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lib/c/2014/labcomm2014_time.c 0 → 100644
View file @ d3921882
/*
labcomm2014_time.c -- labcomm2014 time handling
Copyright 2013 Anders Blomdell <anders.blomdell@control.lth.se>
This file is part of LabComm.
LabComm is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
LabComm is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#include <errno.h>
#include "labcomm2014_scheduler_private.h"
#define TIME_time(time, ...) time
#define TIME(func, ...) \
if (TIME_time(__VA_ARGS__) && \
TIME_time(__VA_ARGS__)->action->func) { \
return TIME_time(__VA_ARGS__)->action->func(__VA_ARGS__); \
} \
return -ENOSYS;
int labcomm2014_time_free(struct labcomm2014_time *s)
{
TIME(free, s);
}
int labcomm2014_time_add_usec(struct labcomm2014_time *s, uint32_t usec)
{
TIME(add_usec, s, usec);
}
lib/c/2014/labcomm2014_type_signature.c 0 → 100644
View file @ d3921882
#include "labcomm2014.h"
#include <string.h> // for memcmp
#include <stdio.h> // for debug printf
/* Dump signature bytes on stdout
*/
void labcomm2014_signature_print(struct labcomm2014_signature_data *signature)
{
struct labcomm2014_signature_data *p = signature ;
while (p->length != -1) {
if (p->length) {
int i;
for ( i = 0 ; i < p->length ; i++) {
printf("%02x ", p->u.bytes[i]);
}
} else if(p->u.signature){
labcomm2014_signature_print(p->u.signature->treedata);
} else {
printf("neither data nor ref, bailing out.\n");
return;
}
p+=1;
}
printf("\n");
}
static labcomm2014_bool sig_dump_checked(struct labcomm2014_signature_data *signature,
char *buf, int *len, int buflen);
/* buf (out) : byte array to write signature into
len (in/out): input: buf size, out: signature length
return LABCOMM2014_TRUE if aborted due to overrun
*/
labcomm2014_bool labcomm2014_signature_dump(struct labcomm2014_signature_data *signature,
char *buf, int *len)
{
int buflen = *len;
*len = 0;
return sig_dump_checked(signature, buf, len, buflen);
}
/* internal function with bounds checking for buf.
* buflen: capacity of buf
*/
static labcomm2014_bool sig_dump_checked(struct labcomm2014_signature_data *signature,
char *buf, int *len, int buflen)
{
struct labcomm2014_signature_data *p = signature;
while ( (p->length != -1) && (*len < buflen)) {
if (p->length) {
int i;
for ( i = 0 ; (i < p->length) && (*len < buflen); i++) {
*buf++ = p->u.bytes[i];
++*len;
}
} else if(p->u.signature){
int tmplen=*len;
//recursing. c.f. dump()
sig_dump_checked(p->u.signature->treedata, buf, len, buflen);
int inner_len = *len-tmplen;
buf += inner_len;
} else {
//printf("neither data nor ref, bailing out.\n");
return LABCOMM2014_TRUE;
}
p+=1;
}
return (*len >= buflen);
}
/* compare signature (flattened, if needed) to other
return LABCOMM2014_TRUE if equal
*/
labcomm2014_bool labcomm2014_signature_cmp( struct labcomm2014_signature_data *s1,
struct labcomm2014_signature_data *s2)
{
int buflen=512;
char buf1[buflen];
int len1=buflen;
char buf2[buflen];
int len2=buflen;
labcomm2014_bool res1 = labcomm2014_signature_dump(s1, buf1, &len1);
labcomm2014_bool res2 = labcomm2014_signature_dump(s2, buf2, &len2);
if(res1 || res2) {
printf("WARNING: OVERRUN\n");
return LABCOMM2014_FALSE;
} else {
return(len1 == len2 && memcmp(buf1, buf2, len1)==0);
}
}
/* maps a function f(char b, struct labcomm2014_signature *s, void *context)
* on each byte (or type ref) in the signature.
*
* If flatten, the signature is flattened to a byte array, and the
* second argument to f is always zero.
*
* Otherwise, when a type ref is encountered, f is called with the first
* argument zero and the referenced type as the second argument.
*
* The context parameter is passed on, unaltered, to f
*/
void map_signature( void(*f)(char, const struct labcomm2014_signature *, void *),
void *context,
const struct labcomm2014_signature *signature, labcomm2014_bool flatten)
{
struct labcomm2014_signature_data* p = signature->treedata;
while (p->length != -1) {
//fprintf(stderr, "%p %x\n", p, p->length);
if (p->length) {
int i;
for ( i = 0 ; i < p->length ; i++) {
(*f)(p->u.bytes[i], 0, context);
}
} else if (p->u.signature) {
if(p->u.signature == 0) printf("p->u.signature == null\n");
if(flatten) {
map_signature(f, context, p->u.signature, flatten);
} else {
(*f)(0, p->u.signature, context);
}
} else {
fprintf(stderr, "neither data nor ref, bailing out.\n");
return;
}
p+=1;
}
}
lib/c/2014/labcomm2014_type_signature.h 0 → 100644
View file @ d3921882
#ifndef __LABCOMM2014_TYPE_SIGNATURE_H__
#define __LABCOMM2014_TYPE_SIGNATURE_H__
//XXX move to common.h
#ifndef labcomm2014_bool
#define labcomm2014_bool char
#define LABCOMM2014_TRUE 1
#define LABCOMM2014_FALSE 0
#endif
/*
* Signature entry
*/
#ifndef LABCOMM_NO_TYPEDECL
#ifdef USE_UNIONS
/* Useful for C99 and up (or GCC without -pedantic) */
#define LABCOMM_SIGDEF_BYTES_OR_SIGNATURE \
union { \
char *bytes; \
struct labcomm2014_signature* signature; \
} u;
#define LABCOMM_SIGDEF_BYTES(l, b) { l, .u.bytes=b }
#define LABCOMM_SIGDEF_SIGNATURE(s) { 0, .u.signature=&s } // addressof, as s is pointing at the sig struct, not directly the the sig_bytes[]
#define LABCOMM_SIGDEF_END { -1, .u.bytes=0 }
#else
#define LABCOMM_SIGDEF_BYTES_OR_SIGNATURE \
struct { \
char *bytes; \
const struct labcomm2014_signature *signature; \
} u;
#define LABCOMM_SIGDEF_BYTES(l, b) { l, { b, 0 } }
#define LABCOMM_SIGDEF_SIGNATURE(s) { 0, { 0, &s } }
#define LABCOMM_SIGDEF_END { -1, { 0, 0 } }
#endif
struct labcomm2014_signature_data {
int length;
LABCOMM_SIGDEF_BYTES_OR_SIGNATURE
};
#endif
struct labcomm2014_sample_ref;
struct labcomm2014_signature {
char *name;
int (*encoded_size)(const struct labcomm2014_signature *sig, void *); /* void* refers to sample_data */
int size;
unsigned char *signature;
int index;
#ifndef LABCOMM_NO_TYPEDECL
int tdsize;
struct labcomm2014_signature_data *treedata;
#endif
#ifdef LABCOMM_EXPERIMENTAL_CACHED_ENCODED_SIZE
int cached_encoded_size; // -1 if not initialized or type is variable size
#endif
};
/* a struct for "raw" type_defs, to be used as an intermediate representation
* between decoder and signature parser
*/
struct labcomm2014_raw_type_def {
char *name;
int index;
int length;
char *signature_data;
};
/* a struct for type bindings
*/
struct labcomm2014_type_binding {
int sample_index;
int type_index;
};
/*
* functions
*/
/* register a handler for type_defs and type bindings
*/
int labcomm2014_decoder_register_labcomm2014_type_def(
struct labcomm2014_decoder *d,
void (*handler)(
struct labcomm2014_raw_type_def *v,
void *context
),
void *context
);
int labcomm2014_decoder_register_labcomm2014_type_binding(
struct labcomm2014_decoder *d,
void (*handler)(
struct labcomm2014_type_binding *v,
void *context
),
void *context
);
/* Dump signature bytes on stdout
*/
void labcomm2014_signature_print(struct labcomm2014_signature_data *signature);
/* compare signatures (flattened, if needed) to other
* return LABCOMM2014_TRUE if equal
*/
labcomm2014_bool labcomm2014_signature_cmp( struct labcomm2014_signature_data *s2,
struct labcomm2014_signature_data *s1);
/* flatten and dump signature to a byte array.
* buf (out) : byte array to write signature into
* len (in/out): input: buf size, out: signature length
*
* return LABCOMM2014_TRUE if aborted due to overrun
*/
labcomm2014_bool labcomm2014_signature_dump(struct labcomm2014_signature_data *signature,
char *buf, int *len);
/* maps function f on each byte in the signature
* if flatten, the signature is flattened, and the second argument of
* f is always zero
* otherwise, when a type ref is encountered, f is called with the first
* argument zero and the type ref as the second argument.
*/
void map_signature( void(*f)(char, const struct labcomm2014_signature *, void *),
void *context,
const struct labcomm2014_signature *signature, labcomm2014_bool flatten);
#endif
lib/c/2014/test/.gitignore 0 → 100644
View file @ d3921882
gen
lib/c/2014/test/another_encoding.lc 0 → 100644
View file @ d3921882
sample void V;
sample byte B;
lib/c/2014/test/cppmacros.h 0 → 100644
View file @ d3921882
// C Preprocessor macros.
