (!p || (table_id >= p->n_tables))
return -EINVAL;
t = table_find_by_id(p, table_id);
if (!t)
return -EINVAL;
if (t->type) {
if (table_ops)
memcpy(table_ops, &t->type->ops, sizeof(*table_ops));
*is_stub = 0;
} else {
*is_stub = 1;
}
return 0;
}
int
rte_swx_ctl_selector_info_get(struct rte_swx_pipeline *p,
uint32_t selector_id,
struct rte_swx_ctl_selector_info *selector)
{
struct selector *s = NULL;
if (!p || !selector)
return -EINVAL;
s = selector_find_by_id(p, selector_id);
if (!s)
return -EINVAL;
strcpy(selector->name, s->name);
selector->n_selector_fields = s->n_selector_fields;
selector->n_groups_max = s->n_groups_max;
selector->n_members_per_group_max = s->n_members_per_group_max;
return 0;
}
int
rte_swx_ctl_selector_group_id_field_info_get(struct rte_swx_pipeline *p,
uint32_t selector_id,
struct rte_swx_ctl_table_match_field_info *field)
{
struct selector *s;
if (!p || (selector_id >= p->n_selectors) || !field)
return -EINVAL;
s = selector_find_by_id(p, selector_id);
if (!s)
return -EINVAL;
field->match_type = RTE_SWX_TABLE_MATCH_EXACT;
field->is_header = 0;
field->n_bits = s->group_id_field->n_bits;
field->offset = s->group_id_field->offset;
return 0;
}
int
rte_swx_ctl_selector_field_info_get(struct rte_swx_pipeline *p,
uint32_t selector_id,
uint32_t selector_field_id,
struct rte_swx_ctl_table_match_field_info *field)
{
struct selector *s;
struct field *f;
if (!p || (selector_id >= p->n_selectors) || !field)
return -EINVAL;
s = selector_find_by_id(p, selector_id);
if (!s || (selector_field_id >= s->n_selector_fields))
return -EINVAL;
f = s->selector_fields[selector_field_id];
field->match_type = RTE_SWX_TABLE_MATCH_EXACT;
field->is_header = s->selector_header ? 1 : 0;
field->n_bits = f->n_bits;
field->offset = f->offset;
return 0;
}
int
rte_swx_ctl_selector_member_id_field_info_get(struct rte_swx_pipeline *p,
uint32_t selector_id,
struct rte_swx_ctl_table_match_field_info *field)
{
struct selector *s;
if (!p || (selector_id >= p->n_selectors) || !field)
return -EINVAL;
s = selector_find_by_id(p, selector_id);
if (!s)
return -EINVAL;
field->match_type = RTE_SWX_TABLE_MATCH_EXACT;
field->is_header = 0;
field->n_bits = s->member_id_field->n_bits;
field->offset = s->member_id_field->offset;
return 0;
}
int
rte_swx_ctl_learner_info_get(struct rte_swx_pipeline *p,
uint32_t learner_id,
struct rte_swx_ctl_learner_info *learner)
{
struct learner *l = NULL;
if (!p || !learner)
return -EINVAL;
l = learner_find_by_id(p, learner_id);
if (!l)
return -EINVAL;
strcpy(learner->name, l->name);
learner->n_match_fields = l->n_fields;
learner->n_actions = l->n_actions;
learner->default_action_is_const = l->default_action_is_const;
learner->size = l->size;
return 0;
}
int
rte_swx_ctl_learner_match_field_info_get(struct rte_swx_pipeline *p,
uint32_t learner_id,
uint32_t match_field_id,
struct rte_swx_ctl_table_match_field_info *match_field)
{
struct learner *l;
struct field *f;
if (!p || (learner_id >= p->n_learners) || !match_field)
return -EINVAL;
l = learner_find_by_id(p, learner_id);
if (!l || (match_field_id >= l->n_fields))
return -EINVAL;
f = l->fields[match_field_id];
match_field->match_type = RTE_SWX_TABLE_MATCH_EXACT;
match_field->is_header = l->header ? 1 : 0;
match_field->n_bits = f->n_bits;
match_field->offset = f->offset;
return 0;
}
int
rte_swx_ctl_learner_action_info_get(struct rte_swx_pipeline *p,
uint32_t learner_id,
uint32_t learner_action_id,
struct rte_swx_ctl_table_action_info *learner_action)
{
struct learner *l;
if (!p || (learner_id >= p->n_learners) || !learner_action)
return -EINVAL;
l = learner_find_by_id(p, learner_id);
if (!l || (learner_action_id >= l->n_actions))
return -EINVAL;
learner_action->action_id = l->actions[learner_action_id]->id;
learner_action->action_is_for_table_entries =
l->action_is_for_table_entries[learner_action_id];
learner_action->action_is_for_default_entry =
l->action_is_for_default_entry[learner_action_id];
return 0;
}
int
rte_swx_pipeline_table_state_get(struct rte_swx_pipeline *p,
struct rte_swx_table_state **table_state)
{
if (!p || !table_state || !p->build_done)
return -EINVAL;
*table_state = p->table_state;
return 0;
}
int
rte_swx_pipeline_table_state_set(struct rte_swx_pipeline *p,
struct rte_swx_table_state *table_state)
{
if (!p || !table_state || !p->build_done)
return -EINVAL;
p->table_state = table_state;
return 0;
}
int
rte_swx_ctl_pipeline_port_in_stats_read(struct rte_swx_pipeline *p,
uint32_t port_id,
struct rte_swx_port_in_stats *stats)
{
struct port_in *port;
if (!p || !stats)
return -EINVAL;
port = port_in_find(p, port_id);
if (!port)
return -EINVAL;
port->type->ops.stats_read(port->obj, stats);
return 0;
}
int
rte_swx_ctl_pipeline_port_out_stats_read(struct rte_swx_pipeline *p,
uint32_t port_id,
struct rte_swx_port_out_stats *stats)
{
struct port_out *port;
if (!p || !stats)
return -EINVAL;
port = port_out_find(p, port_id);
if (!port)
return -EINVAL;
port->type->ops.stats_read(port->obj, stats);
return 0;
}
int
rte_swx_ctl_pipeline_table_stats_read(struct rte_swx_pipeline *p,
const char *table_name,
struct rte_swx_table_stats *stats)
{
struct table *table;
struct table_statistics *table_stats;
if (!p || !table_name || !table_name[0] || !stats || !stats->n_pkts_action)
return -EINVAL;
table = table_find(p, table_name);
if (!table)
return -EINVAL;
table_stats = &p->table_stats[table->id];
memcpy(stats->n_pkts_action,
table_stats->n_pkts_action,
p->n_actions * sizeof(uint64_t));
stats->n_pkts_hit = table_stats->n_pkts_hit[1];
stats->n_pkts_miss = table_stats->n_pkts_hit[0];
return 0;
}
int
rte_swx_ctl_pipeline_selector_stats_read(struct rte_swx_pipeline *p,
const char *selector_name,
struct rte_swx_pipeline_selector_stats *stats)
{
struct selector *s;
if (!p || !selector_name || !selector_name[0] || !stats)
return -EINVAL;
s = selector_find(p, selector_name);
if (!s)
return -EINVAL;
stats->n_pkts = p->selector_stats[s->id].n_pkts;
return 0;
}
int
rte_swx_ctl_pipeline_learner_stats_read(struct rte_swx_pipeline *p,
const char *learner_name,
struct rte_swx_learner_stats *stats)
{
struct learner *l;
struct learner_statistics *learner_stats;
if (!p || !learner_name || !learner_name[0] || !stats || !stats->n_pkts_action)
return -EINVAL;
l = learner_find(p, learner_name);
if (!l)
return -EINVAL;
learner_stats = &p->learner_stats[l->id];
memcpy(stats->n_pkts_action,
learner_stats->n_pkts_action,
p->n_actions * sizeof(uint64_t));
stats->n_pkts_hit = learner_stats->n_pkts_hit[1];
stats->n_pkts_miss = learner_stats->n_pkts_hit[0];
stats->n_pkts_learn_ok = learner_stats->n_pkts_learn[0];
stats->n_pkts_learn_err = learner_stats->n_pkts_learn[1];
stats->n_pkts_forget = learner_stats->n_pkts_forget;
return 0;
}
int
rte_swx_ctl_regarray_info_get(struct rte_swx_pipeline *p,
uint32_t regarray_id,
struct rte_swx_ctl_regarray_info *regarray)
{
struct regarray *r;
if (!p || !regarray)
return -EINVAL;
r = regarray_find_by_id(p, regarray_id);
if (!r)
return -EINVAL;
strcpy(regarray->name, r->name);
regarray->size = r->size;
return 0;
}
int
rte_swx_ctl_pipeline_regarray_read(struct rte_swx_pipeline *p,
const char *regarray_name,
uint32_t regarray_index,
uint64_t *value)
{
struct regarray *regarray;
struct regarray_runtime *r;
if (!p || !regarray_name || !value)
return -EINVAL;
regarray = regarray_find(p, regarray_name);
if (!regarray || (regarray_index >= regarray->size))
return -EINVAL;
r = &p->regarray_runtime[regarray->id];
*value = r->regarray[regarray_index];
return 0;
}
int
rte_swx_ctl_pipeline_regarray_write(struct rte_swx_pipeline *p,
const char *regarray_name,
uint32_t regarray_index,
uint64_t value)
{
struct regarray *regarray;
struct regarray_runtime *r;
if (!p || !regarray_name)
return -EINVAL;
regarray = regarray_find(p, regarray_name);
if (!regarray || (regarray_index >= regarray->size))
return -EINVAL;
r = &p->regarray_runtime[regarray->id];
r->regarray[regarray_index] = value;
return 0;
}
int
rte_swx_ctl_metarray_info_get(struct rte_swx_pipeline *p,
uint32_t metarray_id,
struct rte_swx_ctl_metarray_info *metarray)
{
struct metarray *m;
if (!p || !metarray)
return -EINVAL;
m = metarray_find_by_id(p, metarray_id);
if (!m)
return -EINVAL;
strcpy(metarray->name, m->name);
metarray->size = m->size;
return 0;
}
int
rte_swx_ctl_meter_profile_add(struct rte_swx_pipeline *p,
const char *name,
struct rte_meter_trtcm_params *params)
{
struct meter_profile *mp;
int status;
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK(params, EINVAL);
CHECK(!meter_profile_find(p, name), EEXIST);
/* Node allocation. */
mp = calloc(1, sizeof(struct meter_profile));
CHECK(mp, ENOMEM);
/* Node initialization. */
strcpy(mp->name, name);
memcpy(&mp->params, params, sizeof(struct rte_meter_trtcm_params));
status = rte_meter_trtcm_profile_config(&mp->profile, params);
if (status) {
free(mp);
CHECK(0, EINVAL);
}
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->meter_profiles, mp, node);
return 0;
}
int
rte_swx_ctl_meter_profile_delete(struct rte_swx_pipeline *p,
const char *name)
{
struct meter_profile *mp;
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
mp = meter_profile_find(p, name);
CHECK(mp, EINVAL);
CHECK(!mp->n_users, EBUSY);
/* Remove node from tailq. */
TAILQ_REMOVE(&p->meter_profiles, mp, node);
free(mp);
return 0;
}
int
rte_swx_ctl_meter_reset(struct rte_swx_pipeline *p,
const char *metarray_name,
uint32_t metarray_index)
{
struct meter_profile *mp_old;
struct metarray *metarray;
struct metarray_runtime *metarray_runtime;
struct meter *m;
CHECK(p, EINVAL);
CHECK_NAME(metarray_name, EINVAL);
metarray = metarray_find(p, metarray_name);
CHECK(metarray, EINVAL);
CHECK(metarray_index < metarray->size, EINVAL);
metarray_runtime = &p->metarray_runtime[metarray->id];
m = &metarray_runtime->metarray[metarray_index];
mp_old = m->profile;
meter_init(m);
mp_old->n_users--;
return 0;
}
int
rte_swx_ctl_meter_set(struct rte_swx_pipeline *p,
const char *metarray_name,
uint32_t metarray_index,
const char *profile_name)
{
struct meter_profile *mp, *mp_old;
struct metarray *metarray;
struct metarray_runtime *metarray_runtime;
struct meter *m;
CHECK(p, EINVAL);
CHECK_NAME(metarray_name, EINVAL);
metarray = metarray_find(p, metarray_name);
CHECK(metarray, EINVAL);
CHECK(metarray_index < metarray->size, EINVAL);
mp = meter_profile_find(p, profile_name);
CHECK(mp, EINVAL);
metarray_runtime = &p->metarray_runtime[metarray->id];
m = &metarray_runtime->metarray[metarray_index];
mp_old = m->profile;
memset(m, 0, sizeof(struct meter));
rte_meter_trtcm_config(&m->m, &mp->profile);
m->profile = mp;
m->color_mask = RTE_COLORS;
mp->n_users++;
mp_old->n_users--;
return 0;
}
int
rte_swx_ctl_meter_stats_read(struct rte_swx_pipeline *p,
const char *metarray_name,
uint32_t metarray_index,
struct rte_swx_ctl_meter_stats *stats)
{
struct metarray *metarray;
struct metarray_runtime *metarray_runtime;
struct meter *m;
CHECK(p, EINVAL);
CHECK_NAME(metarray_name, EINVAL);
metarray = metarray_find(p, metarray_name);
CHECK(metarray, EINVAL);
CHECK(metarray_index < metarray->size, EINVAL);
CHECK(stats, EINVAL);
metarray_runtime = &p->metarray_runtime[metarray->id];
m = &metarray_runtime->metarray[metarray_index];
memcpy(stats->n_pkts, m->n_pkts, sizeof(m->n_pkts));
memcpy(stats->n_bytes, m->n_bytes, sizeof(m->n_bytes));
return 0;
}
/*
* Pipeline compilation.
