updated all to 32-bit to save registers and boost performance
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This commit is contained in:
Daniel 2024-11-01 11:23:58 +01:00
parent 9fc55c4c15
commit 68cedd75fc
7 changed files with 113 additions and 106 deletions

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@ -6,8 +6,6 @@ export interpret_gpu
export evaluate_gpu export evaluate_gpu
export test export test
# const SymbolTable64 = Dict{Tuple{Expr, Symbol},Float64}
#
# Some assertions: # Some assertions:
# Variables and parameters start their naming with "1" meaning the first variable/parameter has to be "x1/p1" and not "x0/p0" # Variables and parameters start their naming with "1" meaning the first variable/parameter has to be "x1/p1" and not "x0/p0"
# each index i in exprs has to have the matching values in the column i in Matrix X so that X[:,i] contains the values for expr[i]. The same goes for p # each index i in exprs has to have the matching values in the column i in Matrix X so that X[:,i] contains the values for expr[i]. The same goes for p
@ -15,22 +13,14 @@ export test
# #
# Evaluate Expressions on the GPU # Evaluate Expressions on the GPU
function interpret_gpu(exprs::Vector{Expr}, X::Matrix{Float64}, p::Vector{Vector{Float64}})::Matrix{Float64} function interpret_gpu(exprs::Vector{Expr}, X::Matrix{Float32}, p::Vector{Vector{Float32}})::Matrix{Float32}
# Ensure that no two expressions are interpreted in the same "warp" # Ensure that no two expressions are interpreted in the same "warp"
exprsPostfix = ExpressionProcessing.expr_to_postfix(exprs[1]) exprsPostfix = ExpressionProcessing.expr_to_postfix(exprs[1])
end end
# Convert Expressions to PTX Code and execute that instead # Convert Expressions to PTX Code and execute that instead
function evaluate_gpu(exprs::Vector{Expr}, X::Matrix{Float64}, p::Vector{Vector{Float64}})::Matrix{Float64}
# Look into this to maybe speed up PTX generation: https://cuda.juliagpu.org/stable/tutorials/introduction/#Parallelization-on-the-CPU
end
# TODO: See if it is feasible to make 32 versions too (mostly because 32 is significantly faster than 64)
# If AMD GPU support gets added, it might even be a good idea to add 16 bit floats, since they are even faster than 32 bit. On Nvidia 16 is either slower or equal in performance to 32 bit
function interpret_gpu(exprs::Vector{Expr}, X::Matrix{Float32}, p::Vector{Vector{Float32}})::Matrix{Float32}
end
function evaluate_gpu(exprs::Vector{Expr}, X::Matrix{Float32}, p::Vector{Vector{Float32}})::Matrix{Float32} function evaluate_gpu(exprs::Vector{Expr}, X::Matrix{Float32}, p::Vector{Vector{Float32}})::Matrix{Float32}
# Look into this to maybe speed up PTX generation: https://cuda.juliagpu.org/stable/tutorials/introduction/#Parallelization-on-the-CPU
end end
end end
@ -45,4 +35,4 @@ end
# #
# The following can be done on the CPU # The following can be done on the CPU
# convert expression to postfix notation (mandatory) # convert expression to postfix notation (mandatory)
# replace every variable with the according value from X and p (reduce extensive memory access on the GPU) # optional: replace every parameter with the correct value (should only improve performance if data transfer is the bottleneck)

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@ -3,20 +3,23 @@ module ExpressionProcessing
export expr_to_postfix export expr_to_postfix
export PostfixType export PostfixType
export Operator, ADD, SUBTRACT, MULTIPLY, DIVIDE, POWER, ABS, LOG, EXP, SQRT export Operator, ADD, SUBTRACT, MULTIPLY, DIVIDE, POWER, ABS, LOG, EXP, SQRT
export ElementType, EMPTY, FLOAT64, OPERATOR, INDEX export ElementType, EMPTY, FLOAT32, OPERATOR, INDEX
export ExpressionElement export ExpressionElement
@enum Operator::Int64 ADD=1 SUBTRACT=2 MULTIPLY=3 DIVIDE=4 POWER=5 ABS=6 LOG=7 EXP=8 SQRT=9 @enum Operator ADD=1 SUBTRACT=2 MULTIPLY=3 DIVIDE=4 POWER=5 ABS=6 LOG=7 EXP=8 SQRT=9
@enum ElementType EMPTY=0 FLOAT64=1 OPERATOR=2 INDEX=3 @enum ElementType EMPTY=0 FLOAT32=1 OPERATOR=2 INDEX=3
struct ExpressionElement struct ExpressionElement
Type::ElementType Type::ElementType
Value::Int64 # Reinterpret the stored value to type "ElementType" when using it Value::Int32 # Reinterpret the stored value to type "ElementType" when using it
end end
const PostfixType = Vector{ExpressionElement} const PostfixType = Vector{ExpressionElement}
"Converts a julia expression to its postfix notation" "
Converts a julia expression to its postfix notation.
