Multi Index Table
Module: Contracts API
Classes
| Name | |
|---|---|
| struct | eosio::indexed_by |
| class | eosio::multi_index Defines EOSIO Multi Index Table. |
Functions
| Name | |
|---|---|
| multi_index(name code, uint64_t scope) load_object_by_primary_iterator | |
| name | get_code() const |
| uint64_t | get_scope() const |
| const_iterator | cbegin() const |
| const_iterator | begin() const |
| const_iterator | cend() const |
| const_iterator | end() const |
| const_reverse_iterator | crbegin() const |
| const_reverse_iterator | rbegin() const |
| const_reverse_iterator | crend() const |
| const_reverse_iterator | rend() const |
| const_iterator | lower_bound(uint64_t primary) const |
| const_iterator | upper_bound(uint64_t primary) const |
| uint64_t | available_primary_key() const |
| template <name::raw IndexName> auto | get_index() |
| template <name::raw IndexName> auto | get_index() const |
| const_iterator | iterator_to(const T & obj) const |
| template <typename Lambda > const_iterator | emplace(name payer, Lambda && constructor) |
| template <typename Lambda > void | modify(const_iterator itr, name payer, Lambda && updater) |
| template <typename Lambda > void | modify(const T & obj, name payer, Lambda && updater) |
| const T & | get(uint64_t primary, const char * error_msg ="unable to find key") const |
| const_iterator | find(uint64_t primary) const |
| const_iterator | require_find(uint64_t primary, const char * error_msg ="unable to find key") const |
| const_iterator | erase(const_iterator itr) |
| void | erase(const T & obj) |
Functions Documentation
function multi_index
inline multi_index(
name code,
uint64_t scope
)
load_object_by_primary_iterator
Parameters:
- code - Account that owns table
- scope - Scope identifier within the code hierarchy
Precondition: code and scope member properties are initialized
Postcondition:
- each secondary index table initialized
- Secondary indices are updated to refer to the newly added object. If the secondary index tables do not exist, they are created.
- The payer is charged for the storage usage of the new object and, if the table (and secondary index tables) must be created, for the overhead of the table creation.
Constructs an instance of a Multi-Index table.
Notes The [eosio::multi_index](/cdt/latest/reference/Classes/classeosio_1_1multi__index) template has template parameters <[name::raw](/cdt/latest/reference/Classes/structeosio_1_1name#enum-raw) TableName, typename T, typename... Indices>, where:
TableNameis the name of the table, maximum 12 characters long, characters in the name from the set of lowercase letters, digits 1 to 5, and the "." (period) character and is converted to a eosio::raw - which wraps uint64_t;Tis the object type (i.e., row definition);Indicesis a list of up to 16 secondary indices.- Each must be a default constructable class or struct
- Each must have a function call operator that takes a const reference to the table object type and returns either a secondary key type or a reference to a secondary key type
- It is recommended to use the eosio::const_mem_fun template, which is a type alias to the boost::multi_index::const_mem_fun. See the documentation for the Boost const_mem_fun key extractor for more details. Example:
#include <eosiolib/eosio.hpp>
using namespace eosio;
using namespace std;
class addressbook: contract {
struct address {
uint64_t account_name;
string first_name;
string last_name;
string street;
string city;
string state;
uint64_t primary_key() const { return account_name; }
};
public:
addressbook(name self):contract(self) {}
typedef eosio::multi_index< "address"_n, address > address_index;
void myaction() {
address_index addresses(_self, _self.value); // code, scope
}
}
EOSIO_DISPATCH( addressbook, (myaction) )
function get_code
inline name get_code() const
Return: Account name of the Code that owns the Primary Table.
Returns the code member property.
Example:
// This assumes the code from the constructor example. Replace myaction() {...}
void myaction() {
address_index addresses("dan"_n, "dan"_n.value); // code, scope
eosio::check(addresses.get_code() == "dan"_n, "Codes don't match.");
}
}
EOSIO_DISPATCH( addressbook, (myaction) )
function get_scope
inline uint64_t get_scope() const
Return: Scope id of the Scope within the Code of the Current Receiver under which the desired Primary Table instance can be found.
Returns the scope member property.
Example:
// This assumes the code from the constructor example. Replace myaction() {...}
void myaction() {
address_index addresses("dan"_n, "dan"_n.value); // code, scope
eosio::check(addresses.get_scope() == "dan"_n.value, "Scopes don't match");
}
}
EOSIO_DISPATCH( addressbook, (myaction) )
function cbegin
inline const_iterator cbegin() const
Return: An iterator pointing to the object_type with the lowest primary key value in the Multi-Index table.
