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refactor: reorganize package structure and decouple framework packages (#338)

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* refactor: reorganize package structure and decouple framework packages

## Package Structure Reorganization
- Reorganized 55 packages into categorized subdirectories:
  - packages/framework/ - Generic framework (Laya/Cocos compatible)
  - packages/engine/ - ESEngine core modules
  - packages/rendering/ - Rendering modules (WASM dependent)
  - packages/physics/ - Physics modules
  - packages/streaming/ - World streaming
  - packages/network-ext/ - Network extensions
  - packages/editor/ - Editor framework and plugins
  - packages/rust/ - Rust WASM engine
  - packages/tools/ - Build tools and SDK

## Framework Package Decoupling
- Decoupled behavior-tree and blueprint packages from ESEngine dependencies
- Created abstracted interfaces (IBTAssetManager, IBehaviorTreeAssetContent)
- ESEngine-specific code moved to esengine/ subpath exports
- Framework packages now usable with Cocos/Laya without ESEngine

## CI Configuration
- Updated CI to only type-check and lint framework packages
- Added type-check:framework and lint:framework scripts

## Breaking Changes
- Package import paths changed due to directory reorganization
- ESEngine integrations now use subpath imports (e.g., '@esengine/behavior-tree/esengine')

* fix: update es-engine file path after directory reorganization

* docs: update README to focus on framework over engine

* ci: only build framework packages, remove Rust/WASM dependencies

* fix: remove esengine subpath from behavior-tree and blueprint builds

ESEngine integration code will only be available in full engine builds.
Framework packages are now purely engine-agnostic.