NOTE: All 64-Bit values will be converted to 32-Bit. Be aware of the lost precision
"
function expr_to_postfix(expr::Expr)::PostfixType function expr_to_postfix(expr::Expr)::PostfixType
postfix = PostfixType() postfix = PostfixType()
operator = get_operator(expr.args[1]) operator = get_operator(expr.args[1])
@ -30,7 +33,7 @@ function expr_to_postfix(expr::Expr)::PostfixType
exprElement = convert_to_ExpressionElement(convert_var_to_int(arg)) exprElement = convert_to_ExpressionElement(convert_var_to_int(arg))
push!(postfix, exprElement) push!(postfix, exprElement)
else else
exprElement = convert_to_ExpressionElement(convert(Float64, arg)) exprElement = convert_to_ExpressionElement(convert(Float32, arg))
push!(postfix, exprElement) push!(postfix, exprElement)
end end
@ -73,7 +76,7 @@ end
"Extracts the number from a variable/parameter and returns it. If the symbol is a parameter ```pn```, the resulting value will be negativ. "Extracts the number from a variable/parameter and returns it. If the symbol is a parameter ```pn```, the resulting value will be negativ.
```x0 and p0``` are not allowed." ```x0 and p0``` are not allowed."
function convert_var_to_int(var::Symbol)::Int function convert_var_to_int(var::Symbol)::Int32
varStr = String(var) varStr = String(var)
number = parse(Int32, SubString(varStr, 2)) number = parse(Int32, SubString(varStr, 2))
@ -84,33 +87,39 @@ function convert_var_to_int(var::Symbol)::Int
return number return number
end end
function convert_to_ExpressionElement(element)::ExpressionElement function convert_to_ExpressionElement(element::Int32)::ExpressionElement
value = reinterpret(Int64, element) value = reinterpret(Int32, element)
if element isa Float64
return ExpressionElement(FLOAT64, value)
elseif element isa Int64
return ExpressionElement(INDEX, value) return ExpressionElement(INDEX, value)
elseif element isa Operator
return ExpressionElement(OPERATOR, value)
else
error("Element was of type '$(typeof(element))', which is not supported.")
