Merge branch 'main' of github.com:cyhhao/git3-contract

main
cyhhao 2 years ago
commit bc3194a8d3

@ -2,9 +2,8 @@
pragma solidity ^0.8.0; pragma solidity ^0.8.0;
import "hardhat/console.sol"; import "hardhat/console.sol";
import "./IFileOperator.sol";
import "@openzeppelin/contracts/access/Ownable.sol"; import "@openzeppelin/contracts/access/Ownable.sol";
import "git3-evm-large-storage/contracts/v2/LargeStorageManagerV2.sol"; import "./v2/LargeStorageManagerV2.sol";
contract Git3Hub is LargeStorageManagerV2 { contract Git3Hub is LargeStorageManagerV2 {
struct refInfo { struct refInfo {

@ -1,52 +0,0 @@
//SPDX-License-Identifier: Unlicense
pragma solidity ^0.8.0;
interface IFileOperator {
// Large storage methods
function write(bytes memory name, bytes memory data) external payable;
function read(bytes memory name) external view returns (bytes memory, bool);
// return (size, # of chunks)
function size(bytes memory name) external view returns (uint256, uint256);
function remove(bytes memory name) external returns (uint256);
function countChunks(bytes memory name) external view returns (uint256);
// Chunk-based large storage methods
function writeChunk(
bytes memory name,
uint256 chunkId,
bytes memory data
) external payable;
function readChunk(
bytes memory name,
uint256 chunkId
) external view returns (bytes memory, bool);
function chunkSize(
bytes memory name,
uint256 chunkId
) external view returns (uint256, bool);
function removeChunk(
bytes memory name,
uint256 chunkId
) external returns (bool);
function truncate(
bytes memory name,
uint256 chunkId
) external returns (uint256);
function refund() external;
function destruct() external;
function getChunkHash(
bytes memory name,
uint256 chunkId
) external view returns (bytes32);
}

@ -0,0 +1,278 @@
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.0;
import "./optimize/SlotHelper.sol";
import "./StorageHelperV2.sol";
import "./StorageSlotSelfDestructableV2.sol";
// Large storage manager to support arbitrarily-sized data with multiple chunk
contract LargeStorageManagerV2 {
using SlotHelper for bytes32;
using SlotHelper for address;
uint8 internal immutable SLOT_LIMIT;
mapping(bytes32 => mapping(uint256 => bytes32)) internal keyToMetadata;
mapping(bytes32 => mapping(uint256 => mapping(uint256 => bytes32)))
internal keyToSlots;
constructor(uint8 slotLimit) {
SLOT_LIMIT = slotLimit;
}
function isOptimize() public view returns (bool) {
return SLOT_LIMIT > 0;
}
function _preparePut(bytes32 key, uint256 chunkId) private {
bytes32 metadata = keyToMetadata[key][chunkId];
if (metadata == bytes32(0)) {
require(
chunkId == 0 || keyToMetadata[key][chunkId - 1] != bytes32(0x0),
"must replace or append"
);
}
if (!metadata.isInSlot()) {
address addr = metadata.bytes32ToAddr();
if (addr != address(0x0)) {
// remove the KV first if it exists
StorageSlotSelfDestructableV2(addr).destruct();
}
}
}
function _putChunkFromCalldata(
bytes32 key,
uint256 chunkId,
bytes calldata data,
uint256 value
) internal {
_preparePut(key, chunkId);
// store data and rewrite metadata
if (data.length > SLOT_LIMIT) {
keyToMetadata[key][chunkId] = StorageHelperV2
.putRawFromCalldata(data, value)
.addrToBytes32();
} else {
keyToMetadata[key][chunkId] = SlotHelper.putRaw(
keyToSlots[key][chunkId],
data
);
}
}
function _putChunk(
bytes32 key,
uint256 chunkId,
bytes memory data,
uint256 value
) internal {
_preparePut(key, chunkId);
// store data and rewrite metadata
if (data.length > SLOT_LIMIT) {
keyToMetadata[key][chunkId] = StorageHelperV2
.putRaw(data, value)
.addrToBytes32();
} else {
keyToMetadata[key][chunkId] = SlotHelper.putRaw(
keyToSlots[key][chunkId],
data
);
}
}
function _getChunkAddr(
bytes32 key,
uint256 chunkId
) internal view returns (address) {
bytes32 metadata = keyToMetadata[key][chunkId];
address addr = metadata.bytes32ToAddr();
return addr;
}
function _getChunk(
bytes32 key,
uint256 chunkId
) internal view returns (bytes memory, bool) {
bytes32 metadata = keyToMetadata[key][chunkId];
if (metadata.isInSlot()) {
bytes memory res = SlotHelper.getRaw(
keyToSlots[key][chunkId],
metadata
);
return (res, true);
} else {
address addr = metadata.bytes32ToAddr();
return StorageHelperV2.getRaw(addr);
}
}
function _stakeTokens(
bytes32 key,
uint256 chunkId
) internal view returns (uint256) {
uint256 stakeNum = 0;
while (true) {
(uint256 count, bool found) = _chunkStakeTokens(key, chunkId);
if (!found) {
return stakeNum;
}
stakeNum += count;
chunkId++;
}
return stakeNum;
}
function _chunkStakeTokens(
bytes32 key,
uint256 chunkId
) internal view returns (uint256, bool) {
bytes32 metadata = keyToMetadata[key][chunkId];
