amxmodx/dlls/arrayx/CHashtable.h

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#if !defined _JUDYHS_ENABLED_
#define _JUDYHS_ENABLED_
Pvoid_t MasterHashtable = (Pvoid_t) NULL; //Create the new array
//Create an array that stores whether or not indices are used.
Pvoid_t MasterHashtable_Binary = (Pvoid_t) NULL;
void Delete_MasterHashtable(void);
Word_t New_Hashtable(Word_t Index, Word_t reserve = 0);
Pvoid_t* Find_Hashtable(Word_t Index, Word_t disable_check = 1, AMX *amx = 0);
void Delete_Hashtable(Word_t Index);
void Clear_Hashtable(Word_t Index);
template <class Type>
void Hashtable_Set(PPvoid_t Hashtable, char *Index, Word_t Length, Type value);
PPvoid_t Hashtable_Get(AMX* amx, Pvoid_t Hashtable, char *Index, int ignore_error = 0);
void Delete_MasterHashtable(void)
{
Word_t
Index = 0,
success;
J1F(success, MasterHashtable_Binary, Index);
while( success )
{
Delete_Hashtable(Index);
J1F(success, MasterHashtable_Binary, Index);
}
}
Word_t New_Hashtable(Word_t Index, Word_t reserve)
{
Word_t success; //Dummy for macros.
J1T(success, MasterHashtable_Binary, Index);
if (success && reserve)
return Index; //If the bit is set but it's 'reserved', return the index.
//Only do this if the bit is not set or not reserved.
J1FE(success, MasterHashtable_Binary, Index);
J1S(success, MasterHashtable_Binary, Index);
PPvoid_t Hashtable = JudyLIns(&MasterHashtable, Index, PJE0);
*Hashtable = (PWord_t) NULL;
return Index;
}
PPvoid_t Find_Hashtable(Word_t Index, Word_t disable_check, AMX* amx)
{
Word_t success;
J1T(success, MasterHashtable_Binary, Index);
if (success || disable_check)
{ //Bit is valid
if(!success)
New_Hashtable(Index);
return JudyLGet(MasterHashtable, Index, PJE0);
}
MF_LogError(amx,AMX_ERR_NATIVE,"Hashtable %d is invalid.", Index);
return NULL;
}
void Delete_Hashtable(Word_t Index)
{
int success;
J1T(success, MasterHashtable_Binary, Index);
if (success)
{ //If the bit was set, clear, unset and delist hashtable.
Clear_Hashtable(Index);
J1U(success, MasterHashtable_Binary, Index);
JudyLDel(&MasterHashtable, Index, PJE0);
}
}
void Clear_Hashtable(Word_t Index)
{
int success;
J1T(success, MasterHashtable_Binary, Index);
if (success) //dont bother with unset hashtables.
{
PPvoid_t Hashtable = Find_Hashtable(Index);
JHSFA(success, *Hashtable);
}
}
template <class Type> //This will support input char*, Vector*, int, and cell_real*.
