luet/pkg/solver/solver_test.go

// Copyright © 2019 Ettore Di Giacinto <mudler@gentoo.org>
//
// This program is free software; you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation; either version 2 of the License, or
// (at your option) any later version.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License along
// with this program; if not, see <http://www.gnu.org/licenses/>.

package solver_test

import (
	. "github.com/onsi/ginkgo"
	. "github.com/onsi/gomega"
	pkg "gitlab.com/mudler/luet/pkg/package"

	. "gitlab.com/mudler/luet/pkg/solver"
)

var _ = Describe("Solver", func() {

	Context("Simple set", func() {
		It("Solves correctly if the selected package has no requirements or conflicts and we have nothing installed yet", func() {
			B := pkg.NewPackage("B", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})
			A := pkg.NewPackage("A", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})
			C := pkg.NewPackage("C", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})

			s := NewSolver([]pkg.Package{}, []pkg.Package{A, B, C})
			solution, err := s.Install([]pkg.Package{A})
			Expect(err).ToNot(HaveOccurred())
			Expect(solution).To(ContainElement(PackageAssert{Package: A.IsFlagged(true), Value: true}))
			Expect(len(solution)).To(Equal(1))
		})

		It("Solves correctly if the selected package has no requirements or conflicts and we have installed one package", func() {
			B := pkg.NewPackage("B", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})
			A := pkg.NewPackage("A", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})
			C := pkg.NewPackage("C", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})

			s := NewSolver([]pkg.Package{C}, []pkg.Package{A, B, C})
			solution, err := s.Install([]pkg.Package{B})
			Expect(err).ToNot(HaveOccurred())
			Expect(solution).To(ContainElement(PackageAssert{Package: B.IsFlagged(true), Value: true}))
			Expect(solution).To(ContainElement(PackageAssert{Package: C.IsFlagged(true), Value: true}))
			Expect(len(solution)).To(Equal(2))
		})

		It("Solves correctly if the selected package to install has no requirement or conflicts, but in the world there is one with a requirement", func() {
			B := pkg.NewPackage("B", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})
			A := pkg.NewPackage("A", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})
			C := pkg.NewPackage("C", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})
			D := pkg.NewPackage("D", "", []*pkg.DefaultPackage{B}, []*pkg.DefaultPackage{})
			E := pkg.NewPackage("E", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})

			s := NewSolver([]pkg.Package{E, C}, []pkg.Package{A, B, C, D, E})
			solution, err := s.Install([]pkg.Package{A})
			Expect(err).ToNot(HaveOccurred())
			Expect(solution).To(ContainElement(PackageAssert{Package: A.IsFlagged(true), Value: true}))
			Expect(solution).To(ContainElement(PackageAssert{Package: C.IsFlagged(true), Value: true}))
			Expect(solution).To(ContainElement(PackageAssert{Package: E.IsFlagged(true), Value: true}))
			Expect(solution).To(ContainElement(PackageAssert{Package: B.IsFlagged(true), Value: false}))
			Expect(solution).To(ContainElement(PackageAssert{Package: D.IsFlagged(true), Value: false}))

			Expect(len(solution)).To(Equal(5))
		})

		It("Solves correctly if the selected package to install has requirements", func() {
			B := pkg.NewPackage("B", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})
			C := pkg.NewPackage("C", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})
			D := pkg.NewPackage("D", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})
			A := pkg.NewPackage("A", "", []*pkg.DefaultPackage{D}, []*pkg.DefaultPackage{})

			s := NewSolver([]pkg.Package{C}, []pkg.Package{A, B, C, D})
			solution, err := s.Install([]pkg.Package{A})
			Expect(err).ToNot(HaveOccurred())
			Expect(solution).To(ContainElement(PackageAssert{Package: A.IsFlagged(true), Value: true}))
			Expect(solution).To(ContainElement(PackageAssert{Package: C.IsFlagged(true), Value: true}))
			Expect(solution).To(ContainElement(PackageAssert{Package: D.IsFlagged(true), Value: true}))

