slembcke/drift_physics.c

## drift_physics.c
#include <string.h>

#include "tracy/TracyC.h"

#include "drift_game.h"

typedef struct PhysicsContext PhysicsContext;

typedef struct {
	uint idx0, idx1;
} IndexPair;

typedef void CollideFunc(PhysicsContext* ctx, IndexPair pair);

typedef struct {
	IndexPair ipair;
	CollideFunc* check;
} CollisionPair;

typedef struct {
	IndexPair pair;

	// Collision properties.
	DriftVec2 n, r0, r1;

	// Contact properties.
	float friction, bounce, bias;
	// Generalized mass.
	float mass_n, mass_t;

	// Cached impulses.
	float jn, jt, jbn;
} Contact;

typedef struct {
	IndexPair pair;

	// Collision properties.
	DriftVec2 n, r0, r1;
	float bias;

	// Generalized mass.
	float mass_n;
	float jn;
} Constraint;

struct PhysicsContext {
	DriftTerrain* terra;

	float bias_coef;

	DriftVec2 *x; DriftVec2 *q; DriftVec2 *v; float *w;
	float *m_inv, *i_inv;
	float* r;
	DriftCollisionType* ctype;

	DriftVec2* x_bias; float* q_bias;
	DriftAABB2* bounds;
	DriftVec3* ground_plane;
	DRIFT_ARRAY(CollisionPair) cpair;
	DRIFT_ARRAY(Contact) contact;
	DRIFT_ARRAY(Constraint) constraint;
};

enum {
	CATEGORY_TERRAIN = 0x0001,
	CATEGORY_PLAYER = 0x0002,
	CATEGORY_ITEM = 0x0004,
	CATEGORY_DOG = 0x0008,
	CATEGORY_PLAYER_BULLET = 0x0010,
};

static struct {
	u32 categories, mask;
} COLLISION_TYPES[] = {
	[DRIFT_COLLISION_TYPE_TERRAIN] = {
		.categories = CATEGORY_TERRAIN,
		.mask = -1,
	},
	[DRIFT_COLLISION_TYPE_PLAYER] = {
		.categories = CATEGORY_PLAYER,
		.mask = CATEGORY_TERRAIN | CATEGORY_DOG | CATEGORY_ITEM,
	},
	[DRIFT_COLLISION_TYPE_ITEM] = {
		.categories = CATEGORY_ITEM,
		.mask = -1,
	},
	[DRIFT_COLLISION_TYPE_PLAYER_BULLET] = {
		.categories = CATEGORY_PLAYER_BULLET,
		.mask = CATEGORY_TERRAIN | CATEGORY_ITEM | CATEGORY_DOG,
	},
	[DRIFT_COLLISION_TYPE_DOG] = {
		.categories = CATEGORY_DOG,
		.mask = CATEGORY_TERRAIN | CATEGORY_PLAYER | CATEGORY_PLAYER_BULLET | CATEGORY_ITEM | CATEGORY_DOG,
	},
};

typedef bool DrifctCollisionCallback(DriftUpdate* update, PhysicsContext* phys, IndexPair pair);
static bool do_nothing(DriftUpdate* update, PhysicsContext* phys, IndexPair pair){return true;}

static bool fatal_player_contact(DriftUpdate* update, PhysicsContext* phys, IndexPair pair){
	DriftGameState* state = update->state;
	DriftHealthApplyDamage(update, state->bodies.entity[pair.idx0], 10);
	DriftHealthApplyDamage(update, state->bodies.entity[pair.idx1], INFINITY);
	return true;
}

struct {
	DriftCollisionType types[2];
	DrifctCollisionCallback* callback;
} COLLISION_CALLBACKS[] = {
	{{}, do_nothing},
	{{DRIFT_COLLISION_TYPE_PLAYER, DRIFT_COLLISION_TYPE_DOG}, fatal_player_contact},
	{},
};

static inline uintptr_t collision_hash(DriftCollisionType a, DriftCollisionType b){
	return (a ^ b) | ((a & b) << 16);
}


bool DriftCollisionFilter(DriftCollisionType a, DriftCollisionType b){
	// Both objects must agree to collide by having overlapping category/masks.
	return (1
		&& (COLLISION_TYPES[a].categories & COLLISION_TYPES[b].mask)
		&& (COLLISION_TYPES[b].categories & COLLISION_TYPES[a].mask)
	);
}

DriftVec2 linearized_rotation(DriftVec2 q, float w, float dt){
	return DriftVec2Normalize((DriftVec2){q.x - q.y*w*dt, q.y + q.x*w*dt});
}

void DriftPhysicsSyncTransforms(DriftGameState* state, float dt_diff){
	DriftAffine* transform_arr = state->transforms.matrix;
	DriftVec2* x_arr = state->bodies.position;
	DriftVec2* v_arr = state->bodies.velocity;
	DriftVec2* q_arr = state->bodies.rotation;
	float* w_arr = state->bodies.angular_velocity;