*/
static const char *
instr_type_to_name(struct instruction *instr)
{
switch (instr->type) {
case INSTR_RX: return "INSTR_RX";
case INSTR_TX: return "INSTR_TX";
case INSTR_TX_I: return "INSTR_TX_I";
case INSTR_HDR_EXTRACT: return "INSTR_HDR_EXTRACT";
case INSTR_HDR_EXTRACT2: return "INSTR_HDR_EXTRACT2";
case INSTR_HDR_EXTRACT3: return "INSTR_HDR_EXTRACT3";
case INSTR_HDR_EXTRACT4: return "INSTR_HDR_EXTRACT4";
case INSTR_HDR_EXTRACT5: return "INSTR_HDR_EXTRACT5";
case INSTR_HDR_EXTRACT6: return "INSTR_HDR_EXTRACT6";
case INSTR_HDR_EXTRACT7: return "INSTR_HDR_EXTRACT7";
case INSTR_HDR_EXTRACT8: return "INSTR_HDR_EXTRACT8";
case INSTR_HDR_EXTRACT_M: return "INSTR_HDR_EXTRACT_M";
case INSTR_HDR_LOOKAHEAD: return "INSTR_HDR_LOOKAHEAD";
case INSTR_HDR_EMIT: return "INSTR_HDR_EMIT";
case INSTR_HDR_EMIT_TX: return "INSTR_HDR_EMIT_TX";
case INSTR_HDR_EMIT2_TX: return "INSTR_HDR_EMIT2_TX";
case INSTR_HDR_EMIT3_TX: return "INSTR_HDR_EMIT3_TX";
case INSTR_HDR_EMIT4_TX: return "INSTR_HDR_EMIT4_TX";
case INSTR_HDR_EMIT5_TX: return "INSTR_HDR_EMIT5_TX";
case INSTR_HDR_EMIT6_TX: return "INSTR_HDR_EMIT6_TX";
case INSTR_HDR_EMIT7_TX: return "INSTR_HDR_EMIT7_TX";
case INSTR_HDR_EMIT8_TX: return "INSTR_HDR_EMIT8_TX";
case INSTR_HDR_VALIDATE: return "INSTR_HDR_VALIDATE";
case INSTR_HDR_INVALIDATE: return "INSTR_HDR_INVALIDATE";
case INSTR_MOV: return "INSTR_MOV";
case INSTR_MOV_MH: return "INSTR_MOV_MH";
case INSTR_MOV_HM: return "INSTR_MOV_HM";
case INSTR_MOV_HH: return "INSTR_MOV_HH";
case INSTR_MOV_I: return "INSTR_MOV_I";
case INSTR_DMA_HT: return "INSTR_DMA_HT";
case INSTR_DMA_HT2: return "INSTR_DMA_HT2";
case INSTR_DMA_HT3: return "INSTR_DMA_HT3";
case INSTR_DMA_HT4: return "INSTR_DMA_HT4";
case INSTR_DMA_HT5: return "INSTR_DMA_HT5";
case INSTR_DMA_HT6: return "INSTR_DMA_HT6";
case INSTR_DMA_HT7: return "INSTR_DMA_HT7";
case INSTR_DMA_HT8: return "INSTR_DMA_HT8";
case INSTR_ALU_ADD: return "INSTR_ALU_ADD";
case INSTR_ALU_ADD_MH: return "INSTR_ALU_ADD_MH";
case INSTR_ALU_ADD_HM: return "INSTR_ALU_ADD_HM";
case INSTR_ALU_ADD_HH: return "INSTR_ALU_ADD_HH";
case INSTR_ALU_ADD_MI: return "INSTR_ALU_ADD_MI";
case INSTR_ALU_ADD_HI: return "INSTR_ALU_ADD_HI";
case INSTR_ALU_SUB: return "INSTR_ALU_SUB";
case INSTR_ALU_SUB_MH: return "INSTR_ALU_SUB_MH";
case INSTR_ALU_SUB_HM: return "INSTR_ALU_SUB_HM";
case INSTR_ALU_SUB_HH: return "INSTR_ALU_SUB_HH";
case INSTR_ALU_SUB_MI: return "INSTR_ALU_SUB_MI";
case INSTR_ALU_SUB_HI: return "INSTR_ALU_SUB_HI";
case INSTR_ALU_CKADD_FIELD: return "INSTR_ALU_CKADD_FIELD";
case INSTR_ALU_CKADD_STRUCT20: return "INSTR_ALU_CKADD_STRUCT20";
case INSTR_ALU_CKADD_STRUCT: return "INSTR_ALU_CKADD_STRUCT";
case INSTR_ALU_CKSUB_FIELD: return "INSTR_ALU_CKSUB_FIELD";
case INSTR_ALU_AND: return "INSTR_ALU_AND";
case INSTR_ALU_AND_MH: return "INSTR_ALU_AND_MH";
case INSTR_ALU_AND_HM: return "INSTR_ALU_AND_HM";
case INSTR_ALU_AND_HH: return "INSTR_ALU_AND_HH";
case INSTR_ALU_AND_I: return "INSTR_ALU_AND_I";
case INSTR_ALU_OR: return "INSTR_ALU_OR";
case INSTR_ALU_OR_MH: return "INSTR_ALU_OR_MH";
case INSTR_ALU_OR_HM: return "INSTR_ALU_OR_HM";
case INSTR_ALU_OR_HH: return "INSTR_ALU_OR_HH";
case INSTR_ALU_OR_I: return "INSTR_ALU_OR_I";
case INSTR_ALU_XOR: return "INSTR_ALU_XOR";
case INSTR_ALU_XOR_MH: return "INSTR_ALU_XOR_MH";
case INSTR_ALU_XOR_HM: return "INSTR_ALU_XOR_HM";
case INSTR_ALU_XOR_HH: return "INSTR_ALU_XOR_HH";
case INSTR_ALU_XOR_I: return "INSTR_ALU_XOR_I";
case INSTR_ALU_SHL: return "INSTR_ALU_SHL";
case INSTR_ALU_SHL_MH: return "INSTR_ALU_SHL_MH";
case INSTR_ALU_SHL_HM: return "INSTR_ALU_SHL_HM";
case INSTR_ALU_SHL_HH: return "INSTR_ALU_SHL_HH";
case INSTR_ALU_SHL_MI: return "INSTR_ALU_SHL_MI";
case INSTR_ALU_SHL_HI: return "INSTR_ALU_SHL_HI";
case INSTR_ALU_SHR: return "INSTR_ALU_SHR";
case INSTR_ALU_SHR_MH: return "INSTR_ALU_SHR_MH";
case INSTR_ALU_SHR_HM: return "INSTR_ALU_SHR_HM";
case INSTR_ALU_SHR_HH: return "INSTR_ALU_SHR_HH";
case INSTR_ALU_SHR_MI: return "INSTR_ALU_SHR_MI";
case INSTR_ALU_SHR_HI: return "INSTR_ALU_SHR_HI";
case INSTR_REGPREFETCH_RH: return "INSTR_REGPREFETCH_RH";
case INSTR_REGPREFETCH_RM: return "INSTR_REGPREFETCH_RM";
case INSTR_REGPREFETCH_RI: return "INSTR_REGPREFETCH_RI";
case INSTR_REGRD_HRH: return "INSTR_REGRD_HRH";
case INSTR_REGRD_HRM: return "INSTR_REGRD_HRM";
case INSTR_REGRD_HRI: return "INSTR_REGRD_HRI";
case INSTR_REGRD_MRH: return "INSTR_REGRD_MRH";
case INSTR_REGRD_MRM: return "INSTR_REGRD_MRM";
case INSTR_REGRD_MRI: return "INSTR_REGRD_MRI";
case INSTR_REGWR_RHH: return "INSTR_REGWR_RHH";
case INSTR_REGWR_RHM: return "INSTR_REGWR_RHM";
case INSTR_REGWR_RHI: return "INSTR_REGWR_RHI";
case INSTR_REGWR_RMH: return "INSTR_REGWR_RMH";
case INSTR_REGWR_RMM: return "INSTR_REGWR_RMM";
case INSTR_REGWR_RMI: return "INSTR_REGWR_RMI";
case INSTR_REGWR_RIH: return "INSTR_REGWR_RIH";
case INSTR_REGWR_RIM: return "INSTR_REGWR_RIM";
case INSTR_REGWR_RII: return "INSTR_REGWR_RII";
case INSTR_REGADD_RHH: return "INSTR_REGADD_RHH";
case INSTR_REGADD_RHM: return "INSTR_REGADD_RHM";
case INSTR_REGADD_RHI: return "INSTR_REGADD_RHI";
case INSTR_REGADD_RMH: return "INSTR_REGADD_RMH";
case INSTR_REGADD_RMM: return "INSTR_REGADD_RMM";
case INSTR_REGADD_RMI: return "INSTR_REGADD_RMI";
case INSTR_REGADD_RIH: return "INSTR_REGADD_RIH";
case INSTR_REGADD_RIM: return "INSTR_REGADD_RIM";
case INSTR_REGADD_RII: return "INSTR_REGADD_RII";
case INSTR_METPREFETCH_H: return "INSTR_METPREFETCH_H";
case INSTR_METPREFETCH_M: return "INSTR_METPREFETCH_M";
case INSTR_METPREFETCH_I: return "INSTR_METPREFETCH_I";
case INSTR_METER_HHM: return "INSTR_METER_HHM";
case INSTR_METER_HHI: return "INSTR_METER_HHI";
case INSTR_METER_HMM: return "INSTR_METER_HMM";
case INSTR_METER_HMI: return "INSTR_METER_HMI";
case INSTR_METER_MHM: return "INSTR_METER_MHM";
case INSTR_METER_MHI: return "INSTR_METER_MHI";
case INSTR_METER_MMM: return "INSTR_METER_MMM";
case INSTR_METER_MMI: return "INSTR_METER_MMI";
case INSTR_METER_IHM: return "INSTR_METER_IHM";
case INSTR_METER_IHI: return "INSTR_METER_IHI";
case INSTR_METER_IMM: return "INSTR_METER_IMM";
case INSTR_METER_IMI: return "INSTR_METER_IMI";
case INSTR_TABLE: return "INSTR_TABLE";
case INSTR_TABLE_AF: return "INSTR_TABLE_AF";
case INSTR_SELECTOR: return "INSTR_SELECTOR";
case INSTR_LEARNER: return "INSTR_LEARNER";
case INSTR_LEARNER_AF: return "INSTR_LEARNER_AF";
case INSTR_LEARNER_LEARN: return "INSTR_LEARNER_LEARN";
case INSTR_LEARNER_FORGET: return "INSTR_LEARNER_FORGET";
case INSTR_EXTERN_OBJ: return "INSTR_EXTERN_OBJ";
case INSTR_EXTERN_FUNC: return "INSTR_EXTERN_FUNC";
case INSTR_JMP: return "INSTR_JMP";
case INSTR_JMP_VALID: return "INSTR_JMP_VALID";
case INSTR_JMP_INVALID: return "INSTR_JMP_INVALID";
case INSTR_JMP_HIT: return "INSTR_JMP_HIT";
case INSTR_JMP_MISS: return "INSTR_JMP_MISS";
case INSTR_JMP_ACTION_HIT: return "INSTR_JMP_ACTION_HIT";
case INSTR_JMP_ACTION_MISS: return "INSTR_JMP_ACTION_MISS";
case INSTR_JMP_EQ: return "INSTR_JMP_EQ";
case INSTR_JMP_EQ_MH: return "INSTR_JMP_EQ_MH";
