Difference between revisions of "ApCoCoA-1:GLPK.RPCSolve"
(New page: <command> <title>GLPK.RPCSolve</title> <short_description>Solve a system of polynomial equations over <tt>F_2</tt> for one solution in <tt>F_2^n</tt>.</short_description> <syntax> GLPK.RPC...) |
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+ | {{Version|1}} | ||
<command> | <command> | ||
<title>GLPK.RPCSolve</title> | <title>GLPK.RPCSolve</title> | ||
− | <short_description> | + | <short_description>Solves a system of polynomial equations over <tt>F_2</tt> for one solution in <tt>F_2^n</tt>.</short_description> |
<syntax> | <syntax> | ||
− | GLPK.RPCSolve(F:LIST, QStrategy:INT, CStrategy:INT, MinMax:STRING) | + | GLPK.RPCSolve(F:LIST, QStrategy:INT, CStrategy:INT, MinMax:STRING):LIST |
</syntax> | </syntax> | ||
<description> | <description> | ||
<em>Please note:</em> The function(s) explained on this page is/are using the <em>ApCoCoAServer</em>. You will have to start the ApCoCoAServer in order to use it/them. | <em>Please note:</em> The function(s) explained on this page is/are using the <em>ApCoCoAServer</em>. You will have to start the ApCoCoAServer in order to use it/them. | ||
<par/> | <par/> | ||
− | This function finds one solution in <tt>F_2^n</tt> of a system of polynomial equations over the field <tt>F_2</tt>. It uses Real Polynomial Conversion (RPC) along with some strategies from propositional logic to model a mixed integer linear programming problem. Then the | + | This function finds one solution in <tt>F_2^n</tt> of a system of polynomial equations over the field <tt>F_2</tt>. It uses Real Polynomial Conversion (RPC) along with some strategies from propositional logic to model a mixed integer linear programming problem. Then the modelled mixed integer linear programming problem is solved using glpk. |
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<item>@param <em>QStrategy</em>: Strategy for quadratic substitution. 0 - Standard; 1 - Linear Partner; 2 - Double Linear Partner; 3 - Quadratic Partner;</item> | <item>@param <em>QStrategy</em>: Strategy for quadratic substitution. 0 - Standard; 1 - Linear Partner; 2 - Double Linear Partner; 3 - Quadratic Partner;</item> | ||
<item>@param <em>CStrategy</em>: Strategy for cubic substitution. 0 - Standard; and 1 - Quadratic Partner;</item> | <item>@param <em>CStrategy</em>: Strategy for cubic substitution. 0 - Standard; and 1 - Quadratic Partner;</item> | ||
− | <item>@param <em>MinMax</em>: Optimization direction i.e. minimization ( | + | <item>@param <em>MinMax</em>: Optimization direction i.e. minimization ("Min") or maximization ("Max").</item> |
+ | <item>@return A list containing a zero of the system F.</item> | ||
</itemize> | </itemize> | ||
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QStrategy:=0; | QStrategy:=0; | ||
CStrategy:=0; | CStrategy:=0; | ||
− | MinMax:= | + | MinMax:="Max"; |
-- Then we compute the solution with | -- Then we compute the solution with | ||
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QStrategy:=1; | QStrategy:=1; | ||
CStrategy:=0; | CStrategy:=0; | ||
− | MinMax:= | + | MinMax:="Max"; |
-- Then we compute the solution with | -- Then we compute the solution with | ||
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QStrategy:=0; | QStrategy:=0; | ||
CStrategy:=1; | CStrategy:=1; | ||
− | MinMax:= | + | MinMax:="Max"; |
-- Then we compute the solution with | -- Then we compute the solution with | ||
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<key>solve linear programm</key> | <key>solve linear programm</key> | ||
<key>solve lp</key> | <key>solve lp</key> | ||
− | <key>GLPK. | + | <key>GLPK.rpcsolve</key> |
− | <wiki-category>Package_glpk</wiki-category> | + | <wiki-category>ApCoCoA-1:Package_glpk</wiki-category> |
</command> | </command> |
Latest revision as of 13:32, 29 October 2020
This article is about a function from ApCoCoA-1. |
GLPK.RPCSolve
Solves a system of polynomial equations over F_2 for one solution in F_2^n.