end
end end
function convert_to_ExpressionElement(element::Int64)::ExpressionElement
value = reinterpret(Int32, convert(Int32, element))
return ExpressionElement(INDEX, value)
end
function convert_to_ExpressionElement(element::Float32)::ExpressionElement
value = reinterpret(Int32, element)
return ExpressionElement(FLOAT32, value)
end
function convert_to_ExpressionElement(element::Float64)::ExpressionElement
value = reinterpret(Int32, convert(Float32, element))
return ExpressionElement(FLOAT32, value)
end
function convert_to_ExpressionElement(element::Operator)::ExpressionElement
value = reinterpret(Int32, element)
return ExpressionElement(OPERATOR, value)
end
# #
# Everything below is currently not needed. Left here for potential future use # Everything below is currently not needed. Left here for potential future use
# #
const SymbolTable64 = Dict{Tuple{Expr, Symbol},Float64} const SymbolTable32 = Dict{Tuple{Expr, Symbol},Float32}
"Replaces all the variables and parameters of the given expression with their corresponding Value stored in the symtable "Replaces all the variables and parameters of the given expression with their corresponding Value stored in the symtable
# Arguments # Arguments
- `symtable::SymbolTable64`: Contains the values of all variables for each expression - `symtable::SymbolTable32`: Contains the values of all variables for each expression
- `originalExpr::Expr`: Contains a deep copy of the original expression. It is used to link the expression and variables to their according Value stored in the symtable - `originalExpr::Expr`: Contains a deep copy of the original expression. It is used to link the expression and variables to their according Value stored in the symtable
" "
function replace_variables!(ex::Expr, symtable::SymbolTable64, originalExpr::Expr) function replace_variables!(ex::Expr, symtable::SymbolTable32, originalExpr::Expr)
for i in 1:length(ex.args) for i in 1:length(ex.args)
arg = ex.args[i] arg = ex.args[i]
if typeof(arg) === Expr if typeof(arg) === Expr
@ -123,8 +132,8 @@ end
# TODO: Completly rewrite this function because I misunderstood it. Not every column is linked to an expression. therefore all other functions need to be reworked as well. Probably can't replace the variables in julia anymore, look into this. (see ExpressionExecutorCuda.jl for more info) # TODO: Completly rewrite this function because I misunderstood it. Not every column is linked to an expression. therefore all other functions need to be reworked as well. Probably can't replace the variables in julia anymore, look into this. (see ExpressionExecutorCuda.jl for more info)
# Before rewriting, proceed with just creating a postfix notation and sending the variable matrix as well as the parameter "matrix" to the GPU to perform first calculations # Before rewriting, proceed with just creating a postfix notation and sending the variable matrix as well as the parameter "matrix" to the GPU to perform first calculations
function construct_symtable(expressions::Vector{Expr}, mat::Matrix{Float64}, params::Vector{Vector{Float64}})::SymbolTable64 function construct_symtable(expressions::Vector{Expr}, mat::Matrix{Float32}, params::Vector{Vector{Float32}})::SymbolTable32
symtable = SymbolTable64() symtable = SymbolTable32()
for i in eachindex(expressions) for i in eachindex(expressions)
expr = expressions[i] expr = expressions[i]
@ -138,7 +147,7 @@ function construct_symtable(expressions::Vector{Expr}, mat::Matrix{Float64}, par
return symtable return symtable
end end
function fill_symtable!(expr::Expr, symtable::SymbolTable64, values::Vector{Float64}, symbolPrefix::String) function fill_symtable!(expr::Expr, symtable::SymbolTable32, values::Vector{Float32}, symbolPrefix::String)
varIndex = 1 varIndex = 1
for j in eachindex(values) for j in eachindex(values)
val = values[j] val = values[j]

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@ -8,19 +8,19 @@ export interpret
"Interprets the given expressions with the values provided. "Interprets the given expressions with the values provided.