			Expect(len(solution)).To(Equal(3))
		})

		It("Solves correctly", func() {
			B := pkg.NewPackage("B", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})
			A := pkg.NewPackage("A", "", []*pkg.DefaultPackage{B}, []*pkg.DefaultPackage{})
			C := pkg.NewPackage("C", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})

			s := NewSolver([]pkg.Package{C}, []pkg.Package{A, B, C})
			solution, err := s.Install([]pkg.Package{A})
			Expect(err).ToNot(HaveOccurred())
			Expect(solution).To(ContainElement(PackageAssert{Package: A.IsFlagged(true), Value: true}))
			Expect(solution).To(ContainElement(PackageAssert{Package: B.IsFlagged(true), Value: true}))
			Expect(solution).To(ContainElement(PackageAssert{Package: C.IsFlagged(true), Value: true}))
			Expect(len(solution)).To(Equal(3))
		})
		It("Solves correctly more complex ones", func() {
			C := pkg.NewPackage("C", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})
			D := pkg.NewPackage("D", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})
			B := pkg.NewPackage("B", "", []*pkg.DefaultPackage{D}, []*pkg.DefaultPackage{})
			A := pkg.NewPackage("A", "", []*pkg.DefaultPackage{B}, []*pkg.DefaultPackage{})

			s := NewSolver([]pkg.Package{C}, []pkg.Package{A, B, C, D})

			solution, err := s.Install([]pkg.Package{A})
			Expect(solution).To(ContainElement(PackageAssert{Package: A.IsFlagged(true), Value: true}))
			Expect(solution).To(ContainElement(PackageAssert{Package: B.IsFlagged(true), Value: true}))
			Expect(solution).To(ContainElement(PackageAssert{Package: D.IsFlagged(true), Value: true}))
			Expect(solution).To(ContainElement(PackageAssert{Package: C.IsFlagged(true), Value: true}))
			Expect(len(solution)).To(Equal(4))
			Expect(err).ToNot(HaveOccurred())
		})

		It("Solves correctly more complex ones", func() {
			E := pkg.NewPackage("E", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})
			C := pkg.NewPackage("C", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})
			D := pkg.NewPackage("D", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})
			B := pkg.NewPackage("B", "", []*pkg.DefaultPackage{D}, []*pkg.DefaultPackage{})
			A := pkg.NewPackage("A", "", []*pkg.DefaultPackage{B}, []*pkg.DefaultPackage{})

			s := NewSolver([]pkg.Package{}, []pkg.Package{A, B, C, D, E})

			solution, err := s.Install([]pkg.Package{A})
			Expect(solution).To(ContainElement(PackageAssert{Package: A.IsFlagged(true), Value: true}))
			Expect(solution).To(ContainElement(PackageAssert{Package: B.IsFlagged(true), Value: true}))
			Expect(solution).To(ContainElement(PackageAssert{Package: D.IsFlagged(true), Value: true}))
			Expect(len(solution)).To(Equal(3))
			Expect(err).ToNot(HaveOccurred())
		})

		It("Uninstalls simple package correctly", func() {
			C := pkg.NewPackage("C", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})
			D := pkg.NewPackage("D", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})
			B := pkg.NewPackage("B", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})
			A := pkg.NewPackage("A", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})

			s := NewSolver([]pkg.Package{A, B, C, D}, []pkg.Package{A, B, C, D})

			solution, err := s.Uninstall(A)
			Expect(err).ToNot(HaveOccurred())

			Expect(solution).To(ContainElement(A.IsFlagged(false)))

			//	Expect(solution).To(ContainElement(PackageAssert{Package: C.IsFlagged(true), Value: true}))
			Expect(len(solution)).To(Equal(1))
		})

