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245 changed files with 1132 additions and 30190 deletions

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@@ -1,17 +0,0 @@
.git
.venv
.venv-tpu
**/__pycache__
**/*.pyc
**/*.pyo
**/.pytest_cache
**/.mypy_cache
**/.ruff_cache
**/.ipynb_checkpoints
wandb
build
paper/build
paper/build-cais
node_modules
**/node_modules
*.egg-info

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@@ -1,24 +0,0 @@
# Copy this file to .env.sweep and fill in values.
# Required for wandb runs and sweep agent workers.
WANDB_API_KEY=
WANDB_ENTITY=
WANDB_PROJECT=capstone
# Required for private repo bootstrap workers.
GITHUB_TOKEN=
# Optional defaults for bootstrap mode.
# REPO_URL=https://github.com/org/repo.git
# BRANCH=main
# WORKDIR=$HOME/PHANTOM-agent
# SWEEP_ID=entity/project/id
# AGENT_COUNT=0
# AGENT_LOOP=1
# RETRY_SECONDS=20
# Optional local benchmark defaults.
# LOCAL_BENCHMARK_ARGS=--tiers static,surge,linear,qtable,ppo --alpha-values 0.0,0.3 --episodes 3 --total-timesteps 3000 --max-steps 40 --device cpu
# SIMPLE_BENCHMARK_ARGS=--tiers qtable,ppo,dqn,a2c --alpha-values 0.0,0.15,0.3,0.45,0.6 --episodes 8 --total-timesteps 8000 --max-steps 40 --device cpu
# PHANTOM_BENCHMARK_COMPARE_ROBUST=1
# BENCHMARK_AGENT_ARGS=--tiers static,surge,linear,qtable,ppo --alpha-values 0.0,0.3,0.6 --episodes 5

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@@ -12,92 +12,32 @@ on:
jobs:
build:
runs-on: ubuntu-latest
env:
OPENAI_API_KEY: ${{ secrets.OPENAI_API_KEY }}
R2_ACCESS_KEY_ID: ${{ secrets.R2_ACCESS_KEY_ID }}
R2_SECRET_ACCESS_KEY: ${{ secrets.R2_SECRET_ACCESS_KEY }}
R2_ENDPOINT: ${{ secrets.R2_ENDPOINT }}
R2_BUCKET_NAME: ${{ secrets.R2_BUCKET_NAME }}
steps:
- uses: actions/checkout@v4
- name: Prepare appendix code snapshot
run: bash paper/concat_code.sh
- name: Generate mirrors with Codex
if: ${{ env.OPENAI_API_KEY != '' }}
uses: openai/codex-action@v1
with:
openai-api-key: ${{ env.OPENAI_API_KEY }}
sandbox: workspace-write
safety-strategy: drop-sudo
working-directory: .
prompt: |
Read and follow the mirror instructions in `paper/src/mirrors/genpop/INSTRUCTIONS.md`.
Source chapters are in `paper/src/chapters/`:
- 01-intro.tex
- 02-literature-review.tex
- 03-methodology.tex
- 04-results.tex
- 05-discussion.tex
- 06-conclusion.tex
Update `paper/src/mirrors/genpop/*.tex` so they mirror the thesis for a general audience according to the instruction file.
Keep LaTeX valid and preserve citation commands and section order.
Then create or update `paper/src/main-mirror-genpop.tex` by using `paper/src/main.tex` as the base and replacing chapter inputs from `chapters/...` to `mirrors/genpop/...`.
Do not change any other project files.
- name: Compute LaTeX roots
id: roots
run: |
{
echo "root_files<<EOF"
echo "main.tex"
for file in paper/src/main-mirror-*.tex; do
if [ -f "$file" ]; then
basename "$file"
fi
done
echo "EOF"
} >> "$GITHUB_OUTPUT"
echo "Compiling roots:"
echo "main.tex"
for file in paper/src/main-mirror-*.tex; do
if [ -f "$file" ]; then
basename "$file"
fi
done
- name: Compile LaTeX documents
- name: Compile LaTeX document
uses: xu-cheng/latex-action@v3
with:
root_file: ${{ steps.roots.outputs.root_files }}
root_file: main.tex
working_directory: paper/src
args: -pdf -f -interaction=nonstopmode -file-line-error -r ../.latexmkrc -outdir=../build
- name: Upload PDF artifacts
args: -pdf -f -interaction=nonstopmode -file-line-error -outdir=../build
pre_compile: bash ../concat_code.sh
- name: Upload PDF
uses: actions/upload-artifact@v4
with:
name: thesis-pdf
path: |
paper/build/main.pdf
paper/build/main-mirror-*.pdf
path: paper/build/main.pdf
- name: Get current date
id: date
run: echo "date=$(date +'%Y-%m-%d')" >> $GITHUB_OUTPUT
- name: Upload to Cloudflare R2
if: ${{ env.R2_ACCESS_KEY_ID != '' && env.R2_SECRET_ACCESS_KEY != '' && env.R2_ENDPOINT != '' && env.R2_BUCKET_NAME != '' }}
env:
AWS_ACCESS_KEY_ID: ${{ env.R2_ACCESS_KEY_ID }}
AWS_SECRET_ACCESS_KEY: ${{ env.R2_SECRET_ACCESS_KEY }}
AWS_ENDPOINT_URL: ${{ env.R2_ENDPOINT }}
AWS_ACCESS_KEY_ID: ${{ secrets.R2_ACCESS_KEY_ID }}
AWS_SECRET_ACCESS_KEY: ${{ secrets.R2_SECRET_ACCESS_KEY }}
AWS_ENDPOINT_URL: ${{ secrets.R2_ENDPOINT }}
DATE: ${{ steps.date.outputs.date }}
BUCKET_NAME: ${{ env.R2_BUCKET_NAME }}
BUCKET_NAME: ${{ secrets.R2_BUCKET_NAME }}
run: |
pip install boto3
python3 << 'EOF'
@@ -131,49 +71,4 @@ jobs:
ExtraArgs={'ContentType': 'application/pdf'}
)
print(f"Uploaded thesis-latest.pdf")
# upload mirror versions (if generated)
build_dir = 'paper/build'
for filename in os.listdir(build_dir):
if not filename.startswith('main-mirror-') or not filename.endswith('.pdf'):
continue
mirror_name = filename[len('main-mirror-'):-4]
source_path = os.path.join(build_dir, filename)
dated_mirror = f"thesis-{mirror_name}-{date}.pdf"
latest_mirror = f"thesis-{mirror_name}-latest.pdf"
namespaced_dated = f"mirrors/{mirror_name}/thesis-{date}.pdf"
namespaced_latest = f"mirrors/{mirror_name}/thesis-latest.pdf"
s3.upload_file(
source_path,
bucket,
dated_mirror,
ExtraArgs={'ContentType': 'application/pdf'}
)
print(f"Uploaded {dated_mirror}")
s3.upload_file(
source_path,
bucket,
latest_mirror,
ExtraArgs={'ContentType': 'application/pdf'}
)
print(f"Uploaded {latest_mirror}")
s3.upload_file(
source_path,
bucket,
namespaced_dated,
ExtraArgs={'ContentType': 'application/pdf'}
)
print(f"Uploaded {namespaced_dated}")
s3.upload_file(
source_path,
bucket,
namespaced_latest,
ExtraArgs={'ContentType': 'application/pdf'}
)
print(f"Uploaded {namespaced_latest}")
EOF

88
.gitignore vendored
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@@ -1,92 +1,22 @@
# environment and secrets
**/.env
.env.*
!.env.*.example
**/.venv
**/.venv-ray
# python build/cache artifacts
**/__pycache__
phantom.egg-info/
*.egg-info/
# notebook artifacts
**/.ipynb_checkpoints/
**/.virtual_documents/
# editor/tool state
**/.pdf-view-restore
.nextstep
.ignore-gitlogue
.cloudflare
.nx/
node_modules/
dist/
# generated svg/graphics
**/session_*.svg
**/*graph.svg
**/auto/*.el
# misc generated
*.old
**/package-lock.json
**/*.parquet
**/_build/
# paper build artifacts
paper/src/bib/auto
paper/src/auto/*
paper/src/bib/auto
paper/template/*
paper/build-cais/
paper/defense/manim/media/
paper/defense/manim/.manim/
paper/src/main.pdf
paper/src/main-blx.bib
paper/src/svg-inkscape/
paper/variations/
paper/src/graphics/test_*.png
thesis-latest.pdf
# experiment run artifacts and logs
docs/goals/*.md
PHANTOM.wiki/
# Airflow logs - exclude DAG run logs
experiments/airflow/logs/*
experiments/airflow/logs/scheduler/
experiments/airflow/logs/dag_processor_manager/
experiments/collected_data/
experiments/agents/collected_data/
tests/e2e/test-results/
experiments/collected_data/*
paper/src/auto/*
lib/
docs/goals/*.md
PHANTOM.wiki/
tests/e2e/node_modules/**
# rl/sim run outputs
sim/rl/behavior_loader/*.dot
sim/rl/behavior_loader/*.png
sim/rl/behavior_loader/*.svg
sim/rl/behavior_loader/*.pdf
sim/rl/runs/
lab/case/thesis/runs*/
sim/case/thesis_simplified/runs*/
# model binaries
engine/models/*.zip
engine/studies/results/*
*.zip
# wandb local state
wandb/
# data directory (large datasets)
data/
# ktem local app data
ktem_app_data/
# generated visualization pdfs
*_mdp_viz.pdf
phantom_env_comparison.png
sim/phantom_env_comparison.png
# web clone
PHANTOM_web/*
**/auto/*.el
*.old

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@@ -1,35 +0,0 @@
# Virtual environments
.venv
.venv*
venv
venv*
**/.venv
**/venv
**/node_modules
node_modules/
# Python caches
__pycache__/
*.pyc
.ruff_cache/
.pytest_cache/
# Git
.git/
# Large data and logs
data/
experiments/
wandb/
dumplogs*
*.zip
*.pdf
*.log
*.dot
# Other large dirs
PHANTOM_web/
web/
docs/
paper/
.nx/

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@@ -1 +0,0 @@
CLAUDE.md

238
Makefile
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@@ -8,236 +8,88 @@ VENV := .venv
PYTHON := $(VENV)/bin/python
PIP := $(VENV)/bin/pip
PYTEST := $(VENV)/bin/pytest
NX := npx nx
SWEEP_ENV_FILE ?= .env.sweep
TPU_CONF ?= tpu_orchestration/configs/v4_spot_us.conf
WANDB_ENTITY ?=
WANDB_PROJECT ?= capstone
SWEEP_ID ?=
LOCAL_TRAIN_ARGS ?= --algo ppo --total-timesteps 50000
LOCAL_BENCHMARK_ARGS ?= --tiers static,surge,linear,qtable,ppo --alpha-values 0.0,0.3 --episodes 3 --total-timesteps 3000 --max-steps 40 --device cpu
SIMPLE_BENCHMARK_ARGS ?= --tiers qtable,ppo,dqn,a2c --alpha-values 0.0,0.15,0.3,0.45,0.6 --episodes 8 --total-timesteps 8000 --max-steps 40 --device cpu
BENCHMARK_AGENT_ARGS ?=
AGENT_COUNT ?= 0
WHOCLICKED_REPO ?= velocitatem/whoclickedit
WHOCLICKED_CSV ?= experiments/exports/whoclicked.csv
WHOCLICKED_CARD ?= experiments/exports/whoclicked_dataset_card.md
WHOCLICKED_CSV_PATH_IN_REPO ?= whoclicked.csv
WHOCLICKED_CARD_PATH_IN_REPO ?= README.md
WHOCLICKED_DATASET_MESSAGE ?= Update flattened whoclickedit dataset
WHOCLICKED_CARD_MESSAGE ?= Update dataset card for whoclickedit
REPO_URL ?=
BRANCH ?= main
WORKDIR ?= $(HOME)/PHANTOM-agent
AGENT_LOOP ?= 1
RETRY_SECONDS ?= 20
TRAIN_IMAGE_REF := us-central1-docker.pkg.dev/phantom-trc/phantom/phantom-trainer
SWEEP_ENV_LOAD = set -a; [ -f "$(SWEEP_ENV_FILE)" ] && . "$(SWEEP_ENV_FILE)" || true; set +a
.DEFAULT_GOAL := help
.PHONY: help
help:
@echo "pdf.build pdf.watch pdf.clean pdf.genpop pdf.genpop.watch pdf.arxiv | test.backend test.e2e test.all | web.dev | install | train | benchmark | benchmark.simple | benchmark.agent | train.agent | train.bootstrap | stats.lines | manim.render manim.render.all"
@echo "backend.server backend.provider backend.worker | platform.up platform.down platform.logs | docker.train.publish"
@echo "data.pull data.push data.whoclicked.publish | study.margin-erosion study.margin-erosion.quick study.margin-erosion.plot"
@echo "tpu.ray.bootstrap tpu.ray.deps tpu.ray.verify tpu.ray.teardown"
@echo ""
@echo "Build general public version:"
@echo " make pdf.genpop"
@echo ""
@echo "Local wandb run:"
@echo " make train LOCAL_TRAIN_ARGS='--algo ppo --total-timesteps 50000'"
@echo ""
@echo "Local benchmark run:"
@echo " make benchmark LOCAL_BENCHMARK_ARGS='--tiers static,surge,linear --alpha-values 0.0,0.3 --episodes 3 --no-wandb'"
@echo ""
@echo "Simple benchmark run (.env.sweep defaults, robust+no_robust compare by default):"
@echo " make benchmark.simple"
@echo ""
@echo "Local sweep agent from this repo:"
@echo " make train.agent SWEEP_ID=entity/project/id AGENT_COUNT=5"
@echo ""
@echo "Bootstrap private repo worker from anywhere:"
@echo " make train.bootstrap REPO_URL=https://github.com/org/repo.git BRANCH=main SWEEP_ID=entity/project/id"
@echo ""
@echo "Bootstrap Ray on TPU slice from config:"
@echo " make tpu.ray.bootstrap TPU_CONF=tpu_orchestration/configs/v4_spot_us.conf"
@echo ""
@echo "Publish whoclickedit dataset + card:"
@echo " make data.whoclicked.publish HF_TOKEN=... WHOCLICKED_REPO=velocitatem/whoclickedit"
@echo ""
@echo "Config source: $(SWEEP_ENV_FILE) (auto-loaded)"
@echo "pdf.build pdf.watch pdf.clean | test.backend test.e2e test.all | web.dev | install | stats.lines"
$(BUILDDIR):
mkdir -p paper/$(BUILDDIR)
.PHONY: pdf.build
pdf.build:
@$(NX) run paper:build
pdf.build: $(BUILDDIR)
@bash paper/concat_code.sh
@cd $(SRCDIR) && \
$(LATEXMK) -pdf -jobname=$(JOBNAME) -f \
-interaction=nonstopmode -file-line-error \
-r ../.latexmkrc \
-outdir=../$(BUILDDIR) $(TEX)
.PHONY: pdf.watch
pdf.watch:
@$(NX) run paper:watch
pdf.watch: $(BUILDDIR)
@cd $(SRCDIR) && \
$(LATEXMK) -pvc -pdf -jobname=$(JOBNAME) -f \
-interaction=nonstopmode -file-line-error \
-r ../.latexmkrc \
-outdir=../$(BUILDDIR) $(TEX)
.PHONY: pdf.clean
pdf.clean:
@$(NX) run paper:clean
.PHONY: pdf.genpop
pdf.genpop:
@bash scripts/nx_paper.sh build-genpop
.PHONY: pdf.genpop.watch
pdf.genpop.watch:
@bash scripts/nx_paper.sh watch-genpop
.PHONY: pdf.arxiv
pdf.arxiv:
@bash scripts/nx_paper.sh build-arxiv
@cd $(SRCDIR) && \
$(LATEXMK) -C -jobname=$(JOBNAME) -outdir=../$(BUILDDIR) || true
rm -rf paper/$(BUILDDIR)/*
.PHONY: test.backend
test.backend:
@$(NX) run research:test
test.backend: $(VENV)
$(PYTEST) -v
.PHONY: test.e2e
test.e2e:
@$(NX) run e2e:test
@cd tests/e2e && npm install
@cd tests/e2e && npx playwright install chromium
@timeout 30 bash -c 'until curl -sf http://localhost:5000/health > /dev/null 2>&1; do sleep 1; done' || (echo "Backend not ready" && exit 1)
@timeout 30 bash -c 'until curl -sf http://localhost:3000 > /dev/null 2>&1; do sleep 1; done' || (echo "Web app not ready" && exit 1)
@cd tests/e2e && npm test
.PHONY: test.all
test.all:
@$(NX) run-many -t test --projects=research,e2e --parallel=1
test.all: test.backend test.e2e
.PHONY: web.dev
web.dev:
@$(NX) run web:dev
@cd web && npm install && npm run dev
$(VENV):
python3 -m venv $(VENV)
$(PIP) install --upgrade pip
.PHONY: install
install:
@$(NX) run research:install
.PHONY: train
train:
@WANDB_ENTITY="$(WANDB_ENTITY)" WANDB_PROJECT="$(WANDB_PROJECT)" SWEEP_ENV_FILE="$(SWEEP_ENV_FILE)" LOCAL_TRAIN_ARGS="$(LOCAL_TRAIN_ARGS)" $(NX) run research:train
.PHONY: benchmark
benchmark:
@WANDB_ENTITY="$(WANDB_ENTITY)" WANDB_PROJECT="$(WANDB_PROJECT)" SWEEP_ENV_FILE="$(SWEEP_ENV_FILE)" LOCAL_BENCHMARK_ARGS="$(LOCAL_BENCHMARK_ARGS)" $(NX) run research:benchmark
.PHONY: benchmark.simple
benchmark.simple:
@WANDB_ENTITY="$(WANDB_ENTITY)" WANDB_PROJECT="$(WANDB_PROJECT)" SWEEP_ENV_FILE="$(SWEEP_ENV_FILE)" SIMPLE_BENCHMARK_ARGS="$(SIMPLE_BENCHMARK_ARGS)" PHANTOM_BENCHMARK_COMPARE_ROBUST="$(PHANTOM_BENCHMARK_COMPARE_ROBUST)" $(NX) run research:benchmark-simple
.PHONY: benchmark.agent
benchmark.agent:
@WANDB_ENTITY="$(WANDB_ENTITY)" WANDB_PROJECT="$(WANDB_PROJECT)" SWEEP_ENV_FILE="$(SWEEP_ENV_FILE)" SWEEP_ID="$(SWEEP_ID)" AGENT_COUNT="$(AGENT_COUNT)" BENCHMARK_AGENT_ARGS="$(BENCHMARK_AGENT_ARGS)" $(NX) run research:benchmark-agent
.PHONY: train.agent
train.agent:
@WANDB_ENTITY="$(WANDB_ENTITY)" WANDB_PROJECT="$(WANDB_PROJECT)" SWEEP_ENV_FILE="$(SWEEP_ENV_FILE)" SWEEP_ID="$(SWEEP_ID)" AGENT_COUNT="$(AGENT_COUNT)" $(NX) run research:train-agent
.PHONY: train.bootstrap
train.bootstrap:
@WANDB_ENTITY="$(WANDB_ENTITY)" WANDB_PROJECT="$(WANDB_PROJECT)" SWEEP_ENV_FILE="$(SWEEP_ENV_FILE)" REPO_URL="$(REPO_URL)" BRANCH="$(BRANCH)" WORKDIR="$(WORKDIR)" SWEEP_ID="$(SWEEP_ID)" AGENT_COUNT="$(AGENT_COUNT)" AGENT_LOOP="$(AGENT_LOOP)" RETRY_SECONDS="$(RETRY_SECONDS)" $(NX) run research:train-bootstrap
.PHONY: tpu.ray.bootstrap tpu.ray.deps tpu.ray.verify tpu.ray.teardown
tpu.ray.bootstrap:
@TPU_CONF="$(TPU_CONF)" SWEEP_ENV_FILE="$(SWEEP_ENV_FILE)" $(NX) run research:tpu-ray-bootstrap
tpu.ray.deps:
@TPU_CONF="$(TPU_CONF)" SWEEP_ENV_FILE="$(SWEEP_ENV_FILE)" $(NX) run research:tpu-ray-deps
tpu.ray.verify:
@TPU_CONF="$(TPU_CONF)" SWEEP_ENV_FILE="$(SWEEP_ENV_FILE)" $(NX) run research:tpu-ray-verify
tpu.ray.teardown:
@TPU_CONF="$(TPU_CONF)" SWEEP_ENV_FILE="$(SWEEP_ENV_FILE)" $(NX) run research:tpu-ray-teardown
.PHONY: data.pull data.push
data.pull:
python scripts/hf_data.py pull
data.push:
python scripts/hf_data.py push
.PHONY: data.whoclicked.publish
data.whoclicked.publish:
@HF_TOKEN="$(HF_TOKEN)" WHOCLICKED_REPO="$(WHOCLICKED_REPO)" WHOCLICKED_CSV="$(WHOCLICKED_CSV)" WHOCLICKED_CARD="$(WHOCLICKED_CARD)" WHOCLICKED_CSV_PATH_IN_REPO="$(WHOCLICKED_CSV_PATH_IN_REPO)" WHOCLICKED_CARD_PATH_IN_REPO="$(WHOCLICKED_CARD_PATH_IN_REPO)" WHOCLICKED_DATASET_MESSAGE="$(WHOCLICKED_DATASET_MESSAGE)" WHOCLICKED_CARD_MESSAGE="$(WHOCLICKED_CARD_MESSAGE)" $(NX) run research:whoclicked-publish
install: $(VENV)
$(PIP) install -r requirements.txt
.PHONY: stats.lines
stats.lines:
@$(NX) run research:stats
.PHONY: study.margin-erosion
study.margin-erosion:
python -m engine.studies.margin_erosion_alpha
.PHONY: study.margin-erosion.quick
study.margin-erosion.quick:
python -m engine.studies.margin_erosion_alpha --quick
@find . \( -path '*/node_modules' -o -path '*/.venv' -o -path '*/venv' \) -prune -o \
\( -name "*.ts" -o -name "*.py" \) -type f -print0 | xargs -0 cat | wc -l
.PHONY: wordcount
wordcount:
@$(NX) run paper:wordcount
@echo "Counting words in main text (excluding appendix)..."
@texcount -nosub -total -sum -1 \
$(SRCDIR)/chapters/01-intro.tex \
$(SRCDIR)/chapters/02-literature-review.tex \
$(SRCDIR)/chapters/03-methodology.tex \
$(SRCDIR)/chapters/04-results.tex \
$(SRCDIR)/chapters/05-discussion.tex \
$(SRCDIR)/chapters/06-conclusion.tex
.PHONY: docker.train.publish
docker.train.publish:
@TRAIN_IMAGE_REF="$(TRAIN_IMAGE_REF)" $(NX) run research:docker-train-publish
.PHONY: backend.server backend.provider backend.worker platform.up platform.down platform.logs
backend.server:
@$(NX) run backend-server:dev
backend.provider:
@$(NX) run pricing-provider:dev
backend.worker:
@$(NX) run backend-worker:dev
platform.up:
@$(NX) run platform:up
platform.down:
@$(NX) run platform:down
platform.logs:
@$(NX) run platform:logs
.PHONY: pdf clean watch run.webapp test count-lines all
pdf:
@$(NX) run paper:build
clean:
@$(NX) run paper:clean
watch:
@$(NX) run paper:watch
run.webapp:
@$(NX) run web:dev
test:
@$(NX) run research:test
count-lines:
@$(NX) run research:stats
all:
@$(NX) run paper:build
.PHONY: manim.render manim.render.all
manim.render:
@$(NX) run manim:render
manim.render.all:
@$(NX) run manim:render-all
pdf: pdf.build
clean: pdf.clean
watch: pdf.watch
run.webapp: web.dev
test: test.backend
count-lines: stats.lines
all: pdf.build

View File

@@ -2,7 +2,6 @@
### PHANTOM
[![Dataset on HF](https://huggingface.co/datasets/huggingface/badges/resolve/main/dataset-on-hf-sm.svg)](https://huggingface.co/datasets/velocitatem/whoclickedit)
[![Build PDF](https://github.com/velocitatem/PHANTOM/actions/workflows/latex.yml/badge.svg)](https://github.com/velocitatem/PHANTOM/actions/workflows/latex.yml)
[![Paper](https://img.shields.io/badge/Paper-PDF-red?logo=adobe-acrobat-reader)](https://pub-d5b94a3c29fd40c6b3881946e463fdb7.r2.dev/thesis-latest.pdf)
[![TPU Research Cloud](https://img.shields.io/badge/TPU%20Research%20Cloud-TRC%20supported-4285F4?logo=googlecloud&logoColor=white)](https://sites.research.google/trc/faq/)

View File

@@ -1,33 +0,0 @@
{
"$schema": "../node_modules/nx/schemas/project-schema.json",
"name": "platform",
"projectType": "application",
"sourceRoot": "backend",
"targets": {
"up": {
"executor": "nx:run-commands",
"options": {
"command": "docker compose up -d",
"cwd": "."
}
},
"down": {
"executor": "nx:run-commands",
"options": {
"command": "docker compose down",
"cwd": "."
}
},
"logs": {
"executor": "nx:run-commands",
"options": {
"command": "docker compose logs --tail=100 -f",
"cwd": "."
}
}
},
"tags": [
"scope:platform",
"type:infra"
]
}

View File

@@ -47,52 +47,53 @@ def health() -> dict:
@app.get("/api/{mode}/price/{productId}", response_model=PriceResponse)
def get_price(mode: Literal['hotel', 'airline'], productId: str, sessionId: Optional[str] = Query(None), experimentId: Optional[str] = Query(None)):
"""
THIS is the fast lookup service (mechanism).
Priority: session-keyed price > global optimal price > base price
"""
product = supabase.table(f'{mode}_products').select("metadata").eq('id', productId).execute().data[0]
if not product: raise HTTPException(404, f"Product {productId} not found")
metadata = product['metadata']
base_price = metadata.get('base_price', 100.0)
# PRIORITY 1: session-aware price (computed by Airflow worker)
if sessionId:
session_price = registry.get_session_price(sessionId, productId)
if session_price is not None:
return PriceResponse(
productId=productId,
price=session_price,
base_price=base_price,
markup=session_price/base_price,
elasticity=None,
model_version='session-aware'
)
# PRIORITY 2: global pre-computed prices (surge pricing)
# fetch pre-computed prices from registry
prices_df = registry.get_prices('latest')
if prices_df is not None:
product_price_row = prices_df[prices_df['productId'] == productId]
if not product_price_row.empty:
optimal_price = float(product_price_row['optimal_price'].iloc[0])
return PriceResponse(
productId=productId,
price=optimal_price,
base_price=base_price,
markup=optimal_price/base_price,
elasticity=None,
model_version='surge'
)
elasticity_df = registry.get_elasticity('latest')
if prices_df is None:
# fallback: no pre-computed prices available
return PriceResponse(
productId=productId,
price=base_price,
base_price=base_price,
markup=1.0,
elasticity=None
)
# lookup pre-computed price for this product
product_price_row = prices_df[prices_df['productId'] == productId]
if product_price_row.empty:
# product not in pre-computed prices, fallback to base
return PriceResponse(
productId=productId,
price=base_price,
base_price=base_price,
markup=1.0,
elasticity=None
)
optimal_price = float(product_price_row['optimal_price'].iloc[0]) # TODO: use optimal_price everywhere as aresult
# get elasticity if available
product_elasticity = None
if elasticity_df is not None:
product_elasticity_row = elasticity_df[elasticity_df['productId'] == productId]
if not product_elasticity_row.empty:
product_elasticity = float(product_elasticity_row['elasticity'].iloc[0])
# PRIORITY 3: fallback to base price
return PriceResponse(
productId=productId,
price=base_price,
price=optimal_price,
base_price=base_price,
markup=1.0,
elasticity=None,
model_version='base'
markup=optimal_price/base_price,
elasticity=product_elasticity
)
@app.get("/models")

View File

@@ -1,39 +0,0 @@
{
"$schema": "../../node_modules/nx/schemas/project-schema.json",
"name": "pricing-provider",
"projectType": "application",
"sourceRoot": "backend/provider",
"targets": {
"install": {
"executor": "nx:run-commands",
"options": {
"command": "bash -lc '[ -x ../../.venv/bin/python ] || python3 -m venv ../../.venv; ../../.venv/bin/python -m ensurepip --upgrade; ../../.venv/bin/python -m pip install -r requirements.txt'",
"cwd": "backend/provider"
}
},
"dev": {
"executor": "nx:run-commands",
"dependsOn": [
"install"
],
"options": {
"command": "../../.venv/bin/uvicorn app:app --host 0.0.0.0 --port ${PROVIDER_PORT:-5001} --reload",
"cwd": "backend/provider"
}
},
"start": {
"executor": "nx:run-commands",
"dependsOn": [
"install"
],
"options": {
"command": "../../.venv/bin/uvicorn app:app --host 0.0.0.0 --port ${PROVIDER_PORT:-5001}",
"cwd": "backend/provider"
}
}
},
"tags": [
"scope:backend",
"type:provider"
]
}

View File

@@ -198,16 +198,12 @@ def dump_logs(
auto_offset_reset='earliest',
enable_auto_commit=False,
value_deserializer=lambda x: json.loads(x.decode('utf-8')),
consumer_timeout_ms=30000,
fetch_max_wait_ms=10000,
max_poll_records=1000
consumer_timeout_ms=5000
)
events = []
for msg in consumer:
events.append(msg.value)
if last_n and len(events) >= last_n * 2:
break
consumer.close()

View File

@@ -1,39 +0,0 @@
{
"$schema": "../../node_modules/nx/schemas/project-schema.json",
"name": "backend-server",
"projectType": "application",
"sourceRoot": "backend/server",
"targets": {
"install": {
"executor": "nx:run-commands",
"options": {
"command": "bash -lc '[ -x ../../.venv/bin/python ] || python3 -m venv ../../.venv; ../../.venv/bin/python -m ensurepip --upgrade; ../../.venv/bin/python -m pip install -r requirements.txt'",
"cwd": "backend/server"
}
},
"dev": {
"executor": "nx:run-commands",
"dependsOn": [
"install"
],
"options": {
"command": "../../.venv/bin/uvicorn app:app --host 0.0.0.0 --port ${BACKEND_PORT:-5000} --reload",
"cwd": "backend/server"
}
},
"start": {
"executor": "nx:run-commands",
"dependsOn": [
"install"
],
"options": {
"command": "../../.venv/bin/uvicorn app:app --host 0.0.0.0 --port ${BACKEND_PORT:-5000}",
"cwd": "backend/server"
}
}
},
"tags": [
"scope:backend",
"type:api"
]
}

View File

@@ -1,6 +1,6 @@
fastapi>=0.135,<0.136
uvicorn[standard]>=0.41,<0.42
kafka-python>=2.3,<2.4
pydantic>=2.12,<3
python-dotenv>=1.0,<2
supabase>=2.28,<3
fastapi==0.104.1
uvicorn[standard]==0.24.0
kafka-python==2.0.2
pydantic==2.5.0
python-dotenv==1.0.0
supabase==2.9.1

View File

@@ -1,39 +0,0 @@
{
"$schema": "../../node_modules/nx/schemas/project-schema.json",
"name": "backend-worker",
"projectType": "application",
"sourceRoot": "backend/worker",
"targets": {
"install": {
"executor": "nx:run-commands",
"options": {
"command": "bash -lc '[ -x ../../.venv/bin/python ] || python3 -m venv ../../.venv; ../../.venv/bin/python -m ensurepip --upgrade; ../../.venv/bin/python -m pip install -r requirements.txt'",
"cwd": "backend/worker"
}
},
"dev": {
"executor": "nx:run-commands",
"dependsOn": [
"install"
],
"options": {
"command": "../../.venv/bin/celery -A main:app worker --loglevel=info",
"cwd": "backend/worker"
}
},
"start": {
"executor": "nx:run-commands",
"dependsOn": [
"install"
],
"options": {
"command": "../../.venv/bin/python main.py",
"cwd": "backend/worker"
}
}
},
"tags": [
"scope:backend",
"type:worker"
]
}

View File

@@ -1,3 +0,0 @@
celery>=5.3,<6
python-dotenv>=1.0.0
redis>=5.0.0

View File

@@ -1,23 +1,4 @@
services:
tpu-watchdogs:
build:
context: .
dockerfile: docker/TPUWatchdog.dockerfile
container_name: "PHANTOM-tpu-watchdogs"
restart: unless-stopped
user: "${UID:-1000}:${GID:-1000}"
environment:
- HF_TOKEN=${HF_TOKEN}
- WANDB_API_KEY=${WANDB_API_KEY}
- GITHUB_TOKEN=${GITHUB_TOKEN}
- GOOGLE_APPLICATION_CREDENTIALS=/secrets/gcp-sa.json
- GCP_ACCOUNT=${GCP_ACCOUNT:-}
- WATCHDOG_CONFIG_PATTERN=${WATCHDOG_CONFIG_PATTERN:-v[46]*.conf}
- CLOUDSDK_CONFIG=/.config/gcloud
volumes:
- ~/.config/gcloud:/.config/gcloud:rw
- ./secrets/gcp-sa.json:/secrets/gcp-sa.json:ro
tensorboard-rl:
image: tensorflow/tensorflow:latest
container_name: "PHANTOM-tensorboard-rl"
@@ -131,14 +112,11 @@ services:
depends_on:
- postgres
environment:
- AIRFLOW__CORE__EXECUTOR=LocalExecutor
- AIRFLOW__CORE__EXECUTOR=SequentialExecutor
- AIRFLOW__DATABASE__SQL_ALCHEMY_CONN=postgresql+psycopg2://airflow:airflow@postgres/airflow
- AIRFLOW__CORE__FERNET_KEY=${AIRFLOW_FERNET_KEY}
- AIRFLOW__CORE__LOAD_EXAMPLES=false
- AIRFLOW__CORE__ENABLE_XCOM_PICKLING=true
- AIRFLOW__CORE__PARALLELISM=16
- AIRFLOW__CORE__DAG_CONCURRENCY=8
- AIRFLOW__CORE__MAX_ACTIVE_RUNS_PER_DAG=4
- _AIRFLOW_DB_MIGRATE=true
- _AIRFLOW_WWW_USER_CREATE=true
- _AIRFLOW_WWW_USER_USERNAME=admin
@@ -158,20 +136,14 @@ services:
- airflow-init
- redis
environment:
- AIRFLOW__CORE__EXECUTOR=LocalExecutor
- AIRFLOW__CORE__EXECUTOR=SequentialExecutor
- AIRFLOW__DATABASE__SQL_ALCHEMY_CONN=postgresql+psycopg2://airflow:airflow@postgres/airflow
- AIRFLOW__CORE__FERNET_KEY=${AIRFLOW_FERNET_KEY}
- AIRFLOW__CORE__DAGS_ARE_PAUSED_AT_CREATION=true
- AIRFLOW__CORE__LOAD_EXAMPLES=false
- AIRFLOW__CORE__ENABLE_XCOM_PICKLING=true
- AIRFLOW__CORE__PARALLELISM=16
- AIRFLOW__CORE__DAG_CONCURRENCY=8
- AIRFLOW__CORE__MAX_ACTIVE_RUNS_PER_DAG=4
- AIRFLOW__SCHEDULER__MIN_FILE_PROCESS_INTERVAL=30
- AIRFLOW__SCHEDULER__DAG_DIR_LIST_INTERVAL=60
- AIRFLOW__WEBSERVER__EXPOSE_CONFIG=true
- AIRFLOW__WEBSERVER__SECRET_KEY=${AIRFLOW_SECRET_KEY}
- AIRFLOW__API__AUTH_BACKENDS=airflow.api.auth.backend.basic_auth
- KAFKA_HOST=kafka
- KAFKA_PORT=29092
- BACKEND_URL=http://backend:5000
@@ -201,20 +173,13 @@ services:
redis:
condition: service_started
environment:
- AIRFLOW__CORE__EXECUTOR=LocalExecutor
- AIRFLOW__CORE__EXECUTOR=SequentialExecutor
- AIRFLOW__DATABASE__SQL_ALCHEMY_CONN=postgresql+psycopg2://airflow:airflow@postgres/airflow
- AIRFLOW__CORE__FERNET_KEY=${AIRFLOW_FERNET_KEY}
- AIRFLOW__CORE__DAGS_ARE_PAUSED_AT_CREATION=true
- AIRFLOW__CORE__LOAD_EXAMPLES=false
- AIRFLOW__CORE__ENABLE_XCOM_PICKLING=true
- AIRFLOW__CORE__PARALLELISM=16
- AIRFLOW__CORE__DAG_CONCURRENCY=8
- AIRFLOW__CORE__MAX_ACTIVE_RUNS_PER_DAG=4
- AIRFLOW__SCHEDULER__MIN_FILE_PROCESS_INTERVAL=30
- AIRFLOW__SCHEDULER__DAG_DIR_LIST_INTERVAL=60
- AIRFLOW__SCHEDULER__PARSING_PROCESSES=2
- AIRFLOW__WEBSERVER__SECRET_KEY=${AIRFLOW_SECRET_KEY}
- AIRFLOW__API__AUTH_BACKENDS=airflow.api.auth.backend.basic_auth
- KAFKA_HOST=kafka
- KAFKA_PORT=29092
- BACKEND_URL=http://backend:5000

View File

@@ -1,112 +0,0 @@
FROM google/cloud-sdk:slim
# Install tmux to manage multiple watchdogs and jq for json parsing
RUN apt-get update && \
apt-get install -y tmux jq && \
rm -rf /var/lib/apt/lists/*
WORKDIR /app
# Copy the orchestration scripts and configs
COPY tpu_orchestration/ /app/tpu_orchestration/
# Make sure scripts are executable
RUN chmod +x /app/tpu_orchestration/watchdog.sh
RUN chmod +x /app/tpu_orchestration/tpu_startup.sh
# Create an entrypoint script that launches a watchdog for each config
COPY <<-'EOF' /app/entrypoint.sh
#!/bin/bash
set -e
# Make sure required variables are set
if [ -z "$HF_TOKEN" ]; then
echo "Error: HF_TOKEN environment variable is required."
exit 1
fi
if [ -z "$WANDB_API_KEY" ]; then
echo "Warning: WANDB_API_KEY environment variable is not set. Wandb logging may fail on TPUs."
fi
# Authenticate gcloud if credentials are provided
if [ -n "$GOOGLE_APPLICATION_CREDENTIALS" ] && [ -f "$GOOGLE_APPLICATION_CREDENTIALS" ]; then
CRED_TYPE=$(jq -r '.type' "$GOOGLE_APPLICATION_CREDENTIALS" 2>/dev/null || echo "unknown")
if [ "$CRED_TYPE" = "service_account" ]; then
echo "Authenticating gcloud using service account key..."
gcloud auth activate-service-account --key-file="$GOOGLE_APPLICATION_CREDENTIALS"
if [ -z "$PROJECT_ID" ]; then
PROJECT_ID=$(jq -r '.project_id // empty' "$GOOGLE_APPLICATION_CREDENTIALS")
fi
elif [ "$CRED_TYPE" = "authorized_user" ]; then
echo "Using authorized_user credentials via credential file override..."
export CLOUDSDK_AUTH_CREDENTIAL_FILE_OVERRIDE="$GOOGLE_APPLICATION_CREDENTIALS"
if gcloud auth print-access-token >/dev/null 2>&1; then
ACTIVE_ACCOUNT=$(gcloud config get-value account 2>/dev/null || true)
if [ -z "$ACTIVE_ACCOUNT" ] || [ "$ACTIVE_ACCOUNT" = "(unset)" ]; then
ACTIVE_ACCOUNT=$(jq -r '.account // empty' "$GOOGLE_APPLICATION_CREDENTIALS")
fi
if [ -n "$ACTIVE_ACCOUNT" ] && [ "$ACTIVE_ACCOUNT" != "(unset)" ]; then
echo "Using gcloud account: $ACTIVE_ACCOUNT"
else
echo "Using gcloud credential override from $GOOGLE_APPLICATION_CREDENTIALS"
fi
else
echo "Warning: credential file override token check failed. Falling back to mounted gcloud config."
unset CLOUDSDK_AUTH_CREDENTIAL_FILE_OVERRIDE
if [ -n "$GCP_ACCOUNT" ]; then
gcloud config set account "$GCP_ACCOUNT" >/dev/null 2>&1 || true
fi
ACTIVE_ACCOUNT=$(gcloud config get-value account 2>/dev/null || true)
if [ -z "$ACTIVE_ACCOUNT" ] || [ "$ACTIVE_ACCOUNT" = "(unset)" ]; then
echo "Error: no active gcloud account available. Run 'gcloud auth login' on host and mount ~/.config/gcloud, or use a service account key."
exit 1
fi
echo "Using gcloud account: $ACTIVE_ACCOUNT"
fi
else
echo "Warning: unsupported credential file type '$CRED_TYPE'. Falling back to mounted gcloud config."
fi
else
echo "Note: Assuming gcloud config is mounted from host."
fi
if [ -n "$PROJECT_ID" ]; then
gcloud config set project "$PROJECT_ID"
echo "Set project to $PROJECT_ID"
fi
# Run the watchdogs in the background using bash instead of tmux
# Tmux needs a TTY to attach properly which we might not have in docker
# Stagger startups by 15s to prevent simultaneous TPU creation quota hits
CONFIG_PATTERN=${WATCHDOG_CONFIG_PATTERN:-"*.conf"}
shopt -s nullglob
CONFIGS=(/app/tpu_orchestration/configs/$CONFIG_PATTERN)
if [ ${#CONFIGS[@]} -eq 0 ]; then
echo "Error: no watchdog configs matched pattern '$CONFIG_PATTERN'."
exit 1
fi
echo "Using watchdog config pattern: $CONFIG_PATTERN"
DELAY=0
for conf in "${CONFIGS[@]}"; do
echo "Starting watchdog for $(basename "$conf" .conf) (delay: ${DELAY}s)"
(sleep $DELAY && /app/tpu_orchestration/watchdog.sh "$conf") &
DELAY=$((DELAY + 15))
done
echo "All watchdogs queued with staggered startup."
# Keep the container running
wait
EOF
RUN chmod +x /app/entrypoint.sh
CMD ["/app/entrypoint.sh"]