* fix: move network-protocols to framework, build both in CI

* fix: update workflow paths from packages/core to packages/framework/core

* fix: exclude esengine folder from type-check in behavior-tree and blueprint

* fix: update network tsconfig references to new paths

* fix: add test:ci:framework to only test framework packages in CI

* fix: only build core and math npm packages in CI

* fix: exclude test files from CodeQL and fix string escaping security issue
This commit is contained in:
YHH
2025-12-26 14:50:35 +08:00
committed by GitHub
parent a84ff902e4
commit 155411e743
1936 changed files with 4147 additions and 11578 deletions
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387
packages/physics/rapier2d/src/control/character_controller.ts Normal file
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import {RawKinematicCharacterController, RawCharacterCollision} from "../raw";
import {Rotation, Vector, VectorOps} from "../math";
import {
BroadPhase,
Collider,
ColliderSet,
InteractionGroups,
NarrowPhase,
Shape,
} from "../geometry";
import {QueryFilterFlags, World} from "../pipeline";
import {IntegrationParameters, RigidBody, RigidBodySet} from "../dynamics";
/**
* A collision between the character and an obstacle hit on its path.
*/
export class CharacterCollision {
/** The collider involved in the collision. Null if the collider no longer exists in the physics world. */
public collider: Collider | null;
/** The translation delta applied to the character before this collision took place. */
public translationDeltaApplied: Vector;
/** The translation delta the character would move after this collision if there is no other obstacles. */
public translationDeltaRemaining: Vector;
/** The time-of-impact between the character and the obstacles. */
public toi: number;
/** The world-space contact point on the collider when the collision happens. */
public witness1: Vector;
/** The local-space contact point on the character when the collision happens. */
public witness2: Vector;
/** The world-space outward contact normal on the collider when the collision happens. */
public normal1: Vector;
/** The local-space outward contact normal on the character when the collision happens. */
public normal2: Vector;
}
/**
* A character controller for controlling kinematic bodies and parentless colliders by hitting
* and sliding against obstacles.
*/
export class KinematicCharacterController {
private raw: RawKinematicCharacterController;
private rawCharacterCollision: RawCharacterCollision;
private params: IntegrationParameters;
private broadPhase: BroadPhase;
private narrowPhase: NarrowPhase;
private bodies: RigidBodySet;
private colliders: ColliderSet;
private _applyImpulsesToDynamicBodies: boolean;
private _characterMass: number | null;
constructor(
offset: number,
params: IntegrationParameters,
broadPhase: BroadPhase,
narrowPhase: NarrowPhase,
bodies: RigidBodySet,
colliders: ColliderSet,
) {
this.params = params;
this.bodies = bodies;
this.colliders = colliders;
this.broadPhase = broadPhase;
this.narrowPhase = narrowPhase;
this.raw = new RawKinematicCharacterController(offset);
this.rawCharacterCollision = new RawCharacterCollision();
this._applyImpulsesToDynamicBodies = false;
this._characterMass = null;
}
/** @internal */
public free() {
if (!!this.raw) {
this.raw.free();
this.rawCharacterCollision.free();
}
this.raw = undefined;
this.rawCharacterCollision = undefined;
}
/**
* The direction that goes "up". Used to determine where the floor is, and the floors angle.
*/
public up(): Vector {
return this.raw.up();
}
/**
* Sets the direction that goes "up". Used to determine where the floor is, and the floors angle.
*/
public setUp(vector: Vector) {
let rawVect = VectorOps.intoRaw(vector);
const result = this.raw.setUp(rawVect);
rawVect.free();
return result;
}
public applyImpulsesToDynamicBodies(): boolean {
return this._applyImpulsesToDynamicBodies;
}
public setApplyImpulsesToDynamicBodies(enabled: boolean) {
this._applyImpulsesToDynamicBodies = enabled;
}
/**
* Returns the custom value of the character mass, if it was set by `this.setCharacterMass`.
*/
public characterMass(): number | null {
return this._characterMass;
}
/**
* Set the mass of the character to be used for impulse resolution if `self.applyImpulsesToDynamicBodies`
* is set to `true`.
*
* If no character mass is set explicitly (or if it is set to `null`) it is automatically assumed to be equal
* to the mass of the rigid-body the character collider is attached to; or equal to 0 if the character collider
* isnt attached to any rigid-body.
*
* @param mass - The mass to set.
*/
public setCharacterMass(mass: number | null) {
this._characterMass = mass;
}
/**
* A small gap to preserve between the character and its surroundings.
*
* This value should not be too large to avoid visual artifacts, but shouldnt be too small
* (must not be zero) to improve numerical stability of the character controller.
*/
public offset(): number {
return this.raw.offset();
}
/**
* Sets a small gap to preserve between the character and its surroundings.
*
* This value should not be too large to avoid visual artifacts, but shouldnt be too small
* (must not be zero) to improve numerical stability of the character controller.
*/
public setOffset(value: number) {
this.raw.setOffset(value);
}
/// Increase this number if your character appears to get stuck when sliding against surfaces.
///
/// This is a small distance applied to the movement toward the contact normals of shapes hit
/// by the character controller. This helps shape-casting not getting stuck in an always-penetrating
/// state during the sliding calculation.
///
/// This value should remain fairly small since it can introduce artificial "bumps" when sliding
/// along a flat surface.
public normalNudgeFactor(): number {
return this.raw.normalNudgeFactor();
}
/// Increase this number if your character appears to get stuck when sliding against surfaces.
///
/// This is a small distance applied to the movement toward the contact normals of shapes hit
/// by the character controller. This helps shape-casting not getting stuck in an always-penetrating
/// state during the sliding calculation.
