private void setInterrupt(InterruptFlags IF)
{
m_IFR |= (byte)IF;
if ((m_IFR & m_IER) > 0)
{
m_IFR |= 0x80;
}
}
private void clearInterrupt(InterruptFlags IF)
{
m_IFR = (byte)((m_IFR & (byte)~IF) & 0x7F);
if ((m_IFR & m_IER) > 0)
{
m_IFR |= 0x80;
}
}
public void setInterruptFlag(InterruptFlags flag)
{
int bitAdress = decodeInterruptFlag(flag);
if (isInterruptEnabled(bitAdress))
{
int intCon = memory.getFile(0xb);
intCon |= (1 << bitAdress);
memory.setFile(0xb, intCon);
}
}
private int decodeInterruptFlag(InterruptFlags flag)
{
switch (flag)
{
case InterruptFlags.T0IF: return(2);
case InterruptFlags.INTF: return(1);
case InterruptFlags.RBIF: return(0);
default: return(0);
}
}
/// <summary>
/// Resets the bank to its begin state.
/// </summary>
public void Reset()
{
A = B = C = D = E = F = H = L = 0;
IE = IF = InterruptFlags.None;
IME = false;
}
/// <summary>
/// Checks whether the given spell can be casted by the casting Unit.
/// Does not do range checks.
/// </summary>
public SpellFailedReason CheckCasterConstraints(Unit caster)
{
// check for combat
if (caster.IsInCombat && RequiresCasterOutOfCombat)
{
return(SpellFailedReason.AffectingCombat);
}
if (!caster.CanDoHarm && HasHarmfulEffects)
{
return(SpellFailedReason.Pacified);
}
// Not while silenced
if (InterruptFlags.HasFlag(InterruptFlags.OnSilence) && caster.IsUnderInfluenceOf(SpellMechanic.Silenced) && caster.Class == ClassId.AtackMage && caster.Class == ClassId.SupportMage && caster.Class == ClassId.HealMage)
{
return(SpellFailedReason.Silenced);
}
// Check if castable while stunned
if (!AttributesExD.HasFlag(SpellAttributesExD.UsableWhileStunned) && !caster.CanInteract)
{
return(SpellFailedReason.CantDoThatRightNow);
}
// Not while silenced
else if (!caster.CanCastSpells &&
(!IsPhysicalAbility ||
(InterruptFlags.HasFlag(InterruptFlags.OnSilence) &&
caster.IsUnderInfluenceOf(SpellMechanic.Silenced))) && caster.Class == ClassId.AtackMage && caster.Class == ClassId.SupportMage && caster.Class == ClassId.HealMage)
{
return(SpellFailedReason.Silenced);
}
// cannot use physical ability or not do harm at all
else if ((!caster.CanDoPhysicalActivity && IsPhysicalAbility) ||
(!caster.CanDoHarm && HasHarmfulEffects))
{
return(SpellFailedReason.Pacified);
}
else if (!AttributesExD.HasFlag(SpellAttributesExD.UsableWhileStunned) && !caster.CanInteract)
{
return(SpellFailedReason.Stunned);
}
// Combo points
else if (IsFinishingMove && caster.ComboPoints == 0)
{
return(SpellFailedReason.NoComboPoints);
}
// AuraStates
if (RequiredCasterAuraState != 0 || ExcludeCasterAuraState != 0)
{
// check AuraStates
var state = caster.AuraState;
if ((RequiredCasterAuraState != 0 && !state.HasAnyFlag(RequiredCasterAuraState)) ||
(ExcludeCasterAuraState != 0 && state.HasAnyFlag(ExcludeCasterAuraState)))
{
return(SpellFailedReason.CasterAurastate);
}
}
// Required Auras
if ((ExcludeCasterAuraId != 0 && caster.Auras.Contains(ExcludeCasterAuraId)) ||
(RequiredCasterAuraId != 0 && !caster.Auras.Contains(RequiredCasterAuraId)))
{
return(SpellFailedReason.CasterAurastate);
}
var spells = caster.Spells;
// check cooldown and power cost
if (spells != null && caster.CastingTill > System.DateTime.Now && !spells.IsReady(this))
{
return(SpellFailedReason.NotReady);
}
if (caster is NPC && caster.Target != null && Range.MaxDist < caster.GetDistance(caster.Target))
{
return(SpellFailedReason.OutOfRange);
}
if (!IsPassive)
{
if (!caster.HasEnoughPowerToCast(this, null))
{
return(SpellFailedReason.NoPower);
}
}
return(SpellFailedReason.Ok);
}
/// <summary>
/// Checks whether the given spell can be casted by the casting Unit.