case INSTR_JMP_EQ_HM: return "INSTR_JMP_EQ_HM";
case INSTR_JMP_EQ_HH: return "INSTR_JMP_EQ_HH";
case INSTR_JMP_EQ_I: return "INSTR_JMP_EQ_I";
case INSTR_JMP_NEQ: return "INSTR_JMP_NEQ";
case INSTR_JMP_NEQ_MH: return "INSTR_JMP_NEQ_MH";
case INSTR_JMP_NEQ_HM: return "INSTR_JMP_NEQ_HM";
case INSTR_JMP_NEQ_HH: return "INSTR_JMP_NEQ_HH";
case INSTR_JMP_NEQ_I: return "INSTR_JMP_NEQ_I";
case INSTR_JMP_LT: return "INSTR_JMP_LT";
case INSTR_JMP_LT_MH: return "INSTR_JMP_LT_MH";
case INSTR_JMP_LT_HM: return "INSTR_JMP_LT_HM";
case INSTR_JMP_LT_HH: return "INSTR_JMP_LT_HH";
case INSTR_JMP_LT_MI: return "INSTR_JMP_LT_MI";
case INSTR_JMP_LT_HI: return "INSTR_JMP_LT_HI";
case INSTR_JMP_GT: return "INSTR_JMP_GT";
case INSTR_JMP_GT_MH: return "INSTR_JMP_GT_MH";
case INSTR_JMP_GT_HM: return "INSTR_JMP_GT_HM";
case INSTR_JMP_GT_HH: return "INSTR_JMP_GT_HH";
case INSTR_JMP_GT_MI: return "INSTR_JMP_GT_MI";
case INSTR_JMP_GT_HI: return "INSTR_JMP_GT_HI";
case INSTR_RETURN: return "INSTR_RETURN";
default: return "INSTR_UNKNOWN";
}
}
typedef void
(*instruction_export_t)(struct instruction *, FILE *);
static void
instr_io_export(struct instruction *instr, FILE *f)
{
uint32_t n_io = 0, n_io_imm = 0, n_hdrs = 0, i;
/* n_io, n_io_imm, n_hdrs. */
if (instr->type == INSTR_RX ||
instr->type == INSTR_TX ||
instr->type == INSTR_HDR_EXTRACT_M ||
(instr->type >= INSTR_HDR_EMIT_TX && instr->type <= INSTR_HDR_EMIT8_TX))
n_io = 1;
if (instr->type == INSTR_TX_I)
n_io_imm = 1;
if (instr->type >= INSTR_HDR_EXTRACT && instr->type <= INSTR_HDR_EXTRACT8)
n_hdrs = 1 + (instr->type - INSTR_HDR_EXTRACT);
if (instr->type == INSTR_HDR_EXTRACT_M ||
instr->type == INSTR_HDR_LOOKAHEAD ||
instr->type == INSTR_HDR_EMIT)
n_hdrs = 1;
if (instr->type >= INSTR_HDR_EMIT_TX && instr->type <= INSTR_HDR_EMIT8_TX)
n_hdrs = 1 + (instr->type - INSTR_HDR_EMIT_TX);
/* instr. */
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n",
instr_type_to_name(instr));
/* instr.io. */
fprintf(f,
"\t\t.io = {\n");
/* instr.io.io. */
if (n_io)
fprintf(f,
"\t\t\t.io = {\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t},\n",
instr->io.io.offset,
instr->io.io.n_bits);
if (n_io_imm)
fprintf(f,
"\t\t\t.io = {\n"
"\t\t\t\t.val = %u,\n"
"\t\t\t},\n",
instr->io.io.val);
/* instr.io.hdr. */
if (n_hdrs) {
fprintf(f,
"\t\t.hdr = {\n");
/* instr.io.hdr.header_id. */
fprintf(f,
"\t\t\t.header_id = {");
for (i = 0; i < n_hdrs; i++)
fprintf(f,
"%u, ",
instr->io.hdr.header_id[i]);
fprintf(f,
"},\n");
/* instr.io.hdr.struct_id. */
fprintf(f,
"\t\t\t.struct_id = {");
for (i = 0; i < n_hdrs; i++)
fprintf(f,
"%u, ",
instr->io.hdr.struct_id[i]);
fprintf(f,
"},\n");
/* instr.io.hdr.n_bytes. */
fprintf(f,
"\t\t\t.n_bytes = {");
for (i = 0; i < n_hdrs; i++)
fprintf(f,
"%u, ",
instr->io.hdr.n_bytes[i]);
fprintf(f,
"},\n");
/* instr.io.hdr - closing curly brace. */
fprintf(f,
"\t\t\t}\n,");
}
/* instr.io - closing curly brace. */
fprintf(f,
"\t\t},\n");
/* instr - closing curly brace. */
fprintf(f,
"\t},\n");
}
static void
instr_hdr_validate_export(struct instruction *instr, FILE *f)
{
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t\t.valid = {\n"
"\t\t\t.header_id = %u,\n"
"\t\t},\n"
"\t},\n",
instr_type_to_name(instr),
instr->valid.header_id);
}
static void
instr_mov_export(struct instruction *instr, FILE *f)
{
if (instr->type != INSTR_MOV_I)
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t\t.mov = {\n"
"\t\t\t.dst = {\n"
"\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t},\n"
"\t\t\t.src = {\n"
"\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t},\n"
"\t\t},\n"
"\t},\n",
instr_type_to_name(instr),
instr->mov.dst.struct_id,
instr->mov.dst.n_bits,
instr->mov.dst.offset,
instr->mov.src.struct_id,
instr->mov.src.n_bits,
instr->mov.src.offset);
else
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t\t.mov = {\n"
"\t\t\t.dst = {\n"
"\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t}\n,"
"\t\t\t.src_val = %" PRIu64 ",\n"
"\t\t},\n"
"\t},\n",
instr_type_to_name(instr),
instr->mov.dst.struct_id,
instr->mov.dst.n_bits,
instr->mov.dst.offset,
instr->mov.src_val);
}
static void
instr_dma_ht_export(struct instruction *instr, FILE *f)
{
uint32_t n_dma = 0, i;
/* n_dma. */
n_dma = 1 + (instr->type - INSTR_DMA_HT);
/* instr. */
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n",
instr_type_to_name(instr));
/* instr.dma. */
fprintf(f,
"\t\t.dma = {\n");
/* instr.dma.dst. */
fprintf(f,
"\t\t\t.dst = {\n");
/* instr.dma.dst.header_id. */
fprintf(f,
"\t\t\t\t.header_id = {");
for (i = 0; i < n_dma; i++)
fprintf(f,
"%u, ",
instr->dma.dst.header_id[i]);
fprintf(f,
"},\n");
/* instr.dma.dst.struct_id. */
fprintf(f,
"\t\t\t\t.struct_id = {");
for (i = 0; i < n_dma; i++)
fprintf(f,
"%u, ",
instr->dma.dst.struct_id[i]);
fprintf(f,
"},\n");
/* instr.dma.dst - closing curly brace. */
fprintf(f,
"\t\t\t},\n");
/* instr.dma.src. */
fprintf(f,
"\t\t\t.src = {\n");
/* instr.dma.src.offset. */
fprintf(f,
"\t\t\t\t.offset = {");
for (i = 0; i < n_dma; i++)
fprintf(f,
"%u, ",
instr->dma.src.offset[i]);
fprintf(f,
"},\n");
/* instr.dma.src - closing curly brace. */
fprintf(f,
"\t\t\t},\n");
/* instr.dma.n_bytes. */
fprintf(f,
"\t\t\t.n_bytes = {");
for (i = 0; i < n_dma; i++)
fprintf(f,
"%u, ",
instr->dma.n_bytes[i]);
fprintf(f,
"},\n");
/* instr.dma - closing curly brace. */
fprintf(f,
"\t\t},\n");
/* instr - closing curly brace. */
fprintf(f,
"\t},\n");
}
static void
instr_alu_export(struct instruction *instr, FILE *f)
{
int imm = 0;
if (instr->type == INSTR_ALU_ADD_MI ||
instr->type == INSTR_ALU_ADD_HI ||
instr->type == INSTR_ALU_SUB_MI ||
instr->type == INSTR_ALU_SUB_HI ||
instr->type == INSTR_ALU_SHL_MI ||
instr->type == INSTR_ALU_SHL_HI ||
instr->type == INSTR_ALU_SHR_MI ||
instr->type == INSTR_ALU_SHR_HI ||
instr->type == INSTR_ALU_AND_I ||
instr->type == INSTR_ALU_OR_I ||
instr->type == INSTR_ALU_XOR_I)
imm = 1;
if (!imm)
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t\t.alu = {\n"
"\t\t\t.dst = {\n"
"\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t},\n"
"\t\t\t.src = {\n"
"\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t},\n"
"\t\t},\n"
"\t},\n",
instr_type_to_name(instr),
instr->alu.dst.struct_id,
instr->alu.dst.n_bits,
instr->alu.dst.offset,
instr->alu.src.struct_id,
instr->alu.src.n_bits,
instr->alu.src.offset);
else
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t\t.alu = {\n"
"\t\t\t.dst = {\n"
"\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t}\n,"
"\t\t\t.src_val = %" PRIu64 ",\n"
"\t\t},\n"
"\t},\n",
instr_type_to_name(instr),
instr->alu.dst.struct_id,
instr->alu.dst.n_bits,
instr->alu.dst.offset,
instr->alu.src_val);
}
static void
instr_reg_export(struct instruction *instr __rte_unused, FILE *f __rte_unused)
{
int prefetch = 0, idx_imm = 0, src_imm = 0;
if (instr->type == INSTR_REGPREFETCH_RH ||
instr->type == INSTR_REGPREFETCH_RM ||
instr->type == INSTR_REGPREFETCH_RI)
prefetch = 1;
/* index is the 3rd operand for the regrd instruction and the 2nd
* operand for the regwr and regadd instructions.