Returns an iterator pointing to the object_type with the lowest primary key value in the Multi-Index table.
Example:
// This assumes the code from the constructor example. Replace myaction() {...}
void myaction() {
// create reference to address_index - see emplace example below
// add dan account to table - see emplace example below
auto itr = addresses.find("dan"_n);
eosio::check(itr == addresses.cbegin(), "Only address is not at front.");
}
}
EOSIO_DISPATCH( addressbook, (myaction) )
function begin
inline const_iterator begin() const
Return: An iterator pointing to the object_type with the lowest primary key value in the Multi-Index table.
Returns an iterator pointing to the object_type with the lowest primary key value in the Multi-Index table.
Example:
// This assumes the code from the constructor example. Replace myaction() {...}
void myaction() {
// create reference to address_index - see emplace example below
// add dan account to table - see emplace example below
auto itr = addresses.find("dan"_n);
eosio::check(itr == addresses.begin(), "Only address is not at front.");
}
}
EOSIO_ABI( addressbook, (myaction) )
function cend
inline const_iterator cend() const
Return: An iterator referring to the past-the-end element in the multi index container.
Returns an iterator referring to the past-the-end element in the multi index container. The past-the-end element is the theoretical element that would follow the last element in the vector. It does not point to any element, and thus shall not be dereferenced.
Example:
// This assumes the code from the constructor example. Replace myaction() {...}
void myaction() {
// create reference to address_index - see emplace example below
// add dan account to table - see emplace example below
auto itr = addresses.find("dan"_n);
eosio::check(itr != addresses.cend(), "Address for account doesn't exist");
}
}
EOSIO_DISPATCH( addressbook, (myaction) )
function end
inline const_iterator end() const
Return: An iterator referring to the past-the-end element in the multi index container.
Returns an iterator referring to the past-the-end element in the multi index container. The past-the-end element is the theoretical element that would follow the last element in the vector. It does not point to any element, and thus shall not be dereferenced.
Example:
// This assumes the code from the constructor example. Replace myaction() {...}
void myaction() {
// create reference to address_index - see emplace example below
// add dan account to table - see emplace example below
auto itr = addresses.find("dan"_n);
eosio::check(itr != addresses.end(), "Address for account doesn't exist");
}
}
EOSIO_DISPATCH( addressbook, (myaction) )
function crbegin
inline const_reverse_iterator crbegin() const
Return: A reverse iterator pointing to the object_type with the highest primary key value in the Multi-Index table.
Returns a reverse iterator pointing to the object_type with the highest primary key value in the Multi-Index table.
Example:
// This assumes the code from the constructor example. Replace myaction() {...}
void myaction() {
// create reference to address_index - see emplace example below
// add dan account to table - see emplace example below
// add additional account - brendan
addresses.emplace(payer, [&](auto& address) {
address.account_name = "brendan"_n;
address.first_name = "Brendan";
address.last_name = "Blumer";
address.street = "1 EOS Way";
address.city = "Hong Kong";
address.state = "HK";
});
auto itr = addresses.crbegin();
eosio::check(itr->account_name == name("dan"), "Lock arf, Incorrect Last Record ");
itr++;
eosio::check(itr->account_name == name("brendan"), "Lock arf, Incorrect Second Last Record");
}
}
EOSIO_DISPATCH( addressbook, (myaction) )
function rbegin
inline const_reverse_iterator rbegin() const
Return: A reverse iterator pointing to the object_type with the highest primary key value in the Multi-Index table.
Returns a reverse iterator pointing to the object_type with the highest primary key value in the Multi-Index table.
Example:
// This assumes the code from the constructor example. Replace myaction() {...}
void myaction() {
// create reference to address_index - see emplace example below
// add dan account to table - see emplace example below
// add additional account - brendan
addresses.emplace(payer, [&](auto& address) {
address.account_name = "brendan"_n;
address.first_name = "Brendan";
address.last_name = "Blumer";
address.street = "1 EOS Way";
address.city = "Hong Kong";
address.state = "HK";
});
auto itr = addresses.rbegin();
eosio::check(itr->account_name == name("dan"), "Lock arf, Incorrect Last Record ");
itr++;
eosio::check(itr->account_name == name("brendan"), "Lock arf, Incorrect Second Last Record");
}
}
EOSIO_DISPATCH( addressbook, (myaction) )
function crend
inline const_reverse_iterator crend() const
Return: An iterator pointing to the object_type with the lowest primary key value in the Multi-Index table.