if (metadata == bytes32(0)) {
return (0, false);
} else if (metadata.isInSlot()) {
return (0, true);
} else {
address addr = metadata.bytes32ToAddr();
return (addr.balance, true);
}
}
function _chunkSize(
bytes32 key,
uint256 chunkId
) internal view returns (uint256, bool) {
bytes32 metadata = keyToMetadata[key][chunkId];
if (metadata == bytes32(0)) {
return (0, false);
} else if (metadata.isInSlot()) {
uint256 len = metadata.decodeLen();
return (len, true);
} else {
address addr = metadata.bytes32ToAddr();
return StorageHelperV2.sizeRaw(addr);
}
}
function _countChunks(bytes32 key) internal view returns (uint256) {
uint256 chunkId = 0;
while (true) {
bytes32 metadata = keyToMetadata[key][chunkId];
if (metadata == bytes32(0x0)) {
break;
}
chunkId++;
}
return chunkId;
}
// Returns (size, # of chunks).
function _size(bytes32 key) internal view returns (uint256, uint256) {
uint256 size = 0;
uint256 chunkId = 0;
while (true) {
(uint256 chunkSize, bool found) = _chunkSize(key, chunkId);
if (!found) {
break;
}
size += chunkSize;
chunkId++;
}
return (size, chunkId);
}
function _get(bytes32 key) internal view returns (bytes memory, bool) {
(uint256 size, uint256 chunkNum) = _size(key);
if (chunkNum == 0) {
return (new bytes(0), false);
}
bytes memory data = new bytes(size); // solidity should auto-align the memory-size to 32
uint256 dataPtr;
assembly {
dataPtr := add(data, 0x20)
}
for (uint256 chunkId = 0; chunkId < chunkNum; chunkId++) {
bytes32 metadata = keyToMetadata[key][chunkId];
uint256 chunkSize = 0;
if (metadata.isInSlot()) {
chunkSize = metadata.decodeLen();
SlotHelper.getRawAt(
keyToSlots[key][chunkId],
metadata,
dataPtr
);
} else {
address addr = metadata.bytes32ToAddr();
(chunkSize, ) = StorageHelperV2.sizeRaw(addr);
StorageHelperV2.getRawAt(addr, dataPtr);
}
dataPtr += chunkSize;
}
return (data, true);
}
// Returns # of chunks deleted
function _remove(bytes32 key, uint256 chunkId) internal returns (uint256) {
while (true) {
bytes32 metadata = keyToMetadata[key][chunkId];
if (metadata == bytes32(0x0)) {
break;
}
if (!metadata.isInSlot()) {
address addr = metadata.bytes32ToAddr();
// remove new contract
StorageSlotSelfDestructableV2(addr).destruct();
}
keyToMetadata[key][chunkId] = bytes32(0x0);
chunkId++;
}
return chunkId;
}
function _removeChunk(
bytes32 key,
uint256 chunkId
) internal returns (bool) {
bytes32 metadata = keyToMetadata[key][chunkId];
if (metadata == bytes32(0x0)) {
return false;
}
if (keyToMetadata[key][chunkId + 1] != bytes32(0x0)) {
// only the last chunk can be removed
return false;
}
if (!metadata.isInSlot()) {
address addr = metadata.bytes32ToAddr();
// remove new contract
StorageSlotSelfDestructableV2(addr).destruct();
}
keyToMetadata[key][chunkId] = bytes32(0x0);
return true;
}
}

@ -0,0 +1,84 @@
pragma solidity ^0.8.0;
import "./LargeStorageManagerV2.sol";
contract LargeStorageManagerV2Test is LargeStorageManagerV2 {
constructor(uint8 slotLimit) LargeStorageManagerV2(slotLimit) {}
function get(bytes32 key) public view returns (bytes memory, bool) {
(bytes memory data, bool found) = _get(key);
return (data, found);
}
function getChunk(
bytes32 key,
uint256 chunkId
) public view returns (bytes memory, bool) {
(bytes memory data, bool found) = _getChunk(key, chunkId);
return (data, found);
}
function putChunk(
bytes32 key,
uint256 chunkId,
bytes memory data
) public payable {
_putChunk(key, chunkId, data, msg.value);
}
function putChunkFromCalldata(
bytes32 key,
uint256 chunkId,
bytes calldata data
) public payable {
_putChunkFromCalldata(key, chunkId, data, msg.value);
}
function size(bytes32 key) public view returns (uint256, uint256) {
return _size(key);
}
function chunkSize(
bytes32 key,
uint256 chunkId
) public view returns (uint256, bool) {
return _chunkSize(key, chunkId);
}
function countChunks(bytes32 key) public view returns (uint256) {
return _countChunks(key);
}
function remove(bytes32 key) public {
_remove(key, 0);
}
function removeChunk(bytes32 key, uint256 chunkId) public {
_removeChunk(key, chunkId);
}
function getBalance() public view returns (uint256 balance) {
return address(this).balance;
}
function stakeTokens(
bytes32 key,
uint256 chunkId
) public view returns (uint256) {
return _stakeTokens(key, chunkId);
}
function chunkStakeTokens(
bytes32 key,
uint256 chunkId
) public view returns (uint256, bool) {
return _chunkStakeTokens(key, chunkId);
}
function getChunkAddr(
bytes32 key,
uint256 chunkId
) public view returns (address) {
return _getChunkAddr(key, chunkId);
}
}

@ -0,0 +1,187 @@
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.0;
library Memory {
// Size of a word, in bytes.
