{- This Source Code Form is subject to the terms of the Mozilla Public License, v. 2.0. If a copy of the MPL was not distributed with this file, You can obtain one at https://mozilla.org/MPL/2.0/. -} module Language.Elna.RiscV.CodeGenerator ( Directive(..) , Statement(..) , generateRiscV , riscVConfiguration ) where import Control.Monad.Trans.State (State, get, evalState, modify') import Data.HashMap.Strict (HashMap) import qualified Data.HashMap.Strict as HashMap import Data.Int (Int32) import Data.Word (Word32) import Data.Vector (Vector) import qualified Data.Vector as Vector import qualified Language.Elna.Architecture.RiscV as RiscV import Language.Elna.Backend.Allocator (MachineConfiguration(..), Store(..)) import Language.Elna.Backend.Intermediate ( Label(..) , Operand(..) , ProcedureQuadruples(..) , Quadruple(..) ) import Language.Elna.Location (Identifier(..)) import Data.Bits (Bits(..)) import Data.Foldable (Foldable(..), foldlM) import Data.Text (Text) import qualified Data.Text.Lazy.Builder.Int as Text.Builder import qualified Data.Text.Lazy.Builder as Text.Builder import qualified Data.Text.Lazy as Text.Lazy data Directive = GlobalDirective | FunctionDirective deriving (Eq, Show) data Statement = Instruction RiscV.Instruction | JumpLabel Text [Directive] deriving Eq riscVConfiguration :: MachineConfiguration RiscV.XRegister riscVConfiguration = MachineConfiguration { temporaryRegisters = [ RiscV.T0 , RiscV.T1 , RiscV.T2 , RiscV.T3 , RiscV.T4 , RiscV.T5 , RiscV.T6 ] } -- | Reserved register used for calculations to save an immediate temporary. immediateRegister :: RiscV.XRegister immediateRegister = RiscV.A7 type RiscVStore = Store RiscV.XRegister type RiscVQuadruple = Quadruple RiscVStore type RiscVOperand = Operand RiscVStore newtype RiscVGenerator a = RiscVGenerator { runRiscVGenerator :: State Word32 a } instance Functor RiscVGenerator where fmap f (RiscVGenerator x) = RiscVGenerator $ f <$> x instance Applicative RiscVGenerator where pure = RiscVGenerator . pure (RiscVGenerator f) <*> (RiscVGenerator x) = RiscVGenerator $ f <*> x instance Monad RiscVGenerator where (RiscVGenerator x) >>= f = RiscVGenerator $ x >>= (runRiscVGenerator . f) createLabel :: RiscVGenerator Text createLabel = do currentCounter <- RiscVGenerator get RiscVGenerator $ modify' (+ 1) pure $ mappend ".A" $ Text.Lazy.toStrict $ Text.Builder.toLazyText $ Text.Builder.decimal currentCounter generateRiscV :: HashMap Identifier (ProcedureQuadruples RiscVStore) -> Vector Statement generateRiscV = flip evalState 0 . runRiscVGenerator . foldlM go Vector.empty . HashMap.toList where go accumulator (Identifier key, ProcedureQuadruples{ stackSize, quadruples = value }) = let code = Vector.cons (JumpLabel key [GlobalDirective, FunctionDirective]) . fold <$> mapM (quadruple stackSize) value in (accumulator <>) <$> code quadruple :: Word32 -> RiscVQuadruple -> RiscVGenerator (Vector Statement) quadruple stackSize StartQuadruple = let totalStackSize = stackSize + 8 in pure $ Vector.fromList [ Instruction (RiscV.BaseInstruction RiscV.OpImm $ RiscV.I RiscV.SP RiscV.ADDI RiscV.SP (negate totalStackSize)) , Instruction (RiscV.BaseInstruction RiscV.Store $ RiscV.S 0 RiscV.SW RiscV.SP RiscV.S0) , Instruction (RiscV.BaseInstruction RiscV.Store $ RiscV.S 4 RiscV.SW RiscV.SP RiscV.RA) , Instruction (RiscV.BaseInstruction RiscV.OpImm $ RiscV.I RiscV.S0 RiscV.ADDI RiscV.SP totalStackSize) ] quadruple stackSize StopQuadruple = let totalStackSize = stackSize + 8 in pure $ Vector.fromList [ Instruction (RiscV.BaseInstruction RiscV.Load $ RiscV.I RiscV.S0 RiscV.LW RiscV.SP 0) , Instruction (RiscV.BaseInstruction RiscV.Load $ RiscV.I RiscV.RA RiscV.LW RiscV.SP 4) , Instruction (RiscV.BaseInstruction RiscV.OpImm $ RiscV.I RiscV.SP RiscV.ADDI RiscV.SP totalStackSize) , Instruction (RiscV.BaseInstruction RiscV.Jalr $ RiscV.I RiscV.RA RiscV.JALR RiscV.Zero 0) ] quadruple _ (ParameterQuadruple operand1) = let (operandRegister, statements) = loadImmediateOrRegister operand1 RiscV.A0 in pure $ mappend statements $ Vector.fromList [ Instruction (RiscV.BaseInstruction RiscV.OpImm $ RiscV.I RiscV.SP RiscV.ADDI RiscV.SP (negate 4)) , Instruction (RiscV.BaseInstruction RiscV.Store $ RiscV.S 0 RiscV.SW RiscV.SP operandRegister) ] quadruple _ (CallQuadruple callName numberOfArguments) = let restoreStackSize = numberOfArguments * 4 in pure $ Vector.fromList [ Instruction (RiscV.CallInstruction callName) , Instruction (RiscV.BaseInstruction RiscV.OpImm $ RiscV.I RiscV.SP RiscV.ADDI RiscV.SP restoreStackSize) ] quadruple _ (AddQuadruple operand1 operand2 store) = commutativeBinary (+) RiscV.ADD (RiscV.Funct7 0b0000000) (operand1, operand2) store quadruple _ (ProductQuadruple operand1 operand2 store) = commutativeBinary (*) RiscV.MUL (RiscV.Funct7 0b0000001) (operand1, operand2) store quadruple _ (SubtractionQuadruple operand1 operand2 store) | IntOperand immediateOperand1 <- operand1 , IntOperand immediateOperand2 <- operand2 = let (storeRegister, storeStatements) = storeToStore store in pure $ lui (immediateOperand1 - immediateOperand2) storeRegister <> storeStatements | VariableOperand variableOperand1 <- operand1 , VariableOperand variableOperand2 <- operand2 = let (storeRegister, storeStatements) = storeToStore store (operandRegister1, statements1) = loadFromStore variableOperand1 (operandRegister2, statements2) = loadFromStore variableOperand2 instruction = Instruction $ RiscV.BaseInstruction RiscV.Op $ RiscV.R storeRegister RiscV.SUB operandRegister1 operandRegister2 $ RiscV.Funct7 0b0100000 in pure $ statements1 <> statements2 <> Vector.cons instruction storeStatements | IntOperand immediateOperand1 <- operand1 , VariableOperand variableOperand2 <- operand2 = let (storeRegister, storeStatements) = storeToStore store statements1 = lui immediateOperand1 storeRegister (operandRegister2, statements2) = loadFromStore variableOperand2 instruction = Instruction $ RiscV.BaseInstruction RiscV.Op $ RiscV.R storeRegister RiscV.SUB storeRegister operandRegister2 $ RiscV.Funct7 0b0100000 in pure $ statements1 <> statements2 <> Vector.cons instruction storeStatements | VariableOperand variableOperand1 <- operand1 , IntOperand immediateOperand2 <- operand2 = let (storeRegister, storeStatements) = storeToStore store statements2 = lui (negate immediateOperand2) storeRegister (operandRegister1, statements1) = loadFromStore variableOperand1 instruction = Instruction $ RiscV.BaseInstruction RiscV.Op $ RiscV.R storeRegister RiscV.ADD storeRegister operandRegister1 $ RiscV.Funct7 0b0000000 in pure $ statements1 <> statements2 <> Vector.cons instruction storeStatements quadruple _ (NegationQuadruple