	uint transform_idx, body_idx;
	DriftJoin join = DriftJoinMake((DriftComponentJoin[]){
		{&body_idx, &state->bodies.c},
		{&transform_idx, &state->transforms.c},
		{},
	});
	while(DriftJoinNext(&join)){
		DriftVec2 p = DriftVec2FMA(x_arr[body_idx], v_arr[body_idx], dt_diff);
		DriftVec2 q = linearized_rotation(q_arr[body_idx], w_arr[body_idx], dt_diff);
		transform_arr[transform_idx] = (DriftAffine){q.x, q.y, -q.y, q.x, p.x, p.y};
	}
}

static inline float generalized_mass_inv(float mass_inv, float moment_inv, DriftVec2 r, DriftVec2 n){
	float rcn = DriftVec2Cross(r, n);
	return mass_inv + rcn*rcn*moment_inv;
}

static inline DriftVec2 relative_velocity_at(IndexPair pair, DriftVec2* v, float* w, DriftVec2 r0, DriftVec2 r1){
	DriftVec2 v0 = DriftVec2FMA(v[pair.idx0], DriftVec2Perp(r0), w[pair.idx0]);
	DriftVec2 v1 = DriftVec2FMA(v[pair.idx1], DriftVec2Perp(r1), w[pair.idx1]);
	return DriftVec2Sub(v0, v1);
}

static void PushContact(PhysicsContext* phys, IndexPair pair, float overlap, DriftVec2 n, DriftVec2 r0, DriftVec2 r1){
	DriftVec2 t = DriftVec2Perp(n);
	float mass_sum = phys->m_inv[pair.idx0] + phys->m_inv[pair.idx1];
	float i0 = phys->i_inv[pair.idx0], i1 = phys->i_inv[pair.idx1];
	float rcn0 = DriftVec2Cross(r0, n), rcn1 = DriftVec2Cross(r1, n);
	float rct0 = DriftVec2Cross(r0, t), rct1 = DriftVec2Cross(r1, t);

	float elasticity = 0.0f;
	float vn_rel = DriftVec2Dot(n, relative_velocity_at(pair, phys->v, phys->w, r0, r1));

	DRIFT_ARRAY_PUSH(phys->contact, ((Contact){
		.pair = pair, .n = n, .r0 = r0, .r1 = r1,
		.friction = 0.2f, .bounce = elasticity*vn_rel, .bias = -0.1f*fminf(0.0f, overlap + 1.0f), // TODO hard-coded friction and bias
		.mass_n = 1.0f/(mass_sum + rcn0*rcn0*i0 + rcn1*rcn1*i1),
		.mass_t = 1.0f/(mass_sum + rct0*rct0*i0 + rct1*rct1*i1),
	}));
}

static void CollideCircleCircle(PhysicsContext* phys, IndexPair pair){
	DriftVec2 c0 = phys->x[pair.idx0], c1 = phys->x[pair.idx1];
	DriftVec2 dx = DriftVec2Sub(c0, c1);
	float overlap = DriftVec2Length(dx) - (phys->r[pair.idx0] + phys->r[pair.idx1]);

	if(overlap < 0){
		DriftVec2 n = DriftVec2Normalize(dx);
		DriftVec2 r0 = DriftVec2Mul(n, -phys->r[pair.idx0]);
		DriftVec2 r1 = DriftVec2Mul(n,  phys->r[pair.idx1]);
		PushContact(phys, pair, overlap, n, r0, r1);
	}
}

static inline DriftVec2 ClosestPoint(DriftVec2 p, DriftSegment seg){
	DriftVec2 delta = DriftVec2Sub(seg.a, seg.b);
	float t = DriftClamp(DriftVec2Dot(delta, DriftVec2Sub(p, seg.b))/DriftVec2LengthSq(delta), 0, 1);
	return DriftVec2Add(seg.b, DriftVec2Mul(delta, t));
}

static void ApplyImpulse(PhysicsContext* phys, IndexPair pair, DriftVec2 r0, DriftVec2 r1, DriftVec2 j){
	phys->v[pair.idx0].x += j.x*phys->m_inv[pair.idx0];
	phys->v[pair.idx0].y += j.y*phys->m_inv[pair.idx0];
	phys->v[pair.idx1].x -= j.x*phys->m_inv[pair.idx1];
	phys->v[pair.idx1].y -= j.y*phys->m_inv[pair.idx1];
	phys->w[pair.idx0] += DriftVec2Cross(r0, j)*phys->i_inv[pair.idx0];
	phys->w[pair.idx1] -= DriftVec2Cross(r1, j)*phys->i_inv[pair.idx1];
}

static void ApplyBiasImpulse(PhysicsContext* phys, IndexPair pair, DriftVec2 r0, DriftVec2 r1, DriftVec2 j){
	phys->x_bias[pair.idx0].x += j.x*phys->m_inv[pair.idx0];
	phys->x_bias[pair.idx0].y += j.y*phys->m_inv[pair.idx0];
	phys->x_bias[pair.idx1].x -= j.x*phys->m_inv[pair.idx1];
	phys->x_bias[pair.idx1].y -= j.y*phys->m_inv[pair.idx1];
	phys->q_bias[pair.idx0] += DriftVec2Cross(r0, j)*phys->i_inv[pair.idx0];
	phys->q_bias[pair.idx1] -= DriftVec2Cross(r1, j)*phys->i_inv[pair.idx1];
}

void DriftPhysicsStep(DriftUpdate* update){
	DriftGameState* state = update->state;
	DriftMem* mem = update->mem;

	uint body_count = update->state->bodies.c.table.row_count;

