unleashed-firmware/applications/external/protoview/fields.c
2023-03-15 01:25:18 +03:00

369 lines
12 KiB
C

/* Copyright (C) 2022-2023 Salvatore Sanfilippo -- All Rights Reserved
* See the LICENSE file for information about the license.
*
* Protocol fields implementation. */
#include "app.h"
/* Create a new field of the specified type. Without populating its
* type-specific value. */
static ProtoViewField* field_new(ProtoViewFieldType type, const char* name) {
ProtoViewField* f = malloc(sizeof(*f));
f->type = type;
f->name = strdup(name);
return f;
}
/* Free only the auxiliary data of a field, used to represent the
* current type. Name and type are not touched. */
static void field_free_aux_data(ProtoViewField* f) {
switch(f->type) {
case FieldTypeStr:
free(f->str);
break;
case FieldTypeBytes:
free(f->bytes);
break;
default:
break; // Nothing to free for other types.
}
}
/* Free a field an associated data. */
static void field_free(ProtoViewField* f) {
field_free_aux_data(f);
free(f->name);
free(f);
}
/* Return the type of the field as string. */
const char* field_get_type_name(ProtoViewField* f) {
switch(f->type) {
case FieldTypeStr:
return "str";
case FieldTypeSignedInt:
return "int";
case FieldTypeUnsignedInt:
return "uint";
case FieldTypeBinary:
return "bin";
case FieldTypeHex:
return "hex";
case FieldTypeBytes:
return "bytes";
case FieldTypeFloat:
return "float";
}
return "unknown";
}
/* Set a string representation of the specified field in buf. */
int field_to_string(char* buf, size_t len, ProtoViewField* f) {
switch(f->type) {
case FieldTypeStr:
return snprintf(buf, len, "%s", f->str);
case FieldTypeSignedInt:
return snprintf(buf, len, "%lld", (long long)f->value);
case FieldTypeUnsignedInt:
return snprintf(buf, len, "%llu", (unsigned long long)f->uvalue);
case FieldTypeBinary: {
uint64_t test_bit = (1 << (f->len - 1));
uint64_t idx = 0;
while(idx < len - 1 && test_bit) {
buf[idx++] = (f->uvalue & test_bit) ? '1' : '0';
test_bit >>= 1;
}
buf[idx] = 0;
return idx;
}
case FieldTypeHex:
return snprintf(buf, len, "%*llX", (int)(f->len + 7) / 8, f->uvalue);
case FieldTypeFloat:
return snprintf(buf, len, "%.*f", (int)f->len, (double)f->fvalue);
case FieldTypeBytes: {
uint64_t idx = 0;
while(idx < len - 1 && idx < f->len) {
const char* charset = "0123456789ABCDEF";
uint32_t nibble = idx & 1 ? (f->bytes[idx / 2] & 0xf) : (f->bytes[idx / 2] >> 4);
buf[idx++] = charset[nibble];
}
buf[idx] = 0;
return idx;
}
}
return 0;
}
/* Set the field value from its string representation in 'buf'.
* The field type must already be set and the field should be valid.
* The string represenation 'buf' must be null termianted. Note that
* even when representing binary values containing zero, this values
* are taken as representations, so that would be the string "00" as
* the Bytes type representation.
*
* The function returns true if the filed was successfully set to the
* new value, otherwise if the specified value is invalid for the
* field type, false is returned. */
bool field_set_from_string(ProtoViewField* f, char* buf, size_t len) {
// Initialize values to zero since the Flipper sscanf() implementation
// is fuzzy... may populate only part of the value.
