tinygo/compileopts/config.go

// Package compileopts contains the configuration for a single to-be-built
// binary.
package compileopts

import (
	"fmt"
	"strings"

	"github.com/tinygo-org/tinygo/goenv"
)

// Config keeps all configuration affecting the build in a single struct.
type Config struct {
	Options        *Options
	Target         *TargetSpec
	GoMinorVersion int
	ClangHeaders   string // Clang built-in header include path
	TestConfig     TestConfig
}

// Triple returns the LLVM target triple, like armv6m-none-eabi.
func (c *Config) Triple() string {
	return c.Target.Triple
}

// CPU returns the LLVM CPU name, like atmega328p or arm7tdmi. It may return an
// empty string if the CPU name is not known.
func (c *Config) CPU() string {
	return c.Target.CPU
}

// Features returns a list of features this CPU supports. For example, for a
// RISC-V processor, that could be ["+a", "+c", "+m"]. For many targets, an
// empty list will be returned.
func (c *Config) Features() []string {
	return c.Target.Features
}

// GOOS returns the GOOS of the target. This might not always be the actual OS:
// for example, bare-metal targets will usually pretend to be linux to get the
// standard library to compile.
func (c *Config) GOOS() string {
	return c.Target.GOOS
}

// GOARCH returns the GOARCH of the target. This might not always be the actual
// archtecture: for example, the AVR target is not supported by the Go standard
// library so such targets will usually pretend to be linux/arm.
func (c *Config) GOARCH() string {
	return c.Target.GOARCH
}

// BuildTags returns the complete list of build tags used during this build.
func (c *Config) BuildTags() []string {
	tags := append(c.Target.BuildTags, []string{"tinygo", "gc." + c.GC(), "scheduler." + c.Scheduler()}...)
	for i := 1; i <= c.GoMinorVersion; i++ {
		tags = append(tags, fmt.Sprintf("go1.%d", i))
	}
	if extraTags := strings.Fields(c.Options.Tags); len(extraTags) != 0 {
		tags = append(tags, extraTags...)
	}
	return tags
}

// GC returns the garbage collection strategy in use on this platform. Valid
// values are "none", "leaking", and "conservative".
func (c *Config) GC() string {
	if c.Options.GC != "" {
		return c.Options.GC
	}
	if c.Target.GC != "" {
		return c.Target.GC
	}
	return "conservative"
}

// Scheduler returns the scheduler implementation. Valid values are "coroutines"
// and "tasks".
func (c *Config) Scheduler() string {
	if c.Options.Scheduler != "" {
		return c.Options.Scheduler
	}
	if c.Target.Scheduler != "" {
		return c.Target.Scheduler
	}
	// Fall back to coroutines, which are supported everywhere.
	return "coroutines"
}

// PanicStrategy returns the panic strategy selected for this target. Valid
// values are "print" (print the panic value, then exit) or "trap" (issue a trap
// instruction).
func (c *Config) PanicStrategy() string {
	return c.Options.PanicStrategy
}

// CFlags returns the flags to pass to the C compiler. This is necessary for CGo
// preprocessing.
func (c *Config) CFlags() []string {
	cflags := append([]string{}, c.Options.CFlags...)
	for _, flag := range c.Target.CFlags {
		cflags = append(cflags, strings.Replace(flag, "{root}", goenv.Get("TINYGOROOT"), -1))
	}
	return cflags
}

// DumpSSA returns whether to dump Go SSA while compiling (-dumpssa flag). Only
// enable this for debugging.
func (c *Config) DumpSSA() bool {
	return c.Options.DumpSSA
}

// VerifyIR returns whether to run extra checks on the IR. This is normally
// disabled but enabled during testing.
func (c *Config) VerifyIR() bool {
	return c.Options.VerifyIR
}

// Debug returns whether to add debug symbols to the IR, for debugging with GDB
// and similar.
func (c *Config) Debug() bool {
	return c.Options.Debug
}

type TestConfig struct {
	CompileTestBinary bool
	// TODO: Filter the test functions to run, include verbose flag, etc
}
compiler: move Config struct to compileopts 5 years ago			`// Package compileopts contains the configuration for a single to-be-built`
			`// binary.`
			`package compileopts`

all: refactor compile options Move most of the logic of determining which compiler configuration to use (such as GOOS/GOARCH, build tags, whether to include debug symbols, panic strategy, etc.) into the compileopts package. This makes it a single source of truth for anything related to compiler configuration. It has a few advantages: * The compile configuration is independent of the compiler package. This makes it possible to move optimization passes out of the compiler, as they don't rely on compiler.Config anymore. * There is only one place to look if an incorrect compile option is used. * The compileopts provides some resistance against unintentionally picking the wrong option, such as with c.selectGC() vs c.GC() in the compiler. * It is now a lot easier to change compile options, as most options are getters now. 5 years ago			`import (`
			`"fmt"`
			`"strings"`