# Arguments # Arguments
- expressions::Vector{ExpressionProcessing.PostfixType} : The expressions to execute in postfix form - expressions::Vector{ExpressionProcessing.PostfixType} : The expressions to execute in postfix form
- variables::Matrix{Float64} : The variables to use. Each column is mapped to the variables x1..xn - variables::Matrix{Float32} : The variables to use. Each column is mapped to the variables x1..xn
- parameters::Vector{Vector{Float64}} : The parameters to use. Each Vector contains the values for the parameters p1..pn. The number of parameters can be different for every expression - parameters::Vector{Vector{Float32}} : The parameters to use. Each Vector contains the values for the parameters p1..pn. The number of parameters can be different for every expression
" "
function interpret(expressions::Vector{ExpressionProcessing.PostfixType}, variables::Matrix{Float64}, parameters::Vector{Vector{Float64}})::Matrix{Float64} function interpret(expressions::Vector{ExpressionProcessing.PostfixType}, variables::Matrix{Float32}, parameters::Vector{Vector{Float32}})::Matrix{Float32}
variableCols = size(variables, 2) # number of sets of variables to use for each expression variableCols = size(variables, 2) # number of sets of variables to use for each expression
cudaVars = CuArray(variables) cudaVars = CuArray(variables)
cudaParams = create_cuda_array(parameters, NaN64) # column corresponds to data for one expression cudaParams = create_cuda_array(parameters, NaN32) # column corresponds to data for one expression
cudaExprs = create_cuda_array(expressions, ExpressionElement(EMPTY, 0)) # column corresponds to data for one expression cudaExprs = create_cuda_array(expressions, ExpressionElement(EMPTY, 0)) # column corresponds to data for one expression
# put into seperate cuArray, as this is static and would be inefficient to send seperatly to every kernel # put into seperate cuArray, as this is static and would be inefficient to send seperatly to every kernel
cudaStepsize = CuArray([get_max_inner_length(expressions), get_max_inner_length(parameters), size(variables, 1)]) # max num of values per expression; max nam of parameters per expression; number of variables per expression cudaStepsize = CuArray([get_max_inner_length(expressions), get_max_inner_length(parameters), size(variables, 1)]) # max num of values per expression; max nam of parameters per expression; number of variables per expression
# each expression has nr. of variable sets (nr. of columns of the variables) results and there are n expressions # each expression has nr. of variable sets (nr. of columns of the variables) results and there are n expressions
cudaResults = CuArray{Float64}(undef, variableCols, length(expressions)) cudaResults = CuArray{Float32}(undef, variableCols, length(expressions))
# Start kernel for each expression to ensure that no warp is working on different expressions # Start kernel for each expression to ensure that no warp is working on different expressions
for i in eachindex(expressions) for i in eachindex(expressions)
@ -37,7 +37,7 @@ end
#TODO: Add @inbounds to all indexing after it is verified that all works https://cuda.juliagpu.org/stable/development/kernel/#Bounds-checking #TODO: Add @inbounds to all indexing after it is verified that all works https://cuda.juliagpu.org/stable/development/kernel/#Bounds-checking
const MAX_STACK_SIZE = 25 # The max number of values the expression can have. so Constant values, Variables and parameters const MAX_STACK_SIZE = 25 # The max number of values the expression can have. so Constant values, Variables and parameters
function interpret_expression(expressions::CuDeviceArray{ExpressionElement}, variables::CuDeviceArray{Float64}, parameters::CuDeviceArray{Float64}, results::CuDeviceArray{Float64}, stepsize::CuDeviceArray{Int}, exprIndex::Int) function interpret_expression(expressions::CuDeviceArray{ExpressionElement}, variables::CuDeviceArray{Float32}, parameters::CuDeviceArray{Float32}, results::CuDeviceArray{Float32}, stepsize::CuDeviceArray{Int}, exprIndex::Int)