void Hashtable_Set(PPvoid_t Hashtable, char* Index, Type value)
{
int Len = strlen(Index)+1;
PPvoid_t PValue = JudyHSIns(Hashtable, Index, Len, PJE0);
*PValue = reinterpret_cast<void*>(value);
}
PPvoid_t Hashtable_Get(AMX* amx,PPvoid_t Hashtable, char *Index, int ignore_error = 0)
{
PPvoid_t PValue = JudyHSGet(*Hashtable, Index, strlen(Index)+1);
if (PValue == NULL && !ignore_error)
MF_LogError(amx, AMX_ERR_NATIVE, "Hashtable get on index \"%s\" is invalid", Index);
return PValue;
}
static cell AMX_NATIVE_CALL Hashtable_Create(AMX *amx, cell *params)
{
return New_Hashtable(params[1],params[2]);
}
static cell AMX_NATIVE_CALL Hashtable_Delete(AMX *amx, cell *params)
{
Delete_Hashtable( params[1] );
return 1;
}
static cell AMX_NATIVE_CALL Hashtable_Clear(AMX *amx, cell *params)
{
Clear_Hashtable( params[1] );
return 1;
}
static cell AMX_NATIVE_CALL Hashtable_SetVector(AMX *amx,cell *params)
{
PPvoid_t Hashtable = Find_Hashtable(params[1], params[4], amx);
if (Hashtable == NULL) return 0;
cell *input_vec = MF_GetAmxAddr(amx, params[3]);
Vector *value = new Vector(
amx_ctof(input_vec[0]),
amx_ctof(input_vec[1]),
amx_ctof(input_vec[2])
);
int strlen;
char *Index = MF_GetAmxString(amx, params[2], 0, &strlen);
PPvoid_t PValue = Hashtable_Get(amx, Hashtable, Index, 1);
element *elem_value = NULL;
if ( PValue == NULL )
elem_value = new element(value);
else
{
elem_value = reinterpret_cast<element*>(*PValue);
(*elem_value).set_vec(value);
}
Hashtable_Set(Hashtable,Index,elem_value);
return 1;
}
static cell AMX_NATIVE_CALL Hashtable_GetVector(AMX *amx, cell *params)
{
PPvoid_t Hashtable = Find_Hashtable(params[1], params[4], amx);
if (Hashtable == NULL) return 0;
int strlen;
char *Index = MF_GetAmxString(amx, params[2], 0, &strlen);
PPvoid_t PValue = Hashtable_Get(amx, Hashtable, Index, params[4]);
cell *vAmx = MF_GetAmxAddr(amx, params[3]);
if( PValue == NULL ) {
vAmx[0] = amx_ftoc(0);
vAmx[1] = amx_ftoc(0);
vAmx[2] = amx_ftoc(0);
return 0;
}
element elem_value = *reinterpret_cast<element*>(*PValue);
int error = 0;
const Vector retr_vec = *elem_value.get_vec(error);
if (error)
elem_value.issue_type_error(amx, params[1], Index);
vAmx[0] = amx_ftoc(retr_vec.x);
vAmx[1] = amx_ftoc(retr_vec.y);
vAmx[2] = amx_ftoc(retr_vec.z);
return 1;
}
static cell AMX_NATIVE_CALL Hashtable_SetString(AMX *amx,cell *params)
{
//params[1]: hashtable
PPvoid_t Hashtable = Find_Hashtable(params[1], params[4], amx);
if (Hashtable == NULL) return 0;
//params[2]: key
int strlength;
char *Index = MF_GetAmxString(amx, params[2], 0, &strlength);
//params[3]: value
int iLen = 0;
char *value = MF_GetAmxString(amx,params[3],1,&iLen);
PPvoid_t PValue = Hashtable_Get(amx, Hashtable, Index, 1);
element *elem_value = NULL;
if ( PValue == NULL )
elem_value = new element(value);
else
{
elem_value = reinterpret_cast<element*>(*PValue);
(*elem_value).set_str(value);
}
Hashtable_Set(Hashtable,Index,elem_value);
return 1;
}
static cell AMX_NATIVE_CALL Hashtable_GetString(AMX *amx,cell *params)
{
//params[1]: hashtable
PPvoid_t Hashtable = Find_Hashtable(params[1], params[5], amx);
if (Hashtable == NULL) return 0;
//params[2]: key
int strlength;
char *Index = MF_GetAmxString(amx, params[2], 0, &strlength);
Pvoid_t * PValue = Hashtable_Get(amx, Hashtable, Index, params[5]);
//params[3] and params[4] are the return string and length respectively.