*/
if (instr->type == INSTR_REGPREFETCH_RI ||
instr->type == INSTR_REGRD_HRI ||
instr->type == INSTR_REGRD_MRI ||
instr->type == INSTR_REGWR_RIH ||
instr->type == INSTR_REGWR_RIM ||
instr->type == INSTR_REGWR_RII ||
instr->type == INSTR_REGADD_RIH ||
instr->type == INSTR_REGADD_RIM ||
instr->type == INSTR_REGADD_RII)
idx_imm = 1;
/* src is the 3rd operand for the regwr and regadd instructions. */
if (instr->type == INSTR_REGWR_RHI ||
instr->type == INSTR_REGWR_RMI ||
instr->type == INSTR_REGWR_RII ||
instr->type == INSTR_REGADD_RHI ||
instr->type == INSTR_REGADD_RMI ||
instr->type == INSTR_REGADD_RII)
src_imm = 1;
/* instr.regarray.regarray_id. */
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t\t.regarray = {\n"
"\t\t\t.regarray_id = %u,\n",
instr_type_to_name(instr),
instr->regarray.regarray_id);
/* instr.regarray.idx / instr.regarray.idx_val. */
if (!idx_imm)
fprintf(f,
"\t\t\t\t.idx = {\n"
"\t\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t\t.offset = %u,\n"
"\t\t\t\t},\n",
instr->regarray.idx.struct_id,
instr->regarray.idx.n_bits,
instr->regarray.idx.offset);
else
fprintf(f,
"\t\t\t\t.idx_val = %u,\n",
instr->regarray.idx_val);
/* instr.regarray.dstsrc / instr.regarray.dstsrc_val. */
if (!prefetch) {
if (!src_imm)
fprintf(f,
"\t\t\t\t.dstsrc = {\n"
"\t\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t\t.offset = %u,\n"
"\t\t\t\t},\n",
instr->regarray.dstsrc.struct_id,
instr->regarray.dstsrc.n_bits,
instr->regarray.dstsrc.offset);
else
fprintf(f,
"\t\t\t\t.dstsrc_val = %" PRIu64 ",\n",
instr->regarray.dstsrc_val);
}
/* instr.regarray and instr - closing curly braces. */
fprintf(f,
"\t\t},\n"
"\t},\n");
}
static void
instr_meter_export(struct instruction *instr __rte_unused, FILE *f __rte_unused)
{
int prefetch = 0, idx_imm = 0, color_in_imm = 0;
if (instr->type == INSTR_METPREFETCH_H ||
instr->type == INSTR_METPREFETCH_M ||
instr->type == INSTR_METPREFETCH_I)
prefetch = 1;
/* idx_imm. */
if (instr->type == INSTR_METPREFETCH_I ||
instr->type == INSTR_METER_IHM ||
instr->type == INSTR_METER_IHI ||
instr->type == INSTR_METER_IMM ||
instr->type == INSTR_METER_IMI)
idx_imm = 1;
/* color_in_imm. */
if (instr->type == INSTR_METER_HHI ||
instr->type == INSTR_METER_HMI ||
instr->type == INSTR_METER_MHI ||
instr->type == INSTR_METER_MMI ||
instr->type == INSTR_METER_IHI ||
instr->type == INSTR_METER_IMI)
color_in_imm = 1;
/* instr.meter.metarray_id. */
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t\t.meter = {\n"
"\t\t\t.metarray_id = %u,\n",
instr_type_to_name(instr),
instr->meter.metarray_id);
/* instr.meter.idx / instr.meter.idx_val. */
if (!idx_imm)
fprintf(f,
"\t\t\t.idx = {\n"
"\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t},\n",
instr->meter.idx.struct_id,
instr->meter.idx.n_bits,
instr->meter.idx.offset);
else
fprintf(f,
"\t\t\t.idx_val = %u,\n",
instr->meter.idx_val);
if (!prefetch) {
/* instr.meter.length. */
fprintf(f,
"\t\t\t.length = {\n"
"\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t},\n",
instr->meter.length.struct_id,
instr->meter.length.n_bits,
instr->meter.length.offset);
/* instr.meter.color_in / instr.meter.color_in_val. */
if (!color_in_imm)
fprintf(f,
"\t\t\t.color_in = {\n"
"\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t},\n",
instr->meter.color_in.struct_id,
instr->meter.color_in.n_bits,
instr->meter.color_in.offset);
else
fprintf(f,
"\t\t\t.color_in_val = %u,\n",
(uint32_t)instr->meter.color_in_val);
/* instr.meter.color_out. */
fprintf(f,
"\t\t\t.color_out = {\n"
"\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t},\n",
instr->meter.color_out.struct_id,
instr->meter.color_out.n_bits,
instr->meter.color_out.offset);
}
/* instr.meter and instr - closing curly braces. */
fprintf(f,
"\t\t},\n"
"\t},\n");
}
static void
instr_table_export(struct instruction *instr,
FILE *f)
{
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t\t.table = {\n"
"\t\t\t.table_id = %u,\n"
"\t\t},\n"
"\t},\n",
instr_type_to_name(instr),
instr->table.table_id);
}
static void
instr_learn_export(struct instruction *instr, FILE *f)
{
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t\t.learn = {\n"
"\t\t\t\t.action_id = %u,\n"
"\t\t},\n"
"\t},\n",
instr_type_to_name(instr),
instr->learn.action_id);
}
static void
instr_forget_export(struct instruction *instr, FILE *f)
{
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t},\n",
instr_type_to_name(instr));
}
static void
instr_extern_export(struct instruction *instr, FILE *f)
{
if (instr->type == INSTR_EXTERN_OBJ)
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t\t.ext_obj = {\n"
"\t\t\t.ext_obj_id = %u,\n"
"\t\t\t.func_id = %u,\n"
"\t\t},\n"
"\t},\n",
instr_type_to_name(instr),
instr->ext_obj.ext_obj_id,
instr->ext_obj.func_id);
else
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t\t.ext_func = {\n"
"\t\t\t.ext_func_id = %u,\n"
"\t\t},\n"
"\t},\n",
instr_type_to_name(instr),
instr->ext_func.ext_func_id);
}
static void
instr_jmp_export(struct instruction *instr, FILE *f __rte_unused)
{
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t\t.jmp = {\n"
"\t\t\t.ip = NULL,\n",
instr_type_to_name(instr));
switch (instr->type) {
case INSTR_JMP_VALID:
case INSTR_JMP_INVALID:
fprintf(f,
"\t\t\t.header_id = %u,\n",
instr->jmp.header_id);
break;
case INSTR_JMP_ACTION_HIT:
case INSTR_JMP_ACTION_MISS:
fprintf(f,
"\t\t\t.action_id = %u,\n",
instr->jmp.action_id);
break;
case INSTR_JMP_EQ:
case INSTR_JMP_EQ_MH:
case INSTR_JMP_EQ_HM:
case INSTR_JMP_EQ_HH:
case INSTR_JMP_NEQ:
case INSTR_JMP_NEQ_MH:
case INSTR_JMP_NEQ_HM:
case INSTR_JMP_NEQ_HH:
case INSTR_JMP_LT:
case INSTR_JMP_LT_MH:
case INSTR_JMP_LT_HM:
case INSTR_JMP_LT_HH:
case INSTR_JMP_GT:
case INSTR_JMP_GT_MH:
case INSTR_JMP_GT_HM:
case INSTR_JMP_GT_HH:
fprintf(f,
"\t\t\t.a = {\n"
"\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t},\n"
"\t\t\t.b = {\n"
"\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t},\n",
instr->jmp.a.struct_id,
instr->jmp.a.n_bits,
instr->jmp.a.offset,
instr->jmp.b.struct_id,
instr->jmp.b.n_bits,
instr->jmp.b.offset);
break;
case INSTR_JMP_EQ_I:
case INSTR_JMP_NEQ_I:
case INSTR_JMP_LT_MI:
case INSTR_JMP_LT_HI:
case INSTR_JMP_GT_MI:
case INSTR_JMP_GT_HI:
fprintf(f,
"\t\t\t.a = {\n"
"\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t}\n,"
"\t\t\t.b_val = %" PRIu64 ",\n",
instr->jmp.a.struct_id,
instr->jmp.a.n_bits,
instr->jmp.a.offset,
instr->jmp.b_val);
break;
default:
break;
}
fprintf(f,
"\t\t},\n"
"\t},\n");
}
static void
instr_return_export(struct instruction *instr,
FILE *f)
{
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n",
instr_type_to_name(instr));
fprintf(f,
"\t},\n");
}
static instruction_export_t export_table[] = {
[INSTR_RX] = instr_io_export,
[INSTR_TX] = instr_io_export,
[INSTR_TX_I] = instr_io_export,
[INSTR_HDR_EXTRACT] = instr_io_export,
[INSTR_HDR_EXTRACT2] = instr_io_export,
[INSTR_HDR_EXTRACT3] = instr_io_export,
[INSTR_HDR_EXTRACT4] = instr_io_export,
[INSTR_HDR_EXTRACT5] = instr_io_export,
[INSTR_HDR_EXTRACT6] = instr_io_export,
[INSTR_HDR_EXTRACT7] = instr_io_export,
[INSTR_HDR_EXTRACT8] = instr_io_export,
[INSTR_HDR_EXTRACT_M] = instr_io_export,
[INSTR_HDR_LOOKAHEAD] = instr_io_export,
[INSTR_HDR_EMIT] = instr_io_export,
[INSTR_HDR_EMIT_TX] = instr_io_export,
[INSTR_HDR_EMIT2_TX] = instr_io_export,
[INSTR_HDR_EMIT3_TX] = instr_io_export,
[INSTR_HDR_EMIT4_TX] = instr_io_export,
[INSTR_HDR_EMIT5_TX] = instr_io_export,
[INSTR_HDR_EMIT6_TX] = instr_io_export,
[INSTR_HDR_EMIT7_TX] = instr_io_export,
[INSTR_HDR_EMIT8_TX] = instr_io_export,
[INSTR_HDR_VALIDATE] = instr_hdr_validate_export,
[INSTR_HDR_INVALIDATE] = instr_hdr_validate_export,
[INSTR_MOV] = instr_mov_export,
[INSTR_MOV_MH] = instr_mov_export,
[INSTR_MOV_HM] = instr_mov_export,
[INSTR_MOV_HH] = instr_mov_export,
[INSTR_MOV_I] = instr_mov_export,
[INSTR_DMA_HT] = instr_dma_ht_export,
[INSTR_DMA_HT2] = instr_dma_ht_export,
[INSTR_DMA_HT3] = instr_dma_ht_export,
[INSTR_DMA_HT4] = instr_dma_ht_export,
[INSTR_DMA_HT5] = instr_dma_ht_export,
[INSTR_DMA_HT6] = instr_dma_ht_export,
[INSTR_DMA_HT7] = instr_dma_ht_export,
[INSTR_DMA_HT8] = instr_dma_ht_export,
[INSTR_ALU_ADD] = instr_alu_export,
[INSTR_ALU_ADD_MH] = instr_alu_export,
[INSTR_ALU_ADD_HM] = instr_alu_export,
[INSTR_ALU_ADD_HH] = instr_alu_export,
[INSTR_ALU_ADD_MI] = instr_alu_export,
[INSTR_ALU_ADD_HI] = instr_alu_export,
[INSTR_ALU_SUB] = instr_alu_export,
[INSTR_ALU_SUB_MH] = instr_alu_export,
[INSTR_ALU_SUB_HM] = instr_alu_export,
[INSTR_ALU_SUB_HH] = instr_alu_export,
[INSTR_ALU_SUB_MI] = instr_alu_export,
[INSTR_ALU_SUB_HI] = instr_alu_export,
[INSTR_ALU_CKADD_FIELD] = instr_alu_export,
[INSTR_ALU_CKADD_STRUCT] = instr_alu_export,
[INSTR_ALU_CKADD_STRUCT20] = instr_alu_export,
[INSTR_ALU_CKSUB_FIELD] = instr_alu_export,
[INSTR_ALU_AND] = instr_alu_export,
[INSTR_ALU_AND_MH] = instr_alu_export,
[INSTR_ALU_AND_HM] = instr_alu_export,
[INSTR_ALU_AND_HH] = instr_alu_export,
[INSTR_ALU_AND_I] = instr_alu_export,
[INSTR_ALU_OR] = instr_alu_export,
[INSTR_ALU_OR_MH] = instr_alu_export,
[INSTR_ALU_OR_HM] = instr_alu_export,
[INSTR_ALU_OR_HH] = instr_alu_export,
[INSTR_ALU_OR_I] = instr_alu_export,
[INSTR_ALU_XOR] = instr_alu_export,
[INSTR_ALU_XOR_MH] = instr_alu_export,
[INSTR_ALU_XOR_HM] = instr_alu_export,
[INSTR_ALU_XOR_HH] = instr_alu_export,
[INSTR_ALU_XOR_I] = instr_alu_export,
[INSTR_ALU_SHL] = instr_alu_export,
[INSTR_ALU_SHL_MH] = instr_alu_export,
[INSTR_ALU_SHL_HM] = instr_alu_export,
[INSTR_ALU_SHL_HH] = instr_alu_export,
[INSTR_ALU_SHL_MI] = instr_alu_export,
[INSTR_ALU_SHL_HI] = instr_alu_export,
[INSTR_ALU_SHR] = instr_alu_export,
[INSTR_ALU_SHR_MH] = instr_alu_export,
[INSTR_ALU_SHR_HM] = instr_alu_export,
[INSTR_ALU_SHR_HH] = instr_alu_export,
[INSTR_ALU_SHR_MI] = instr_alu_export,
[INSTR_ALU_SHR_HI] = instr_alu_export,
[INSTR_REGPREFETCH_RH] = instr_reg_export,
[INSTR_REGPREFETCH_RM] = instr_reg_export,