#ifndef CPP_MACROS_H
#define CPP_MACROS_H
#define X_EMPTY(mac) var ## 1
#define EMPTY(mac) X_EMPTY(mac) // Returns 1 if macro mac is empty.
#endif
lib/c/2014/test/generated_encoding.lc 0 → 100644
View file @ d3921882
typedef void unused_t;
typedef void v_t;
sample v_t V;
sample byte B;
sample struct {
int i;
} S1;
sample int I[_];
sample struct { int i; } P[_];
sample void UnusedE;
sample void UnusedD;
sample sample R[4];
lib/c/2014/test/labcomm_mem_reader.c 0 → 100644
View file @ d3921882
#include "labcomm_mem_reader.h"
#include <errno.h>
#include <stdlib.h>
#include <string.h>
/* This implementation assumes labcomm will call end exactly once after each start
* It is not allowed to save data in mcontext->enc_data,
* this pointer will be set to NULL after decoding.
*/
/* NOTE!!!!
* start will be run first, once a signature or a data section is decoded
* end will be run and then start again. If end of encoded data is reached this
* must be handled in start.
*/
// TODO make labcomm use result!
int labcomm_mem_reader(labcomm_reader_t *r,
labcomm_reader_action_t action,
...)
{
int result = -EINVAL;
labcomm_mem_reader_context_t *mcontext = (labcomm_mem_reader_context_t *) r->context;
switch (action) {
case labcomm_reader_alloc: {
r->data = NULL;
r->data_size = 0;
r->pos = 0;
r->count = 0;
} break;
case labcomm_reader_start: {
if (r->data == NULL && mcontext->enc_data != NULL) {
r->data = (unsigned char *) malloc(mcontext->size);
if(r->data != NULL) {
memcpy(r->data, mcontext->enc_data, mcontext->size);
r->data_size = mcontext->size;
r->count = mcontext->size;
r->pos = 0;
result = r->data_size;
} else {
r->data_size = 0;
result = -ENOMEM;
}
} else if (r->data == NULL && mcontext->enc_data == NULL) {
result = -1;
} else {
result = r->count - r->pos;
}
} break;
case labcomm_reader_continue: {
if (r->pos < r->count) {
result = r->count - r->pos;
} else {
// TODO set some describing error here
result = -1;
}
} break;
case labcomm_reader_end: {
if (r->pos >= r->count) {
free(r->data);
r->data = NULL;
r->data_size = 0;
mcontext->enc_data = NULL;
mcontext->size = 0;
}
result = r->count - r->pos;
} break;
case labcomm_reader_free: {
r->count = 0;
r->pos = 0;
result = 0;
} break;
case labcomm_reader_ioctl: {
result = -ENOTSUP;
}
}
return result;
}
lib/c/2014/test/labcomm_mem_reader.h 0 → 100644
View file @ d3921882
#ifndef LABCOMM_MEM_READER_H
#define LABCOMM_MEM_READER_H
#include "labcomm.h"
/* enc_data: The data to be decoded
* size: the size of the data to be decoded
*/
typedef struct labcomm_mem_reader_context_t labcomm_mem_reader_context_t;
struct labcomm_mem_reader_context_t {
size_t size;
unsigned char *enc_data;
};
int labcomm_mem_reader(labcomm_reader_t *r,
labcomm_reader_action_t action,
...);
#endif
lib/c/2014/test/labcomm_mem_writer.c 0 → 100644
View file @ d3921882
#include "labcomm_mem_writer.h"
#include <stddef.h> // For size_t.
#include <stdarg.h>
#include <stdlib.h>
#include <errno.h>
#include "labcomm.h"
#include "cppmacros.h"
#define BUFFER_SIZE 150 // Suitable size is at least the size of a fully encoded message. Found by inspecting size of file genreated from the labcomm_fs_reader_writer.c on the same message type.
// Put encdoded data directly in mcontext->mbuf or malloc new temporary memory.
// 1 == Allocate new memory.
// 2 == Use mcontext->buf directly. But _beware_; you can not then later change
// mcontext->buf to something else since the writer gets a reference to this
// buffer!
#if defined(MEM_WRITER_ENCODED_BUFFER) && (EMPTY(MEM_WRITER_ENCODED_BUFFER) != 1)
#define ENCODED_BUFFER MEM_WRITER_ENCODED_BUFFER
#else
#define ENCODED_BUFFER 1
#endif
static int get_writer_available(labcomm_writer_t *w, labcomm_mem_writer_context_t *mcontext);
static void copy_data(labcomm_writer_t *w, labcomm_mem_writer_context_t *mcontext, unsigned char *mbuf);
/*
* Write encoded messages to memory. w->context is assumed to be a pointer to a
* labcomm_mem_writer_context_t structure.
*/
int labcomm_mem_writer(labcomm_writer_t *w, labcomm_writer_action_t action, ...)
{
int result = 0;
// Unwrap pointers for easy access.
labcomm_mem_writer_context_t *mcontext = (labcomm_mem_writer_context_t *) w->context;
unsigned char *mbuf = mcontext->buf;
switch (action) {
case labcomm_writer_alloc: {
#if (ENCODED_BUFFER == 1)
w->data = malloc(BUFFER_SIZE); // Buffer that LabComm will use for putting the encoded data.
if (w->data == NULL) {
result = -ENOMEM;
w->data_size = 0;
w->count = 0;
w->pos = 0;
} else {
w->data_size = BUFFER_SIZE;
w->count = BUFFER_SIZE;
w->pos = 0;
}
#elif (ENCODED_BUFFER == 2)
w->data = mbuf;
int bytes_left = (mcontext->length - mcontext->write_pos);
w->data_size = bytes_left;
w->count = bytes_left;
w->pos = mcontext->write_pos;
#endif
} break;
case labcomm_writer_free:{
#if (ENCODED_BUFFER == 1)
free(w->data);
#endif
w->data = 0;
w->data_size = 0;
w->count = 0;
w->pos = 0;
} break;
case labcomm_writer_start:
case labcomm_writer_start_signature: {
#if (ENCODED_BUFFER == 1)
w->pos = 0;
#elif (ENCODED_BUFFER == 2)
w->pos = mcontext->write_pos;
#endif
} break;
case labcomm_writer_continue:
case labcomm_writer_continue_signature: {
// Encode-buffer(w->data) is full; empty/handle it. (w->pos == w->count) most likely.
#if (ENCODED_BUFFER == 1)
copy_data(w, mcontext, mbuf);
result = w->pos; // Assume result here should be number of bytes written.
w->pos = 0;
#elif (ENCODED_BUFFER == 2)
mcontext->write_pos = w->pos;
#endif
result = 0;
} break;
case labcomm_writer_end:
case labcomm_writer_end_signature:{ // Nothing more to encode, handle encode-buffer(w->data).
#if (ENCODED_BUFFER == 1)
copy_data(w, mcontext, mbuf);
result = w->pos;
w->pos = 0;
#elif (ENCODED_BUFFER == 2)
mcontext->write_pos = w->pos;
#endif
result = 0;
} break;
}
return result;
}
labcomm_mem_writer_context_t *labcomm_mem_writer_context_t_new(size_t init_pos, size_t length, unsigned char *buf)
{
labcomm_mem_writer_context_t *mcontext = (labcomm_mem_writer_context_t *) malloc(sizeof(labcomm_mem_writer_context_t));
if (mcontext == NULL) {
//fprintf(stderr, "error: Can not allocate labcomm_mem_writer_context_t.\n");
} else {
mcontext->write_pos = init_pos;
mcontext->length = length;
mcontext->buf = buf;
}
return mcontext;
}
void labcomm_mem_writer_context_t_free(labcomm_mem_writer_context_t **mcontext)
{
free(*mcontext);
*mcontext = NULL;
}
// Get the number of available bytes in the mcontext->buf buffer.
static int get_writer_available(labcomm_writer_t *w, labcomm_mem_writer_context_t *mcontext)
{
return (mcontext->length - mcontext->write_pos);
}
// Copy data from encoded buffer to mbuf.
static void copy_data(labcomm_writer_t *w, labcomm_mem_writer_context_t *mcontext, unsigned char *mbuf)
{
int writer_available = get_writer_available(w, mcontext);
if (( writer_available - w->pos) < 0) {
w->on_error(LABCOMM_ERROR_ENC_BUF_FULL, 3, "labcomm_writer_t->pos=%i, but available in mcontext is %i", w->pos, writer_available);
} else {
int i;
for (i = 0; i < w->pos; ++i, mcontext->write_pos++) {
mbuf[mcontext->write_pos] = w->data[i];
}
}
}
void test_copy_data(labcomm_writer_t *w, labcomm_mem_writer_context_t *mcontext, unsigned char *mbuf)
{
copy_data(w, mcontext, mbuf);
}
lib/c/2014/test/labcomm_mem_writer.h 0 → 100644
View file @ d3921882
#ifndef LABCOMM_MEM_WRITER_H
#define LABCOMM_MEM_WRITER_H
#include "labcomm.h"
/* Wrapper structure for the memory buffer including a writer position. */
typedef struct labcomm_mem_writer_context_t labcomm_mem_writer_context_t;
struct labcomm_mem_writer_context_t {
size_t write_pos; // Position where next write should be.
size_t length; // Length of the buffer.
unsigned char *buf; // Allocated destination buffer.