uint256 internal constant WORD_SIZE = 32;
// Size of the header of a 'bytes' array.
uint256 internal constant BYTES_HEADER_SIZE = 32;
// Address of the free memory pointer.
uint256 internal constant FREE_MEM_PTR = 0x40;
// Compares the 'len' bytes starting at address 'addr' in memory with the 'len'
// bytes starting at 'addr2'.
// Returns 'true' if the bytes are the same, otherwise 'false'.
function equals(
uint256 addr,
uint256 addr2,
uint256 len
) internal pure returns (bool equal) {
assembly {
equal := eq(keccak256(addr, len), keccak256(addr2, len))
}
}
// Compares the 'len' bytes starting at address 'addr' in memory with the bytes stored in
// 'bts'. It is allowed to set 'len' to a lower value then 'bts.length', in which case only
// the first 'len' bytes will be compared.
// Requires that 'bts.length >= len'
function equals(
uint256 addr,
uint256 len,
bytes memory bts
) internal pure returns (bool equal) {
require(bts.length >= len);
uint256 addr2;
assembly {
addr2 := add(
bts,
/*BYTES_HEADER_SIZE*/
32
)
}
return equals(addr, addr2, len);
}
// Allocates 'numBytes' bytes in memory. This will prevent the Solidity compiler
// from using this area of memory. It will also initialize the area by setting
// each byte to '0'.
function allocate(uint256 numBytes) internal pure returns (uint256 addr) {
// Take the current value of the free memory pointer, and update.
assembly {
addr := mload(
/*FREE_MEM_PTR*/
0x40
)
mstore(
/*FREE_MEM_PTR*/
0x40,
add(addr, numBytes)
)
}
uint256 words = (numBytes + WORD_SIZE - 1) / WORD_SIZE;
for (uint256 i = 0; i < words; i++) {
assembly {
mstore(
add(
addr,
mul(
i,
/*WORD_SIZE*/
32
)
),
0
)
}
}
}
// Copy 'len' bytes from memory address 'src', to address 'dest'.
// This function does not check the or destination, it only copies
// the bytes.
function copy(uint256 src, uint256 dest, uint256 len) internal pure {
// Copy word-length chunks while possible
// Reverse copy to prevent out of memory bound error
src = src + len;
dest = dest + len;
for (; len >= WORD_SIZE; len -= WORD_SIZE) {
dest -= WORD_SIZE;
src -= WORD_SIZE;
assembly {
mstore(dest, mload(src))
}
}
if (len == 0) {
return;
}
// Copy remaining bytes
src = src - len;
dest = dest - len;
assembly {
mstore(dest, mload(src))
}
}
// Returns a memory pointer to the provided bytes array.
function ptr(bytes memory bts) internal pure returns (uint256 addr) {
assembly {
addr := bts
}
}
// Returns a memory pointer to the data portion of the provided bytes array.
function dataPtr(bytes memory bts) internal pure returns (uint256 addr) {
assembly {
addr := add(
bts,
/*BYTES_HEADER_SIZE*/
32
)
}
}
// This function does the same as 'dataPtr(bytes memory)', but will also return the
// length of the provided bytes array.
function fromBytes(
bytes memory bts
) internal pure returns (uint256 addr, uint256 len) {
len = bts.length;
assembly {
addr := add(
bts,
/*BYTES_HEADER_SIZE*/
32
)
}
}
// Creates a 'bytes memory' variable from the memory address 'addr', with the
// length 'len'. The function will allocate new memory for the bytes array, and
// the 'len bytes starting at 'addr' will be copied into that new memory.