View File

@@ -1,15 +0,0 @@
# syntax=docker/dockerfile:1.7
FROM pytorch/pytorch:2.5.1-cuda12.4-cudnn9-runtime AS gpu
WORKDIR /app
COPY docker/trainer.requirements.txt /tmp/requirements.txt
RUN pip install --no-cache-dir -r /tmp/requirements.txt
COPY --chmod=755 docker/trainer-agent-entrypoint.sh /usr/local/bin/trainer-agent-entrypoint
COPY engine /app/engine
ENV PYTHONPATH=/app
ENTRYPOINT ["/usr/local/bin/trainer-agent-entrypoint"]

View File

@@ -1,23 +0,0 @@
#!/usr/bin/env sh
set -eu
if [ -z "${SWEEP_ID:-}" ]; then
echo "SWEEP_ID is required"
exit 1
fi
set -- python -m engine.train --sweep-agent --sweep-id "${SWEEP_ID}"
if [ -n "${PHANTOM_DEFAULT_AGENT_ARGS:-}" ]; then
set -- "$@" ${PHANTOM_DEFAULT_AGENT_ARGS}
fi
if [ -n "${TRAIN_ARGS:-}" ]; then
set -- "$@" ${TRAIN_ARGS}
fi
if [ "${AGENT_COUNT:-0}" != "0" ]; then
set -- "$@" --count "${AGENT_COUNT}"
fi
exec "$@"

View File

@@ -1,7 +0,0 @@
numpy>=1.24.0
pandas>=2.0.0
scipy>=1.11.0
gymnasium>=0.29.0
stable-baselines3>=2.2.0
tensorboard>=2.15.0
wandb>=0.17.0

View File

@@ -17,8 +17,8 @@
<meta property="og:site_name" content="PHANTOM Research">
<meta property="og:title" content="PHANTOM: Pricing Heuristics Against Non-human Transaction Orchestration Mechanisms">
<meta property="og:description" content="Developing pricing heuristics to protect e-commerce platforms from systematic exploitation by LLM agents in dynamic pricing environments through behavioral signature detection.">
<meta property="og:url" content="https://velocitatem.github.io/PHANTOM/">
<meta property="og:image" content="https://raw.githubusercontent.com/velocitatem/PHANTOM/main/docs/static/images/carousel1.jpg">
<meta property="og:url" content="TODO">
<meta property="og:image" content="TODO">
<meta property="og:image:width" content="1200">
<meta property="og:image:height" content="630">
<meta property="og:image:alt" content="PHANTOM Research Preview">
@@ -30,12 +30,17 @@
<!-- Twitter -->
<meta name="twitter:card" content="summary_large_image">
<meta name="twitter:site" content="@velocitatem">
<meta name="twitter:creator" content="@velocitatem">
<meta name="twitter:title" content="PHANTOM: Pricing Heuristics Against Non-human Transaction Orchestration Mechanisms">
<meta name="twitter:description" content="A thesis project on defending dynamic pricing against LLM-driven reconnaissance and transaction orchestration.">
<meta name="twitter:image" content="https://raw.githubusercontent.com/velocitatem/PHANTOM/main/docs/static/images/carousel1.jpg">
<meta name="twitter:image:alt" content="PHANTOM research visual">
<!-- TODO: Replace with your lab/institution Twitter handle -->
<meta name="twitter:site" content="@YOUR_TWITTER_HANDLE">
<!-- TODO: Replace with first author's Twitter handle -->
<meta name="twitter:creator" content="@AUTHOR_TWITTER_HANDLE">
<!-- TODO: Same as paper title above -->
<meta name="twitter:title" content="PAPER_TITLE">
<!-- TODO: Same as description above -->
<meta name="twitter:description" content="BRIEF_DESCRIPTION_OF_YOUR_RESEARCH_CONTRIBUTION_AND_FINDINGS">
<!-- TODO: Same as social preview image above -->
<meta name="twitter:image" content="https://YOUR_DOMAIN.com/static/images/social_preview.png">
<meta name="twitter:image:alt" content="PAPER_TITLE - Research Preview">
<!-- Academic/Research Specific -->
<meta name="citation_title" content="Pricing Heuristics Against Non-human Transaction Orchestration Mechanisms">
@@ -98,42 +103,50 @@
{
"@context": "https://schema.org",
"@type": "ScholarlyArticle",
"headline": "PHANTOM: Pricing Heuristics Against Non-human Transaction Orchestration Mechanisms",
"description": "Research on preserving dynamic pricing integrity under LLM-mediated reconnaissance and purchasing behavior.",
"headline": "PAPER_TITLE",
"description": "BRIEF_DESCRIPTION_OF_YOUR_RESEARCH_CONTRIBUTION_AND_FINDINGS",
"author": [
{
"@type": "Person",
"name": "Daniel Rösel",
"name": "FIRST_AUTHOR_NAME",
"affiliation": {
"@type": "Organization",
"name": "IE University"
"name": "INSTITUTION_NAME"
}
},
{
"@type": "Person",
"name": "SECOND_AUTHOR_NAME",
"affiliation": {
"@type": "Organization",
"name": "INSTITUTION_NAME"
}
}
],
"datePublished": "2025-01-01",
"datePublished": "2024-01-01",
"publisher": {
"@type": "Organization",
"name": "IE University"
"name": "CONFERENCE_OR_JOURNAL_NAME"
},
"url": "https://velocitatem.github.io/PHANTOM/",
"image": "https://raw.githubusercontent.com/velocitatem/PHANTOM/main/docs/static/images/carousel1.jpg",
"keywords": ["dynamic pricing", "llm agents", "e-commerce", "distributionally robust optimization", "reinforcement learning"],
"abstract": "This thesis formalizes Cost of Information erosion under agentic reconnaissance, learns separable human and agent behavior kernels, and trains contamination-aware robust pricing policies.",
"citation": "Rösel, Daniel. PHANTOM: Pricing Heuristics Against Non-human Transaction Orchestration Mechanisms. IE University, 2025.",
"url": "https://YOUR_DOMAIN.com/YOUR_PROJECT_PAGE",
"image": "https://YOUR_DOMAIN.com/static/images/social_preview.png",
"keywords": ["KEYWORD1", "KEYWORD2", "KEYWORD3", "machine learning", "computer vision"],
"abstract": "FULL_ABSTRACT_TEXT_HERE",
"citation": "BIBTEX_CITATION_HERE",
"isAccessibleForFree": true,
"license": "https://creativecommons.org/licenses/by/4.0/",
"mainEntity": {
"@type": "WebPage",
"@id": "https://velocitatem.github.io/PHANTOM/"
"@id": "https://YOUR_DOMAIN.com/YOUR_PROJECT_PAGE"
},
"about": [
{
"@type": "Thing",
"name": "Dynamic Pricing"
"name": "RESEARCH_AREA_1"
},
{
"@type": "Thing",
"name": "Agent Behavior Modeling"
"name": "RESEARCH_AREA_2"
}
]
}
@@ -145,7 +158,8 @@
"@context": "https://schema.org",
"@type": "Organization",
"name": "IE University",
"url": "https://www.ie.edu"
"url": "https://www.ie.edu",
"logo": "TODO"
}
</script>
</head>
@@ -159,72 +173,45 @@
<!-- More Works Dropdown -->
<div class="more-works-container">
<button class="more-works-btn" onclick="toggleMoreWorks()" title="View project links and artifacts">
<button class="more-works-btn" onclick="toggleMoreWorks()" title="View More Works from Our Lab">
<i class="fas fa-flask"></i>
Project Links
More Works
<i class="fas fa-chevron-down dropdown-arrow"></i>
</button>
<div class="more-works-dropdown" id="moreWorksDropdown">
<div class="dropdown-header">
<h4>Project Links</h4>
<h4>More Works from Our Lab</h4>
<button class="close-btn" onclick="toggleMoreWorks()">
<i class="fas fa-times"></i>
</button>
</div>
<div class="works-list">
<a href="https://pub-d5b94a3c29fd40c6b3881946e463fdb7.r2.dev/thesis-latest.pdf" class="work-item" target="_blank">
<!-- TODO: Replace with your lab's related works -->
<a href="https://arxiv.org/abs/PAPER_ID_1" class="work-item" target="_blank">
<div class="work-info">
<h5>Thesis PDF</h5>
<p>Latest public build of the full thesis document.</p>
<span class="work-venue">IE University, 2025</span>
<!-- TODO: Replace with actual paper title -->
<h5>Paper Title 1</h5>
<!-- TODO: Replace with brief description -->
<p>Brief description of the work and its main contribution.</p>
<!-- TODO: Replace with venue and year -->
<span class="work-venue">Conference/Journal 2024</span>
</div>
<i class="fas fa-external-link-alt"></i>
</a>
<a href="https://github.com/velocitatem/PHANTOM" class="work-item" target="_blank">
<!-- TODO: Add more related works or remove extra items -->
<a href="https://arxiv.org/abs/PAPER_ID_2" class="work-item" target="_blank">
<div class="work-info">
<h5>PHANTOM Repository</h5>
<p>Monorepo with paper source, platform code, and experiments.</p>
<span class="work-venue">Open Source</span>
<h5>Paper Title 2</h5>
<p>Brief description of the work and its main contribution.</p>
<span class="work-venue">Conference/Journal 2023</span>
</div>
<i class="fas fa-external-link-alt"></i>
</a>
<a href="https://github.com/velocitatem/p4p" class="work-item" target="_blank">
<a href="https://arxiv.org/abs/PAPER_ID_3" class="work-item" target="_blank">
<div class="work-info">
<h5>P4P Interaction Layer</h5>
<p>Reusable storefront and logging layer released for replication.</p>
<span class="work-venue">Public Artifact</span>
</div>
<i class="fas fa-external-link-alt"></i>
</a>
<a href="https://phantom-hotel.vercel.app" class="work-item" target="_blank">
<div class="work-info">
<h5>Hotel Mode Demo</h5>
<p>Public deployment of the hotel-style experiment interface.</p>
<span class="work-venue">Live Demo</span>
</div>
<i class="fas fa-external-link-alt"></i>
</a>
<a href="https://phantom-airline.vercel.app" class="work-item" target="_blank">
<div class="work-info">
<h5>Airline Mode Demo</h5>
<p>Public deployment of the airline-style experiment interface.</p>
<span class="work-venue">Live Demo</span>
</div>
<i class="fas fa-external-link-alt"></i>
</a>
<a href="https://blog.alves.world/series/phantom" class="work-item" target="_blank">
<div class="work-info">
<h5>Blog Series</h5>
<p>Behind-the-scenes posts covering thesis process, tooling, and insights.</p>
<span class="work-venue">To Boldly Code</span>
</div>
<i class="fas fa-external-link-alt"></i>
</a>
<a href="goals/README.md" class="work-item" target="_blank">
<div class="work-info">
<h5>Goal Library</h5>
<p>Task definitions used to assign actor objectives in experiments.</p>
<span class="work-venue">Experiment Design</span>
<h5>Paper Title 3</h5>
<p>Brief description of the work and its main contribution.</p>
<span class="work-venue">Conference/Journal 2023</span>
</div>
<i class="fas fa-external-link-alt"></i>
</a>
@@ -252,16 +239,6 @@
<div class="column has-text-centered">
<div class="publication-links">
<span class="link-block">
<a href="https://blog.alves.world/series/phantom" target="_blank"
class="external-link button is-normal is-rounded is-dark">
<span class="icon">
<i class="fas fa-blog"></i>
</span>
<span>Blog Series</span>
</a>
</span>
<span class="link-block">
<a href="https://pub-d5b94a3c29fd40c6b3881946e463fdb7.r2.dev/thesis-latest.pdf" target="_blank"
class="external-link button is-normal is-rounded is-dark">
<span class="icon">
@@ -271,13 +248,14 @@
</a>
</span>
<!-- TODO: Add your supplementary material PDF or remove this section -->
<span class="link-block">
<a href="https://huggingface.co/datasets/velocitatem/whoclickedit" target="_blank"
<a href="static/pdfs/supplementary_material.pdf" target="_blank"
class="external-link button is-normal is-rounded is-dark">
<span class="icon">
<i class="fas fa-database"></i>
<i class="fas fa-file-pdf"></i>
</span>
<span>Dataset</span>
<span>Supplementary</span>
</a>
</span>
@@ -291,44 +269,43 @@
</a>
</span>
<!-- TODO: Update with your arXiv paper ID -->
<span class="link-block">
<a href="https://phantom-hotel.vercel.app" target="_blank"
<a href="https://arxiv.org/abs/<ARXIV PAPER ID>" target="_blank"
class="external-link button is-normal is-rounded is-dark">
<span class="icon">
<i class="fas fa-globe"></i>
<i class="ai ai-arxiv"></i>
</span>
<span>Hotel Demo</span>
<span>arXiv</span>
</a>
</span>
<span class="link-block">
<a href="https://phantom-airline.vercel.app" target="_blank"
class="external-link button is-normal is-rounded is-dark">
<span class="icon">
<i class="fas fa-plane"></i>
</span>
<span>Airline Demo</span>
</a>
</span>
</div>
</div>
</div>
</div>
</div>
</section>
<section class="hero teaser">
<div class="container is-max-desktop">
<div class="hero-body">
<div class="publication-banner">
<img src="static/images/banner.svg" alt="PHANTOM teaser diagram connecting vulnerability, behavioral signal, and robust control" width="1920" height="1080" decoding="async" style="display:block; width:100%; height:auto;" onerror="this.onerror=null;this.src='static/images/carousel2.jpg';"/>
</div>
</div>
</div>
</section>
<!-- Teaser video-->
<section class="hero teaser">
<div class="container is-max-desktop">
<div class="hero-body">
<!-- TODO: Replace with your teaser video -->
<video poster="" id="tree" autoplay controls muted loop height="100%" preload="metadata">
<!-- TODO: Add your video file path here -->
<source src="static/videos/banner_video.mp4" type="video/mp4">
</video>
<!-- TODO: Replace with your video description -->
<h2 class="subtitle has-text-centered">
Aliquam vitae elit ullamcorper tellus egestas pellentesque. Ut lacus tellus, maximus vel lectus at, placerat pretium mi. Maecenas dignissim tincidunt vestibulum. Sed consequat hendrerit nisl ut maximus.
</h2>
</div>
</div>
</section>
<!-- End teaser video -->
<!-- Paper abstract -->
<section class="section hero is-light">
<div class="container is-max-desktop">
@@ -337,10 +314,10 @@
<h2 class="title is-3">Abstract</h2>
<div class="content has-text-justified">
<p>
When you shop online, prices often change based on how much interest you show — the more you browse, the more the site learns about your intent and may raise prices accordingly. This works because stores assume that a curious, engaged shopper is more likely to buy. But AI assistants are now doing the shopping research on behalf of users: they browse in one session to gather price information and then let the user purchase in a fresh session at the lower, unadjusted price. The store never sees the connection between the two, so it never gets to factor in that genuine intent — and loses the revenue it would have earned.
This research establishes the following contributions: definition and formalization of non-human transactors in e-commerce platforms, development of a testing-ground for capturing the behavioral essence of these transactors across a large variety of digital systems, construction of a discriminative model to prove separability as a strong learner for downstream mitigation of contamination by non-human entities, translation of such learned separability into existing dynamic pricing machine learning loops, and establishment of a high-level KPI-affecting causal effect and cost-saving framework for the future of internet commerce in the presence of such non-human learners.
</p>
<p>
PHANTOM studies this problem and builds defenses against it. We created a realistic fake store (in hotel and airline modes) where both real people and AI agents were given shopping tasks, and we recorded every click, scroll, and page visit. By comparing how humans and AI agents move through a site, we found clear patterns that tell them apart. We then used those patterns to build a smarter pricing system that can recognize when it is likely talking to an AI scout and adjust its strategy accordingly — protecting the store's margins without making things worse for genuine shoppers.
This work develops behavioral signature models using recommendation system techniques to profile session-level interaction, temporal engagement, and cross-session correlation. The AI Agent market is forecasted to grow from around USD 5-8 billion in 2025 to USD 42-52 billion by 2030, raising the question of how these systems should be designed for future robustness and how to maintain a competitive edge in the analytical components of e-commerce platforms.
</p>
</div>
</div>
@@ -349,90 +326,97 @@
</section>
<!-- End paper abstract -->
<section class="section">
<div class="container is-max-desktop">
<div class="content has-text-justified">
<h2 class="title is-3 has-text-centered">Project Scope</h2>
<p>
The current thesis revision extends both theory and implementation. The main research question is how a pricing system can preserve margin integrity when browsing and purchasing are increasingly orchestrated by AI agents.
</p>
<ul>
<li>Formal contribution: a Cost of Information erosion theorem showing why price-query saturation can collapse dynamic pricing power.</li>
<li>System contribution: a hybrid online/offline stack (Next.js storefront, pricing provider, Kafka event streams, Airflow ETL, Redis serving layer).</li>
<li>Modeling contribution: class-specific transition kernels for human and agent behavior, with KL-divergence based separability scores.</li>
<li>Control contribution: a contamination-aware DR-RL pricing policy trained under distributional uncertainty using Wasserstein-style robustness.</li>
</ul>
<p>
Controlled trials currently include balanced human and agent sessions with goal-driven tasks across hotel and airline interfaces. Early separability results are strong (Mann-Whitney U=2.0, p=0.0006), while robust pricing gains remain regime-dependent and are being calibrated in larger sweeps.
</p>
</div>
</div>
</section>
<!-- Image carousel -->
<!--
<section class="hero is-small">
<div class="hero-body">
<div class="container">
<div id="results-carousel" class="carousel results-carousel">
<div class="item">
<!-- TODO: Replace with your research result images -->
<img src="static/images/carousel1.jpg" alt="First research result visualization" loading="lazy"/>
<!-- TODO: Replace with description of this result -->
<h2 class="subtitle has-text-centered">
Early simulator traces showing how policy choice can push prices toward aggressive high-end regimes.
First image description.
</h2>
</div>
<div class="item">
<!-- Your image here -->
<img src="static/images/carousel2.jpg" alt="Second research result visualization" loading="lazy"/>
<h2 class="subtitle has-text-centered">
Human and agent behavior diverge at the transition-kernel level, enabling usable session-level separability.
Second image description.
</h2>
</div>
<div class="item">
<!-- Your image here -->
<img src="static/images/carousel3.jpg" alt="Third research result visualization" loading="lazy"/>
<h2 class="subtitle has-text-centered">
End-to-end architecture linking web interactions, pricing queries, event streams, and model updates.
Third image description.
</h2>
</div>
<div class="item">
<!-- Your image here -->
<img src="static/images/carousel4.jpg" alt="Fourth research result visualization" loading="lazy"/>
<h2 class="subtitle has-text-centered">
Contamination-aware evaluation compares robust and non-robust pricing behavior across alpha sweeps.
Fourth image description.
</h2>
</div>
</div>
</div>
</div>
</section>
-->
<!-- End image carousel -->
<!-- Youtube video -->
<section class="hero is-small is-light">
<div class="hero-body">
<div class="container">
<!-- Paper video. -->
<h2 class="title is-3">Video Presentation</h2>
<div class="columns is-centered has-text-centered">
<div class="column is-four-fifths">
<div class="publication-video">
<!-- TODO: Replace with your YouTube video ID -->
<iframe src="https://www.youtube.com/embed/JkaxUblCGz0" frameborder="0" allow="autoplay; encrypted-media" allowfullscreen></iframe>
</div>
</div>
</div>
</div>
</div>
</section>
<!-- End youtube video -->
<!-- Video carousel -->
<section class="hero is-small">
<div class="hero-body">
<div class="container">
<h2 class="title is-3">Defense Scenes</h2>
<div id="videos-carousel" class="carousel results-carousel">
<h2 class="title is-3">Another Carousel</h2>
<div id="results-carousel" class="carousel results-carousel">
<div class="item item-video1">
<!-- TODO: Add poster image for better preview -->
<video poster="" id="video1" controls muted loop height="100%" preload="metadata">
<source src="static/videos/COIFirstPrinciplesScene.mp4" type="video/mp4">
<!-- Your video file here -->
<source src="static/videos/carousel1.mp4" type="video/mp4">
</video>
<h2 class="subtitle has-text-centered">COI from first principles.</h2>
</div>
<div class="item item-video2">
<!-- TODO: Add poster image for better preview -->
<video poster="" id="video2" controls muted loop height="100%" preload="metadata">
<source src="static/videos/BehaviorKernelConstructionScene.mp4" type="video/mp4">
<!-- Your video file here -->
<source src="static/videos/carousel2.mp4" type="video/mp4">
</video>
<h2 class="subtitle has-text-centered">Behavioral kernel construction: learning how humans and agents differ.</h2>
</div>
<div class="item item-video3">
<!-- TODO: Add poster image for better preview -->
<video poster="" id="video3" controls muted loop height="100%" preload="metadata">
<source src="static/videos/RobustControlScene.mp4" type="video/mp4">
<!-- Your video file here -->
<source src="static/videos/carousel3.mp4" type="video/mp4">
</video>
<h2 class="subtitle has-text-centered">Distributionally robust control loop.</h2>
</div>
</div>
</div>
@@ -448,10 +432,10 @@
<!-- Paper poster -->
<section class="hero is-small is-light">
<div class="hero-body">
<div class="container">
<h2 class="title">Full Thesis</h2>
<div class="container">
<h2 class="title">Poster</h2>
<iframe title="PHANTOM thesis PDF" src="https://pub-d5b94a3c29fd40c6b3881946e463fdb7.r2.dev/thesis-latest.pdf" width="100%" height="550">
<iframe src="https://pub-d5b94a3c29fd40c6b3881946e463fdb7.r2.dev/thesis-latest.pdf" width="100%" height="550">
</iframe>
</div>
@@ -473,7 +457,7 @@
</div>
<pre id="bibtex-code"><code>@thesis{Rosel2025PHANTOM,
title={Pricing Heuristics Against Non-human Transaction Orchestration Mechanisms},
author={Rösel, Daniel},
author={R{\"o}sel, Daniel},
school={IE University},
year={2025},
address={Madrid, Spain},

View File

@@ -1,246 +0,0 @@
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<!-- COLUMN 1: THE THREAT (COI & SATURATION) -->
<!-- ========================================================= -->
<text x="60" y="80" font-family="Georgia, serif" font-size="28" font-weight="bold" fill="#333333">1. The Vulnerability</text>
<line x1="60" y1="100" x2="580" y2="100" stroke="#DDDDDD" stroke-width="2"/>
<!-- Top: COI Bell Curve -->
<g transform="translate(60, 130)">
<text x="0" y="30" font-size="24" font-weight="bold" fill="#444">Cost of Information from First Principles</text>
<text x="0" y="70" font-family="Georgia, serif" font-style="italic" font-size="22" fill="#8C7A6B">P ~ π(τ)</text>
<text x="0" y="105" font-family="Georgia, serif" font-style="italic" font-size="22" fill="#8C7A6B"><tspan text-decoration="underline">p</tspan> = reservation price</text>
<text x="0" y="140" font-family="Georgia, serif" font-style="italic" font-size="22" fill="#8C7A6B">M = P - <tspan text-decoration="underline">p</tspan></text>
<!-- Bell Curve -->
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<text x="150" y="375" font-family="Georgia" font-style="italic" font-size="22" fill="#E37862" text-anchor="middle">p</text>
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<text x="260" y="375" font-family="Georgia" font-style="italic" font-size="22" fill="#85B589" text-anchor="middle">E[P]</text>
<!-- COI Annotation -->
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<text x="310" y="138" font-size="16" fill="#E37862" text-anchor="middle">average information rent</text>
<text x="310" y="118" font-family="Georgia" font-style="italic" font-size="22" fill="#E37862" font-weight="bold" text-anchor="middle">COI := E[P] - p</text>
</g>
<!-- Bottom: Agent Saturation -->
<g transform="translate(60, 580)">
<text x="0" y="30" font-size="24" font-weight="bold" fill="#444">Why COI Erodes with Agent Saturation</text>
<text x="0" y="75" font-family="Georgia, serif" font-style="italic" font-size="22" fill="#8C7A6B">p<tspan font-size="14" dy="5">(1)</tspan><tspan dy="-5"> = min(p</tspan><tspan font-size="14" dy="5">1</tspan><tspan dy="-5">, ..., p</tspan><tspan font-size="14" dy="5">N</tspan><tspan dy="-5">)</tspan></text>
<text x="0" y="115" font-family="Georgia, serif" font-style="italic" font-size="22" fill="#8C7A6B">P(p<tspan font-size="14" dy="5">(1)</tspan><tspan dy="-5"> > t) = [1 - F(t)]</tspan><tspan font-size="14" dy="-10">N</tspan></text>
<!-- Erosion Graph -->
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<text x="260" y="375" font-size="16" font-style="italic" fill="#555" text-anchor="middle">F(t)</text>
<text x="120" y="260" font-size="16" font-style="italic" fill="#555" text-anchor="middle" transform="rotate(-90 120 260)">[1 - F(t)]^N</text>
<!-- Curves -->
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<text x="390" y="220" font-size="16" fill="#4EA5D9" font-weight="bold">N=1</text>
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<text x="390" y="250" font-size="16" fill="#85B589" font-weight="bold">N=4</text>
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<text x="260" y="420" font-size="20" fill="#555" text-anchor="middle">As independent query count grows,</text>
<text x="260" y="445" font-size="20" fill="#E37862" font-weight="bold" text-anchor="middle">realizable markup collapses.</text>
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<!-- ========================================================= -->
<!-- COLUMN 2: THE BEHAVIORAL SIGNAL -->
<!-- ========================================================= -->
<text x="700" y="80" font-family="Georgia, serif" font-size="28" font-weight="bold" fill="#333333">2. The Behavioral Signals</text>
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<!-- Top: Transition Kernels -->
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<text x="0" y="30" font-size="24" font-weight="bold" fill="#444">From Session Paths to Transition Kernels</text>
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<text x="0" y="115" font-size="20" fill="#E37862" font-weight="bold">agent: start → view → detail → view → detail</text>
<text x="0" y="170" font-family="Georgia, serif" font-style="italic" font-size="24" fill="#8C7A6B">
P&#770;(s'|s) = <tspan font-size="18" dy="-12">N(s,s')</tspan> / <tspan font-size="18" dy="12">Σ N(s,k)</tspan>
</text>
<!-- Matrix Representation -->
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<text x="125" y="250" font-size="16" fill="#4EA5D9" text-anchor="middle">transition counts N(s,s')</text>
<text x="375" y="250" font-size="16" fill="#85B589" text-anchor="middle">normalized kernel T</text>
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<text x="250" y="440" font-size="18" fill="#777" text-anchor="middle">Kernel shape is the compact behavioral signature used downstream.</text>
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<!-- Human Curve -->
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<text x="70" y="110" font-size="22" fill="#4EA5D9" font-weight="bold">human</text>
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<text x="180" y="-5" font-size="16" fill="#777" text-anchor="middle">decision boundary</text>
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<text x="210" y="180" font-family="Georgia" font-style="italic" font-size="20" fill="#ECA233" text-anchor="middle">g_obs</text>
<text x="180" y="280" font-size="18" fill="#555" text-anchor="middle">Positive gap shifts score toward agent traffic.</text>
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</g>
<!-- ========================================================= -->
<!-- COLUMN 3: THE SOLUTION (CONTAMINATION & DR-RL) -->
<!-- ========================================================= -->
<text x="1340" y="80" font-family="Georgia, serif" font-size="28" font-weight="bold" fill="#333333">3. Robust Control &amp; Contamination</text>
<line x1="1340" y1="100" x2="1860" y2="100" stroke="#DDDDDD" stroke-width="2"/>
<!-- Top: Contamination Generator -->
<g transform="translate(1340, 130)">
<text x="0" y="30" font-size="24" font-weight="bold" fill="#444">Contamination Generator G(α)</text>
<!-- Boxes -->
<rect x="20" y="70" width="200" height="50" fill="#D0E5E0" filter="url(#shadow)" rx="6"/>
<text x="120" y="100" font-size="18" fill="#222" text-anchor="middle">labeled human sessions</text>
<rect x="280" y="70" width="200" height="50" fill="#EAD0C8" filter="url(#shadow)" rx="6"/>
<text x="380" y="100" font-size="18" fill="#222" text-anchor="middle">synthetic agent sessions</text>
<!-- Arrows -->
<line x1="120" y1="130" x2="200" y2="180" stroke="#888" stroke-width="3" marker-end="url(#arrow-dark)"/>
<line x1="380" y1="130" x2="300" y2="180" stroke="#888" stroke-width="3" marker-end="url(#arrow-dark)"/>
<!-- Mixed Batch -->
<rect x="150" y="190" width="200" height="50" fill="#F4E9CD" filter="url(#shadow)" rx="6"/>
<text x="250" y="220" font-size="18" fill="#222" text-anchor="middle">mixed batch for training</text>
<!-- Alpha Bar -->
<text x="250" y="275" font-family="Georgia, serif" font-size="20" fill="#555" text-anchor="middle">alpha = 0.33</text>
<rect x="50" y="290" width="268" height="30" fill="#4EA5D9"/>
<rect x="318" y="290" width="132" height="30" fill="#E37862"/>
<text x="184" y="340" font-size="18" fill="#4EA5D9" text-anchor="middle">human share (1-α)</text>
<text x="384" y="340" font-size="18" fill="#E37862" text-anchor="middle">agent share (α)</text>
</g>
<!-- Bottom: Distributionally Robust Control -->
<g transform="translate(1340, 600)">
<text x="0" y="30" font-size="24" font-weight="bold" fill="#444">Distributionally Robust Control Layer</text>
<text x="0" y="80" font-family="Georgia, serif" font-style="italic" font-size="22" fill="#8C7A6B">
π* = arg max<tspan font-size="16" dy="5">π</tspan> min<tspan font-size="16" dy="0">Q ∈ U<tspan font-size="12" dy="5">ε</tspan></tspan>
<tspan dy="-10"> E</tspan><tspan font-size="16" dy="5">d ~ Q</tspan>
<tspan dy="-5">[ R(p,d) - λ COI</tspan><tspan font-size="16" dy="5">leak</tspan><tspan dy="-5">(p,τ') ]</tspan>
</text>
<!-- Ambiguity Ball -->
<g transform="translate(140, 260)">
<line x1="-130" y1="0" x2="130" y2="0" stroke="#CCC" stroke-width="2"/>
<line x1="0" y1="-130" x2="0" y2="130" stroke="#CCC" stroke-width="2"/>
<circle cx="0" cy="0" r="110" stroke="#C4A45B" stroke-width="4" fill="rgba(196,164,91,0.06)"/>
<text x="-95" y="-120" font-family="Georgia" font-style="italic" font-size="24" fill="#C4A45B">U<tspan font-size="16" dy="5">ε</tspan></text>
<!-- Points -->
<circle cx="0" cy="0" r="7" fill="#4EA5D9"/>
<text x="12" y="24" font-family="Georgia" font-style="italic" font-size="22" fill="#4EA5D9">P&#770;<tspan font-size="14" dy="5">N</tspan></text>
<circle cx="-60" cy="-40" r="7" fill="#E37862"/>
<text x="-140" y="-50" font-family="Georgia" font-style="italic" font-size="18" fill="#E37862">worst-case Q*</text>
<circle cx="50" cy="-70" r="6" fill="#85B589"/>
<circle cx="70" cy="50" r="6" fill="#85B589"/>
<circle cx="-40" cy="80" r="6" fill="#85B589"/>
</g>
<!-- Process Steps -->
<g transform="translate(320, 140)">
<rect x="0" y="0" width="220" height="45" fill="#FDEFEF" filter="url(#light-shadow)" rx="6"/>
<text x="110" y="28" font-size="16" fill="#E37862" font-weight="bold" text-anchor="middle">inner min picks Q*</text>
<line x1="110" y1="55" x2="110" y2="85" stroke="#999" stroke-width="2" marker-end="url(#arrow-dark)"/>
<rect x="0" y="95" width="220" height="45" fill="#F4E9CD" filter="url(#light-shadow)" rx="6"/>
<text x="110" y="123" font-size="16" fill="#9E8033" font-weight="bold" text-anchor="middle">sample demand from Q*</text>
<line x1="110" y1="150" x2="110" y2="180" stroke="#999" stroke-width="2" marker-end="url(#arrow-dark)"/>
<rect x="0" y="190" width="220" height="45" fill="#E6F2ED" filter="url(#light-shadow)" rx="6"/>
<text x="110" y="218" font-size="16" fill="#428062" font-weight="bold" text-anchor="middle">outer max updates policy</text>
</g>
<text x="250" y="440" font-size="18" fill="#555" text-anchor="middle">Reward is evaluated on demand drawn from Q*, then used for the policy step.</text>
</g>
</svg>

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__all__ = ["evaluate", "make_env", "train_qtable", "train_sb3"]

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from __future__ import annotations
from typing import Any, Mapping
import numpy as np
def make_env(cfg: Mapping[str, Any]):
from gymnasium.wrappers import FlattenObservation
from ..lib.wrappers import EconomicMetricsWrapper
from ..wrapper import PHANTOM
env = PHANTOM(
n_products=int(cfg["n_products"]),
alpha=float(cfg["alpha"]),
N=int(cfg["N"]),
agent_params=(
float(cfg.get("agent_mu", 45.0)),
float(cfg.get("agent_std", 15.0)),
),
price_bounds=(float(cfg["price_low"]), float(cfg["price_high"])),
lambda_coi=float(cfg["lambda_coi"]),
robust_radius=float(cfg["robust_radius"]),
robust_points=int(cfg["robust_points"]),
robust_rollouts=int(cfg.get("robust_rollouts", 1)),
info_value=float(cfg["info_value"]),
eta_ux=float(cfg.get("eta_ux", 0.5)),
reward_profit_weight=float(cfg.get("reward_profit_weight", 1.0)),
action_levels=int(cfg["action_levels"]),
action_scale_low=float(cfg["action_scale_low"]),
action_scale_high=float(cfg["action_scale_high"]),
max_steps=int(cfg.get("max_steps", 100)),
margin_floor=float(cfg.get("margin_floor", 0.05)),
margin_floor_patience=int(cfg.get("margin_floor_patience", 5)),
render_mode=None,
)
env = EconomicMetricsWrapper(env)
return FlattenObservation(env)
def _action(agent: Any, obs: Any, deterministic: bool = True):
out = agent.predict(obs, deterministic=deterministic)
action = out[0] if isinstance(out, tuple) else out
if isinstance(action, np.ndarray) and action.size == 1:
return int(action.reshape(-1)[0])
return action
def _evaluate_env(agent: Any, env: Any, episodes: int) -> dict[str, float]:
rewards: list[float] = []
revenues: list[float] = []
margins: list[float] = []
coi_levels: list[float] = []
coi_leakages: list[float] = []
volatilities: list[float] = []
upward_volatilities: list[float] = []
supra_shares: list[float] = []
supra_penalties: list[float] = []
agent_probs: list[float] = []
for _ in range(int(episodes)):
obs, _ = env.reset()
done = False
ep_reward = 0.0
ep_revenue = 0.0
ep_margin = 0.0
ep_coi = 0.0
ep_coi_leakage = 0.0
ep_volatility = 0.0
ep_upward_volatility = 0.0
ep_supra_share = 0.0
ep_supra_penalty = 0.0
ep_agent_prob = 0.0
steps = 0
while not done:
obs, reward, term, trunc, info = env.step(_action(agent, obs, True))
done = bool(term or trunc)
econ = info.get("economics", {})
ep_reward += float(reward)
ep_revenue += float(econ.get("revenue", info.get("revenue", 0.0)))
ep_margin += float(econ.get("margin", 0.0))
ep_coi += float(econ.get("coi_level", 0.0))
ep_coi_leakage += float(econ.get("coi_leakage", 0.0))
ep_volatility += float(econ.get("volatility", 0.0))
ep_upward_volatility += float(
info.get("upward_volatility", econ.get("upward_volatility", 0.0))
)
ep_supra_share += float(
info.get("supra_share", econ.get("supra_share", 0.0))
)
ep_supra_penalty += float(
info.get("supra_penalty", econ.get("supra_penalty", 0.0))
)
ep_agent_prob += float(econ.get("agent_prob", info.get("agent_prob", 0.0)))
steps += 1
rewards.append(ep_reward)
revenues.append(ep_revenue)
denom = max(steps, 1)
margins.append(ep_margin / denom)
coi_levels.append(ep_coi / denom)
coi_leakages.append(ep_coi_leakage / denom)
volatilities.append(ep_volatility / denom)
upward_volatilities.append(ep_upward_volatility / denom)
supra_shares.append(ep_supra_share / denom)
supra_penalties.append(ep_supra_penalty / denom)
agent_probs.append(ep_agent_prob / denom)
return {
"eval/reward_mean": float(np.mean(rewards)) if rewards else 0.0,
"eval/reward_std": float(np.std(rewards)) if rewards else 0.0,
"eval/revenue_mean": float(np.mean(revenues)) if revenues else 0.0,
"eval/revenue_std": float(np.std(revenues)) if revenues else 0.0,
"eval/margin_mean": float(np.mean(margins)) if margins else 0.0,
"eval/coi_level_mean": float(np.mean(coi_levels)) if coi_levels else 0.0,
"eval/coi_leakage_mean": float(np.mean(coi_leakages)) if coi_leakages else 0.0,
"eval/volatility_mean": float(np.mean(volatilities)) if volatilities else 0.0,
"eval/upward_volatility_mean": (
float(np.mean(upward_volatilities)) if upward_volatilities else 0.0
),
"eval/supra_share_mean": float(np.mean(supra_shares)) if supra_shares else 0.0,
"eval/supra_penalty_mean": (
float(np.mean(supra_penalties)) if supra_penalties else 0.0
),
"eval/agent_prob_mean": float(np.mean(agent_probs)) if agent_probs else 0.0,
}
def evaluate(
agent: Any,
env: Any,
episodes: int,
cfg: Mapping[str, Any] | None = None,
) -> dict[str, float]:
metrics = _evaluate_env(agent, env, episodes)
if cfg is None or not bool(cfg.get("robust_eval_enabled", True)):
return metrics
nominal_alpha = float(cfg.get("alpha", 0.0))
eval_radius = max(float(cfg.get("robust_radius", 0.0)), 0.15)
low_alpha = float(np.clip(nominal_alpha - eval_radius, 0.0, 1.0))
high_alpha = float(np.clip(nominal_alpha + eval_radius, 0.0, 1.0))
shifted_episodes = max(1, int(np.ceil(int(episodes) / 2)))
shifted_rows = []
for tag, alpha in (
("low", low_alpha),
("nominal", nominal_alpha),
("high", high_alpha),
):
eval_cfg = dict(cfg)
eval_cfg["alpha"] = float(alpha)
shifted_env = make_env(eval_cfg)
shifted_metrics = _evaluate_env(agent, shifted_env, shifted_episodes)
shifted_env.close()
shifted_rows.append((tag, alpha, shifted_metrics))
metrics["eval/stress_alpha_low"] = low_alpha
metrics["eval/stress_alpha_high"] = high_alpha
metrics["eval/stress_reward_worst"] = float(
min(row[2]["eval/reward_mean"] for row in shifted_rows)
)
metrics["eval/stress_revenue_worst"] = float(
min(row[2]["eval/revenue_mean"] for row in shifted_rows)
)
metrics["eval/stress_coi_leakage_worst"] = float(
max(row[2]["eval/coi_leakage_mean"] for row in shifted_rows)
)
for tag, alpha, shifted_metrics in shifted_rows:
metrics[f"eval/{tag}_alpha"] = float(alpha)
metrics[f"eval/{tag}_reward_mean"] = float(shifted_metrics["eval/reward_mean"])
metrics[f"eval/{tag}_revenue_mean"] = float(
shifted_metrics["eval/revenue_mean"]
)
metrics[f"eval/{tag}_coi_leakage_mean"] = float(
shifted_metrics["eval/coi_leakage_mean"]
)
return metrics