///
/// This value should remain fairly small since it can introduce artificial "bumps" when sliding
/// along a flat surface.
public setNormalNudgeFactor(value: number) {
this.raw.setNormalNudgeFactor(value);
}
/**
* Is sliding against obstacles enabled?
*/
public slideEnabled(): boolean {
return this.raw.slideEnabled();
}
/**
* Enable or disable sliding against obstacles.
*/
public setSlideEnabled(enabled: boolean) {
this.raw.setSlideEnabled(enabled);
}
/**
* The maximum step height a character can automatically step over.
*/
public autostepMaxHeight(): number | null {
return this.raw.autostepMaxHeight();
}
/**
* The minimum width of free space that must be available after stepping on a stair.
*/
public autostepMinWidth(): number | null {
return this.raw.autostepMinWidth();
}
/**
* Can the character automatically step over dynamic bodies too?
*/
public autostepIncludesDynamicBodies(): boolean | null {
return this.raw.autostepIncludesDynamicBodies();
}
/**
* Is automatically stepping over small objects enabled?
*/
public autostepEnabled(): boolean {
return this.raw.autostepEnabled();
}
/**
* Enabled automatically stepping over small objects.
*
* @param maxHeight - The maximum step height a character can automatically step over.
* @param minWidth - The minimum width of free space that must be available after stepping on a stair.
* @param includeDynamicBodies - Can the character automatically step over dynamic bodies too?
*/
public enableAutostep(
maxHeight: number,
minWidth: number,
includeDynamicBodies: boolean,
) {
this.raw.enableAutostep(maxHeight, minWidth, includeDynamicBodies);
}
/**
* Disable automatically stepping over small objects.
*/
public disableAutostep() {
return this.raw.disableAutostep();
}
/**
* The maximum angle (radians) between the floors normal and the `up` vector that the
* character is able to climb.
*/
public maxSlopeClimbAngle(): number {
return this.raw.maxSlopeClimbAngle();
}
/**
* Sets the maximum angle (radians) between the floors normal and the `up` vector that the
* character is able to climb.
*/
public setMaxSlopeClimbAngle(angle: number) {
this.raw.setMaxSlopeClimbAngle(angle);
}
/**
* The minimum angle (radians) between the floors normal and the `up` vector before the
* character starts to slide down automatically.
*/
public minSlopeSlideAngle(): number {
return this.raw.minSlopeSlideAngle();
}
/**
* Sets the minimum angle (radians) between the floors normal and the `up` vector before the
* character starts to slide down automatically.
*/
public setMinSlopeSlideAngle(angle: number) {
this.raw.setMinSlopeSlideAngle(angle);
}
/**
* If snap-to-ground is enabled, should the character be automatically snapped to the ground if
* the distance between the ground and its feet are smaller than the specified threshold?
*/
public snapToGroundDistance(): number | null {
return this.raw.snapToGroundDistance();
}
/**
* Enables automatically snapping the character to the ground if the distance between
* the ground and its feet are smaller than the specified threshold.
*/
public enableSnapToGround(distance: number) {
this.raw.enableSnapToGround(distance);
}
/**
* Disables automatically snapping the character to the ground.
*/
public disableSnapToGround() {
this.raw.disableSnapToGround();
}
/**
* Is automatically snapping the character to the ground enabled?
*/
public snapToGroundEnabled(): boolean {
return this.raw.snapToGroundEnabled();
}
/**
* Computes the movement the given collider is able to execute after hitting and sliding on obstacles.
*
* @param collider - The collider to move.
* @param desiredTranslationDelta - The desired collider movement.
* @param filterFlags - Flags for excluding whole subsets of colliders from the obstacles taken into account.
* @param filterGroups - Groups for excluding colliders with incompatible collision groups from the obstacles
* taken into account.
* @param filterPredicate - Any collider for which this closure returns `false` will be excluded from the
* obstacles taken into account.
*/
public computeColliderMovement(
collider: Collider,
desiredTranslationDelta: Vector,
filterFlags?: QueryFilterFlags,
filterGroups?: InteractionGroups,
filterPredicate?: (collider: Collider) => boolean,
) {
let rawTranslationDelta = VectorOps.intoRaw(desiredTranslationDelta);
this.raw.computeColliderMovement(
this.params.dt,
this.broadPhase.raw,
this.narrowPhase.raw,
this.bodies.raw,
this.colliders.raw,
collider.handle,
rawTranslationDelta,
this._applyImpulsesToDynamicBodies,
this._characterMass,
filterFlags,
filterGroups,
this.colliders.castClosure(filterPredicate),
);
rawTranslationDelta.free();
}
/**
* The movement computed by the last call to `this.computeColliderMovement`.
*/
public computedMovement(): Vector {
return VectorOps.fromRaw(this.raw.computedMovement());
}
/**
* The result of ground detection computed by the last call to `this.computeColliderMovement`.
*/
public computedGrounded(): boolean {
return this.raw.computedGrounded();
}
/**
* The number of collisions against obstacles detected along the path of the last call
* to `this.computeColliderMovement`.
*/
public numComputedCollisions(): number {
return this.raw.numComputedCollisions();
}
/**
* Returns the collision against one of the obstacles detected along the path of the last
* call to `this.computeColliderMovement`.
*
* @param i - The i-th collision will be returned.
* @param out - If this argument is set, it will be filled with the collision information.
*/
public computedCollision(
i: number,
out?: CharacterCollision,
): CharacterCollision | null {
if (!this.raw.computedCollision(i, this.rawCharacterCollision)) {
return null;
} else {
let c = this.rawCharacterCollision;
out = out ?? new CharacterCollision();
out.translationDeltaApplied = VectorOps.fromRaw(
c.translationDeltaApplied(),
);
out.translationDeltaRemaining = VectorOps.fromRaw(
c.translationDeltaRemaining(),
);
out.toi = c.toi();
out.witness1 = VectorOps.fromRaw(c.worldWitness1());
out.witness2 = VectorOps.fromRaw(c.worldWitness2());
out.normal1 = VectorOps.fromRaw(c.worldNormal1());
out.normal2 = VectorOps.fromRaw(c.worldNormal2());
out.collider = this.colliders.get(c.handle());
return out;
}
}
}