		It("Uninstalls complex package correctly", func() {
			C := pkg.NewPackage("C", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})
			D := pkg.NewPackage("D", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})
			B := pkg.NewPackage("B", "", []*pkg.DefaultPackage{D}, []*pkg.DefaultPackage{})
			A := pkg.NewPackage("A", "", []*pkg.DefaultPackage{B}, []*pkg.DefaultPackage{})
			C.IsFlagged(true) // installed

			s := NewSolver([]pkg.Package{A, B, C, D}, []pkg.Package{A, B, C, D})

			solution, err := s.Uninstall(A)
			Expect(solution).To(ContainElement(A.IsFlagged(false)))
			Expect(solution).To(ContainElement(B.IsFlagged(false)))
			//Expect(solution).To(ContainElement(C.IsFlagged(true)))
			Expect(solution).To(ContainElement(D.IsFlagged(false)))

			//	Expect(solution).To(ContainElement(PackageAssert{Package: C.IsFlagged(true), Value: true}))
			Expect(len(solution)).To(Equal(3))
			Expect(err).ToNot(HaveOccurred())

		})

	})

	Context("Conflict set", func() {

		It("is unsolvable - as we something we ask to install conflict with system stuff", func() {
			C := pkg.NewPackage("C", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})
			//	D := pkg.NewPackage("D", "", []pkg.Package{}, []pkg.Package{})
			B := pkg.NewPackage("B", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{C})
			A := pkg.NewPackage("A", "", []*pkg.DefaultPackage{B}, []*pkg.DefaultPackage{})

			s := NewSolver([]pkg.Package{C}, []pkg.Package{A, B, C})

			solution, err := s.Install([]pkg.Package{A})
			Expect(len(solution)).To(Equal(0))
			Expect(err).To(HaveOccurred())
		})

	})

	Context("Complex data sets", func() {
		It("Solves them correctly", func() {
			C := pkg.NewPackage("C", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})
			E := pkg.NewPackage("E", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})
			F := pkg.NewPackage("F", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})
			G := pkg.NewPackage("G", "", []*pkg.DefaultPackage{}, []*pkg.DefaultPackage{})
			H := pkg.NewPackage("H", "", []*pkg.DefaultPackage{G}, []*pkg.DefaultPackage{})
			D := pkg.NewPackage("D", "", []*pkg.DefaultPackage{H}, []*pkg.DefaultPackage{})
			B := pkg.NewPackage("B", "", []*pkg.DefaultPackage{D}, []*pkg.DefaultPackage{})
			A := pkg.NewPackage("A", "", []*pkg.DefaultPackage{B}, []*pkg.DefaultPackage{})

			s := NewSolver([]pkg.Package{C}, []pkg.Package{A, B, C, D, E, F, G})

			solution, err := s.Install([]pkg.Package{A})
			Expect(solution).To(ContainElement(PackageAssert{Package: A.IsFlagged(true), Value: true}))
			Expect(solution).To(ContainElement(PackageAssert{Package: B.IsFlagged(true), Value: true}))
			Expect(solution).To(ContainElement(PackageAssert{Package: D.IsFlagged(true), Value: true}))
			Expect(solution).To(ContainElement(PackageAssert{Package: C.IsFlagged(true), Value: true}))
			Expect(solution).To(ContainElement(PackageAssert{Package: H.IsFlagged(true), Value: true}))
			Expect(solution).To(ContainElement(PackageAssert{Package: G.IsFlagged(true), Value: true}))

			Expect(len(solution)).To(Equal(6))
			Expect(err).ToNot(HaveOccurred())
		})
	})

})
Draft 2018-09-21 21:29:50 +00:00			`// Copyright © 2019 Ettore Di Giacinto <mudler@gentoo.org>`
			`//`
			`// This program is free software; you can redistribute it and/or modify`
			`// it under the terms of the GNU General Public License as published by`
			`// the Free Software Foundation; either version 2 of the License, or`
			`// (at your option) any later version.`
			`//`
			`// This program is distributed in the hope that it will be useful,`
			`// but WITHOUT ANY WARRANTY; without even the implied warranty of`
			`// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the`
			`// GNU General Public License for more details.`
			`//`
			`// You should have received a copy of the GNU General Public License along`
			`// with this program; if not, see <http://www.gnu.org/licenses/>.`