	PhysicsContext phys = {
		.terra = state->terra,
		.bias_coef = 0.25f,

		.x = state->bodies.position, .q = state->bodies.rotation,
		.v = state->bodies.velocity, .w = state->bodies.angular_velocity,

		.m_inv = state->bodies.mass_inv, .i_inv = state->bodies.moment_inv,
		.r = state->bodies.radius,
		.ctype = state->bodies.collision_type,

		.x_bias = DriftAlloc(mem, body_count*sizeof(*phys.x_bias)),
		.q_bias = DriftAlloc(mem, body_count*sizeof(*phys.q_bias)),
		// TODO should come up with real hueristics for these eventually.
		.bounds = DriftAlloc(mem, body_count*sizeof(*phys.bounds)),
		.ground_plane = DriftAlloc(mem, body_count*sizeof(*phys.ground_plane)),
		.cpair = DRIFT_ARRAY_NEW(mem, 2*body_count, CollisionPair),
		.contact = DRIFT_ARRAY_NEW(mem, 2*body_count, Contact),
		.constraint = DRIFT_ARRAY_NEW(mem, 0, Constraint),
	};

	TracyCZoneN(ZONE_BOUNDS, "Bounds", true);
	DRIFT_COMPONENT_FOREACH(&state->bodies.c, i){
		DriftVec2 center = phys.x[i];
		float radius = phys.r[i];
		DriftVec2 displacement = DriftVec2Mul(phys.v[i], update->dt);

		phys.bounds[i] = (DriftAABB2){
			.l = center.x - radius + fmaxf(0.0f, -displacement.x),
			.b = center.y - radius + fmaxf(0.0f, -displacement.y),
			.r = center.x + radius + fmaxf(0.0f, +displacement.x),
			.t = center.y + radius + fmaxf(0.0f, +displacement.y),
		};
	}
	TracyCZoneEnd(ZONE_BOUNDS);

	TracyCZoneN(ZONE_TERRAIN, "Terrain", true);
	for(uint i = 1; i < body_count; i++){
		// TODO collision filtering.
		DriftTerrainSampleInfo info = DriftTerrainSampleFine(state->terra, phys.x[i]);
		phys.ground_plane[i] = (DriftVec3){{.x = info.grad.x, .y = info.grad.y, .z = DriftVec2Dot(info.grad, phys.x[i]) - info.dist}};
	}
	TracyCZoneEnd(ZONE_TERRAIN);

	TracyCZoneN(ZONE_BROADPHASE, "Broadphase", true);
	// TODO Collision broadphase.
	for(uint i = 1; i < body_count; i++){
		DriftCollisionType type0 = phys.ctype[i];
		DriftAABB2 bounds0 = phys.bounds[i];
		for(uint j = i + 1; j < body_count; j++){
			if(DriftCollisionFilter(type0, phys.ctype[j]) && DriftAABB2Overlap(bounds0, phys.bounds[j])){
				DRIFT_ARRAY_PUSH(phys.cpair, ((CollisionPair){.ipair = {i, j}, .check = CollideCircleCircle}));
			}
		}
	}
	TracyCZoneEnd(ZONE_BROADPHASE);

	uint pair_count = DriftArrayLength(phys.cpair);

	TracyCZoneN(ZONE_CALLBACKS, "Callbacks", true);
	static DriftMap COLLISION_MAP;
	// Initialize collision calback map if needed.
	if(COLLISION_MAP.table.buffer == NULL){
		DriftMapInit(&COLLISION_MAP, DriftSystemMem, "CollisionCallbacks", 0);
		for(uint i = 1; COLLISION_CALLBACKS[i].callback; i++){
			uintptr_t key = collision_hash(COLLISION_CALLBACKS[i].types[0], COLLISION_CALLBACKS[i].types[1]);
			DriftMapInsert(&COLLISION_MAP, key, i);
		}
	}

	// TODO should this happen in substep to access contacts?
	for(uint i = 0; i < pair_count; i++){
		IndexPair pair = phys.cpair[i].ipair;
		DriftCollisionType t0 = phys.ctype[pair.idx0], t1 = phys.ctype[pair.idx1];
		uint idx = DriftMapFind(&COLLISION_MAP, collision_hash(t0, t1));
		// Swap the order if the it doesn't match the definition.
		if(COLLISION_CALLBACKS[idx].types[0] != t0) pair = (IndexPair){pair.idx1, pair.idx0};
		// TODO Need to pass contact info or fixup swapped normals?
		COLLISION_CALLBACKS[idx].callback(update, &phys, pair);
	}
	TracyCZoneEnd(ZONE_CALLBACKS);

	uint substeps = 4, iterations = 2;
	float dt_diff = update->fixed_dt/substeps;
	float dt_inv = 1/dt_diff;

	for(uint substep = 0; substep < substeps; substep++){
		TracyCZoneN(ZONE_SUBSTEP, "Substep", true);
		TracyCZoneN(ZONE_INTPOS, "IntPos", true);
		// Integrate position.
		for(uint i = 0; i < body_count; i++){
			phys.x[i].x += phys.v[i].x*dt_diff;
			phys.x[i].y += phys.v[i].y*dt_diff;
			phys.q[i] = linearized_rotation(phys.q[i], phys.w[i], dt_diff);