[INSTR_REGPREFETCH_RI] = instr_reg_export,
[INSTR_REGRD_HRH] = instr_reg_export,
[INSTR_REGRD_HRM] = instr_reg_export,
[INSTR_REGRD_MRH] = instr_reg_export,
[INSTR_REGRD_MRM] = instr_reg_export,
[INSTR_REGRD_HRI] = instr_reg_export,
[INSTR_REGRD_MRI] = instr_reg_export,
[INSTR_REGWR_RHH] = instr_reg_export,
[INSTR_REGWR_RHM] = instr_reg_export,
[INSTR_REGWR_RMH] = instr_reg_export,
[INSTR_REGWR_RMM] = instr_reg_export,
[INSTR_REGWR_RHI] = instr_reg_export,
[INSTR_REGWR_RMI] = instr_reg_export,
[INSTR_REGWR_RIH] = instr_reg_export,
[INSTR_REGWR_RIM] = instr_reg_export,
[INSTR_REGWR_RII] = instr_reg_export,
[INSTR_REGADD_RHH] = instr_reg_export,
[INSTR_REGADD_RHM] = instr_reg_export,
[INSTR_REGADD_RMH] = instr_reg_export,
[INSTR_REGADD_RMM] = instr_reg_export,
[INSTR_REGADD_RHI] = instr_reg_export,
[INSTR_REGADD_RMI] = instr_reg_export,
[INSTR_REGADD_RIH] = instr_reg_export,
[INSTR_REGADD_RIM] = instr_reg_export,
[INSTR_REGADD_RII] = instr_reg_export,
[INSTR_METPREFETCH_H] = instr_meter_export,
[INSTR_METPREFETCH_M] = instr_meter_export,
[INSTR_METPREFETCH_I] = instr_meter_export,
[INSTR_METER_HHM] = instr_meter_export,
[INSTR_METER_HHI] = instr_meter_export,
[INSTR_METER_HMM] = instr_meter_export,
[INSTR_METER_HMI] = instr_meter_export,
[INSTR_METER_MHM] = instr_meter_export,
[INSTR_METER_MHI] = instr_meter_export,
[INSTR_METER_MMM] = instr_meter_export,
[INSTR_METER_MMI] = instr_meter_export,
[INSTR_METER_IHM] = instr_meter_export,
[INSTR_METER_IHI] = instr_meter_export,
[INSTR_METER_IMM] = instr_meter_export,
[INSTR_METER_IMI] = instr_meter_export,
[INSTR_TABLE] = instr_table_export,
[INSTR_TABLE_AF] = instr_table_export,
[INSTR_SELECTOR] = instr_table_export,
[INSTR_LEARNER] = instr_table_export,
[INSTR_LEARNER_AF] = instr_table_export,
[INSTR_LEARNER_LEARN] = instr_learn_export,
[INSTR_LEARNER_FORGET] = instr_forget_export,
[INSTR_EXTERN_OBJ] = instr_extern_export,
[INSTR_EXTERN_FUNC] = instr_extern_export,
[INSTR_JMP] = instr_jmp_export,
[INSTR_JMP_VALID] = instr_jmp_export,
[INSTR_JMP_INVALID] = instr_jmp_export,
[INSTR_JMP_HIT] = instr_jmp_export,
[INSTR_JMP_MISS] = instr_jmp_export,
[INSTR_JMP_ACTION_HIT] = instr_jmp_export,
[INSTR_JMP_ACTION_MISS] = instr_jmp_export,
[INSTR_JMP_EQ] = instr_jmp_export,
[INSTR_JMP_EQ_MH] = instr_jmp_export,
[INSTR_JMP_EQ_HM] = instr_jmp_export,
[INSTR_JMP_EQ_HH] = instr_jmp_export,
[INSTR_JMP_EQ_I] = instr_jmp_export,
[INSTR_JMP_NEQ] = instr_jmp_export,
[INSTR_JMP_NEQ_MH] = instr_jmp_export,
[INSTR_JMP_NEQ_HM] = instr_jmp_export,
[INSTR_JMP_NEQ_HH] = instr_jmp_export,
[INSTR_JMP_NEQ_I] = instr_jmp_export,
[INSTR_JMP_LT] = instr_jmp_export,
[INSTR_JMP_LT_MH] = instr_jmp_export,
[INSTR_JMP_LT_HM] = instr_jmp_export,
[INSTR_JMP_LT_HH] = instr_jmp_export,
[INSTR_JMP_LT_MI] = instr_jmp_export,
[INSTR_JMP_LT_HI] = instr_jmp_export,
[INSTR_JMP_GT] = instr_jmp_export,
[INSTR_JMP_GT_MH] = instr_jmp_export,
[INSTR_JMP_GT_HM] = instr_jmp_export,
[INSTR_JMP_GT_HH] = instr_jmp_export,
[INSTR_JMP_GT_MI] = instr_jmp_export,
[INSTR_JMP_GT_HI] = instr_jmp_export,
[INSTR_RETURN] = instr_return_export,
};
static void
action_data_codegen(struct action *a, FILE *f)
{
uint32_t i;
fprintf(f,
"static const struct instruction action_%s_instructions[] = {\n",
a->name);
for (i = 0; i < a->n_instructions; i++) {
struct instruction *instr = &a->instructions[i];
instruction_export_t func = export_table[instr->type];
func(instr, f);
}
fprintf(f, "};\n");
}
static const char *
instr_type_to_func(struct instruction *instr)
{
switch (instr->type) {
case INSTR_RX: return NULL;
case INSTR_TX: return "__instr_tx_exec";
case INSTR_TX_I: return "__instr_tx_i_exec";
case INSTR_HDR_EXTRACT: return "__instr_hdr_extract_exec";
case INSTR_HDR_EXTRACT2: return "__instr_hdr_extract2_exec";
case INSTR_HDR_EXTRACT3: return "__instr_hdr_extract3_exec";
case INSTR_HDR_EXTRACT4: return "__instr_hdr_extract4_exec";
case INSTR_HDR_EXTRACT5: return "__instr_hdr_extract5_exec";
case INSTR_HDR_EXTRACT6: return "__instr_hdr_extract6_exec";
case INSTR_HDR_EXTRACT7: return "__instr_hdr_extract7_exec";
case INSTR_HDR_EXTRACT8: return "__instr_hdr_extract8_exec";
case INSTR_HDR_EXTRACT_M: return "__instr_hdr_extract_m_exec";
case INSTR_HDR_LOOKAHEAD: return "__instr_hdr_lookahead_exec";
case INSTR_HDR_EMIT: return "__instr_hdr_emit_exec";
case INSTR_HDR_EMIT_TX: return "__instr_hdr_emit_tx_exec";
case INSTR_HDR_EMIT2_TX: return "__instr_hdr_emit2_tx_exec";
case INSTR_HDR_EMIT3_TX: return "__instr_hdr_emit3_tx_exec";
case INSTR_HDR_EMIT4_TX: return "__instr_hdr_emit4_tx_exec";
case INSTR_HDR_EMIT5_TX: return "__instr_hdr_emit5_tx_exec";
case INSTR_HDR_EMIT6_TX: return "__instr_hdr_emit6_tx_exec";
case INSTR_HDR_EMIT7_TX: return "__instr_hdr_emit7_tx_exec";
case INSTR_HDR_EMIT8_TX: return "__instr_hdr_emit8_tx_exec";
case INSTR_HDR_VALIDATE: return "__instr_hdr_validate_exec";
case INSTR_HDR_INVALIDATE: return "__instr_hdr_invalidate_exec";
case INSTR_MOV: return "__instr_mov_exec";
case INSTR_MOV_MH: return "__instr_mov_mh_exec";
case INSTR_MOV_HM: return "__instr_mov_hm_exec";
case INSTR_MOV_HH: return "__instr_mov_hh_exec";
case INSTR_MOV_I: return "__instr_mov_i_exec";
case INSTR_DMA_HT: return "__instr_dma_ht_exec";
case INSTR_DMA_HT2: return "__instr_dma_ht2_exec";
case INSTR_DMA_HT3: return "__instr_dma_ht3_exec";
case INSTR_DMA_HT4: return "__instr_dma_ht4_exec";
case INSTR_DMA_HT5: return "__instr_dma_ht5_exec";
case INSTR_DMA_HT6: return "__instr_dma_ht6_exec";
case INSTR_DMA_HT7: return "__instr_dma_ht7_exec";
case INSTR_DMA_HT8: return "__instr_dma_ht8_exec";
case INSTR_ALU_ADD: return "__instr_alu_add_exec";
case INSTR_ALU_ADD_MH: return "__instr_alu_add_mh_exec";
case INSTR_ALU_ADD_HM: return "__instr_alu_add_hm_exec";
case INSTR_ALU_ADD_HH: return "__instr_alu_add_hh_exec";
case INSTR_ALU_ADD_MI: return "__instr_alu_add_mi_exec";
case INSTR_ALU_ADD_HI: return "__instr_alu_add_hi_exec";
case INSTR_ALU_SUB: return "__instr_alu_sub_exec";
case INSTR_ALU_SUB_MH: return "__instr_alu_sub_mh_exec";
case INSTR_ALU_SUB_HM: return "__instr_alu_sub_hm_exec";
case INSTR_ALU_SUB_HH: return "__instr_alu_sub_hh_exec";
case INSTR_ALU_SUB_MI: return "__instr_alu_sub_mi_exec";
case INSTR_ALU_SUB_HI: return "__instr_alu_sub_hi_exec";
case INSTR_ALU_CKADD_FIELD: return "__instr_alu_ckadd_field_exec";
case INSTR_ALU_CKADD_STRUCT20: return "__instr_alu_ckadd_struct20_exec";
case INSTR_ALU_CKADD_STRUCT: return "__instr_alu_ckadd_struct_exec";
case INSTR_ALU_CKSUB_FIELD: return "__instr_alu_cksub_field_exec";
case INSTR_ALU_AND: return "__instr_alu_and_exec";
case INSTR_ALU_AND_MH: return "__instr_alu_and_mh_exec";
case INSTR_ALU_AND_HM: return "__instr_alu_and_hm_exec";
case INSTR_ALU_AND_HH: return "__instr_alu_and_hh_exec";
case INSTR_ALU_AND_I: return "__instr_alu_and_i_exec";
case INSTR_ALU_OR: return "__instr_alu_or_exec";
case INSTR_ALU_OR_MH: return "__instr_alu_or_mh_exec";
case INSTR_ALU_OR_HM: return "__instr_alu_or_hm_exec";
case INSTR_ALU_OR_HH: return "__instr_alu_or_hh_exec";
case INSTR_ALU_OR_I: return "__instr_alu_or_i_exec";
case INSTR_ALU_XOR: return "__instr_alu_xor_exec";
case INSTR_ALU_XOR_MH: return "__instr_alu_xor_mh_exec";
case INSTR_ALU_XOR_HM: return "__instr_alu_xor_hm_exec";
case INSTR_ALU_XOR_HH: return "__instr_alu_xor_hh_exec";
case INSTR_ALU_XOR_I: return "__instr_alu_xor_i_exec";
case INSTR_ALU_SHL: return "__instr_alu_shl_exec";
case INSTR_ALU_SHL_MH: return "__instr_alu_shl_mh_exec";
case INSTR_ALU_SHL_HM: return "__instr_alu_shl_hm_exec";
case INSTR_ALU_SHL_HH: return "__instr_alu_shl_hh_exec";
case INSTR_ALU_SHL_MI: return "__instr_alu_shl_mi_exec";
case INSTR_ALU_SHL_HI: return "__instr_alu_shl_hi_exec";
case INSTR_ALU_SHR: return "__instr_alu_shr_exec";
case INSTR_ALU_SHR_MH: return "__instr_alu_shr_mh_exec";
case INSTR_ALU_SHR_HM: return "__instr_alu_shr_hm_exec";
case INSTR_ALU_SHR_HH: return "__instr_alu_shr_hh_exec";
case INSTR_ALU_SHR_MI: return "__instr_alu_shr_mi_exec";
case INSTR_ALU_SHR_HI: return "__instr_alu_shr_hi_exec";
case INSTR_REGPREFETCH_RH: return "__instr_regprefetch_rh_exec";
case INSTR_REGPREFETCH_RM: return "__instr_regprefetch_rm_exec";
case INSTR_REGPREFETCH_RI: return "__instr_regprefetch_ri_exec";
case INSTR_REGRD_HRH: return "__instr_regrd_hrh_exec";
case INSTR_REGRD_HRM: return "__instr_regrd_hrm_exec";
case INSTR_REGRD_HRI: return "__instr_regrd_hri_exec";
case INSTR_REGRD_MRH: return "__instr_regrd_mrh_exec";
case INSTR_REGRD_MRM: return "__instr_regrd_mrm_exec";
case INSTR_REGRD_MRI: return "__instr_regrd_mri_exec";
case INSTR_REGWR_RHH: return "__instr_regwr_rhh_exec";
case INSTR_REGWR_RHM: return "__instr_regwr_rhm_exec";
case INSTR_REGWR_RHI: return "__instr_regwr_rhi_exec";
case INSTR_REGWR_RMH: return "__instr_regwr_rmh_exec";
case INSTR_REGWR_RMM: return "__instr_regwr_rmm_exec";
case INSTR_REGWR_RMI: return "__instr_regwr_rmi_exec";
case INSTR_REGWR_RIH: return "__instr_regwr_rih_exec";
case INSTR_REGWR_RIM: return "__instr_regwr_rim_exec";
case INSTR_REGWR_RII: return "__instr_regwr_rii_exec";
case INSTR_REGADD_RHH: return "__instr_regadd_rhh_exec";
case INSTR_REGADD_RHM: return "__instr_regadd_rhm_exec";
case INSTR_REGADD_RHI: return "__instr_regadd_rhi_exec";
case INSTR_REGADD_RMH: return "__instr_regadd_rmh_exec";
case INSTR_REGADD_RMM: return "__instr_regadd_rmm_exec";
case INSTR_REGADD_RMI: return "__instr_regadd_rmi_exec";
case INSTR_REGADD_RIH: return "__instr_regadd_rih_exec";
case INSTR_REGADD_RIM: return "__instr_regadd_rim_exec";
case INSTR_REGADD_RII: return "__instr_regadd_rii_exec";
case INSTR_METPREFETCH_H: return "__instr_metprefetch_h_exec";
case INSTR_METPREFETCH_M: return "__instr_metprefetch_m_exec";
case INSTR_METPREFETCH_I: return "__instr_metprefetch_i_exec";
case INSTR_METER_HHM: return "__instr_meter_hhm_exec";
case INSTR_METER_HHI: return "__instr_meter_hhi_exec";