operand1 store) | IntOperand immediateOperand1 <- operand1 = let (storeRegister, storeStatements) = storeToStore store in pure $ lui (negate immediateOperand1) storeRegister <> storeStatements | VariableOperand variableOperand1 <- operand1 = let (storeRegister, storeStatements) = storeToStore store (operandRegister1, statements1) = loadFromStore variableOperand1 instruction = Instruction $ RiscV.BaseInstruction RiscV.Op $ RiscV.R storeRegister RiscV.SUB RiscV.Zero operandRegister1 $ RiscV.Funct7 0b0100000 in pure $ statements1 <> Vector.cons instruction storeStatements quadruple _ (DivisionQuadruple operand1 operand2 store) | IntOperand immediateOperand1 <- operand1 , IntOperand immediateOperand2 <- operand2 = if immediateOperand2 == 0 then pure $ Vector.singleton $ Instruction (RiscV.CallInstruction "_divide_by_zero_error") else let (storeRegister, storeStatements) = storeToStore store in pure $ lui (quot immediateOperand1 immediateOperand2) storeRegister <> storeStatements | VariableOperand variableOperand1 <- operand1 , VariableOperand variableOperand2 <- operand2 = do let (storeRegister, storeStatements) = storeToStore store (operandRegister1, statements1) = loadFromStore variableOperand1 (operandRegister2, statements2) = loadFromStore variableOperand2 divisionInstruction = Instruction $ RiscV.BaseInstruction RiscV.Op $ RiscV.R storeRegister RiscV.DIV operandRegister1 operandRegister2 (RiscV.Funct7 0b0000001) branchLabel <- createLabel let branchInstruction = Instruction $ RiscV.RelocatableInstruction RiscV.Branch $ RiscV.RBranch branchLabel RiscV.BNE RiscV.Zero operandRegister2 pure $ statements1 <> statements2 <> Vector.fromList [ branchInstruction , Instruction (RiscV.CallInstruction "_divide_by_zero_error") , JumpLabel branchLabel [] , divisionInstruction ] <> storeStatements | VariableOperand variableOperand1 <- operand1 , IntOperand immediateOperand2 <- operand2 = let (storeRegister, storeStatements) = storeToStore store statements2 = lui immediateOperand2 storeRegister (operandRegister1, statements1) = loadFromStore variableOperand1 operationInstruction | immediateOperand2 == 0 = RiscV.CallInstruction "_divide_by_zero_error" | otherwise = RiscV.BaseInstruction RiscV.Op $ RiscV.R storeRegister RiscV.DIV operandRegister1 storeRegister $ RiscV.Funct7 0b0000001 in pure $ statements1 <> statements2 <> Vector.cons (Instruction operationInstruction) storeStatements | IntOperand immediateOperand1 <- operand1 , VariableOperand variableOperand2 <- operand2 = do let (storeRegister, storeStatements) = storeToStore store statements1 = lui immediateOperand1 storeRegister (operandRegister2, statements2) = loadFromStore variableOperand2 divisionInstruction = Instruction $ RiscV.BaseInstruction RiscV.Op $ RiscV.R storeRegister RiscV.DIV storeRegister operandRegister2 (RiscV.Funct7 0b0000001) branchLabel <- createLabel let branchInstruction = Instruction $ RiscV.RelocatableInstruction RiscV.Branch $ RiscV.RBranch branchLabel RiscV.BNE RiscV.Zero operandRegister2 pure $ statements1 <> statements2 <> Vector.fromList [ branchInstruction , Instruction (RiscV.CallInstruction "_divide_by_zero_error") , JumpLabel branchLabel [] , divisionInstruction ] <> storeStatements quadruple _ (LabelQuadruple (Label label)) = pure $ Vector.singleton $ JumpLabel label mempty quadruple _ (GoToQuadruple label) = pure $ Vector.singleton $ unconditionalJal label quadruple _ (EqualQuadruple operand1 operand2 goToLabel) = commutativeComparison (==) RiscV.BEQ (operand1, operand2) goToLabel quadruple _ (NonEqualQuadruple operand1 operand2 goToLabel) = commutativeComparison (/=) RiscV.BNE (operand1, operand2) goToLabel quadruple _ (LessQuadruple operand1 operand2 goToLabel) = lessThan (operand1, operand2) goToLabel quadruple _ (GreaterQuadruple operand1 operand2 goToLabel) = lessThan (operand2, operand1) goToLabel quadruple _ (LessOrEqualQuadruple operand1 operand2 goToLabel) = lessOrEqualThan (operand1, operand2) goToLabel quadruple _ (GreaterOrEqualQuadruple operand1 operand2 goToLabel) = lessOrEqualThan (operand2, operand1) goToLabel quadruple _ (AssignQuadruple operand1 store) | IntOperand immediateOperand1 <- operand1 = let (storeRegister, storeStatements) = storeToStore store in pure $ lui immediateOperand1 storeRegister <> storeStatements | VariableOperand variableOperand1 <- operand1 = let (operandRegister1, statements1) = loadFromStore variableOperand1 (storeRegister, storeStatements) = storeToStore store instruction = Instruction $ RiscV.BaseInstruction RiscV.OpImm $ RiscV.I storeRegister RiscV.ADDI operandRegister1 0 in pure $ statements1 <> Vector.cons instruction storeStatements quadruple _ (ArrayAssignQuadruple assigneeOperand indexOperand store) | IntOperand immediateAssigneeOperand <- assigneeOperand = let (storeRegister, storeStatements) = storeWithOffset store indexOperand in pure $ lui immediateAssigneeOperand storeRegister <> storeStatements | VariableOperand variableAssigneeOperand <- assigneeOperand = let (assigneeOperandRegister, assigneeStatements) = loadFromStore variableAssigneeOperand (storeRegister, storeStatements) = storeWithOffset store indexOperand instruction = Instruction $ RiscV.BaseInstruction RiscV.OpImm $ RiscV.I storeRegister RiscV.ADDI assigneeOperandRegister 0 in pure $ assigneeStatements <> Vector.cons instruction storeStatements where storeWithOffset :: RiscVStore -> Operand RiscVStore -> (RiscV.XRegister, Vector Statement) storeWithOffset (RegisterStore register) _ = (register, mempty) storeWithOffset (StackStore offset register) (IntOperand indexOffset) = let storeInstruction = Instruction $ RiscV.BaseInstruction RiscV.Store $ RiscV.S (fromIntegral $ offset + indexOffset * 4) RiscV.SW RiscV.S0 register in (register, Vector.singleton storeInstruction) storeWithOffset (StackStore offset register) (VariableOperand indexOffset) = let storeInstruction = Instruction $ RiscV.BaseInstruction RiscV.Store $ RiscV.S (fromIntegral offset) RiscV.SW immediateRegister register statements = calculateIndexOffset indexOffset in (register, Vector.snoc statements storeInstruction) quadruple _ (ArrayQuadruple assigneeVariable indexOperand store) = let (operandRegister1, statements1) = loadWithOffset assigneeVariable indexOperand (storeRegister, storeStatements) = storeToStore store instruction = Instruction $ RiscV.BaseInstruction RiscV.OpImm $ RiscV.I storeRegister RiscV.ADDI operandRegister1 0 in pure $ statements1 <> Vector.cons instruction storeStatements where loadWithOffset :: RiscVStore -> Operand RiscVStore -> (RiscV.XRegister, Vector Statement) loadWithOffset (RegisterStore register) _ = (register, mempty) loadWithOffset (StackStore offset register) (IntOperand indexOffset) = let loadInstruction = Instruction $ RiscV.BaseInstruction RiscV.Load $ RiscV.I register RiscV.LW RiscV.S0 (fromIntegral $ offset + indexOffset * 4) in (register, Vector.singleton loadInstruction) loadWithOffset (StackStore offset register) (VariableOperand indexOffset) = let loadInstruction = Instruction $ RiscV.BaseInstruction RiscV.Load $ RiscV.I register RiscV.SW immediateRegister (fromIntegral offset) statements = calculateIndexOffset indexOffset in (register, Vector.snoc statements loadInstruction) calculateIndexOffset :: RiscVStore -> Vector Statement calculateIndexOffset indexOffset = let (indexRegister, indexStatements) = loadFromStore indexOffset baseRegisterInstruction = Instruction $ RiscV.BaseInstruction RiscV.OpImm $ RiscV.I immediateRegister RiscV.ADDI RiscV.Zero 4 indexRelativeOffset = Instruction $ RiscV.BaseInstruction RiscV.Op $ RiscV.R immediateRegister RiscV.MUL immediateRegister indexRegister (RiscV.Funct7 0b0000001) registerWithOffset = Instruction $ RiscV.BaseInstruction RiscV.Op $ RiscV.R immediateRegister RiscV.ADD immediateRegister RiscV.S0 (RiscV.Funct7 0b0000000) statements = Vector.fromList [ baseRegisterInstruction , indexRelativeOffset , registerWithOffset ] in indexStatements <> statements unconditionalJal :: Label -> Statement unconditionalJal (Label goToLabel) = Instruction $ RiscV.RelocatableInstruction RiscV.Jal $ RiscV.RJal RiscV.Zero goToLabel loadImmediateOrRegister :: RiscVOperand -> RiscV.XRegister -> (RiscV.XRegister, Vector Statement) loadImmediateOrRegister (IntOperand intValue) targetRegister = (targetRegister, lui intValue targetRegister) loadImmediateOrRegister (VariableOperand store) _ = loadFromStore store lui :: Int32 -> RiscV.XRegister -> Vector Statement lui intValue targetRegister | intValue >= -2048 , intValue <= 2047 = Vector.singleton $ Instruction (RiscV.BaseInstruction RiscV.OpImm $ RiscV.I targetRegister RiscV.ADDI RiscV.Zero lo) | intValue .&. 0x800 /= 0 = Vector.fromList [ Instruction (RiscV.BaseInstruction RiscV.Lui $ RiscV.U targetRegister $ fromIntegral $ succ hi) , Instruction (RiscV.BaseInstruction RiscV.OpImm $ RiscV.I targetRegister RiscV.ADDI targetRegister lo) ] | otherwise = Vector.fromList [ Instruction (RiscV.BaseInstruction RiscV.Lui $ RiscV.U targetRegister $ fromIntegral hi) , Instruction (RiscV.BaseInstruction RiscV.OpImm $ RiscV.I targetRegister RiscV.ADDI targetRegister lo) ] where hi = intValue `shiftR` 12 lo = fromIntegral intValue commutativeBinary :: (Int32 -> Int32 -> Int32) -> RiscV.Funct3 -> RiscV.Funct7 -> (Operand RiscVStore, Operand RiscVStore) -> Store RiscV.XRegister -> RiscVGenerator (Vector Statement) commutativeBinary immediateOperation funct3 funct7 (operand1, operand2) store | IntOperand immediateOperand1 <- operand1 , IntOperand immediateOperand2 <- operand2 = let (storeRegister, storeStatements) = storeToStore store immediateOperation' = immediateOperation immediateOperand1 immediateOperand2 in pure $ lui immediateOperation' storeRegister <> storeStatements | VariableOperand variableOperand1 <- operand1 , VariableOperand variableOperand2 <- operand2 = let (operandRegister1, statements1) = loadFromStore variableOperand1 (operandRegister2, statements2) = loadFromStore variableOperand2 (storeRegister, storeStatements) = storeToStore store instruction = Instruction $ RiscV.BaseInstruction RiscV.Op $ RiscV.R storeRegister funct3 operandRegister1 operandRegister2 funct7 in pure $ statements1 <> statements2 <> Vector.cons instruction storeStatements | VariableOperand variableOperand1 <- operand1 , IntOperand immediateOperand2 <- operand2 = commutativeImmediateRegister variableOperand1 immediateOperand2 | IntOperand immediateOperand1 <- operand1 , VariableOperand variableOperand2 <- operand2 = commutativeImmediateRegister variableOperand2 immediateOperand1 where commutativeImmediateRegister variableOperand immediateOperand = let (storeRegister, storeStatements) = storeToStore store immediateStatements = lui immediateOperand storeRegister (operandRegister, registerStatements) = loadFromStore variableOperand instruction = Instruction $ RiscV.BaseInstruction RiscV.Op $ RiscV.R storeRegister funct3 storeRegister operandRegister funct7 in pure $ immediateStatements <> registerStatements <> Vector.cons instruction storeStatements commutativeComparison :: (Int32 -> Int32 -> Bool) -> RiscV.Funct3 -> (Operand RiscVStore, Operand RiscVStore) -> Label -> RiscVGenerator (Vector Statement) commutativeComparison immediateOperation funct3 (operand1, operand2) goToLabel | IntOperand immediateOperand1 <- operand1 , IntOperand immediateOperand2 <- operand2 = if immediateOperation immediateOperand1 immediateOperand2 then pure $ Vector.singleton $ unconditionalJal goToLabel else pure Vector.empty | VariableOperand variableOperand1 <- operand1 , VariableOperand variableOperand2 <- operand2 = do let (operandRegister1, statements1) = loadFromStore variableOperand1 (operandRegister2, statements2) = loadFromStore variableOperand2 Label goToLabel' = goToLabel pure $ Vector.snoc (statements1 <> statements2) $ Instruction $ RiscV.RelocatableInstruction RiscV.Branch $ RiscV.RBranch goToLabel' funct3 operandRegister1 operandRegister2 | VariableOperand variableOperand1 <- operand1 , IntOperand immediateOperand2 <- operand2 = compareImmediateRegister variableOperand1 immediateOperand2 | IntOperand immediateOperand1 <- operand1 , VariableOperand variableOperand2 <- operand2 = compareImmediateRegister variableOperand2 immediateOperand1 where compareImmediateRegister variableOperand immediateOperand = let immediateStatements = lui immediateOperand immediateRegister (operandRegister, registerStatements) = loadFromStore variableOperand Label goToLabel' = goToLabel in pure $ Vector.snoc (immediateStatements <> registerStatements) $ Instruction $ RiscV.RelocatableInstruction RiscV.Branch $ RiscV.RBranch goToLabel' funct3 operandRegister immediateRegister lessThan :: (Operand RiscVStore, Operand RiscVStore) -> Label -> RiscVGenerator (Vector Statement) lessThan (operand1, operand2) goToLabel | IntOperand immediateOperand1 <- operand1 , IntOperand immediateOperand2 <- operand2 = if immediateOperand1 < immediateOperand2 then pure $ Vector.singleton $ unconditionalJal goToLabel else pure Vector.empty | VariableOperand variableOperand1 <- operand1 , VariableOperand variableOperand2 <- operand2 = do let (operandRegister1, statements1) = loadFromStore variableOperand1 (operandRegister2, statements2) = loadFromStore variableOperand2 Label goToLabel' = goToLabel pure $ Vector.snoc (statements1 <> statements2) $ Instruction $ RiscV.RelocatableInstruction RiscV.Branch $ RiscV.RBranch goToLabel' RiscV.BLT operandRegister1 operandRegister2 | VariableOperand variableOperand1 <- operand1 , IntOperand immediateOperand2 <- operand2 = let statements2 = lui immediateOperand2 immediateRegister (operandRegister1, statements1) = loadFromStore variableOperand1 Label goToLabel' = goToLabel in pure $ Vector.snoc (statements1 <> statements2) $ Instruction $ RiscV.RelocatableInstruction RiscV.Branch $ RiscV.RBranch goToLabel' RiscV.BLT operandRegister1 immediateRegister | IntOperand immediateOperand1 <- operand1 , VariableOperand variableOperand2 <- operand2 = let statements1 = lui immediateOperand1 immediateRegister (operandRegister2, statements2) = loadFromStore variableOperand2 Label goToLabel' = goToLabel in pure $ Vector.snoc (statements1 <> statements2) $ Instruction $ RiscV.RelocatableInstruction RiscV.Branch $ RiscV.RBranch goToLabel' RiscV.BLT immediateRegister operandRegister2 lessOrEqualThan :: (Operand RiscVStore, Operand RiscVStore) -> Label -> RiscVGenerator (Vector Statement) lessOrEqualThan (operand1, operand2) goToLabel | IntOperand immediateOperand1 <- operand1 , IntOperand immediateOperand2 <- operand2 = if immediateOperand1 <= immediateOperand2 then pure $ Vector.singleton $ unconditionalJal goToLabel else pure Vector.empty | VariableOperand variableOperand1 <- operand1 , VariableOperand variableOperand2 <- operand2 = do let (operandRegister1, statements1) = loadFromStore variableOperand1 (operandRegister2, statements2) = loadFromStore variableOperand2 Label goToLabel' = goToLabel pure $ Vector.snoc (statements1 <> statements2) $ Instruction $ RiscV.RelocatableInstruction RiscV.Branch $ RiscV.RBranch goToLabel' RiscV.BGE operandRegister2 operandRegister1 | VariableOperand variableOperand1 <- operand1 , IntOperand immediateOperand2 <- operand2 = let statements2 = lui immediateOperand2 immediateRegister (operandRegister1, statements1) = loadFromStore variableOperand1 Label goToLabel' = goToLabel in pure $ Vector.snoc (statements1 <> statements2) $ Instruction $ RiscV.RelocatableInstruction RiscV.Branch $ RiscV.RBranch goToLabel' RiscV.BGE immediateRegister operandRegister1 | IntOperand immediateOperand1 <- operand1 , VariableOperand variableOperand2 <- operand2 = let statements1 = lui immediateOperand1 immediateRegister (operandRegister2, statements2) = loadFromStore variableOperand2 Label goToLabel' = goToLabel in pure $ Vector.snoc (statements1 <> statements2) $ Instruction $ RiscV.RelocatableInstruction RiscV.Branch $ RiscV.RBranch goToLabel' RiscV.BGE operandRegister2 immediateRegister loadFromStore :: RiscVStore -> (RiscV.XRegister, Vector Statement) loadFromStore (RegisterStore register) = (register, mempty) loadFromStore (StackStore offset register) = let loadInstruction = Instruction $ RiscV.BaseInstruction RiscV.Load $ RiscV.I register RiscV.LW RiscV.S0 (fromIntegral offset) in (register, Vector.singleton loadInstruction) storeToStore :: RiscVStore -> (RiscV.XRegister, Vector Statement) storeToStore (RegisterStore register) = (register, mempty) storeToStore (StackStore offset register) = let storeInstruction = Instruction $ RiscV.BaseInstruction RiscV.Store $ RiscV.S (fromIntegral offset) RiscV.SW RiscV.S0 register in (register, Vector.singleton storeInstruction)