Returns an iterator pointing to the object_type with the lowest primary key value in the Multi-Index table.
Example:
// This assumes the code from the constructor example. Replace myaction() {...}
void myaction() {
// create reference to address_index - see emplace example below
// add dan account to table - see emplace example below
// add additional account - brendan
addresses.emplace(payer, [&](auto& address) {
address.account_name = "brendan"_n;
address.first_name = "Brendan";
address.last_name = "Blumer";
address.street = "1 EOS Way";
address.city = "Hong Kong";
address.state = "HK";
});
auto itr = addresses.crend();
itr--;
eosio::check(itr->account_name == name("brendan"), "Lock arf, Incorrect First Record ");
itr--;
eosio::check(itr->account_name == name("dan"), "Lock arf, Incorrect Second Record");
}
}
EOSIO_DISPATCH( addressbook, (myaction) )
function rend
inline const_reverse_iterator rend() const
Return: An iterator pointing to the object_type with the lowest primary key value in the Multi-Index table.
Returns an iterator pointing to the object_type with the lowest primary key value in the Multi-Index table.
Example:
// This assumes the code from the constructor example. Replace myaction() {...}
void myaction() {
// create reference to address_index - see emplace example below
// add dan account to table - see emplace example below
// add additional account - brendan
addresses.emplace(payer, [&](auto& address) {
address.account_name = "brendan"_n;
address.first_name = "Brendan";
address.last_name = "Blumer";
address.street = "1 EOS Way";
address.city = "Hong Kong";
address.state = "HK";
});
auto itr = addresses.rend();
itr--;
eosio::check(itr->account_name == name("brendan"), "Lock arf, Incorrect First Record ");
itr--;
eosio::check(itr->account_name == name("dan"), "Lock arf, Incorrect Second Record");
}
}
EOSIO_DISPATCH( addressbook, (myaction) )
function lower_bound
inline const_iterator lower_bound(
uint64_t primary
) const
Parameters:
- primary - Primary key that establishes the target value for the lower bound search.
Return: An iterator pointing to the object_type that has the lowest primary key that is greater than or equal to primary. If an object could not be found, or if the table does not exist**, it will return the end iterator.
Searches for the object_type with the lowest primary key that is greater than or equal to a given primary key.
Example:
// This assumes the code from the get_index() example below. Replace myaction() {...}
void myaction() {
// create reference to address_index - see emplace example below
// add dan account to table - see emplace example below
// add additional account - brendan
addresses.emplace(payer, [&](auto& address) {
address.account_name = "brendan"_n;
address.first_name = "Brendan";
address.last_name = "Blumer";
address.street = "1 EOS Way";
address.city = "Hong Kong";
address.state = "HK";
address.zip = 93445;
});
uint32_t zipnumb = 93445;
auto zip_index = addresses.get_index<name("zip")>();
auto itr = zip_index.lower_bound(zipnumb);
eosio::check(itr->account_name == name("brendan"), "Lock arf, Incorrect First Lower Bound Record ");
itr++;
eosio::check(itr->account_name == name("dan"), "Lock arf, Incorrect Second Lower Bound Record");
itr++;
eosio::check(itr == zip_index.end(), "Lock arf, Incorrect End of Iterator");
}
}
EOSIO_DISPATCH( addressbook, (myaction) )
function upper_bound
inline const_iterator upper_bound(
uint64_t primary
) const
Parameters:
- primary - Primary key that establishes the target value for the upper bound search
Return: An iterator pointing to the object_type that has the lowest primary key that is greater than a given primary key. If an object could not be found, or if the table does not exist**, it will return the end iterator.
Searches for the object_type with the lowest primary key that is greater than a given primary key.
Example:
// This assumes the code from the get_index() example below. Replace myaction() {...}
void myaction() {
// create reference to address_index - see emplace example below
// add dan account to table - see emplace example below
// add additional account - brendan
addresses.emplace(payer, [&](auto& address) {
address.account_name = "brendan"_n;
address.first_name = "Brendan";
address.last_name = "Blumer";
address.street = "1 EOS Way";
address.city = "Hong Kong";
address.state = "HK";
address.zip = 93445;
});
uint32_t zipnumb = 93445;
auto zip_index = addresses.get_index<name("zip")>();
auto itr = zip_index.upper_bound(zipnumb);
eosio::check(itr->account_name == name("dan"), "Lock arf, Incorrect First Upper Bound Record ");
itr++;
eosio::check(itr == zip_index.end(), "Lock arf, Incorrect End of Iterator");
}
}
EOSIO_DISPATCH( addressbook, (myaction) )
function available_primary_key
inline uint64_t available_primary_key() const
Return: An available (unused) primary key value.