			// TODO Should this validate bounding boxes?
			// Is it realistically possible to add to the cpairs here anyway?
		}
		TracyCZoneEnd(ZONE_INTPOS);

		// Generate contacts
		TracyCZoneN(ZONE_CONTACTS, "Contacts", true);
		DriftArrayHeader(phys.contact)->count = 0;
		for(uint i = 0; i < pair_count; i++) phys.cpair[i].check(&phys, phys.cpair[i].ipair);
		TracyCZoneEnd(ZONE_CONTACTS);

		TracyCZoneN(ZONE_TERRAIN, "Terrain", true);
		for(uint i = 1; i < body_count; i++){
			DriftVec3 plane = phys.ground_plane[i];
			DriftVec2 n = {plane.x, plane.y};
			float overlap = DriftVec2Dot(phys.x[i], n) - phys.r[i] - plane.z;
			if(overlap < 0) PushContact(&phys, (IndexPair){i, 0}, overlap, n, DriftVec2Mul(n, -phys.r[i]), DRIFT_VEC2_ZERO);
		}
		TracyCZoneEnd(ZONE_TERRAIN);

		uint contact_count = DriftArrayLength(phys.contact);
		uint constraint_count = DriftArrayLength(phys.constraint);

		// Integrate velocity here... in the future if needed I guess?
		{}

		// Apply cached impulses.
		TracyCZoneN(ZONE_PRESTEP, "PreStep", true);
		for(uint i = 0; i < contact_count; i++){
			Contact* con = phys.contact + i;
			ApplyImpulse(&phys, con->pair, con->r0, con->r1, DriftVec2Rotate(con->n, (DriftVec2){con->jn, con->jt}));
		}

		for(uint i = 0; i < constraint_count; i++){
			Constraint* con = phys.constraint + i;
			ApplyImpulse(&phys, con->pair, con->r0, con->r1, DriftVec2Mul(con->n, con->jn));
		}
		TracyCZoneEnd(ZONE_PRESTEP);

		TracyCZoneN(ZONE_SOLVE, "Solve", true);
		for(uint iter = 0; iter < iterations; iter++){
			// Reset bias velocities.
			memset(phys.x_bias, 0, body_count*sizeof(*phys.x_bias));
			memset(phys.q_bias, 0, body_count*sizeof(*phys.q_bias));

			// Solve contacts.
			for(uint i = 0; i < contact_count; i++){
				Contact* con = phys.contact + i;
				IndexPair pair = con->pair;

				DriftVec2 n = con->n, r0 = con->r0, r1 = con->r1;
				DriftVec2 v_rel = relative_velocity_at(pair, phys.v, phys.w, r0, r1);

				// Normal + restitution impulse.
				float vn_rel = DriftVec2Dot(v_rel, n);
				float jn0 = con->jn, jn = -(con->bounce + vn_rel)*con->mass_n;
				jn = con->jn = fmaxf(jn + jn0, 0.0f);

				// Friction impulse.
				float vt_rel = DriftVec2Dot(v_rel, DriftVec2Perp(n));
				float jt_max = con->friction*con->jn;
				float jt0 = con->jt, jt = -vt_rel*con->mass_t;
				jt = con->jt = DriftClamp(jt + jt0, -jt_max, jt_max);

				ApplyImpulse(&phys, con->pair, r0, r1, DriftVec2Rotate(n, (DriftVec2){jn - jn0, jt - jt0}));

				// Bias impulse.
				float vn_rel_bias = DriftVec2Dot(n, relative_velocity_at(pair, phys.x_bias, phys.q_bias, r0, r1));
				float jbn = (con->bias - vn_rel_bias)*con->mass_n;
				con->jbn = fmaxf(jbn + con->jbn, 0.0f);

				ApplyBiasImpulse(&phys, pair, r0, r1, DriftVec2Mul(n, con->jbn));
			}

			for(uint i = 0; i < constraint_count; i++){
				Constraint* con = phys.constraint + i;
				IndexPair pair = con->pair;

				DriftVec2 v_rel = relative_velocity_at(pair, phys.v, phys.w, con->r0, con->r1);

				float vn_rel = DriftVec2Dot(v_rel, con->n);
				float jn = (con->bias - vn_rel)*con->mass_n;
				float jn0 = con->jn;
				jn = con->jn = DriftClamp(jn + jn0, 0.0f, 500*dt_diff);
				ApplyImpulse(&phys, con->pair, con->r0, con->r1, DriftVec2Mul(con->n, jn - jn0));
			}
		}
		TracyCZoneEnd(ZONE_SOLVE);

		TracyCZoneN(ZONE_RESOLVE, "Resolve", true);
		for(uint i = 0; i < body_count; i++){
			phys.x[i].x += phys.x_bias[i].x;
			phys.x[i].y += phys.x_bias[i].y;
			phys.w[i] += phys.q_bias[i];
		}
		TracyCZoneEnd(ZONE_RESOLVE);
		TracyCZoneEnd(ZONE_SUBSTEP);
	}
}
	#include <string.h>