long long val = 0;
unsigned long long uval = 0;
float fval = 0;
switch(f->type) {
case FieldTypeStr:
free(f->str);
f->len = len;
f->str = malloc(len + 1);
memcpy(f->str, buf, len + 1);
break;
case FieldTypeSignedInt:
if(!sscanf(buf, "%lld", &val)) return false;
f->value = val;
break;
case FieldTypeUnsignedInt:
if(!sscanf(buf, "%llu", &uval)) return false;
f->uvalue = uval;
break;
case FieldTypeBinary: {
uint64_t bit_to_set = (1 << (len - 1));
uint64_t idx = 0;
uval = 0;
while(buf[idx]) {
if(buf[idx] == '1')
uval |= bit_to_set;
else if(buf[idx] != '0')
return false;
bit_to_set >>= 1;
idx++;
}
f->uvalue = uval;
} break;
case FieldTypeHex:
if(!sscanf(buf, "%llx", &uval) && !sscanf(buf, "%llX", &uval)) return false;
f->uvalue = uval;
break;
case FieldTypeFloat:
if(!sscanf(buf, "%f", &fval)) return false;
f->fvalue = fval;
break;
case FieldTypeBytes: {
if(len > f->len) return false;
uint64_t idx = 0;
while(buf[idx]) {
uint8_t nibble = 0;
char c = toupper(buf[idx]);
if(c >= '0' && c <= '9')
nibble = c - '0';
else if(c >= 'A' && c <= 'F')
nibble = 10 + (c - 'A');
else
return false;
if(idx & 1) {
f->bytes[idx / 2] = (f->bytes[idx / 2] & 0xF0) | nibble;
} else {
f->bytes[idx / 2] = (f->bytes[idx / 2] & 0x0F) | (nibble << 4);
}
idx++;
}
buf[idx] = 0;
} break;
}
return true;
}
/* Set the 'dst' field to contain a copy of the value of the 'src'
* field. The field name is not modified. */
void field_set_from_field(ProtoViewField* dst, ProtoViewField* src) {
field_free_aux_data(dst);
dst->type = src->type;
dst->len = src->len;
switch(src->type) {
case FieldTypeStr:
dst->str = strdup(src->str);
break;
case FieldTypeBytes:
dst->bytes = malloc(src->len);
memcpy(dst->bytes, src->bytes, dst->len);
break;
case FieldTypeSignedInt:
dst->value = src->value;
break;
case FieldTypeUnsignedInt:
case FieldTypeBinary:
case FieldTypeHex:
dst->uvalue = src->uvalue;
break;
case FieldTypeFloat:
dst->fvalue = src->fvalue;
break;
}
}
/* Increment the specified field value of 'incr'. If the field type
* does not support increments false is returned, otherwise the
* action is performed. */
bool field_incr_value(ProtoViewField* f, int incr) {
switch(f->type) {
case FieldTypeStr:
return false;
case FieldTypeSignedInt: {
/* Wrap around depending on the number of bits (f->len)
* the integer was declared to have. */
int64_t max = (1ULL << (f->len - 1)) - 1;
int64_t min = -max - 1;
int64_t v = (int64_t)f->value + incr;
if(v > max) v = min + (v - max - 1);
if(v < min) v = max + (v - min + 1);
f->value = v;
break;
}
case FieldTypeBinary:
case FieldTypeHex:
case FieldTypeUnsignedInt: {
/* Wrap around like for the unsigned case, but here
* is simpler. */
uint64_t max = (1ULL << f->len) - 1; // Broken for 64 bits.
uint64_t uv = (uint64_t)f->value + incr;
if(uv > max) uv = uv & max;
f->uvalue = uv;
break;
}
case FieldTypeFloat:
f->fvalue += incr;
break;
case FieldTypeBytes: {
// For bytes we only support single unit increments.
if(incr != -1 && incr != 1) return false;
for(int j = f->len - 1; j >= 0; j--) {
uint8_t nibble = (j & 1) ? (f->bytes[j / 2] & 0x0F) : ((f->bytes[j / 2] & 0xF0) >> 4);
nibble += incr;
nibble &= 0x0F;
f->bytes[j / 2] = (j & 1) ? ((f->bytes[j / 2] & 0xF0) | nibble) :
((f->bytes[j / 2] & 0x0F) | (nibble << 4));
/* Propagate the operation on overflow of this nibble. */
if((incr == 1 && nibble == 0) || (incr == -1 && nibble == 0xf)) {
continue;
}
break; // Otherwise stop the loop here.