/// Does not do range checks.
/// </summary>
public SpellFailedReason CheckCasterConstraints(Unit caster)
{
// check for combat
if (caster.IsInCombat && RequiresCasterOutOfCombat)
{
return(SpellFailedReason.AffectingCombat);
}
// Power Type
if (CostsPower &&
PowerType != caster.PowerType &&
PowerType != PowerType.Health &&
!AttributesExB.HasFlag(SpellAttributesExB.DoesNotNeedShapeshift))
{
return(SpellFailedReason.OnlyShapeshift);
}
if (!caster.CanDoHarm && HasHarmfulEffects)
{
return(SpellFailedReason.Pacified);
}
// Not while silenced
if (InterruptFlags.HasFlag(InterruptFlags.OnSilence) && caster.IsUnderInfluenceOf(SpellMechanic.Silenced))
{
return(SpellFailedReason.Silenced);
}
// Check if castable while stunned
if (!AttributesExD.HasFlag(SpellAttributesExD.UsableWhileStunned) && !caster.CanInteract)
{
return(SpellFailedReason.CantDoThatRightNow);
}
// Combo points
if (IsFinishingMove && caster.ComboPoints == 0)
{
return(SpellFailedReason.NoComboPoints);
}
// spell focus
if (!CheckSpellFocus(caster))
{
return(SpellFailedReason.RequiresSpellFocus);
}
// Not while silenced
else if (!caster.CanCastSpells &&
(!IsPhysicalAbility ||
(InterruptFlags.HasFlag(InterruptFlags.OnSilence) &&
caster.IsUnderInfluenceOf(SpellMechanic.Silenced))))
{
return(SpellFailedReason.Silenced);
}
// cannot use physical ability or not do harm at all
else if ((!caster.CanDoPhysicalActivity && IsPhysicalAbility) ||
(!caster.CanDoHarm && HasHarmfulEffects))
{
return(SpellFailedReason.Pacified);
}
else if (!AttributesExD.HasFlag(SpellAttributesExD.UsableWhileStunned) && !caster.CanInteract)
{
return(SpellFailedReason.Stunned);
}
// Combo points
else if (IsFinishingMove && caster.ComboPoints == 0)
{
return(SpellFailedReason.NoComboPoints);
}
// AuraStates
if (RequiredCasterAuraState != 0 || ExcludeCasterAuraState != 0)
{
// check AuraStates
var state = caster.AuraState;
if ((RequiredCasterAuraState != 0 && !state.HasAnyFlag(RequiredCasterAuraState)) ||
(ExcludeCasterAuraState != 0 && state.HasAnyFlag(ExcludeCasterAuraState)))
{
return(SpellFailedReason.CasterAurastate);
}
}
// Required Auras
if ((ExcludeCasterAuraId != 0 && caster.Auras.Contains(ExcludeCasterAuraId)) ||
(RequiredCasterAuraId != 0 && !caster.Auras.Contains(RequiredCasterAuraId)))
{
return(SpellFailedReason.CasterAurastate);
}
// Shapeshift
var shapeshiftMask = caster.ShapeshiftMask;
bool ignoreShapeshiftRequirement = false; // use this to allow for lazy requirement lookup
if (ExcludeShapeshiftMask.HasAnyFlag(shapeshiftMask))
{
if (!(ignoreShapeshiftRequirement = caster.Auras.IsShapeshiftRequirementIgnored(this)))
{
return(SpellFailedReason.NotShapeshift);
}
}
else if (!RequiredShapeshiftMask.HasAnyFlag(shapeshiftMask))
{