Returns an available primary key.
Notes: Intended to be used in tables in which the primary keys of the table are strictly intended to be auto-incrementing, and thus will never be set to custom values by the contract. Violating this expectation could result in the table appearing to be full due to inability to allocate an available primary key. Ideally this method would only be used to determine the appropriate primary key to use within new objects added to a table in which the primary keys of the table are strictly intended from the beginning to be autoincrementing and thus will not ever be set to custom arbitrary values by the contract. Violating this agreement could result in the table appearing full when in reality there is plenty of space left.
Example:
// This assumes the code from the constructor example. Replace myaction() {...}
void myaction() {
address_index addresses(_self, _self.value); // code, scope
// add to table, first argument is account to bill for storage
addresses.emplace(payer, [&](auto& address) {
address.key = addresses.available_primary_key();
address.first_name = "Daniel";
address.last_name = "Larimer";
address.street = "1 EOS Way";
address.city = "Blacksburg";
address.state = "VA";
});
}
}
EOSIO_DISPATCH( addressbook, (myaction) )
function get_index
template <name::raw IndexName>
inline auto get_index()
Template Parameters:
- IndexName - the ID of the desired secondary index
Return: An index of the appropriate type: Primitive 64-bit unsigned integer key (idx64), Primitive 128-bit unsigned integer key (idx128), 128-bit fixed-size lexicographical key (idx128), 256-bit fixed-size lexicographical key (idx256), Floating point key, Double precision floating point key, Long Double (quadruple) precision floating point key
Returns an appropriately typed Secondary Index.
Example:
#include <eosiolib/eosio.hpp>
using namespace eosio;
using namespace std;
class addressbook: contract {
struct address {
uint64_t account_name;
string first_name;
string last_name;
string street;
string city;
string state;
uint32_t zip = 0;
uint64_t primary_key() const { return account_name; }
uint64_t by_zip() const { return zip; }
};
public:
addressbook(name receiver, name code, datastream<const char*> ds):contract(receiver, code, ds) {}
typedef eosio::multi_index< name("address"), address, indexed_by< name("zip"), const_mem_fun<address, uint64_t, &address::by_zip> > address_index;
void myaction() {
// create reference to address_index - see emplace example below
// add dan account to table - see emplace example below
uint32_t zipnumb = 93446;
auto zip_index = addresses.get_index<name("zip")>();
auto itr = zip_index.find(zipnumb);
eosio::check(itr->account_name == name("dan"), "Lock arf, Incorrect Record ");
}
}
EOSIO_DISPATCH( addressbook, (myaction) )
function get_index
template <name::raw IndexName>
inline auto get_index() const
Template Parameters:
- IndexName - the ID of the desired secondary index
Return: An index of the appropriate type: Primitive 64-bit unsigned integer key (idx64), Primitive 128-bit unsigned integer key (idx128), 128-bit fixed-size lexicographical key (idx128), 256-bit fixed-size lexicographical key (idx256), Floating point key, Double precision floating point key, Long Double (quadruple) precision floating point key
Returns an appropriately typed Secondary Index.
Example:
// This assumes the code from the get_index() example. Replace myaction() {...}
void myaction() {
// create reference to address_index - see emplace example below
// add dan account to table - see emplace example below
// add additional account - brendan
addresses.emplace(payer, [&](auto& address) {
address.account_name = "brendan"_n;
address.first_name = "Brendan";
address.last_name = "Blumer";
address.street = "1 EOS Way";
address.city = "Hong Kong";
address.state = "HK";
address.zip = 93445;
});
uint32_t zipnumb = 93445;
auto zip_index = addresses.get_index<name("zip")>();
auto itr = zip_index.upper_bound(zipnumb);
eosio::check(itr->account_name == name("dan"), "Lock arf, Incorrect First Upper Bound Record ");
itr++;
eosio::check(itr == zip_index.end(), "Lock arf, Incorrect End of Iterator");
}
}
EOSIO_DISPATCH( addressbook, (myaction) )
function iterator_to
inline const_iterator iterator_to(
const T & obj
) const
Parameters:
- obj - A reference to the desired object
Return: An iterator to the given object
Returns an iterator to the given object in a Multi-Index table.