if( PValue == NULL )
return MF_SetAmxString(amx, params[3] , "dne", params[4] );
element elem_value = *reinterpret_cast<element*>(*PValue);
int error = 0;
if (error)
elem_value.issue_type_error(amx, params[1], Index);
const char* str_out = elem_value.get_str(error);
return MF_SetAmxString( amx , params[3] , str_out, params[4] );
}
static cell AMX_NATIVE_CALL Hashtable_SetFloat(AMX *amx,cell *params)
{
//params[1]: hashtable
PPvoid_t Hashtable = Find_Hashtable(params[1], params[4], amx);
if (Hashtable == NULL) return 0;
//params[2]: key
int strlength;
char *Index = MF_GetAmxString(amx, params[2], 0, &strlength);
//params[3]: value
PPvoid_t PValue = Hashtable_Get(amx, Hashtable, Index, 1);
element *elem_value = NULL;
if ( PValue == NULL )
elem_value = new element(amx_ctof(params[3]));
else
{
elem_value = reinterpret_cast<element*>(*PValue);
(*elem_value).set_flo(amx_ctof(params[3]));
}
Hashtable_Set(Hashtable,Index,elem_value);
return 1;
}
static cell AMX_NATIVE_CALL Hashtable_GetFloat(AMX *amx,cell *params)
{
//params[1]: hashtable
PPvoid_t Hashtable = Find_Hashtable(params[1], params[3], amx);
if (Hashtable == NULL) return 0;
//params[2]: key
int strlength;
char *Index = MF_GetAmxString(amx, params[2], 0, &strlength);
PPvoid_t PValue = Hashtable_Get(amx, Hashtable, Index, params[3]);
if( PValue == NULL ) return amx_ftoc(0.0);
element elem_value = *reinterpret_cast<element*>(*PValue);
int error = 0;
cell retr_float = amx_ftoc(elem_value.get_flo(error));
if (error)
elem_value.issue_type_error(amx, params[1], Index);
return retr_float;
}
static cell AMX_NATIVE_CALL Hashtable_SetInt(AMX *amx,cell *params)
{
//params[1]: hashtable
PPvoid_t Hashtable = Find_Hashtable(params[1], params[4], amx);
if (Hashtable == NULL) return 0;
//params[2]: key
int strlength;
char *Index = MF_GetAmxString(amx, params[2], 0, &strlength);
PPvoid_t PValue = Hashtable_Get(amx, Hashtable, Index, 1);
element *elem_value = NULL;
if ( PValue == NULL )
elem_value = new element(params[3]);
else
{
elem_value = reinterpret_cast<element*>(*PValue);
(*elem_value).set_int(params[3]);
}
Hashtable_Set(Hashtable,Index,elem_value);
return 1;
}
static cell AMX_NATIVE_CALL Hashtable_GetInt(AMX *amx,cell *params)
{
//params[1]: hashtable
PPvoid_t Hashtable = Find_Hashtable(params[1], params[3], amx);
if (Hashtable == NULL) return 0;
//params[2]: key
int strlength;
char *Index = MF_GetAmxString(amx, params[2], 0, &strlength);
Pvoid_t * PValue = Hashtable_Get(amx, Hashtable, Index, params[3]);
if( PValue == NULL ) return 0;
element elem_value = *reinterpret_cast<element*>(*PValue);
int error = 0;
cell retr_int = elem_value.get_int(error);
if (error)
elem_value.issue_type_error(amx, params[1], Index);
return retr_int;
}
static cell AMX_NATIVE_CALL Hashtable_Memory(AMX *amx,cell *params)
{
Pvoid_t * Array = Find_Hashtable(params[1],params[2],amx);
if (Array == NULL) return 0;
return JudyLMemUsed(*Array);
}
static cell AMX_NATIVE_CALL Hashtable_Remove(AMX *amx,cell *params)
{
//params[1]: hashtable
PPvoid_t Hashtable = Find_Hashtable(params[1], 0, amx);
if (Hashtable == NULL) return 0;
//params[2]: key
int strlength;
char *Index = MF_GetAmxString(amx, params[2], 0, &strlength);
JudyHSDel(Hashtable, Index, strlength+1, PJE0 );
return 1;
}
AMX_NATIVE_INFO hashtable_exports[] = {
{ "hashtable_set_str", Hashtable_SetString },
{ "hashtable_get_str", Hashtable_GetString },
{ "hashtable_set_vec", Hashtable_SetVector },
{ "hashtable_get_vec", Hashtable_GetVector },
{ "hashtable_set_int", Hashtable_SetInt },
{ "hashtable_get_int", Hashtable_GetInt },
{ "hashtable_set_float", Hashtable_SetFloat },
{ "hashtable_get_float", Hashtable_GetFloat },
{ "hashtable_memory", Hashtable_Memory },
{ "hashtable_remove", Hashtable_Remove },
{ "hashtable_create", Hashtable_Create },
{ "hashtable_delete", Hashtable_Delete },
{ "hashtable_clear", Hashtable_Clear },
{ NULL, NULL }
};
#endif