This is an example of BLE GATT Client, which receives broadcast data from BLE_Server_BME280 ( a GATT server) , then transfers values up to mbed Device Connector (cloud).
Please refer details about BLEClient_mbedDevConn below. https://github.com/soramame21/BLEClient_mbedDevConn
The location of required BLE GATT server, BLE_Server_BME280, is at here. https://developer.mbed.org/users/edamame22/code/BLE_Server_BME280/
mbed-client/source/m2mstring.cpp
- Committer:
- Ren Boting
- Date:
- 2017-09-05
- Revision:
- 2:b894b3508057
- Parent:
- 0:29983394c6b6
File content as of revision 2:b894b3508057:
/* * Copyright (c) 2015 ARM Limited. All rights reserved. * SPDX-License-Identifier: Apache-2.0 * Licensed under the Apache License, Version 2.0 (the License); you may * not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an AS IS BASIS, WITHOUT * WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include "mbed-client/m2mstring.h" #include <string.h> // strlen #include <stdlib.h> // malloc, realloc #include <assert.h> #include <algorithm> // min namespace m2m { const String::size_type String::npos = static_cast<size_t>(-1); char* String::strdup(const char* s) { const size_t len = strlen(s)+1; char *p2 = static_cast<char*>(malloc(len)); memcpy(p2, s, len); allocated_ = len; size_ = len-1; return p2; } String::String() : p( strdup("") ) { } String::~String() { free(p); p = 0; } String::String(const String& s) : p(0) { if( &s != NULL ) { p = static_cast<char*>(malloc(s.size_ + 1)); allocated_ = s.size_ + 1; size_ = s.size_; memcpy(p, s.p, size_ + 1); } } String::String(const char* s) : p(strdup(s)) { } String::String(const char* str, size_t n) { p = static_cast<char*>(malloc(n + 1)); allocated_ = n + 1; size_ = n; memcpy(p, str, n); p[n] = 0; } String& String::operator=(const char* s) { if ( p != s ) { // s could point into our own string, so we have to allocate a new string const size_t len = strlen(s); char* copy = (char*) malloc( len + 1); memmove(copy, s, len+1); // trailing 0 free( p ); p = copy; size_ = len; allocated_ = len+1; } return *this; } String& String::operator=(const String& s) { return operator=(s.p); } String& String::operator+=(const String& s) { if (s.size_ > 0) { this->reserve(size_ + s.size_); memmove(p+size_, s.p, s.size_+1); // trailing 0 size_ += s.size_; } return *this; } // since p and s may overlap, we have to copy our own string first String& String::operator+=(const char* s) { const size_type lens = strlen(s); if (lens > 0) { if (size_ + lens + 1 <= allocated_) { memmove(p+size_, s, lens+1); // trailing 0 size_ += lens; } else { String s2( *this ); // copy own data s2.reserve(size_ + lens); memmove(s2.p+size_, s, lens+1); // trailing 0 s2.size_ = size_ + lens; this->swap( s2 ); } } return *this; } String& String::operator+=(const char c) { push_back(c); return *this; } void String::push_back(const char c) { if (size_ == allocated_ - 1) { size_t more = (allocated_* 3) / 2; // factor 1.5 if ( more < 4 ) more = 4; reserve( size_ + more ); } p[size_] = c; size_++; p[size_] = 0; } bool String::operator==(const char* s) const { if( s == NULL ) { if( p == NULL ) { return true; } return false; } bool ret = strcmp(p, s); return !ret; } bool String::operator==(const String& s) const { bool ret = strcmp(p, s.p); return !ret; } void String::clear() { size_ = 0; p[0] = 0; } String String::substr(const size_type pos, size_type length) const { String s; const size_type len = size_; if ( pos <= len ) { size_type remain = len - pos; if ( length > remain ) length = remain; s.reserve( length ); memcpy(s.p, p + pos, length); s.p[length] = '\0'; s.size_ = length; } return s; } // checked access, accessing the NUL at end is allowed char String::at(const size_type i) const { if ( i <= strlen(p) ) { return p[i]; } else { return '\0'; } } String& String::erase(size_type pos, size_type len) { if (len > 0) { if ( pos < size_ ) { // user must not remove trailing 0 size_type s2 = size_; size_type remain = s2 - pos - len; if (remain > 0) { // erase by overwriting memmove(p + pos, p + pos + len, remain); } //if ( remain < 0 ) remain = 0; // remove unused space this->resize( pos+remain ); } } return *this; } String& String::append( const char* str, size_type n) { if (str && n > 0) { size_t lens = strlen(str); if (n > lens) n = lens; size_t newlen = size_ + n; this->reserve( newlen ); memmove(p+size_, str, n); // p and s.p MAY overlap p[newlen] = 0; // add NUL termination size_ = newlen; } return *this; } String& String::append_raw( const char* str, size_type n) { if (str && n > 0) { size_t newlen = size_ + n; this->reserve( newlen ); memmove(p+size_, str, n); // p and s.p MAY overlap p[newlen] = 0; // add NUL termination size_ = newlen; } return *this; } void String::append_int(int param) { // max len of "-9223372036854775808" plus zero termination char conv_buff[20+1]; int len = itoa_c(param, conv_buff); append_raw(conv_buff, len); } int String::compare( size_type pos, size_type len, const String& str ) const { int r = -1; if (pos <= size_) { if ( len > size_ - pos) len = size_ - pos; // limit len to available length const size_type osize = str.size(); const size_type len2 = std::min(len, osize); r = strncmp( p + pos, str.p, len2); if (r==0) // equal so far, now compare sizes r = len < osize ? -1 : ( len == osize ? 0 : +1 ); } return r; } int String::compare( size_type pos, size_type len, const char* str ) const { int r = -1; if (pos <= size_) { if ( len > size_ - pos) len = size_ - pos; // limit len to available length const size_type osize = strlen(str); const size_type len2 = std::min(len, osize); r = strncmp( p + pos, str, len2); if (r==0) // equal so far, now compare sizes r = len < osize ? -1 : ( len == osize ? 0 : +1 ); } return r; } int String::find_last_of(char c) const { int r = -1; char *v; v = strrchr(p,c); if (v != NULL) { r = 0; char* i = p; while (v != i) { i++; r++; } } return r; } void String::new_realloc( size_type n) { if (n > 0 ) { char* pnew = static_cast<char*>(realloc(p, n)); // could return NULL if (pnew) p = pnew; } } void String::reserve( const size_type n) { if (n >= allocated_ ) { this->new_realloc(n + 1); allocated_ = n + 1; } } void String::resize( const size_type n) { this->resize( n, 0 ); } void String::resize( const size_type n, const char c) { if (n < size_ ) { p[n] = 0; size_ = n; } else if (n > size_ ) { this->reserve( n ); for (size_type i=size_; i < n; ++i ) p[i] = c; p[n] = 0; size_ = n; } } void String::swap( String& s ) { std::swap( allocated_, s.allocated_ ); std::swap( size_, s.size_ ); std::swap( p, s.p ); } // Comparison bool operator<( const String& s1, const String& s2 ) { return strcmp( s1.c_str(), s2.c_str() ) < 0; } void reverse(char s[], uint32_t length) { uint32_t i, j; char c; for (i = 0, j = length-1; i<j; i++, j--) { c = s[i]; s[i] = s[j]; s[j] = c; } } uint32_t itoa_c (int64_t n, char s[]) { int64_t sign; uint32_t i; if ((sign = n) < 0) n = -n; i = 0; do { s[i++] = n % 10 + '0'; } while ((n /= 10) > 0); if (sign < 0) s[i++] = '-'; s[i] = '\0'; m2m::reverse(s, i); return i; } uint8_t* String::convert_integer_to_array(int64_t value, uint8_t &size, uint8_t *array, uint32_t array_size) { uint8_t* buffer = NULL; size = 0; if (array) { value = String::convert_array_to_integer(array, array_size); } if(value < 0xFF) { size = 1; } else if(value < 0xFFFF) { size = 2; } else if(value < 0xFFFFFF) { size = 3; } else if(value < 0xFFFFFFFF) { size = 4; } else if(value < 0xFFFFFFFFFF) { size = 5; } else if(value < 0xFFFFFFFFFFFF) { size = 6; } else if(value < 0xFFFFFFFFFFFFFF) { size = 7; } else { size = 8; } buffer = (uint8_t*)malloc(size); if (buffer) { for (int i = 0; i < size; i++) { buffer[i] = (value >> ((size - i - 1) * 8)); } } else { size = 0; } return buffer; } int64_t String::convert_array_to_integer(uint8_t *value, uint32_t size) { int64_t temp_64 = 0; for (int i = size - 1; i >= 0; i--) { temp_64 += (uint64_t)(*value++) << i * 8; } return temp_64; } } // namespace