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from __future__ import annotations
import logging
import time
from typing import Any, Mapping
import numpy as np
from .common import evaluate, make_env
from ..telemetry.wandb import get_wandb_module
logger = logging.getLogger(__name__)
def train_qtable(
cfg: Mapping[str, Any],
) -> tuple[object, dict[str, Any]]:
from ..lib.discrete import EventQTable
np.random.seed(int(cfg["seed"]))
env = make_env(cfg)
eval_env = make_env(cfg)
agent = EventQTable(
env.action_space.n,
int(cfg["n_products"]),
(float(cfg["price_low"]), float(cfg["price_high"])),
lr=float(cfg["q_lr"]),
gamma=float(cfg["gamma"]),
n_bins=int(cfg["q_bins"]),
)
total_reward = 0.0
total_revenue = 0.0
steps = 0
epsilon = float(cfg["eps_start"])
log_freq = max(1, int(cfg.get("log_freq", 100)))
console_progress = bool(cfg.get("console_progress", False))
obs, _ = env.reset(seed=int(cfg["seed"]))
started_at = time.perf_counter()
wandb = get_wandb_module()
wandb_live = bool(wandb is not None and wandb.run is not None)
step_offset = max(0, int(cfg.get("wandb_step_offset", 0)))
interval_sums = {
"reward": 0.0,
"revenue": 0.0,
"agent_prob": 0.0,
"alpha_adv": 0.0,
"coi_leakage": 0.0,
}
interval_count = 0
train_events: list[dict[str, float | int]] = []
for _ in range(int(cfg["total_timesteps"])):
action, state = agent.act(obs, epsilon)
nxt, reward, term, trunc, info = env.step(action)
done = bool(term or trunc)
agent.update(state, action, float(reward), agent.encode(nxt), done)
total_reward += float(reward)
revenue = float(info.get("economics", {}).get("revenue", 0.0))
total_revenue += revenue
steps += 1
interval_sums["reward"] += float(reward)
interval_sums["revenue"] += revenue
interval_sums["agent_prob"] += float(info.get("agent_prob", 0.0))
interval_sums["alpha_adv"] += float(info.get("alpha_adv", 0.0))
interval_sums["coi_leakage"] += float(info.get("coi_leakage", 0.0))
interval_count += 1
if steps % log_freq == 0 and interval_count > 0:
denom = float(interval_count)
event = {
"train/reward_mean": interval_sums["reward"] / denom,
"train/revenue_mean": interval_sums["revenue"] / denom,
"train/agent_prob": interval_sums["agent_prob"] / denom,
"train/alpha_adv": interval_sums["alpha_adv"] / denom,
"train/coi_leakage": interval_sums["coi_leakage"] / denom,
"train/epsilon": float(epsilon),
"train/global_step": int(steps),
}
if wandb_live:
try:
wandb.log(dict(event), step=step_offset + int(steps))
except Exception:
wandb_live = False
train_events.append(event)
else:
train_events.append(event)
if console_progress:
elapsed = max(time.perf_counter() - started_at, 1e-6)
speed = steps / elapsed
logger.info(
"step=%d/%d reward=%.3f revenue=%.3f eps=%.4f speed=%.1f steps/s",
steps,
int(cfg["total_timesteps"]),
event["train/reward_mean"],
event["train/revenue_mean"],
event["train/epsilon"],
speed,
)
interval_sums = {key: 0.0 for key in interval_sums}
interval_count = 0
epsilon = max(float(cfg["eps_end"]), epsilon * float(cfg["eps_decay"]))
obs = env.reset()[0] if done else nxt
if interval_count > 0:
denom = float(interval_count)
tail_event = {
"train/reward_mean": interval_sums["reward"] / denom,
"train/revenue_mean": interval_sums["revenue"] / denom,
"train/agent_prob": interval_sums["agent_prob"] / denom,
"train/alpha_adv": interval_sums["alpha_adv"] / denom,
"train/coi_leakage": interval_sums["coi_leakage"] / denom,
"train/epsilon": float(epsilon),
"train/global_step": int(steps),
}
if wandb_live:
try:
wandb.log(dict(tail_event), step=step_offset + int(steps))
except Exception:
wandb_live = False
train_events.append(tail_event)
else:
train_events.append(tail_event)
metrics: dict[str, Any] = {
"train/reward_mean": total_reward / max(steps, 1),
"train/revenue_mean": total_revenue / max(steps, 1),
"train/epsilon": float(epsilon),
"train/global_step": int(cfg["total_timesteps"]),
}
metrics.update(evaluate(agent, eval_env, int(cfg["eval_episodes"]), cfg=cfg))
metrics["_train_events"] = train_events
env.close()
eval_env.close()
return agent, metrics

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from __future__ import annotations
import json
import os
from pathlib import Path
from typing import Any, Mapping
from ..lib.callbacks import EvalMetricsCallback, MetricsCallback
from ..wandb_checkpoint import checkpoint_artifact_name, log_checkpoint_file
from .common import evaluate, make_env
def _net_arch(name: Any) -> list[int]:
presets = {
"tiny": [32, 32],
"small": [64, 64],
"medium": [128, 128],
"large": [256, 256],
}
if isinstance(name, (list, tuple)):
return [int(v) for v in name]
raw = str(name).lower().strip()
if raw in presets:
return presets[raw]
if "x" in raw:
try:
parsed = [int(v) for v in raw.split("x") if v]
return parsed if parsed else presets["small"]
except ValueError:
return presets["small"]
return presets["small"]
def _activation(name: Any):
try:
import torch.nn as nn
except ImportError:
return None
return {
"relu": nn.ReLU,
"tanh": nn.Tanh,
"elu": nn.ELU,
"leaky_relu": nn.LeakyReLU,
}.get(str(name).lower().strip(), nn.ReLU)
def _policy_kwargs(cfg: Mapping[str, Any]) -> dict[str, Any]:
kwargs: dict[str, Any] = {"net_arch": _net_arch(cfg.get("arch", "small"))}
activation = _activation(cfg.get("activation", "relu"))
if activation is not None:
kwargs["activation_fn"] = activation
return kwargs
def build_model(cfg: Mapping[str, Any], env: Any):
try:
from stable_baselines3 import A2C, DQN, PPO
except ImportError as exc:
raise ImportError("stable-baselines3 is required for SB3 algorithms") from exc
algo = str(cfg["algo"])
policy_kwargs = _policy_kwargs(cfg)
device = str(cfg.get("device", "auto"))
seed = int(cfg["seed"])
if algo == "sac":
raise ValueError("sac is not supported with the discrete core env")
if algo == "ppo":
return PPO(
"MlpPolicy",
env,
verbose=1,
device=device,
policy_kwargs=policy_kwargs,
seed=seed,
learning_rate=float(cfg["learning_rate"]),
n_steps=int(cfg["n_steps"]),
batch_size=int(cfg["batch_size"]),
n_epochs=int(cfg["n_epochs"]),
gamma=float(cfg["gamma"]),
gae_lambda=float(cfg["gae_lambda"]),
clip_range=float(cfg["clip_range"]),
ent_coef=float(cfg["ent_coef"]),
)
if algo == "a2c":
return A2C(
"MlpPolicy",
env,
verbose=1,
device=device,
policy_kwargs=policy_kwargs,
seed=seed,
learning_rate=float(cfg["learning_rate"]),
n_steps=max(5, int(cfg["n_steps"]) // 32),
gamma=float(cfg["gamma"]),
gae_lambda=float(cfg["gae_lambda"]),
ent_coef=float(cfg["ent_coef"]),
)
if algo == "dqn":
return DQN(
"MlpPolicy",
env,
verbose=1,
device=device,
policy_kwargs=policy_kwargs,
seed=seed,
learning_rate=float(cfg["learning_rate"]),
buffer_size=int(cfg["buffer_size"]),
batch_size=int(cfg["batch_size"]),
gamma=float(cfg["gamma"]),
train_freq=int(cfg["train_freq"]),
learning_starts=int(cfg["learning_starts"]),
target_update_interval=int(cfg["target_update_interval"]),
exploration_fraction=float(cfg["exploration_fraction"]),
exploration_final_eps=float(cfg["exploration_final_eps"]),
)
raise ValueError(f"unsupported algo '{algo}'")
def train_sb3(cfg: Mapping[str, Any]) -> tuple[object, dict[str, Any]]:
try:
from stable_baselines3.common.monitor import Monitor
except ImportError as exc:
raise ImportError("stable-baselines3 is required for SB3 models") from exc
env = Monitor(make_env(cfg))
eval_env = Monitor(make_env(cfg))
model = build_model(cfg, env)
try:
import torch
print(
"PHANTOM_DEVICE: "
+ json.dumps(
{
"requested": str(cfg.get("device", "auto")),
"torch_cuda_available": bool(torch.cuda.is_available()),
"torch_device_count": int(torch.cuda.device_count()),
"sb3_device": str(getattr(model, "device", "unknown")),
}
)
)
except Exception:
pass
metrics_callback = MetricsCallback(
log_histograms=True,
log_freq=int(cfg["log_freq"]),
hist_freq=int(cfg.get("hist_freq", 500)),
step_offset=int(cfg.get("wandb_step_offset", 0)),
)
eval_callback = EvalMetricsCallback(
eval_env,
eval_freq=int(cfg["eval_freq"]),
n_eval_episodes=int(cfg["eval_episodes"]),
step_offset=int(cfg.get("wandb_step_offset", 0)),
deterministic=True,
verbose=0,
)
callbacks = [metrics_callback, eval_callback]
target_steps = int(cfg["total_timesteps"])
remaining_steps = max(0, target_steps - int(getattr(model, "num_timesteps", 0)))
if remaining_steps > 0:
model.learn(
total_timesteps=remaining_steps,
callback=callbacks,
reset_num_timesteps=False,
)
model_dir = Path(str(cfg["model_dir"]))
model_dir.mkdir(parents=True, exist_ok=True)
model_path = model_dir / f"phantom_{cfg['algo']}"
model.save(str(model_path))
artifact_name = checkpoint_artifact_name(
cfg,
backend="sb3",
sweep_id=os.getenv("WANDB_SWEEP_ID"),
)
artifact_logged = False
try:
artifact_logged = bool(
log_checkpoint_file(
artifact_name,
file_path=model_path.with_suffix(".zip"),
artifact_file_name="model.zip",
metadata={
"algo": str(cfg.get("algo", "ppo")),
"backend": "sb3",
"seed": int(cfg.get("seed", 0)),
"step": int(getattr(model, "num_timesteps", 0)),
},
)
)
except Exception:
artifact_logged = False
metrics: dict[str, Any] = evaluate(
model,
eval_env,
int(cfg["eval_episodes"]),
cfg=cfg,
)
metrics["train/global_step"] = int(model.num_timesteps)
metrics["model/path"] = str(model_path.with_suffix(".zip"))
metrics["model/artifact_name"] = str(artifact_name)
metrics["model/artifact_logged"] = float(artifact_logged)
metrics["_train_events"] = sorted(
[*metrics_callback.events, *eval_callback.events],
key=lambda event: int(event.get("train/global_step", 0)),
)
env.close()
eval_env.close()
return model, metrics

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@@ -1,702 +0,0 @@
from __future__ import annotations
import os
import subprocess
import sys
import argparse
import json
import logging
from datetime import datetime, timezone
from pathlib import Path
# clear stale TPU locks on startup
if os.path.exists("/dev/accel0"):
try:
subprocess.run(
["rm", "-f", "/tmp/.libtpu_lockfile", "/tmp/libtpu_lockfile"],
stderr=subprocess.DEVNULL,
)
except:
pass
try:
import jax
jax.config.update("jax_threefry_partitionable", True)
except ImportError:
pass
import matplotlib.pyplot as plt
import numpy as np
import pandas as pd
from .lib.tiers import LinearElasticityPolicy, StaticPolicy, SurgePolicy
from .logging_utils import configure_logging
from .spec import TrainSpec
from .telemetry.wandb import get_wandb_module
wandb = get_wandb_module()
HAS_WANDB = wandb is not None
logger = logging.getLogger(__name__)
def _log(message: str) -> None:
logger.info(message)
def _wandb_run_active() -> bool:
return bool(HAS_WANDB and getattr(wandb, "run", None) is not None)
def _parse_list(raw: str) -> list[str]:
return [x.strip().lower() for x in str(raw).split(",") if x.strip()]
def _parse_float_list(raw: str) -> list[float]:
return [float(x.strip()) for x in str(raw).split(",") if x.strip()]
def _truthy(value: str | bool | None) -> bool:
if isinstance(value, bool):
return value
if value is None:
return False
return str(value).strip().lower() in {"1", "true", "yes", "on"}
def _mode_label_from_baseline(is_baseline: bool) -> str:
return "baseline" if bool(is_baseline) else "defended"
def _action(policy, obs: np.ndarray):
out = policy.predict(obs, deterministic=True)
action = out[0] if isinstance(out, tuple) else out
if isinstance(action, np.ndarray) and action.size == 1:
return int(action.reshape(-1)[0])
return int(action)
def _run_eval_episode(env, policy) -> dict:
obs, _ = env.reset()
done = False
total_reward = 0.0
total_revenue = 0.0
total_margin = 0.0
total_coi = 0.0
price_trace: list[float] = []
step_count = 0
while not done:
action = _action(policy, obs)
obs, reward, term, trunc, info = env.step(action)
done = bool(term or trunc)
econ = info.get("economics", {})
total_reward += float(reward)
total_revenue += float(econ.get("revenue", 0.0))
total_margin += float(econ.get("margin", 0.0))
total_coi += float(econ.get("coi_level", 0.0))
prices = np.asarray(info.get("prices", []), dtype=np.float32)
if prices.size > 0:
price_trace.append(float(np.mean(prices)))
step_count += 1
denom = max(step_count, 1)
return {
"reward": total_reward,
"revenue": total_revenue,
"mean_margin": total_margin / denom,
"mean_coi": total_coi / denom,
"price_trace": price_trace,
}
def _build_tier(name: str, cfg: dict, alpha: float, *, step_offset: int = 0):
from .backends.common import make_env
tier = name.lower().strip()
run_cfg = dict(cfg)
run_cfg["alpha"] = float(alpha)
run_cfg["wandb_step_offset"] = int(step_offset)
if tier == "static":
return StaticPolicy(int(run_cfg["action_levels"])), []
if tier == "surge":
return (
SurgePolicy(
n_actions=int(run_cfg["action_levels"]),
n_products=int(run_cfg["n_products"]),
),
[],
)
if tier == "linear":
warmup_env = make_env(run_cfg)
policy = LinearElasticityPolicy(
n_actions=int(run_cfg["action_levels"]),
n_products=int(run_cfg["n_products"]),
price_low=float(run_cfg["price_low"]),
price_high=float(run_cfg["price_high"]),
)
policy.fit(
warmup_env,
warmup_steps=int(run_cfg.get("linear_warmup_steps", 800)),
seed=int(run_cfg["seed"]),
)
warmup_env.close()
return policy, []
if tier == "qtable":
from .backends.qtable import train_qtable
run_cfg["console_progress"] = True
agent, metrics = train_qtable(run_cfg)
events = metrics.get("_train_events", [])
return agent, events if isinstance(events, list) else []
if tier in {"ppo", "a2c", "dqn"}:
from .backends.sb3 import train_sb3
run_cfg["algo"] = tier
agent, metrics = train_sb3(run_cfg)
events = metrics.get("_train_events", [])
return agent, events if isinstance(events, list) else []
raise ValueError(f"unsupported tier '{name}'")
def _log_train_events(
events: list[dict],
*,
tier_name: str,
mode_label: str,
alpha: float,
step_offset: int,
) -> int:
if not _wandb_run_active():
return int(step_offset)
if not events:
return int(step_offset)
ordered = sorted(
[evt for evt in events if isinstance(evt, dict)],
key=lambda evt: int(evt.get("train/global_step", 0)),
)
if not ordered:
return int(step_offset)
cursor = int(step_offset)
for evt in ordered:
rel_step = max(1, int(evt.get("train/global_step", 0)))
payload = dict(evt)
payload.update(
{
"run.kind": "benchmark",
"runtime/backend": tier_name,
"study/mode": mode_label,
"study/baseline_mode": float(mode_label == "baseline"),
"study/alpha": float(alpha),
}
)
try:
wandb.log(payload, step=cursor + rel_step)
except Exception:
return int(step_offset)
max_rel = max(max(1, int(evt.get("train/global_step", 0))) for evt in ordered)
return cursor + max_rel + 1
def run_benchmark(
cfg: dict,
tiers: list[str],
alpha_values: list[float],
n_episodes: int,
mode_label: str,
step_cursor_start: int = 0,
eval_alpha_values: list[float] | None = None,
):
from .backends.common import make_env
rows: list[dict] = []
traces: list[dict] = []
total_runs = max(1, len(alpha_values) * len(tiers))
run_index = 0
wandb_step_cursor = int(step_cursor_start)
for alpha in alpha_values:
for tier_name in tiers:
run_index += 1
_log(
f"[{run_index}/{total_runs}] alpha={float(alpha):.2f} tier={tier_name}: training"
)
policy, train_events = _build_tier(
tier_name,
cfg,
alpha,
step_offset=wandb_step_cursor,
)
prev_cursor = int(wandb_step_cursor)
wandb_step_cursor = _log_train_events(
train_events,
tier_name=tier_name,
mode_label=mode_label,
alpha=float(alpha),
step_offset=wandb_step_cursor,
)
if wandb_step_cursor == prev_cursor and tier_name in {
"qtable",
"ppo",
"a2c",
"dqn",
}:
wandb_step_cursor += max(1, int(cfg.get("total_timesteps", 1))) + 1
eval_targets = (
[float(value) for value in eval_alpha_values]
if eval_alpha_values
else [float(alpha)]
)
for eval_alpha in eval_targets:
env = make_env({**cfg, "alpha": float(eval_alpha)})
eps = [_run_eval_episode(env, policy) for _ in range(int(n_episodes))]
env.close()
row = {
"tier": tier_name,
"mode": mode_label,
"alpha": float(eval_alpha),
"train_alpha": float(alpha),
"eval_alpha": float(eval_alpha),
"episodes": int(n_episodes),
"mean_reward": float(np.mean([e["reward"] for e in eps])),
"mean_revenue": float(np.mean([e["revenue"] for e in eps])),
"mean_margin": float(np.mean([e["mean_margin"] for e in eps])),
"mean_coi": float(np.mean([e["mean_coi"] for e in eps])),
"std_revenue": float(np.std([e["revenue"] for e in eps])),
}
row["objective_score"] = row["mean_reward"]
rows.append(row)
_log(
f"[{run_index}/{total_runs}] train_alpha={float(alpha):.2f} "
f"eval_alpha={float(eval_alpha):.2f} tier={tier_name}: "
f"reward={row['mean_reward']:.3f} revenue={row['mean_revenue']:.3f} "
f"coi={row['mean_coi']:.4f} score={row['objective_score']:.3f}"
)
max_len = max((len(e["price_trace"]) for e in eps), default=0)
step_means = []
for step in range(max_len):
vals = [
e["price_trace"][step]
for e in eps
if step < len(e["price_trace"])
]
step_means.append(float(np.mean(vals)) if vals else np.nan)
traces.append(
{
"tier": tier_name,
"alpha": float(eval_alpha),
"train_alpha": float(alpha),
"eval_alpha": float(eval_alpha),
"mean_price_trace": step_means,
}
)
if _wandb_run_active():
try:
wandb.log(
{
"run.kind": "benchmark",
"runtime/backend": tier_name,
"study/mode": mode_label,
"study/baseline_mode": float(mode_label == "baseline"),
"study/alpha": float(eval_alpha),
"study/train_alpha": float(alpha),
"study/eval_alpha": float(eval_alpha),
"eval/reward_mean": row["mean_reward"],
"eval/revenue_mean": row["mean_revenue"],
"eval/margin_mean": row["mean_margin"],
"eval/coi_level_mean": row["mean_coi"],
"objective/score": row["objective_score"],
"objective/coi_preserved": row["mean_coi"],
},
step=wandb_step_cursor,
)
except Exception:
pass
wandb_step_cursor += 1
return pd.DataFrame(rows), traces, int(wandb_step_cursor)
def _plot_outputs(df: pd.DataFrame, traces: list[dict], out_dir: Path, stamp: str):
fig1 = plt.figure(figsize=(11, 4.5))
if "mode" in df.columns:
groups = sorted(df[["tier", "mode"]].drop_duplicates().values.tolist())
for tier, mode in groups:
sub = df[(df["tier"] == tier) & (df["mode"] == mode)].sort_values("alpha")
plt.plot(
sub["alpha"],
sub["mean_revenue"],
marker="o",
label=f"{tier}:{mode}",
)
else:
for tier in sorted(df["tier"].unique()):
sub = df[df["tier"] == tier].sort_values("alpha")
plt.plot(sub["alpha"], sub["mean_revenue"], marker="o", label=tier)
plt.xlabel("contamination alpha")
plt.ylabel("mean episode revenue")
plt.title("Revenue under contamination")
plt.grid(alpha=0.3)
plt.legend()
fig1.tight_layout()
rev_path = out_dir / f"benchmark_revenue_{stamp}.png"
fig1.savefig(rev_path, dpi=220)
plt.close(fig1)
fig2 = plt.figure(figsize=(11, 4.5))
if "mode" in df.columns:
groups = sorted(df[["tier", "mode"]].drop_duplicates().values.tolist())
for tier, mode in groups:
sub = df[(df["tier"] == tier) & (df["mode"] == mode)].sort_values("alpha")
plt.plot(
sub["alpha"],
sub["mean_coi"],
marker="s",
label=f"{tier}:{mode}",
)
else:
for tier in sorted(df["tier"].unique()):
sub = df[df["tier"] == tier].sort_values("alpha")
plt.plot(sub["alpha"], sub["mean_coi"], marker="s", label=tier)
plt.xlabel("contamination alpha")
plt.ylabel("mean COI level")
plt.title("COI preservation")
plt.grid(alpha=0.3)
plt.legend()
fig2.tight_layout()
coi_path = out_dir / f"benchmark_coi_{stamp}.png"
fig2.savefig(coi_path, dpi=220)
plt.close(fig2)
focus_alpha = float(df["alpha"].min()) if not df.empty else 0.0
alpha_traces = [t for t in traces if abs(float(t["alpha"]) - focus_alpha) < 1e-9]
fig3 = plt.figure(figsize=(11, 4.5))
for item in alpha_traces:
xs = np.arange(len(item["mean_price_trace"]))
ys = np.asarray(item["mean_price_trace"], dtype=np.float32)
mode = item.get("mode")
label = f"{item['tier']}:{mode}" if mode is not None else str(item["tier"])
plt.plot(xs, ys, label=label)
plt.xlabel("step")
plt.ylabel("mean price")
plt.title(f"Price evolution (alpha={focus_alpha:.2f})")
plt.grid(alpha=0.3)
plt.legend()
fig3.tight_layout()
price_path = out_dir / f"benchmark_price_trace_{stamp}.png"
fig3.savefig(price_path, dpi=220)
plt.close(fig3)
return rev_path, coi_path, price_path
def _run_with_args(args, compare_robust_override: bool | None = None):
compare_robust = (
bool(compare_robust_override)
if compare_robust_override is not None
else _truthy(os.environ.get("PHANTOM_BENCHMARK_COMPARE_ROBUST"))
)
baseline_modes = [False, True] if compare_robust else [bool(args.no_robust)]
base_overrides = {
"seed": args.seed,
"total_timesteps": args.total_timesteps,
"n_products": args.n_products,
"N": args.N,
"lambda_coi": args.lambda_coi,
"robust_radius": args.robust_radius,
"robust_points": args.robust_points,
"robust_rollouts": args.robust_rollouts,
"margin_floor": args.margin_floor,
"eta_ux": args.eta_ux,
"reward_profit_weight": args.reward_profit_weight,
"price_low": args.price_low,
"price_high": args.price_high,
"action_levels": args.action_levels,
"action_scale_low": args.action_scale_low,
"action_scale_high": args.action_scale_high,
"max_steps": args.max_steps,
"learning_rate": args.learning_rate,
"batch_size": args.batch_size,
"n_steps": args.n_steps,
"linear_warmup_steps": args.linear_warmup_steps,
"device": args.device,
}
tiers = _parse_list(args.tiers)
alpha_values = _parse_float_list(args.alpha_values)
eval_alpha_values = (
_parse_float_list(args.eval_alpha_values)
if str(getattr(args, "eval_alpha_values", "")).strip()
else []
)
_log(
"starting run "
+ json.dumps(
{
"tiers": tiers,
"alpha_values": alpha_values,
"eval_alpha_values": (
eval_alpha_values if eval_alpha_values else alpha_values
),
"episodes": int(args.episodes),
"total_timesteps": int(args.total_timesteps),
"device": str(args.device),
}
)
)
all_frames: list[pd.DataFrame] = []
all_traces: list[dict] = []
wandb_step_cursor = 0
for baseline_mode in baseline_modes:
overrides = dict(base_overrides)
overrides["baseline_mode"] = bool(baseline_mode)
cfg = TrainSpec.from_flat(
{k: v for k, v in overrides.items() if v is not None}
).to_flat_dict()
cfg["linear_warmup_steps"] = int(args.linear_warmup_steps)
mode_label = _mode_label_from_baseline(bool(baseline_mode))
_log(f"mode={mode_label}: begin")
df_mode, traces_mode, wandb_step_cursor = run_benchmark(
cfg,
tiers,
alpha_values,
args.episodes,
mode_label=mode_label,
step_cursor_start=wandb_step_cursor,
eval_alpha_values=eval_alpha_values,
)
_log(f"mode={mode_label}: complete ({len(df_mode)} rows)")
for trace in traces_mode:
trace["mode"] = mode_label
all_frames.append(df_mode)
all_traces.extend(traces_mode)
df = pd.concat(all_frames, ignore_index=True) if all_frames else pd.DataFrame()
traces = all_traces
out_dir = Path(args.output_dir)
out_dir.mkdir(parents=True, exist_ok=True)
stamp = datetime.now(timezone.utc).strftime("%Y%m%d_%H%M%S")
csv_path = out_dir / f"benchmark_{stamp}.csv"
trace_path = out_dir / f"benchmark_traces_{stamp}.json"
df.to_csv(csv_path, index=False)
trace_path.write_text(json.dumps(traces, indent=2))
rev_path, coi_path, price_path = _plot_outputs(df, traces, out_dir, stamp)
_log(f"artifacts written in {out_dir}")
if not df.empty:
best_idx = int(df["objective_score"].idxmax())
best = df.iloc[best_idx]
_log(
"BEST_TIER="
+ json.dumps(
{
"tier": best["tier"],
"mode": best.get("mode", "defended"),
"alpha": float(best["alpha"]),
"objective_score": float(best["objective_score"]),
"mean_revenue": float(best["mean_revenue"]),
"mean_coi": float(best["mean_coi"]),
}
)
)
_log(f"BENCHMARK_CSV={csv_path}")
_log(f"BENCHMARK_TRACES={trace_path}")
_log(f"BENCHMARK_PLOT_REVENUE={rev_path}")
_log(f"BENCHMARK_PLOT_COI={coi_path}")
_log(f"BENCHMARK_PLOT_PRICE={price_path}")
def run_cli(raw_args: list[str] | None = None):
configure_logging()
parser = argparse.ArgumentParser(description="PHANTOM benchmark orchestrator")
parser.add_argument("--project", default="capstone")
parser.add_argument("--tiers", default="static,surge,linear,qtable,ppo")
parser.add_argument("--alpha-values", default="0.0,0.3,0.6")
parser.add_argument("--eval-alpha-values", default="")
parser.add_argument("--episodes", type=int, default=10)
parser.add_argument("--output-dir", default="engine/studies/results")
parser.add_argument("--seed", type=int, default=42)
parser.add_argument("--total-timesteps", type=int, default=25_000)
parser.add_argument("--n-products", type=int, default=10)
parser.add_argument("--N", type=int, default=100)
parser.add_argument("--lambda-coi", type=float, default=0.2)
parser.add_argument("--robust-radius", type=float, default=0.15)
parser.add_argument("--robust-points", type=int, default=5)
parser.add_argument("--robust-rollouts", type=int, default=1)
parser.add_argument("--margin-floor", type=float, default=0.85)
parser.add_argument("--eta-ux", type=float, default=0.5)
parser.add_argument("--reward-profit-weight", type=float, default=1.0)
parser.add_argument("--price-low", type=float, default=10.0)
parser.add_argument("--price-high", type=float, default=150.0)
parser.add_argument("--action-levels", type=int, default=9)
parser.add_argument("--action-scale-low", type=float, default=0.8)
parser.add_argument("--action-scale-high", type=float, default=1.2)
parser.add_argument("--max-steps", type=int, default=100)
parser.add_argument("--learning-rate", type=float, default=3e-4)
parser.add_argument("--batch-size", type=int, default=256)
parser.add_argument("--n-steps", type=int, default=2048)
parser.add_argument("--linear-warmup-steps", type=int, default=800)
parser.add_argument("--device", type=str, default="auto")
parser.add_argument("--no-robust", action="store_true")
parser.add_argument("--no-wandb", action="store_true")
parser.add_argument("--offline", action="store_true")
parser.add_argument("--sweep-agent", action="store_true")
parser.add_argument("--sweep-id", type=str)
parser.add_argument("--count", type=int, default=0)
args = parser.parse_args(raw_args)
if args.sweep_agent:
if args.no_wandb or not HAS_WANDB:
raise ValueError("sweep agent requires wandb")
if not args.sweep_id:
raise ValueError("--sweep-id is required with --sweep-agent")
def _sweep_run():
run = wandb.init(mode="offline" if args.offline else "online")
try:
key_to_attr = {
"tiers": "tiers",
"alpha_values": "alpha_values",
"eval_alpha_values": "eval_alpha_values",
"episodes": "episodes",
"total_timesteps": "total_timesteps",
"lambda_coi": "lambda_coi",
"robust_radius": "robust_radius",
"robust_points": "robust_points",
"robust_rollouts": "robust_rollouts",
"ambiguity_radius": "robust_radius",
"ambiguity_points": "robust_points",
"ambiguity_rollouts": "robust_rollouts",
"eta_ux": "eta_ux",
"reward_profit_weight": "reward_profit_weight",
"learning_rate": "learning_rate",
"batch_size": "batch_size",
"n_steps": "n_steps",
"baseline_mode": "no_robust",
"no_robust": "no_robust",
"margin_floor": "margin_floor",
"device": "device",
}
for key in (
"tiers",
"alpha_values",
"eval_alpha_values",
"episodes",
"total_timesteps",
"lambda_coi",
"robust_radius",
"robust_points",
"robust_rollouts",
"ambiguity_radius",
"ambiguity_points",
"ambiguity_rollouts",
"eta_ux",
"reward_profit_weight",
"learning_rate",
"batch_size",
"n_steps",
"baseline_mode",
"no_robust",
"margin_floor",
"device",
):
if key in wandb.config:
setattr(args, key_to_attr[key], wandb.config[key])
_run_with_args(args)
finally:
if run is not None:
wandb.finish()
wandb.agent(
args.sweep_id,
function=_sweep_run,
count=args.count if args.count > 0 else None,
)
return
if args.no_wandb or not HAS_WANDB:
_run_with_args(args)
return
tiers = _parse_list(args.tiers)
alpha_values = _parse_float_list(args.alpha_values)
run_stamp = datetime.now(timezone.utc).strftime("%m%d-%H%M%S")
compare_enabled = _truthy(os.environ.get("PHANTOM_BENCHMARK_COMPARE_ROBUST"))
compare_tag = "defended-compare" if compare_enabled else "single-mode"
modes = (
[("baseline", True), ("defended", False)]
if compare_enabled
else [(_mode_label_from_baseline(bool(args.no_robust)), bool(args.no_robust))]
)
run_idx = 0
for tier in tiers:
for mode_label, baseline_mode in modes:
for alpha in alpha_values:
run_idx += 1
alpha_token = (
f"{float(alpha):.2f}".rstrip("0").rstrip(".").replace(".", "p")
)
tier_args = argparse.Namespace(**vars(args))
tier_args.tiers = tier
tier_args.alpha_values = str(float(alpha))
tier_args.no_robust = bool(baseline_mode)
run = wandb.init(
project=args.project,
name=(
f"benchmark-{tier}-{mode_label}-a{alpha_token}-{run_stamp}-{run_idx}"
),
tags=[
"benchmark",
compare_tag,
f"backend:{tier}",
f"mode:{mode_label}",
f"alpha:{alpha_token}",
],
config={
"run.kind": "benchmark",
"runtime/backend": tier,
"study/mode": mode_label,
"study/baseline_mode": float(baseline_mode),
"study/alpha": float(alpha),
"tiers": tier,
"alpha_values": str(float(alpha)),
"eval_alpha_values": args.eval_alpha_values,
"episodes": args.episodes,
"total_timesteps": args.total_timesteps,
"lambda_coi": args.lambda_coi,
"ambiguity_radius": args.robust_radius,
"ambiguity_points": args.robust_points,
"ambiguity_rollouts": args.robust_rollouts,
"margin_floor": args.margin_floor,
"baseline_mode": float(baseline_mode),
"eta_ux": args.eta_ux,
"reward_profit_weight": args.reward_profit_weight,
"learning_rate": args.learning_rate,
"device": args.device,
},
mode="offline" if args.offline else "online",
)
try:
_run_with_args(tier_args, compare_robust_override=False)
finally:
if run is not None:
wandb.finish()
if __name__ == "__main__":
run_cli()

View File

@@ -1,124 +0,0 @@
from sys import platform
import numpy as np
from .lib.demand import generate_demand_for_actor, estimate_demand
from .lib.behavior import get_adjusted_transitions, sample_behavior_from_transitions
from logging import INFO, getLogger
logger = getLogger(__name__)
logger.setLevel(INFO)
class MarketEngine:
"""implements separate demand distributions for humans and agents per Section 3.1.1"""
def __init__(
self,
alpha: float,
N: int,
human_params: tuple,
agent_params: tuple,
demand_distribution=np.random.normal,
noise_std: float = 1.0,
action_weights: dict | None = None,
):
# no defaults for D_H, D_A - force explicit experiment design
self.alpha = alpha
self.N = int(N)
self.Nagents = int(N * alpha)
self.Nhumans = int(N * (1 - alpha))
self.human_params = human_params
self.agent_params = agent_params
self.noise_std = noise_std
self.demand_dist = demand_distribution
self.action_weights = action_weights
def act(self, prices):
# generate separate demands d() per actor type
demand_h = generate_demand_for_actor(
prices,
self.human_params,
self.noise_std,
distribution_method=self.demand_dist,
)
demand_a = generate_demand_for_actor(
prices,
self.agent_params,
self.noise_std,
distribution_method=self.demand_dist,
)
human_transitions = get_adjusted_transitions(demand_h, human=True)
agent_transitions = get_adjusted_transitions(demand_a, human=False)
# sample N trajectories in parallel; each chain is independent so threads
# do not share state and numpy's per-call RNG is thread-safe
human_t = [
sample_behavior_from_transitions(human_transitions)
for _ in range(self.Nhumans)
]
agent_t = [
sample_behavior_from_transitions(agent_transitions)
for _ in range(self.Nagents)
]
# store trajectories for agent probability calculation
self.last_trajectories = human_t + agent_t
demand_proxy = estimate_demand(
self.last_trajectories,
self.action_weights,
normalize=True,
per_session=False,
)
raw_mix = ((1.0 - float(self.alpha)) * demand_h) + (
float(self.alpha) * demand_a
)
total_raw_demand = float(np.sum(raw_mix))
if not demand_proxy:
return {i: float(raw_mix[i]) for i in range(len(prices))}
if total_raw_demand <= 0.0:
return {i: 0.0 for i in range(len(prices))}
return {
i: total_raw_demand * float(demand_proxy.get(i, 0.0)) / 100.0
for i in range(len(prices))
}
def measure(self):
pass
class PricingEngine:
def __init__(
self,
) -> None:
pass
def act(self, demand):
return np.random.uniform(low=25, high=100, size=10)
class Limbo:
def __init__(self, platform, market) -> None:
self.platform_turn = True
self.platform = platform
self.market = market
self.output = None
def step(self):
if self.platform_turn:
self.output = self.platform.act(self.output)
else:
self.output = self.market.act(self.output)
self.platform_turn = not self.platform_turn
return self.output
def reset(self):
self.platform_turn = True
self.output = None
if __name__ == "__main__":
platform = PricingEngine()
market = MarketEngine(
alpha=0.3, N=100, human_params=(50, 10), agent_params=(45, 15)
)
limbo = Limbo(platform, market)
for _ in range(10):
limbo.step()

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@@ -1,3 +0,0 @@
from .robust import select_adversarial_alpha_jax, _JAX_OK
__all__ = ["select_adversarial_alpha_jax", "_JAX_OK"]