			`package solver_test`

			`import (`
			`. "github.com/onsi/ginkgo"`
			`. "github.com/onsi/gomega"`
			`pkg "gitlab.com/mudler/luet/pkg/package"`

			`. "gitlab.com/mudler/luet/pkg/solver"`
			`)`

			`var _ = Describe("Solver", func() {`

			`Context("Simple set", func() {`
Add uninstall Uninstall can be done in different ways - the most accurate would be to try find a minimum subset of packages that gives conflicts and try to reduce them gradually. E.g. this could be done with other SAT algorithms. For now we keep things simple and we compute the uninstalls as an indirect of an installation from an empty profile. Also take care of corner cases where world has no clauses, and fixes a typo in building the world formula 2019-06-05 15:51:24 +00:00			`It("Solves correctly if the selected package has no requirements or conflicts and we have nothing installed yet", func() {`
			`B := pkg.NewPackage("B", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`
			`A := pkg.NewPackage("A", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`
			`C := pkg.NewPackage("C", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`

			`s := NewSolver([]pkg.Package{}, []pkg.Package{A, B, C})`
			`solution, err := s.Install([]pkg.Package{A})`
			`Expect(err).ToNot(HaveOccurred())`
			`Expect(solution).To(ContainElement(PackageAssert{Package: A.IsFlagged(true), Value: true}))`
			`Expect(len(solution)).To(Equal(1))`
			`})`

			`It("Solves correctly if the selected package has no requirements or conflicts and we have installed one package", func() {`
			`B := pkg.NewPackage("B", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`
			`A := pkg.NewPackage("A", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`
			`C := pkg.NewPackage("C", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`

			`s := NewSolver([]pkg.Package{C}, []pkg.Package{A, B, C})`
			`solution, err := s.Install([]pkg.Package{B})`
			`Expect(err).ToNot(HaveOccurred())`
			`Expect(solution).To(ContainElement(PackageAssert{Package: B.IsFlagged(true), Value: true}))`
			`Expect(solution).To(ContainElement(PackageAssert{Package: C.IsFlagged(true), Value: true}))`
			`Expect(len(solution)).To(Equal(2))`
			`})`

			`It("Solves correctly if the selected package to install has no requirement or conflicts, but in the world there is one with a requirement", func() {`
			`B := pkg.NewPackage("B", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`
			`A := pkg.NewPackage("A", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`
			`C := pkg.NewPackage("C", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`
			`D := pkg.NewPackage("D", "", []pkg.DefaultPackage{B}, []pkg.DefaultPackage{})`
			`E := pkg.NewPackage("E", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`

			`s := NewSolver([]pkg.Package{E, C}, []pkg.Package{A, B, C, D, E})`
			`solution, err := s.Install([]pkg.Package{A})`
			`Expect(err).ToNot(HaveOccurred())`
			`Expect(solution).To(ContainElement(PackageAssert{Package: A.IsFlagged(true), Value: true}))`
			`Expect(solution).To(ContainElement(PackageAssert{Package: C.IsFlagged(true), Value: true}))`
			`Expect(solution).To(ContainElement(PackageAssert{Package: E.IsFlagged(true), Value: true}))`
			`Expect(solution).To(ContainElement(PackageAssert{Package: B.IsFlagged(true), Value: false}))`
			`Expect(solution).To(ContainElement(PackageAssert{Package: D.IsFlagged(true), Value: false}))`

			`Expect(len(solution)).To(Equal(5))`
			`})`

			`It("Solves correctly if the selected package to install has requirements", func() {`
			`B := pkg.NewPackage("B", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`
			`C := pkg.NewPackage("C", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`
			`D := pkg.NewPackage("D", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`
			`A := pkg.NewPackage("A", "", []pkg.DefaultPackage{D}, []pkg.DefaultPackage{})`