	#include "tracy/TracyC.h"

	#include "drift_game.h"

	typedef struct PhysicsContext PhysicsContext;

	typedef struct {
	uint idx0, idx1;
	} IndexPair;

	typedef void CollideFunc(PhysicsContext* ctx, IndexPair pair);

	typedef struct {
	IndexPair ipair;
	CollideFunc* check;
	} CollisionPair;

	typedef struct {
	IndexPair pair;

	// Collision properties.
	DriftVec2 n, r0, r1;

	// Contact properties.
	float friction, bounce, bias;
	// Generalized mass.
	float mass_n, mass_t;

	// Cached impulses.
	float jn, jt, jbn;
	} Contact;

	typedef struct {
	IndexPair pair;

	// Collision properties.
	DriftVec2 n, r0, r1;
	float bias;

	// Generalized mass.
	float mass_n;
	float jn;
	} Constraint;

	struct PhysicsContext {
	DriftTerrain* terra;

	float bias_coef;

	DriftVec2 x; DriftVec2 q; DriftVec2 v; float w;
	float m_inv, i_inv;
	float* r;
	DriftCollisionType* ctype;

	DriftVec2* x_bias; float* q_bias;
	DriftAABB2* bounds;
	DriftVec3* ground_plane;
	DRIFT_ARRAY(CollisionPair) cpair;
	DRIFT_ARRAY(Contact) contact;
	DRIFT_ARRAY(Constraint) constraint;
	};

	enum {
	CATEGORY_TERRAIN = 0x0001,
	CATEGORY_PLAYER = 0x0002,
	CATEGORY_ITEM = 0x0004,
	CATEGORY_DOG = 0x0008,
	CATEGORY_PLAYER_BULLET = 0x0010,
	};

	static struct {
	u32 categories, mask;
	} COLLISION_TYPES[] = {
	[DRIFT_COLLISION_TYPE_TERRAIN] = {
	.categories = CATEGORY_TERRAIN,
	.mask = -1,
	},
	[DRIFT_COLLISION_TYPE_PLAYER] = {
	.categories = CATEGORY_PLAYER,
	.mask = CATEGORY_TERRAIN \| CATEGORY_DOG \| CATEGORY_ITEM,
	},
	[DRIFT_COLLISION_TYPE_ITEM] = {
	.categories = CATEGORY_ITEM,
	.mask = -1,
	},
	[DRIFT_COLLISION_TYPE_PLAYER_BULLET] = {
	.categories = CATEGORY_PLAYER_BULLET,
	.mask = CATEGORY_TERRAIN \| CATEGORY_ITEM \| CATEGORY_DOG,
	},
	[DRIFT_COLLISION_TYPE_DOG] = {
	.categories = CATEGORY_DOG,
	.mask = CATEGORY_TERRAIN \| CATEGORY_PLAYER \| CATEGORY_PLAYER_BULLET \| CATEGORY_ITEM \| CATEGORY_DOG,
	},
	};

	typedef bool DrifctCollisionCallback(DriftUpdate* update, PhysicsContext* phys, IndexPair pair);
	static bool do_nothing(DriftUpdate* update, PhysicsContext* phys, IndexPair pair){return true;}

	static bool fatal_player_contact(DriftUpdate* update, PhysicsContext* phys, IndexPair pair){
	DriftGameState* state = update->state;
	DriftHealthApplyDamage(update, state->bodies.entity[pair.idx0], 10);
	DriftHealthApplyDamage(update, state->bodies.entity[pair.idx1], INFINITY);
	return true;
	}

	struct {
	DriftCollisionType types[2];
	DrifctCollisionCallback* callback;
	} COLLISION_CALLBACKS[] = {
	{{}, do_nothing},
	{{DRIFT_COLLISION_TYPE_PLAYER, DRIFT_COLLISION_TYPE_DOG}, fatal_player_contact},
	{},
	};

	static inline uintptr_t collision_hash(DriftCollisionType a, DriftCollisionType b){
	return (a ^ b) \| ((a & b) << 16);
	}


	bool DriftCollisionFilter(DriftCollisionType a, DriftCollisionType b){
	// Both objects must agree to collide by having overlapping category/masks.
	return (1
	&& (COLLISION_TYPES[a].categories & COLLISION_TYPES[b].mask)
	&& (COLLISION_TYPES[b].categories & COLLISION_TYPES[a].mask)
	);
	}

	DriftVec2 linearized_rotation(DriftVec2 q, float w, float dt){
	return DriftVec2Normalize((DriftVec2){q.x - q.ywdt, q.y + q.xwdt});
	}

	void DriftPhysicsSyncTransforms(DriftGameState* state, float dt_diff){
	DriftAffine* transform_arr = state->transforms.matrix;
	DriftVec2* x_arr = state->bodies.position;
	DriftVec2* v_arr = state->bodies.velocity;
	DriftVec2* q_arr = state->bodies.rotation;
	float* w_arr = state->bodies.angular_velocity;