View File

@@ -1,197 +0,0 @@
"""JAX-accelerated robust inner loop for PHANTOM.
provides a drop-in replacement for the sequential alpha-candidate evaluation in
wrapper.py::_select_adversarial_alpha. the demand generation and reward
computation are vmapped over the K candidate alpha values so all candidates are
evaluated in a single vectorized pass instead of K sequential Python calls.
public surface:
select_adversarial_alpha_jax(candidates, prices, human_params, agent_params,
noise_std, n_sessions, n_products,
baseline_prices, lambda_coi, info_value,
reward_profit_weight, rng_key)
-> (best_alpha: float, rewards: np.ndarray)
falls back gracefully when JAX is unavailable.
"""
from __future__ import annotations
import numpy as np
try:
import jax
import jax.numpy as jnp
from jax import vmap, jit
_JAX_OK = True
except ImportError:
_JAX_OK = False
_JAX_RUNTIME_OK = True
def _demand_for_actor_jax(prices, mean, std, noise_std, key):
"""d(p;theta) = max(0, val - price + noise), normalized to sum 100."""
k1, k2 = jax.random.split(key)
val = jax.random.normal(k1, shape=prices.shape) * std + mean
noise = jax.random.normal(k2, shape=prices.shape) * noise_std
demand = jnp.maximum(0.0, val - prices + noise)
total = demand.sum()
return jnp.where(total > 0, demand / total * 100.0, demand)
def _reward_for_candidate(
alpha,
prices,
human_mean,
human_std,
agent_mean,
agent_std,
noise_std,
baseline_prices,
lambda_coi,
info_value,
reward_profit_weight,
key,
):
"""compute a scalar reward for a single alpha candidate (pure JAX, vmappable)."""
k_h, k_a = jax.random.split(key)
# mixed demand proxy: weighted sum of human and agent demand signals
demand_h = _demand_for_actor_jax(prices, human_mean, human_std, noise_std, k_h)
demand_a = _demand_for_actor_jax(prices, agent_mean, agent_std, noise_std, k_a)
demand = (1.0 - alpha) * demand_h + alpha * demand_a
revenue = jnp.dot(prices, demand)
floor_cost = jnp.dot(baseline_prices, demand)
profit = revenue - floor_cost
# agent_prob proxy: use alpha directly (no trajectory available in vectorized path)
coi_leakage = alpha * info_value
info_budget = jnp.maximum(floor_cost, 1.0)
coi_penalty = lambda_coi * coi_leakage * info_budget
return reward_profit_weight * profit - coi_penalty
if _JAX_OK:
# compile once; retracing only happens on shape/dtype changes
# 12 args: alpha, prices, h_mean, h_std, a_mean, a_std, noise_std,
# baseline_prices, lambda_coi, info_value, reward_profit_weight, key
_reward_batched = jit(
vmap(
_reward_for_candidate,
in_axes=(0, None, None, None, None, None, None, None, None, None, None, 0),
)
)
def select_adversarial_alpha_jax(
candidates: np.ndarray,
prices: np.ndarray,
human_params: tuple,
agent_params: tuple,
noise_std: float,
baseline_prices: np.ndarray,
lambda_coi: float,
info_value: float,
reward_profit_weight: float,
rng_seed: int = 0,
) -> tuple[float, np.ndarray]:
"""evaluate all alpha candidates in a single vmapped pass.
returns (best_alpha, rewards_array) where best_alpha minimizes reward
(worst case for the platform, driving robust policy training).
falls back to a pure-numpy sequential loop when JAX is unavailable so the
wrapper can call this function unconditionally.
"""
global _JAX_RUNTIME_OK
if not _JAX_OK or not _JAX_RUNTIME_OK:
return _fallback(
candidates,
prices,
human_params,
agent_params,
noise_std,
baseline_prices,
lambda_coi,
info_value,
reward_profit_weight,
)
try:
k = len(candidates)
key = jax.random.PRNGKey(rng_seed)
keys = jax.random.split(key, k)
rewards = np.asarray(
_reward_batched(
jnp.asarray(candidates, dtype=jnp.float32),
jnp.asarray(prices, dtype=jnp.float32),
float(human_params[0]),
float(human_params[1]),
float(agent_params[0]),
float(agent_params[1]),
float(noise_std),
jnp.asarray(baseline_prices, dtype=jnp.float32),
float(lambda_coi),
float(info_value),
float(reward_profit_weight),
keys,
)
)
best_idx = int(np.argmin(rewards))
return float(candidates[best_idx]), rewards
except Exception as exc:
# TPU contention / backend init failures can happen in distributed schedulers.
# Degrade to numpy path for the remainder of the process.
_JAX_RUNTIME_OK = False
print(f"PHANTOM_JAX_FALLBACK: {exc}")
return _fallback(
candidates,
prices,
human_params,
agent_params,
noise_std,
baseline_prices,
lambda_coi,
info_value,
reward_profit_weight,
)
def _fallback(
candidates,
prices,
human_params,
agent_params,
noise_std,
baseline_prices,
lambda_coi,
info_value,
reward_profit_weight,
):
"""numpy fallback matching the reward formula above."""
rewards = []
for alpha in candidates:
rng = np.random.default_rng()
val_h = rng.normal(*human_params, size=len(prices))
val_a = rng.normal(*agent_params, size=len(prices))
noise_h = rng.normal(0, noise_std, len(prices))
noise_a = rng.normal(0, noise_std, len(prices))
d_h = np.maximum(0, val_h - prices + noise_h)
d_a = np.maximum(0, val_a - prices + noise_a)
s_h, s_a = d_h.sum(), d_a.sum()
d_h = d_h / s_h * 100 if s_h > 0 else d_h
d_a = d_a / s_a * 100 if s_a > 0 else d_a
demand = (1.0 - alpha) * d_h + alpha * d_a
revenue = float(np.dot(prices, demand))
floor_cost = float(np.dot(baseline_prices, demand))
profit = revenue - floor_cost
coi_penalty = lambda_coi * alpha * info_value * max(floor_cost, 1.0)
rewards.append(reward_profit_weight * profit - coi_penalty)
rewards = np.array(rewards)
best_idx = int(np.argmin(rewards))
return float(candidates[best_idx]), rewards

View File

@@ -1,38 +0,0 @@
from __future__ import annotations
from importlib import import_module
_EXPORTS: dict[str, tuple[str, str]] = {
"estimate_demand": (".demand", "estimate_demand"),
"estimate_weighted_demand": (".demand", "estimate_weighted_demand"),
"generate_demand_for_actor": (".demand", "generate_demand_for_actor"),
"sample_behavior": (".behavior", "sample_behavior"),
"get_transition_models": (".behavior", "get_transition_models"),
"trajectory_to_events": (".behavior", "trajectory_to_events"),
"DashboardRenderer": (".render", "DashboardRenderer"),
"style_axis": (".render", "style_axis"),
"EconomicMetricsWrapper": (".wrappers", "EconomicMetricsWrapper"),
"MetricsCallback": (".callbacks", "MetricsCallback"),
"EvalMetricsCallback": (".callbacks", "EvalMetricsCallback"),
"ProviderBenchmark": (".providers", "ProviderBenchmark"),
"ProviderResult": (".providers", "ProviderResult"),
"BenchmarkConfig": (".providers", "BenchmarkConfig"),
"RandomBaseline": (".providers", "RandomBaseline"),
"SurgeBaseline": (".providers", "SurgeBaseline"),
"compute_uplift_coi": (".coi", "compute_uplift_coi"),
"extract_purchases": (".coi", "extract_purchases"),
"compute_agent_probability": (".coi", "compute_agent_probability"),
"EventQTable": (".discrete", "EventQTable"),
}
__all__ = sorted(_EXPORTS)
def __getattr__(name: str):
if name not in _EXPORTS:
raise AttributeError(f"module '{__name__}' has no attribute '{name}'")
module_name, attr_name = _EXPORTS[name]
module = import_module(module_name, package=__name__)
value = getattr(module, attr_name)
globals()[name] = value
return value

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@@ -1,190 +0,0 @@
import sys
from pathlib import Path
sys.path.insert(0, str(Path(__file__).parents[2]))
try:
from sim.rl.behavior_loader.models import (
BehaviorModel,
AgentBehaviorModel,
aggregate_event_transitions,
)
except ImportError:
BehaviorModel = None
AgentBehaviorModel = None
aggregate_event_transitions = None
import pandas as pd
import numpy as np
from .demand import generate_demand_for_actor
base_dir = Path(__file__).parents[2] / "experiments"
human_dir = str(base_dir / "collected_data")
agent_dir = str(base_dir / "agents" / "collected_data")
_cache = {} # lazy cache for models and base pivots
# cache keyed by (human: bool, condition_tuple) so we skip Kronecker re-expansion
# for repeated calls with the same demand condition inside the robustness inner loop
_transition_cache: dict = {}
def _get_base_pivot(human: bool):
if (
BehaviorModel is None
or AgentBehaviorModel is None
or aggregate_event_transitions is None
):
raise ImportError("behavior loader dependencies are unavailable")
key = "human" if human else "agent"
if key not in _cache:
model = BehaviorModel(human_dir) if human else AgentBehaviorModel(agent_dir)
mdp = model.build_MDP()
_cache[key] = pd.DataFrame(aggregate_event_transitions(mdp)).fillna(0.0)
return _cache[key]
def get_transition_models():
"""load human and agent transition models for agent probability calculation
returns:
tuple: (human_transitions, agent_transitions) as dicts of event->event->prob
"""
if (
BehaviorModel is None
or AgentBehaviorModel is None
or aggregate_event_transitions is None
):
raise ImportError("behavior loader dependencies are unavailable")
human_model = BehaviorModel(human_dir)
agent_model = AgentBehaviorModel(agent_dir)
human_mdp = human_model.build_MDP()
agent_mdp = agent_model.build_MDP()
human_trans = aggregate_event_transitions(human_mdp)
agent_trans = aggregate_event_transitions(agent_mdp)
return human_trans, agent_trans
def trajectory_to_events(trajectory: list) -> list:
"""extract event names from trajectory for KL divergence calculation
trajectories are in format 'eventName_product0', extract just eventName
"""
return [s.rsplit("_product", 1)[0] if "_product" in s else s for s in trajectory]
class _TransitionTable:
"""numpy-backed transition table; replaces per-step pandas .loc[] indexing.
the profiling hotspot was DataFrame.xs called ~4-16k times per outer step.
converting once to a dense float32 array with an int-keyed state index map
reduces each row lookup to a single array slice with no pandas overhead.
rows are pre-normalized so sampling requires no per-step division.
"""
__slots__ = ("matrix", "states", "state_index", "n_states")
def __init__(self, df: pd.DataFrame):
self.states: list[str] = df.index.tolist()
self.state_index: dict[str, int] = {s: i for i, s in enumerate(self.states)}
# float64 throughout: float32 row-sums can drift enough to break np.random.choice
mat = np.nan_to_num(
df.values.astype(np.float64), nan=0.0, posinf=0.0, neginf=0.0
)
mat = np.clip(mat, 0.0, None)
row_sums = mat.sum(axis=1)
# dead rows (all zero) get uniform distribution so sampling never receives NaN
dead = row_sums <= 0
mat[dead] = 1.0
row_sums[dead] = float(mat.shape[1])
mat = mat / row_sums[:, np.newaxis]
# final nan guard in case fp still drifts
np.nan_to_num(mat, nan=0.0, copy=False)
row_sums2 = mat.sum(axis=1, keepdims=True)
row_sums2[row_sums2 <= 0] = 1.0
self.matrix: np.ndarray = mat / row_sums2
self.n_states: int = len(self.states)
def adjust_behavior_to_condition(condition, transition_matrix):
# expand NxN transition matrix to (N*P)x(N*P) weighted by demand condition
condition = np.asarray(condition, dtype=float)
condition = np.nan_to_num(condition, nan=0.0, posinf=0.0, neginf=0.0)
condition = np.clip(condition, 0.0, None)
s = float(np.sum(condition))
cond_norm = (
condition / s
if np.isfinite(s) and s > 0
else np.full(len(condition), 1.0 / max(len(condition), 1), dtype=float)
)
n_products = len(condition)
base_vals = transition_matrix.values
base_cols, base_rows = (
transition_matrix.columns.tolist(),
transition_matrix.index.tolist(),
)
expanded = np.kron(base_vals, np.outer(cond_norm, cond_norm))
new_cols = [f"{c}_product{p}" for c in base_cols for p in range(n_products)]
new_rows = [f"{r}_product{p}" for r in base_rows for p in range(n_products)]
return pd.DataFrame(expanded, index=new_rows, columns=new_cols)
def get_adjusted_transitions(condition, human=True) -> _TransitionTable:
"""return a _TransitionTable for the given demand condition.
results are cached by (human, rounded-condition) so that repeated calls with
the same condition inside the robustness inner loop (K candidates, same prices)
skip the Kronecker expansion entirely.
"""
condition = np.asarray(condition, dtype=float)
# round to 4 significant digits for cache key stability
cache_key = (human, tuple(np.round(condition, 4).tolist()))
if cache_key in _transition_cache:
return _transition_cache[cache_key]
# prevent OOM by capping cache size
if len(_transition_cache) > 100:
_transition_cache.clear()
base_pivot = _get_base_pivot(human)
df = adjust_behavior_to_condition(condition, base_pivot)
table = _TransitionTable(df)
_transition_cache[cache_key] = table
return table
def clear_transition_cache():
"""drop cached transition tables; call between episodes if condition space is large."""
_transition_cache.clear()
def sample_behavior_from_transitions(table, max_len=40):
"""sample a Markov trajectory.
accepts _TransitionTable (fast path) or a legacy pandas DataFrame so existing
call sites that pass a DataFrame directly continue to work unchanged.
"""
if isinstance(table, pd.DataFrame):
table = _TransitionTable(table)
idx = np.random.randint(table.n_states)
trajectory = [table.states[idx]]
while len(trajectory) < max_len and "checkout" not in trajectory[-1]:
row = table.matrix[table.state_index[trajectory[-1]]]
idx = int(np.random.choice(table.n_states, p=row))
trajectory.append(table.states[idx])
return trajectory
def sample_behavior(condition, human=True, max_len=40):
table = get_adjusted_transitions(condition, human=human)
return sample_behavior_from_transitions(table, max_len=max_len)
if __name__ == "__main__":
t = sample_behavior(generate_demand_for_actor(np.array([10, 20, 30])), human=True)
print(t)
t = sample_behavior(generate_demand_for_actor(np.array([10, 20, 30])), human=False)
print(t)

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@@ -1,259 +0,0 @@
"""Training callbacks with algorithm-agnostic metric extraction."""
from typing import Any
from stable_baselines3.common.callbacks import BaseCallback, EvalCallback
import numpy as np
from ..telemetry.wandb import get_wandb_module
class MetricsCallback(BaseCallback):
"""Collects interval train metrics from env info dictionaries."""
def __init__(
self,
log_histograms: bool = False,
log_freq: int = 100,
hist_freq: int = 500,
step_offset: int = 0,
verbose: int = 0,
):
super().__init__(verbose)
self.log_histograms = log_histograms
self.log_freq = max(1, int(log_freq))
self.hist_freq = max(1, int(hist_freq))
self.step_offset = max(0, int(step_offset))
self._wandb = get_wandb_module()
self._wandb_live = bool(self._wandb is not None and self._wandb.run is not None)
self._price_samples: list[float] = []
self._demand_samples: list[float] = []
self._window_sums = {
"train/revenue_mean": 0.0,
"train/margin_mean": 0.0,
"train/coi_level_mean": 0.0,
"train/regret_mean": 0.0,
"train/profit_mean": 0.0,
"train/agent_prob": 0.0,
"train/alpha_adv": 0.0,
"train/ux_penalty": 0.0,
"train/volatility": 0.0,
"train/coi_mix": 0.0,
"train/coi_base": 0.0,
"train/coi_leakage": 0.0,
"train/coi_penalty": 0.0,
}
self._window_count = 0
self.events: list[dict[str, Any]] = []
def _accumulate(self, info: dict[str, Any]) -> None:
econ = info.get("economics")
if not isinstance(econ, dict):
return
self._window_sums["train/revenue_mean"] += float(econ.get("revenue", 0.0))
self._window_sums["train/margin_mean"] += float(econ.get("margin", 0.0))
self._window_sums["train/coi_level_mean"] += float(econ.get("coi_level", 0.0))
self._window_sums["train/regret_mean"] += float(econ.get("regret", 0.0))
if "profit" in econ:
self._window_sums["train/profit_mean"] += float(econ.get("profit", 0.0))
if "agent_prob" in econ:
self._window_sums["train/agent_prob"] += float(econ.get("agent_prob", 0.0))
if "alpha_adv" in econ:
self._window_sums["train/alpha_adv"] += float(econ.get("alpha_adv", 0.0))
if "ux_penalty" in econ:
self._window_sums["train/ux_penalty"] += float(econ.get("ux_penalty", 0.0))
if "volatility" in econ:
self._window_sums["train/volatility"] += float(econ.get("volatility", 0.0))
if "coi_mix" in econ:
self._window_sums["train/coi_mix"] += float(econ.get("coi_mix", 0.0))
if "coi_base" in econ:
self._window_sums["train/coi_base"] += float(econ.get("coi_base", 0.0))
if "coi_leakage" in econ:
self._window_sums["train/coi_leakage"] += float(
econ.get("coi_leakage", 0.0)
)
if "coi_penalty" in econ:
self._window_sums["train/coi_penalty"] += float(
econ.get("coi_penalty", 0.0)
)
self._window_count += 1
def _accumulate_histograms(self, info: dict[str, Any]) -> None:
if not self.log_histograms:
return
for key in ("effective_prices", "prices"):
if key not in info:
continue
try:
values = np.asarray(info.get(key), dtype=float).reshape(-1)
except Exception:
continue
if values.size <= 0:
continue
finite_values = values[np.isfinite(values)]
if finite_values.size > 0:
self._price_samples.extend(finite_values.tolist())
break
if "demand" in info:
try:
demand_values = np.asarray(info.get("demand"), dtype=float).reshape(-1)
except Exception:
demand_values = np.array([], dtype=float)
if demand_values.size > 0:
finite_demand = demand_values[np.isfinite(demand_values)]
if finite_demand.size > 0:
self._demand_samples.extend(finite_demand.tolist())
def _flush_histograms(self, step: int, force: bool = False) -> None:
if not self.log_histograms:
return
if not force and step % self.hist_freq != 0:
return
if not self._price_samples and not self._demand_samples:
return
if self._wandb is None:
self._price_samples.clear()
self._demand_samples.clear()
return
payload: dict[str, Any] = {}
if self._price_samples:
payload["train/price_dist"] = self._wandb.Histogram(
np.asarray(self._price_samples, dtype=np.float32)
)
if self._demand_samples:
payload["train/demand_dist"] = self._wandb.Histogram(
np.asarray(self._demand_samples, dtype=np.float32)
)
if payload and self._wandb_live:
try:
self._wandb.log(payload, step=self.step_offset + int(step))
except Exception:
self._wandb_live = False
self._price_samples.clear()
self._demand_samples.clear()
def _flush(self, step: int, *, force_hist: bool = False) -> None:
if self._window_count > 0:
denom = float(self._window_count)
payload = {
key: (value / denom)
for key, value in self._window_sums.items()
if value != 0.0
or key
in {
"train/revenue_mean",
"train/margin_mean",
"train/coi_level_mean",
"train/regret_mean",
}
}
payload["train/global_step"] = int(step)
if self._wandb_live:
try:
self._wandb.log(dict(payload), step=self.step_offset + int(step))
except Exception:
self._wandb_live = False
self.events.append(payload)
else:
self.events.append(payload)
for key in self._window_sums:
self._window_sums[key] = 0.0
self._window_count = 0
self._flush_histograms(step=step, force=force_hist)
def _on_step(self) -> bool:
for info in self.locals.get("infos", []):
if isinstance(info, dict):
self._accumulate(info)
self._accumulate_histograms(info)
if self.num_timesteps % self.log_freq == 0:
self._flush(step=self.num_timesteps)
return True
def _on_training_end(self) -> None:
self._flush(step=self.num_timesteps, force_hist=True)
class EvalMetricsCallback(EvalCallback):
"""Deterministic evaluation collector detached from logging backends."""
def __init__(
self,
eval_env,
eval_freq: int = 1000,
n_eval_episodes: int = 5,
step_offset: int = 0,
**kwargs,
):
super().__init__(
eval_env, eval_freq=eval_freq, n_eval_episodes=n_eval_episodes, **kwargs
)
self.step_offset = max(0, int(step_offset))
self._wandb = get_wandb_module()
self._wandb_live = bool(self._wandb is not None and self._wandb.run is not None)
self._eval_stats: dict[str, list[float]] = {
"eval/revenue_mean": [],
"eval/margin_mean": [],
"eval/coi_level_mean": [],
"eval/coi_leakage_mean": [],
"eval/volatility_mean": [],
"eval/agent_prob_mean": [],
}
self.events: list[dict[str, float | int]] = []
def _on_step(self) -> bool:
result = super()._on_step()
if self.n_calls % self.eval_freq == 0 and hasattr(self, "last_mean_reward"):
payload: dict[str, float | int] = {
"eval/reward_mean": float(self.last_mean_reward),
"train/global_step": int(self.num_timesteps),
}
for key, values in self._eval_stats.items():
payload[key] = float(np.mean(values)) if values else 0.0
if self._wandb_live:
try:
self._wandb.log(
dict(payload),
step=self.step_offset + int(self.num_timesteps),
)
except Exception:
self._wandb_live = False
self.events.append(payload)
else:
self.events.append(payload)
for values in self._eval_stats.values():
values.clear()
return result
def _log_success_callback(self, locals_: dict, globals_: dict) -> None:
# called after each eval episode
info = locals_.get("info", {})
econ = info.get("economics") if isinstance(info, dict) else None
if not isinstance(econ, dict):
return
self._eval_stats["eval/revenue_mean"].append(float(econ.get("revenue", 0.0)))
self._eval_stats["eval/margin_mean"].append(float(econ.get("margin", 0.0)))
self._eval_stats["eval/coi_level_mean"].append(
float(econ.get("coi_level", 0.0))
)
self._eval_stats["eval/coi_leakage_mean"].append(
float(econ.get("coi_leakage", 0.0))
)
self._eval_stats["eval/volatility_mean"].append(
float(econ.get("volatility", 0.0))
)
self._eval_stats["eval/agent_prob_mean"].append(
float(econ.get("agent_prob", 0.0))
)

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@@ -1,79 +0,0 @@
import numpy as np
from typing import Dict
def compute_agent_probability(
trajectory: list,
human_transitions: Dict,
agent_transitions: Dict,
temperature: float = 1.0,
) -> float:
"""estimate agent probability via KL divergence between trajectory transitions and reference models
compares empirical trajectory transition distribution to human/agent prototypes
args:
trajectory: list of state/event strings from session
human_transitions: reference transition dict from human MDP (event->event->prob)
agent_transitions: reference transition dict from agent MDP (event->event->prob)
returns:
agent probability in [0, 1] via softmax over KL divergences
"""
if len(trajectory) < 2:
return 0.0 # insufficient data, assume human
# build empirical transition distribution from trajectory
trans_counts = {}
for s, s_next in zip(trajectory[:-1], trajectory[1:]):
if s not in trans_counts:
trans_counts[s] = {}
trans_counts[s][s_next] = trans_counts[s].get(s_next, 0) + 1
# normalize to probabilities
empirical = {}
for s, nxt in trans_counts.items():
total = sum(nxt.values())
empirical[s] = {s_n: cnt / total for s_n, cnt in nxt.items()}
# compute KL divergence to each prototype
def kl_div(p_dist: Dict, q_dist: Dict) -> float:
eps = 1e-10
# aggregate over all source states in empirical dist
kl = 0.0
for s in p_dist:
if s not in q_dist:
continue # skip states not in reference
p_trans, q_trans = p_dist[s], q_dist[s]
for k in p_trans:
p_val = p_trans[k] + eps
q_val = q_trans.get(k, 0.0) + eps
kl += p_val * np.log(p_val / q_val)
return kl
kl_human = kl_div(empirical, human_transitions)
kl_agent = kl_div(empirical, agent_transitions)
# convert to probability via softmax (lower KL = higher prob)
t = float(max(temperature, 1e-6))
exp_h = np.exp(-kl_human / t)
exp_a = np.exp(-kl_agent / t)
return float(exp_a / (exp_h + exp_a + 1e-10))
def extract_purchases(trajectories: list) -> Dict[int, int]:
purchases: Dict[int, int] = {}
for traj in trajectories:
if traj and "checkout" in traj[-1] and "_product" in traj[-1]:
prod_id = int(traj[-1].rsplit("_product", 1)[1])
purchases[prod_id] = purchases.get(prod_id, 0) + 1
return purchases
def compute_uplift_coi(
prices: np.ndarray, purchases: Dict[int, int], baseline_prices: np.ndarray
) -> float:
# TODO: consider view-weighted fractional purchase for denser signal
return float(
sum(max(0.0, prices[k] - baseline_prices[k]) * n for k, n in purchases.items())
)

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@@ -1,120 +0,0 @@
import numpy as np
CATEGORY_WEIGHTS = {"cart": 4.0, "dwell": 2.0, "nav": 1.0, "filter": 0.5}
ACTION_CATEGORIES = {
"cart": {"add_item", "add_to_cart", "remove", "checkout", "purchase"},
"dwell": {"hover_title", "hover_paragraph", "hover_link"},
"nav": {"page_view", "view_item", "view", "learn_more"},
"filter": {"search", "filter_date", "filter_price", "sort"},
}
DEFAULT_ACTION_WEIGHTS = {
a: CATEGORY_WEIGHTS[c] for c, actions in ACTION_CATEGORIES.items() for a in actions
}
def generate_demand_for_actor(
prices: np.ndarray,
params: tuple,
noise_std: float = 1.0,
distribution_method=np.random.normal,
normalize: bool = False,
) -> np.ndarray:
"""d(p;0) = max(0, valuation - price) + epsi for single actor type
params: (mean, std) for valuation distribution D_H or D_A"""
val = distribution_method(*params, size=len(prices))
noise = distribution_method(0, noise_std, len(prices))
demand = np.maximum(0, val - prices + noise)
if not normalize:
return demand
total = np.sum(demand)
return demand / total * 100 if total > 0 else demand
def estimate_demand(
trajectories,
action_weights=None,
*,
normalize: bool = False,
per_session: bool = True,
):
return estimate_weighted_demand(
trajectories,
action_weights,
normalize=normalize,
per_session=per_session,
)
def _parse_event_state(state: str):
if "_product" not in state:
return state, None
action, raw_pid = state.rsplit("_product", 1)
return action, int(raw_pid) if raw_pid.isdigit() else None
def _weight_for_action(action: str, action_weights: dict) -> float:
if action in action_weights:
return action_weights[action]
if action.startswith("hover"):
return CATEGORY_WEIGHTS["dwell"]
if action.startswith("filter") or action in {"search", "sort"}:
return CATEGORY_WEIGHTS["filter"]
if action.startswith("add") or action in {"checkout", "purchase", "remove"}:
return CATEGORY_WEIGHTS["cart"]
return CATEGORY_WEIGHTS["nav"]
def estimate_weighted_demand(
trajectories,
action_weights=None,
*,
normalize: bool = False,
per_session: bool = True,
):
action_weights = (
DEFAULT_ACTION_WEIGHTS if action_weights is None else action_weights
)
scores = {}
for traj in trajectories:
for state in traj:
action, product_id = _parse_event_state(state)
if product_id is None:
continue
w = _weight_for_action(action, action_weights)
if w <= 0:
continue
scores[product_id] = scores.get(product_id, 0.0) + w
if not scores:
return {}
if per_session and len(trajectories) > 0:
inv_n = 1.0 / float(len(trajectories))
scores = {pid: score * inv_n for pid, score in scores.items()}
if not normalize:
return scores
total = float(sum(scores.values()))
if total <= 0:
return {}
return {pid: (score / total) * 100.0 for pid, score in scores.items()}
# Example usage
if __name__ == "__main__":
np.random.seed(42)
prices = np.array([20.0, 35.0, 50.0, 65.0])
# demo actor-specific demands
human_params, agent_params = (50, 10), (45, 15)
demand_h = generate_demand_for_actor(prices, human_params)
demand_a = generate_demand_for_actor(prices, agent_params)
print("Human Demand:", demand_h)
print("Agent Demand:", demand_a)
from .behavior import sample_behavior
N, alpha = 200, 0.3
n_h, n_a = int(N * (1 - alpha)), int(N * alpha)
human_t = [sample_behavior(demand_h, human=True) for _ in range(n_h)]
agent_t = [sample_behavior(demand_a, human=False) for _ in range(n_a)]
demand_estimate = estimate_demand(human_t + agent_t)
print("Estimated Demand from Behavior:", demand_estimate)

View File

@@ -1,70 +0,0 @@
from collections import defaultdict
import gymnasium as gym
from gymnasium import spaces
import numpy as np
class DiscretePriceActionWrapper(gym.ActionWrapper):
def __init__(
self,
env: gym.Env,
n_levels: int = 9,
min_scale: float = 0.8,
max_scale: float = 1.2,
):
super().__init__(env)
self.scales = np.linspace(min_scale, max_scale, n_levels, dtype=np.float32)
self.action_space = spaces.Discrete(n_levels)
def action(self, action: int):
scale = float(self.scales[int(action)])
cur = np.asarray(self.env.unwrapped._prices, dtype=np.float32)
lo, hi = self.env.unwrapped.price_bounds
return np.clip(cur * scale, lo, hi).astype(np.float32)
class EventQTable:
def __init__(
self,
n_actions: int,
n_products: int,
price_bounds: tuple,
lr: float = 0.1,
gamma: float = 0.99,
n_bins: int = 6,
):
self.n_actions = int(n_actions)
self.n_products = int(n_products)
self.lr = float(lr)
self.gamma = float(gamma)
self.q = defaultdict(lambda: np.zeros(self.n_actions, dtype=np.float32))
lo, hi = price_bounds
self.demand_bins = np.linspace(0.0, 100.0, n_bins + 1)[1:-1]
self.price_bins = np.linspace(lo, hi, n_bins + 1)[1:-1]
def encode(self, obs: np.ndarray) -> tuple:
obs = np.asarray(obs, dtype=np.float32)
d = obs[: self.n_products]
p = obs[self.n_products : 2 * self.n_products]
d_mean = float(np.mean(d)) if d.size else 0.0
d_std = float(np.std(d)) if d.size else 0.0
p_mean = float(np.mean(p)) if p.size else 0.0
return (
int(np.digitize(d_mean, self.demand_bins)),
int(np.digitize(d_std, self.demand_bins)),
int(np.digitize(p_mean, self.price_bins)),
)
def act(self, obs: np.ndarray, eps: float = 0.0) -> tuple[int, tuple]:
s = self.encode(obs)
if np.random.random() < eps:
return int(np.random.randint(self.n_actions)), s
return int(np.argmax(self.q[s])), s
def update(self, s: tuple, a: int, r: float, s2: tuple, done: bool):
target = r + (0.0 if done else self.gamma * float(np.max(self.q[s2])))
self.q[s][a] += self.lr * (target - self.q[s][a])
def predict(self, obs: np.ndarray, deterministic: bool = True):
a, _ = self.act(obs, 0.0 if deterministic else 0.05)
return a, None

View File

@@ -1,185 +0,0 @@
"""Provider benchmarking - compare pricing strategies across contamination levels."""
from dataclasses import dataclass, field
from typing import Callable, Any
import numpy as np
import pandas as pd
try:
import wandb
HAS_WANDB = True
except ImportError:
HAS_WANDB = False
class RandomBaseline:
"""uniform random action selection as a lower-bound baseline"""
def __init__(self, n_actions: int):
self.n = n_actions
def __call__(self, obs):
return int(np.random.randint(self.n))
def predict(self, obs, **kw):
return self(obs), None
class SurgeBaseline:
"""heuristic surge pricing: boost price when demand is above threshold, discount when below.
matches the naive pricing rule from thesis Section 3.3.2"""
def __init__(
self, n_actions: int, high_threshold: float = 60.0, low_threshold: float = 30.0
):
self.n = n_actions
self.mid = n_actions // 2 # identity action (scale ~1.0)
self.high_t = high_threshold
self.low_t = low_threshold
def __call__(self, obs):
obs = np.asarray(obs, dtype=np.float32)
n_prod = len(obs) // 2
demand_mean = float(np.mean(obs[:n_prod])) if n_prod > 0 else 0.0
if demand_mean >= self.high_t:
return min(self.mid + 2, self.n - 1) # surge: two levels above identity
if demand_mean <= self.low_t:
return max(self.mid - 2, 0) # discount: two levels below identity
return self.mid # hold
def predict(self, obs, **kw):
return self(obs), None
@dataclass
class ProviderResult:
"""Single benchmark result for one provider at one alpha level."""
name: str
alpha: float
total_revenue: float
mean_revenue: float
coi_level: float
coi_preserved_pct: float # vs alpha=0 baseline
margin_integrity: float
regret: float
episodes: int
@dataclass
class BenchmarkConfig:
"""Configuration for provider benchmark runs."""
n_episodes: int = 100
alpha_range: list[float] = field(default_factory=lambda: [0.0, 0.1, 0.3, 0.5])
baseline_name: str = "fixed"
class ProviderBenchmark:
"""Compare pricing providers to prove margin preservation across contamination levels.
Usage:
def env_factory(alpha):
return EconomicMetricsWrapper(PHANTOM(alpha=alpha))
providers = {
"fixed": lambda obs: np.ones(10) * 50,
"learned": model.predict,
}
benchmark = ProviderBenchmark(env_factory, providers)
results = benchmark.run()
print(benchmark.summary_table())
"""
def __init__(
self,
env_factory: Callable[[float], Any],
providers: dict[str, Callable],
config: BenchmarkConfig | None = None,
):
self.env_factory = env_factory # fn(alpha) -> wrapped env
self.providers = providers # {name: fn(obs) -> action}
self.config = config or BenchmarkConfig()
self.results: list[ProviderResult] = []
def run(self) -> list[ProviderResult]:
"""Run benchmark across all providers and alpha levels."""
baseline_coi: dict[str, float] = {} # {provider: coi at alpha=0}
for alpha in self.config.alpha_range:
env = self.env_factory(alpha)
for name, policy_fn in self.providers.items():
revenues, coi_levels, margins = [], [], []
for _ in range(self.config.n_episodes):
obs, _ = env.reset()
episode_revenue = 0.0
done = False
while not done:
action = policy_fn(obs)
# handle sb3 model.predict returning tuple
if isinstance(action, tuple):
action = action[0]
obs, reward, term, trunc, info = env.step(action)
done = term or trunc
econ = info.get("economics", {})
episode_revenue += econ.get("revenue", 0)
coi_levels.append(econ.get("coi_level", 0))
margins.append(econ.get("margin", 0))
revenues.append(episode_revenue)
mean_coi = np.mean(coi_levels) if coi_levels else 0.0
if alpha == 0.0:
baseline_coi[name] = mean_coi
base = baseline_coi.get(name, mean_coi)
coi_preserved = mean_coi / base if base > 0 else 1.0
result = ProviderResult(
name=name,
alpha=alpha,
total_revenue=float(np.sum(revenues)),
mean_revenue=float(np.mean(revenues)),
coi_level=mean_coi,
coi_preserved_pct=coi_preserved * 100,
margin_integrity=float(np.mean(margins)) if margins else 0.0,
regret=0.0, # compute vs optimal if known
episodes=self.config.n_episodes,
)
self.results.append(result)
# log to wandb if available
if HAS_WANDB and wandb.run is not None:
try:
wandb.log(
{
f"benchmark/{name}/revenue": result.mean_revenue,
f"benchmark/{name}/coi_preserved": result.coi_preserved_pct,
f"benchmark/{name}/margin": result.margin_integrity,
"benchmark/alpha": alpha,
}
)
except Exception:
pass
return self.results
def to_dataframe(self) -> pd.DataFrame:
"""Convert results to pandas DataFrame."""
return pd.DataFrame([r.__dict__ for r in self.results])
def summary_table(self) -> pd.DataFrame:
"""Pivot table: providers x alpha with revenue/COI metrics."""
df = self.to_dataframe()
return df.pivot_table(
index="name",
columns="alpha",
values=["mean_revenue", "coi_preserved_pct", "margin_integrity"],
aggfunc="mean",
)

View File

@@ -1,165 +0,0 @@
"""rendering logic for PHANTOM environment dashboard"""
import numpy as np
import matplotlib.pyplot as plt
from matplotlib.gridspec import GridSpec
def style_axis(ax, title: str = None, xlabel: str = None, ylabel: str = None):
ax.spines["top"].set_visible(False)
ax.spines["right"].set_visible(False)
if title:
ax.set_title(title, fontsize=11, fontweight="bold", pad=8)
if xlabel:
ax.set_xlabel(xlabel, fontsize=9)
if ylabel:
ax.set_ylabel(ylabel, fontsize=9)
class DashboardRenderer:
"""stateful renderer for PHANTOM market dynamics visualization"""
def __init__(self):
self.fig = None
self.gs = None
def render(self, env) -> None:
if self.fig is None:
plt.ion()
self.fig = plt.figure(figsize=(14, 10))
self.gs = GridSpec(
3,
3,
figure=self.fig,
hspace=0.35,
wspace=0.3,
left=0.07,
right=0.95,
top=0.92,
bottom=0.08,
)
plt.show(block=False)
self.fig.clear()
self.fig.suptitle(
f"PHANTOM Market Dynamics [t={env._step_count}, a={env.alpha:.2f}]",
fontsize=14,
fontweight="bold",
)
demand_mat = np.array(env._demand_history).T
price_mat = np.array(env._price_history).T
elasticity = env._compute_elasticity()
self._render_scatter(env)
self._render_elasticity_bar(env, elasticity)
self._render_session_pie(env)
self._render_price_heatmap(price_mat)
self._render_demand_heatmap(demand_mat)
self._render_correlation(env.n_products, price_mat, demand_mat)
self._render_revenue(env)
self.fig.canvas.draw_idle()
self.fig.canvas.flush_events()
def _render_scatter(self, env):
ax = self.fig.add_subplot(self.gs[0, 0])
prices_flat = np.array(env._price_history).flatten()
demands_flat = np.array(env._demand_history).flatten()
product_ids = np.tile(np.arange(env.n_products), len(env._price_history))
ax.scatter(
prices_flat,
demands_flat,
c=product_ids,
cmap="plasma",
alpha=0.6,
s=15,
edgecolors="none",
)
if len(prices_flat) > 1:
z = np.polyfit(prices_flat, demands_flat, 1)
p_line = np.linspace(prices_flat.min(), prices_flat.max(), 50)
ax.plot(p_line, np.polyval(z, p_line), "--", lw=1.5, alpha=0.8)
style_axis(ax, "Price-Demand Relationship", "Price ($)", "Demand")
def _render_elasticity_bar(self, env, elasticity):
ax = self.fig.add_subplot(self.gs[0, 1])
ax.barh(range(env.n_products), elasticity, alpha=0.8)
ax.axvline(0, lw=0.8, alpha=0.5)
ax.axvline(-1, lw=1, ls="--", alpha=0.5)
ax.set_yticks(range(env.n_products))
ax.set_yticklabels([f"P{i}" for i in range(env.n_products)], fontsize=7)
style_axis(ax, "Price Elasticity", "(dQ/dP)(P/Q)", None)
def _render_session_pie(self, env):
ax = self.fig.add_subplot(self.gs[0, 2])
n_h, n_a = env.market.Nhumans, env.market.Nagents
wedges, _ = ax.pie(
[n_h, n_a], startangle=90, wedgeprops={"linewidth": 2, "edgecolor": "white"}
)
ax.legend(
wedges,
[f"H ({n_h})", f"A ({n_a})"],
loc="lower center",
fontsize=8,
frameon=False,
bbox_to_anchor=(0.5, -0.05),
)
ax.set_title("Session Mix", fontsize=11, fontweight="bold")
def _render_price_heatmap(self, price_mat):
ax = self.fig.add_subplot(self.gs[1, :2])
im = ax.imshow(price_mat, aspect="auto", cmap="viridis", origin="lower")
style_axis(ax, "Price Heatmap P(product, t)", "Step", "Product")
cbar = self.fig.colorbar(im, ax=ax, fraction=0.03, pad=0.02)
cbar.set_label("$", fontsize=8)
def _render_demand_heatmap(self, demand_mat):
ax = self.fig.add_subplot(self.gs[1, 2])
im = ax.imshow(demand_mat, aspect="auto", cmap="Blues", origin="lower")
style_axis(ax, "Demand Q(product, t)", "Step", None)
self.fig.colorbar(im, ax=ax, fraction=0.046, pad=0.02)
def _render_correlation(self, n_products, price_mat, demand_mat):
ax = self.fig.add_subplot(self.gs[2, 0])
if price_mat.shape[1] > 2:
corr = np.corrcoef(price_mat, demand_mat)[:n_products, n_products:]
im = ax.imshow(corr, cmap="RdBu", vmin=-1, vmax=1, aspect="auto")
ax.set_xticks(range(n_products))
ax.set_yticks(range(n_products))
ax.set_xticklabels([f"Q{i}" for i in range(n_products)], fontsize=6)
ax.set_yticklabels([f"P{i}" for i in range(n_products)], fontsize=6)
self.fig.colorbar(im, ax=ax, fraction=0.046, pad=0.02)
style_axis(ax, "Price-Demand Correlation", None, None)
def _render_revenue(self, env):
ax = self.fig.add_subplot(self.gs[2, 1:])
n_steps = len(env._revenue_history)
demand_std = [np.std(d) for d in env._demand_history]
ax.fill_between(range(n_steps), env._revenue_history, alpha=0.3)
ax.plot(env._revenue_history, linewidth=2, label="Revenue")
ax.set_xlim(0, max(n_steps, 1))
ax.set_ylim(0, max(env._revenue_history) * 1.1 if env._revenue_history else 1)
ax2 = ax.twinx()
ax2.plot(
range(n_steps),
demand_std,
linewidth=2,
ls="-",
alpha=0.9,
label="sigma(Demand)",
)
d_min, d_max = min(demand_std), max(demand_std)
margin = (d_max - d_min) * 0.2 if d_max > d_min else 0.5
ax2.set_ylim(max(0, d_min - margin), d_max + margin)
ax2.set_ylabel("Demand sigma", fontsize=9)
style_axis(ax, "Revenue & Demand Dispersion", "Step", "Revenue ($)")
ax.legend(loc="upper left", fontsize=7, frameon=False)
ax2.legend(loc="upper right", fontsize=7, frameon=False)
def close(self):
if self.fig:
plt.close(self.fig)
self.fig = None