			`s := NewSolver([]pkg.Package{C}, []pkg.Package{A, B, C, D})`
			`solution, err := s.Install([]pkg.Package{A})`
			`Expect(err).ToNot(HaveOccurred())`
			`Expect(solution).To(ContainElement(PackageAssert{Package: A.IsFlagged(true), Value: true}))`
			`Expect(solution).To(ContainElement(PackageAssert{Package: C.IsFlagged(true), Value: true}))`
			`Expect(solution).To(ContainElement(PackageAssert{Package: D.IsFlagged(true), Value: true}))`

			`Expect(len(solution)).To(Equal(3))`
			`})`
Draft 2018-09-21 21:29:50 +00:00
			`It("Solves correctly", func() {`
Implement basic install algorithm 2019-06-04 19:25:17 +00:00			`B := pkg.NewPackage("B", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`
			`A := pkg.NewPackage("A", "", []pkg.DefaultPackage{B}, []pkg.DefaultPackage{})`
			`C := pkg.NewPackage("C", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`
Draft 2018-09-21 21:29:50 +00:00
Add uninstall Uninstall can be done in different ways - the most accurate would be to try find a minimum subset of packages that gives conflicts and try to reduce them gradually. E.g. this could be done with other SAT algorithms. For now we keep things simple and we compute the uninstalls as an indirect of an installation from an empty profile. Also take care of corner cases where world has no clauses, and fixes a typo in building the world formula 2019-06-05 15:51:24 +00:00			`s := NewSolver([]pkg.Package{C}, []pkg.Package{A, B, C})`
Rename Solve to Install 2019-06-04 20:22:45 +00:00			`solution, err := s.Install([]pkg.Package{A})`
Draft 2018-09-21 21:29:50 +00:00			`Expect(err).ToNot(HaveOccurred())`
Implement basic install algorithm 2019-06-04 19:25:17 +00:00			`Expect(solution).To(ContainElement(PackageAssert{Package: A.IsFlagged(true), Value: true}))`
			`Expect(solution).To(ContainElement(PackageAssert{Package: B.IsFlagged(true), Value: true}))`
			`Expect(solution).To(ContainElement(PackageAssert{Package: C.IsFlagged(true), Value: true}))`
Handle case when no packages are installed in the system, and add test for it 2019-06-04 20:05:52 +00:00			`Expect(len(solution)).To(Equal(3))`
Draft 2018-09-21 21:29:50 +00:00			`})`
Build formulas recursively 2019-06-03 21:23:02 +00:00			`It("Solves correctly more complex ones", func() {`
Implement basic install algorithm 2019-06-04 19:25:17 +00:00			`C := pkg.NewPackage("C", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`
			`D := pkg.NewPackage("D", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`
			`B := pkg.NewPackage("B", "", []pkg.DefaultPackage{D}, []pkg.DefaultPackage{})`
			`A := pkg.NewPackage("A", "", []pkg.DefaultPackage{B}, []pkg.DefaultPackage{})`
Build formulas recursively 2019-06-03 21:23:02 +00:00
Rename Solve to Install 2019-06-04 20:22:45 +00:00			`s := NewSolver([]pkg.Package{C}, []pkg.Package{A, B, C, D})`
Build formulas recursively 2019-06-03 21:23:02 +00:00
Rename Solve to Install 2019-06-04 20:22:45 +00:00			`solution, err := s.Install([]pkg.Package{A})`
Implement basic install algorithm 2019-06-04 19:25:17 +00:00			`Expect(solution).To(ContainElement(PackageAssert{Package: A.IsFlagged(true), Value: true}))`
			`Expect(solution).To(ContainElement(PackageAssert{Package: B.IsFlagged(true), Value: true}))`
			`Expect(solution).To(ContainElement(PackageAssert{Package: D.IsFlagged(true), Value: true}))`
Handle case when no packages are installed in the system, and add test for it 2019-06-04 20:05:52 +00:00			`Expect(solution).To(ContainElement(PackageAssert{Package: C.IsFlagged(true), Value: true}))`
			`Expect(len(solution)).To(Equal(4))`
			`Expect(err).ToNot(HaveOccurred())`
			`})`