case INSTR_METER_HMM: return "__instr_meter_hmm_exec";
case INSTR_METER_HMI: return "__instr_meter_hmi_exec";
case INSTR_METER_MHM: return "__instr_meter_mhm_exec";
case INSTR_METER_MHI: return "__instr_meter_mhi_exec";
case INSTR_METER_MMM: return "__instr_meter_mmm_exec";
case INSTR_METER_MMI: return "__instr_meter_mmi_exec";
case INSTR_METER_IHM: return "__instr_meter_ihm_exec";
case INSTR_METER_IHI: return "__instr_meter_ihi_exec";
case INSTR_METER_IMM: return "__instr_meter_imm_exec";
case INSTR_METER_IMI: return "__instr_meter_imi_exec";
case INSTR_TABLE: return NULL;
case INSTR_TABLE_AF: return NULL;
case INSTR_SELECTOR: return NULL;
case INSTR_LEARNER: return NULL;
case INSTR_LEARNER_AF: return NULL;
case INSTR_LEARNER_LEARN: return "__instr_learn_exec";
case INSTR_LEARNER_FORGET: return "__instr_forget_exec";
case INSTR_EXTERN_OBJ: return NULL;
case INSTR_EXTERN_FUNC: return NULL;
case INSTR_JMP: return NULL;
case INSTR_JMP_VALID: return NULL;
case INSTR_JMP_INVALID: return NULL;
case INSTR_JMP_HIT: return NULL;
case INSTR_JMP_MISS: return NULL;
case INSTR_JMP_ACTION_HIT: return NULL;
case INSTR_JMP_ACTION_MISS: return NULL;
case INSTR_JMP_EQ: return NULL;
case INSTR_JMP_EQ_MH: return NULL;
case INSTR_JMP_EQ_HM: return NULL;
case INSTR_JMP_EQ_HH: return NULL;
case INSTR_JMP_EQ_I: return NULL;
case INSTR_JMP_NEQ: return NULL;
case INSTR_JMP_NEQ_MH: return NULL;
case INSTR_JMP_NEQ_HM: return NULL;
case INSTR_JMP_NEQ_HH: return NULL;
case INSTR_JMP_NEQ_I: return NULL;
case INSTR_JMP_LT: return NULL;
case INSTR_JMP_LT_MH: return NULL;
case INSTR_JMP_LT_HM: return NULL;
case INSTR_JMP_LT_HH: return NULL;
case INSTR_JMP_LT_MI: return NULL;
case INSTR_JMP_LT_HI: return NULL;
case INSTR_JMP_GT: return NULL;
case INSTR_JMP_GT_MH: return NULL;
case INSTR_JMP_GT_HM: return NULL;
case INSTR_JMP_GT_HH: return NULL;
case INSTR_JMP_GT_MI: return NULL;
case INSTR_JMP_GT_HI: return NULL;
case INSTR_RETURN: return NULL;
default: return NULL;
}
}
static void
action_instr_does_tx_codegen(struct action *a,
uint32_t instr_pos,
struct instruction *instr,
FILE *f)
{
fprintf(f,
"%s(p, t, &action_%s_instructions[%u]);\n"
"\tthread_ip_reset(p, t);\n"
"\tinstr_rx_exec(p);\n"
"\treturn;\n",
instr_type_to_func(instr),
a->name,
instr_pos);
}
static void
action_instr_extern_obj_codegen(struct action *a,
uint32_t instr_pos,
FILE *f)
{
fprintf(f,
"while (!__instr_extern_obj_exec(p, t, &action_%s_instructions[%u]));\n",
a->name,
instr_pos);
}
static void
action_instr_extern_func_codegen(struct action *a,
uint32_t instr_pos,
FILE *f)
{
fprintf(f,
"while (!__instr_extern_func_exec(p, t, &action_%s_instructions[%u]));\n",
a->name,
instr_pos);
}
static void
action_instr_jmp_codegen(struct action *a,
uint32_t instr_pos,
struct instruction *instr,
struct instruction_data *data,
FILE *f)
{
switch (instr->type) {
case INSTR_JMP:
fprintf(f,
"goto %s;\n",
data->jmp_label);
return;
case INSTR_JMP_VALID:
fprintf(f,
"if (HEADER_VALID(t, action_%s_instructions[%u].jmp.header_id))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_INVALID:
fprintf(f,
"if (!HEADER_VALID(t, action_%s_instructions[%u].jmp.header_id))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_HIT:
fprintf(f,
"if (t->hit)\n"
"\t\tgoto %s;\n",
data->jmp_label);
return;
case INSTR_JMP_MISS:
fprintf(f,
"if (!t->hit)\n"
"\t\tgoto %s;\n",
data->jmp_label);
return;
case INSTR_JMP_ACTION_HIT:
fprintf(f,
"if (t->action_id == action_%s_instructions[%u].jmp.action_id)\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_ACTION_MISS:
fprintf(f,
"if (t->action_id != action_%s_instructions[%u].jmp.action_id)\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_EQ:
fprintf(f,
"if (instr_operand_hbo(t, &action_%s_instructions[%u].jmp.a) == "
"instr_operand_hbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_EQ_MH:
fprintf(f,
"if (instr_operand_hbo(t, &action_%s_instructions[%u].jmp.a) == "
"instr_operand_nbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_EQ_HM:
fprintf(f,
"if (instr_operand_nbo(t, &action_%s_instructions[%u].jmp.a) == "
"instr_operand_hbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_EQ_HH:
fprintf(f,
"if (instr_operand_nbo(t, &action_%s_instructions[%u].jmp.a) == "
"instr_operand_nbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_EQ_I:
fprintf(f,
"if (instr_operand_hbo(t, &action_%s_instructions[%u].jmp.a) == "
"action_%s_instructions[%u].jmp.b_val)\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_NEQ:
fprintf(f,
"if (instr_operand_hbo(t, &action_%s_instructions[%u].jmp.a) != "
"instr_operand_hbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_NEQ_MH:
fprintf(f,
"if (instr_operand_hbo(t, &action_%s_instructions[%u].jmp.a) != "
"instr_operand_nbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_NEQ_HM:
fprintf(f,
"if (instr_operand_nbo(t, &action_%s_instructions[%u].jmp.a) != "
"instr_operand_hbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_NEQ_HH:
fprintf(f,
"if (instr_operand_nbo(t, &action_%s_instructions[%u].jmp.a) != "
"instr_operand_nbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_NEQ_I:
fprintf(f,
"if (instr_operand_hbo(t, &action_%s_instructions[%u].jmp.a) != "
"action_%s_instructions[%u].jmp.b_val)\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_LT:
fprintf(f,
"if (instr_operand_hbo(t, &action_%s_instructions[%u].jmp.a) < "
"instr_operand_hbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_LT_MH:
fprintf(f,
"if (instr_operand_hbo(t, &action_%s_instructions[%u].jmp.a) < "
"instr_operand_nbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_LT_HM:
fprintf(f,
"if (instr_operand_nbo(t, &action_%s_instructions[%u].jmp.a) < "
"instr_operand_hbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_LT_HH:
fprintf(f,
"if (instr_operand_nbo(t, &action_%s_instructions[%u].jmp.a) < "
"instr_operand_nbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_LT_MI:
fprintf(f,
"if (instr_operand_hbo(t, &action_%s_instructions[%u].jmp.a) < "
"action_%s_instructions[%u].jmp.b_val)\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_LT_HI:
fprintf(f,
"if (instr_operand_nbo(t, &action_%s_instructions[%u].jmp.a) < "
"action_%s_instructions[%u].jmp.b_val)\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_GT:
fprintf(f,
"if (instr_operand_hbo(t, &action_%s_instructions[%u].jmp.a) > "
"instr_operand_hbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_GT_MH:
fprintf(f,
"if (instr_operand_hbo(t, &action_%s_instructions[%u].jmp.a) > "
"instr_operand_nbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_GT_HM:
fprintf(f,
"if (instr_operand_nbo(t, &action_%s_instructions[%u].jmp.a) > "
"instr_operand_hbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_GT_HH:
fprintf(f,
"if (instr_operand_nbo(t, &action_%s_instructions[%u].jmp.a) > "
"instr_operand_nbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_GT_MI:
fprintf(f,
"if (instr_operand_hbo(t, &action_%s_instructions[%u].jmp.a) > "
"action_%s_instructions[%u].jmp.b_val)\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_GT_HI:
fprintf(f,
"if (instr_operand_nbo(t, &action_%s_instructions[%u].jmp.a) > "
"action_%s_instructions[%u].jmp.b_val)\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
default:
return;
}
}
static void
action_instr_return_codegen(FILE *f)
{
fprintf(f,
"return;\n");
}
static void
action_instr_codegen(struct action *a, FILE *f)
{
uint32_t i;
fprintf(f,
"void\n"
"action_%s_run(struct rte_swx_pipeline *p)\n"
"{\n"
"\tstruct thread *t = &p->threads[p->thread_id];\n"
"\n",
a->name);
for (i = 0; i < a->n_instructions; i++) {
struct instruction *instr = &a->instructions[i];
struct instruction_data *data = &a->instruction_data[i];
/* Label, if present. */
if (data->label[0])
fprintf(f, "\n%s : ", data->label);
else
fprintf(f, "\n\t");
/* TX instruction type. */
if (instruction_does_tx(instr)) {
action_instr_does_tx_codegen(a, i, instr, f);
continue;
}
/* Extern object/function instruction type. */
if (instr->type == INSTR_EXTERN_OBJ) {
action_instr_extern_obj_codegen(a, i, f);
continue;
}
if (instr->type == INSTR_EXTERN_FUNC) {
action_instr_extern_func_codegen(a, i, f);
continue;
}
/* Jump instruction type. */
if (instruction_is_jmp(instr)) {
action_instr_jmp_codegen(a, i, instr, data, f);
continue;
}
/* Return instruction type. */
if (instr->type == INSTR_RETURN) {
action_instr_return_codegen(f);
continue;
}
/* Any other instruction type. */
fprintf(f,
"%s(p, t, &action_%s_instructions[%u]);\n",
instr_type_to_func(instr),
a->name,
i);
}
fprintf(f, "}\n\n");
}
struct instruction_group {
TAILQ_ENTRY(instruction_group) node;
uint32_t group_id;
uint32_t first_instr_id;
uint32_t last_instr_id;
instr_exec_t func;
};
TAILQ_HEAD(instruction_group_list, instruction_group);
static struct instruction_group *
instruction_group_list_group_find(struct instruction_group_list *igl, uint32_t instruction_id)
{
struct instruction_group *g;
TAILQ_FOREACH(g, igl, node)
if ((g->first_instr_id <= instruction_id) && (instruction_id <= g->last_instr_id))
return g;
return NULL;
}
static void
instruction_group_list_free(struct instruction_group_list *igl)
{
if (!igl)
return;
for ( ; ; ) {
struct instruction_group *g;
g = TAILQ_FIRST(igl);
if (!g)
break;
TAILQ_REMOVE(igl, g, node);
free(g);
}
free(igl);
}
static struct instruction_group_list *
instruction_group_list_create(struct rte_swx_pipeline *p)
{
struct instruction_group_list *igl = NULL;
struct instruction_group *g = NULL;
uint32_t n_groups = 0, i;
if (!p || !p->instructions || !p->instruction_data || !p->n_instructions)
goto error;
/* List init. */
igl = calloc(1, sizeof(struct instruction_group_list));
if (!igl)
goto error;
TAILQ_INIT(igl);
/* Allocate the first group. */
g = calloc(1, sizeof(struct instruction_group));
if (!g)
goto error;
/* Iteration 1: Separate the instructions into groups based on the thread yield
* instructions. Do not worry about the jump instructions at this point.