			`"github.com/tinygo-org/tinygo/goenv"`
			`)`

compiler: move Config struct to compileopts 5 years ago			`// Config keeps all configuration affecting the build in a single struct.`
			`type Config struct {`
all: refactor compile options Move most of the logic of determining which compiler configuration to use (such as GOOS/GOARCH, build tags, whether to include debug symbols, panic strategy, etc.) into the compileopts package. This makes it a single source of truth for anything related to compiler configuration. It has a few advantages: * The compile configuration is independent of the compiler package. This makes it possible to move optimization passes out of the compiler, as they don't rely on compiler.Config anymore. * There is only one place to look if an incorrect compile option is used. * The compileopts provides some resistance against unintentionally picking the wrong option, such as with c.selectGC() vs c.GC() in the compiler. * It is now a lot easier to change compile options, as most options are getters now. 5 years ago			`Options *Options`
			`Target *TargetSpec`
			`GoMinorVersion int`
			`ClangHeaders string // Clang built-in header include path`
			`TestConfig TestConfig`
			`}`

			`// Triple returns the LLVM target triple, like armv6m-none-eabi.`
			`func (c *Config) Triple() string {`
			`return c.Target.Triple`
			`}`

			`// CPU returns the LLVM CPU name, like atmega328p or arm7tdmi. It may return an`
			`// empty string if the CPU name is not known.`
			`func (c *Config) CPU() string {`
			`return c.Target.CPU`
			`}`

			`// Features returns a list of features this CPU supports. For example, for a`
			`// RISC-V processor, that could be ["+a", "+c", "+m"]. For many targets, an`
			`// empty list will be returned.`
			`func (c *Config) Features() []string {`
			`return c.Target.Features`
			`}`

			`// GOOS returns the GOOS of the target. This might not always be the actual OS:`
			`// for example, bare-metal targets will usually pretend to be linux to get the`
			`// standard library to compile.`
			`func (c *Config) GOOS() string {`
			`return c.Target.GOOS`
			`}`

			`// GOARCH returns the GOARCH of the target. This might not always be the actual`
			`// archtecture: for example, the AVR target is not supported by the Go standard`
			`// library so such targets will usually pretend to be linux/arm.`
			`func (c *Config) GOARCH() string {`
			`return c.Target.GOARCH`
			`}`

			`// BuildTags returns the complete list of build tags used during this build.`
			`func (c *Config) BuildTags() []string {`
			`tags := append(c.Target.BuildTags, []string{"tinygo", "gc." + c.GC(), "scheduler." + c.Scheduler()}...)`
			`for i := 1; i <= c.GoMinorVersion; i++ {`
			`tags = append(tags, fmt.Sprintf("go1.%d", i))`
			`}`
			`if extraTags := strings.Fields(c.Options.Tags); len(extraTags) != 0 {`
			`tags = append(tags, extraTags...)`
			`}`
			`return tags`
			`}`

			`// GC returns the garbage collection strategy in use on this platform. Valid`
			`// values are "none", "leaking", and "conservative".`
			`func (c *Config) GC() string {`
			`if c.Options.GC != "" {`
			`return c.Options.GC`
			`}`
			`if c.Target.GC != "" {`
			`return c.Target.GC`
			`}`
			`return "conservative"`
			`}`

			`// Scheduler returns the scheduler implementation. Valid values are "coroutines"`
			`// and "tasks".`
			`func (c *Config) Scheduler() string {`
			`if c.Options.Scheduler != "" {`
			`return c.Options.Scheduler`
			`}`
			`if c.Target.Scheduler != "" {`
			`return c.Target.Scheduler`
			`}`
			`// Fall back to coroutines, which are supported everywhere.`
			`return "coroutines"`
			`}`

			`// PanicStrategy returns the panic strategy selected for this target. Valid`
			`// values are "print" (print the panic value, then exit) or "trap" (issue a trap`
			`// instruction).`
			`func (c *Config) PanicStrategy() string {`
			`return c.Options.PanicStrategy`
			`}`

			`// CFlags returns the flags to pass to the C compiler. This is necessary for CGo`
			`// preprocessing.`
			`func (c *Config) CFlags() []string {`
			`cflags := append([]string{}, c.Options.CFlags...)`
			`for _, flag := range c.Target.CFlags {`
			`cflags = append(cflags, strings.Replace(flag, "{root}", goenv.Get("TINYGOROOT"), -1))`
			`}`
			`return cflags`
			`}`

			`// DumpSSA returns whether to dump Go SSA while compiling (-dumpssa flag). Only`
			`// enable this for debugging.`
			`func (c *Config) DumpSSA() bool {`
			`return c.Options.DumpSSA`
			`}`

			`// VerifyIR returns whether to run extra checks on the IR. This is normally`
			`// disabled but enabled during testing.`
			`func (c *Config) VerifyIR() bool {`
			`return c.Options.VerifyIR`
			`}`

			`// Debug returns whether to add debug symbols to the IR, for debugging with GDB`
			`// and similar.`
			`func (c *Config) Debug() bool {`
			`return c.Options.Debug`
compiler: move Config struct to compileopts 5 years ago			`}`

			`type TestConfig struct {`
			`CompileTestBinary bool`
			`// TODO: Filter the test functions to run, include verbose flag, etc`
			`}`