			`It("Solves correctly more complex ones", func() {`
Add uninstall Uninstall can be done in different ways - the most accurate would be to try find a minimum subset of packages that gives conflicts and try to reduce them gradually. E.g. this could be done with other SAT algorithms. For now we keep things simple and we compute the uninstalls as an indirect of an installation from an empty profile. Also take care of corner cases where world has no clauses, and fixes a typo in building the world formula 2019-06-05 15:51:24 +00:00			`E := pkg.NewPackage("E", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`
Handle case when no packages are installed in the system, and add test for it 2019-06-04 20:05:52 +00:00			`C := pkg.NewPackage("C", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`
			`D := pkg.NewPackage("D", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`
			`B := pkg.NewPackage("B", "", []pkg.DefaultPackage{D}, []pkg.DefaultPackage{})`
			`A := pkg.NewPackage("A", "", []pkg.DefaultPackage{B}, []pkg.DefaultPackage{})`

Add uninstall Uninstall can be done in different ways - the most accurate would be to try find a minimum subset of packages that gives conflicts and try to reduce them gradually. E.g. this could be done with other SAT algorithms. For now we keep things simple and we compute the uninstalls as an indirect of an installation from an empty profile. Also take care of corner cases where world has no clauses, and fixes a typo in building the world formula 2019-06-05 15:51:24 +00:00			`s := NewSolver([]pkg.Package{}, []pkg.Package{A, B, C, D, E})`
Handle case when no packages are installed in the system, and add test for it 2019-06-04 20:05:52 +00:00
Rename Solve to Install 2019-06-04 20:22:45 +00:00			`solution, err := s.Install([]pkg.Package{A})`
Handle case when no packages are installed in the system, and add test for it 2019-06-04 20:05:52 +00:00			`Expect(solution).To(ContainElement(PackageAssert{Package: A.IsFlagged(true), Value: true}))`
			`Expect(solution).To(ContainElement(PackageAssert{Package: B.IsFlagged(true), Value: true}))`
			`Expect(solution).To(ContainElement(PackageAssert{Package: D.IsFlagged(true), Value: true}))`
			`Expect(len(solution)).To(Equal(3))`
Build formulas recursively 2019-06-03 21:23:02 +00:00			`Expect(err).ToNot(HaveOccurred())`
			`})`

Add uninstall Uninstall can be done in different ways - the most accurate would be to try find a minimum subset of packages that gives conflicts and try to reduce them gradually. E.g. this could be done with other SAT algorithms. For now we keep things simple and we compute the uninstalls as an indirect of an installation from an empty profile. Also take care of corner cases where world has no clauses, and fixes a typo in building the world formula 2019-06-05 15:51:24 +00:00			`It("Uninstalls simple package correctly", func() {`
			`C := pkg.NewPackage("C", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`
			`D := pkg.NewPackage("D", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`
			`B := pkg.NewPackage("B", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`
			`A := pkg.NewPackage("A", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`

			`s := NewSolver([]pkg.Package{A, B, C, D}, []pkg.Package{A, B, C, D})`

			`solution, err := s.Uninstall(A)`
			`Expect(err).ToNot(HaveOccurred())`

			`Expect(solution).To(ContainElement(A.IsFlagged(false)))`

			`// Expect(solution).To(ContainElement(PackageAssert{Package: C.IsFlagged(true), Value: true}))`
			`Expect(len(solution)).To(Equal(1))`
			`})`

			`It("Uninstalls complex package correctly", func() {`
			`C := pkg.NewPackage("C", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`
			`D := pkg.NewPackage("D", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`
			`B := pkg.NewPackage("B", "", []pkg.DefaultPackage{D}, []pkg.DefaultPackage{})`
			`A := pkg.NewPackage("A", "", []pkg.DefaultPackage{B}, []pkg.DefaultPackage{})`
			`C.IsFlagged(true) // installed`