*/
for (i = 0; i < p->n_instructions; i++) {
struct instruction *instr = &p->instructions[i];
/* Check for thread yield instructions. */
if (!instruction_does_thread_yield(instr))
continue;
/* If the current group contains at least one instruction, then finalize it (with
* the previous instruction), add it to the list and allocate a new group (that
* starts with the current instruction).
*/
if (i - g->first_instr_id) {
/* Finalize the group. */
g->last_instr_id = i - 1;
/* Add the group to the list. Advance the number of groups. */
TAILQ_INSERT_TAIL(igl, g, node);
n_groups++;
/* Allocate a new group. */
g = calloc(1, sizeof(struct instruction_group));
if (!g)
goto error;
/* Initialize the new group. */
g->group_id = n_groups;
g->first_instr_id = i;
}
/* Finalize the current group (with the current instruction, therefore this group
* contains just the current thread yield instruction), add it to the list and
* allocate a new group (that starts with the next instruction).
*/
/* Finalize the group. */
g->last_instr_id = i;
/* Add the group to the list. Advance the number of groups. */
TAILQ_INSERT_TAIL(igl, g, node);
n_groups++;
/* Allocate a new group. */
g = calloc(1, sizeof(struct instruction_group));
if (!g)
goto error;
/* Initialize the new group. */
g->group_id = n_groups;
g->first_instr_id = i + 1;
}
/* Handle the last group. */
if (i - g->first_instr_id) {
/* Finalize the group. */
g->last_instr_id = i - 1;
/* Add the group to the list. Advance the number of groups. */
TAILQ_INSERT_TAIL(igl, g, node);
n_groups++;
} else
free(g);
g = NULL;
/* Iteration 2: Handle jumps. If the current group contains an instruction which represents
* the destination of a jump instruction located in a different group ("far jump"), then the
* current group has to be split, so that the instruction representing the far jump
* destination is at the start of its group.
*/
for ( ; ; ) {
int is_modified = 0;
for (i = 0; i < p->n_instructions; i++) {
struct instruction_data *data = &p->instruction_data[i];
struct instruction_group *g;
uint32_t j;
/* Continue when the current instruction is not a jump destination. */
if (!data->n_users)
continue;
g = instruction_group_list_group_find(igl, i);
if (!g)
goto error;
/* Find out all the jump instructions with this destination. */
for (j = 0; j < p->n_instructions; j++) {
struct instruction *jmp_instr = &p->instructions[j];
struct instruction_data *jmp_data = &p->instruction_data[j];
struct instruction_group *jmp_g, *new_g;
/* Continue when not a jump instruction. Even when jump instruction,
* continue when the jump destination is not this instruction.
*/
if (!instruction_is_jmp(jmp_instr) ||
strcmp(jmp_data->jmp_label, data->label))
continue;
jmp_g = instruction_group_list_group_find(igl, j);
if (!jmp_g)
goto error;
/* Continue when both the jump instruction and the jump destination
* instruction are in the same group. Even when in different groups,
* still continue if the jump destination instruction is already the
* first instruction of its group.
*/
if ((jmp_g->group_id == g->group_id) || (g->first_instr_id == i))
continue;
/* Split the group of the current jump destination instruction to
* make this instruction the first instruction of a new group.
*/
new_g = calloc(1, sizeof(struct instruction_group));
if (!new_g)
goto error;
new_g->group_id = n_groups;
new_g->first_instr_id = i;
new_g->last_instr_id = g->last_instr_id;
g->last_instr_id = i - 1;
TAILQ_INSERT_AFTER(igl, g, new_g, node);
n_groups++;
is_modified = 1;
/* The decision to split this group (to make the current instruction
* the first instruction of a new group) is already taken and fully
* implemented, so no need to search for more reasons to do it.
*/
break;
}
}
/* Re-evaluate everything, as at least one group got split, so some jumps that were
* previously considered local (i.e. the jump destination is in the same group as
* the jump instruction) can now be "far jumps" (i.e. the jump destination is in a
* different group than the jump instruction). Wost case scenario: each instruction
* that is a jump destination ends up as the first instruction of its group.
*/
if (!is_modified)
break;
}
/* Re-assign the group IDs to be in incremental order. */
i = 0;
TAILQ_FOREACH(g, igl, node) {
g->group_id = i;
i++;
}
return igl;
error:
instruction_group_list_free(igl);
free(g);
return NULL;
}
static void
pipeline_instr_does_tx_codegen(struct rte_swx_pipeline *p __rte_unused,
uint32_t instr_pos,
struct instruction *instr,
FILE *f)
{
fprintf(f,
"%s(p, t, &pipeline_instructions[%u]);\n"
"\tthread_ip_reset(p, t);\n"
"\tinstr_rx_exec(p);\n"
"\treturn;\n",
instr_type_to_func(instr),
instr_pos);
}
static int
pipeline_instr_jmp_codegen(struct rte_swx_pipeline *p,
struct instruction_group_list *igl,
uint32_t jmp_instr_id,
struct instruction *jmp_instr,
struct instruction_data *jmp_data,
FILE *f)
{
struct instruction_group *jmp_g, *g;
struct instruction_data *data;
uint32_t instr_id;
switch (jmp_instr->type) {
case INSTR_JMP:
break;
case INSTR_JMP_VALID:
fprintf(f,
"if (HEADER_VALID(t, pipeline_instructions[%u].jmp.header_id))",
jmp_instr_id);
break;
case INSTR_JMP_INVALID:
fprintf(f,
"if (!HEADER_VALID(t, pipeline_instructions[%u].jmp.header_id))",
jmp_instr_id);
break;
case INSTR_JMP_HIT:
fprintf(f,
"if (t->hit)\n");
break;
case INSTR_JMP_MISS:
fprintf(f,
"if (!t->hit)\n");
break;
case INSTR_JMP_ACTION_HIT:
fprintf(f,
"if (t->action_id == pipeline_instructions[%u].jmp.action_id)",
jmp_instr_id);
break;
case INSTR_JMP_ACTION_MISS:
fprintf(f,
"if (t->action_id != pipeline_instructions[%u].jmp.action_id)",
jmp_instr_id);
break;
case INSTR_JMP_EQ:
fprintf(f,
"if (instr_operand_hbo(t, &pipeline_instructions[%u].jmp.a) == "
"instr_operand_hbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_EQ_MH:
fprintf(f,
"if (instr_operand_hbo(t, &pipeline_instructions[%u].jmp.a) == "
"instr_operand_nbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_EQ_HM:
fprintf(f,
"if (instr_operand_nbo(t, &pipeline_instructions[%u].jmp.a) == "
"instr_operand_hbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_EQ_HH:
fprintf(f,
"if (instr_operand_nbo(t, &pipeline_instructions[%u].jmp.a) == "
"instr_operand_nbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_EQ_I:
fprintf(f,
"if (instr_operand_hbo(t, &pipeline_instructions[%u].jmp.a) == "
"pipeline_instructions[%u].jmp.b_val)",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_NEQ:
fprintf(f,
"if (instr_operand_hbo(t, &pipeline_instructions[%u].jmp.a) != "
"instr_operand_hbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_NEQ_MH:
fprintf(f,
"if (instr_operand_hbo(t, &pipeline_instructions[%u].jmp.a) != "
"instr_operand_nbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_NEQ_HM:
fprintf(f,
"if (instr_operand_nbo(t, &pipeline_instructions[%u].jmp.a) != "
"instr_operand_hbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_NEQ_HH:
fprintf(f,
"if (instr_operand_nbo(t, &pipeline_instructions[%u].jmp.a) != "
"instr_operand_nbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_NEQ_I:
fprintf(f,
"if (instr_operand_hbo(t, &pipeline_instructions[%u].jmp.a) != "
"pipeline_instructions[%u].jmp.b_val)",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_LT:
fprintf(f,
"if (instr_operand_hbo(t, &pipeline_instructions[%u].jmp.a) < "
"instr_operand_hbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_LT_MH:
fprintf(f,
"if (instr_operand_hbo(t, &pipeline_instructions[%u].jmp.a) < "
"instr_operand_nbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_LT_HM:
fprintf(f,
"if (instr_operand_nbo(t, &pipeline_instructions[%u].jmp.a) < "
"instr_operand_hbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_LT_HH:
fprintf(f,
"if (instr_operand_nbo(t, &pipeline_instructions[%u].jmp.a) < "
"instr_operand_nbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_LT_MI:
fprintf(f,
"if (instr_operand_hbo(t, &pipeline_instructions[%u].jmp.a) < "
"pipeline_instructions[%u].jmp.b_val)",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_LT_HI:
fprintf(f,
"if (instr_operand_nbo(t, &pipeline_instructions[%u].jmp.a) < "
"pipeline_instructions[%u].jmp.b_val)",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_GT:
fprintf(f,
"if (instr_operand_hbo(t, &pipeline_instructions[%u].jmp.a) > "
"instr_operand_hbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_GT_MH:
fprintf(f,
"if (instr_operand_hbo(t, &pipeline_instructions[%u].jmp.a) > "
"instr_operand_nbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_GT_HM:
fprintf(f,
"if (instr_operand_nbo(t, &pipeline_instructions[%u].jmp.a) > "
"instr_operand_hbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_GT_HH:
fprintf(f,
"if (instr_operand_nbo(t, &pipeline_instructions[%u].jmp.a) > "
"instr_operand_nbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_GT_MI:
fprintf(f,
"if (instr_operand_hbo(t, &pipeline_instructions[%u].jmp.a) > "
"pipeline_instructions[%u].jmp.b_val)",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_GT_HI:
fprintf(f,
"if (instr_operand_nbo(t, &pipeline_instructions[%u].jmp.a) > "
"pipeline_instructions[%u].jmp.b_val)",
jmp_instr_id,
jmp_instr_id);
break;
default:
break;
}
/* Find the instruction group of the jump instruction. */
jmp_g = instruction_group_list_group_find(igl, jmp_instr_id);
if (!jmp_g)
return -EINVAL;
/* Find the instruction group of the jump destination instruction. */
data = label_find(p->instruction_data, p->n_instructions, jmp_data->jmp_label);
if (!data)
return -EINVAL;
instr_id = data - p->instruction_data;
g = instruction_group_list_group_find(igl, instr_id);
if (!g)
return -EINVAL;
/* Code generation for "near" jump (same instruction group) or "far" jump (different
* instruction group).