}
break;
}
}
return true;
}
/* Free a field set and its contained fields. */
void fieldset_free(ProtoViewFieldSet* fs) {
for(uint32_t j = 0; j < fs->numfields; j++) field_free(fs->fields[j]);
free(fs->fields);
free(fs);
}
/* Allocate and init an empty field set. */
ProtoViewFieldSet* fieldset_new(void) {
ProtoViewFieldSet* fs = malloc(sizeof(*fs));
fs->numfields = 0;
fs->fields = NULL;
return fs;
}
/* Append an already allocated field at the end of the specified field set. */
static void fieldset_add_field(ProtoViewFieldSet* fs, ProtoViewField* field) {
fs->numfields++;
fs->fields = realloc(fs->fields, sizeof(ProtoViewField*) * fs->numfields);
fs->fields[fs->numfields - 1] = field;
}
/* Allocate and append an integer field. */
void fieldset_add_int(ProtoViewFieldSet* fs, const char* name, int64_t val, uint8_t bits) {
ProtoViewField* f = field_new(FieldTypeSignedInt, name);
f->value = val;
f->len = bits;
fieldset_add_field(fs, f);
}
/* Allocate and append an unsigned field. */
void fieldset_add_uint(ProtoViewFieldSet* fs, const char* name, uint64_t uval, uint8_t bits) {
ProtoViewField* f = field_new(FieldTypeUnsignedInt, name);
f->uvalue = uval;
f->len = bits;
fieldset_add_field(fs, f);
}
/* Allocate and append a hex field. This is an unsigned number but
* with an hex representation. */
void fieldset_add_hex(ProtoViewFieldSet* fs, const char* name, uint64_t uval, uint8_t bits) {
ProtoViewField* f = field_new(FieldTypeHex, name);
f->uvalue = uval;
f->len = bits;
fieldset_add_field(fs, f);
}
/* Allocate and append a bin field. This is an unsigned number but
* with a binary representation. */
void fieldset_add_bin(ProtoViewFieldSet* fs, const char* name, uint64_t uval, uint8_t bits) {
ProtoViewField* f = field_new(FieldTypeBinary, name);
f->uvalue = uval;
f->len = bits;
fieldset_add_field(fs, f);
}
/* Allocate and append a string field. The string 's' does not need to point
* to a null terminated string, but must have at least 'len' valid bytes
* starting from the pointer. The field object will be correctly null
* terminated. */
void fieldset_add_str(ProtoViewFieldSet* fs, const char* name, const char* s, size_t len) {
ProtoViewField* f = field_new(FieldTypeStr, name);
f->len = len;
f->str = malloc(len + 1);
memcpy(f->str, s, len);
f->str[len] = 0;
fieldset_add_field(fs, f);
}
/* Allocate and append a bytes field. Note that 'count' is specified in
* nibbles (bytes*2). */
void fieldset_add_bytes(
ProtoViewFieldSet* fs,
const char* name,
const uint8_t* bytes,
uint32_t count_nibbles) {
uint32_t numbytes = (count_nibbles + count_nibbles % 2) / 2;
ProtoViewField* f = field_new(FieldTypeBytes, name);
f->bytes = malloc(numbytes);
memcpy(f->bytes, bytes, numbytes);
f->len = count_nibbles;
fieldset_add_field(fs, f);
}
/* Allocate and append a float field. */
void fieldset_add_float(
ProtoViewFieldSet* fs,
const char* name,
float val,
uint32_t digits_after_dot) {
ProtoViewField* f = field_new(FieldTypeFloat, name);
f->fvalue = val;
f->len = digits_after_dot;
fieldset_add_field(fs, f);
}
/* For each field of the destination filedset 'dst', look for a matching
* field name/type in the source fieldset 'src', and if one is found copy
* its value into the 'dst' field. */
void fieldset_copy_matching_fields(ProtoViewFieldSet* dst, ProtoViewFieldSet* src) {
for(uint32_t j = 0; j < dst->numfields; j++) {
for(uint32_t i = 0; i < src->numfields; i++) {
if(dst->fields[j]->type == src->fields[i]->type &&
!strcmp(dst->fields[j]->name, src->fields[i]->name)) {
field_set_from_field(dst->fields[j], src->fields[i]);
}
}
}
}