			`s := NewSolver([]pkg.Package{A, B, C, D}, []pkg.Package{A, B, C, D})`

			`solution, err := s.Uninstall(A)`
			`Expect(solution).To(ContainElement(A.IsFlagged(false)))`
			`Expect(solution).To(ContainElement(B.IsFlagged(false)))`
			`//Expect(solution).To(ContainElement(C.IsFlagged(true)))`
			`Expect(solution).To(ContainElement(D.IsFlagged(false)))`

			`// Expect(solution).To(ContainElement(PackageAssert{Package: C.IsFlagged(true), Value: true}))`
			`Expect(len(solution)).To(Equal(3))`
			`Expect(err).ToNot(HaveOccurred())`

			`})`

Draft 2018-09-21 21:29:50 +00:00			`})`

			`Context("Conflict set", func() {`

Implement basic install algorithm 2019-06-04 19:25:17 +00:00			`It("is unsolvable - as we something we ask to install conflict with system stuff", func() {`
			`C := pkg.NewPackage("C", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`
Make formula built less complex 2019-06-03 21:06:53 +00:00			`// D := pkg.NewPackage("D", "", []pkg.Package{}, []pkg.Package{})`
Implement basic install algorithm 2019-06-04 19:25:17 +00:00			`B := pkg.NewPackage("B", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{C})`
			`A := pkg.NewPackage("A", "", []pkg.DefaultPackage{B}, []pkg.DefaultPackage{})`
Draft 2018-09-21 21:29:50 +00:00
Rename Solve to Install 2019-06-04 20:22:45 +00:00			`s := NewSolver([]pkg.Package{C}, []pkg.Package{A, B, C})`
Draft 2018-09-21 21:29:50 +00:00
Rename Solve to Install 2019-06-04 20:22:45 +00:00			`solution, err := s.Install([]pkg.Package{A})`
Implement basic install algorithm 2019-06-04 19:25:17 +00:00			`Expect(len(solution)).To(Equal(0))`
			`Expect(err).To(HaveOccurred())`
Draft 2018-09-21 21:29:50 +00:00			`})`

			`})`

Normalize input data beforeahead 2019-06-05 16:40:33 +00:00			`Context("Complex data sets", func() {`
			`It("Solves them correctly", func() {`
			`C := pkg.NewPackage("C", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`
			`E := pkg.NewPackage("E", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`
			`F := pkg.NewPackage("F", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`
			`G := pkg.NewPackage("G", "", []pkg.DefaultPackage{}, []pkg.DefaultPackage{})`
			`H := pkg.NewPackage("H", "", []pkg.DefaultPackage{G}, []pkg.DefaultPackage{})`
			`D := pkg.NewPackage("D", "", []pkg.DefaultPackage{H}, []pkg.DefaultPackage{})`
			`B := pkg.NewPackage("B", "", []pkg.DefaultPackage{D}, []pkg.DefaultPackage{})`
			`A := pkg.NewPackage("A", "", []pkg.DefaultPackage{B}, []pkg.DefaultPackage{})`

			`s := NewSolver([]pkg.Package{C}, []pkg.Package{A, B, C, D, E, F, G})`

			`solution, err := s.Install([]pkg.Package{A})`
			`Expect(solution).To(ContainElement(PackageAssert{Package: A.IsFlagged(true), Value: true}))`
			`Expect(solution).To(ContainElement(PackageAssert{Package: B.IsFlagged(true), Value: true}))`
			`Expect(solution).To(ContainElement(PackageAssert{Package: D.IsFlagged(true), Value: true}))`
			`Expect(solution).To(ContainElement(PackageAssert{Package: C.IsFlagged(true), Value: true}))`
			`Expect(solution).To(ContainElement(PackageAssert{Package: H.IsFlagged(true), Value: true}))`
			`Expect(solution).To(ContainElement(PackageAssert{Package: G.IsFlagged(true), Value: true}))`

			`Expect(len(solution)).To(Equal(6))`
			`Expect(err).ToNot(HaveOccurred())`
			`})`
			`})`

Draft 2018-09-21 21:29:50 +00:00			`})`