function toBytes(
uint256 addr,
uint256 len
) internal pure returns (bytes memory bts) {
bts = new bytes(len);
uint256 btsptr;
assembly {
btsptr := add(
bts,
/*BYTES_HEADER_SIZE*/
32
)
}
copy(addr, btsptr, len);
}
// Get the word stored at memory address 'addr' as a 'uint'.
function toUint(uint256 addr) internal pure returns (uint256 n) {
assembly {
n := mload(addr)
}
}
// Get the word stored at memory address 'addr' as a 'bytes32'.
function toBytes32(uint256 addr) internal pure returns (bytes32 bts) {
assembly {
bts := mload(addr)
}
}
/*
// Get the byte stored at memory address 'addr' as a 'byte'.
function toByte(uint addr, uint8 index) internal pure returns (byte b) {
require(index < WORD_SIZE);
uint8 n;
assembly {
n := byte(index, mload(addr))
}
b = byte(n);
}
*/
}

@ -0,0 +1,224 @@
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.0;
import "./Memory.sol";
import "./StorageSlotFactory.sol";
library StorageHelperV2 {
// StorageSlotSelfDestructableV2 compiled via solc 0.8.7 optimized 200
bytes internal constant STORAGE_SLOT_CODE_V2 =
hex"6080604052348015600f57600080fd5b506004361060285760003560e01c80632b68b9c614602d575b600080fd5b60336035565b005b336001600160a01b037f0000000000000000000000000000000000000000000000000000000000000000161460965760405162461bcd60e51b81526020600482015260036024820152624e464f60e81b604482015260640160405180910390fd5b7f00000000000000000000000000000000000000000000000000000000000000006001600160a01b0316fffea2646970667358221220154417754813d1989858c876ab2ded2ba1aa380679fff7a4c8faea076ba020e664736f6c63430008070033";
uint256 internal constant OWNER_ADDR_OFF = 64;
uint256 internal constant USER_ADDR_OFF = 152;
// StorageSlotFactoryFromInput compiled via solc 0.8.7 optimized 200 + STORAGE_SLOT_CODE
bytes internal constant FACTORY_CODE =
hex"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";
uint256 internal constant FACTORY_SIZE_OFF = 305;
uint256 internal constant FACTORY_ADDR_OFF0 = 305 + 32 + OWNER_ADDR_OFF;
uint256 internal constant FACTORY_ADDR_OFF1 = 305 + 32 + USER_ADDR_OFF;
function putRawFromCalldata(
bytes calldata data,
uint256 value
) internal returns (address) {
bytes memory bytecode = bytes.concat(STORAGE_SLOT_CODE_V2, data);
address userAddr = msg.sender;
{
// revise the owner to the contract (so that it is destructable)
uint256 off = OWNER_ADDR_OFF + 0x20;
assembly {
mstore(add(bytecode, off), address())
}
off = USER_ADDR_OFF + 0x20;
assembly {
mstore(add(bytecode, off), userAddr)
}
}
StorageSlotFactoryFromInput c = new StorageSlotFactoryFromInput{
value: value
}(bytecode);
return address(c);
}
function putRaw(
bytes memory data,
uint256 value
) internal returns (address) {
// create the new contract code with the data
bytes memory bytecode = STORAGE_SLOT_CODE_V2;
uint256 bytecodeLen = bytecode.length;
uint256 newSize = bytecode.length + data.length;
assembly {
// in-place resize of bytecode bytes
// note that this must be done when bytecode is the last allocated object by solidity.
mstore(bytecode, newSize)
// notify solidity about the memory size increase, must be 32-bytes aligned
mstore(
0x40,
add(bytecode, and(add(add(newSize, 0x20), 0x1f), not(0x1f)))
)
}
// append data to self-destruct byte code
Memory.copy(
Memory.dataPtr(data),
Memory.dataPtr(bytecode) + bytecodeLen,
data.length
);
address userAddr = msg.sender;
{
// revise the owner to the contract (so that it is destructable)
uint256 off = OWNER_ADDR_OFF + 0x20;
assembly {
mstore(add(bytecode, off), address())
}
off = USER_ADDR_OFF + 0x20;
assembly {
mstore(add(bytecode, off), userAddr)
}
}
StorageSlotFactoryFromInput c = new StorageSlotFactoryFromInput{
value: value
}(bytecode);
return address(c);
}
function putRaw2(
bytes32 key,
bytes memory data,
uint256 value
) internal returns (address) {
// create the new contract code with the data
bytes memory bytecode = FACTORY_CODE;
uint256 bytecodeLen = bytecode.length;
uint256 newSize = bytecode.length + data.length;
assembly {
// in-place resize of bytecode bytes
// note that this must be done when bytecode is the last allocated object by solidity.