};
int labcomm_mem_writer(labcomm_writer_t *w, labcomm_writer_action_t action, ...);
/* Wrapper the internal static function copy_data. This is needed so that the exceptions can be unit tested. */
void test_copy_data(labcomm_writer_t *w, labcomm_mem_writer_context_t *mcontext, unsigned char *mbuf);
/* Allocate new labcomm_mem_writer_context_t. */
labcomm_mem_writer_context_t *labcomm_mem_writer_context_t_new(size_t init_pos, size_t length, unsigned char *buf);
/* Deallocate mcontext. */
void labcomm_mem_writer_context_t_free(labcomm_mem_writer_context_t **mcontext);
#endif
lib/c/2014/test/more_types.lc 0 → 100644
View file @ d3921882
sample string S;
sample int A[8];
sample struct {
string s1;
string s2;
} NS;
sample string AS[_];
lib/c/2014/test/test_labcomm.c 0 → 100644
View file @ d3921882
/*
test_labcomm2014.c -- Various labcomm2014 tests
Copyright 2013 Anders Blomdell <anders.blomdell@control.lth.se>
This file is part of LabComm.
LabComm is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
LabComm is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#include <stdint.h>
#include <inttypes.h>
#include <string.h>
#include <stdlib.h>
#include <errno.h>
#include "labcomm2014_private.h"
#include "labcomm2014_default_error_handler.h"
#include "labcomm2014_default_memory.h"
#include "labcomm2014_default_scheduler.h"
#include "test/gen/test_sample.h"
static struct labcomm2014_writer writer;
static struct expect {
char *description;
int result;
int (*trampoline)(struct labcomm2014_decoder *context);
struct labcomm2014_decoder *context;
} *expect;
static void check_expect()
{
struct expect *p = expect;
{
int i;
for (i = 0 ; i < writer.pos ; i++) {
fprintf(stderr, "%02x ", writer.data[i]);
}
fprintf(stderr, "\n");
}
if (p && p->trampoline) {
int err;
expect = p + 1;
fprintf(stderr, "Checking '%s' expected=%d ", p->description, p->result);
err = p->trampoline(p->context);
fprintf(stderr, "actual=%d\n", err);
if (p->result >= 0 && p->result != err) {
fprintf(stderr, "FAILED\n");
exit(1);
} else if (err == 0) {
fprintf(stderr, "FAILED (unexpected 0)\n");
exit(1);
}
writer.pos = 0;
}
}
static unsigned char buffer[512];
static int writer_alloc(struct labcomm2014_writer *w,
struct labcomm2014_writer_action_context *action_context)
{
w->data = buffer;
w->data_size = sizeof(buffer);
w->count = sizeof(buffer);
return 0;
}
static int writer_start(struct labcomm2014_writer *w,
struct labcomm2014_writer_action_context *action_context,
int index, const struct labcomm2014_signature *signature,
void *value)
{
return 0;
}
static int buf_writer_end(
struct labcomm2014_writer *w,
struct labcomm2014_writer_action_context *action_context)
{
check_expect();
return 0;
}
const struct labcomm2014_writer_action writer_action = {
.alloc = writer_alloc,
.start = writer_start,
.end = buf_writer_end,
};
static struct labcomm2014_writer_action_context writer_action_context = {
.next = NULL,
.action = &writer_action,
.context = NULL
};
static struct labcomm2014_writer writer = {
.action_context = &writer_action_context,
.data = buffer,
.data_size = sizeof(buffer),
.count = sizeof(buffer),
.pos = 0,
.error = 0,
};
static int reader_alloc(struct labcomm2014_reader *r,
struct labcomm2014_reader_action_context *action_context)
{
r->data = buffer;
r->data_size = sizeof(buffer);
r->count = 0;
r->memory = labcomm2014_default_memory;
return 0;
}
static int reader_fill(struct labcomm2014_reader *r,
struct labcomm2014_reader_action_context *action_context)
{
r->error = -ENOMEM;
return r->error;
}
const struct labcomm2014_reader_action reader_action = {
.alloc = reader_alloc,
.fill = reader_fill,
};
static struct labcomm2014_reader_action_context reader_action_context = {
.next = NULL,
.action = &reader_action,
.context = NULL
};
static struct labcomm2014_reader reader = {
.action_context = &reader_action_context,
.data = buffer,
.data_size = sizeof(buffer),
.count = 0,
.pos = 0,
.error = 0,
};
static int32_t encoder_data[256];
static test_sample_test_var encoder_var = {
.n_0 = 1,
.n_2 = 1,
.a = encoder_data,
};
static int32_t decoder_data[256];
static test_sample_test_var decoder_var = {
.n_0 = 1,
.n_2 = 1,
.a = decoder_data,
};;
void handle_test_var(test_sample_test_var *v, void *ctx)
{
if (v->n_0 * v->n_2 > 0) {
decoder_var.a[0] = v->a[0];
}
}
int test_decode_one(struct labcomm2014_decoder *decoder)
{
int result;
for (reader.count = 0 ; reader.count < writer.pos ; reader.count++) {
reader.error = 0;
reader.pos = 0;
result = labcomm2014_decoder_decode_one(decoder);
if (result >= 0 ) {
fprintf(stderr,
"Got result from buffer with bogus length (%d, %d != %d)\n",
result, reader.count, writer.pos);
exit(1);
}
}
reader.error = 0;
reader.pos = 0;
reader.count = writer.pos;
result = labcomm2014_decoder_decode_one(decoder);
if (result < 0) {
fprintf(stderr, "Got no result from buffer with correct length (%d)\n",
result);
exit(1);
}
return result;
}
static void test_encode_decode(struct labcomm2014_encoder *encoder,
struct labcomm2014_decoder *decoder,
int expected, uint32_t n_0, uint32_t n_2)
{
int err;
writer.pos = 0;
encoder_var.n_0 = n_0;
encoder_var.n_2 = n_2;
encoder_var.a[0] = 314;
labcomm2014_encode_test_sample_test_var(encoder, &encoder_var);
err = test_decode_one(decoder);
fprintf(stderr, "decode of sample %u * 2 * %u -> size=%d err=%d\n",
n_0, n_2, writer.pos, err);
if (writer.pos != labcomm2014_sizeof_test_sample_test_var(NULL, &encoder_var)) {
fprintf(stderr, "Incorrect sizeof %u * 2 * %u (%d != %d)\n",
n_0, n_2,
writer.pos, labcomm2014_sizeof_test_sample_test_var(NULL, &encoder_var));
exit(1);
}
if (writer.pos != expected) {
fprintf(stderr, "Unexpected size %u * 2 * %u (%d != %d)\n",
n_0, n_2,
writer.pos, expected);
exit(1);
}
}
static int do_test(int argc, char *argv[])
{
int i;
struct labcomm2014_decoder *decoder = labcomm2014_decoder_new(
&reader,
labcomm2014_default_error_handler,
labcomm2014_default_memory,
labcomm2014_default_scheduler);
struct expect expect_version[] = {
{ "Version", 1, test_decode_one, decoder },
{ 0, 0, 0 }
};
expect = expect_version;
struct labcomm2014_encoder *encoder = labcomm2014_encoder_new(
&writer,
labcomm2014_default_error_handler,
labcomm2014_default_memory,
labcomm2014_default_scheduler);
labcomm2014_decoder_register_test_sample_test_var(decoder,
handle_test_var,
NULL);
struct expect expect_registration[] = {
{ "Sampledef", -1, test_decode_one, decoder },
#ifdef SHOULD_THIS_BE_REMOVED
{ "Typedef", -1, test_decode_one, decoder },
#endif
{ "Binding", -1, test_decode_one, decoder },
{ 0, 0, 0 }
};
expect = expect_registration;
labcomm2014_encoder_register_test_sample_test_var(encoder);
test_encode_decode(encoder, decoder, 12, 1, 1);
if (decoder_var.a[0] != encoder_var.a[0]) {
fprintf(stderr, "Failed to decode correct value %d != %d\n",
encoder_var.a[0], decoder_var.a[0]);
exit(1);
}
test_encode_decode(encoder, decoder, 36, 2, 2);
test_encode_decode(encoder, decoder, 4, 0, 0);
for (i = 1 ; i <= 4 ; i++) {
test_encode_decode(encoder, decoder, 3+i, 0, (1<<(7*i))-1);
test_encode_decode(encoder, decoder, 4+i, 0, (1<<(7*i)));
}
test_encode_decode(encoder, decoder, 8, 0, 4294967295);
labcomm2014_encoder_free(encoder);
labcomm2014_decoder_free(decoder);
return 0;
}
int main(int argc, char *argv[])
{
return do_test(argc, argv);
}
lib/c/2014/test/test_labcomm_basic_type_encoding.c 0 → 100644
View file @ d3921882
/*
test_labcomm2014_basic_type_encoding.c -- LabComm tests of basic encoding
Copyright 2013 Anders Blomdell <anders.blomdell@control.lth.se>
This file is part of LabComm.