Example:
// This assumes the code from the get_index() example. Replace myaction() {...}
void myaction() {
// create reference to address_index - see emplace example below
// add dan account to table - see emplace example below
// add additional account - brendan
addresses.emplace(payer, [&](auto& address) {
address.account_name = "brendan"_n;
address.first_name = "Brendan";
address.last_name = "Blumer";
address.street = "1 EOS Way";
address.city = "Hong Kong";
address.state = "HK";
address.zip = 93445;
});
auto user = addresses.get("dan"_n);
auto itr = address.find("dan"_n);
eosio::check(iterator_to(user) == itr, "Invalid iterator");
}
}
EOSIO_DISPATCH( addressbook, (myaction) )
Warning: the interator_to can have undefined behavior if the caller passes in a reference to a stack-allocated object rather than the reference returned by get or by dereferencing a const_iterator.
function emplace
template <typename Lambda >
inline const_iterator emplace(
name payer,
Lambda && constructor
)
Parameters:
- payer - Account name of the payer for the Storage usage of the new object
- constructor - Lambda function that does an in-place initialization of the object to be created in the table
Return: A primary key iterator to the newly created object
Precondition: A multi index table has been instantiated
Postcondition:
- A new object is created in the Multi-Index table, with a unique primary key (as specified in the object). The object is serialized and written to the table. If the table does not exist, it is created.
- Secondary indices are updated to refer to the newly added object. If the secondary index tables do not exist, they are created.
- The payer is charged for the storage usage of the new object and, if the table (and secondary index tables) must be created, for the overhead of the table creation.
Adds a new object (i.e., row) to the table.
Exception - The account is not authorized to write to the table.
Example:
// This assumes the code from the constructor example. Replace myaction() {...}
void myaction() {
address_index addresses(_self, _self.value); // code, scope
// add to table, first argument is account to bill for storage
addresses.emplace(_self, [&](auto& address) {
address.account_name = "dan"_n;
address.first_name = "Daniel";
address.last_name = "Larimer";
address.street = "1 EOS Way";
address.city = "Blacksburg";
address.state = "VA";
});
}
}
EOSIO_DISPATCH( addressbook, (myaction) )
function modify
template <typename Lambda >
inline void modify(
const_iterator itr,
name payer,
Lambda && updater
)
Parameters:
- itr - an iterator pointing to the object to be updated
- payer - account name of the payer for the storage usage of the updated row
- updater - lambda function that updates the target object
Precondition:
- itr points to an existing element
- payer is a valid account that is authorized to execute the action and be billed for storage usage.
Postcondition:
- The modified object is serialized, then replaces the existing object in the table.
- Secondary indices are updated; the primary key of the updated object is not changed.
- The payer is charged for the storage usage of the updated object.
- If payer is the same as the existing payer, payer only pays for the usage difference between existing and updated object (and is refunded if this difference is negative).
- If payer is different from the existing payer, the existing payer is refunded for the storage usage of the existing object.
Modifies an existing object in a table.
Exceptions: If called with an invalid precondition, execution is aborted.
Example:
// This assumes the code from the constructor example. Replace myaction() {...}
void myaction() {
// create reference to address_index - see emplace example
// add dan account to table - see emplace example
auto itr = addresses.find("dan"_n);
eosio::check(itr != addresses.end(), "Address for account not found");
addresses.modify( itr, account payer, [&]( auto& address ) {
address.city = "San Luis Obispo";
address.state = "CA";
});
}
}
EOSIO_DISPATCH( addressbook, (myaction) )
function modify
template <typename Lambda >
inline void modify(
const T & obj,
name payer,
Lambda && updater
)
Parameters:
- obj - a reference to the object to be updated
- payer - account name of the payer for the storage usage of the updated row
- updater - lambda function that updates the target object
Precondition:
- obj is an existing object in the table
- payer is a valid account that is authorized to execute the action and be billed for storage usage.
Postcondition:
- The modified object is serialized, then replaces the existing object in the table.
- Secondary indices are updated; the primary key of the updated object is not changed.
- The payer is charged for the storage usage of the updated object.
- If payer is the same as the existing payer, payer only pays for the usage difference between existing and updated object (and is refunded if this difference is negative).
- If payer is different from the existing payer, the existing payer is refunded for the storage usage of the existing object.
Modifies an existing object in a table.
Exceptions: If called with an invalid precondition, execution is aborted.