// our mask did not pass -> do the default checks
var shapeshiftEntry = caster.ShapeshiftEntry;
var shapeshifted = shapeshiftEntry != null && (shapeshiftEntry.Flags & ShapeshiftInfoFlags.NotActualShapeshift) == 0;
if (shapeshifted)
{
if (RequiredShapeshiftMask != 0)
{
// When shapeshifted, can only use spells that allow this form
if (!(ignoreShapeshiftRequirement = caster.Auras.IsShapeshiftRequirementIgnored(this)))
{
return(SpellFailedReason.OnlyShapeshift);
}
}
else if (Attributes.HasAnyFlag(SpellAttributes.NotWhileShapeshifted))
{
if (!(ignoreShapeshiftRequirement = caster.Auras.IsShapeshiftRequirementIgnored(this)))
{
// cannot cast this spell when shapeshifted
return(SpellFailedReason.NotShapeshift);
}
}
}
if (Attributes.HasFlag(SpellAttributes.RequiresStealth) && caster.Stealthed < 1)
{
if (!caster.Auras.IsShapeshiftRequirementIgnored(this))
{
// Stealth Required, but not stealthed and not ignored by a SPELL_AURA_MOD_IGNORE_SHAPESHIFT aura
return(SpellFailedReason.OnlyStealthed);
}
}
}
var spells = caster.Spells as PlayerSpellCollection;
// check cooldown and power cost
if (spells != null && !spells.IsReady(this))
{
return(SpellFailedReason.NotReady);
}
if (!IsPassive)
{
if (!caster.HasEnoughPowerToCast(this, null))
{
return(SpellFailedReason.NoPower);
}
}
return(SpellFailedReason.Ok);
}
public byte this[int address]
{
get
{
address &= 0xFFFF; // Mostly just a sanity check
if (address >= 0xFF80 && address < 0xFFFF) // HRAM
{
return(HRAM[address & 0x7F]);
}
// During DMA, only HRAM is accessable
else if (DMAInProcess)
{
return(0);
}
if (address >= 0xF000)
{
if (address >= 0xFF00) // IO Registers
{
switch (address & 0xF0)
{
default: return(0);
case 0:
switch (address & 0x0F)
{
case 0: return(Joypad.P1Register);
case 1: return(SerialTxReg);
case 2: return(SerialControlReg);
// 3: unused
case 4: return(Timer.DivisionRegister);
case 5: return(Timer.CountRegister);
case 6: return(Timer.ModuloRegister);
case 7: return(Timer.ControlRegister);
// 8 - 14 unused
case 15: return((byte)IFlagsReg);
}
return(0);
case 0x10: // Sound Registers
case 0x20:
case 0x30:
return(0); //su.ReadByte(address);
case 0x40: // LCD registers
switch (address & 0x0F)
{
case 0: return(GraphicsUnit.LCDCReg);
case 1: return(GraphicsUnit.STATReg);
case 2: return(GraphicsUnit.SCY);
case 3: return(GraphicsUnit.SCX);
case 4: return(GraphicsUnit.LCDYCoord);
case 5: return(GraphicsUnit.LYC);
case 6: return(DMAStart);
case 7: return(GraphicsUnit.BGPallet);
case 8: return(GraphicsUnit.ObjPallets[0]);
case 9: return(GraphicsUnit.ObjPallets[1]);
case 10: return(GraphicsUnit.WY);
case 11: return(GraphicsUnit.WX);
}
return(0);
case 0xF0: return((byte)IEnableReg);
}
}
// Addresses 0xFE00 - 0xFE9A is reserved for the graphics OAM.