*/
if (g->group_id == jmp_g->group_id)
fprintf(f,
"\n\t\tgoto %s;\n",
jmp_data->jmp_label);
else
fprintf(f,
" {\n"
"\t\tthread_ip_set(t, &p->instructions[%u]);\n"
"\t\treturn;\n"
"\t}\n\n",
g->group_id);
return 0;
}
static void
instruction_group_list_codegen(struct instruction_group_list *igl,
struct rte_swx_pipeline *p,
FILE *f)
{
struct instruction_group *g;
uint32_t i;
int is_required = 0;
/* Check if code generation is required. */
TAILQ_FOREACH(g, igl, node)
if (g->first_instr_id < g->last_instr_id)
is_required = 1;
if (!is_required)
return;
/* Generate the code for the pipeline instruction array. */
fprintf(f,
"static const struct instruction pipeline_instructions[] = {\n");
for (i = 0; i < p->n_instructions; i++) {
struct instruction *instr = &p->instructions[i];
instruction_export_t func = export_table[instr->type];
func(instr, f);
}
fprintf(f, "};\n\n");
/* Generate the code for the pipeline functions: one function for each instruction group
* that contains more than one instruction.
*/
TAILQ_FOREACH(g, igl, node) {
struct instruction *last_instr;
uint32_t j;
/* Skip if group contains a single instruction. */
if (g->last_instr_id == g->first_instr_id)
continue;
/* Generate new pipeline function. */
fprintf(f,
"void\n"
"pipeline_func_%u(struct rte_swx_pipeline *p)\n"
"{\n"
"\tstruct thread *t = &p->threads[p->thread_id];\n"
"\n",
g->group_id);
/* Generate the code for each pipeline instruction. */
for (j = g->first_instr_id; j <= g->last_instr_id; j++) {
struct instruction *instr = &p->instructions[j];
struct instruction_data *data = &p->instruction_data[j];
/* Label, if present. */
if (data->label[0])
fprintf(f, "\n%s : ", data->label);
else
fprintf(f, "\n\t");
/* TX instruction type. */
if (instruction_does_tx(instr)) {
pipeline_instr_does_tx_codegen(p, j, instr, f);
continue;
}
/* Jump instruction type. */
if (instruction_is_jmp(instr)) {
pipeline_instr_jmp_codegen(p, igl, j, instr, data, f);
continue;
}
/* Any other instruction type. */
fprintf(f,
"%s(p, t, &pipeline_instructions[%u]);\n",
instr_type_to_func(instr),
j);
}
/* Finalize the generated pipeline function. For some instructions such as TX,
* emit-many-and-TX and unconditional jump, the next instruction has been already
* decided unconditionally and the instruction pointer of the current thread set
* accordingly; for all the other instructions, the instruction pointer must be
* incremented now.
*/
last_instr = &p->instructions[g->last_instr_id];
if (!instruction_does_tx(last_instr) && (last_instr->type != INSTR_JMP))
fprintf(f,
"thread_ip_inc(p);\n");
fprintf(f,
"}\n"
"\n");
}
}
static uint32_t
instruction_group_list_custom_instructions_count(struct instruction_group_list *igl)
{
struct instruction_group *g;
uint32_t n_custom_instr = 0;
/* Groups with a single instruction: no function is generated for this group, the group
* keeps its current instruction. Groups with more than two instructions: one function and
* the associated custom instruction get generated for each such group.
*/
TAILQ_FOREACH(g, igl, node) {
if (g->first_instr_id == g->last_instr_id)
continue;
n_custom_instr++;
}
return n_custom_instr;
}
static int
pipeline_codegen(struct rte_swx_pipeline *p, struct instruction_group_list *igl)
{
struct action *a;
FILE *f = NULL;
/* Create the .c file. */
f = fopen("/tmp/pipeline.c", "w");
if (!f)
return -EIO;
/* Include the .h file. */
fprintf(f, "#include \"rte_swx_pipeline_internal.h\"\n");
/* Add the code for each action. */
TAILQ_FOREACH(a, &p->actions, node) {
fprintf(f, "/**\n * Action %s\n */\n\n", a->name);
action_data_codegen(a, f);
fprintf(f, "\n");
action_instr_codegen(a, f);
fprintf(f, "\n");
}
/* Add the pipeline code. */
instruction_group_list_codegen(igl, p, f);
/* Close the .c file. */
fclose(f);
return 0;
}
#ifndef RTE_SWX_PIPELINE_CMD_MAX_SIZE
#define RTE_SWX_PIPELINE_CMD_MAX_SIZE 4096
#endif
static int
pipeline_libload(struct rte_swx_pipeline *p, struct instruction_group_list *igl)
{
struct action *a;
struct instruction_group *g;
char *dir_in, *buffer = NULL;
const char *dir_out;
int status = 0;
/* Get the environment variables. */
dir_in = getenv("RTE_INSTALL_DIR");
if (!dir_in) {
status = -EINVAL;
goto free;
}
dir_out = "/tmp";
/* Memory allocation for the command buffer. */
buffer = malloc(RTE_SWX_PIPELINE_CMD_MAX_SIZE);
if (!buffer) {
status = -ENOMEM;
goto free;
}
snprintf(buffer,
RTE_SWX_PIPELINE_CMD_MAX_SIZE,
"gcc -c -O3 -fpic -Wno-deprecated-declarations -o %s/pipeline.o %s/pipeline.c "
"-I %s/lib/pipeline "
"-I %s/lib/eal/include "
"-I %s/lib/eal/x86/include "
"-I %s/lib/eal/include/generic "
"-I %s/lib/meter "
"-I %s/lib/port "
"-I %s/lib/table "
"-I %s/lib/pipeline "
"-I %s/config "
"-I %s/build "
"-I %s/lib/eal/linux/include "
">%s/pipeline.log 2>&1 "
"&& "
"gcc -shared %s/pipeline.o -o %s/libpipeline.so "
">>%s/pipeline.log 2>&1",
dir_out,
dir_out,
dir_in,
dir_in,
dir_in,
dir_in,
dir_in,
dir_in,
dir_in,
dir_in,
dir_in,
dir_in,
dir_in,
dir_out,
dir_out,
dir_out,
dir_out);
/* Build the shared object library. */
status = system(buffer);
if (status)
goto free;
/* Open library. */
snprintf(buffer,
RTE_SWX_PIPELINE_CMD_MAX_SIZE,
"%s/libpipeline.so",
dir_out);
p->lib = dlopen(buffer, RTLD_LAZY);
if (!p->lib) {
status = -EIO;
goto free;
}
/* Get the action function symbols. */
TAILQ_FOREACH(a, &p->actions, node) {
snprintf(buffer, RTE_SWX_PIPELINE_CMD_MAX_SIZE, "action_%s_run", a->name);
p->action_funcs[a->id] = dlsym(p->lib, buffer);
if (!p->action_funcs[a->id]) {
status = -EINVAL;
goto free;
}
}
/* Get the pipeline function symbols. */
TAILQ_FOREACH(g, igl, node) {
if (g->first_instr_id == g->last_instr_id)
continue;
snprintf(buffer, RTE_SWX_PIPELINE_CMD_MAX_SIZE, "pipeline_func_%u", g->group_id);
g->func = dlsym(p->lib, buffer);
if (!g->func) {
status = -EINVAL;
goto free;
}
}
free:
if (status && p->lib) {
dlclose(p->lib);
p->lib = NULL;
}
free(buffer);
return status;
}
static int
pipeline_adjust_check(struct rte_swx_pipeline *p __rte_unused,
struct instruction_group_list *igl)
{
uint32_t n_custom_instr = instruction_group_list_custom_instructions_count(igl);
/* Check that enough space is available within the pipeline instruction table to store all
* the custom instructions.
*/
if (INSTR_CUSTOM_0 + n_custom_instr > RTE_SWX_PIPELINE_INSTRUCTION_TABLE_SIZE_MAX)
return -ENOSPC;
return 0;
}
static void
pipeline_adjust(struct rte_swx_pipeline *p, struct instruction_group_list *igl)
{
struct instruction_group *g;
uint32_t i;
/* Pipeline table instructions. */
for (i = 0; i < p->n_instructions; i++) {
struct instruction *instr = &p->instructions[i];
if (instr->type == INSTR_TABLE)
instr->type = INSTR_TABLE_AF;
if (instr->type == INSTR_LEARNER)
instr->type = INSTR_LEARNER_AF;
}
/* Pipeline custom instructions. */
i = 0;
TAILQ_FOREACH(g, igl, node) {
struct instruction *instr = &p->instructions[g->first_instr_id];
uint32_t j;
if (g->first_instr_id == g->last_instr_id)
continue;
/* Install a new custom instruction. */
p->instruction_table[INSTR_CUSTOM_0 + i] = g->func;
/* First instruction of the group: change its type to the new custom instruction. */
instr->type = INSTR_CUSTOM_0 + i;
/* All the subsequent instructions of the group: invalidate. */
for (j = g->first_instr_id + 1; j <= g->last_instr_id; j++) {
struct instruction_data *data = &p->instruction_data[j];
data->invalid = 1;
}
i++;
}
/* Remove the invalidated instructions. */
p->n_instructions = instr_compact(p->instructions, p->instruction_data, p->n_instructions);
/* Resolve the jump destination for any "standalone" jump instructions (i.e. those jump
* instructions that are the only instruction within their group, so they were left
* unmodified).
*/
instr_jmp_resolve(p->instructions, p->instruction_data, p->n_instructions);
}
static int
pipeline_compile(struct rte_swx_pipeline *p)
{
struct instruction_group_list *igl = NULL;
int status = 0;
igl = instruction_group_list_create(p);
if (!igl) {
status = -ENOMEM;
goto free;
}
/* Code generation. */
status = pipeline_codegen(p, igl);
if (status)
goto free;
/* Build and load the shared object library. */
status = pipeline_libload(p, igl);
if (status)
goto free;
/* Adjust instructions. */
status = pipeline_adjust_check(p, igl);
if (status)
goto free;
pipeline_adjust(p, igl);
free:
instruction_group_list_free(igl);
return status;
}
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