LabComm is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
LabComm is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#include <stdint.h>
#include <inttypes.h>
#include <string.h>
#include <stdlib.h>
#include "labcomm2014_private.h"
static int line;
static unsigned char buffer[128];
static struct labcomm2014_writer writer = {
.action_context = NULL,
.data = buffer,
.data_size = sizeof(buffer),
.count = sizeof(buffer),
.pos = 0,
.error = 0,
};
static struct labcomm2014_reader reader = {
.action_context = NULL,
.data = buffer,
.data_size = sizeof(buffer),
.count = 0,
.pos = 0,
};
typedef uint32_t packed32;
#define TEST_WRITE_READ(type, ltype, format, value, expect_count, expect_bytes) \
{ \
type decoded; \
line = __LINE__; \
writer.pos = 0; \
labcomm2014_write_##ltype(&writer, value); \
writer_assert(#ltype, expect_count, (uint8_t*)expect_bytes); \
reader.count = writer.pos; \
reader.pos = 0; \
decoded = labcomm2014_read_##ltype(&reader); \
if (decoded != value) { \
fprintf(stderr, "Decode error" format " != " format " @%s:%d \n", \
value, decoded, __FILE__, __LINE__); \
exit(1); \
} \
}
static void writer_assert(char *type,
int count,
uint8_t *bytes)
{
if (writer.pos != count) {
fprintf(stderr,
"Wrong number of bytes written for '%s' (%d != %d) @%s:%d\n",
type, writer.pos, count, __FILE__, line);
exit(1);
}
if (memcmp(writer.data, bytes, count) != 0) {
int i;
fprintf(stderr, "Wrong bytes written for '%s' ( ", type);
for (i = 0 ; i < count ; i++) {
fprintf(stderr, "%2.2x ", writer.data[i]);
}
fprintf(stderr, "!= ");
for (i = 0 ; i < count ; i++) {
fprintf(stderr, "%2.2x ", bytes[i]);
}
fprintf(stderr, ") @%s:%d\n", __FILE__, line);
exit(1);
}
}
static int do_test(int argc, char *argv[])
{
TEST_WRITE_READ(packed32, packed32, "%d", 0x0, 1, "\x00");
TEST_WRITE_READ(packed32, packed32, "%d", 0x7f, 1, "\x7f");
TEST_WRITE_READ(packed32, packed32, "%d", 0x80, 2, "\x81\x00");
TEST_WRITE_READ(packed32, packed32, "%d", 0x3fff, 2, "\xff\x7f");
TEST_WRITE_READ(packed32, packed32, "%d", 0x4000, 3, "\x81\x80\x00");
TEST_WRITE_READ(packed32, packed32, "%d", 0x1fffff, 3, "\xff\xff\x7f");
TEST_WRITE_READ(packed32, packed32, "%d", 0x200000, 4, "\x81\x80\x80\x00");
TEST_WRITE_READ(packed32, packed32, "%d", 0xfffffff, 4, "\xff\xff\xff\x7f");
TEST_WRITE_READ(packed32, packed32, "%d", 0x10000000, 5, "\x81\x80\x80\x80\x00");
TEST_WRITE_READ(packed32, packed32, "%d", 0xffffffff, 5, "\x8f\xff\xff\xff\x7f");
TEST_WRITE_READ(uint8_t, boolean, "%d", 0, 1, "\x00");
TEST_WRITE_READ(uint8_t, boolean, "%d", 1, 1, "\x01");
TEST_WRITE_READ(uint8_t, byte, "%d", 0, 1, "\x00");
TEST_WRITE_READ(uint8_t, byte, "%d", 1, 1, "\x01");
TEST_WRITE_READ(uint8_t, byte, "%d", 0xff, 1, "\xff");
TEST_WRITE_READ(int16_t, short, "%d", 0, 2, "\x00\x00");
TEST_WRITE_READ(int16_t, short, "%d", 0x7fff, 2, "\x7f\xff");
TEST_WRITE_READ(int16_t, short, "%d", -1, 2, "\xff\xff");
TEST_WRITE_READ(int32_t, int, "%d", 0, 4, "\x00\x00\x00\x00");
TEST_WRITE_READ(int32_t, int, "%d", 0x7fffffff, 4, "\x7f\xff\xff\xff");
TEST_WRITE_READ(int32_t, int, "%d", -1, 4, "\xff\xff\xff\xff");
TEST_WRITE_READ(int64_t, long, "%" PRId64, INT64_C(0), 8, "\x00\x00\x00\x00\x00\x00\x00\x00");
TEST_WRITE_READ(int64_t, long, "%" PRId64, INT64_C(0x7fffffffffffffff), 8, "\x7f\xff\xff\xff\xff\xff\xff\xff");
TEST_WRITE_READ(int64_t, long, "%" PRId64, INT64_C(-1), 8, "\xff\xff\xff\xff\xff\xff\xff\xff");
TEST_WRITE_READ(float, float, "%f", 0.0, 4, "\x00\x00\x00\x00");
TEST_WRITE_READ(float, float, "%f", 1.0, 4, "\x3f\x80\x00\x00");
TEST_WRITE_READ(float, float, "%f", 2.0, 4, "\x40\x00\x00\x00");
TEST_WRITE_READ(float, float, "%f", 0.5, 4, "\x3f\x00\x00\x00");
TEST_WRITE_READ(float, float, "%f", 0.25, 4, "\x3e\x80\x00\x00");
TEST_WRITE_READ(float, float, "%f", -0.0, 4, "\x80\x00\x00\x00");
TEST_WRITE_READ(float, float, "%f", -1.0, 4, "\xbf\x80\x00\x00");
TEST_WRITE_READ(float, float, "%f", -2.0, 4, "\xc0\x00\x00\x00");
TEST_WRITE_READ(float, float, "%f", -0.5, 4, "\xbf\x00\x00\x00");
TEST_WRITE_READ(float, float, "%f", -0.25, 4, "\xbe\x80\x00\x00");
TEST_WRITE_READ(double, double, "%f", 0.0, 8, "\x00\x00\x00\x00\x00\x00\x00\x00");
TEST_WRITE_READ(double, double, "%f", 1.0, 8, "\x3f\xf0\x00\x00\x00\x00\x00\x00");
TEST_WRITE_READ(double, double, "%f", 2.0, 8, "\x40\x00\x00\x00\x00\x00\x00\x00");
TEST_WRITE_READ(double, double, "%f", 0.5, 8, "\x3f\xe0\x00\x00\x00\x00\x00\x00");
TEST_WRITE_READ(double, double, "%f", 0.25, 8, "\x3f\xd0\x00\x00\x00\x00\x00\x00");
TEST_WRITE_READ(double, double, "%f", -0.0, 8, "\x80\x00\x00\x00\x00\x00\x00\x00");
TEST_WRITE_READ(double, double, "%f", -1.0, 8, "\xbf\xf0\x00\x00\x00\x00\x00\x00");
TEST_WRITE_READ(double, double, "%f", -2.0, 8, "\xc0\x00\x00\x00\x00\x00\x00\x00");
TEST_WRITE_READ(double, double, "%f", -0.5, 8, "\xbf\xe0\x00\x00\x00\x00\x00\x00");
TEST_WRITE_READ(double, double, "%f", -0.25, 8, "\xbf\xd0\x00\x00\x00\x00\x00\x00");
fprintf(stderr, "%s succeded\n", __FILE__);
return 0;
}
int main(int argc, char *argv[])
{
return do_test(argc, argv);
}
lib/c/2014/test/test_labcomm_copy.c 0 → 100644
View file @ d3921882
#include <stdlib.h>
#include <stdio.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <unistd.h>
#include <fcntl.h>
#include <assert.h>
#include <err.h>
#include "labcomm2014.h"
#include "labcomm2014_private.h"
#include "labcomm2014_default_error_handler.h"
#include "labcomm2014_default_memory.h"
#include "labcomm2014_default_scheduler.h"
#include "labcomm2014_fd_writer.h"
#include "labcomm2014_fd_reader.h"
#include "test/gen/generated_encoding.h"
#include "test/gen/test_sample.h"
#include "test/gen/more_types.h"
#define DATA_FILE "copy_test.dat"
static void handle_s1(generated_encoding_S1 *v, void *context)
{
labcomm2014_copy_generated_encoding_S1(labcomm2014_default_memory, context, v);
}
static void handle_b(generated_encoding_B *v, void *context)
{
labcomm2014_copy_generated_encoding_B(labcomm2014_default_memory, context, v);
}
static void handle_i(generated_encoding_I *v, void *context)
{
labcomm2014_copy_generated_encoding_I(labcomm2014_default_memory, context, v);
}
static void handle_p(generated_encoding_P *v, void *context)
{
labcomm2014_copy_generated_encoding_P(labcomm2014_default_memory, context, v);
}
static void handle_r(generated_encoding_R *v, void *context)
{
labcomm2014_copy_generated_encoding_R(labcomm2014_default_memory, context, v);
}
static void handle_test_var(test_sample_test_var *v, void *context)
{
labcomm2014_copy_test_sample_test_var(labcomm2014_default_memory, context, v);
}
static void handle_a(more_types_A *v, void *context)
{
labcomm2014_copy_more_types_A(labcomm2014_default_memory, context, v);
}
static void handle_s(more_types_S *v, void *context)
{
labcomm2014_copy_more_types_S(labcomm2014_default_memory, context, v);
}
static void handle_ns(more_types_NS *v, void *context)
{
labcomm2014_copy_more_types_NS(labcomm2014_default_memory, context, v);
}
static void handle_as(more_types_AS *v, void *context)
{
labcomm2014_copy_more_types_AS(labcomm2014_default_memory, context, v);
}
int do_test(int argc, char **argv)
{
struct labcomm2014_encoder *encoder;
struct labcomm2014_decoder *decoder;
int fd;
generated_encoding_S1 s1;
generated_encoding_S1 cache_s1;
generated_encoding_B b;
generated_encoding_B cache_b;
generated_encoding_I I;
generated_encoding_I cache_I;
generated_encoding_P p;
generated_encoding_P cache_p;
test_sample_test_var test_var;
test_sample_test_var cache_test_var;
more_types_A a;
more_types_A cache_a;
more_types_S s;
more_types_S cache_s = NULL;
more_types_NS ns;
more_types_NS cache_ns;
more_types_AS as;
more_types_AS cache_as;
generated_encoding_R r;
generated_encoding_R cache_r;
fd = open(DATA_FILE, O_RDWR | O_CREAT | O_TRUNC, 0644);
if (fd == -1)