// The rest is intentionally empty and should not be used.
else if (address >= 0xFEA0)
{
return(0);
}
else if (address >= 0xFE00)
{
return(GraphicsUnit.ReadOAM(address));
}
// F000-FDFF echos D000-DDFF
return(InternalRAM[(address & 0x1FFF)]);
}
else if (address >= 0xC000) // C000 - EFFF: Internal RAM and Internal RAM Echo
{
// C000 ~ DFFF is the actual internal RAM
// E000 ~ FDFF is an echo of the RAM, so we just read from the same place
return(InternalRAM[(address & 0x1FFF)]);
}
else if (address >= 0xA000) // A000 - BFFF: Switchable RAM bank, i.e. External/Cartridge RAM
{
return(Cartridge.ReadRAM(address));
}
else if (address >= 0x8000) // Graphics VRAM
{
return(GraphicsUnit.ReadVRAM(address));
}
// Cartidge ROM
else if ((address < 0x100) && BIOSLoaded)
{
return(BIOS[address]);
}
return(Cartridge.ReadROM(address));
}
set
{
address &= 0xFFFF; // Sanity check again
if (address >= 0xFF80 && address < 0xFFFF) // HRAM
{
HRAM[address & 0x7F] = value;
}
// During DMA, only HRAM is accessable
else if (DMAInProcess)
{
return;
}
if (address >= 0xF000)
{
if (address >= 0xFF00) // IO Registers
{
switch (address & 0xF0)
{
case 0:
switch (address & 0x0F)
{
case 0: Joypad.P1Register = value; break;
case 1: SerialTxReg = value; break;
case 2: SerialControlReg = value; break;
// 3: unused
case 4: Timer.DivisionRegister = value; break;
case 5: Timer.CountRegister = value; break;
case 6: Timer.ModuloRegister = value; break;
case 7: Timer.ControlRegister = value; break;
// 8 - 14 unused
case 15: IFlagsReg = (InterruptFlags)value; break;
}
return;
case 0x10: // Sound Registers
case 0x20:
case 0x30:
return; //su.WriteByte(address, value);
case 0x40: // LCD registers
switch (address & 0x0F)
{
case 0: GraphicsUnit.LCDCReg = value; break;
case 1: GraphicsUnit.STATReg = value; break;
case 2: GraphicsUnit.SCY = value; break;
case 3: GraphicsUnit.SCX = value; break;
// 4: LY (read-only)
case 5: GraphicsUnit.LYC = value; break;
case 6:
DMAStart = value;
StartDMATransfer();
break;
case 7: GraphicsUnit.BGPallet = value; break;
case 8: GraphicsUnit.ObjPallets[0] = value; break;
case 9: GraphicsUnit.ObjPallets[1] = value; break;
case 10: GraphicsUnit.WY = value; break;
case 11: GraphicsUnit.WX = value; break;
}
return;
case 0x50:
if (BIOSLoaded)
{
BIOSLoaded = value == 0;
}
break;
case 0xF0:
if (address == 0xFFFF)
{
IEnableReg = (InterruptFlags)value;
}
break;
}
}
// Addresses 0xFE00 - 0xFE9A is reserved for the graphics OAM.
// The rest is intentionally empty and should not be used.
else if (address >= 0xFE00 && address < 0xFEA0)
{
GraphicsUnit.WriteOAM(address, value);
}
// F000-FDFF echos D000-DDFF and is read-only
}
else if (address >= 0xC000 && address < 0xE000) // C000-DFFF - Internal RAM
{
switch (address)
{
case 0xc004:
break;
}
InternalRAM[address & 0x1FFF] = value;
}
else if (address >= 0xA000 && address < 0xC000) // A000-BFFF : External/Cartridge RAM
{
Cartridge.WriteRAM(address, value);
}
else if (address >= 0x8000 && address < 0xA000) // Graphics VRAM
{
GraphicsUnit.WriteVRAM(address, value);
}
else if (address < 0x8000)
{
Cartridge.WriteToRegister(address, value);
}
}
}
private void Gu_VBlankInterrupt()
{
IFlagsReg |= InterruptFlags.VerticalBlank;
}
private void Gu_LCDCInterrupt()
{
IFlagsReg |= InterruptFlags.LCDCStatus;
}
private void Timer_TimerOverflow()
{
IFlagsReg |= InterruptFlags.TimerOverflow;
}
private void Joypad_JoypadInterrupt()
{
IFlagsReg |= InterruptFlags.InputSignalLow;
}