index = (blockIdx().x - 1) * blockDim().x + threadIdx().x # ctaid.x * ntid.x + tid.x index = (blockIdx().x - 1) * blockDim().x + threadIdx().x # ctaid.x * ntid.x + tid.x
stride = gridDim().x * blockDim().x # nctaid.x * ntid.x stride = gridDim().x * blockDim().x # nctaid.x * ntid.x
@ -46,7 +46,7 @@ function interpret_expression(expressions::CuDeviceArray{ExpressionElement}, var
firstParamIndex = ((exprIndex - 1) * stepsize[2]) # Exclusive firstParamIndex = ((exprIndex - 1) * stepsize[2]) # Exclusive
variableCols = length(variables) / stepsize[3] variableCols = length(variables) / stepsize[3]
operationStack = MVector{MAX_STACK_SIZE, Float64}(undef) # Try to get this to function with variable size too, to allow better memory usage operationStack = MVector{MAX_STACK_SIZE, Float32}(undef) # Try to get this to function with variable size too, to allow better memory usage
operationStackTop = 0 # stores index of the last defined/valid value operationStackTop = 0 # stores index of the last defined/valid value
for varSetIndex in index:stride for varSetIndex in index:stride
@ -65,9 +65,9 @@ function interpret_expression(expressions::CuDeviceArray{ExpressionElement}, var
val = -val val = -val
operationStack[operationStackTop] = parameters[firstParamIndex + val] operationStack[operationStackTop] = parameters[firstParamIndex + val]
end end
elseif expressions[i].Type == FLOAT64 elseif expressions[i].Type == FLOAT32
operationStackTop += 1 operationStackTop += 1
operationStack[operationStackTop] = reinterpret(Float64, expressions[i].Value) operationStack[operationStackTop] = reinterpret(Float32, expressions[i].Value)
elseif expressions[i].Type == OPERATOR elseif expressions[i].Type == OPERATOR
type = reinterpret(Operator, expressions[i].Value) type = reinterpret(Operator, expressions[i].Value)
if type == ADD if type == ADD

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@ -106,11 +106,11 @@ function transpile(expression::ExpressionProcessing.PostfixType)::String
ptxBuffer = IOBuffer() ptxBuffer = IOBuffer()
println(ptxBuffer, get_cuda_header()) println(ptxBuffer, get_cuda_header())
println(ptxBuffer, get_kernel_signature("ExpressionProcessing", [Int64, Float64])) println(ptxBuffer, get_kernel_signature("ExpressionProcessing", [Int32, Float32]))
println(ptxBuffer, "{") println(ptxBuffer, "{")
# TODO: Actually calculate the number of needed registers and extend to more register kinds # TODO: Actually calculate the number of needed registers and extend to more register kinds
println(ptxBuffer, get_register_definitions(1, 5, 1)) # apparently I can define registers anywhere. This might make things easier println(ptxBuffer, get_register_definitions(1, 5, 0)) # apparently I can define registers anywhere. This might make things easier
# TODO: Parameter loading # TODO: Parameter loading
println(ptxBuffer, get_guard_clause()) println(ptxBuffer, get_guard_clause())
@ -120,7 +120,9 @@ function transpile(expression::ExpressionProcessing.PostfixType)::String
# Variables have: %var0 to %varn - 1 # Variables have: %var0 to %varn - 1
# Parameters have: %param0 to %paramn - 1 # Parameters have: %param0 to %paramn - 1
# Code goes here # Code goes here
println(ptxBuffer, generate_calculation_code(expression)) (calc_code, fRegisterCount) = generate_calculation_code(expression)
println(ptxBuffer, get_register_definitions(0, 0, fRegisterCount))
println(ptxBuffer, calc_code)
# exit jump location # exit jump location
print(ptxBuffer, exitJumpLocationMarker); println(ptxBuffer, ": ret;") print(ptxBuffer, exitJumpLocationMarker); println(ptxBuffer, ": ret;")
@ -184,7 +186,8 @@ function get_guard_clause()::String
return String(take!(guardBuffer)) return String(take!(guardBuffer))
end end
function get_register_definitions(nrPred::Int, nr32Bit::Int, nrFloat64::Int)::String # TODO: refactor this for better usage. Maybe make this generate only one register definition and pass in the details
function get_register_definitions(nrPred::Int, nr32Bit::Int, nrFloat32::Int)::String