err(1, "open()");
encoder =
labcomm2014_encoder_new(labcomm2014_fd_writer_new(labcomm2014_default_memory, fd, 0),
labcomm2014_default_error_handler,
labcomm2014_default_memory,
labcomm2014_default_scheduler);
labcomm2014_encoder_register_generated_encoding_S1(encoder);
s1.i = 1;
labcomm2014_encode_generated_encoding_S1(encoder, &s1);
labcomm2014_encoder_register_generated_encoding_B(encoder);
b = 2;
labcomm2014_encode_generated_encoding_B(encoder, &b);
labcomm2014_encoder_register_generated_encoding_I(encoder);
I.n_0 = 3;
I.a = calloc(I.n_0, sizeof(I.a[0]));
I.a[0] = 4;
I.a[1] = 5;
I.a[2] = 6;
labcomm2014_encode_generated_encoding_I(encoder, &I);
labcomm2014_encoder_register_generated_encoding_P(encoder);
p.n_0 = 7;
p.a = calloc(p.n_0, sizeof(p.a[0]));
for (int i = 0; i < p.n_0; i++)
p.a[i].i = 8 + i;
labcomm2014_encode_generated_encoding_P(encoder, &p);
labcomm2014_encoder_register_test_sample_test_var(encoder);
test_var.n_0 = 2;
test_var.n_2 = 7;
test_var.a = calloc(test_var.n_0 * 2 * test_var.n_2, sizeof(*test_var.a));
for (int i = 0; i < test_var.n_0; i++)
for (int j = 0; j < 2; j++)
for (int k = 0; k < test_var.n_2; k++) {
test_var.a[(((i) * 2 + j) * test_var.n_2) + k] = 100 * i + 10 * j + k;
}
labcomm2014_encode_test_sample_test_var(encoder, &test_var);
labcomm2014_encoder_register_more_types_A(encoder);
for (int i = 0; i < sizeof(a.a) / sizeof(a.a[0]); i++)
a.a[i] = i;
labcomm2014_encode_more_types_A(encoder, &a);
labcomm2014_encoder_register_more_types_S(encoder);
s = "this is a string";
labcomm2014_encode_more_types_S(encoder, &s);
labcomm2014_encoder_register_more_types_NS(encoder);
ns.s1 = "this is a string";
ns.s2 = "this is a another string";
labcomm2014_encode_more_types_NS(encoder, &ns);
labcomm2014_encoder_register_more_types_AS(encoder);
as.n_0 = 3;
as.a = calloc(as.n_0, sizeof(as.a[0]));
as.a[0] = "string 0";
as.a[1] = "string 1";
as.a[2] = "string 2";
labcomm2014_encode_more_types_AS(encoder, &as);
labcomm2014_encoder_register_generated_encoding_R(encoder);
labcomm2014_encoder_sample_ref_register(encoder, labcomm2014_signature_generated_encoding_V);
labcomm2014_encoder_sample_ref_register(encoder,
labcomm2014_signature_generated_encoding_UnusedD);
labcomm2014_encoder_sample_ref_register(encoder, labcomm2014_signature_generated_encoding_R);
r.a[0] = labcomm2014_encoder_get_sample_ref(
encoder, labcomm2014_signature_generated_encoding_V);
r.a[1] = labcomm2014_encoder_get_sample_ref(
encoder, labcomm2014_signature_generated_encoding_UnusedE);
r.a[2] = labcomm2014_encoder_get_sample_ref(
encoder, labcomm2014_signature_generated_encoding_UnusedD);
r.a[3] = labcomm2014_encoder_get_sample_ref(
encoder, labcomm2014_signature_generated_encoding_R);
labcomm2014_encode_generated_encoding_R(encoder, &r);
labcomm2014_encoder_free(encoder);
encoder = NULL;
lseek(fd, 0, SEEK_SET);
decoder =
labcomm2014_decoder_new(labcomm2014_fd_reader_new(labcomm2014_default_memory, fd, 0),
labcomm2014_default_error_handler,
labcomm2014_default_memory,
labcomm2014_default_scheduler);
labcomm2014_decoder_register_generated_encoding_S1(decoder, handle_s1, &cache_s1);
labcomm2014_decoder_register_generated_encoding_B(decoder, handle_b, &cache_b);
labcomm2014_decoder_register_generated_encoding_I(decoder, handle_i, &cache_I);
labcomm2014_decoder_register_generated_encoding_P(decoder, handle_p, &cache_p);
labcomm2014_decoder_register_test_sample_test_var(decoder, handle_test_var,
&cache_test_var);
labcomm2014_decoder_register_more_types_A(decoder, handle_a, &cache_a);
labcomm2014_decoder_register_more_types_S(decoder, handle_s, &cache_s);
labcomm2014_decoder_register_more_types_NS(decoder, handle_ns, &cache_ns);
labcomm2014_decoder_register_more_types_AS(decoder, handle_as, &cache_as);
labcomm2014_decoder_register_generated_encoding_R(decoder, handle_r, &cache_r);
labcomm2014_decoder_sample_ref_register(decoder, labcomm2014_signature_generated_encoding_V);
labcomm2014_decoder_sample_ref_register(decoder,
labcomm2014_signature_generated_encoding_UnusedE);
labcomm2014_decoder_sample_ref_register(decoder, labcomm2014_signature_generated_encoding_R);
while (labcomm2014_decoder_decode_one(decoder) > 0) ;
printf("cache_s1.i = %d, s1.i = %d\n", cache_s1.i, s1.i);
assert(cache_s1.i == s1.i);
puts("S1 copied ok");
assert(cache_b == b);
puts("B copied ok");
assert(cache_I.n_0 == I.n_0);
assert(cache_I.a[0] == I.a[0]);
assert(cache_I.a[1] == I.a[1]);
assert(cache_I.a[2] == I.a[2]);
free(I.a);
puts("I copied ok");
assert(cache_p.n_0 == p.n_0);
for (int i = 0; i < p.n_0; i++)
assert(cache_p.a[i].i == p.a[i].i);
free(p.a);
puts("P copied ok");
assert(cache_test_var.n_0 == test_var.n_0);
assert(cache_test_var.n_2 == test_var.n_2);
for (int i = 0; i < test_var.n_0; i++)
for (int j = 0; j < 2; j++)
for (int k = 0; k < test_var.n_2; k++) {
assert(cache_test_var.a[(((i) * 2 + j) * test_var.n_2) + k] ==
test_var.a[(((i) * 2 + j) * test_var.n_2) + k]);
assert(cache_test_var.a[(((i) * 2 + j) * test_var.n_2) + k] ==
100 * i + 10 * j + k);
}
free(test_var.a);
puts("test_var copied ok");
for (int i = 0; i < sizeof(a.a) / sizeof(a.a[0]); i++)
assert(cache_a.a[i] == a.a[i]);
puts("A copied ok");
assert(!strcmp(cache_s, s));
puts("S copied ok");
assert(!strcmp(cache_ns.s1, ns.s1));
assert(!strcmp(cache_ns.s2, ns.s2));
puts("NS copied ok");
for (int i = 0; i < as.n_0; i++)
assert(!strcmp(cache_as.a[i], as.a[i]));
free(as.a);
puts("AS copied ok");
fprintf(stderr, "%p %p\n", r.a[0], cache_r.a[0]);
fprintf(stderr, "%p %p\n", r.a[1], cache_r.a[1]);
fprintf(stderr, "%p %p\n", r.a[2], cache_r.a[2]);
fprintf(stderr, "%p %p\n", r.a[3], cache_r.a[3]);
assert(cache_r.a[0] == r.a[0]);
assert(cache_r.a[1] == NULL); /* UnusedE */
assert(cache_r.a[2] == NULL); /* UnusedD */
assert(cache_r.a[3] == r.a[3]);
puts("R copied ok");
labcomm2014_decoder_free(decoder);
close(fd);
unlink(DATA_FILE);
labcomm2014_copy_free_generated_encoding_S1(labcomm2014_default_memory, &cache_s1);
puts("S1 deallocated ok");
labcomm2014_copy_free_generated_encoding_B(labcomm2014_default_memory, &cache_b);
puts("B deallocated ok");
labcomm2014_copy_free_generated_encoding_I(labcomm2014_default_memory, &cache_I);
puts("I deallocated ok");
labcomm2014_copy_free_generated_encoding_P(labcomm2014_default_memory, &cache_p);
puts("P deallocated ok");
labcomm2014_copy_free_test_sample_test_var(labcomm2014_default_memory, &cache_test_var);
puts("test_var deallocated ok");
labcomm2014_copy_free_more_types_A(labcomm2014_default_memory, &cache_a);
puts("A deallocated ok");
labcomm2014_copy_free_more_types_S(labcomm2014_default_memory, &cache_s);
puts("S deallocated ok");
labcomm2014_copy_free_more_types_NS(labcomm2014_default_memory, &cache_ns);
puts("NS deallocated ok");
labcomm2014_copy_free_more_types_AS(labcomm2014_default_memory, &cache_as);
puts("AS deallocated ok");
labcomm2014_copy_free_generated_encoding_R(labcomm2014_default_memory,
&cache_r);
puts("R deallocated ok");
return 0;
}
int main(int argc, char **argv)
{
return do_test(argc, argv);
}
lib/c/2014/test/test_labcomm_errors.c 0 → 100644
View file @ d3921882
#include "test_labcomm_errors.h"
#include <stdlib.h>
#include <labcomm.h>
#include <labcomm_private.h>
#include <labcomm_mem_writer.h>
#include <labcomm_mem_reader.h>
static enum labcomm_error callback_error_id;
int assert_callback(enum labcomm_error expected, const char *name, const char *err_msg)
{
int success;
printf("----> %s()\n", name);
if (callback_error_id == expected) {
printf("Succeeded.\n");
success = 1;
} else {
printf("Failed! %s\n", err_msg);
success = 0;
}
return success;
}
/* Our callback that just logs which error_id that the library reported. */
void test_callback(enum labcomm_error error_id, size_t nbr_va_args, ...)