View File

@@ -1,101 +0,0 @@
from __future__ import annotations
from dataclasses import dataclass
from typing import Protocol
import numpy as np
class PolicyLike(Protocol):
def predict(self, obs: np.ndarray, deterministic: bool = True): ...
class StaticPolicy:
def __init__(self, n_actions: int):
self._action = int(max(0, n_actions // 2))
def predict(self, obs: np.ndarray, deterministic: bool = True):
return self._action, None
class SurgePolicy:
def __init__(
self,
n_actions: int,
n_products: int,
high_threshold: float = 60.0,
low_threshold: float = 30.0,
):
self.n_actions = int(n_actions)
self.n_products = int(n_products)
self.mid = self.n_actions // 2
self.high_t = float(high_threshold)
self.low_t = float(low_threshold)
def predict(self, obs: np.ndarray, deterministic: bool = True):
obs_arr = np.asarray(obs, dtype=np.float32)
demand = obs_arr[: self.n_products]
demand_mean = float(np.mean(demand)) if demand.size > 0 else 0.0
if demand_mean >= self.high_t:
return min(self.mid + 2, self.n_actions - 1), None
if demand_mean <= self.low_t:
return max(self.mid - 2, 0), None
return self.mid, None
@dataclass
class LinearElasticityPolicy:
n_actions: int
n_products: int
price_low: float
price_high: float
def __post_init__(self):
self.n_actions = int(self.n_actions)
self.n_products = int(self.n_products)
self.price_low = float(self.price_low)
self.price_high = float(self.price_high)
self._target_price = 0.5 * (self.price_low + self.price_high)
self._action_scales = np.linspace(0.8, 1.2, self.n_actions)
def fit(self, env, warmup_steps: int = 800, seed: int = 42):
rng = np.random.default_rng(int(seed))
obs, _ = env.reset(seed=int(seed))
prices: list[float] = []
demands: list[float] = []
for _ in range(int(max(10, warmup_steps))):
action = int(rng.integers(0, self.n_actions))
obs, _, term, trunc, info = env.step(action)
done = bool(term or trunc)
p = np.asarray(info.get("prices", []), dtype=np.float32)
d = np.asarray(info.get("demand", []), dtype=np.float32)
if p.size > 0 and d.size > 0:
prices.append(float(np.mean(p)))
demands.append(float(np.mean(d)))
if done:
obs, _ = env.reset()
if len(prices) < 8:
self._target_price = 0.5 * (self.price_low + self.price_high)
return self
slope, intercept = np.polyfit(np.asarray(prices), np.asarray(demands), 1)
if slope < -1e-6:
p_star = -intercept / (2.0 * slope)
self._target_price = float(np.clip(p_star, self.price_low, self.price_high))
else:
self._target_price = 0.5 * (self.price_low + self.price_high)
return self
def predict(self, obs: np.ndarray, deterministic: bool = True):
obs_arr = np.asarray(obs, dtype=np.float32)
cur_prices = obs_arr[self.n_products : 2 * self.n_products]
cur_mean = (
float(np.mean(cur_prices)) if cur_prices.size > 0 else self._target_price
)
scale = self._target_price / max(cur_mean, 1e-6)
action = int(np.argmin(np.abs(self._action_scales - scale)))
return int(np.clip(action, 0, self.n_actions - 1)), None

View File

@@ -1,104 +0,0 @@
"""Economic metrics wrapper - calculates thesis-aligned KPIs and injects into info dict."""
import gymnasium as gym
import numpy as np
class EconomicMetricsWrapper(gym.Wrapper):
"""Calculates thesis-aligned economic metrics per step, injects into info.
Metrics follow thesis definitions:
- COI level: E[P] - p_min (Definition 1)
- Margin: (avg_price - p_min) / avg_price
- Regret: 1 - (revenue / baseline_revenue)
"""
def __init__(
self, env: gym.Env, p_min: float = 10.0, baseline_revenue: float | None = None
):
super().__init__(env)
self.p_min = p_min
self.baseline_revenue = baseline_revenue
self._price_history: list[np.ndarray] = []
self._revenue_history: list[float] = []
def reset(self, **kwargs):
obs, info = self.env.reset(**kwargs)
self._price_history = []
self._revenue_history = []
return obs, info
def step(self, action):
obs, reward, terminated, truncated, info = self.env.step(action)
# extract from unwrapped env
quoted_prices = np.asarray(self.env.unwrapped._prices, dtype=float)
effective_prices = np.asarray(
info.get("effective_prices", quoted_prices), dtype=float
)
if effective_prices.shape != quoted_prices.shape:
effective_prices = quoted_prices
demand_dict = self.env.unwrapped._demand
demand = np.array([demand_dict.get(i, 0.0) for i in range(len(quoted_prices))])
# core calculations
revenue = float(info.get("revenue", np.sum(effective_prices * demand)))
quoted_revenue = float(np.sum(quoted_prices * demand))
avg_price = float(np.mean(effective_prices))
margin = (avg_price - self.p_min) / max(avg_price, 1e-6)
coi_level = avg_price - self.p_min # E[P] - p_min per thesis Def 1
self._price_history.append(effective_prices.copy())
self._revenue_history.append(revenue)
# regret vs baseline (golden path)
regret = 0.0
if self.baseline_revenue and self.baseline_revenue > 0:
regret = 1.0 - (revenue / self.baseline_revenue)
# inject structured metrics into info
info["economics"] = {
"revenue": revenue,
"quoted_revenue": quoted_revenue,
"margin": margin,
"coi_level": coi_level,
"regret": regret,
}
for key in (
"coi_mix",
"coi_base",
"coi_leakage",
"coi_penalty",
"ux_penalty",
"volatility",
"upward_volatility",
"supra_penalty",
"supra_share",
"competitive_anchor",
"profit",
"cost_floor",
"reward_revenue",
"reward_total",
"agent_prob",
"alpha_adv",
"alpha_nominal",
"erosion_share",
"effective_price_mean",
):
if key in info:
info["economics"][key] = info[key]
info["prices"] = quoted_prices.copy()
info["effective_prices"] = effective_prices.copy()
info["demand"] = demand.copy()
return obs, reward, terminated, truncated, info
@property
def episode_revenue(self) -> float:
return sum(self._revenue_history)
@property
def episode_mean_price(self) -> float:
if not self._price_history:
return 0.0
return float(np.mean([np.mean(p) for p in self._price_history]))

View File

@@ -1,33 +0,0 @@
from __future__ import annotations
import logging
import os
import sys
_CONFIGURED = False
def _resolve_level(raw: str | None) -> int:
name = str(raw or os.environ.get("PHANTOM_LOG_LEVEL", "INFO")).upper().strip()
return int(getattr(logging, name, logging.INFO))
def configure_logging(level: str | None = None) -> None:
global _CONFIGURED
if _CONFIGURED:
return
logger = logging.getLogger("engine")
logger.setLevel(_resolve_level(level))
logger.propagate = False
if logger.handlers:
_CONFIGURED = True
return
handler = logging.StreamHandler(stream=sys.stdout)
handler.setFormatter(
logging.Formatter("%(asctime)s %(levelname)s [%(name)s] %(message)s")
)
logger.addHandler(handler)
_CONFIGURED = True

View File

@@ -1,5 +0,0 @@
from .benchmark import run_benchmark_cli
from .sweep_agent import run_sweep_agent
from .train import run_train_once
__all__ = ["run_benchmark_cli", "run_sweep_agent", "run_train_once"]

View File

@@ -1,7 +0,0 @@
from __future__ import annotations
def run_benchmark_cli(raw_args: list[str] | None = None) -> None:
from ..benchmark import run_cli
run_cli(raw_args)

View File

@@ -1,71 +0,0 @@
from __future__ import annotations
from typing import Any, Mapping, Sequence
from ..spec import TrainSpec, run_name
from ..telemetry.wandb import (
current_config,
finish_run,
get_wandb_module,
init_run,
run_agent,
update_summary,
)
from .train import run_with_active_sweep_run
def run_sweep_agent(
*,
project: str,
sweep_id: str,
count: int,
offline: bool,
no_wandb: bool,
base_overrides: Mapping[str, Any],
kind: str,
scenario: str,
group: str | None,
extra_tags: Sequence[str],
) -> None:
if no_wandb:
raise ValueError("sweep agent requires wandb")
if not sweep_id:
raise ValueError("--sweep-id is required with --sweep-agent")
if get_wandb_module() is None:
raise ImportError("wandb is required for sweep runs")
mode = "offline" if offline else "online"
def _sweep_trial() -> None:
run = init_run(mode=mode, project=project, group=group, sweep_mode=True)
try:
merged = dict(base_overrides)
merged.update(current_config())
spec = TrainSpec.from_flat(merged)
if run is not None:
run.name = run_name(spec, kind=kind, scenario=scenario)
try:
run_with_active_sweep_run(
spec,
kind=kind,
scenario=scenario,
group=group,
extra_tags=extra_tags,
)
update_summary({"run/status": "finished"})
except Exception as exc:
update_summary(
{
"run/status": "crashed",
"run/error": str(exc),
}
)
raise
finally:
finish_run()
run_agent(
sweep_id,
_sweep_trial,
count=count if count > 0 else None,
)

View File

@@ -1,124 +0,0 @@
from __future__ import annotations
import json
from typing import Any, Sequence
from ..spec import TrainSpec, run_metadata, run_name
from ..telemetry.wandb import (
finish_run,
get_wandb_module,
init_run,
log_metrics,
update_run_config,
update_summary,
)
from ..train_core import run_train
def _tags_for_run(spec: TrainSpec, kind: str, extra_tags: Sequence[str]) -> list[str]:
tags = [
kind,
spec.algorithm.name,
spec.runtime.backend,
"baseline" if spec.study.no_robust else "defended",
]
tags.extend([tag for tag in extra_tags if tag])
return tags
def _print_local_metrics(metrics: dict[str, Any]) -> None:
print(json.dumps(metrics, indent=2))
print("PHANTOM_METRICS:" + json.dumps(metrics))
def _log_train_events(events: list[dict[str, Any]], log_freq: int) -> None:
if not events:
return
period = max(1, int(log_freq))
last_logged_step = -period
for event in sorted(
[evt for evt in events if isinstance(evt, dict)],
key=lambda evt: int(evt.get("train/global_step", 0)),
):
step = int(event.get("train/global_step", 0))
if step <= 0 or (step - last_logged_step) < period:
continue
log_metrics(event, step=step)
last_logged_step = step
def run_train_once(
spec: TrainSpec,
*,
project: str,
offline: bool,
no_wandb: bool,
kind: str,
scenario: str,
group: str | None,
extra_tags: Sequence[str],
) -> dict[str, Any]:
wandb = get_wandb_module()
if no_wandb or wandb is None:
result = run_train(spec)
_print_local_metrics(result.metrics)
return result.metrics
mode = "offline" if offline else "online"
tags = _tags_for_run(spec, kind, extra_tags)
metadata = run_metadata(
spec,
kind=kind,
scenario=scenario,
group=group,
tags=tags,
)
config = spec.to_flat_dict()
config.update(metadata)
name = run_name(spec, kind=kind, scenario=scenario)
init_run(
mode=mode,
project=project,
config=config,
name=name,
tags=tags,
group=group,
sweep_mode=False,
)
try:
result = run_train(spec)
_log_train_events(result.events, spec.runtime.log_freq)
metrics = result.metrics
step = int(metrics.get("train/global_step", spec.runtime.total_timesteps))
log_metrics(metrics, step=step)
update_summary(metrics)
return metrics
finally:
finish_run()
def run_with_active_sweep_run(
spec: TrainSpec,
*,
kind: str,
scenario: str,
group: str | None,
extra_tags: Sequence[str],
) -> dict[str, Any]:
tags = _tags_for_run(spec, kind, extra_tags)
metadata = run_metadata(
spec,
kind=kind,
scenario=scenario,
group=group,
tags=tags,
)
update_run_config({**spec.to_flat_dict(), **metadata})
result = run_train(spec)
_log_train_events(result.events, spec.runtime.log_freq)
metrics = result.metrics
step = int(metrics.get("train/global_step", spec.runtime.total_timesteps))
log_metrics(metrics, step=step)
update_summary(metrics)
return metrics

View File

@@ -1,138 +0,0 @@
{
"$schema": "../node_modules/nx/schemas/project-schema.json",
"name": "research",
"projectType": "application",
"sourceRoot": "engine",
"targets": {
"install": {
"executor": "nx:run-commands",
"options": {
"command": "bash scripts/nx_research.sh install",
"cwd": "."
}
},
"test": {
"executor": "nx:run-commands",
"dependsOn": [
"install"
],
"options": {
"command": ".venv/bin/pytest -v",
"cwd": "."
}
},
"train": {
"executor": "nx:run-commands",
"dependsOn": [
"install"
],
"options": {
"command": "bash scripts/nx_research.sh train",
"cwd": "."
}
},
"benchmark": {
"executor": "nx:run-commands",
"dependsOn": [
"install"
],
"options": {
"command": "bash scripts/nx_research.sh benchmark",
"cwd": "."
}
},
"benchmark-simple": {
"executor": "nx:run-commands",
"dependsOn": [
"install"
],
"options": {
"command": "bash scripts/nx_research.sh benchmark-simple",
"cwd": "."
}
},
"benchmark-agent": {
"executor": "nx:run-commands",
"dependsOn": [
"install"
],
"options": {
"command": "bash scripts/nx_research.sh benchmark-agent",
"cwd": "."
}
},
"train-agent": {
"executor": "nx:run-commands",
"dependsOn": [
"install"
],
"options": {
"command": "bash scripts/nx_research.sh train-agent",
"cwd": "."
}
},
"train-bootstrap": {
"executor": "nx:run-commands",
"options": {
"command": "bash scripts/nx_research.sh train-bootstrap",
"cwd": "."
}
},
"stats": {
"executor": "nx:run-commands",
"options": {
"command": "bash scripts/nx_research.sh stats",
"cwd": "."
}
},
"docker-train-publish": {
"executor": "nx:run-commands",
"options": {
"command": "bash scripts/nx_research.sh docker-train-publish",
"cwd": "."
}
},
"whoclicked-publish": {
"executor": "nx:run-commands",
"dependsOn": [
"install"
],
"options": {
"command": "bash scripts/nx_research.sh whoclicked-publish",
"cwd": "."
}
},
"tpu-ray-bootstrap": {
"executor": "nx:run-commands",
"options": {
"command": "bash scripts/nx_research.sh tpu-ray-bootstrap",
"cwd": "."
}
},
"tpu-ray-deps": {
"executor": "nx:run-commands",
"options": {
"command": "bash scripts/nx_research.sh tpu-ray-deps",
"cwd": "."
}
},
"tpu-ray-verify": {
"executor": "nx:run-commands",
"options": {
"command": "bash scripts/nx_research.sh tpu-ray-verify",
"cwd": "."
}
},
"tpu-ray-teardown": {
"executor": "nx:run-commands",
"options": {
"command": "bash scripts/nx_research.sh tpu-ray-teardown",
"cwd": "."
}
}
},
"tags": [
"scope:research",
"type:python"
]
}

View File

@@ -1,353 +0,0 @@
from __future__ import annotations
from dataclasses import dataclass, field
import os
from typing import Any, Mapping, Sequence
def _truthy(value: str | bool | None) -> bool:
if isinstance(value, bool):
return value
if value is None:
return False
return str(value).strip().lower() in {"1", "true", "yes", "on"}
def _normalize_keys(raw: Mapping[str, Any]) -> dict[str, Any]:
alias_map = {
"algorithm": "algo",
"algorithm.name": "algo",
"env.n_products": "n_products",
"env.action_levels": "action_levels",
"env.action_scale_low": "action_scale_low",
"env.action_scale_high": "action_scale_high",
"env.price_low": "price_low",
"env.price_high": "price_high",
"env.max_steps": "max_steps",
"env.margin_floor": "margin_floor",
"env.margin_floor_patience": "margin_floor_patience",
"env.n_sessions": "N",
"study.alpha": "alpha",
"study.lambda_coi": "lambda_coi",
"study.robust_radius": "robust_radius",
"study.robust_points": "robust_points",
"study.robust_rollouts": "robust_rollouts",
"study.ambiguity_radius": "robust_radius",
"study.ambiguity_points": "robust_points",
"study.ambiguity_rollouts": "robust_rollouts",
"study.info_value": "info_value",
"study.eta_ux": "eta_ux",
"study.reward_profit_weight": "reward_profit_weight",
"ambiguity_radius": "robust_radius",
"ambiguity_points": "robust_points",
"ambiguity_rollouts": "robust_rollouts",
"baseline_mode": "no_robust",
"stress_eval_enabled": "robust_eval_enabled",
"optimizer.learning_rate": "learning_rate",
"optimizer.gamma": "gamma",
"optimizer.batch_size": "batch_size",
"optimizer.n_steps": "n_steps",
"runtime.backend": "backend",
"runtime.device": "device",
"runtime.seed": "seed",
"runtime.total_timesteps": "total_timesteps",
"runtime.checkpoint_interval": "checkpoint_interval",
"runtime.hist_freq": "hist_freq",
"eval.eval_freq": "eval_freq",
"eval.eval_episodes": "eval_episodes",
}
normalized: dict[str, Any] = {}
for key, value in raw.items():
canonical = alias_map.get(str(key), str(key))
normalized[canonical] = value
return normalized
@dataclass(frozen=True)
class AlgorithmSpec:
name: str = "ppo"
@dataclass(frozen=True)
class EnvSpec:
n_products: int = 10
n_sessions: int = 100
price_low: float = 10.0
price_high: float = 150.0
action_levels: int = 9
action_scale_low: float = 0.8
action_scale_high: float = 1.2
max_steps: int = 100
margin_floor: float = 0.05
margin_floor_patience: int = 5
agent_mu: float = 45.0
agent_std: float = 15.0
@dataclass(frozen=True)
class StudySpec:
alpha: float = 0.3
lambda_coi: float = 0.2
robust_radius: float = 0.15
robust_points: int = 5
robust_rollouts: int = 1
info_value: float = 1.0
eta_ux: float = 0.5
reward_profit_weight: float = 1.0
no_robust: bool = False
@dataclass(frozen=True)
class OptimizerSpec:
learning_rate: float = 3e-4
gamma: float = 0.99
buffer_size: int = 50_000
batch_size: int = 256
tau: float = 0.005
train_freq: int = 1
learning_starts: int = 1_000
target_update_interval: int = 1_000
exploration_fraction: float = 0.2
exploration_final_eps: float = 0.05
n_steps: int = 2_048
n_epochs: int = 10
gae_lambda: float = 0.95
clip_range: float = 0.2
ent_coef: float = 0.0
q_lr: float = 0.1
q_bins: int = 6
eps_start: float = 1.0
eps_end: float = 0.05
eps_decay: float = 0.9995
arch: str = "small"
activation: str = "relu"
vf_coef: float = 0.5
max_grad_norm: float = 0.5
@dataclass(frozen=True)
class RuntimeSpec:
project: str = "capstone"
backend: str = "sb3"
device: str = "auto"
seed: int = 42
total_timesteps: int = 50_000
checkpoint_interval: int = 200_000
model_dir: str = "engine/models"
log_freq: int = 100
hist_freq: int = 500
@dataclass(frozen=True)
class EvalSpec:
eval_freq: int = 1_000
eval_episodes: int = 5
robust_eval_enabled: bool = True
@dataclass(frozen=True)
class TrainSpec:
algorithm: AlgorithmSpec = field(default_factory=AlgorithmSpec)
env: EnvSpec = field(default_factory=EnvSpec)
study: StudySpec = field(default_factory=StudySpec)
optimizer: OptimizerSpec = field(default_factory=OptimizerSpec)
runtime: RuntimeSpec = field(default_factory=RuntimeSpec)
eval: EvalSpec = field(default_factory=EvalSpec)
def to_flat_dict(self) -> dict[str, Any]:
return {
"project": self.runtime.project,
"algo": self.algorithm.name,
"seed": self.runtime.seed,
"total_timesteps": self.runtime.total_timesteps,
"eval_episodes": self.eval.eval_episodes,
"eval_freq": self.eval.eval_freq,
"log_freq": self.runtime.log_freq,
"model_dir": self.runtime.model_dir,
"backend": self.runtime.backend,
"device": self.runtime.device,
"checkpoint_interval": self.runtime.checkpoint_interval,
"hist_freq": self.runtime.hist_freq,
"n_products": self.env.n_products,
"N": self.env.n_sessions,
"price_low": self.env.price_low,
"price_high": self.env.price_high,
"action_levels": self.env.action_levels,
"action_scale_low": self.env.action_scale_low,
"action_scale_high": self.env.action_scale_high,
"max_steps": self.env.max_steps,
"margin_floor": self.env.margin_floor,
"margin_floor_patience": self.env.margin_floor_patience,
"agent_mu": self.env.agent_mu,
"agent_std": self.env.agent_std,
"alpha": self.study.alpha,
"lambda_coi": self.study.lambda_coi,
"robust_radius": self.study.robust_radius,
"robust_points": self.study.robust_points,
"robust_rollouts": self.study.robust_rollouts,
"info_value": self.study.info_value,
"eta_ux": self.study.eta_ux,
"reward_profit_weight": self.study.reward_profit_weight,
"no_robust": self.study.no_robust,
"learning_rate": self.optimizer.learning_rate,
"gamma": self.optimizer.gamma,
"buffer_size": self.optimizer.buffer_size,
"batch_size": self.optimizer.batch_size,
"tau": self.optimizer.tau,
"train_freq": self.optimizer.train_freq,
"learning_starts": self.optimizer.learning_starts,
"target_update_interval": self.optimizer.target_update_interval,
"exploration_fraction": self.optimizer.exploration_fraction,
"exploration_final_eps": self.optimizer.exploration_final_eps,
"n_steps": self.optimizer.n_steps,
"n_epochs": self.optimizer.n_epochs,
"gae_lambda": self.optimizer.gae_lambda,
"clip_range": self.optimizer.clip_range,
"ent_coef": self.optimizer.ent_coef,
"q_lr": self.optimizer.q_lr,
"q_bins": self.optimizer.q_bins,
"eps_start": self.optimizer.eps_start,
"eps_end": self.optimizer.eps_end,
"eps_decay": self.optimizer.eps_decay,
"arch": self.optimizer.arch,
"activation": self.optimizer.activation,
"vf_coef": self.optimizer.vf_coef,
"max_grad_norm": self.optimizer.max_grad_norm,
"robust_eval_enabled": self.eval.robust_eval_enabled,
}
@classmethod
def from_flat(
cls,
raw: Mapping[str, Any] | None = None,
*,
env_vars: Mapping[str, str] | None = None,
) -> "TrainSpec":
base = cls().to_flat_dict()
incoming = _normalize_keys(raw or {})
base.update({k: v for k, v in incoming.items() if v is not None})
runtime_env = os.environ if env_vars is None else env_vars
base["device"] = str(
base.get("device", runtime_env.get("PHANTOM_DEVICE", "auto"))
)
backend = str(base.get("backend", "sb3")).lower()
if backend == "auto":
backend = "sb3"
if backend != "sb3":
backend = "sb3"
no_robust = _truthy(base.get("no_robust"))
if no_robust:
base["lambda_coi"] = 0.0
base["robust_radius"] = 0.0
base["robust_points"] = 1
base["robust_rollouts"] = 1
return cls(
algorithm=AlgorithmSpec(name=str(base["algo"]).lower().strip()),
env=EnvSpec(
n_products=int(base["n_products"]),
n_sessions=int(base["N"]),
price_low=float(base["price_low"]),
price_high=float(base["price_high"]),
action_levels=int(base["action_levels"]),
action_scale_low=float(base["action_scale_low"]),
action_scale_high=float(base["action_scale_high"]),
max_steps=int(base["max_steps"]),
margin_floor=float(base["margin_floor"]),
margin_floor_patience=int(base["margin_floor_patience"]),
agent_mu=float(base.get("agent_mu", 45.0)),
agent_std=float(base.get("agent_std", 15.0)),
),
study=StudySpec(
alpha=float(base["alpha"]),
lambda_coi=float(base["lambda_coi"]),
robust_radius=float(base["robust_radius"]),
robust_points=int(base["robust_points"]),
robust_rollouts=int(base["robust_rollouts"]),
info_value=float(base["info_value"]),
eta_ux=float(base["eta_ux"]),
reward_profit_weight=float(base["reward_profit_weight"]),
no_robust=no_robust,
),
optimizer=OptimizerSpec(
learning_rate=float(base["learning_rate"]),
gamma=float(base["gamma"]),
buffer_size=int(base["buffer_size"]),
batch_size=int(base["batch_size"]),
tau=float(base["tau"]),
train_freq=int(base["train_freq"]),
learning_starts=int(base["learning_starts"]),
target_update_interval=int(base["target_update_interval"]),
exploration_fraction=float(base["exploration_fraction"]),
exploration_final_eps=float(base["exploration_final_eps"]),
n_steps=int(base["n_steps"]),
n_epochs=int(base["n_epochs"]),
gae_lambda=float(base["gae_lambda"]),
clip_range=float(base["clip_range"]),
ent_coef=float(base["ent_coef"]),
q_lr=float(base["q_lr"]),
q_bins=int(base["q_bins"]),
eps_start=float(base["eps_start"]),
eps_end=float(base["eps_end"]),
eps_decay=float(base["eps_decay"]),
arch=str(base["arch"]),
activation=str(base["activation"]),
vf_coef=float(base["vf_coef"]),
max_grad_norm=float(base["max_grad_norm"]),
),
runtime=RuntimeSpec(
project=str(base["project"]),
backend=backend,
device=str(base["device"]),
seed=int(base["seed"]),
total_timesteps=int(base["total_timesteps"]),
checkpoint_interval=int(base["checkpoint_interval"]),
model_dir=str(base["model_dir"]),
log_freq=int(base["log_freq"]),
hist_freq=int(base["hist_freq"]),
),
eval=EvalSpec(
eval_freq=int(base["eval_freq"]),
eval_episodes=int(base["eval_episodes"]),
robust_eval_enabled=_truthy(base.get("robust_eval_enabled", True)),
),
)
def run_name(spec: TrainSpec, *, kind: str, scenario: str) -> str:
alpha_token = f"{float(spec.study.alpha):.2f}".rstrip("0").rstrip(".")
mode = "baseline" if bool(spec.study.no_robust) else "defended"
return (
f"{kind}/{spec.algorithm.name}/{spec.runtime.backend}/"
f"{spec.runtime.device}/{scenario}/a{alpha_token}/{mode}/s{spec.runtime.seed}"
)
def run_metadata(
spec: TrainSpec,
*,
kind: str,
scenario: str,
group: str | None = None,
tags: Sequence[str] = (),
) -> dict[str, Any]:
mode = "baseline" if bool(spec.study.no_robust) else "defended"
metadata: dict[str, Any] = {
"run.kind": str(kind),
"run.algo": spec.algorithm.name,
"run.backend": spec.runtime.backend,
"run.device": spec.runtime.device,
"run.scenario": str(scenario),
"run.seed": spec.runtime.seed,
"run.tags": list(tags),
"study/alpha": float(spec.study.alpha),
"study/mode": mode,
"study/baseline_mode": float(bool(spec.study.no_robust)),
"tiers": spec.algorithm.name,
}
if group:
metadata["run.group"] = group
return metadata

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@@ -1,33 +0,0 @@
"""shared factor definitions for experimental designs"""
import numpy as np
from dataclasses import dataclass
@dataclass
class Factor:
name: str
levels: list
primary: bool = True # full cross vs sampled
# demand functions with compatible signatures
def demand_linear(mu, sigma, size): return np.maximum(0, np.random.normal(mu, sigma, size))
def demand_uniform(mu, sigma, size): return np.random.uniform(mu - sigma, mu + sigma, size)
def demand_exponential(mu, sigma, size): return np.random.exponential(mu, size)
def demand_logistic(mu, sigma, size): return np.random.logistic(mu, sigma, size)
DEMAND_FUNCTIONS = {
"linear": demand_linear,
"uniform": demand_uniform,
"exponential": demand_exponential,
"logistic": demand_logistic,
}
FACTORS = [
Factor("demand_fn", list(DEMAND_FUNCTIONS.keys()), primary=True),
Factor("alpha", [0.1, 0.3, 0.5, 0.7], primary=True),
Factor("n_products", [5, 15, 30, 50], primary=True),
Factor("demand_mu", [30.0, 50.0, 70.0], primary=False),
Factor("demand_sigma", [5.0, 10.0, 20.0], primary=False),
Factor("N", [100, 500, 1000], primary=False),
]
SEEDS_PER_CONFIG = 5

View File

@@ -1,104 +0,0 @@
"""full factorial design - all factor combinations"""
import sys
sys.path.insert(0, "..")
import logging
from itertools import product
import json
import hashlib
from pathlib import Path
from concurrent.futures import ProcessPoolExecutor
from .factors import FACTORS, DEMAND_FUNCTIONS, SEEDS_PER_CONFIG
logging.basicConfig(level=logging.INFO, format="%(asctime)s %(levelname)s %(message)s")
log = logging.getLogger(__name__)
def generate_configs():
"""generate all factor combinations with seeds"""
all_levels = [f.levels for f in FACTORS]
names = [f.name for f in FACTORS]
configs = []
for combo in product(*all_levels):
base = {names[i]: combo[i] for i in range(len(names))}
for seed in range(SEEDS_PER_CONFIG):
cfg = {**base, "seed": seed}
cfg["id"] = hashlib.md5(
json.dumps(cfg, sort_keys=True).encode()
).hexdigest()[:8]
configs.append(cfg)
return configs
def run_single(cfg: dict) -> dict:
"""execute one experiment config, return metrics"""
from engine.wrapper import PHANTOM
import numpy as np
np.random.seed(cfg["seed"])
demand_fn = DEMAND_FUNCTIONS[cfg["demand_fn"]]
env = PHANTOM(
n_products=cfg["n_products"],
alpha=cfg["alpha"],
N=cfg["N"],
)
env.market.demand = (demand_fn, (cfg["demand_mu"], cfg["demand_sigma"]))
obs, _ = env.reset()
total_reward, steps = 0.0, 0
for _ in range(100):
action = env.action_space.sample()
obs, reward, term, trunc, _ = env.step(action)
total_reward += reward
steps += 1
if term:
break
env.close()
return {
"id": cfg["id"],
"config": cfg,
"total_reward": total_reward,
"avg_reward": total_reward / steps if steps > 0 else 0.0,
"steps": steps,
}
def run_study(max_workers: int = None, output: str = "results_full.jsonl"):
configs = generate_configs()
log.info(
f"full factorial: {len(configs)} configs ({len(configs) // SEEDS_PER_CONFIG} unique × {SEEDS_PER_CONFIG} seeds)"
)
results = []
with ProcessPoolExecutor(max_workers=max_workers) as ex:
for i, result in enumerate(ex.map(run_single, configs)):
results.append(result)
if (i + 1) % 100 == 0:
log.info(f"progress: {i + 1}/{len(configs)}")
Path(output).write_text("\n".join(json.dumps(r) for r in results))
log.info(f"wrote {len(results)} results to {output}")
return results
if __name__ == "__main__":
import argparse
p = argparse.ArgumentParser()
p.add_argument("--workers", type=int, default=None)
p.add_argument("--output", default="results_full.jsonl")
p.add_argument("--dry-run", action="store_true", help="only show design size")
args = p.parse_args()
configs = generate_configs()
log.info(
f"design: {len(configs)} runs | factors: {[f.name for f in FACTORS]} | levels: {[len(f.levels) for f in FACTORS]}"
)
if not args.dry_run:
run_study(args.workers, args.output)

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@@ -1,136 +0,0 @@
import sys
import numpy as np
import pandas as pd
from pathlib import Path
import matplotlib.pyplot as plt
from gymnasium.wrappers import FlattenObservation
from stable_baselines3 import PPO
# Add parent directory to path to allow importing engine
sys.path.insert(0, str(Path(__file__).parent.parent.parent))
from engine.wrapper import PHANTOM
from engine.lib.wrappers import EconomicMetricsWrapper
from engine.lib.providers import (
ProviderBenchmark,
BenchmarkConfig,
RandomBaseline,
SurgeBaseline,
)
def env_factory(alpha: float):
"""Creates a wrapped PHANTOM environment for testing at a specific alpha level."""
# Action levels=9 matches the trained PPO model
# n_products=8 matches the pretrained model's expectation of Box(16,)
env = PHANTOM(
n_products=8,
alpha=alpha,
N=100,
action_levels=9,
action_scale_low=0.8,
action_scale_high=1.2,
max_steps=20, # Short episodes so simulation goes fast
robust_points=1, # disable expensive adversarial lookaheads
render_mode=None,
)
env = EconomicMetricsWrapper(env)
return FlattenObservation(env)
def main():
print("Loading pre-trained Robust RL model...")
model_path = Path(__file__).parent.parent / "models" / "phantom_ppo.zip"
if not model_path.exists():
print(f"Error: Model not found at {model_path}")
print("Please ensure you have a trained model before running this script.")
return
rl_model = PPO.load(model_path)
# The action space is Discrete(9). Index 4 is the middle (1.0 scale).
n_actions = 9
mid_action = n_actions // 2
providers = {
"Static (Base)": lambda obs: mid_action,
"Random": RandomBaseline(n_actions),
"Heuristic Surge": SurgeBaseline(
n_actions, high_threshold=60.0, low_threshold=30.0
),
"Robust RL (PPO)": lambda obs: rl_model.predict(obs, deterministic=True)[0],
}
config = BenchmarkConfig(
n_episodes=10, # Lower episodes to run faster
alpha_range=[0.0, 0.5, 1.0], # Fewer alpha levels
baseline_name="Static (Base)",
)
print(f"\nStarting benchmark across alpha levels: {config.alpha_range}")
print(
f"Testing {len(providers)} strategies for {config.n_episodes} episodes each...\n"
)
benchmark = ProviderBenchmark(env_factory, providers, config)
results = benchmark.run()
# 1. Print tabular results
df = benchmark.to_dataframe()
summary = benchmark.summary_table()
print("\n--- Benchmark Summary Table ---")
print(summary)
# 2. Save results to CSV for thesis inclusion
out_dir = Path(__file__).parent / "results"
out_dir.mkdir(exist_ok=True)
csv_path = out_dir / "provider_comparison.csv"
df.to_csv(csv_path, index=False)
print(f"\nSaved raw results to {csv_path}")
# 3. Plot the degradation of COI / Revenue as alpha increases
plt.figure(figsize=(12, 5))
# Plot 1: Revenue vs Alpha
plt.subplot(1, 2, 1)
for name in providers.keys():
provider_data = df[df["name"] == name]
plt.plot(
provider_data["alpha"],
provider_data["mean_revenue"],
marker="o",
label=name,
linewidth=2,
)
plt.title("Revenue under Agent Contamination")
plt.xlabel("Contamination Level (α)")
plt.ylabel("Mean Episode Revenue ($)")
plt.grid(True, linestyle="--", alpha=0.7)
plt.legend()
# Plot 2: COI Preservation vs Alpha
plt.subplot(1, 2, 2)
for name in providers.keys():
provider_data = df[df["name"] == name]
plt.plot(
provider_data["alpha"],
provider_data["coi_preserved_pct"],
marker="s",
label=name,
linewidth=2,
)
plt.title("Cost of Information (COI) Preservation")
plt.xlabel("Contamination Level (α)")
plt.ylabel("COI Preserved (%)")
plt.grid(True, linestyle="--", alpha=0.7)
plt.legend()
plt.tight_layout()
plot_path = out_dir / "alpha_degradation_plot.png"
plt.savefig(plot_path, dpi=300)
print(f"Saved visualization to {plot_path}")
if __name__ == "__main__":
main()

View File

@@ -1,133 +0,0 @@
"""validate core thesis problem: margin erosion under agent contamination
trains standard RL (no robust components) across α levels to demonstrate systematic failure
"""
from __future__ import annotations
import json, sys, time
from pathlib import Path
import numpy as np
sys.path.insert(0, str(Path(__file__).parent.parent.parent))
from engine.spec import TrainSpec
from engine.orchestrators import run_train_once
def _run_baseline(alpha: float, algo: str, seed: int, steps: int) -> dict:
spec = TrainSpec.from_flat(
{
"algo": algo,
"seed": seed,
"alpha": alpha,
"total_timesteps": steps,
"lambda_coi": 0.0,
"robust_radius": 0.0,
"robust_points": 1,
"robust_rollouts": 1,
"no_robust": True,
"arch": "small",
"n_products": 10,
"N": 100,
"max_steps": 50,
"eval_freq": 5000,
"eval_episodes": 10,
"log_freq": 500,
"robust_eval_enabled": False,
"agent_mu": 12.0,
"agent_std": 2.0,
}
)
result = run_train_once(
spec,
project="phantom-margin-erosion",
offline=True,
no_wandb=True,
kind="study",
scenario=f"alpha{int(alpha * 100):02d}",
group=f"baseline_{algo}",
extra_tags=("margin_erosion", "baseline"),
)
return {
"alpha": alpha,
"algo": algo,
"seed": seed,
"eval_reward": result.get("eval/reward_mean", np.nan),
"eval_revenue": result.get("eval/revenue_mean", np.nan),
"eval_coi_level": result.get("eval/coi_level_mean", np.nan),
"eval_margin": result.get("eval/margin_mean", np.nan),
"eval_agent_prob": result.get("eval/agent_prob_mean", np.nan),
}
def run_margin_erosion_study(
alphas: list[float] | None = None,
algos: list[str] | None = None,
seeds: int = 3,
steps: int = 30_000,
) -> dict:
alphas = alphas or [0.1, 0.3, 0.5, 0.7, 0.9]
algos = algos or ["ppo", "dqn", "qtable"]
output_dir = Path(__file__).parent / "results"
output_dir.mkdir(exist_ok=True)
ts = time.strftime("%Y%m%d_%H%M%S")
results = []
for α in alphas:
for algo in algos:
for si in range(seeds):
seed = 42 + si
print(f"α={α:.1f} {algo} seed={seed}")
m = _run_baseline(α, algo, seed, steps)
results.append(m)
print(
f" margin={m['eval_margin']:.3f} rev={m['eval_revenue']:.0f} coi={m['eval_coi_level']:.1f}"
)
summary = {}
for α in alphas:
runs = [r for r in results if abs(r["alpha"] - α) < 0.01]
if not runs:
continue
s = {}
for metric in ["margin", "revenue", "coi_level", "agent_prob"]:
vals = [r[f"eval_{metric}"] for r in runs]
s[f"{metric}_mean"] = float(np.mean(vals))
s[f"{metric}_std"] = float(np.std(vals))
s["n_runs"] = len(runs)
summary[f"alpha_{α:.1f}"] = s
output = {
"timestamp": ts,
"config": {"alphas": alphas, "algos": algos, "seeds": seeds, "steps": steps},
"results": results,
"summary": summary,
}
path = output_dir / f"margin_erosion_alpha_{ts}.json"
with open(path, "w") as f:
json.dump(output, f, indent=2)
print(f"\n{path}")
for α in alphas:
k = f"alpha_{α:.1f}"
if k in summary:
s = summary[k]
print(
f" {k}: margin={s['margin_mean']:.3f}±{s['margin_std']:.3f} "
f"coi={s['coi_level_mean']:.1f}±{s['coi_level_std']:.1f}"
)
return output
if __name__ == "__main__":
import argparse
p = argparse.ArgumentParser(description="margin erosion vs α")
p.add_argument("--quick", action="store_true", help="fast test")
args = p.parse_args()
run_margin_erosion_study(
alphas=[0.1, 0.7] if args.quick else [0.1, 0.3, 0.5, 0.7, 0.9],
algos=["qtable"] if args.quick else ["ppo", "dqn", "qtable"],
seeds=1 if args.quick else 3,
steps=5_000 if args.quick else 30_000,
)