registersBuffer = IOBuffer() registersBuffer = IOBuffer()
if nrPred > 0 if nrPred > 0
@ -193,8 +196,8 @@ function get_register_definitions(nrPred::Int, nr32Bit::Int, nrFloat64::Int)::St
if nr32Bit > 0 if nr32Bit > 0
println(registersBuffer, ".reg .b32 %r<$nr32Bit>;") println(registersBuffer, ".reg .b32 %r<$nr32Bit>;")
end end
if nrFloat64 > 0 if nrFloat32 > 0
println(registersBuffer, ".reg .f64 %f<$nrFloat64>;") println(registersBuffer, ".reg .f32 %f<$nrFloat32>;")
end end
return String(take!(registersBuffer)) return String(take!(registersBuffer))
@ -205,38 +208,41 @@ end
# Probably do this: Get Expr -> traverse tree -> if child node is Expr: basically replace that node with the register containing the result of that Expr # Probably do this: Get Expr -> traverse tree -> if child node is Expr: basically replace that node with the register containing the result of that Expr
# Current assumption: Expression only made out of constant values # Current assumption: Expression only made out of constant values
function generate_calculation_code(expression::ExpressionProcessing.PostfixType)::String function generate_calculation_code(expression::ExpressionProcessing.PostfixType)::Tuple{String, Int}
codeBuffer = IOBuffer() codeBuffer = IOBuffer()
operands = Vector{Float64}() operands = Vector{Union{Float32, String}}() # Maybe make it of type ANY. Then I could put the register name "on the stack" instead and build up the code like that. Could also make it easier implementing variables/params
registerCounter = 0 registerCounter = 0
println(expression) println(expression)
for i in eachindex(expression) for i in eachindex(expression)
token = expression[i] token = expression[i]
if token.Type == FLOAT64 if token.Type == FLOAT32
push!(operands, reinterpret(Float64, token.Value)) push!(operands, reinterpret(Float32, token.Value))
elseif token.Type == OPERATOR elseif token.Type == OPERATOR
operator = get_ptx_operator(reinterpret(Operator, token.Value)) operator = get_ptx_operator(reinterpret(Operator, token.Value))
print(codeBuffer, " $operator %f$registerCounter ") register = "%f$registerCounter"
print(codeBuffer, " $operator $register, ")
# Ugly temporary proof of concept which is ignoring unary operators # Ugly temporary proof of concept which is ignoring unary operators
if length(operands) == 0 # if length(operands) == 0
print(codeBuffer, "%f") # print(codeBuffer, "%f")
print(codeBuffer, registerCounter - 2) # add result before previous result # print(codeBuffer, registerCounter - 2) # add result before previous result
end # end
print(codeBuffer, " ") # print(codeBuffer, " ")
if length(operands) <= 1 # if length(operands) <= 1
print(codeBuffer, "%f") # print(codeBuffer, "%f")
print(codeBuffer, registerCounter - 1) # add previous result # print(codeBuffer, registerCounter - 1) # add previous result
end # end
print(codeBuffer, " ") # print(codeBuffer, " ")
ops = last(operands, 2) ops = last(operands, 2)
pop!(operands);pop!(operands) pop!(operands);pop!(operands)
print(codeBuffer, join(ops, ", ")) # if operands has too few values it means the previous calculation is needed. So we need to use registerCounter - 1 or registerCounter - 2 previous registers print(codeBuffer, join(ops, ", ")) # if operands has too few values it means the previous calculation is needed. So we need to use registerCounter - 1 or registerCounter - 2 previous registers
println(codeBuffer, ";") println(codeBuffer, ";")
# empty!(operands) # empty!(operands)
push!(operands, register)
registerCounter += 1 registerCounter += 1
end end
@ -247,14 +253,14 @@ function generate_calculation_code(expression::ExpressionProcessing.PostfixType)
# on all other operations either 1 or 2 (one if unary and two if binary operator) # on all other operations either 1 or 2 (one if unary and two if binary operator)
end end
return String(take!(codeBuffer)) return (String(take!(codeBuffer)), registerCounter)
end end
function type_to_ptx_type(type::DataType)::String function type_to_ptx_type(type::DataType)::String