	uint transform_idx, body_idx;
	DriftJoin join = DriftJoinMake((DriftComponentJoin[]){
	{&body_idx, &state->bodies.c},
	{&transform_idx, &state->transforms.c},
	{},
	});
	while(DriftJoinNext(&join)){
	DriftVec2 p = DriftVec2FMA(x_arr[body_idx], v_arr[body_idx], dt_diff);
	DriftVec2 q = linearized_rotation(q_arr[body_idx], w_arr[body_idx], dt_diff);
	transform_arr[transform_idx] = (DriftAffine){q.x, q.y, -q.y, q.x, p.x, p.y};
	}
	}

	static inline float generalized_mass_inv(float mass_inv, float moment_inv, DriftVec2 r, DriftVec2 n){
	float rcn = DriftVec2Cross(r, n);
	return mass_inv + rcnrcnmoment_inv;
	}

	static inline DriftVec2 relative_velocity_at(IndexPair pair, DriftVec2* v, float* w, DriftVec2 r0, DriftVec2 r1){
	DriftVec2 v0 = DriftVec2FMA(v[pair.idx0], DriftVec2Perp(r0), w[pair.idx0]);
	DriftVec2 v1 = DriftVec2FMA(v[pair.idx1], DriftVec2Perp(r1), w[pair.idx1]);
	return DriftVec2Sub(v0, v1);
	}

	static void PushContact(PhysicsContext* phys, IndexPair pair, float overlap, DriftVec2 n, DriftVec2 r0, DriftVec2 r1){
	DriftVec2 t = DriftVec2Perp(n);
	float mass_sum = phys->m_inv[pair.idx0] + phys->m_inv[pair.idx1];
	float i0 = phys->i_inv[pair.idx0], i1 = phys->i_inv[pair.idx1];
	float rcn0 = DriftVec2Cross(r0, n), rcn1 = DriftVec2Cross(r1, n);
	float rct0 = DriftVec2Cross(r0, t), rct1 = DriftVec2Cross(r1, t);

	float elasticity = 0.0f;
	float vn_rel = DriftVec2Dot(n, relative_velocity_at(pair, phys->v, phys->w, r0, r1));

	DRIFT_ARRAY_PUSH(phys->contact, ((Contact){
	.pair = pair, .n = n, .r0 = r0, .r1 = r1,
	.friction = 0.2f, .bounce = elasticityvn_rel, .bias = -0.1ffminf(0.0f, overlap + 1.0f), // TODO hard-coded friction and bias
	.mass_n = 1.0f/(mass_sum + rcn0rcn0i0 + rcn1rcn1i1),
	.mass_t = 1.0f/(mass_sum + rct0rct0i0 + rct1rct1i1),
	}));
	}

	static void CollideCircleCircle(PhysicsContext* phys, IndexPair pair){
	DriftVec2 c0 = phys->x[pair.idx0], c1 = phys->x[pair.idx1];
	DriftVec2 dx = DriftVec2Sub(c0, c1);
	float overlap = DriftVec2Length(dx) - (phys->r[pair.idx0] + phys->r[pair.idx1]);

	if(overlap < 0){
	DriftVec2 n = DriftVec2Normalize(dx);
	DriftVec2 r0 = DriftVec2Mul(n, -phys->r[pair.idx0]);
	DriftVec2 r1 = DriftVec2Mul(n, phys->r[pair.idx1]);
	PushContact(phys, pair, overlap, n, r0, r1);
	}
	}

	static inline DriftVec2 ClosestPoint(DriftVec2 p, DriftSegment seg){
	DriftVec2 delta = DriftVec2Sub(seg.a, seg.b);
	float t = DriftClamp(DriftVec2Dot(delta, DriftVec2Sub(p, seg.b))/DriftVec2LengthSq(delta), 0, 1);
	return DriftVec2Add(seg.b, DriftVec2Mul(delta, t));
	}

	static void ApplyImpulse(PhysicsContext* phys, IndexPair pair, DriftVec2 r0, DriftVec2 r1, DriftVec2 j){
	phys->v[pair.idx0].x += j.x*phys->m_inv[pair.idx0];
	phys->v[pair.idx0].y += j.y*phys->m_inv[pair.idx0];
	phys->v[pair.idx1].x -= j.x*phys->m_inv[pair.idx1];
	phys->v[pair.idx1].y -= j.y*phys->m_inv[pair.idx1];
	phys->w[pair.idx0] += DriftVec2Cross(r0, j)*phys->i_inv[pair.idx0];
	phys->w[pair.idx1] -= DriftVec2Cross(r1, j)*phys->i_inv[pair.idx1];
	}

	static void ApplyBiasImpulse(PhysicsContext* phys, IndexPair pair, DriftVec2 r0, DriftVec2 r1, DriftVec2 j){
	phys->x_bias[pair.idx0].x += j.x*phys->m_inv[pair.idx0];
	phys->x_bias[pair.idx0].y += j.y*phys->m_inv[pair.idx0];
	phys->x_bias[pair.idx1].x -= j.x*phys->m_inv[pair.idx1];
	phys->x_bias[pair.idx1].y -= j.y*phys->m_inv[pair.idx1];
	phys->q_bias[pair.idx0] += DriftVec2Cross(r0, j)*phys->i_inv[pair.idx0];
	phys->q_bias[pair.idx1] -= DriftVec2Cross(r1, j)*phys->i_inv[pair.idx1];
	}

	void DriftPhysicsStep(DriftUpdate* update){
	DriftGameState* state = update->state;
	DriftMem* mem = update->mem;

	uint body_count = update->state->bodies.c.table.row_count;