mstore(bytecode, newSize)
// notify solidity about the memory size increase, must be 32-bytes aligned
mstore(
0x40,
add(bytecode, and(add(add(newSize, 0x20), 0x1f), not(0x1f)))
)
}
// append data to self-destruct byte code
Memory.copy(
Memory.dataPtr(data),
Memory.dataPtr(bytecode) + bytecodeLen,
data.length
);
{
// revise the size of calldata
uint256 calldataSize = STORAGE_SLOT_CODE_V2.length + data.length;
uint256 off = FACTORY_SIZE_OFF + 0x20;
assembly {
mstore(add(bytecode, off), calldataSize)
}
}
{
// revise the owner to the contract (so that it is destructable)
uint256 off = FACTORY_ADDR_OFF0 + 0x20;
assembly {
mstore(add(bytecode, off), address())
}
off = FACTORY_ADDR_OFF1 + 0x20;
assembly {
mstore(add(bytecode, off), address())
}
}
address addr;
assembly {
addr := create2(
value,
add(bytecode, 0x20), // data offset
mload(bytecode), // size
key
)
if iszero(extcodesize(addr)) {
revert(0, 0)
}
}
return addr;
}
function sizeRaw(address addr) internal view returns (uint256, bool) {
if (addr == address(0x0)) {
return (0, false);
}
uint256 codeSize;
uint256 off = STORAGE_SLOT_CODE_V2.length;
assembly {
codeSize := extcodesize(addr)
}
if (codeSize < off) {
return (0, false);
}
return (codeSize - off, true);
}
function getRaw(address addr) internal view returns (bytes memory, bool) {
(uint256 dataSize, bool found) = sizeRaw(addr);
if (!found) {
return (new bytes(0), false);
}
// copy the data without the "code"
bytes memory data = new bytes(dataSize);
uint256 off = STORAGE_SLOT_CODE_V2.length;
assembly {
// retrieve data size
extcodecopy(addr, add(data, 0x20), off, dataSize)
}
return (data, true);
}
function getRawAt(
address addr,
uint256 memoryPtr
) internal view returns (uint256, bool) {
(uint256 dataSize, bool found) = sizeRaw(addr);
if (!found) {
return (0, false);
}
uint256 off = STORAGE_SLOT_CODE_V2.length;
assembly {
// retrieve data size
extcodecopy(addr, memoryPtr, off, dataSize)
}
return (dataSize, true);
}
function returnBytesInplace(bytes memory content) internal pure {
// equal to return abi.encode(content)
uint256 size = content.length + 0x40; // pointer + size
size = (size + 0x20 + 0x1f) & ~uint256(0x1f);
assembly {
// (DATA CORRUPTION): the caller method must be "external returns (bytes)", cannot be public!
mstore(sub(content, 0x20), 0x20)
return(sub(content, 0x20), size)
}
}
function calculateValueForData(
uint256 datalen,
uint256 chunkSize,
uint256 codeStakingPerChunk
) internal pure returns (uint256) {
return
((datalen + STORAGE_SLOT_CODE_V2.length - 1) / chunkSize) *
codeStakingPerChunk;
}
function storageSlotCodeLength() internal pure returns (uint256) {
return STORAGE_SLOT_CODE_V2.length;
}
}

@ -0,0 +1,51 @@
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.0;
import "./Memory.sol";
// Create a storage slot by appending data to the end
contract StorageSlotFromContract {
constructor(address contractAddr, bytes memory data) payable {
uint256 codeSize;
assembly {
// retrieve the size of the code, this needs assembly
codeSize := extcodesize(contractAddr)
}
uint256 totalSize = codeSize + data.length + 32;
bytes memory deployCode = new bytes(totalSize);
// Copy contract code
assembly {
// actually retrieve the code, this needs assembly
extcodecopy(contractAddr, add(deployCode, 0x20), 0, codeSize)
}
// Copy data
uint256 off = Memory.dataPtr(deployCode) + codeSize;
Memory.copy(Memory.dataPtr(data), off, data.length);
off += data.length;
uint256 len = data.length;
// Set data size
assembly {
mstore(off, len)
}
// Return the contract manually
assembly {
return(add(deployCode, 0x20), totalSize)
}
}
}
// Create a storage slot
contract StorageSlotFactoryFromInput {
constructor(bytes memory codeAndData) payable {
uint256 size = codeAndData.length;
// Return the contract manually
assembly {
return(add(codeAndData, 0x20), size)
}
}
}

@ -0,0 +1,32 @@
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.0;
contract StorageSlotSelfDestructableV2 {
address immutable owner;
address immutable userToRefund;
constructor(address user) payable {
owner = msg.sender;