Syntax
GLPK.RPCSolve(F:LIST, QStrategy:INT, CStrategy:INT, MinMax:STRING):LIST
Description
Please note: The function(s) explained on this page is/are using the ApCoCoAServer. You will have to start the ApCoCoAServer in order to use it/them.
This function finds one solution in F_2^n of a system of polynomial equations over the field F_2. It uses Real Polynomial Conversion (RPC) along with some strategies from propositional logic to model a mixed integer linear programming problem. Then the modelled mixed integer linear programming problem is solved using glpk.
@param F: A List containing the polynomials of the given system.
@param QStrategy: Strategy for quadratic substitution. 0 - Standard; 1 - Linear Partner; 2 - Double Linear Partner; 3 - Quadratic Partner;
@param CStrategy: Strategy for cubic substitution. 0 - Standard; and 1 - Quadratic Partner;
@param MinMax: Optimization direction i.e. minimization ("Min") or maximization ("Max").
@return A list containing a zero of the system F.
Example
Use Z/(2)[x[1..4]]; F:=[ x[1]x[2] + x[2]x[3] + x[2]x[4] + x[3]x[4] + x[1] + x[3] + 1, x[1]x[2] + x[1]x[3] + x[1]x[4] + x[3]x[4] + x[2] + x[3] + 1, x[1]x[2] + x[1]x[3] + x[2]x[3] + x[3]x[4] + x[1] + x[4] + 1, x[1]x[3] + x[2]x[3] + x[1]x[4] + x[2]x[4] + 1 ]; QStrategy:=0; CStrategy:=0; MinMax:="Max"; -- Then we compute the solution with GLPK.RPCSolve(F, QStrategy, CStrategy, MinMax); -- The result will be the following: Modelling the system as a mixed integer programming problem. QStrategy: Standard, CStrategy: Standard. Model is ready to solve with GLPK... Solution Status: INTEGER OPTIMAL Value of objective function: 2 [0, 1, 0, 1] -------------------------------
Example
Use S::=Z/(2)[x[1..5]]; F:=[ x[1]x[5] + x[3]x[5] + x[4]x[5] + x[1] + x[4], x[1]x[2] + x[1]x[4] + x[3]x[4] + x[1]x[5] + x[2]x[5] + x[3]x[5] + x[1] + x[4] + x[5] + 1, x[1]x[2] + x[4]x[5] + x[1] + x[2] + x[4], x[1]x[4] + x[3]x[4] + x[2]x[5] + x[1] + x[2] + x[4] + x[5] + 1, x[1]x[4] + x[2]x[4] + x[3]x[4] + x[2]x[5] + x[4]x[5] + x[1] + x[2] + x[4] + x[5] ]; QStrategy:=1; CStrategy:=0; MinMax:="Max"; -- Then we compute the solution with GLPK.RPCSolve(F, QStrategy, CStrategy, MinMax); -- The result will be the following: Modelling the system as a mixed integer programming problem. QStrategy: LinearPartner, CStrategy: Standard. Model is ready to solve with GLPK... Solution Status: INTEGER OPTIMAL Value of objective function: 4 [1, 1, 1, 1, 0] -------------------------------
Example
Use ZZ/(2)[x[1..3]]; F := [ x[1]x[2]x[3] + x[1]x[2] + x[2]x[3] + x[1] + x[3] +1, x[1]x[2]x[3] + x[1]x[2] + x[2]x[3] + x[1] + x[2], x[1]x[2] + x[2]x[3] + x[2] ]; QStrategy:=0; CStrategy:=1; MinMax:="Max"; -- Then we compute the solution with GLPK.RPCSolve(F, QStrategy, CStrategy, MinMax); -- The result will be the following: Modelling the system as a mixed integer programming problem. QStrategy: Standard, CStrategy: CubicParnterDegree2. Model is ready to solve with GLPK... Solution Status: INTEGER OPTIMAL Value of objective function: 1 [0, 0, 1] -------------------------------