	PhysicsContext phys = {
	.terra = state->terra,
	.bias_coef = 0.25f,

	.x = state->bodies.position, .q = state->bodies.rotation,
	.v = state->bodies.velocity, .w = state->bodies.angular_velocity,

	.m_inv = state->bodies.mass_inv, .i_inv = state->bodies.moment_inv,
	.r = state->bodies.radius,
	.ctype = state->bodies.collision_type,

	.x_bias = DriftAlloc(mem, body_countsizeof(phys.x_bias)),
	.q_bias = DriftAlloc(mem, body_countsizeof(phys.q_bias)),
	// TODO should come up with real hueristics for these eventually.
	.bounds = DriftAlloc(mem, body_countsizeof(phys.bounds)),
	.ground_plane = DriftAlloc(mem, body_countsizeof(phys.ground_plane)),
	.cpair = DRIFT_ARRAY_NEW(mem, 2*body_count, CollisionPair),
	.contact = DRIFT_ARRAY_NEW(mem, 2*body_count, Contact),
	.constraint = DRIFT_ARRAY_NEW(mem, 0, Constraint),
	};

	TracyCZoneN(ZONE_BOUNDS, "Bounds", true);
	DRIFT_COMPONENT_FOREACH(&state->bodies.c, i){
	DriftVec2 center = phys.x[i];
	float radius = phys.r[i];
	DriftVec2 displacement = DriftVec2Mul(phys.v[i], update->dt);

	phys.bounds[i] = (DriftAABB2){
	.l = center.x - radius + fmaxf(0.0f, -displacement.x),
	.b = center.y - radius + fmaxf(0.0f, -displacement.y),
	.r = center.x + radius + fmaxf(0.0f, +displacement.x),
	.t = center.y + radius + fmaxf(0.0f, +displacement.y),
	};
	}
	TracyCZoneEnd(ZONE_BOUNDS);

	TracyCZoneN(ZONE_TERRAIN, "Terrain", true);
	for(uint i = 1; i < body_count; i++){
	// TODO collision filtering.
	DriftTerrainSampleInfo info = DriftTerrainSampleFine(state->terra, phys.x[i]);
	phys.ground_plane[i] = (DriftVec3){{.x = info.grad.x, .y = info.grad.y, .z = DriftVec2Dot(info.grad, phys.x[i]) - info.dist}};
	}
	TracyCZoneEnd(ZONE_TERRAIN);

	TracyCZoneN(ZONE_BROADPHASE, "Broadphase", true);
	// TODO Collision broadphase.
	for(uint i = 1; i < body_count; i++){
	DriftCollisionType type0 = phys.ctype[i];
	DriftAABB2 bounds0 = phys.bounds[i];
	for(uint j = i + 1; j < body_count; j++){
	if(DriftCollisionFilter(type0, phys.ctype[j]) && DriftAABB2Overlap(bounds0, phys.bounds[j])){
	DRIFT_ARRAY_PUSH(phys.cpair, ((CollisionPair){.ipair = {i, j}, .check = CollideCircleCircle}));
	}
	}
	}
	TracyCZoneEnd(ZONE_BROADPHASE);

	uint pair_count = DriftArrayLength(phys.cpair);

	TracyCZoneN(ZONE_CALLBACKS, "Callbacks", true);
	static DriftMap COLLISION_MAP;
	// Initialize collision calback map if needed.
	if(COLLISION_MAP.table.buffer == NULL){
	DriftMapInit(&COLLISION_MAP, DriftSystemMem, "CollisionCallbacks", 0);
	for(uint i = 1; COLLISION_CALLBACKS[i].callback; i++){
	uintptr_t key = collision_hash(COLLISION_CALLBACKS[i].types[0], COLLISION_CALLBACKS[i].types[1]);
	DriftMapInsert(&COLLISION_MAP, key, i);
	}
	}

	// TODO should this happen in substep to access contacts?
	for(uint i = 0; i < pair_count; i++){
	IndexPair pair = phys.cpair[i].ipair;
	DriftCollisionType t0 = phys.ctype[pair.idx0], t1 = phys.ctype[pair.idx1];
	uint idx = DriftMapFind(&COLLISION_MAP, collision_hash(t0, t1));
	// Swap the order if the it doesn't match the definition.
	if(COLLISION_CALLBACKS[idx].types[0] != t0) pair = (IndexPair){pair.idx1, pair.idx0};
	// TODO Need to pass contact info or fixup swapped normals?
	COLLISION_CALLBACKS[idx].callback(update, &phys, pair);
	}
	TracyCZoneEnd(ZONE_CALLBACKS);

	uint substeps = 4, iterations = 2;
	float dt_diff = update->fixed_dt/substeps;
	float dt_inv = 1/dt_diff;

	for(uint substep = 0; substep < substeps; substep++){
	TracyCZoneN(ZONE_SUBSTEP, "Substep", true);
	TracyCZoneN(ZONE_INTPOS, "IntPos", true);
	// Integrate position.
	for(uint i = 0; i < body_count; i++){
	phys.x[i].x += phys.v[i].x*dt_diff;
	phys.x[i].y += phys.v[i].y*dt_diff;
	phys.q[i] = linearized_rotation(phys.q[i], phys.w[i], dt_diff);