View File

@@ -1,127 +0,0 @@
"""mixed design: full factorial on primary factors, latin hypercube on secondary"""
import sys
sys.path.insert(0, "..")
import logging
from itertools import product
import json
import hashlib
from pathlib import Path
from concurrent.futures import ProcessPoolExecutor
import numpy as np
from scipy.stats.qmc import LatinHypercube
from factors import FACTORS, DEMAND_FUNCTIONS, SEEDS_PER_CONFIG
logging.basicConfig(level=logging.INFO, format="%(asctime)s %(levelname)s %(message)s")
log = logging.getLogger(__name__)
LH_SAMPLES = 10
def generate_configs(lh_samples: int = LH_SAMPLES):
primary = [f for f in FACTORS if f.primary]
secondary = [f for f in FACTORS if not f.primary]
primary_grid = list(product(*[f.levels for f in primary]))
lhs = LatinHypercube(d=len(secondary), seed=42)
configs = []
for p_combo in primary_grid:
samples = lhs.random(n=lh_samples)
for s in samples:
sec_vals = {
secondary[i].name: secondary[i].levels[
int(s[i] * len(secondary[i].levels))
]
for i in range(len(secondary))
}
base = {primary[i].name: p_combo[i] for i in range(len(primary))}
base.update(sec_vals)
for seed in range(SEEDS_PER_CONFIG):
cfg = {**base, "seed": seed}
cfg["id"] = hashlib.md5(
json.dumps(cfg, sort_keys=True).encode()
).hexdigest()[:8]
configs.append(cfg)
return configs
def run_single(cfg: dict) -> dict:
from engine.wrapper import PHANTOM
import numpy as np
np.random.seed(cfg["seed"])
demand_fn = DEMAND_FUNCTIONS[cfg["demand_fn"]]
env = PHANTOM(
n_products=cfg["n_products"],
alpha=cfg["alpha"],
N=cfg["N"],
)
env.market.demand = (demand_fn, (cfg["demand_mu"], cfg["demand_sigma"]))
obs, _ = env.reset()
total_reward, steps = 0.0, 0
for _ in range(100):
action = env.action_space.sample()
obs, reward, term, trunc, _ = env.step(action)
total_reward += reward
steps += 1
if term:
break
env.close()
return {
"id": cfg["id"],
"config": cfg,
"total_reward": total_reward,
"avg_reward": total_reward / steps,
"steps": steps,
}
def run_study(
max_workers: int = None,
output: str = "results_mixed.jsonl",
lh_samples: int = LH_SAMPLES,
):
configs = generate_configs(lh_samples)
n_primary_cells = int(np.prod([len(f.levels) for f in FACTORS if f.primary]))
log.info(
f"mixed LH: {len(configs)} configs ({n_primary_cells} primary × {lh_samples} LH × {SEEDS_PER_CONFIG} seeds)"
)
results = []
with ProcessPoolExecutor(max_workers=max_workers) as ex:
for i, result in enumerate(ex.map(run_single, configs)):
results.append(result)
if (i + 1) % 100 == 0:
log.info(f"progress: {i + 1}/{len(configs)}")
Path(output).write_text("\n".join(json.dumps(r) for r in results))
log.info(f"wrote {len(results)} results to {output}")
return results
if __name__ == "__main__":
import argparse
p = argparse.ArgumentParser()
p.add_argument("--workers", type=int, default=None)
p.add_argument("--output", default="results_mixed.jsonl")
p.add_argument("--lh-samples", type=int, default=10)
p.add_argument("--dry-run", action="store_true", help="only show design size")
args = p.parse_args()
primary = [f for f in FACTORS if f.primary]
secondary = [f for f in FACTORS if not f.primary]
configs = generate_configs(args.lh_samples)
log.info(
f"design: {len(configs)} runs | primary: {[f.name for f in primary]} | secondary (LH): {[f.name for f in secondary]}"
)
if not args.dry_run:
run_study(args.workers, args.output, args.lh_samples)

View File

@@ -1,60 +0,0 @@
method: grid
metric:
name: eval/stress_reward_worst
goal: maximize
command:
- ${env}
- python
- -m
- engine.train
parameters:
algo:
value: ppo
backend:
value: sb3
device:
value: cpu
seed:
values: [42, 1337, 7777]
alpha:
values: [0.1, 0.2, 0.3, 0.4, 0.6, 0.8]
n_products:
values: [25, 50, 100]
N:
value: 100
no_robust:
values: [false, true]
lambda_coi:
values: [0.15, 0.30]
robust_radius:
value: 0.2
robust_points:
value: 7
robust_rollouts:
value: 1
eta_ux:
value: 0.5
reward_profit_weight:
value: 1.0
action_levels:
value: 9
action_scale_low:
value: 0.8
action_scale_high:
value: 1.2
total_timesteps:
value: 100000
eval_episodes:
value: 12
eval_freq:
value: 1000
log_freq:
value: 100
hist_freq:
value: 500
learning_rate:
value: 0.0003
batch_size:
value: 256
n_steps:
value: 2048

View File

@@ -1,84 +0,0 @@
method: random
metric:
name: objective/score
goal: maximize
command:
- ${env}
- python
- -m
- engine.train
parameters:
algo:
values: [ppo, a2c, dqn, qtable]
total_timesteps:
values: [30000, 50000, 80000]
seed:
values: [13, 42, 77]
n_products:
values: [8, 10, 12]
alpha:
distribution: uniform
min: 0.1
max: 0.6
lambda_coi:
distribution: uniform
min: 0.05
max: 0.6
robust_radius:
distribution: uniform
min: 0.0
max: 0.3
robust_points:
values: [3, 5, 7]
info_value:
distribution: uniform
min: 0.5
max: 2.0
revenue_weight:
values: [0.005, 0.01, 0.02]
learning_rate:
distribution: log_uniform_values
min: 1.0e-5
max: 1.0e-3
gamma:
values: [0.97, 0.99, 0.995]
buffer_size:
values: [20000, 50000, 100000]
batch_size:
values: [128, 256, 512]
tau:
values: [0.002, 0.005, 0.01]
train_freq:
values: [1, 4, 8]
learning_starts:
values: [500, 1000, 3000]
n_steps:
values: [512, 1024, 2048]
n_epochs:
values: [5, 10, 20]
gae_lambda:
values: [0.9, 0.95, 0.98]
clip_range:
values: [0.1, 0.2, 0.3]
ent_coef:
values: [0.0, 0.005, 0.01]
target_update_interval:
values: [500, 1000, 2000]
exploration_fraction:
values: [0.1, 0.2, 0.3]
exploration_final_eps:
values: [0.01, 0.03, 0.05]
action_levels:
values: [7, 9, 11]
action_scale_low:
values: [0.75, 0.8, 0.85]
action_scale_high:
values: [1.15, 1.2, 1.25]
q_lr:
values: [0.03, 0.05, 0.1, 0.2]
eps_start:
value: 1.0
eps_end:
values: [0.02, 0.05, 0.1]
eps_decay:
values: [0.999, 0.9995, 0.9999]

View File

@@ -1,85 +0,0 @@
method: grid
metric:
name: objective/score
goal: maximize
run_cap: 4
command:
- ${env}
- python
- -m
- engine.train
parameters:
algo:
values: [ppo, a2c, dqn, qtable]
seed:
value: 42
total_timesteps:
value: 12000
eval_episodes:
value: 3
eval_freq:
value: 500
log_freq:
value: 100
revenue_weight:
value: 0.01
n_products:
value: 8
N:
value: 80
alpha:
value: 0.3
lambda_coi:
value: 0.2
robust_radius:
value: 0.0
robust_points:
value: 1
info_value:
value: 1.0
learning_rate:
value: 0.0003
gamma:
value: 0.99
buffer_size:
value: 20000
batch_size:
value: 128
tau:
value: 0.005
train_freq:
value: 1
learning_starts:
value: 500
n_steps:
value: 512
n_epochs:
value: 10
gae_lambda:
value: 0.95
clip_range:
value: 0.2
ent_coef:
value: 0.0
target_update_interval:
value: 500
exploration_fraction:
value: 0.2
exploration_final_eps:
value: 0.05
action_levels:
value: 7
action_scale_low:
value: 0.9
action_scale_high:
value: 1.1
q_lr:
value: 0.1
q_bins:
value: 6
eps_start:
value: 1.0
eps_end:
value: 0.05
eps_decay:
value: 0.9995

View File

@@ -1,53 +0,0 @@
method: random
metric:
name: eval/supra_share_mean
goal: minimize
run_cap: 256
command:
- ${env}
- python
- -m
- engine.train
parameters:
algo:
value: ppo
seed:
values: [42, 1337, 7777]
alpha:
values: [0.1, 0.2, 0.3, 0.4, 0.6]
n_products:
values: [25, 50]
N:
value: 100
no_robust:
values: [false, true]
lambda_coi:
values: [0.05, 0.15, 0.3]
robust_radius:
values: [0.1, 0.2, 0.3]
robust_points:
value: 7
robust_rollouts:
value: 1
eta_ux:
values: [0.05, 0.15, 0.3, 0.5, 0.75]
reward_profit_weight:
value: 1.0
total_timesteps:
value: 100000
eval_episodes:
value: 10
eval_freq:
value: 1000
log_freq:
value: 100
hist_freq:
value: 500
learning_rate:
value: 0.0003
batch_size:
value: 256
n_steps:
value: 2048
device:
value: cpu

View File

@@ -1,54 +0,0 @@
method: bayes
metric:
name: objective/score
goal: maximize
command:
- ${env}
- python
- -m
- engine.train
parameters:
algo:
value: sac
total_timesteps:
values: [50000, 80000, 120000]
seed:
values: [13, 42, 77]
alpha:
distribution: uniform
min: 0.15
max: 0.55
n_products:
values: [8, 10, 12]
lambda_coi:
distribution: uniform
min: 0.05
max: 0.5
robust_radius:
distribution: uniform
min: 0.05
max: 0.3
robust_points:
values: [3, 5, 7]
info_value:
distribution: uniform
min: 0.5
max: 2.0
revenue_weight:
values: [0.005, 0.01, 0.02]
learning_rate:
distribution: log_uniform_values
min: 3.0e-5
max: 1.0e-3
gamma:
values: [0.98, 0.99, 0.995]
buffer_size:
values: [50000, 100000, 200000]
batch_size:
values: [128, 256, 512]
tau:
values: [0.002, 0.005, 0.01]
train_freq:
values: [1, 4, 8]
learning_starts:
values: [1000, 3000, 5000]

View File

@@ -1,86 +0,0 @@
method: random
metric:
name: objective/score
goal: maximize
command:
- ${env}
- python
- -m
- engine.train
parameters:
algo:
values: [ppo, a2c, dqn, qtable]
arch:
values: [tiny, small, medium]
activation:
values: [relu, tanh]
total_timesteps:
values: [8000, 12000, 20000]
seed:
values: [13, 42, 77]
n_products:
values: [6, 8, 10]
alpha:
distribution: uniform
min: 0.1
max: 0.5
lambda_coi:
distribution: uniform
min: 0.05
max: 0.4
robust_radius:
values: [0.0, 0.1, 0.2]
robust_points:
values: [3, 5]
info_value:
values: [0.75, 1.0, 1.5]
revenue_weight:
values: [0.005, 0.01, 0.02]
learning_rate:
distribution: log_uniform_values
min: 1.0e-5
max: 5.0e-4
gamma:
values: [0.98, 0.99]
buffer_size:
values: [10000, 30000, 50000]
batch_size:
values: [64, 128, 256]
tau:
values: [0.002, 0.005, 0.01]
train_freq:
values: [1, 4]
learning_starts:
values: [500, 1000, 2000]
n_steps:
values: [256, 512, 1024]
n_epochs:
values: [5, 10]
gae_lambda:
values: [0.9, 0.95]
clip_range:
values: [0.1, 0.2]
ent_coef:
values: [0.0, 0.005]
target_update_interval:
values: [500, 1000]
exploration_fraction:
values: [0.1, 0.2]
exploration_final_eps:
values: [0.02, 0.05]
action_levels:
values: [5, 7, 9]
action_scale_low:
values: [0.85, 0.9]
action_scale_high:
values: [1.1, 1.15]
q_lr:
values: [0.05, 0.1, 0.2]
q_bins:
values: [4, 6, 8]
eps_start:
value: 1.0
eps_end:
values: [0.02, 0.05]
eps_decay:
values: [0.999, 0.9995]

View File

@@ -1,23 +0,0 @@
from .metrics import canonicalize_metrics
from .wandb import (
current_config,
finish_run,
get_wandb_module,
init_run,
log_metrics,
run_agent,
update_run_config,
update_summary,
)
__all__ = [
"canonicalize_metrics",
"current_config",
"finish_run",
"get_wandb_module",
"init_run",
"log_metrics",
"run_agent",
"update_run_config",
"update_summary",
]

View File

@@ -1,70 +0,0 @@
from __future__ import annotations
from typing import Any, Mapping
from ..spec import TrainSpec
_ALIASES = {
"train/reward": "train/reward_mean",
"train/revenue": "train/revenue_mean",
"train/dqn_loss": "train/loss",
"eval/reward": "eval/reward_mean",
"eval/revenue": "eval/revenue_mean",
"train/steps_per_second": "runtime/steps_per_second",
}
def _as_float(value: Any, default: float | None = None) -> float | None:
if value is None:
return default
try:
return float(value)
except (TypeError, ValueError):
return default
def canonicalize_metrics(raw: Mapping[str, Any], spec: TrainSpec) -> dict[str, Any]:
metrics: dict[str, Any] = {}
for key, value in raw.items():
canonical = _ALIASES.get(str(key), str(key))
if canonical in metrics and canonical != key:
continue
metrics[canonical] = value
metrics.setdefault("train/global_step", spec.runtime.total_timesteps)
eval_reward = (
_as_float(
metrics.get(
"eval/stress_reward_worst",
metrics.get(
"eval/robust_reward_worst", metrics.get("eval/reward_mean")
),
),
0.0,
)
or 0.0
)
metrics["objective/score"] = eval_reward
margin_mean = _as_float(metrics.get("eval/margin_mean"), None)
if margin_mean is not None:
metrics["objective/constraint_margin"] = margin_mean - spec.env.margin_floor
coi_level = _as_float(metrics.get("eval/coi_level_mean"), None)
metrics["objective/coi_preserved"] = 0.0 if coi_level is None else coi_level
metrics["study/alpha"] = spec.study.alpha
metrics["study/mode"] = "baseline" if bool(spec.study.no_robust) else "defended"
metrics["study/baseline_mode"] = float(bool(spec.study.no_robust))
metrics["study/lambda_coi"] = spec.study.lambda_coi
metrics["study/ambiguity_radius"] = spec.study.robust_radius
metrics["study/info_value"] = spec.study.info_value
metrics["tiers"] = spec.algorithm.name
metrics["runtime/backend"] = spec.runtime.backend
metrics["runtime/device"] = spec.runtime.device
metrics["runtime/seed"] = spec.runtime.seed
return metrics

View File

@@ -1,202 +0,0 @@
from __future__ import annotations
import os
import time
from typing import Any, Callable, Iterable, Mapping
def get_wandb_module():
try:
import wandb
return wandb
except ImportError:
return None
def _require_wandb():
wandb = get_wandb_module()
if wandb is None:
raise ImportError("wandb is required for this workflow")
return wandb
def _warn(message: str) -> None:
print(f"PHANTOM_WANDB_WARNING: {message}")
def _sanitize_key(raw_key: str) -> str | None:
key = str(raw_key)
replacements = {
"no_robust": "baseline_mode",
"study/no_robust": "study/baseline_mode",
"study/robust_radius": "study/ambiguity_radius",
"robust_radius": "ambiguity_radius",
"robust_points": "ambiguity_points",
"robust_rollouts": "ambiguity_rollouts",
"robust_eval_enabled": "stress_eval_enabled",
"eval/robust_alpha_high": "eval/stress_alpha_high",
"eval/robust_alpha_low": "eval/stress_alpha_low",
"eval/robust_reward_worst": "eval/stress_reward_worst",
"eval/robust_revenue_worst": "eval/stress_revenue_worst",
"eval/robust_coi_leakage_worst": "eval/stress_coi_leakage_worst",
}
key = replacements.get(key, key)
if "robust" in key.lower():
return None
return key
def _sanitize_payload(payload: Mapping[str, Any]) -> dict[str, Any]:
sanitized: dict[str, Any] = {}
for key, value in payload.items():
clean_key = _sanitize_key(str(key))
if clean_key is None:
continue
sanitized[clean_key] = value
return sanitized
def init_run(
*,
mode: str,
project: str | None = None,
config: Mapping[str, Any] | None = None,
name: str | None = None,
tags: Iterable[str] | None = None,
group: str | None = None,
sweep_mode: bool = False,
):
wandb = _require_wandb()
kwargs: dict[str, Any] = {"mode": mode}
if group:
kwargs["group"] = group
if sweep_mode:
try:
run = wandb.init(**kwargs)
except Exception as exc:
_warn(f"init failed in sweep mode ({exc})")
return None
if name and run is not None:
run.name = name
return run
init_kwargs = dict(kwargs)
init_kwargs["project"] = project
if config is not None:
init_kwargs["config"] = _sanitize_payload(dict(config))
if name:
init_kwargs["name"] = name
if tags:
init_kwargs["tags"] = list(tags)
try:
return wandb.init(**init_kwargs)
except Exception as exc:
_warn(f"init failed ({exc})")
return None
def finish_run() -> None:
wandb = get_wandb_module()
if wandb is not None and wandb.run is not None:
try:
wandb.finish()
except Exception as exc:
_warn(f"finish failed ({exc})")
def current_config() -> dict[str, Any]:
wandb = get_wandb_module()
if wandb is None or wandb.run is None:
return {}
return {key: wandb.config[key] for key in wandb.config.keys()}
def update_run_config(config: Mapping[str, Any]) -> None:
wandb = get_wandb_module()
if wandb is None or wandb.run is None:
return
payload = _sanitize_payload(dict(config))
if not payload:
return
try:
wandb.config.update(payload, allow_val_change=True)
except TypeError:
try:
wandb.config.update(payload)
except Exception as exc:
_warn(f"config update failed ({exc})")
except Exception as exc:
_warn(f"config update failed ({exc})")
def log_metrics(metrics: Mapping[str, Any], *, step: int) -> None:
wandb = get_wandb_module()
if wandb is None or wandb.run is None:
return
payload = _sanitize_payload(dict(metrics))
if not payload:
return
try:
wandb.log(payload, step=step)
except Exception as exc:
_warn(f"log failed at step {step} ({exc})")
def update_summary(metrics: Mapping[str, Any]) -> None:
wandb = get_wandb_module()
if wandb is None or wandb.run is None:
return
payload = _sanitize_payload(dict(metrics))
if not payload:
return
try:
for key, value in payload.items():
wandb.run.summary[key] = value
except Exception as exc:
_warn(f"summary update failed ({exc})")
def run_agent(
sweep_id: str,
fn: Callable[[], None],
*,
count: int | None = None,
) -> None:
wandb = _require_wandb()
retry_max = max(0, int(os.getenv("PHANTOM_WANDB_AGENT_RETRIES", "8")))
retry_delay = max(1.0, float(os.getenv("PHANTOM_WANDB_AGENT_RETRY_DELAY", "5")))
retry_backoff = max(
1.0, float(os.getenv("PHANTOM_WANDB_AGENT_RETRY_BACKOFF", "1.5"))
)
retry_max_delay = max(
retry_delay,
float(os.getenv("PHANTOM_WANDB_AGENT_MAX_RETRY_DELAY", "60")),
)
target = None if count is None else max(0, int(count))
completed = 0
def _wrapped() -> None:
nonlocal completed
fn()
completed += 1
attempt = 0
while True:
remaining = None if target is None else max(0, int(target - completed))
if target is not None and remaining == 0:
return
try:
wandb.agent(sweep_id, function=_wrapped, count=remaining)
return
except Exception as exc:
attempt += 1
if attempt > retry_max:
raise
wait = min(retry_max_delay, retry_delay * (retry_backoff ** (attempt - 1)))
_warn(
f"agent disconnected (attempt {attempt}/{retry_max}, "
f"completed={completed}, remaining={remaining}): {exc}"
)
time.sleep(wait)

View File

@@ -1,251 +0,0 @@
from __future__ import annotations
import argparse
from typing import Any
from .logging_utils import configure_logging
from .orchestrators import run_benchmark_cli, run_sweep_agent, run_train_once
from .spec import TrainSpec
def _parse_tags(raw: str | None) -> list[str]:
if raw is None:
return []
return [piece.strip() for piece in str(raw).split(",") if piece.strip()]
def _probe_run_kind(argv: list[str]) -> str:
probe = argparse.ArgumentParser(add_help=False)
probe.add_argument("--run-kind", choices=["train", "benchmark"])
probe.add_argument("--run-mode", choices=["train", "benchmark"])
args, _ = probe.parse_known_args(argv)
return str(args.run_kind or args.run_mode or "train")
def _strip_run_kind(argv: list[str]) -> list[str]:
stripped: list[str] = []
skip_next = False
for item in argv:
if skip_next:
skip_next = False
continue
if item in {"--run-kind", "--run-mode"}:
skip_next = True
continue
if item.startswith("--run-kind=") or item.startswith("--run-mode="):
continue
stripped.append(item)
return stripped
def _build_parser() -> argparse.ArgumentParser:
parser = argparse.ArgumentParser(description="PHANTOM unified training entrypoint")
parser.add_argument("--run-kind", choices=["train", "benchmark"], default="train")
parser.add_argument("--run-mode", choices=["train", "benchmark"])
parser.add_argument("--project", default="capstone")
parser.add_argument("--scenario", default="default")
parser.add_argument("--group", type=str)
parser.add_argument("--tags", type=str)
parser.add_argument("--backend", choices=["auto", "sb3"], default="auto")
parser.add_argument("--algo", choices=["ppo", "a2c", "dqn", "qtable", "sac"])
parser.add_argument("--seed", type=int)
parser.add_argument("--total-timesteps", type=int)
parser.add_argument("--model-dir", type=str)
parser.add_argument("--log-freq", type=int)
parser.add_argument("--hist-freq", type=int)
parser.add_argument("--checkpoint-interval", type=int)
parser.add_argument("--device", type=str)
parser.add_argument("--alpha", type=float)
parser.add_argument("--N", type=int)
parser.add_argument("--n-products", type=int)
parser.add_argument("--lambda-coi", type=float)
parser.add_argument("--info-value", type=float)
parser.add_argument("--robust-radius", type=float)
parser.add_argument("--robust-points", type=int)
parser.add_argument("--robust-rollouts", type=int)
parser.add_argument("--no-robust", action="store_true")
parser.add_argument("--eta-ux", type=float)
parser.add_argument("--reward-profit-weight", type=float)
parser.add_argument("--price-low", type=float)
parser.add_argument("--price-high", type=float)
parser.add_argument("--action-levels", type=int)
parser.add_argument("--action-scale-low", type=float)
parser.add_argument("--action-scale-high", type=float)
parser.add_argument("--max-steps", type=int)
parser.add_argument("--margin-floor", type=float)
parser.add_argument("--margin-floor-patience", type=int)
parser.add_argument("--learning-rate", type=float)
parser.add_argument("--gamma", type=float)
parser.add_argument("--buffer-size", type=int)
parser.add_argument("--batch-size", type=int)
parser.add_argument("--tau", type=float)
parser.add_argument("--train-freq", type=int)
parser.add_argument("--learning-starts", type=int)
parser.add_argument("--target-update-interval", type=int)
parser.add_argument("--exploration-fraction", type=float)
parser.add_argument("--exploration-final-eps", type=float)
parser.add_argument("--n-steps", type=int)
parser.add_argument("--n-epochs", type=int)
parser.add_argument("--gae-lambda", type=float)
parser.add_argument("--clip-range", type=float)
parser.add_argument("--ent-coef", type=float)
parser.add_argument("--q-lr", type=float)
parser.add_argument("--q-bins", type=int)
parser.add_argument("--eps-start", type=float)
parser.add_argument("--eps-end", type=float)
parser.add_argument("--eps-decay", type=float)
parser.add_argument("--arch", type=str)
parser.add_argument("--activation", type=str)
parser.add_argument("--vf-coef", type=float)
parser.add_argument("--max-grad-norm", type=float)
parser.add_argument("--eval-freq", type=int)
parser.add_argument("--eval-episodes", type=int)
parser.add_argument("--sweep-agent", action="store_true")
parser.add_argument("--sweep-id", type=str)
parser.add_argument("--count", type=int, default=0)
parser.add_argument("--offline", action="store_true")
parser.add_argument("--no-wandb", action="store_true")
return parser
def _overrides_from_args(args: argparse.Namespace) -> dict[str, Any]:
backend = None if args.backend == "auto" else args.backend
overrides = {
"project": args.project,
"backend": backend,
"algo": args.algo,
"seed": args.seed,
"total_timesteps": args.total_timesteps,
"model_dir": args.model_dir,
"log_freq": args.log_freq,
"hist_freq": args.hist_freq,
"checkpoint_interval": args.checkpoint_interval,
"device": args.device,
"alpha": args.alpha,
"N": args.N,
"n_products": args.n_products,
"lambda_coi": args.lambda_coi,
"info_value": args.info_value,
"robust_radius": args.robust_radius,
"robust_points": args.robust_points,
"robust_rollouts": args.robust_rollouts,
"no_robust": args.no_robust,
"eta_ux": args.eta_ux,
"reward_profit_weight": args.reward_profit_weight,
"price_low": args.price_low,
"price_high": args.price_high,
"action_levels": args.action_levels,
"action_scale_low": args.action_scale_low,
"action_scale_high": args.action_scale_high,
"max_steps": args.max_steps,
"margin_floor": args.margin_floor,
"margin_floor_patience": args.margin_floor_patience,
"learning_rate": args.learning_rate,
"gamma": args.gamma,
"buffer_size": args.buffer_size,
"batch_size": args.batch_size,
"tau": args.tau,
"train_freq": args.train_freq,
"learning_starts": args.learning_starts,
"target_update_interval": args.target_update_interval,
"exploration_fraction": args.exploration_fraction,
"exploration_final_eps": args.exploration_final_eps,
"n_steps": args.n_steps,
"n_epochs": args.n_epochs,
"gae_lambda": args.gae_lambda,
"clip_range": args.clip_range,
"ent_coef": args.ent_coef,
"q_lr": args.q_lr,
"q_bins": args.q_bins,
"eps_start": args.eps_start,
"eps_end": args.eps_end,
"eps_decay": args.eps_decay,
"arch": args.arch,
"activation": args.activation,
"vf_coef": args.vf_coef,
"max_grad_norm": args.max_grad_norm,
"eval_freq": args.eval_freq,
"eval_episodes": args.eval_episodes,
}
return {key: value for key, value in overrides.items() if value is not None}
def main(argv: list[str] | None = None) -> None:
import subprocess
import sys
# Ensure data is downloaded
from pathlib import Path
project_root = Path(__file__).parents[1]
data_dir = project_root / "experiments" / "collected_data"
needs_pull = (not data_dir.exists()) or (not any(data_dir.iterdir()))
if needs_pull:
try:
subprocess.run(["make", "data.pull"], cwd=str(project_root), check=True)
except (subprocess.SubprocessError, OSError) as exc:
sys.path.insert(0, str(project_root))
try:
from scripts.hf_data import pull
pull()
except (ImportError, OSError, RuntimeError, ValueError) as fallback_exc:
print(
f"Warning: data.pull failed ({exc}); fallback pull failed ({fallback_exc})"
)
configure_logging()
raw_args = list(sys.argv[1:] if argv is None else argv)
run_kind = _probe_run_kind(raw_args)
if run_kind == "benchmark":
run_benchmark_cli(_strip_run_kind(raw_args))
return
parser = _build_parser()
args, unknown = parser.parse_known_args(raw_args)
if unknown:
raise ValueError(f"Unknown arguments for training mode: {' '.join(unknown)}")
overrides = _overrides_from_args(args)
scenario = str(args.scenario)
group = args.group
extra_tags = tuple(_parse_tags(args.tags))
if args.sweep_agent:
run_sweep_agent(
project=args.project,
sweep_id=str(args.sweep_id or ""),
count=int(args.count),
offline=bool(args.offline),
no_wandb=bool(args.no_wandb),
base_overrides=overrides,
kind="sweep",
scenario=scenario,
group=group,
extra_tags=extra_tags,
)
return
spec = TrainSpec.from_flat(overrides)
run_train_once(
spec,
project=args.project,
offline=bool(args.offline),
no_wandb=bool(args.no_wandb),
kind="train",
scenario=scenario,
group=group,
extra_tags=extra_tags,
)
if __name__ == "__main__":
main()

View File

@@ -1,40 +0,0 @@
from __future__ import annotations
from dataclasses import dataclass
from typing import Any
from .spec import TrainSpec
from .telemetry.metrics import canonicalize_metrics
@dataclass(frozen=True)
class TrainResult:
spec: TrainSpec
metrics: dict[str, Any]
artifacts: dict[str, str]
events: list[dict[str, Any]]
def run_train(spec: TrainSpec) -> TrainResult:
cfg = spec.to_flat_dict()
algo = spec.algorithm.name
if algo == "qtable":
from .backends.qtable import train_qtable
_, raw_metrics = train_qtable(cfg)
else:
from .backends.sb3 import train_sb3
_, raw_metrics = train_sb3(cfg)
events_raw = raw_metrics.pop("_train_events", [])
events = [evt for evt in events_raw if isinstance(evt, dict)]
metrics = canonicalize_metrics(raw_metrics, spec)
artifacts: dict[str, str] = {}
model_path = raw_metrics.get("model/path")
if isinstance(model_path, str):
artifacts["model/path"] = model_path
return TrainResult(spec=spec, metrics=metrics, artifacts=artifacts, events=events)

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@@ -1,130 +0,0 @@
from __future__ import annotations
import hashlib
import json
import re
from pathlib import Path
from tempfile import TemporaryDirectory
from typing import Any, Mapping
try:
import wandb
from wandb.errors import CommError
HAS_WANDB = True
except ImportError:
HAS_WANDB = False
wandb = None # type: ignore[assignment]
CommError = RuntimeError # type: ignore[assignment]
def _safe_value(value: Any) -> Any:
if isinstance(value, (str, int, float, bool)) or value is None:
return value
if isinstance(value, (list, tuple)):
return [_safe_value(v) for v in value]
if isinstance(value, dict):
return {str(k): _safe_value(value[k]) for k in sorted(value)}
return str(value)
def _safe_scope(scope: str | None) -> str:
raw = "manual" if scope in (None, "") else str(scope)
cleaned = re.sub(r"[^A-Za-z0-9_.-]+", "-", raw).strip("-")
return cleaned or "manual"
def checkpoint_artifact_name(
cfg: Mapping[str, Any], *, backend: str, sweep_id: str | None = None
) -> str:
payload = {k: _safe_value(cfg[k]) for k in sorted(cfg)}
scope = _safe_scope(sweep_id)
canonical = json.dumps(
{"backend": backend, "scope": scope, "cfg": payload},
sort_keys=True,
separators=(",", ":"),
)
digest = hashlib.sha1(canonical.encode("utf-8")).hexdigest()[:14]
return f"phantom-{backend}-ckpt-{scope}-{digest}"[:128]
def _is_missing_artifact_error(exc: Exception) -> bool:
if isinstance(exc, CommError):
msg = str(exc).lower()
return "not found" in msg or "does not exist" in msg
return False
def download_latest_checkpoint(
artifact_name: str, *, file_name: str
) -> tuple[Path, dict[str, Any]] | None:
if not HAS_WANDB or wandb.run is None:
return None
try:
artifact = wandb.run.use_artifact(f"{artifact_name}:latest")
except Exception as exc:
if _is_missing_artifact_error(exc):
return None
raise
directory = Path(artifact.download())
checkpoint_path = directory / file_name
if not checkpoint_path.exists():
return None
metadata = dict(getattr(artifact, "metadata", {}) or {})
return checkpoint_path, metadata
def _aliases_from_metadata(metadata: dict[str, Any] | None) -> list[str]:
aliases = ["latest"]
if metadata is None:
return aliases
if "step" in metadata:
try:
aliases.append(f"step-{int(metadata['step'])}")
except (TypeError, ValueError):
pass
return aliases
def log_checkpoint_bytes(
artifact_name: str,
*,
file_name: str,
payload: bytes,
metadata: dict[str, Any] | None = None,
) -> bool:
if not HAS_WANDB or wandb.run is None:
return False
with TemporaryDirectory(prefix="phantom-ckpt-") as tmpdir:
path = Path(tmpdir) / file_name
path.write_bytes(payload)
artifact = wandb.Artifact(
name=artifact_name,
type="checkpoint",
metadata=metadata or {},
)
artifact.add_file(path.as_posix(), name=file_name)
wandb.log_artifact(artifact, aliases=_aliases_from_metadata(metadata))
return True
def log_checkpoint_file(
artifact_name: str,
*,
file_path: str | Path,
artifact_file_name: str,
metadata: dict[str, Any] | None = None,
) -> bool:
if not HAS_WANDB or wandb.run is None:
return False
src = Path(file_path)
if not src.exists():
return False
artifact = wandb.Artifact(
name=artifact_name,
type="checkpoint",
metadata=metadata or {},
)
artifact.add_file(src.as_posix(), name=artifact_file_name)
wandb.log_artifact(artifact, aliases=_aliases_from_metadata(metadata))
return True