{
va_list arg_pointer;
va_start(arg_pointer, nbr_va_args);
va_end(arg_pointer);
callback_error_id = error_id;
}
void reset_callback_erro_id()
{
callback_error_id = -128;
}
int encoded_size_mock(struct labcomm_signature *signature, void *voidp)
{
return 0;
}
int test_enc_not_reg_encoder_sign()
{
reset_callback_erro_id();
unsigned char *buf = (unsigned char *) "a";
labcomm_mem_writer_context_t *mcontext = labcomm_mem_writer_context_t_new(0, 1, buf);
labcomm_encoder_t *encoder = labcomm_encoder_new(labcomm_mem_writer, mcontext);
labcomm_register_error_handler_encoder(encoder, test_callback);
labcomm_signature_t signature = {
.type = 0,
.name = "test_signature",
.encoded_size = encoded_size_mock,
.size = 0,
.signature = (unsigned char *) "0"};
encoder->do_encode(encoder, &signature, NULL);
return assert_callback(LABCOMM_ERROR_ENC_NO_REG_SIGNATURE, __FUNCTION__, "");
}
int test_enc_missing_do_reg()
{
reset_callback_erro_id();
unsigned char *buf = (unsigned char *) "a";
labcomm_mem_writer_context_t *mcontext = labcomm_mem_writer_context_t_new(0, 1, buf);
labcomm_encoder_t *encoder = labcomm_encoder_new(labcomm_mem_writer, mcontext);
labcomm_register_error_handler_encoder(encoder, test_callback);
encoder->do_register = NULL;
labcomm_internal_encoder_register(encoder, NULL, NULL);
return assert_callback(LABCOMM_ERROR_ENC_MISSING_DO_REG, __FUNCTION__, "");
}
int test_enc_missing_do_encode()
{
reset_callback_erro_id();
unsigned char *buf = (unsigned char *) "a";
labcomm_mem_writer_context_t *mcontext = labcomm_mem_writer_context_t_new(0, 1, buf);
labcomm_encoder_t *encoder = labcomm_encoder_new(labcomm_mem_writer, mcontext);
labcomm_register_error_handler_encoder(encoder, test_callback);
encoder->do_encode = NULL;
labcomm_internal_encode(encoder, NULL, NULL);
return assert_callback(LABCOMM_ERROR_ENC_MISSING_DO_ENCODE, __FUNCTION__, "");
}
int test_enc_buf_full()
{
reset_callback_erro_id();
unsigned char *buf = (unsigned char *) "a";
labcomm_mem_writer_context_t *mcontext = labcomm_mem_writer_context_t_new(0, 1, buf);
labcomm_encoder_t *encoder = labcomm_encoder_new(labcomm_mem_writer, mcontext);
labcomm_register_error_handler_encoder(encoder, test_callback);
unsigned char *mbuf = mcontext->buf;
labcomm_writer_t writer = encoder->writer;
writer.data = malloc(1);
writer.pos = 1;
mcontext->write_pos = 1;
test_copy_data(&writer, mcontext, mbuf);
return assert_callback(LABCOMM_ERROR_ENC_BUF_FULL, __FUNCTION__, "");
}
void labcomm_decoder_typecast_t_mock(struct labcomm_decoder *decoder, labcomm_handler_typecast_t handler, void *voidp)
{
;
}
void labcomm_handler_typecast_t_mock(void *arg1, void *arg2)
{
;
}
int test_dec_missing_do_reg()
{
reset_callback_erro_id();
unsigned char *buf = (unsigned char *) "a";
labcomm_mem_reader_context_t *mcontext = (labcomm_mem_reader_context_t *) malloc(sizeof(labcomm_mem_reader_context_t));
labcomm_decoder_t *decoder = labcomm_decoder_new(labcomm_mem_reader, mcontext);
labcomm_register_error_handler_decoder(decoder, test_callback);
decoder->do_register = NULL;
labcomm_internal_decoder_register(decoder, NULL, labcomm_decoder_typecast_t_mock, labcomm_handler_typecast_t_mock, buf);
return assert_callback(LABCOMM_ERROR_DEC_MISSING_DO_REG, __FUNCTION__, "");
}
int test_dec_missing_do_decode_one()
{
reset_callback_erro_id();
labcomm_mem_reader_context_t *mcontext = (labcomm_mem_reader_context_t *) malloc(sizeof(labcomm_mem_reader_context_t));
labcomm_decoder_t *decoder = labcomm_decoder_new(labcomm_mem_reader, mcontext);
labcomm_register_error_handler_decoder(decoder, test_callback);
decoder->do_decode_one = NULL;
labcomm_decoder_decode_one(decoder);
return assert_callback(LABCOMM_ERROR_DEC_MISSING_DO_DECODE_ONE, __FUNCTION__, "");
}
int main()
{
printf("####> Begin tests.\n");
unsigned int nbr_succeed = 0;
unsigned int nbr_tests = 6; // Increment this when new tests are written.
nbr_succeed += test_enc_not_reg_encoder_sign();
nbr_succeed += test_enc_missing_do_reg();
nbr_succeed += test_enc_missing_do_encode();
nbr_succeed += test_enc_buf_full();
nbr_succeed += test_dec_missing_do_reg();
nbr_succeed += test_dec_missing_do_decode_one();
// Too tedius to test really...
//nbr_succeed += test_dec_unknown_datatype();
//nbr_succeed += test_dec_index_mismatch();
//nbr_succeed += test_dec_type_not_found();
//nbr_succeed += test_unimplemented_func(); // This test will be obsolete in the future ;-)
//nbr_succeed += test_user_def(); // There are no user defined errors in the library of course.
printf("####> End tests.\nSummary: %u/%u tests succeed.\n", nbr_succeed, nbr_tests);
if (nbr_succeed == nbr_tests) {
return EXIT_SUCCESS;
} else {
return EXIT_FAILURE;
}
}
lib/c/2014/test/test_labcomm_errors.h 0 → 100644
View file @ d3921882
#ifndef TEST_LABCOMM_ERRORS_H
#define TEST_LABCOMM_ERRORS_H
void test_not_reg_encoder_sign();
#endif
lib/c/2014/test/test_labcomm_generated_encoding.c 0 → 100644
View file @ d3921882
/*
test_labcomm2014_generated_encoding.c -- LabComm tests of generated encoding
Copyright 2013 Anders Blomdell <anders.blomdell@control.lth.se>
This file is part of LabComm.