userToRefund = user;
}
function destruct() public {
require(msg.sender == owner, "NFO");
selfdestruct(payable(userToRefund));
}
}
contract StorageSlotSelfDestructableV2_DEBUG {
address public immutable owner;
address public immutable userToRefund;
constructor(address user) payable {
owner = msg.sender;
userToRefund = user;
}
function destruct() public {
require(msg.sender == owner, "NFO");
selfdestruct(payable(userToRefund));
}
}

@ -0,0 +1,151 @@
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.0;
library SlotHelper {
uint256 internal constant SLOTDATA_RIGHT_SHIFT = 32;
uint256 internal constant LEN_OFFSET = 224;
uint256 internal constant FIRST_SLOT_DATA_SIZE = 28;
function putRaw(
mapping(uint256 => bytes32) storage slots,
bytes memory datas
) internal returns (bytes32 mdata) {
uint256 len = datas.length;
mdata = encodeMetadata(datas);
if (len > FIRST_SLOT_DATA_SIZE) {
bytes32 value;
uint256 ptr;
assembly {
ptr := add(datas, add(0x20, FIRST_SLOT_DATA_SIZE))
}
for (
uint256 i = 0;
i < (len - FIRST_SLOT_DATA_SIZE + 32 - 1) / 32;
i++
) {
assembly {
value := mload(ptr)
}
ptr = ptr + 32;
slots[i] = value;
}
}
}
function encodeMetadata(
bytes memory data
) internal pure returns (bytes32 medata) {
uint256 datLen = data.length;
uint256 value;
assembly {
value := mload(add(data, 0x20))
}
datLen = datLen << LEN_OFFSET;
value = value >> SLOTDATA_RIGHT_SHIFT;
medata = bytes32(value | datLen);
}
function decodeMetadata(
bytes32 mdata
) internal pure returns (uint256 len, bytes32 data) {
len = decodeLen(mdata);
data = mdata << SLOTDATA_RIGHT_SHIFT;
}
function decodeMetadataToData(
bytes32 mdata
) internal pure returns (uint256 len, bytes memory data) {
len = decodeLen(mdata);
mdata = mdata << SLOTDATA_RIGHT_SHIFT;
data = new bytes(len);
assembly {
mstore(add(data, 0x20), mdata)
}
}
function getRaw(
mapping(uint256 => bytes32) storage slots,
bytes32 mdata
) internal view returns (bytes memory data) {
uint256 datalen;
(datalen, data) = decodeMetadataToData(mdata);
if (datalen > FIRST_SLOT_DATA_SIZE) {
uint256 ptr = 0;
bytes32 value = 0;
assembly {
ptr := add(data, add(0x20, FIRST_SLOT_DATA_SIZE))
}
for (
uint256 i = 0;
i < (datalen - FIRST_SLOT_DATA_SIZE + 32 - 1) / 32;
i++
) {
value = slots[i];
assembly {
mstore(ptr, value)
}
ptr = ptr + 32;
}
}
}
function getRawAt(
mapping(uint256 => bytes32) storage slots,
bytes32 mdata,
uint256 memoryPtr
) internal view returns (uint256 datalen, bool found) {
bytes32 datapart;
(datalen, datapart) = decodeMetadata(mdata);
// memoryPtr:memoryPtr+32 is allocated for the data
uint256 dataPtr = memoryPtr;
assembly {
mstore(dataPtr, datapart)
}
if (datalen > FIRST_SLOT_DATA_SIZE) {
uint256 ptr = 0;
bytes32 value = 0;
assembly {
ptr := add(dataPtr, FIRST_SLOT_DATA_SIZE)
}
for (
uint256 i = 0;
i < (datalen - FIRST_SLOT_DATA_SIZE + 32 - 1) / 32;
i++
) {
value = slots[i];
assembly {
mstore(ptr, value)
}
ptr = ptr + 32;
}
}
found = true;
}
function isInSlot(bytes32 mdata) internal pure returns (bool succeed) {
return decodeLen(mdata) > 0;
}
function encodeLen(uint256 datalen) internal pure returns (bytes32 res) {
res = bytes32(datalen << LEN_OFFSET);
}
function decodeLen(bytes32 mdata) internal pure returns (uint256 res) {
res = uint256(mdata) >> LEN_OFFSET;
}
function addrToBytes32(address addr) internal pure returns (bytes32) {
return bytes32(uint256(uint160(addr)));
}
function bytes32ToAddr(bytes32 bt) internal pure returns (address) {
return address(uint160(uint256(bt)));
}
}

@ -0,0 +1,47 @@
// SPDX-License-Identifier: MIT
pragma solidity ^0.8.0;
import "./SlotHelper.sol";
contract SlotHelperTest {
mapping(bytes32 => bytes32) public metadatas;
mapping(bytes32 => mapping(uint256 => bytes32)) public slots;
function put(bytes32 key, bytes memory data) public {
metadatas[key] = SlotHelper.putRaw(slots[key], data);
}
function get(bytes32 key) public view returns (bytes memory res) {
bytes32 md = metadatas[key];
res = SlotHelper.getRaw(slots[key], md);
}
function encodeMetadata(bytes memory data) public pure returns (bytes32) {
return SlotHelper.encodeMetadata(data);