if type == Int64 if type == Int64
return ".s64" return ".s64"
elseif type == Float64 elseif type == Float32
return ".f64" return ".f32"
else else
return ".b64" return ".b64"
end end
@ -264,23 +270,23 @@ end
# Left out for now since I don't have register management yet # Left out for now since I don't have register management yet
function get_ptx_operator(operator::Operator)::String function get_ptx_operator(operator::Operator)::String
if operator == ADD if operator == ADD
return "add.f64" return "add.f32"
elseif operator == SUBTRACT elseif operator == SUBTRACT
return "sub.f64" return "sub.f32"
elseif operator == MULTIPLY elseif operator == MULTIPLY
return "mul.f64" return "mul.f32"
elseif operator == DIVIDE elseif operator == DIVIDE
return "div.approx.f64" return "div.approx.f32"
elseif operator == POWER elseif operator == POWER
return "" return ""
elseif operator == ABS elseif operator == ABS
return "abs.f64" return "abs.f32"
elseif operator == LOG elseif operator == LOG
return "lg2.approx.f64" return "lg2.approx.f32"
elseif operator == EXP elseif operator == EXP
return "" return ""
elseif operator == SQRT elseif operator == SQRT
return "sqrt.approx.f64" return "sqrt.approx.f32"
else else
throw(ArgumentError("Operator conversion to ptx not implemented for $operator")) throw(ArgumentError("Operator conversion to ptx not implemented for $operator"))
end end

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@ -1,20 +1,20 @@
using .ExpressionProcessing using .ExpressionProcessing
expressions = Vector{Expr}(undef, 1) expressions = Vector{Expr}(undef, 1)
variables = Matrix{Float64}(undef, 1,2) variables = Matrix{Float32}(undef, 1,2)
parameters = Vector{Vector{Float64}}(undef, 1) parameters = Vector{Vector{Float32}}(undef, 1)
# Resulting value should be 10 # Resulting value should be 10
expressions[1] = :(x1 + 1 * x2 + p1) expressions[1] = :(x1 + 1 * x2 + p1)
variables[1,1] = 2 variables[1,1] = 2
variables[1,2] = 3 variables[1,2] = 3
parameters[1] = Vector{Float64}(undef, 1) parameters[1] = Vector{Float32}(undef, 1)
parameters[1][1] = 5 parameters[1][1] = 5
@testset "Test conversion expression element" begin @testset "Test conversion expression element" begin
reference1 = ExpressionElement(FLOAT64, reinterpret(Int64, 1.0)) reference1 = ExpressionElement(FLOAT32, reinterpret(Int32, 1f0))
reference2 = ExpressionElement(INDEX, reinterpret(Int64, 1)) reference2 = ExpressionElement(INDEX, reinterpret(Int32, Int32(1)))
reference3 = ExpressionElement(OPERATOR, reinterpret(Int64, ADD)) reference3 = ExpressionElement(OPERATOR, reinterpret(Int32, ADD))
@test isequal(reference1, ExpressionProcessing.convert_to_ExpressionElement(1.0)) @test isequal(reference1, ExpressionProcessing.convert_to_ExpressionElement(1.0))
@test isequal(reference2, ExpressionProcessing.convert_to_ExpressionElement(1)) @test isequal(reference2, ExpressionProcessing.convert_to_ExpressionElement(1))

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@ -3,8 +3,8 @@ using .ExpressionProcessing
using .Interpreter using .Interpreter
expressions = Vector{Expr}(undef, 2) expressions = Vector{Expr}(undef, 2)
variables = Matrix{Float64}(undef, 2,2) variables = Matrix{Float32}(undef, 2,2)
parameters = Vector{Vector{Float64}}(undef, 2) parameters = Vector{Vector{Float32}}(undef, 2)
# Resulting value should be 10 for the first expression # Resulting value should be 10 for the first expression
expressions[1] = :(x1 + 1 * x2 + p1) expressions[1] = :(x1 + 1 * x2 + p1)
@ -13,34 +13,36 @@ variables[1,1] = 2.0
variables[2,1] = 3.0 variables[2,1] = 3.0
variables[1,2] = 0.0 variables[1,2] = 0.0
variables[2,2] = 5.0 variables[2,2] = 5.0
parameters[1] = Vector{Float64}(undef, 1) parameters[1] = Vector{Float32}(undef, 1)
parameters[2] = Vector{Float64}(undef, 2) parameters[2] = Vector{Float32}(undef, 2)
parameters[1][1] = 5.0 parameters[1][1] = 5.0
parameters[2][1] = 5.0 parameters[2][1] = 5.0
parameters[2][2] = 0.0 parameters[2][2] = 0.0