Example:
// This assumes the code from the constructor example. Replace myaction() {...}
void myaction() {
// create reference to address_index - see emplace example
// add dan account to table - see emplace example
auto itr = addresses.find("dan"_n);
eosio::check(itr != addresses.end(), "Address for account not found");
addresses.modify( *itr, payer, [&]( auto& address ) {
address.city = "San Luis Obispo";
address.state = "CA";
});
eosio::check(itr->city == "San Luis Obispo", "Lock arf, Address not modified");
}
}
EOSIO_DISPATCH( addressbook, (myaction) )
function get
inline const T & get(
uint64_t primary,
const char * error_msg ="unable to find key"
) const
Parameters:
- primary - Primary key value of the object.
Return: A constant reference to the object containing the specified primary key.
Retrieves an existing object from a table using its primary key.
Exception - No object matches the given key.
Example:
// This assumes the code from the constructor example. Replace myaction() {...}
void myaction() {
// create reference to address_index - see emplace example
// add dan account to table - see emplace example
auto& user = addresses.get("dan"_n);
eosio::check(user.first_name == "Daniel", "Couldn't get him.");
}
}
EOSIO_DISPATCH( addressbook, (myaction) )
Warning:
Avoid the common pitfall of copy-assigning the T& reference returned to a stack-allocated local variable and then passing that into modify of the multi-index. The most common mistake is when the local variable is defined as auto typename, instead it should be of type auto& or decltype(auto).
function find
inline const_iterator find(
uint64_t primary
) const
Parameters:
- primary - Primary key value of the object
Return: An iterator to the found object which has a primary key equal to primary OR the end iterator of the referenced table if an object with primary key primary is not found.
Search for an existing object in a table using its primary key.
Example:
// This assumes the code from the constructor example. Replace myaction() {...}
void myaction() {
// create reference to address_index - see emplace example
// add dan account to table - see emplace example
auto itr = addresses.find("dan"_n);
eosio::check(itr != addresses.end(), "Couldn't get him.");
}
}
EOSIO_DISPATCH( addressbook, (myaction) )
function require_find
inline const_iterator require_find(
uint64_t primary,
const char * error_msg ="unable to find key"
) const
Parameters:
- primary - Primary key value of the object
- error_msg - error message if an object with primary key
primaryis not found.
Return: An iterator to the found object which has a primary key equal to primary OR throws an exception if an object with primary key primary is not found.
Search for an existing object in a table using its primary key.
function erase
inline const_iterator erase(
const_iterator itr
)
Parameters:
- itr - An iterator pointing to the object to be removed
Return: For the signature with [const_iterator](/cdt/latest/reference/Classes/structeosio_1_1multi__index_1_1const__iterator), returns a pointer to the object following the removed object.
Precondition: itr points to an existing element
Postcondition:
- The object is removed from the table and all associated storage is reclaimed.
- Secondary indices associated with the table are updated.
- The existing payer for storage usage of the object is refunded for the table and secondary indices usage of the removed object, and if the table and indices are removed, for the associated overhead.
Remove an existing object from a table using its primary key.
Exceptions: The object to be removed is not in the table. The action is not authorized to modify the table. The given iterator is invalid.
Example:
// This assumes the code from the constructor example. Replace myaction() {...}
void myaction() {
// create reference to address_index - see emplace example
// add dan account to table - see emplace example
auto itr = addresses.find("dan"_n);
eosio::check(itr != addresses.end(), "Address for account not found");
addresses.erase( itr );
eosio::check(itr != addresses.end(), "Everting lock arf, Address not erased properly");
}
}
EOSIO_ABI( addressbook, (myaction) )
function erase
inline void erase(
const T & obj
)
Parameters:
- obj - Object to be removed
Precondition: obj is an existing object in the table
Postcondition:
- The object is removed from the table and all associated storage is reclaimed.
- Secondary indices associated with the table are updated.
- The existing payer for storage usage of the object is refunded for the table and secondary indices usage of the removed object, and if the table and indices are removed, for the associated overhead.
Remove an existing object from a table using its primary key.
Exceptions: The object to be removed is not in the table. The action is not authorized to modify the table. The given iterator is invalid.
Example:
// This assumes the code from the constructor example. Replace myaction() {...}
void myaction() {
auto itr = addresses.find("dan"_n);
eosio::check(itr != addresses.end(), "Record is not found");
addresses.erase(*itr);
itr = addresses.find("dan"_n);
eosio::check(itr == addresses.end(), "Record is not deleted");
}
}
EOSIO_DISPATCH( addressbook, (myaction) )
Updated on 2022-12-05 at 15:38:07 +0000