}
function decodeMetadata(
bytes32 mdata
) public pure returns (uint256, bytes32) {
return SlotHelper.decodeMetadata(mdata);
}
function decodeMetadata1(
bytes32 mdata
) public pure returns (uint256, bytes memory) {
return SlotHelper.decodeMetadataToData(mdata);
}
function encodeLen(uint256 datalen) public pure returns (bytes32) {
return SlotHelper.encodeLen(datalen);
}
function decodeLen(bytes32 mdata) public pure returns (uint256 res) {
res = SlotHelper.decodeLen(mdata);
}
function getLen(bytes32 key) public view returns (uint256 resLen) {
bytes32 mdata = metadatas[key];
resLen = SlotHelper.decodeLen(mdata);
}
}

@ -36,7 +36,6 @@
"@nomiclabs/hardhat-etherscan": "^3.1.3", "@nomiclabs/hardhat-etherscan": "^3.1.3",
"@openzeppelin/contracts": "^4.8.0", "@openzeppelin/contracts": "^4.8.0",
"chai": "^4.3.7", "chai": "^4.3.7",
"git3-evm-large-storage": "^1.1.0",
"typechain": "^8.1.1" "typechain": "^8.1.1"
} }
} }

@ -0,0 +1,138 @@
const { web3 } = require("hardhat");
const { expect } = require("chai");
const { ethers } = require("hardhat");
const { defaultAbiCoder } = require("ethers/lib/utils");
var ToBig = (x) => ethers.BigNumber.from(x);
const contractName = "LargeStorageManagerV2Test";
let key = Buffer.from("a".repeat(32));
let ETH = ethers.BigNumber.from("10").pow("18");
describe("FlatDirectory Test", function () {
it("read/write", async function () {
const FlatDirectory = await ethers.getContractFactory(contractName);
const fd = await FlatDirectory.deploy(0);
await fd.deployed();
await fd.putChunk(key, 0, "0x112233");
expect(await fd.get(key)).to.eql(["0x112233", true]);
let data = Array.from({ length: 40 }, () =>
Math.floor(Math.random() * 256)
);
await fd.putChunk(key, 0, data);
expect(await fd.get(key)).to.eql([ethers.utils.hexlify(data), true]);
expect(await fd.size(key)).to.eql([ToBig(40), ToBig(1)]);
});
it("read/write chunks", async function () {
const FlatDirectory = await ethers.getContractFactory(contractName);
const fd = await FlatDirectory.deploy(0);
await fd.deployed();
let data0 = Array.from({ length: 1024 }, () =>
Math.floor(Math.random() * 256)
);
await fd.putChunk(key, 0, data0);
expect(await fd.get(key)).to.eql([ethers.utils.hexlify(data0), true]);
let data1 = Array.from({ length: 512 }, () =>
Math.floor(Math.random() * 256)
);
await fd.putChunk(key, 1, data1);
expect(await fd.getChunk(key, 1)).to.eql([
ethers.utils.hexlify(data1),
true,
]);
let data = data0.concat(data1);
expect(await fd.get(key)).to.eql([ethers.utils.hexlify(data), true]);
expect(await fd.size(key)).to.eql([ToBig(1536), ToBig(2)]);
});
it("write/remove chunks", async function () {
const FlatDirectory = await ethers.getContractFactory(contractName);
const fd = await FlatDirectory.deploy(0);
await fd.deployed();
expect(await fd.countChunks(key)).to.eql(ToBig(0));
let data0 = Array.from({ length: 10 }, () =>
Math.floor(Math.random() * 256)
);
await fd.putChunk(key, 0, data0);
expect(await fd.get(key)).to.eql([ethers.utils.hexlify(data0), true]);
let data1 = Array.from({ length: 20 }, () =>
Math.floor(Math.random() * 256)
);
await fd.putChunk(key, 1, data1);
expect(await fd.getChunk(key, 1)).to.eql([
ethers.utils.hexlify(data1),
true,
]);
await fd.removeChunk(key, 0); // should do nothing
expect(await fd.size(key)).to.eql([ToBig(30), ToBig(2)]);
expect(await fd.countChunks(key)).to.eql(ToBig(2));
expect(await fd.getChunk(key, 0)).to.eql([
ethers.utils.hexlify(data0),
true,
]);
await fd.removeChunk(key, 1); // should succeed
expect(await fd.size(key)).to.eql([ToBig(10), ToBig(1)]);
expect(await fd.get(key)).to.eql([ethers.utils.hexlify(data0), true]);
expect(await fd.getChunk(key, 1)).to.eql(["0x", false]);
expect(await fd.countChunks(key)).to.eql(ToBig(1));
});
it("remove chunks and refund to user", async function () {
const FlatDirectory = await ethers.getContractFactory(contractName);
const fd = await FlatDirectory.deploy(0);
await fd.deployed();
let stakeTokenNum = ETH;
let signer;
[signer] = await ethers.getSigners();
let data0 = Array.from({ length: 10 }, () =>