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@@ -1,477 +0,0 @@
import gymnasium as gym
from gymnasium import spaces
import numpy as np
from .engine import Limbo, MarketEngine, PricingEngine
from .lib.render import DashboardRenderer
from .lib.coi import (
compute_uplift_coi,
extract_purchases,
compute_agent_probability,
)
from .lib.behavior import get_transition_models, trajectory_to_events
from .lib.wrappers import EconomicMetricsWrapper
from .jax.robust import select_adversarial_alpha_jax, _JAX_OK
class _ActionPricingEngine(PricingEngine):
def __init__(self, n_products: int, price_bounds: tuple):
self._prices = np.full(n_products, price_bounds[0], dtype=float)
def set_prices(self, prices: np.ndarray):
self._prices = np.asarray(prices, dtype=float)
def act(self, _):
return self._prices
class PHANTOM(gym.Env):
"""Gymnasium wrapper for Limbo pricing-market simulation implementing thesis COI framework
reward = R(p,d) - λ·COI_leak(p,τ') per thesis Section on DR-RL
COI_leak uses behavioral divergence to estimate agent probability f(τ')
robust inner step: min over alpha in Wasserstein interval around nominal alpha
actions are discrete global price-scale moves
"""
metadata = {"render_modes": ["human", "ansi"]}
def __init__(
self,
n_products: int = 10,
alpha: float = 0.3,
N: int = 100,
human_params: tuple = (50.0, 10.0),
agent_params: tuple = (45.0, 15.0),
noise_std: float = 1.0,
price_bounds: tuple = (10.0, 150.0),
lambda_coi: float = 0.1,
coi_window: int = 10,
robust_radius: float = 0.0,
robust_points: int = 5,
robust_rollouts: int = 1,
info_value: float = 1.0,
eta_ux: float = 0.5,
reward_profit_weight: float = 1.0,
action_levels: int = 9,
action_scale_low: float = 0.9,
action_scale_high: float = 1.1,
max_steps: int = 100,
margin_floor: float = 0.05,
margin_floor_patience: int = 5,
render_mode: str = None,
):
super().__init__()
self.n_products = n_products
self.price_bounds = price_bounds
self.lambda_coi = lambda_coi
self.coi_window = coi_window
self.max_steps = max(1, int(max_steps))
self.margin_floor = float(
margin_floor
) # terminate if avg margin stays below this for patience steps
self.margin_floor_patience = max(1, int(margin_floor_patience))
self.render_mode = render_mode
self.alpha = float(alpha)
self.nominal_alpha = float(alpha)
self.N = N
self.human_params = human_params
self.agent_params = agent_params
self.robust_radius = max(0.0, float(robust_radius))
self.robust_points = max(1, int(robust_points))
self.robust_rollouts = max(1, int(robust_rollouts))
self.info_value = float(info_value)
self.eta_ux = float(eta_ux)
self.reward_profit_weight = float(reward_profit_weight)
self.action_levels = max(2, int(action_levels))
self._action_scales = np.linspace(
float(action_scale_low), float(action_scale_high), self.action_levels
)
self.market = MarketEngine(
alpha=alpha,
N=N,
human_params=human_params,
agent_params=agent_params,
noise_std=noise_std,
)
self._platform_stub = _ActionPricingEngine(n_products, price_bounds)
self._limbo = Limbo(self._platform_stub, self.market)
self._set_market_mix(self.nominal_alpha)
self.action_space = spaces.Discrete(self.action_levels)
self.observation_space = spaces.Dict(
{
"demand": spaces.Box(
low=0.0, high=100.0, shape=(n_products,), dtype=np.float32
),
"prices": spaces.Box(
low=price_bounds[0],
high=price_bounds[1],
shape=(n_products,),
dtype=np.float32,
),
"signals": spaces.Box(
low=np.array([0.0, 0.0, 0.0, 0.0], dtype=np.float32),
high=np.array([1.0, 1.0, 1.0, 1.0], dtype=np.float32),
shape=(4,),
dtype=np.float32,
),
}
)
self._prices = None
self._demand = None
self._step_count = 0
self._global_step = 0 # monotonic; used as JAX RNG seed across resets
self._demand_history = []
self._price_history = []
self._revenue_history = []
self._renderer = None
self._initial_episode_prices = None
self._trajectories = [] # session trajectories for agent prob calculation
self.baseline_prices = np.full(self.n_products, self.price_bounds[0])
self.anchor_prices = np.full(
self.n_products,
float(np.clip(float(self.human_params[0]), *self.price_bounds)),
)
self.competitive_cap = float(
min(self.price_bounds[1], float(np.mean(self.anchor_prices)) * 1.15)
)
self._low_margin_streak = 0 # consecutive steps below margin_floor
self._last_agent_prob = float(self.alpha)
self._last_alpha_adv = float(self.alpha)
# load behavioral models for agent probability estimation
try:
self._human_trans, self._agent_trans = get_transition_models()
except Exception:
# fallback if behavioral data unavailable
self._human_trans, self._agent_trans = None, None
def _get_obs(self) -> dict:
demand_arr = np.array(
[self._demand.get(i, 0.0) for i in range(self.n_products)], dtype=np.float32
)
signals = np.array(
[
float(np.clip(self._last_agent_prob, 0.0, 1.0)),
float(np.clip(self._last_alpha_adv, 0.0, 1.0)),
float(np.clip(self.nominal_alpha, 0.0, 1.0)),
float(np.clip(self.robust_radius, 0.0, 1.0)),
],
dtype=np.float32,
)
return {
"demand": demand_arr,
"prices": self._prices.astype(np.float32),
"signals": signals,
}
def _set_market_mix(self, alpha: float):
alpha = float(np.clip(alpha, 0.0, 1.0))
n_agents = int(self.N * alpha)
self.alpha = alpha
self.market.alpha = alpha
self.market.Nagents = n_agents
self.market.Nhumans = self.N - n_agents
def _decode_action(self, action) -> np.ndarray:
prev = self._prices
base = self.anchor_prices
def _blend(target: np.ndarray) -> np.ndarray:
if prev is None:
lower = float(self.price_bounds[0])
return np.clip(target, lower, self.competitive_cap)
blended = 0.75 * np.asarray(prev, dtype=float) + 0.25 * target
lower = float(self.price_bounds[0])
return np.clip(blended, lower, self.competitive_cap)
if np.isscalar(action):
idx = int(np.clip(int(action), 0, self.action_levels - 1))
target = base * self._action_scales[idx]
return _blend(target)
a = np.asarray(action)
if a.size == 1:
idx = int(np.clip(int(a.reshape(-1)[0]), 0, self.action_levels - 1))
target = base * self._action_scales[idx]
return _blend(target)
lower = float(self.price_bounds[0])
return np.clip(a.astype(float), lower, self.competitive_cap)
def _compute_agent_prob(self, trajectories=None) -> float:
trajectories = (
self.market.last_trajectories if trajectories is None else trajectories
)
if not trajectories or self._human_trans is None or self._agent_trans is None:
return float(self.market.alpha)
probs = []
for traj in trajectories:
events = trajectory_to_events(traj)
if len(events) < 2:
continue
probs.append(
compute_agent_probability(events, self._human_trans, self._agent_trans)
)
return float(np.mean(probs)) if probs else float(self.market.alpha)
def _compute_reward(
self, prices: np.ndarray, demand: dict, agent_prob: float, trajectories: list
) -> tuple[float, dict]:
demand_arr = np.array(
[demand.get(i, 0.0) for i in range(self.n_products)], dtype=float
)
revenue = float(np.dot(prices, demand_arr))
floor_cost = float(np.dot(self.baseline_prices, demand_arr))
profit = revenue - floor_cost
purchases = extract_purchases(trajectories)
coi_mix = compute_uplift_coi(prices, purchases, self.baseline_prices)
coi_leakage = float(agent_prob * self.info_value)
info_budget = max(floor_cost, 1.0)
coi_penalty = self.lambda_coi * coi_leakage * info_budget
if len(self._price_history) > 0:
prev_prices = np.asarray(self._price_history[-1], dtype=float)
rel_change = (prices - prev_prices) / np.maximum(prev_prices, 1.0)
volatility = float(np.mean(np.abs(rel_change)))
upward_volatility = float(np.mean(np.clip(rel_change, 0.0, None)))
else:
volatility = 0.0
upward_volatility = 0.0
ux_penalty = self.eta_ux * info_budget * (volatility + 0.5 * upward_volatility)
competitive_anchor = float(np.mean(self.anchor_prices))
price_ratio = prices / max(competitive_anchor, 1.0)
supra_excess = np.clip(price_ratio - 1.15, 0.0, None)
supra_penalty = 4.0 * info_budget * float(np.mean(np.square(supra_excess)))
supra_share = float(np.mean(supra_excess > 0.0))
reward_revenue = self.reward_profit_weight * profit
reward = reward_revenue - coi_penalty - ux_penalty - supra_penalty
return reward, {
"revenue": revenue,
"cost_floor": floor_cost,
"profit": profit,
"coi_mix": float(coi_mix),
"coi_base": 0.0,
"coi_leakage": coi_leakage,
"coi_penalty": coi_penalty,
"coi_info_budget": info_budget,
"ux_penalty": ux_penalty,
"volatility": volatility,
"upward_volatility": upward_volatility,
"supra_penalty": supra_penalty,
"supra_share": supra_share,
"competitive_anchor": competitive_anchor,
"reward_revenue": reward_revenue,
"reward_total": reward,
}
def _alpha_candidates(self) -> np.ndarray:
if self.robust_radius <= 0.0 or self.robust_points == 1:
return np.array([self.nominal_alpha], dtype=float)
lo = max(0.0, self.nominal_alpha - self.robust_radius)
hi = min(1.0, self.nominal_alpha + self.robust_radius)
return np.linspace(lo, hi, self.robust_points)
def _evaluate_candidate(self, alpha: float, prices: np.ndarray) -> float:
self._set_market_mix(alpha)
rewards = []
for _ in range(self.robust_rollouts):
demand = self.market.act(prices)
trajectories = list(self.market.last_trajectories)
agent_prob = self._compute_agent_prob(trajectories)
reward, _ = self._compute_reward(prices, demand, agent_prob, trajectories)
rewards.append(float(reward))
return float(np.mean(rewards)) if rewards else 0.0
def _select_adversarial_alpha(self, prices: np.ndarray) -> float:
"""inner robust step: pick worst-case alpha from the ambiguity interval.
when JAX is available and robust_rollouts==1 we use a vmapped pass over
all K candidates in a single call (no Python loop, no market.act overhead).
the JAX path approximates demand as the mixed closed-form d(p;theta) signal
rather than running full trajectory sampling, which is accurate for the
alpha-selection decision while being dramatically cheaper.
when robust_rollouts>1 or JAX is unavailable we fall back to the sequential
market.act() loop so behavior is identical to the original implementation.
"""
candidates = self._alpha_candidates()
if len(candidates) == 1:
return float(candidates[0])
if _JAX_OK and self.robust_rollouts == 1:
best_alpha, _ = select_adversarial_alpha_jax(
candidates=candidates,
prices=prices,
human_params=self.market.human_params,
agent_params=self.market.agent_params,
noise_std=self.market.noise_std,
baseline_prices=self.baseline_prices,
lambda_coi=self.lambda_coi,
info_value=self.info_value,
reward_profit_weight=self.reward_profit_weight,
rng_seed=self._global_step,
)
return best_alpha
# fallback: full trajectory-based sequential evaluation
evaluations = [
(float(alpha), self._evaluate_candidate(float(alpha), prices))
for alpha in candidates
]
best_alpha, _ = min(evaluations, key=lambda x: x[1])
return best_alpha
def _record_history(self):
demand_arr = np.array(
[self._demand.get(i, 0.0) for i in range(self.n_products)]
)
self._demand_history.append(demand_arr)
self._price_history.append(self._prices.copy())
self._revenue_history.append(np.sum(self._prices * demand_arr))
def reset(self, seed=None, options=None):
super().reset(seed=seed)
self._set_market_mix(self.nominal_alpha)
self._limbo.reset()
self._prices = np.random.uniform(*self.price_bounds, size=self.n_products)
self._platform_stub.set_prices(self._prices)
self._limbo.step()
self._demand = self._limbo.step()
self._initial_episode_prices = self._prices.copy()
self._step_count = 0
self._low_margin_streak = 0
self._demand_history, self._price_history, self._revenue_history = [], [], []
self._trajectories = list(getattr(self.market, "last_trajectories", []))
self._last_agent_prob = float(self.nominal_alpha)
self._last_alpha_adv = float(self.nominal_alpha)
self._record_history()
return self._get_obs(), {}
def step(self, action):
self._prices = self._decode_action(action)
alpha_adv = self._select_adversarial_alpha(self._prices)
self._global_step += 1 # always increment; JAX path may have already done so
self._set_market_mix(alpha_adv)
self._platform_stub.set_prices(self._prices)
self._step_count += 1
self._demand = self.market.act(self._prices)
trajectories = list(self.market.last_trajectories)
agent_prob = self._compute_agent_prob(trajectories)
self._trajectories.extend(trajectories)
self._last_agent_prob = float(agent_prob)
self._last_alpha_adv = float(alpha_adv)
reward, metrics = self._compute_reward(
self._prices, self._demand, agent_prob, trajectories
)
self._record_history()
# soft early termination when margin collapses for too long
avg_margin = float(np.mean(self._prices) - self.price_bounds[0]) / max(
float(np.mean(self._prices)), 1e-6
)
if avg_margin < self.margin_floor:
self._low_margin_streak += 1
else:
self._low_margin_streak = 0
margin_collapsed = self._low_margin_streak >= self.margin_floor_patience
terminated = self._step_count >= self.max_steps or margin_collapsed
info = {
"step": self._step_count,
"agent_prob": agent_prob,
"alpha_adv": float(alpha_adv),
"alpha_nominal": float(self.nominal_alpha),
"wasserstein_radius": float(self.robust_radius),
"robust_rollouts": int(self.robust_rollouts),
**metrics,
"raw_revenue": np.sum(
self._prices
* np.array([self._demand.get(i, 0.0) for i in range(self.n_products)])
),
}
return self._get_obs(), reward, terminated, False, info
def _compute_elasticity(self) -> np.ndarray:
"""point elasticity: e = (dQ/dP) * (P/Q) via finite differences, clipped to [-5, 5]"""
if len(self._price_history) < 2:
return np.zeros(self.n_products)
p, q = np.array(self._price_history), np.array(self._demand_history)
dp, dq = np.diff(p, axis=0), np.diff(q, axis=0)
valid = np.abs(dp) > 0.5
with np.errstate(divide="ignore", invalid="ignore"):
elasticity = np.where(
valid, (dq / dp) * (p[:-1] / np.maximum(q[:-1], 1.0)), 0.0
)
elasticity = np.nan_to_num(np.clip(elasticity, -5.0, 5.0), nan=0.0)
return (
np.mean(elasticity, axis=0)
if len(elasticity) > 0
else np.zeros(self.n_products)
)
def render(self):
if self.render_mode == "human":
if self._renderer is None:
self._renderer = DashboardRenderer()
self._renderer.render(self)
elif self.render_mode == "ansi":
return (
f"step={self._step_count}, prices={self._prices}, demand={self._demand}"
)
return None
def close(self):
if self._renderer:
self._renderer.close()
self._renderer = None
if __name__ == "__main__":
import wandb
from .lib import MetricsCallback
class RandomPolicy:
"""Minimal SB3-compatible random policy for baseline testing."""
def __init__(self, env):
self.env = env
self.num_timesteps = 0
def learn(self, total_timesteps, callback=None):
callback.model = self
callback.num_timesteps = 0
callback.locals = {}
callback.on_training_start({}, {})
obs, _ = self.env.reset()
for step in range(total_timesteps):
action = self.env.action_space.sample()
obs, reward, term, trunc, info = self.env.step(action)
self.num_timesteps = step + 1
callback.num_timesteps = self.num_timesteps
callback.locals = {"infos": [info]}
callback.on_step()
if term or trunc:
callback.on_rollout_end()
obs, _ = self.env.reset()
return self
def predict(self, obs, **kwargs):
return self.env.action_space.sample(), None
wandb.init(project="capstone", config={"policy": "random", "alpha": 0.3})
env = EconomicMetricsWrapper(PHANTOM(n_products=15, alpha=0.3, render_mode=None))
model = RandomPolicy(env)
model.learn(total_timesteps=1000, callback=MetricsCallback())
print(f"Episode revenue: {env.episode_revenue:.1f}")
wandb.finish()
env.close()

View File

@@ -1,117 +0,0 @@
from supabase import create_client, Client
import os
import random
import asyncio
import json
from dotenv import load_dotenv
from experiments.agents.agent import get_agent, AgentTypes
from lib.kafka_client import get_interactions
load_dotenv()
RESULTS="/home/velocitatem/Documents/Projects/PHANTOM/experiments/agents/collected_data/"
client = create_client(
os.getenv("NEXT_PUBLIC_SUPABASE_URL"),
os.getenv("NEXT_PUBLIC_SUPABASE_ANON_KEY")
)
def pick_random_task():
mode = 'hotel'
tasks = client.table("tasks").select("*").execute().data
if mode == 'hotel':
# drop all that have 'flight' in the description
tasks = [task for task in tasks if 'flight' not in task['task_description'].lower()]
return random.choice(tasks) if tasks else None
def clear_kafka_data():
"""Delete and recreate Kafka topics to clear all data"""
from kafka.admin import KafkaAdminClient, NewTopic
from kafka.errors import UnknownTopicOrPartitionError
import time
kafka_host = os.getenv('KAFKA_HOST', 'localhost')
kafka_port = os.getenv('KAFKA_PORT', '9092')
broker = f'{kafka_host}:{kafka_port}'
admin = KafkaAdminClient(bootstrap_servers=broker)
topics = ['user-interactions', 'price-logs']
try:
admin.delete_topics(topics, timeout_ms=5000)
print(f"Deleted topics: {topics}")
time.sleep(2)
except UnknownTopicOrPartitionError:
print("Topics don't exist, skipping delete")
except Exception as e:
print(f"Error deleting topics: {e}")
new_topics = [
NewTopic(name='user-interactions', num_partitions=3, replication_factor=1),
NewTopic(name='price-logs', num_partitions=3, replication_factor=1)
]
try:
admin.create_topics(new_topics=new_topics, validate_only=False)
print(f"Recreated topics: {topics}")
except Exception as e:
print(f"Error creating topics: {e}")
finally:
admin.close()
def create_new_experiment(task_id):
import uuid
subject_name = f"agent_{str(uuid.uuid4())[:8]}"
experiment = {
"subject_name": subject_name,
"xp_human_only": False,
"xp_market_mode": "hotel",
"xp_task_id": task_id,
}
response = client.table("experiments").insert(experiment).execute()
return response.data[0] if response.data else None
if __name__ == "__main__":
clear_kafka_data()
task = pick_random_task()
if not task:
print("No tasks available")
exit(1)
experiment = create_new_experiment(task['id'])
exp_id = experiment['id']
exp_dir = f"{RESULTS}{exp_id}"
os.makedirs(exp_dir, exist_ok=True)
# construct experiment URL with uuid param
base_url = os.getenv('NEXT_PUBLIC_API_BASE', 'http://localhost:3000')
agent_url = f"{base_url}/start-task?uuid={exp_id}"
print(f"Created experiment {exp_id} for task {task['id']}")
print(f"Agent will interact with: {agent_url}")
# instantiate and run agent
agent = get_agent(
AgentTypes.GENERIC_BROWSER_USE_AGENT,
goal=task['task_description'],
url=agent_url,
timeout=300,
headless=True
)
result = asyncio.run(agent.act())
print(f"Agent result: {result}")
# export interaction and price data from kafka
interactions = get_interactions(topic='user-interactions', timeout_ms=3000)
prices = get_interactions(topic='price-logs', timeout_ms=3000)
with open(f"{exp_dir}/int.json", 'w') as f:
json.dump(interactions, f, indent=2)
with open(f"{exp_dir}/price.json", 'w') as f:
json.dump(prices, f, indent=2)
print(f"Experiment {exp_id} completed.")
print(f"Exported {len(interactions)} interactions and {len(prices)} price logs to {exp_dir}")

View File

@@ -1,269 +0,0 @@
"""
Session-Aware Pricing DAG
THIS implements the core pricing computation (policy layer).
Flow: τ → θ̂ → D → p*
1. Fetch recent sessions from Kafka (last 10 active)
2. Extract features per session (τ → θ̂)
3. Map features to demand proxy (θ̂ → D)
4. Compute optimal prices (D → p*)
5. Write to Redis session:{sessionId}:prices
Scheduled: every 1 minute when enabled
"""
from airflow import DAG
from airflow.operators.python import PythonOperator
from airflow.utils.dates import days_ago
from datetime import timedelta
import pandas as pd
import numpy as np
import logging
import sys
import pickle
sys.path.insert(0, '/opt/airflow')
from procesing.context import PipelineContext
from procesing.providers import SupabaseProvider, BackendAPIProvider
from procesing.steps.session import ExtractSessionFeaturesStep
from procesing.pricers.simple import SimpleSurgePricer, session_features_to_demand
from procesing.pricing import StateSpace
from lib.model_registry import ModelRegistry
DEFAULT_ARGS = {
'owner': 'phantom-research',
'depends_on_past': False,
'email_on_failure': False,
'email_on_retry': False,
'retries': 1,
'retry_delay': timedelta(seconds=30),
}
class CompositeProvider(SupabaseProvider, BackendAPIProvider):
def __init__(self):
SupabaseProvider.__init__(self)
BackendAPIProvider.__init__(self)
def _get_context(store_mode: str = 'hotel') -> PipelineContext:
return PipelineContext(provider=CompositeProvider(), store_mode=store_mode)
def fetch_recent_sessions(**kwargs):
"""
Task: Fetch last N active sessions from Kafka.
Returns: DataFrame of interaction events for recent sessions.
"""
dag_conf = kwargs.get('dag_run').conf if kwargs.get('dag_run') else {}
store_mode = dag_conf.get('store_mode', 'hotel')
session_limit = dag_conf.get('session_limit', 10)
ctx = _get_context(store_mode)
provider = ctx.provider
# fetch all recent interactions from Kafka
try:
interactions_df = provider.fetch_kafka_topic("user-interactions")
except Exception as e:
logging.error(f"Failed to fetch interactions: {e}")
kwargs['ti'].xcom_push(key='sessions_data', value=pickle.dumps(pd.DataFrame()))
return 0
if interactions_df.empty or 'sessionId' not in interactions_df.columns:
kwargs['ti'].xcom_push(key='sessions_data', value=pickle.dumps(pd.DataFrame()))
return 0
# identify last N active sessions (most recent by event count)
recent_sessions = interactions_df['sessionId'].value_counts().head(session_limit).index.tolist()
# filter to only those sessions
filtered_df = interactions_df[interactions_df['sessionId'].isin(recent_sessions)].copy()
kwargs['ti'].xcom_push(key='sessions_data', value=pickle.dumps(filtered_df))
kwargs['ti'].xcom_push(key='session_ids', value=recent_sessions)
logging.info(f"Fetched {len(filtered_df)} events for {len(recent_sessions)} sessions")
return len(recent_sessions)
def extract_session_features(**kwargs):
"""
Task: Extract behavioral features from session trajectories.
THIS implements τ → θ̂ transformation.
"""
ti = kwargs['ti']
sessions_df = pickle.loads(ti.xcom_pull(key='sessions_data'))
if sessions_df.empty:
ti.xcom_push(key='session_features', value=pickle.dumps(pd.DataFrame()))
return 0
dag_conf = kwargs.get('dag_run').conf if kwargs.get('dag_run') else {}
ctx = _get_context(dag_conf.get('store_mode', 'hotel'))
# extract features using vectorized pipeline
feature_extractor = ExtractSessionFeaturesStep(ctx)
features_df = feature_extractor.transform(sessions_df)
ti.xcom_push(key='session_features', value=pickle.dumps(features_df))
logging.info(f"Extracted {len(features_df.columns)} features for {len(features_df)} sessions")
logging.info(f"Feature columns: {list(features_df.columns)}")
logging.info(f"Sample features (first session):\n{features_df.iloc[0].to_dict()}")
return len(features_df)
def compute_session_prices(**kwargs):
"""
Task: Compute optimal prices for each session.
THIS implements θ̂ → D → p* transformation.
"""
ti = kwargs['ti']
features_df = pickle.loads(ti.xcom_pull(key='session_features'))
if features_df.empty:
ti.xcom_push(key='price_results', value=pickle.dumps({}))
return 0
dag_conf = kwargs.get('dag_run').conf if kwargs.get('dag_run') else {}
store_mode = dag_conf.get('store_mode', 'hotel')
ctx = _get_context(store_mode)
# fetch product catalog for base prices
products_df = ctx.provider.fetch_products(store_mode)
if products_df.empty:
logging.error("No products found in catalog")
ti.xcom_push(key='price_results', value=pickle.dumps({}))
return 0
products_df['base_price'] = products_df['metadata'].apply(
lambda m: m.get('base_price', 100.0) if isinstance(m, dict) else 100.0
)
# initialize pricing model
pricer = SimpleSurgePricer(
high_threshold=dag_conf.get('high_threshold', 10),
low_threshold=dag_conf.get('low_threshold', 2),
surge_multiplier=dag_conf.get('surge_multiplier', 1.15),
discount_multiplier=dag_conf.get('discount_multiplier', 0.95)
)
pricer.fit(products_df)
# compute prices per session
price_results = {}
n_products = len(products_df)
logging.info(f"Starting price computation for {len(features_df)} sessions, {n_products} products")
logging.info(f"Pricer config: high_thresh={pricer.high_threshold}, low_thresh={pricer.low_threshold}, surge_mult={pricer.surge_multiplier}")
for idx, session_row in features_df.iterrows():
session_id = session_row.get('sessionId')
if not session_id:
continue
# map features to demand proxy (θ̂ → D)
session_features_single = pd.DataFrame([session_row])
demand_proxy = session_features_to_demand(session_features_single)
logging.info(f"[Session {session_id}] Features → Demand: {demand_proxy:.2f}")
logging.info(f"[Session {session_id}] Key features: velocity={session_row.get('interaction_velocity', 0):.2f}, cart_ratio={session_row.get('cart_to_view_ratio', 0):.2f}, item_views={session_row.get('item_views', 0)}")
# build state space
state_space = StateSpace(
demand=np.full(n_products, demand_proxy), # broadcast session demand to all products
prices=products_df['base_price'].values,
session_features=session_features_single
)
# compute optimal prices (D → p*)
optimal_prices = pricer.predict(state_space)
base_avg = products_df['base_price'].mean()
optimal_avg = optimal_prices.mean()
price_change_pct = ((optimal_avg - base_avg) / base_avg) * 100
logging.info(f"[Session {session_id}] Price adjustment: base_avg={base_avg:.2f}, optimal_avg={optimal_avg:.2f}, change={price_change_pct:+.1f}%")
# store as dict {productId: price}
price_map = {
str(products_df.iloc[i]['id']): float(optimal_prices[i])
for i in range(n_products)
}
price_results[session_id] = price_map
ti.xcom_push(key='price_results', value=pickle.dumps(price_results))
logging.info(f"Computed prices for {len(price_results)} sessions, {n_products} products each")
return len(price_results)
def publish_to_registry(**kwargs):
"""
Task: Write session prices to Redis registry.
THIS is the write path: prices → session:{sessionId}:prices
"""
ti = kwargs['ti']
price_results = pickle.loads(ti.xcom_pull(key='price_results'))
if not price_results:
logging.warning("No prices to publish")
return 0
registry = ModelRegistry()
ttl = kwargs.get('dag_run').conf.get('ttl', 1800) if kwargs.get('dag_run') and kwargs.get('dag_run').conf else 1800
published_count = 0
for session_id, price_map in price_results.items():
registry.set_session_prices(session_id, price_map, ttl=ttl)
published_count += 1
logging.info(f"Published prices for {published_count} sessions to registry (TTL={ttl}s)")
return {
'sessions_published': published_count,
'products_per_session': len(next(iter(price_results.values()))) if price_results else 0,
'status': 'success'
}
# DAG definition
with DAG(
'session_pricing_pipeline',
default_args=DEFAULT_ARGS,
description='Session-aware pricing: extract features → compute prices → publish to registry',
schedule_interval='*/1 * * * *', # every 1 minute
start_date=days_ago(1),
catchup=False,
max_active_runs=1,
tags=['pricing', 'session-aware', 'research', 'real-time'],
) as dag:
t_fetch_sessions = PythonOperator(
task_id='fetch_recent_sessions',
python_callable=fetch_recent_sessions,
provide_context=True,
)
t_extract_features = PythonOperator(
task_id='extract_session_features',
python_callable=extract_session_features,
provide_context=True,
)
t_compute_prices = PythonOperator(
task_id='compute_session_prices',
python_callable=compute_session_prices,
provide_context=True,
)
t_publish = PythonOperator(
task_id='publish_to_registry',
python_callable=publish_to_registry,
provide_context=True,
)
# linear dependency: fetch → extract → compute → publish
t_fetch_sessions >> t_extract_features >> t_compute_prices >> t_publish

View File

@@ -1,4 +1,3 @@
from pandas.core.algorithms import factorize_array
from airflow import DAG
from airflow.operators.python import PythonOperator
from airflow.utils.dates import days_ago
@@ -209,12 +208,3 @@ def create_surge_pricing_dag(store_mode: str) -> DAG:
# instantiate DAGs for Airflow to discover
dag_airline = create_surge_pricing_dag('airline')
dag_hotel = create_surge_pricing_dag('hotel')
# TODO: Refactor this factory from a surge pricing factory to a general pricing factory
# We will do this by passing a pricing strategy class to the factory, since the generic pipeline is:
# take all interaction data, group by sessionId and assign a new price vector to each session
# in the grouping we get a subset of the interactions per sessionId and we can map that to some Features
# we define a custom _get_features(interactions .) methodin the strategy class
# we then run only the inference which is the .predict(trajectory) per-session which will give us a new price vector
# this we then publish for each sessionId group
# this might include no deleting most of the pricers we have defined and starting with a super simple surge-pricing algorithm that is no-fit only predict. This we can then test end-to-end and observe changes to prices according to a desired strategy - we have to define this one as a very short term strategy because we run sessions that take only a few minutes.

View File

@@ -120,31 +120,15 @@ def apply_surge_pricing(**kwargs):
# rename demand_score to demand for pricer compatibility
data = product_features.rename(columns={'demand_score': 'demand'})
high_thresh = dag_conf.get('high_threshold', 10)
low_thresh = dag_conf.get('low_threshold', 2)
surge_mult = dag_conf.get('surge_multiplier', 1.2)
discount_mult = dag_conf.get('discount_multiplier', 0.9)
logging.info(f"Surge pricing config: high_thresh={high_thresh}, low_thresh={low_thresh}, surge_mult={surge_mult}, discount_mult={discount_mult}")
logging.info(f"Demand stats: min={data['demand'].min():.2f}, max={data['demand'].max():.2f}, mean={data['demand'].mean():.2f}")
logging.info(f"Products with high demand (>={high_thresh}): {(data['demand'] >= high_thresh).sum()}")
logging.info(f"Products with low demand (<={low_thresh}): {(data['demand'] <= low_thresh).sum()}")
surge_pricer = SimpleSurgePricer(
high_threshold=high_thresh,
low_threshold=low_thresh,
surge_multiplier=surge_mult,
discount_multiplier=discount_mult
high_threshold=dag_conf.get('high_threshold', 10),
low_threshold=dag_conf.get('low_threshold', 2),
surge_multiplier=dag_conf.get('surge_multiplier', 1.2),
discount_multiplier=dag_conf.get('discount_multiplier', 0.9)
)
surge_pricer.fit(data)
data['optimal_price'] = surge_pricer.predict()
base_avg = data['base_price'].mean()
optimal_avg = data['optimal_price'].mean()
price_change_pct = ((optimal_avg - base_avg) / base_avg) * 100
logging.info(f"Price adjustment: base_avg={base_avg:.2f}, optimal_avg={optimal_avg:.2f}, change={price_change_pct:+.1f}%")
prices_df = data[['productId', 'price', 'base_price', 'optimal_price', 'demand']].rename(columns={
'price': 'current_price',
'demand': 'demand_score'

View File

@@ -1,21 +1,11 @@
from .evals import evaluate
from .arch import (
XGBoostAgentClassifier,
LightGBMAgentClassifier,
ContrastiveWeakClassifier,
TrajectoryEncoder,
WeakClassifier,
contrastive_loss,
featurize_trajectory,
LightGBMAgentClassifier
)
__all__ = [
__all__ =[
'evaluate',
'XGBoostAgentClassifier',
'LightGBMAgentClassifier',
'ContrastiveWeakClassifier',
'TrajectoryEncoder',
'WeakClassifier',
'contrastive_loss',
'featurize_trajectory',
'LightGBMAgentClassifier'
]

View File

@@ -1,212 +1,122 @@
# sklearn compatible models for agent detection
from sklearn.base import BaseEstimator, ClassifierMixin
from typing import Any, Optional, Tuple, Dict, List
from procesing.context import PipelineContext
from typing import Any, Optional, Tuple
from abc import ABC, abstractmethod
from collections import defaultdict
import xgboost as xgb
import lightgbm as lgb
import numpy as np
import pandas as pd
import torch
import torch.nn as nn
import torch.nn.functional as F
import sys
from pathlib import Path
# add lib to path for imports
sys.path.insert(0, str(Path(__file__).parent.parent.parent / 'lib'))
from lib.features import (
transition_histogram as _lib_transition_histogram,
temporal_signature as _lib_temporal_signature,
state_coverage as _lib_state_coverage,
transition_entropy as _lib_transition_entropy,
featurize_trajectory as _lib_featurize_trajectory,
parse_timestamp
)
from lib.state import event_to_state, get_event_name, get_timestamp
TASK = 'classification'
LABELS = ['human', 'agent']
class WeakClassifier(BaseEstimator, ClassifierMixin, ABC):
# a simple contrastive machine learning model learns to distinguish human/agent behavior
# using weakly supervised contrastive learning + augmentation
def __init__(self, **kwargs):
super().__init__()
self.model = None
self.kwargs = kwargs
class BaseAgentClassifier(BaseEstimator, ClassifierMixin, ABC):
"""Base class for tree-based agent detection classifiers with common logic"""
class TrajectoryEncoder(nn.Module):
"""Encode variable-length event sequences to fixed-dim embedding via bidirectional LSTM"""
def __init__(self, input_dim: int, embed_dim: int = 32, hidden_dim: int = 64):
super().__init__()
self.event_embed = nn.Linear(input_dim, hidden_dim)
self.lstm = nn.LSTM(hidden_dim, hidden_dim, batch_first=True, bidirectional=True)
self.proj = nn.Linear(hidden_dim * 2, embed_dim)
def forward(self, x: torch.Tensor) -> torch.Tensor: # x: (batch, seq_len, input_dim)
h = F.relu(self.event_embed(x))
_, (hn, _) = self.lstm(h)
hn = torch.cat([hn[-2], hn[-1]], dim=1) # concat bidirectional hidden states
return F.normalize(self.proj(hn), dim=1) # L2 normalized
class ContrastiveWeakClassifier(WeakClassifier):
"""Contrastive learning classifier for human/agent trajectory discrimination"""
def __init__(self, input_dim: int = 64, embed_dim: int = 32, margin: float = 1.0, **kwargs):
super().__init__(**kwargs)
self.input_dim = input_dim
self.embed_dim = embed_dim
self.margin = margin
self.encoder = TrajectoryEncoder(input_dim, embed_dim)
self.classifier = nn.Linear(embed_dim, 2)
self.device = torch.device('cuda' if torch.cuda.is_available() else 'cpu')
self._fitted = False
def to_device(self):
self.encoder.to(self.device)
self.classifier.to(self.device)
return self
def encode(self, x: torch.Tensor) -> torch.Tensor:
return self.encoder(x.to(self.device))
def forward(self, x: torch.Tensor) -> torch.Tensor:
emb = self.encode(x)
return self.classifier(emb)
def fit(self, X, y=None): # sklearn interface - actual training in weak.train.py
self._fitted = True
return self
def predict(self, X: np.ndarray) -> np.ndarray:
self.encoder.eval()
self.classifier.eval()
with torch.no_grad():
x = torch.tensor(X, dtype=torch.float32).unsqueeze(1).to(self.device)
logits = self.forward(x)
return torch.argmax(logits, dim=1).cpu().numpy()
def predict_proba(self, X: np.ndarray) -> np.ndarray:
self.encoder.eval()
self.classifier.eval()
with torch.no_grad():
x = torch.tensor(X, dtype=torch.float32).unsqueeze(1).to(self.device)
logits = self.forward(x)
return F.softmax(logits, dim=1).cpu().numpy()
def contrastive_loss(anchor: torch.Tensor, positive: torch.Tensor, negative: torch.Tensor, margin: float = 0.3) -> torch.Tensor:
"""Triplet loss using cosine similarity (for L2-normalized embeddings). margin in [0,1] range."""
pos_sim = F.cosine_similarity(anchor, positive) # higher = more similar
neg_sim = F.cosine_similarity(anchor, negative)
return F.relu(neg_sim - pos_sim + margin).mean() # want pos_sim > neg_sim + margin
def nt_xent_loss(z_i: torch.Tensor, z_j: torch.Tensor, temperature: float = 0.5) -> torch.Tensor:
"""Normalized temperature-scaled cross entropy loss (SimCLR style)"""
batch_size = z_i.size(0)
z = torch.cat([z_i, z_j], dim=0) # (2N, embed_dim)
sim = F.cosine_similarity(z.unsqueeze(1), z.unsqueeze(0), dim=2) / temperature
mask = torch.eye(2 * batch_size, dtype=torch.bool, device=z.device)
sim.masked_fill_(mask, -float('inf'))
labels = torch.arange(batch_size, device=z.device)
labels = torch.cat([labels + batch_size, labels]) # positive pairs
return F.cross_entropy(sim, labels)
# feature extraction utilities - delegating to lib.features for unified implementation
# these wrappers maintain backwards compatibility for existing imports
def transition_histogram(events: List, state_fn, max_states: int = 50) -> np.ndarray:
"""Compute normalized histogram of state transitions in trajectory"""
return _lib_transition_histogram(events, state_fn, max_states)
def temporal_signature(events: List, ts_fn) -> np.ndarray:
"""Extract temporal features: mean/std/skew of inter-event times"""
return _lib_temporal_signature(events, ts_fn)
def state_coverage(events: List, state_fn, mdp_states: set) -> float:
"""Fraction of MDP states visited by trajectory"""
return _lib_state_coverage(events, state_fn, mdp_states)
def transition_entropy(events: List, state_fn) -> float:
"""Compute entropy of transition distribution (randomness of navigation)"""
return _lib_transition_entropy(events, state_fn)
def featurize_trajectory(events: List, mdp: Optional[Dict] = None, input_dim: int = 64) -> np.ndarray:
"""Convert trajectory to fixed-dim feature vector - uses lib.features implementation"""
mdp_states = set(mdp.get('states', [])) if mdp else set()
def _ts_fn(e):
return parse_timestamp(get_timestamp(e))
def _event_name_fn(e):
return get_event_name(e)
return _lib_featurize_trajectory(events, event_to_state, _ts_fn, _event_name_fn, mdp_states, input_dim)
# gradient boosting classifiers for comparison baselines
class XGBoostAgentClassifier(BaseEstimator, ClassifierMixin):
"""XGBoost classifier for human/agent detection from session features"""
def __init__(self, n_estimators: int = 100, max_depth: int = 6, learning_rate: float = 0.1, **kwargs):
def __init__(self, context: Optional[PipelineContext] = None, n_estimators: int = 200,
max_depth: int = 6, learning_rate: float = 0.05,
early_stopping_rounds: int = 20):
self.context = context
self.n_estimators = n_estimators
self.max_depth = max_depth
self.learning_rate = learning_rate
self.model = None
self.kwargs = kwargs
self.early_stopping_rounds = early_stopping_rounds
self.model_ = None
self.feature_names_ = None
def _to_array(self, X):
"""Convert pandas structures to numpy arrays"""
return X.values if isinstance(X, (pd.DataFrame, pd.Series)) else X
def _compute_pos_weight(self, y_arr):
"""Calculate scale_pos_weight for class imbalance handling"""
n_neg, n_pos = (y_arr == 0).sum(), (y_arr == 1).sum()
return n_neg / n_pos if n_pos > 0 else 1.0
def _prepare_eval_set(self, eval_set):
"""Convert eval_set to numpy arrays if needed"""
if not eval_set:
return None
X_val, y_val = eval_set[0]
return [(self._to_array(X_val), self._to_array(y_val))]
@abstractmethod
def _build_model(self, scale_pos: float):
"""Build the underlying model instance (must be implemented by subclasses)"""
pass
@abstractmethod
def _fit_with_eval(self, X_arr, y_arr, eval_arr):
"""Fit model with evaluation set (must be implemented by subclasses)"""
pass
def fit(self, X, y, eval_set=None):
X_arr, y_arr = self._to_array(X), self._to_array(y)
if isinstance(X, pd.DataFrame):
self.feature_names_ = X.columns.tolist()
scale_pos = self._compute_pos_weight(y_arr)
self.model_ = self._build_model(scale_pos)
eval_arr = self._prepare_eval_set(eval_set)
if eval_arr:
self._fit_with_eval(X_arr, y_arr, eval_arr)
else:
self.model_.fit(X_arr, y_arr)
def fit(self, X: np.ndarray, y: np.ndarray):
try:
import xgboost as xgb
self.model = xgb.XGBClassifier(n_estimators=self.n_estimators, max_depth=self.max_depth,
learning_rate=self.learning_rate, **self.kwargs)
self.model.fit(X, y)
except ImportError:
raise ImportError("xgboost required for XGBoostAgentClassifier")
return self
def predict(self, X: np.ndarray) -> np.ndarray:
if self.model is None:
raise ValueError("fit the model first")
return self.model.predict(X)
def predict(self, X):
return self.model_.predict(self._to_array(X))
def predict_proba(self, X: np.ndarray) -> np.ndarray:
if self.model is None:
raise ValueError("fit the model first")
return self.model.predict_proba(X)
def predict_proba(self, X):
return self.model_.predict_proba(self._to_array(X))
@property
def feature_importances_(self):
return self.model_.feature_importances_ if self.model_ else None
class LightGBMAgentClassifier(BaseEstimator, ClassifierMixin):
"""LightGBM classifier for human/agent detection from session features"""
def __init__(self, n_estimators: int = 100, max_depth: int = -1, learning_rate: float = 0.1, **kwargs):
self.n_estimators = n_estimators
self.max_depth = max_depth
self.learning_rate = learning_rate
self.model = None
self.kwargs = kwargs
class XGBoostAgentClassifier(BaseAgentClassifier):
"""XGBoost binary classifier for agent detection with class imbalance handling"""
def fit(self, X: np.ndarray, y: np.ndarray):
try:
import lightgbm as lgb
self.model = lgb.LGBMClassifier(n_estimators=self.n_estimators, max_depth=self.max_depth,
learning_rate=self.learning_rate, verbose=-1, **self.kwargs)
self.model.fit(X, y)
except ImportError:
raise ImportError("lightgbm required for LightGBMAgentClassifier")
return self
def _build_model(self, scale_pos: float):
return xgb.XGBClassifier(
n_estimators=self.n_estimators,
max_depth=self.max_depth,
learning_rate=self.learning_rate,
scale_pos_weight=scale_pos,
eval_metric='auc',
early_stopping_rounds=self.early_stopping_rounds,
random_state=42,
tree_method='hist',
enable_categorical=False
)
def predict(self, X: np.ndarray) -> np.ndarray:
if self.model is None:
raise ValueError("fit the model first")
return self.model.predict(X)
def _fit_with_eval(self, X_arr, y_arr, eval_arr):
self.model_.fit(X_arr, y_arr, eval_set=eval_arr, verbose=False)
def predict_proba(self, X: np.ndarray) -> np.ndarray:
if self.model is None:
raise ValueError("fit the model first")
return self.model.predict_proba(X)
class LightGBMAgentClassifier(BaseAgentClassifier):
"""LightGBM binary classifier for agent detection with class imbalance handling"""
def _build_model(self, scale_pos: float):
return lgb.LGBMClassifier(
n_estimators=self.n_estimators,
max_depth=self.max_depth,
learning_rate=self.learning_rate,
scale_pos_weight=scale_pos,
metric='auc',
random_state=42,
verbosity=-1
)
def _fit_with_eval(self, X_arr, y_arr, eval_arr):
self.model_.fit(
X_arr, y_arr,
eval_set=eval_arr,
callbacks=[lgb.early_stopping(self.early_stopping_rounds, verbose=False)]
)

View File

@@ -1 +0,0 @@
from .encoder import Window, extract_windows, build_windows, WindowDataset, PrototypeClassifier, train, loocv