function testHelper(expression::Expr, variables::Matrix{Float64}, parameters::Vector{Vector{Float64}}, expectedResult::Float64) function testHelper(expression::Expr, variables::Matrix{Float32}, parameters::Vector{Vector{Float32}}, expectedResult)
postfix = Vector([expr_to_postfix(expression)]) postfix = Vector([expr_to_postfix(expression)])
result = Interpreter.interpret(postfix, variables, parameters) result = Interpreter.interpret(postfix, variables, parameters)
@test isequal(result[1,1], expectedResult)
expectedResult32 = convert(Float32, expectedResult)
@test isequal(result[1,1], expectedResult32)
end end
@testset "Test conversion to matrix" begin @testset "Test conversion to matrix" begin
reference = Matrix{Float64}(undef, 2, 2) reference = Matrix{Float32}(undef, 2, 2)
reference[1,1] = 5.0 reference[1,1] = 5.0
reference[2,1] = NaN64 reference[2,1] = NaN32
reference[1,2] = 5.0 reference[1,2] = 5.0
reference[2,2] = 0.0 reference[2,2] = 0.0
# reference = Matrix([5.0, NaN], # reference = Matrix([5.0, NaN],
# [5.0, 0.0]) # [5.0, 0.0])
result = Interpreter.convert_to_matrix(parameters, NaN64) result = Interpreter.convert_to_matrix(parameters, NaN32)
@test isequal(result, reference) @test isequal(result, reference)
end end
@testset "Test commutative interpretation" begin @testset "Test commutative interpretation" begin
var = Matrix{Float64}(undef, 2, 1) var = Matrix{Float32}(undef, 2, 1)
param = Vector{Vector{Float64}}(undef, 1) param = Vector{Vector{Float32}}(undef, 1)
expectedResult = 8.0 # Not using "eval" because the variables are not stored in global scope expectedResult = 8.0 # Not using "eval" because the variables are not stored in global scope
var[1,1] = 3.0 var[1,1] = 3.0
@ -59,8 +61,8 @@ end
end end
@testset "Test non commutative interpretation" begin @testset "Test non commutative interpretation" begin
var = Matrix{Float64}(undef, 2, 1) var = Matrix{Float32}(undef, 2, 1)
param = Vector{Vector{Float64}}(undef, 1) param = Vector{Vector{Float32}}(undef, 1)
expectedResult = -2.0 # Not using "eval" because the variables are not stored in global scope expectedResult = -2.0 # Not using "eval" because the variables are not stored in global scope
var[1,1] = 3.0 var[1,1] = 3.0
@ -89,8 +91,8 @@ end
end end
@testset "Test single value operator interpretation" begin @testset "Test single value operator interpretation" begin
var = Matrix{Float64}(undef, 1, 1) var = Matrix{Float32}(undef, 1, 1)
param = Vector{Vector{Float64}}(undef, 1) param = Vector{Vector{Float32}}(undef, 1)
expectedResult = 3.0 # Not using "eval" because the variables are not stored in global scope expectedResult = 3.0 # Not using "eval" because the variables are not stored in global scope
var[1,1] = -3.0 var[1,1] = -3.0
@ -108,8 +110,8 @@ end
end end
@testset "Test complex expressions" begin @testset "Test complex expressions" begin
var = Matrix{Float64}(undef, 2, 2) var = Matrix{Float32}(undef, 2, 2)
param = Vector{Vector{Float64}}(undef, 2) param = Vector{Vector{Float32}}(undef, 2)
# var set 1 # var set 1
var[1,1] = 3.0 var[1,1] = 3.0

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@ -3,8 +3,8 @@ using .ExpressionProcessing
using .Transpiler using .Transpiler
expressions = Vector{Expr}(undef, 2) expressions = Vector{Expr}(undef, 2)
variables = Matrix{Float64}(undef, 2,2) variables = Matrix{Float32}(undef, 2,2)
parameters = Vector{Vector{Float64}}(undef, 2) parameters = Vector{Vector{Float32}}(undef, 2)
# Resulting value should be 10 for the first expression # Resulting value should be 10 for the first expression
expressions[1] = :(1 + 3 * 5 / 7 - 1) expressions[1] = :(1 + 3 * 5 / 7 - 1)
@ -13,8 +13,8 @@ variables[1,1] = 2.0
variables[2,1] = 3.0 variables[2,1] = 3.0
variables[1,2] = 0.0 variables[1,2] = 0.0
variables[2,2] = 5.0 variables[2,2] = 5.0
parameters[1] = Vector{Float64}(undef, 1) parameters[1] = Vector{Float32}(undef, 1)
parameters[2] = Vector{Float64}(undef, 2) parameters[2] = Vector{Float32}(undef, 2)
parameters[1][1] = 5.0 parameters[1][1] = 5.0
parameters[2][1] = 5.0 parameters[2][1] = 5.0
parameters[2][2] = 0.0 parameters[2][2] = 0.0