	// TODO Should this validate bounding boxes?
	// Is it realistically possible to add to the cpairs here anyway?
	}
	TracyCZoneEnd(ZONE_INTPOS);

	// Generate contacts
	TracyCZoneN(ZONE_CONTACTS, "Contacts", true);
	DriftArrayHeader(phys.contact)->count = 0;
	for(uint i = 0; i < pair_count; i++) phys.cpair[i].check(&phys, phys.cpair[i].ipair);
	TracyCZoneEnd(ZONE_CONTACTS);

	TracyCZoneN(ZONE_TERRAIN, "Terrain", true);
	for(uint i = 1; i < body_count; i++){
	DriftVec3 plane = phys.ground_plane[i];
	DriftVec2 n = {plane.x, plane.y};
	float overlap = DriftVec2Dot(phys.x[i], n) - phys.r[i] - plane.z;
	if(overlap < 0) PushContact(&phys, (IndexPair){i, 0}, overlap, n, DriftVec2Mul(n, -phys.r[i]), DRIFT_VEC2_ZERO);
	}
	TracyCZoneEnd(ZONE_TERRAIN);

	uint contact_count = DriftArrayLength(phys.contact);
	uint constraint_count = DriftArrayLength(phys.constraint);

	// Integrate velocity here... in the future if needed I guess?
	{}

	// Apply cached impulses.
	TracyCZoneN(ZONE_PRESTEP, "PreStep", true);
	for(uint i = 0; i < contact_count; i++){
	Contact* con = phys.contact + i;
	ApplyImpulse(&phys, con->pair, con->r0, con->r1, DriftVec2Rotate(con->n, (DriftVec2){con->jn, con->jt}));
	}

	for(uint i = 0; i < constraint_count; i++){
	Constraint* con = phys.constraint + i;
	ApplyImpulse(&phys, con->pair, con->r0, con->r1, DriftVec2Mul(con->n, con->jn));
	}
	TracyCZoneEnd(ZONE_PRESTEP);

	TracyCZoneN(ZONE_SOLVE, "Solve", true);
	for(uint iter = 0; iter < iterations; iter++){
	// Reset bias velocities.
	memset(phys.x_bias, 0, body_countsizeof(phys.x_bias));
	memset(phys.q_bias, 0, body_countsizeof(phys.q_bias));

	// Solve contacts.
	for(uint i = 0; i < contact_count; i++){
	Contact* con = phys.contact + i;
	IndexPair pair = con->pair;

	DriftVec2 n = con->n, r0 = con->r0, r1 = con->r1;
	DriftVec2 v_rel = relative_velocity_at(pair, phys.v, phys.w, r0, r1);

	// Normal + restitution impulse.
	float vn_rel = DriftVec2Dot(v_rel, n);
	float jn0 = con->jn, jn = -(con->bounce + vn_rel)*con->mass_n;
	jn = con->jn = fmaxf(jn + jn0, 0.0f);

	// Friction impulse.
	float vt_rel = DriftVec2Dot(v_rel, DriftVec2Perp(n));
	float jt_max = con->friction*con->jn;
	float jt0 = con->jt, jt = -vt_rel*con->mass_t;
	jt = con->jt = DriftClamp(jt + jt0, -jt_max, jt_max);

	ApplyImpulse(&phys, con->pair, r0, r1, DriftVec2Rotate(n, (DriftVec2){jn - jn0, jt - jt0}));

	// Bias impulse.
	float vn_rel_bias = DriftVec2Dot(n, relative_velocity_at(pair, phys.x_bias, phys.q_bias, r0, r1));
	float jbn = (con->bias - vn_rel_bias)*con->mass_n;
	con->jbn = fmaxf(jbn + con->jbn, 0.0f);

	ApplyBiasImpulse(&phys, pair, r0, r1, DriftVec2Mul(n, con->jbn));
	}

	for(uint i = 0; i < constraint_count; i++){
	Constraint* con = phys.constraint + i;
	IndexPair pair = con->pair;

	DriftVec2 v_rel = relative_velocity_at(pair, phys.v, phys.w, con->r0, con->r1);

	float vn_rel = DriftVec2Dot(v_rel, con->n);
	float jn = (con->bias - vn_rel)*con->mass_n;
	float jn0 = con->jn;
	jn = con->jn = DriftClamp(jn + jn0, 0.0f, 500*dt_diff);
	ApplyImpulse(&phys, con->pair, con->r0, con->r1, DriftVec2Mul(con->n, jn - jn0));
	}
	}
	TracyCZoneEnd(ZONE_SOLVE);

	TracyCZoneN(ZONE_RESOLVE, "Resolve", true);
	for(uint i = 0; i < body_count; i++){
	phys.x[i].x += phys.x_bias[i].x;
	phys.x[i].y += phys.x_bias[i].y;
	phys.w[i] += phys.q_bias[i];
	}
	TracyCZoneEnd(ZONE_RESOLVE);
	TracyCZoneEnd(ZONE_SUBSTEP);
	}
	}