LabComm is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
LabComm is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#include <stdint.h>
#include <stdlib.h>
#include <string.h>
#include <errno.h>
#include "labcomm2014_private.h"
#include "labcomm2014_default_error_handler.h"
#include "labcomm2014_default_memory.h"
#include "labcomm2014_pthread_scheduler.h"
#include "test/gen/generated_encoding.h"
#define IOCTL_WRITER_ASSERT_BYTES 4096
#define IOCTL_WRITER_RESET 4097
#define EXPECT(...) \
{ \
int expected[] = __VA_ARGS__; \
labcomm2014_encoder_ioctl(encoder, IOCTL_WRITER_ASSERT_BYTES, \
__LINE__, \
sizeof(expected)/sizeof(expected[0]), \
expected); \
}
#define VARIABLE(i) -(i + 1)
#define IS_VARIABLE(i) (i < 0)
static unsigned char buffer[128];
struct labcomm2014_writer *writer;
static int seen_variable[1024];
static int buf_writer_alloc(
struct labcomm2014_writer *w,
struct labcomm2014_writer_action_context *action_context)
{
writer = w; /* Hack */
w->data_size = sizeof(buffer);
w->count = w->data_size;
w->data = buffer;
w->pos = 0;
return 0;
}
static int buf_writer_free(
struct labcomm2014_writer *w,
struct labcomm2014_writer_action_context *action_context)
{
return 0;
}
static int buf_writer_start(
struct labcomm2014_writer *w,
struct labcomm2014_writer_action_context *action_context,
int index,
const struct labcomm2014_signature *signature,
void *value)
{
return 0;
}
static int buf_writer_end(
struct labcomm2014_writer *w,
struct labcomm2014_writer_action_context *action_context)
{
return 0;
}
static int buf_writer_flush(
struct labcomm2014_writer *w,
struct labcomm2014_writer_action_context *action_context)
{
fprintf(stderr, "Should not come here %s:%d\n", __FILE__, __LINE__);
exit(1);
return 0;
}
static int buf_writer_ioctl(
struct labcomm2014_writer *w,
struct labcomm2014_writer_action_context *action_context,
int signature_index, const struct labcomm2014_signature *signature,
uint32_t action, va_list arg)
{
int result = -ENOTSUP;
switch (action) {
case IOCTL_WRITER_ASSERT_BYTES: {
int line = va_arg(arg, int);
int count = va_arg(arg, int);
int *expected = va_arg(arg, int *);
int i, mismatch;
mismatch = 0;
if (w->pos != count) {
fprintf(stderr, "Invalid length detected %d != %d (%s:%d)\n",
w->pos, count, __FILE__, line);
mismatch = 1;
}
for (i = 0 ; i < count ; i++) {
if (IS_VARIABLE(expected[i])) {
if (seen_variable[VARIABLE(expected[i])] == -1) {
seen_variable[VARIABLE(expected[i])] = buffer[i];
}
if (seen_variable[VARIABLE(expected[i])] != buffer[i]) {
fprintf(stderr, "Unexpected variable (%d: != %d)\n",
seen_variable[VARIABLE(expected[i])], buffer[i]);
mismatch = 1;
}
} else if (expected[i] != buffer[i]) {
mismatch = 1;
}
}
if (mismatch) {
fprintf(stderr, "Encoder mismatch (%s:%d)\n",
__FILE__, line);
for (i = 0 ; i < w->pos ; i++) {
printf("%2.2x ", w->data[i]);
}
printf("\n");
for (i = 0 ; i < count ; i++) {
if (expected[i] < 0) {
printf("v%d ", VARIABLE(expected[i]));
} else {
printf("%2.2x ", expected[i] );
}
}
printf("\n");
exit(1);
}
result = 0;
} break;
case IOCTL_WRITER_RESET: {
w->pos = 0;
result = 0;
}
}
return result;
}
const struct labcomm2014_writer_action writer_action = {
.alloc = buf_writer_alloc,
.free = buf_writer_free,
.start = buf_writer_start,
.end = buf_writer_end,
.flush = buf_writer_flush,
.ioctl = buf_writer_ioctl
};
static struct labcomm2014_writer_action_context action_context = {
.next = NULL,
.action = &writer_action,
.context = NULL
};
static struct labcomm2014_writer buffer_writer = {
.action_context = &action_context,
.data = buffer,
.data_size = sizeof(buffer),
.count = sizeof(buffer),
.pos = 0,
.error = 0,
};
void dump_encoder(struct labcomm2014_encoder *encoder)
{
int i;
for (i = 0 ; i < writer->pos ; i++) {
printf("%2.2x ", writer->data[i]);
}
printf("\n");
}
int main(void)
{
generated_encoding_B B = 1;
generated_encoding_R R;
struct labcomm2014_encoder *encoder;
int i;
for (i = 0 ; i < sizeof(seen_variable)/sizeof(seen_variable[0]) ; i++) {
seen_variable[i] = -1;
}
encoder = labcomm2014_encoder_new(
&buffer_writer,
labcomm2014_default_error_handler,
labcomm2014_default_memory,
labcomm2014_pthread_scheduler_new(labcomm2014_default_memory));
EXPECT({ 0x01, 0x0c, 0x0b,
'L', 'a', 'b', 'C', 'o', 'm', 'm', '2','0', '1', '4' });
labcomm2014_encoder_ioctl(encoder, IOCTL_WRITER_RESET);
/* Register twice to make sure that only one registration gets encoded */
labcomm2014_encoder_register_generated_encoding_V(encoder);
labcomm2014_encoder_register_generated_encoding_V(encoder);
EXPECT({ 0x02, 0x08, VARIABLE(0), 0x01, 0x00, 0x01, 'V', 0x02, 0x11, 0x00,
0x04, 0x0a, VARIABLE(1), 0x01, 0x00, 0x03, 'v', '_', 't', 0x02, 0x11, 0x00,
0x04, 0x07, VARIABLE(2), 0x01, 0x00, 0x01, 'V', 0x01, VARIABLE(1),
0x05, 0x02, VARIABLE(0), VARIABLE(2) });
labcomm2014_encoder_ioctl(encoder, IOCTL_WRITER_RESET);
/* Register twice to make sure that only one registration gets encoded */
labcomm2014_encoder_register_generated_encoding_B(encoder);
labcomm2014_encoder_register_generated_encoding_B(encoder);
EXPECT({ 0x02, 0x07, VARIABLE(3),0x01, 0x00, 0x01, 'B', 0x01, 0x21,
0x05, 0x02, VARIABLE(3), LABCOMM_BIND_SELF });
labcomm2014_encoder_ioctl(encoder, IOCTL_WRITER_RESET);
/* Register twice to make sure that only one registration gets encoded */
labcomm2014_encoder_register_generated_encoding_R(encoder);
labcomm2014_encoder_register_generated_encoding_R(encoder);
EXPECT({ 0x02, 0x0a, VARIABLE(4), 0x01, 0x00, 0x01, 'R', 0x04, 0x10, 0x01, 0x04, 0x28,
0x05, 0x02, VARIABLE(4), LABCOMM_BIND_SELF });
labcomm2014_encoder_ioctl(encoder, IOCTL_WRITER_RESET);
/* Register twice to make sure that only one registration gets encoded */
labcomm2014_encoder_sample_ref_register(encoder,
labcomm2014_signature_generated_encoding_V);
labcomm2014_encoder_sample_ref_register(encoder,
labcomm2014_signature_generated_encoding_V);
EXPECT({0x03, 0x08, VARIABLE(5), 0x01, 0x00, 0x01, 'V', 0x02, 0x11, 0x00});
labcomm2014_encoder_ioctl(encoder, IOCTL_WRITER_RESET);
/* Register twice to make sure that only one registration gets encoded */
labcomm2014_encoder_sample_ref_register(encoder,
labcomm2014_signature_generated_encoding_B);
labcomm2014_encoder_sample_ref_register(encoder,
labcomm2014_signature_generated_encoding_B);
EXPECT({0x03, 0x07, VARIABLE(6), 0x01, 0x00, 0x01, 'B', 0x01, 0x21});
labcomm2014_encoder_ioctl(encoder, IOCTL_WRITER_RESET);
/* Register twice to make sure that only one registration gets encoded */
labcomm2014_encoder_sample_ref_register(encoder,
labcomm2014_signature_generated_encoding_R);
labcomm2014_encoder_sample_ref_register(encoder,
labcomm2014_signature_generated_encoding_R);
EXPECT({0x03, 0x0a, VARIABLE(7), 0x01, 0x00, 0x01, 'R', 0x04, 0x10, 0x01, 0x04, 0x28});
labcomm2014_encoder_ioctl(encoder, IOCTL_WRITER_RESET);
// was: labcomm2014_encode_generated_encoding_V(encoder, &V);
labcomm2014_encode_generated_encoding_V(encoder);
EXPECT({VARIABLE(10), 0x00 });
labcomm2014_encoder_ioctl(encoder, IOCTL_WRITER_RESET);
labcomm2014_encode_generated_encoding_B(encoder, &B);
EXPECT({VARIABLE(20), 0x01, 1});
labcomm2014_encoder_ioctl(encoder, IOCTL_WRITER_RESET);
R.a[0] = labcomm2014_encoder_get_sample_ref(
encoder, labcomm2014_signature_generated_encoding_V);
R.a[1] = labcomm2014_encoder_get_sample_ref(
encoder, labcomm2014_signature_generated_encoding_B);
R.a[2] = labcomm2014_encoder_get_sample_ref(
encoder, labcomm2014_signature_generated_encoding_UnusedE);
R.a[3] = labcomm2014_encoder_get_sample_ref(
encoder, labcomm2014_signature_generated_encoding_R);
labcomm2014_encode_generated_encoding_R(encoder, &R);
EXPECT({VARIABLE(4), 0x10, 0x00, 0x00, 0x00, VARIABLE(5),
0x00, 0x00, 0x00, VARIABLE(6),
0x00, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, VARIABLE(7)});
return 0;
}
lib/c/2014/test/test_labcomm_pthread_scheduler.c 0 → 100644
View file @ d3921882
/*
test_labcomm2014_pthread_scheduler.c -- test labcomm2014 pthread based task
coordination
Copyright 2013 Anders Blomdell <anders.blomdell@control.lth.se>
This file is part of LabComm.