Math.floor(Math.random() * 256)
);
await fd.putChunk(key, 0, data0, { value: stakeTokenNum });
expect(await fd.get(key)).to.eql([ethers.utils.hexlify(data0), true]);
let data1 = Array.from({ length: 20 }, () =>
Math.floor(Math.random() * 256)
);
await fd.putChunkFromCalldata(key, 1, data1, { value: stakeTokenNum });
expect(await fd.getChunk(key, 1)).to.eql([
ethers.utils.hexlify(data1),
true,
]);
// get stake tokens from files
let amount = await fd.stakeTokens(key, 0);
expect(amount).to.equal(stakeTokenNum.mul(2));
let amount1 = await fd.stakeTokens(key, 1);
expect(amount1).to.equal(stakeTokenNum);
let chunk0Addr = await fd.getChunkAddr(key, 0);
let chunk0Balance = await ethers.provider.getBalance(chunk0Addr);
expect(chunk0Balance).to.equal(stakeTokenNum);
// check the balance of user after removing chunk
// The tokens pledged by the chunk should all be returned to the user
let balBefore = await signer.getBalance();
let tx1 = await fd.remove(key); // should succeed
let rec1 = await tx1.wait();
amount1 = await fd.stakeTokens(key, 1);
expect(amount1).to.equal(ethers.BigNumber.from("0"));
let removeTxCost = rec1.gasUsed.mul(rec1.effectiveGasPrice);
let balAfter = await signer.getBalance();
// check balance after refunding
expect(
balBefore.add(stakeTokenNum).add(stakeTokenNum).sub(removeTxCost)
).to.eq(balAfter);
});
});

@ -0,0 +1,80 @@
const { web3, ethers } = require("hardhat");
const { expect } = require("chai");
const { Contract, BigNumber } = require("ethers");
describe("SlotHelper Library Test", function () {
let SlotHelperTest;
const SHITLEFT224BIT = BigNumber.from(1).mul(16).pow(56);
beforeEach(async () => {
let factory = await ethers.getContractFactory("SlotHelperTest");
SlotHelperTest = await factory.deploy();
await SlotHelperTest.deployed();
});
it("SlotHelper/encodeLen & decodeLen", async function () {
const len = 20;
let res = await SlotHelperTest.encodeLen(len);
let expectRes = BigNumber.from(len).mul(SHITLEFT224BIT).toHexString();
expect(BigNumber.from(res).eq(expectRes)).to.eq(true);
let resLen = await SlotHelperTest.decodeLen(res);
expect(resLen.eq(BigNumber.from(len))).to.eq(true);
});
it("SlotHelper/encodeMetadata & decodeMetadata & decodeMetadata1", async function () {
const len = 20;
const data = [];
for (let i = 0; i < len; i++) {
data.push(1);
}
//return mdata = "0x0000001401010101010101010101010101010101010101010000000000000000"
let mdata = await SlotHelperTest.encodeMetadata(data);
//return [resLen1,resData1] = [20,"0x0101010101010101010101010101010101010101000000000000000000000000"]
let [resLen1, resData1] = await SlotHelperTest.decodeMetadata(mdata);
expect(resLen1.toNumber()).to.eq(len);
//return [resLen2,resData2] = [20,"0x0101010101010101010101010101010101010101"]
let [resLen2, resData2] = await SlotHelperTest.decodeMetadata1(mdata);
expect(resLen2.toNumber()).to.eq(len);
expect(BigNumber.from(data).toHexString()).to.eq(resData2);
// 20
let resLen3 = await SlotHelperTest.decodeLen(mdata);
expect(resLen2.eq(BigNumber.from(len))).to.eq(true);
});
it("SlotHelper/ put & get", async function () {
let key =
"0x00000000000000000000000000000000000000000000000000000000000000aa";
let data = "0xaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa";
let datalen = 17;
let tx1 = await SlotHelperTest.put(key, data);
await tx1.wait();
let resData = await SlotHelperTest.get(key);
let resLen = await SlotHelperTest.getLen(key);
expect(data).to.eq(resData);
expect(resLen.toNumber()).to.eq(datalen);
});
it("SlotHelper/ put & get over 28byte", async function () {
let key =
"0x00000000000000000000000000000000000000000000000000000000000000aa";
let data =
"0xbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbbaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa";
let datalen = 64;
let tx1 = await SlotHelperTest.put(key, data);
await tx1.wait();
let resData = await SlotHelperTest.get(key);
let resLen = await SlotHelperTest.getLen(key);
expect(data).to.eq(resData);
expect(resLen.toNumber()).to.eq(datalen);
});
});
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