LabComm is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
LabComm is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#include <stdio.h>
#include <stdlib.h>
#include "labcomm2014_default_memory.h"
#include "labcomm2014_scheduler.h"
#include "labcomm2014_pthread_scheduler.h"
#define TICK 100000
struct func_arg {
struct labcomm2014_scheduler *scheduler;
int i;
};
static void func(void *arg)
{
struct func_arg *func_arg = arg;
printf("%p %d\n", arg, func_arg->i);
if (func_arg->i == 999) {
labcomm2014_scheduler_wakeup(func_arg->scheduler);
}
free(func_arg);
}
void enqueue(struct labcomm2014_scheduler *scheduler,
int first, int last)
{
int i;
for (i = first ; i <= last ; i++) {
struct func_arg *tmp = malloc(sizeof(*tmp));
tmp->scheduler = scheduler;
tmp->i = i;
labcomm2014_scheduler_enqueue(scheduler, i*TICK, func, tmp);
}
}
static int do_test(int argc, char *argv[])
{
struct labcomm2014_scheduler *scheduler;
struct labcomm2014_time *time;
scheduler = labcomm2014_pthread_scheduler_new(labcomm2014_default_memory);
enqueue(scheduler, 0, 5);
enqueue(scheduler, 0, 1);
enqueue(scheduler, 1, 3);
enqueue(scheduler, 7, 10);
{
struct func_arg *tmp = malloc(sizeof(*tmp));
tmp->scheduler = scheduler;
tmp->i = 999;
labcomm2014_scheduler_enqueue(scheduler, 6*TICK, func, tmp);
}
time = labcomm2014_scheduler_now(scheduler);
labcomm2014_time_add_usec(time, 12*TICK);
labcomm2014_scheduler_sleep(scheduler, NULL);
labcomm2014_scheduler_sleep(scheduler, time);
labcomm2014_time_free(time);
labcomm2014_scheduler_free(scheduler);
return 0;
}
int main(int argc, char *argv[])
{
return do_test(argc, argv);
}
lib/c/2014/test/test_labcomm_renaming_decoder.c 0 → 100644
View file @ d3921882
#include <stdlib.h>
#include <stdio.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <unistd.h>
#include <fcntl.h>
#include <assert.h>
#include <err.h>
#include "labcomm2014.h"
#include "labcomm2014_private.h"
#include "labcomm2014_default_error_handler.h"
#include "labcomm2014_default_memory.h"
#include "labcomm2014_default_scheduler.h"
#include "labcomm2014_fd_writer.h"
#include "labcomm2014_fd_reader.h"
#include "labcomm2014_renaming.h"
#include "labcomm2014_renaming_encoder.h"
#include "labcomm2014_renaming_decoder.h"
#include "test/gen/generated_encoding.h"
#define DATA_FILE "renaming_test.dat"
static void handle_r(generated_encoding_R *v, void *context)
{
labcomm2014_copy_generated_encoding_R(labcomm2014_default_memory, context, v);
}
int main(int argc, char **argv)
{
struct labcomm2014_renaming_registry *registry;
struct labcomm2014_encoder *encoder, *prefix_encoder, *suffix_encoder;
struct labcomm2014_decoder *decoder, *prefix_decoder, *suffix_decoder;
int fd;
generated_encoding_R r;
generated_encoding_R cache_r, prefix_cache_r, suffix_cache_r;
fd = open(DATA_FILE, O_RDWR | O_CREAT | O_TRUNC, 0644);
if (fd == -1) {
err(1, "open()");
}
registry = labcomm2014_renaming_registry_new(
labcomm2014_default_error_handler,
labcomm2014_default_memory,
labcomm2014_default_scheduler);
encoder = labcomm2014_encoder_new(
labcomm2014_fd_writer_new(labcomm2014_default_memory, fd, 0),
labcomm2014_default_error_handler,
labcomm2014_default_memory,
labcomm2014_default_scheduler);
prefix_encoder = labcomm2014_renaming_encoder_new(
encoder, registry, labcomm2014_renaming_prefix, "p.");
suffix_encoder = labcomm2014_renaming_encoder_new(
prefix_encoder, registry, labcomm2014_renaming_suffix, ".s");
labcomm2014_encoder_register_generated_encoding_R(encoder);
labcomm2014_encoder_register_generated_encoding_R(prefix_encoder);
labcomm2014_encoder_register_generated_encoding_R(suffix_encoder);
labcomm2014_encoder_sample_ref_register(
encoder, labcomm2014_signature_generated_encoding_R);
labcomm2014_encoder_sample_ref_register(
prefix_encoder, labcomm2014_signature_generated_encoding_R);
labcomm2014_encoder_sample_ref_register(
suffix_encoder, labcomm2014_signature_generated_encoding_R);
r.a[0] = labcomm2014_encoder_get_sample_ref(
encoder, labcomm2014_signature_generated_encoding_R);
r.a[1] = labcomm2014_encoder_get_sample_ref(
prefix_encoder, labcomm2014_signature_generated_encoding_R);
r.a[2] = labcomm2014_encoder_get_sample_ref(
suffix_encoder, labcomm2014_signature_generated_encoding_R);
r.a[3] = labcomm2014_encoder_get_sample_ref(
encoder, labcomm2014_signature_generated_encoding_R);
labcomm2014_encode_generated_encoding_R(encoder, &r);
r.a[3] = labcomm2014_encoder_get_sample_ref(
prefix_encoder, labcomm2014_signature_generated_encoding_R);
labcomm2014_encode_generated_encoding_R(prefix_encoder, &r);
r.a[3] = labcomm2014_encoder_get_sample_ref(
suffix_encoder, labcomm2014_signature_generated_encoding_R);
labcomm2014_encode_generated_encoding_R(suffix_encoder, &r);
labcomm2014_encoder_free(suffix_encoder);
labcomm2014_encoder_free(prefix_encoder);
labcomm2014_encoder_free(encoder);
encoder = NULL;
lseek(fd, 0, SEEK_SET);
decoder =
labcomm2014_decoder_new(
labcomm2014_fd_reader_new(labcomm2014_default_memory, fd, 0),
labcomm2014_default_error_handler,
labcomm2014_default_memory,
labcomm2014_default_scheduler);
prefix_decoder = labcomm2014_renaming_decoder_new(
decoder, registry, labcomm2014_renaming_prefix, "p.");
suffix_decoder = labcomm2014_renaming_decoder_new(
prefix_decoder, registry, labcomm2014_renaming_suffix, ".s");
labcomm2014_decoder_register_generated_encoding_R(
decoder, handle_r, &cache_r);
labcomm2014_decoder_register_generated_encoding_R(
prefix_decoder, handle_r, &prefix_cache_r);
labcomm2014_decoder_register_generated_encoding_R(
suffix_decoder, handle_r, &suffix_cache_r);
labcomm2014_decoder_sample_ref_register(
decoder, labcomm2014_signature_generated_encoding_R);
labcomm2014_decoder_sample_ref_register(
prefix_decoder, labcomm2014_signature_generated_encoding_R);
labcomm2014_decoder_sample_ref_register(
suffix_decoder, labcomm2014_signature_generated_encoding_R);
while (labcomm2014_decoder_decode_one(decoder) > 0) ;
fprintf(stderr, "cache_r:\n");
fprintf(stderr, "%p %p %p %p\n",
cache_r.a[0],
cache_r.a[1],
cache_r.a[2],
cache_r.a[3]);
fprintf(stderr, "prefix_cache_r:\n");
fprintf(stderr, "%p %p %p %p\n",
prefix_cache_r.a[0],
prefix_cache_r.a[1],
prefix_cache_r.a[2],
prefix_cache_r.a[3]);
fprintf(stderr, "suffix_cache_r:\n");
fprintf(stderr, "%p %p %p %p\n",
suffix_cache_r.a[0],
suffix_cache_r.a[1],
suffix_cache_r.a[2],
suffix_cache_r.a[3]);
assert(cache_r.a[0] ==
labcomm2014_decoder_get_sample_ref(
decoder, labcomm2014_signature_generated_encoding_R));
assert(cache_r.a[1] ==
labcomm2014_decoder_get_sample_ref(
prefix_decoder, labcomm2014_signature_generated_encoding_R));
assert(cache_r.a[2] ==
labcomm2014_decoder_get_sample_ref(
suffix_decoder, labcomm2014_signature_generated_encoding_R));
assert(cache_r.a[3] ==
labcomm2014_decoder_get_sample_ref(
decoder, labcomm2014_signature_generated_encoding_R));
assert(prefix_cache_r.a[0] ==
labcomm2014_decoder_get_sample_ref(
decoder, labcomm2014_signature_generated_encoding_R));
assert(prefix_cache_r.a[1] ==
labcomm2014_decoder_get_sample_ref(
prefix_decoder, labcomm2014_signature_generated_encoding_R));
assert(prefix_cache_r.a[2] ==
labcomm2014_decoder_get_sample_ref(
suffix_decoder, labcomm2014_signature_generated_encoding_R));
assert(prefix_cache_r.a[3] ==
labcomm2014_decoder_get_sample_ref(
prefix_decoder, labcomm2014_signature_generated_encoding_R));
assert(suffix_cache_r.a[0] ==
labcomm2014_decoder_get_sample_ref(
decoder, labcomm2014_signature_generated_encoding_R));
assert(suffix_cache_r.a[1] ==
labcomm2014_decoder_get_sample_ref(
prefix_decoder, labcomm2014_signature_generated_encoding_R));
assert(suffix_cache_r.a[2] ==
labcomm2014_decoder_get_sample_ref(
suffix_decoder, labcomm2014_signature_generated_encoding_R));
assert(suffix_cache_r.a[3] ==
labcomm2014_decoder_get_sample_ref(
suffix_decoder, labcomm2014_signature_generated_encoding_R));
labcomm2014_decoder_free(suffix_decoder);
labcomm2014_decoder_free(prefix_decoder);
labcomm2014_decoder_free(decoder);
labcomm2014_renaming_registry_free(registry);
close(fd);
unlink(DATA_FILE);
}