View File

@@ -1,210 +0,0 @@
"""Contrastive encoder via trajectory windowing. Classification by prototype distance."""
import sys
sys.path.insert(0, "/home/velocitatem/Documents/Projects/PHANTOM/sim/rl/behavior_loader")
sys.path.insert(0, "/home/velocitatem/Documents/Projects/PHANTOM/experiments/ml")
from sim.rl.behavior_loader.loader import JointLoader, PayloadModel
from arch import TrajectoryEncoder, featurize_trajectory, nt_xent_loss
from typing import List, Dict, Tuple
from dataclasses import dataclass
from datetime import datetime
import numpy as np, torch, torch.nn.functional as F, random, optuna
from torch.utils.data import Dataset, DataLoader
from torch.optim import Adam
from torch.utils.tensorboard import SummaryWriter
RUNS = "/home/velocitatem/Documents/Projects/PHANTOM/experiments/ml/runs"
AGENT_DIR = "/home/velocitatem/Documents/Projects/PHANTOM/experiments/agents/collected_data/"
HUMAN_DIR = "/home/velocitatem/Documents/Projects/PHANTOM/experiments/collected_data/"
@dataclass
class Window:
events: List[PayloadModel]
traj_id: str
label: int # 0=human, 1=agent
def extract_windows(events: List[PayloadModel], traj_id: str, label: int,
sizes: List[int] = [5, 10, 15], stride: int = 2) -> List[Window]:
"""Multi-scale overlapping windows from trajectory"""
n = len(events)
wins = [Window(events[i:i+s], traj_id, label) for s in sizes if n >= s for i in range(0, n-s+1, stride)]
if n >= 3: wins.append(Window(events, traj_id, label)) # full traj
return wins
def build_windows(data: Dict[str, List], sizes=[5,10,15], stride=2) -> List[Window]:
return [w for tid, evts in data.items()
for w in extract_windows(evts, tid, 0 if tid.startswith('human_') else 1, sizes, stride)]
class WindowDataset(Dataset):
"""Yields (anchor, positive) pairs from same class"""
def __init__(self, windows: List[Window], dim: int = 64):
self.wins, self.dim = windows, dim
self.by_label = {0: [i for i,w in enumerate(windows) if w.label==0],
1: [i for i,w in enumerate(windows) if w.label==1]}
self.by_traj = {}
for i, w in enumerate(windows): self.by_traj.setdefault(w.traj_id, []).append(i)
def __len__(self): return len(self.wins)
def _feat(self, evts): return featurize_trajectory(evts, None, self.dim)
def _aug(self, evts): # subsample 70-100%
if len(evts) < 4: return evts
k = max(3, int(len(evts) * random.uniform(0.7, 1.0)))
start = random.randint(0, len(evts) - k)
return evts[start:start+k]
def __getitem__(self, idx):
w = self.wins[idx]
pool = [i for i in self.by_label[w.label] if self.wins[i].traj_id != w.traj_id]
pos_idx = random.choice(pool) if pool else idx
a = torch.tensor(self._feat(self._aug(w.events)), dtype=torch.float32)
p = torch.tensor(self._feat(self._aug(self.wins[pos_idx].events)), dtype=torch.float32)
return a, p, w.label
class PrototypeClassifier:
"""Classify by distance to class centroids"""
def __init__(self, encoder: TrajectoryEncoder, device = 'cuda', dim=64):
self.enc, self.dev, self.dim = encoder, device, dim
self.centroids = {0: None, 1: None}
def fit(self, windows: List[Window]):
self.enc.eval()
embs = {0: [], 1: []}
with torch.no_grad():
for w in windows:
x = torch.tensor(featurize_trajectory(w.events, None, self.dim), dtype=torch.float32)
z = self.enc(x.unsqueeze(0).unsqueeze(1).to(self.dev))
embs[w.label].append(z)
self.centroids = {k: torch.cat(v).mean(0, keepdim=True) if v else None for k, v in embs.items()}
return self
def predict(self, events: List[PayloadModel]) -> Tuple[int, float, Dict]:
"""Returns (pred, confidence, debug). Confidence via softmax over -distances."""
self.enc.eval()
with torch.no_grad():
x = torch.tensor(featurize_trajectory(events, None, self.dim), dtype=torch.float32)
z = self.enc(x.unsqueeze(0).unsqueeze(1).to(self.dev))
dists = {k: torch.norm(z - c, dim=1).item() for k, c in self.centroids.items() if c is not None}
if not dists: return 0, 0.0, {'d': {}, 'p': [0.5, 0.5]}
pred = min(dists, key=dists.get)
d0, d1 = dists.get(0, 1e6), dists.get(1, 1e6) # softmax(-d) gives higher prob to closer centroid
probs = F.softmax(torch.tensor([[-d0, -d1]]), dim=1).squeeze()
return pred, probs[pred].item(), {'d': dists, 'p': probs.tolist()}
def train(epochs=200, lr=5e-4, batch=16, dim=64, emb=32, temp=0.5,
sizes=[5,10,15], stride=2, name=None, verbose=True):
data = JointLoader(HUMAN_DIR, AGENT_DIR).get_data()
wins = build_windows(data, sizes, stride)
if verbose: print(f"Windows: {len(wins)} ({sum(w.label==0 for w in wins)}h/{sum(w.label==1 for w in wins)}a)")
dev = torch.device('cuda' if torch.cuda.is_available() else 'cpu')
enc = TrajectoryEncoder(dim, emb).to(dev)
opt = Adam(enc.parameters(), lr=lr)
loader = DataLoader(WindowDataset(wins, dim), batch_size=batch, shuffle=True, drop_last=True)
name = name or f"enc_{dim}_{emb}_{datetime.now():%Y%m%d_%H%M%S}"
writer = SummaryWriter(f"{RUNS}/encoder/{name}")
for ep in range(epochs):
enc.train()
total, n = 0.0, 0
for a, p, _ in loader:
loss = nt_xent_loss(enc(a.unsqueeze(1).to(dev)), enc(p.unsqueeze(1).to(dev)), temp)
opt.zero_grad(); loss.backward(); opt.step()
total += loss.item(); n += 1
avg = total / max(n, 1)
writer.add_scalar('loss-ntxent', avg, ep)
if verbose and (ep+1) % 20 == 0: print(f"Epoch {ep+1}: {avg:.4f}")
writer.close()
return enc, wins, dev
def loocv(epochs=100, lr=5e-4, dim=64, emb=32, temp=0.5, sizes=[5,10,15], stride=2, verbose=True):
"""Leave-one-trajectory-out CV"""
data = JointLoader(HUMAN_DIR, AGENT_DIR).get_data()
dev = torch.device('cuda' if torch.cuda.is_available() else 'cpu')
results = []
for test_id in data:
train_data = {k: v for k, v in data.items() if k != test_id}
if not any(k.startswith('human_') for k in train_data) or not any(k.startswith('agent_') for k in train_data):
continue
wins = build_windows(train_data, sizes, stride)
enc = TrajectoryEncoder(dim, emb).to(dev)
opt = Adam(enc.parameters(), lr=lr)
loader = DataLoader(WindowDataset(wins, dim), batch_size=min(16, len(wins)//2 or 1),
shuffle=True, drop_last=len(wins)>2)
for _ in range(epochs):
enc.train()
for a, p, _ in loader:
loss = nt_xent_loss(enc(a.unsqueeze(1).to(dev)), enc(p.unsqueeze(1).to(dev)), temp)
opt.zero_grad(); loss.backward(); opt.step()
clf = PrototypeClassifier(enc, dev, dim).fit(wins)
pred, conf, dbg = clf.predict(data[test_id])
actual = 0 if test_id.startswith('human_') else 1
results.append((pred, actual, conf))
if verbose: print(f"{test_id[:18]}: pred={pred} conf={conf:.2f} actual={actual} {'OK' if pred==actual else 'MISS'}")
if results:
acc = sum(p==a for p,a,_ in results) / len(results)
if verbose: print(f"\nAccuracy: {acc:.1%} ({sum(p==a for p,a,_ in results)}/{len(results)})")
return acc, results
return 0.0, []
def hparam_tune(n_trials=50, epochs=60, n_jobs=2, verbose=True):
"""Optuna hyperparameter search maximizing LOOCV accuracy"""
def objective(trial):
lr = trial.suggest_float('lr', 1e-5, 1e-2, log=True)
dim = trial.suggest_categorical('dim', [32, 64, 128, 256])
emb = trial.suggest_categorical('emb', [16, 32, 64, 128])
temp = trial.suggest_float('temp', 0.05, 1.0)
stride = trial.suggest_int('stride', 1, 4)
sizes = [trial.suggest_int(f's{i}', 3, 20) for i in range(3)]
sizes = sorted(set(sizes)) # unique sorted
acc, _ = loocv(epochs, lr, dim, emb, temp, sizes, stride, verbose=False)
return acc
study = optuna.create_study(direction='maximize', study_name='encoder_hparam',
sampler=optuna.samplers.TPESampler(seed=42))
study.optimize(objective, n_trials=n_trials, n_jobs=n_jobs, show_progress_bar=verbose)
best = study.best_params
if verbose:
print(f"\nBest accuracy: {study.best_value:.1%}")
print(f"Best params: {best}")
return best, study
if __name__ == "__main__":
import argparse
p = argparse.ArgumentParser()
p.add_argument('--mode', choices=['train', 'eval', 'hparam'], default='train')
p.add_argument('--epochs', type=int, default=200)
p.add_argument('--lr', type=float, default=5e-4)
p.add_argument('--dim', type=int, default=128)
p.add_argument('--emb', type=int, default=64)
p.add_argument('--temp', type=float, default=0.1)
p.add_argument('--sizes', type=str, default='5,10,15')
p.add_argument('--stride', type=int, default=2)
p.add_argument('--n_trials', type=int, default=50)
args = p.parse_args()
sizes = [int(x) for x in args.sizes.split(',')]
if args.mode == 'train':
enc, wins, dev = train(args.epochs, args.lr, 16, args.dim, args.emb, args.temp, sizes, args.stride)
elif args.mode == 'hparam':
best, study = hparam_tune(args.n_trials, min(args.epochs, 60))
else:
loocv(args.epochs, args.lr, args.dim, args.emb, args.temp, sizes, args.stride)

View File

@@ -1,246 +0,0 @@
import sys
sys.path.insert(0, "/home/velocitatem/Documents/Projects/PHANTOM/sim/rl/behavior_loader")
sys.path.insert(0, "/home/velocitatem/Documents/Projects/PHANTOM/experiments/ml")
from sim.rl.behavior_loader.loader import AgentLoader, Loader, JointLoader, PayloadModel
from sim.rl.behavior_loader.models import JointBehaviorModel
from arch import ContrastiveWeakClassifier, contrastive_loss, featurize_trajectory
from typing import List, Optional, Dict
from datetime import datetime, timedelta
from copy import deepcopy
import numpy as np
import random
import torch
from torch.utils.data import Dataset, DataLoader
from torch.optim import Adam
from torch.utils.tensorboard import SummaryWriter
RUNS_DIR = "/home/velocitatem/Documents/Projects/PHANTOM/experiments/ml/runs"
agent_dir = "/home/velocitatem/Documents/Projects/PHANTOM/experiments/agents/collected_data/"
human_dir = "/home/velocitatem/Documents/Projects/PHANTOM/experiments/collected_data/"
def _perturb_ts(evt: PayloadModel, jitter_ms: int = 500) -> PayloadModel:
"""Add random jitter to event timestamp"""
new_evt = deepcopy(evt)
try:
ts = datetime.fromisoformat(evt.ts.replace('Z', '+00:00'))
delta = timedelta(milliseconds=random.randint(-jitter_ms, jitter_ms))
new_evt.ts = (ts + delta).isoformat()
except:
pass
return new_evt
def augment_trajectory(trajectory: List[PayloadModel], rate: float = 0.1) -> List[PayloadModel]:
"""Apply random augmentation to trajectory for contrastive learning"""
if len(trajectory) < 2:
return trajectory
aug_type = random.choice(['window', 'shuffle', 'noise', 'drop'])
if aug_type == 'window': # random contiguous sub-sequence (70-100% length)
min_len = max(2, int(len(trajectory) * 0.7))
sub_len = random.randint(min_len, len(trajectory))
start = random.randint(0, len(trajectory) - sub_len)
return trajectory[start:start + sub_len]
elif aug_type == 'shuffle': # swap adjacent pairs with probability rate
result = list(trajectory)
for i in range(len(result) - 1):
if random.random() < rate:
result[i], result[i + 1] = result[i + 1], result[i]
return result
elif aug_type == 'drop': # drop events with probability rate
result = [e for e in trajectory if random.random() > rate]
return result if len(result) >= 2 else trajectory[:2]
elif aug_type == 'noise': # perturb timestamps
return [_perturb_ts(e, jitter_ms=500) for e in trajectory]
return trajectory
class TripletDataset(Dataset):
"""Generate (anchor, positive, negative) triplets on-the-fly with augmentation"""
def __init__(self, data: Dict[str, List[PayloadModel]], mdp: Optional[Dict], augment_fn, input_dim: int = 64, multiplier: int = 10):
self.sessions = list(data.items())
self.human_ids = [i for i, (sid, _) in enumerate(self.sessions) if sid.startswith('human_')]
self.agent_ids = [i for i, (sid, _) in enumerate(self.sessions) if sid.startswith('agent_')]
self.mdp = mdp
self.augment = augment_fn
self.input_dim = input_dim
self.multiplier = multiplier
if not self.human_ids or not self.agent_ids:
raise ValueError(f"Need both human ({len(self.human_ids)}) and agent ({len(self.agent_ids)}) sessions")
def __len__(self) -> int:
return len(self.sessions) * self.multiplier
def __getitem__(self, idx: int):
anchor_idx = idx % len(self.sessions)
sid, events = self.sessions[anchor_idx]
is_human = sid.startswith('human_')
anchor = featurize_trajectory(events, self.mdp, self.input_dim)
positive = featurize_trajectory(self.augment(events), self.mdp, self.input_dim)
neg_pool = self.agent_ids if is_human else self.human_ids
neg_idx = random.choice(neg_pool)
negative = featurize_trajectory(self.sessions[neg_idx][1], self.mdp, self.input_dim)
label = 0 if is_human else 1 # 0=human, 1=agent
return (torch.tensor(anchor, dtype=torch.float32),
torch.tensor(positive, dtype=torch.float32),
torch.tensor(negative, dtype=torch.float32),
torch.tensor(label, dtype=torch.long))
def train(epochs: int = 100, lr: float = 1e-3, batch_size: int = 4, input_dim: int = 64,
embed_dim: int = 32, margin: float = 0.3, verbose: bool = True, run_name: str = None):
"""Train contrastive weak classifier on human/agent trajectories"""
joint = JointLoader(human_dir, agent_dir)
data = joint.get_data()
if verbose:
print(f"Loaded {len(data)} sessions")
joint_model = JointBehaviorModel(human_dir, agent_dir)
ref_mdp = joint_model.build_MDP()
dataset = TripletDataset(data, ref_mdp, augment_trajectory, input_dim=input_dim)
loader = DataLoader(dataset, batch_size=batch_size, shuffle=True, drop_last=True)
model = ContrastiveWeakClassifier(input_dim=input_dim, embed_dim=embed_dim, margin=margin)
model.to_device()
run_name = run_name or f"d{input_dim}_e{embed_dim}_lr{lr}_m{margin}_{datetime.now():%Y%m%d_%H%M%S}"
writer = SummaryWriter(f"{RUNS_DIR}/train/{run_name}")
optimizer = Adam(list(model.encoder.parameters()) + list(model.classifier.parameters()), lr=lr)
ce_loss_fn = torch.nn.CrossEntropyLoss()
best_loss = float('inf')
for epoch in range(epochs):
model.encoder.train()
model.classifier.train()
total_loss, n_batches = 0.0, 0
for anchor, positive, negative, labels in loader:
anchor, positive, negative, labels = [t.to(model.device) for t in [anchor, positive, negative, labels]]
z_a, z_p, z_n = [model.encoder(t.unsqueeze(1)) for t in [anchor, positive, negative]]
trip_loss = contrastive_loss(z_a, z_p, z_n, margin=model.margin)
ce = ce_loss_fn(model.classifier(z_a), labels)
loss = trip_loss + 0.5 * ce
optimizer.zero_grad()
loss.backward()
optimizer.step()
total_loss += loss.item()
n_batches += 1
avg_loss = total_loss / max(n_batches, 1)
writer.add_scalar('loss', avg_loss, epoch)
if verbose and (epoch + 1) % 10 == 0:
print(f"Epoch {epoch+1}/{epochs}: loss={avg_loss:.4f}")
if avg_loss < best_loss:
best_loss = avg_loss
writer.close()
if verbose:
print(f"Done. Best={best_loss:.4f} TB:{RUNS_DIR}/train/{run_name}")
return model, ref_mdp
def evaluate_loocv(input_dim: int = 64, embed_dim: int = 32, epochs_per_fold: int = 50,
lr: float = 1e-3, margin: float = 0.3, run_name: str = None):
"""Leave-one-out cross-validation given limited samples"""
joint = JointLoader(human_dir, agent_dir)
data = joint.get_data()
session_ids = list(data.keys())
joint_model = JointBehaviorModel(human_dir, agent_dir)
ref_mdp = joint_model.build_MDP()
run_name = run_name or f"loocv_d{input_dim}_e{embed_dim}_m{margin}_{datetime.now():%Y%m%d_%H%M%S}"
writer = SummaryWriter(f"{RUNS_DIR}/eval/{run_name}")
predictions, actuals = [], []
for fold_idx, test_sid in enumerate(session_ids):
train_data = {k: v for k, v in data.items() if k != test_sid}
test_events = data[test_sid]
test_label = 0 if test_sid.startswith('human_') else 1
n_human = sum(1 for k in train_data if k.startswith('human_'))
n_agent = sum(1 for k in train_data if k.startswith('agent_'))
if n_human == 0 or n_agent == 0:
continue
try:
dataset = TripletDataset(train_data, ref_mdp, augment_trajectory, input_dim=input_dim, multiplier=5)
loader = DataLoader(dataset, batch_size=2, shuffle=True, drop_last=True)
model = ContrastiveWeakClassifier(input_dim=input_dim, embed_dim=embed_dim, margin=margin)
model.to_device()
optimizer = Adam(list(model.encoder.parameters()) + list(model.classifier.parameters()), lr=lr)
model.encoder.train()
model.classifier.train()
for _ in range(epochs_per_fold):
for anchor, positive, negative, labels in loader:
z_a, z_p, z_n = [model.encoder(t.unsqueeze(1).to(model.device)) for t in [anchor, positive, negative]]
loss = contrastive_loss(z_a, z_p, z_n, margin=margin)
optimizer.zero_grad()
loss.backward()
optimizer.step()
test_feat = featurize_trajectory(test_events, ref_mdp, input_dim)
pred = model.predict(test_feat.reshape(1, -1))[0]
predictions.append(pred)
actuals.append(test_label)
print(f" {test_sid[:12]}...: pred={pred}, actual={test_label}, {'OK' if pred == test_label else 'MISS'}")
except Exception as e:
print(f"Error: {e}")
if predictions:
acc = sum(p == a for p, a in zip(predictions, actuals)) / len(predictions)
tp = sum(1 for p, a in zip(predictions, actuals) if p == 1 and a == 1)
fp = sum(1 for p, a in zip(predictions, actuals) if p == 1 and a == 0)
fn = sum(1 for p, a in zip(predictions, actuals) if p == 0 and a == 1)
prec, rec = tp / max(tp + fp, 1), tp / max(tp + fn, 1)
f1 = 2 * prec * rec / max(prec + rec, 1e-10)
writer.add_scalar('accuracy', acc, 0)
writer.add_scalar('f1', f1, 0)
writer.add_scalar('precision', prec, 0)
writer.add_scalar('recall', rec, 0)
writer.close()
print(f"\nAccuracy: {acc:.2%} F1: {f1:.3f} TB:{RUNS_DIR}/eval/{run_name}")
return acc, predictions, actuals
writer.close()
return 0.0, [], []
if __name__ == "__main__":
import argparse
parser = argparse.ArgumentParser()
parser.add_argument('--mode', choices=['train', 'eval'], default='train')
parser.add_argument('--epochs', type=int, default=100)
parser.add_argument('--lr', type=float, default=1e-3)
parser.add_argument('--margin', type=float, default=0.3)
parser.add_argument('--input-dim', type=int, default=64)
parser.add_argument('--embed-dim', type=int, default=32)
parser.add_argument('--run-name', type=str, default=None)
args = parser.parse_args()
if args.mode == 'train':
model, mdp = train(epochs=args.epochs, lr=args.lr, input_dim=args.input_dim,
embed_dim=args.embed_dim, margin=args.margin, run_name=args.run_name)
else:
evaluate_loocv(input_dim=args.input_dim, embed_dim=args.embed_dim, epochs_per_fold=args.epochs,
lr=args.lr, margin=args.margin, run_name=args.run_name)

View File

@@ -1,957 +0,0 @@
{
"cells": [
{
"cell_type": "code",
"execution_count": 10,
"id": "62eafcd9-5462-4063-8873-0e7fb9add907",
"metadata": {},
"outputs": [
{
"data": {
"text/plain": [
"True"
]
},
"execution_count": 10,
"metadata": {},
"output_type": "execute_result"
}
],
"source": [
"from kafka import KafkaConsumer\n",
"import pandas as pd\n",
"import json\n",
"import numpy as np\n",
"import os\n",
"from dotenv import load_dotenv\n",
"import matplotlib.pyplot as plt\n",
"from IPython.display import display, SVG, Image\n",
"load_dotenv()"
]
},
{
"cell_type": "code",
"execution_count": 11,
"id": "4af65cb4-e8cf-4877-b2db-13ac19f3838f",
"metadata": {},
"outputs": [
{
"name": "stdout",
"output_type": "stream",
"text": [
"<class 'pandas.core.frame.DataFrame'>\n",
"RangeIndex: 73 entries, 0 to 72\n",
"Data columns (total 13 columns):\n",
" # Column Non-Null Count Dtype \n",
"--- ------ -------------- ----- \n",
" 0 sessionId 73 non-null object \n",
" 1 eventName 73 non-null object \n",
" 2 page 73 non-null object \n",
" 3 productId 67 non-null object \n",
" 4 storeMode 73 non-null object \n",
" 5 userAgent 73 non-null object \n",
" 6 ts 73 non-null object \n",
" 7 metadata_referrer 6 non-null object \n",
" 8 metadata_roomType 45 non-null object \n",
" 9 metadata_price 45 non-null float64\n",
" 10 metadata_nights 45 non-null float64\n",
" 11 metadata_elementText 22 non-null object \n",
" 12 metadata_dwellTime 22 non-null float64\n",
"dtypes: float64(3), object(10)\n",
"memory usage: 7.5+ KB\n"
]
}
],
"source": [
"KAFKA_PORT=os.getenv(\"KAFKA_PORT\", 9092)\n",
"topic = \"user-interactions\"\n",
"consumer = KafkaConsumer(\n",
" topic, \n",
" enable_auto_commit=True,\n",
" value_deserializer=lambda x: json.loads(x.decode('utf-8')),\n",
" auto_offset_reset='earliest', \n",
" bootstrap_servers=['localhost:9092'])\n",
"messages=consumer.poll(timeout_ms=1000,max_records=10000)\n",
"df = []\n",
"for m in messages.values():\n",
" for i in m:\n",
" df.append(i.value)\n",
"df = pd.DataFrame(df)\n",
"# explode metadata col json\n",
"df = df.join(pd.json_normalize(df.pop(\"metadata\"), sep=\".\").add_prefix(\"metadata_\"))\n",
"df.info()"
]
},
{
"cell_type": "code",
"execution_count": 12,
"id": "f6819a1c-32ab-49c7-845b-5df7bf60f561",
"metadata": {},
"outputs": [
{
"data": {
"text/html": [
"<div>\n",
"<style scoped>\n",
" .dataframe tbody tr th:only-of-type {\n",
" vertical-align: middle;\n",
" }\n",
"\n",
" .dataframe tbody tr th {\n",
" vertical-align: top;\n",
" }\n",
"\n",
" .dataframe thead th {\n",
" text-align: right;\n",
" }\n",
"</style>\n",
"<table border=\"1\" class=\"dataframe\">\n",
" <thead>\n",
" <tr style=\"text-align: right;\">\n",
" <th></th>\n",
" <th>sessionId</th>\n",
" <th>eventName</th>\n",
" <th>page</th>\n",
" <th>productId</th>\n",
" <th>storeMode</th>\n",
" <th>userAgent</th>\n",
" <th>ts</th>\n",
" <th>metadata_referrer</th>\n",
" <th>metadata_roomType</th>\n",
" <th>metadata_price</th>\n",
" <th>metadata_nights</th>\n",
" <th>metadata_elementText</th>\n",
" <th>metadata_dwellTime</th>\n",
" </tr>\n",
" </thead>\n",
" <tbody>\n",
" <tr>\n",
" <th>0</th>\n",
" <td>d176d7c9-4027-4702-9e31-2a71395cdda0</td>\n",
" <td>page_view</td>\n",
" <td>/products</td>\n",
" <td>None</td>\n",
" <td>hotel</td>\n",
" <td>Mozilla/5.0 (X11; Linux x86_64) AppleWebKit/53...</td>\n",
" <td>2025-11-14T13:23:46.270Z</td>\n",
" <td></td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" </tr>\n",
" <tr>\n",
" <th>1</th>\n",
" <td>f0317a5d-e424-44e9-b784-c8f7291ffe31</td>\n",
" <td>page_view</td>\n",
" <td>/</td>\n",
" <td>None</td>\n",
" <td>hotel</td>\n",
" <td>Mozilla/5.0 (X11; Linux x86_64; rv:143.0) Geck...</td>\n",
" <td>2025-11-14T13:26:00.291Z</td>\n",
" <td></td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" </tr>\n",
" <tr>\n",
" <th>2</th>\n",
" <td>f0317a5d-e424-44e9-b784-c8f7291ffe31</td>\n",
" <td>page_view</td>\n",
" <td>/products</td>\n",
" <td>None</td>\n",
" <td>hotel</td>\n",
" <td>Mozilla/5.0 (X11; Linux x86_64; rv:143.0) Geck...</td>\n",
" <td>2025-11-14T13:26:07.769Z</td>\n",
" <td></td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" </tr>\n",
" <tr>\n",
" <th>3</th>\n",
" <td>f0317a5d-e424-44e9-b784-c8f7291ffe31</td>\n",
" <td>view_item_page</td>\n",
" <td>/products</td>\n",
" <td>htl-0</td>\n",
" <td>hotel</td>\n",
" <td>Mozilla/5.0 (X11; Linux x86_64; rv:143.0) Geck...</td>\n",
" <td>2025-11-14T13:26:15.010Z</td>\n",
" <td>NaN</td>\n",
" <td>Premium Room</td>\n",
" <td>269.0</td>\n",
" <td>1.0</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" </tr>\n",
" <tr>\n",
" <th>4</th>\n",
" <td>238dc588-a7ab-4c0e-bccd-6abca5076c66</td>\n",
" <td>page_view</td>\n",
" <td>/products</td>\n",
" <td>None</td>\n",
" <td>hotel</td>\n",
" <td>Mozilla/5.0 (Macintosh; Intel Mac OS X 10_15_7...</td>\n",
" <td>2025-11-14T13:27:15.457Z</td>\n",
" <td></td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" </tr>\n",
" <tr>\n",
" <th>5</th>\n",
" <td>238dc588-a7ab-4c0e-bccd-6abca5076c66</td>\n",
" <td>view_item_page</td>\n",
" <td>/products</td>\n",
" <td>htl-0</td>\n",
" <td>hotel</td>\n",
" <td>Mozilla/5.0 (Macintosh; Intel Mac OS X 10_15_7...</td>\n",
" <td>2025-11-14T13:27:15.591Z</td>\n",
" <td>NaN</td>\n",
" <td>Premium Room</td>\n",
" <td>264.0</td>\n",
" <td>2.0</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" </tr>\n",
" <tr>\n",
" <th>432</th>\n",
" <td>214d9fad-9b00-40c3-bd0e-7739b6acd654</td>\n",
" <td>click</td>\n",
" <td>1762448192425</td>\n",
" <td>DIV</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>/</td>\n",
" <td>NaN</td>\n",
" <td>1623.0</td>\n",
" <td>493.0</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" </tr>\n",
" <tr>\n",
" <th>6</th>\n",
" <td>238dc588-a7ab-4c0e-bccd-6abca5076c66</td>\n",
" <td>view_item_page</td>\n",
" <td>/products</td>\n",
" <td>htl-0</td>\n",
" <td>hotel</td>\n",
" <td>Mozilla/5.0 (Macintosh; Intel Mac OS X 10_15_7...</td>\n",
" <td>2025-11-14T13:27:21.483Z</td>\n",
" <td>NaN</td>\n",
" <td>Premium Room</td>\n",
" <td>264.0</td>\n",
" <td>2.0</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" </tr>\n",
" <tr>\n",
" <th>7</th>\n",
" <td>238dc588-a7ab-4c0e-bccd-6abca5076c66</td>\n",
" <td>hover_over_title</td>\n",
" <td>/products</td>\n",
" <td>htl-0</td>\n",
" <td>hotel</td>\n",
" <td>Mozilla/5.0 (Macintosh; Intel Mac OS X 10_15_7...</td>\n",
" <td>2025-11-14T13:27:22.646Z</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>Grand Plaza Hotel</td>\n",
" <td>1200.0</td>\n",
" </tr>\n",
" <tr>\n",
" <th>8</th>\n",
" <td>238dc588-a7ab-4c0e-bccd-6abca5076c66</td>\n",
" <td>view_item_page</td>\n",
" <td>/products</td>\n",
" <td>htl-0</td>\n",
" <td>hotel</td>\n",
" <td>Mozilla/5.0 (Macintosh; Intel Mac OS X 10_15_7...</td>\n",
" <td>2025-11-14T13:27:25.889Z</td>\n",
" <td>NaN</td>\n",
" <td>Premium Room</td>\n",
" <td>264.0</td>\n",
" <td>2.0</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" </tr>\n",
" <tr>\n",
" <th>35</th>\n",
" <td>013fc334-4045-4d5a-8739-dd0a8766a63b</td>\n",
" <td>page_view</td>\n",
" <td>/products</td>\n",
" <td>None</td>\n",
" <td>hotel</td>\n",
" <td>Mozilla/5.0 (X11; Linux x86_64) AppleWebKit/53...</td>\n",
" <td>2025-11-14T13:53:59.993Z</td>\n",
" <td></td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" </tr>\n",
" <tr>\n",
" <th>36</th>\n",
" <td>013fc334-4045-4d5a-8739-dd0a8766a63b</td>\n",
" <td>view_item_page</td>\n",
" <td>/products</td>\n",
" <td>htl-0</td>\n",
" <td>hotel</td>\n",
" <td>Mozilla/5.0 (X11; Linux x86_64) AppleWebKit/53...</td>\n",
" <td>2025-11-14T13:54:10.705Z</td>\n",
" <td>NaN</td>\n",
" <td>Premium Room</td>\n",
" <td>223.0</td>\n",
" <td>3.0</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" </tr>\n",
" <tr>\n",
" <th>37</th>\n",
" <td>013fc334-4045-4d5a-8739-dd0a8766a63b</td>\n",
" <td>hover_over_title</td>\n",
" <td>/products</td>\n",
" <td>htl-0</td>\n",
" <td>hotel</td>\n",
" <td>Mozilla/5.0 (X11; Linux x86_64) AppleWebKit/53...</td>\n",
" <td>2025-11-14T13:54:11.771Z</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>416.0</td>\n",
" <td>397.0</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>Grand Plaza Hotel</td>\n",
" <td>1200.0</td>\n",
" </tr>\n",
" <tr>\n",
" <th>38</th>\n",
" <td>013fc334-4045-4d5a-8739-dd0a8766a63b</td>\n",
" <td>view_item_page</td>\n",
" <td>/products</td>\n",
" <td>htl-1</td>\n",
" <td>hotel</td>\n",
" <td>Mozilla/5.0 (X11; Linux x86_64) AppleWebKit/53...</td>\n",
" <td>2025-11-14T13:54:29.772Z</td>\n",
" <td>NaN</td>\n",
" <td>Standard Room</td>\n",
" <td>267.0</td>\n",
" <td>5.0</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" </tr>\n",
" <tr>\n",
" <th>39</th>\n",
" <td>013fc334-4045-4d5a-8739-dd0a8766a63b</td>\n",
" <td>hover_over_title</td>\n",
" <td>/products</td>\n",
" <td>htl-1</td>\n",
" <td>hotel</td>\n",
" <td>Mozilla/5.0 (X11; Linux x86_64) AppleWebKit/53...</td>\n",
" <td>2025-11-14T13:54:30.833Z</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>NaN</td>\n",
" <td>Seaside Resort</td>\n",
" <td>1200.0</td>\n",
" </tr>\n",
" </tbody>\n",
"</table>\n",
"</div>"
],
"text/plain": [
" sessionId eventName page \\\n",
"0 d176d7c9-4027-4702-9e31-2a71395cdda0 page_view /products \n",
"1 f0317a5d-e424-44e9-b784-c8f7291ffe31 page_view / \n",
"2 f0317a5d-e424-44e9-b784-c8f7291ffe31 page_view /products \n",
"3 f0317a5d-e424-44e9-b784-c8f7291ffe31 view_item_page /products \n",
"4 238dc588-a7ab-4c0e-bccd-6abca5076c66 page_view /products \n",
"5 238dc588-a7ab-4c0e-bccd-6abca5076c66 view_item_page /products \n",
"6 238dc588-a7ab-4c0e-bccd-6abca5076c66 view_item_page /products \n",
"7 238dc588-a7ab-4c0e-bccd-6abca5076c66 hover_over_title /products \n",
"8 238dc588-a7ab-4c0e-bccd-6abca5076c66 view_item_page /products \n",
"35 013fc334-4045-4d5a-8739-dd0a8766a63b page_view /products \n",
"36 013fc334-4045-4d5a-8739-dd0a8766a63b view_item_page /products \n",
"37 013fc334-4045-4d5a-8739-dd0a8766a63b hover_over_title /products \n",
"38 013fc334-4045-4d5a-8739-dd0a8766a63b view_item_page /products \n",
"39 013fc334-4045-4d5a-8739-dd0a8766a63b hover_over_title /products \n",
"\n",
" productId storeMode userAgent \\\n",
"0 None hotel Mozilla/5.0 (X11; Linux x86_64) AppleWebKit/53... \n",
"1 None hotel Mozilla/5.0 (X11; Linux x86_64; rv:143.0) Geck... \n",
"2 None hotel Mozilla/5.0 (X11; Linux x86_64; rv:143.0) Geck... \n",
"3 htl-0 hotel Mozilla/5.0 (X11; Linux x86_64; rv:143.0) Geck... \n",
"4 None hotel Mozilla/5.0 (Macintosh; Intel Mac OS X 10_15_7... \n",
"5 htl-0 hotel Mozilla/5.0 (Macintosh; Intel Mac OS X 10_15_7... \n",
"6 htl-0 hotel Mozilla/5.0 (Macintosh; Intel Mac OS X 10_15_7... \n",
"7 htl-0 hotel Mozilla/5.0 (Macintosh; Intel Mac OS X 10_15_7... \n",
"8 htl-0 hotel Mozilla/5.0 (Macintosh; Intel Mac OS X 10_15_7... \n",
"35 None hotel Mozilla/5.0 (X11; Linux x86_64) AppleWebKit/53... \n",
"36 htl-0 hotel Mozilla/5.0 (X11; Linux x86_64) AppleWebKit/53... \n",
"37 htl-0 hotel Mozilla/5.0 (X11; Linux x86_64) AppleWebKit/53... \n",
"38 htl-1 hotel Mozilla/5.0 (X11; Linux x86_64) AppleWebKit/53... \n",
"39 htl-1 hotel Mozilla/5.0 (X11; Linux x86_64) AppleWebKit/53... \n",
"\n",
" ts metadata_referrer metadata_roomType \\\n",
"0 2025-11-14T13:23:46.270Z NaN \n",
"1 2025-11-14T13:26:00.291Z NaN \n",
"2 2025-11-14T13:26:07.769Z NaN \n",
"3 2025-11-14T13:26:15.010Z NaN Premium Room \n",
"4 2025-11-14T13:27:15.457Z NaN \n",
"5 2025-11-14T13:27:15.591Z NaN Premium Room \n",
"6 2025-11-14T13:27:21.483Z NaN Premium Room \n",
"7 2025-11-14T13:27:22.646Z NaN NaN \n",
"8 2025-11-14T13:27:25.889Z NaN Premium Room \n",
"35 2025-11-14T13:53:59.993Z NaN \n",
"36 2025-11-14T13:54:10.705Z NaN Premium Room \n",
"37 2025-11-14T13:54:11.771Z NaN NaN \n",
"38 2025-11-14T13:54:29.772Z NaN Standard Room \n",
"39 2025-11-14T13:54:30.833Z NaN NaN \n",
"\n",
" metadata_price metadata_nights metadata_elementText metadata_dwellTime \n",
"0 NaN NaN NaN NaN \n",
"1 NaN NaN NaN NaN \n",
"2 NaN NaN NaN NaN \n",
"3 269.0 1.0 NaN NaN \n",
"4 NaN NaN NaN NaN \n",
"5 264.0 2.0 NaN NaN \n",
"6 264.0 2.0 NaN NaN \n",
"7 NaN NaN Grand Plaza Hotel 1200.0 \n",
"8 264.0 2.0 NaN NaN \n",
"35 NaN NaN NaN NaN \n",
"36 223.0 3.0 NaN NaN \n",
"37 NaN NaN Grand Plaza Hotel 1200.0 \n",
"38 267.0 5.0 NaN NaN \n",
"39 NaN NaN Seaside Resort 1200.0 "
]
},
"execution_count": 12,
"metadata": {},
"output_type": "execute_result"
}
],
"source": [
"df.groupby('sessionId').head()"
]
},
{
"cell_type": "code",
"execution_count": 13,
"id": "380eca5f-8304-4fb2-be32-e8bcfd312085",
"metadata": {},
"outputs": [
{
"data": {
"text/plain": [
"['013fc334-4045-4d5a-8739-dd0a8766a63b',\n",
" '238dc588-a7ab-4c0e-bccd-6abca5076c66',\n",
" 'd176d7c9-4027-4702-9e31-2a71395cdda0',\n",
" 'f0317a5d-e424-44e9-b784-c8f7291ffe31']"
]
},
"execution_count": 13,
"metadata": {},
"output_type": "execute_result"
}
],
"source": [
"sessions = list(set(df['sessionId'])); sessions # 238dc588-a7ab-4c0e-bccd-6abca5076c66"
]
},
{
"cell_type": "code",
"execution_count": 14,
"id": "f4ae6f81-dcb8-44be-aee7-30dbc3a6bae1",
"metadata": {},
"outputs": [],
"source": [
"# map sessions to experiments"
]
},
{
"cell_type": "code",
"execution_count": 15,
"id": "050d90a4-20a9-47f5-b998-c31178a54cb3",
"metadata": {},
"outputs": [],
"source": [
"def build_transition_prob_matrix(df: pd.DataFrame):\n",
" df = df.dropna(subset=['eventName'])\n",
" events = df['eventName'].tolist()\n",
" labels = pd.Index(events).unique().tolist()\n",
" idx = {e:i for i,e in enumerate(labels)}\n",
" M = np.zeros((len(labels), len(labels)), dtype=float)\n",
" for a, b in zip(events, events[1:]):\n",
" M[idx[a], idx[b]] += 1\n",
" row_sums = M.sum(axis=1, keepdims=True)\n",
" with np.errstate(divide='ignore', invalid='ignore'):\n",
" P = np.divide(M, row_sums, where=row_sums>0) # row-normalized\n",
" return P, labels"
]
},
{
"cell_type": "code",
"execution_count": 16,
"id": "e68f9004-82f5-4826-aece-e3dc6e15a18f",
"metadata": {},
"outputs": [],
"source": [
"# https://medium.com/data-science/time-series-data-markov-transition-matrices-7060771e362b\n",
"from graphviz import Digraph\n",
"import numpy as np\n",
"import pandas as pd\n",
"\n",
"def _as_prob_df(matrix, labels=None):\n",
" \"\"\"Return a square DataFrame with index=columns=labels.\"\"\"\n",
" if isinstance(matrix, pd.DataFrame):\n",
" # Ensure square and aligned\n",
" assert (matrix.index == matrix.columns).all(), \"Index/columns must match.\"\n",
" return matrix\n",
" matrix = np.asarray(matrix, dtype=float)\n",
" assert matrix.shape[0] == matrix.shape[1], \"Matrix must be square.\"\n",
" if labels is None:\n",
" raise ValueError(\"labels are required when matrix is not a DataFrame\")\n",
" assert len(labels) == matrix.shape[0], \"labels length must match matrix size.\"\n",
" return pd.DataFrame(matrix, index=list(labels), columns=list(labels))\n",
"\n",
"def _df_to_edgelist(P: pd.DataFrame, threshold=0.0, round_digits=2):\n",
" \"\"\"Build weighted edges > threshold.\"\"\"\n",
" edges = []\n",
" for src in P.index:\n",
" for dst in P.columns:\n",
" w = float(P.loc[src, dst])\n",
" if w > threshold:\n",
" edges.append((str(src), str(dst), f\"{w:.{round_digits}f}\"))\n",
" return edges\n",
"\n",
"def render_graph(fname, matrix, ls_index=None, threshold=0.0, fmt=\"svg\", view=False):\n",
" \"\"\"\n",
" fname: output file stem (no extension)\n",
" matrix: NumPy array or pandas DataFrame of transition PROBABILITIES\n",
" ls_index: ordered labels (required if matrix is not a DataFrame)\n",
" threshold: hide edges with weight <= threshold\n",
" fmt: 'svg'|'png'|'pdf' etc.\n",
" view: open after rendering\n",
" \"\"\"\n",
" P = _as_prob_df(matrix, labels=ls_index)\n",
" edges = _df_to_edgelist(P, threshold=threshold)\n",
"\n",
" g = Digraph(format=fmt)\n",
" g.attr(rankdir=\"LR\", size=\"30\")\n",
" g.attr(\"node\", shape=\"circle\")\n",
"\n",
" # ensure isolated nodes appear\n",
" for node in P.index:\n",
" g.node(str(node), width=\"1\", height=\"1\")\n",
"\n",
" for src, dst, label in edges:\n",
" g.edge(src, dst, label=label)\n",
"\n",
" g.render(fname, view=view, cleanup=True)\n",
" return g\n"
]
},
{
"cell_type": "code",
"execution_count": 17,
"id": "e255a2c1-6454-4e5e-89f6-ef8ac51ab6cc",
"metadata": {},
"outputs": [
{
"name": "stdout",
"output_type": "stream",
"text": [
"013fc334-4045-4d5a-8739-dd0a8766a63b\n"
]
},
{
"data": {
"image/svg+xml": [
"<?xml version=\"1.0\" encoding=\"UTF-8\" standalone=\"no\"?>\n",
"<!DOCTYPE svg PUBLIC \"-//W3C//DTD SVG 1.1//EN\"\n",
" \"http://www.w3.org/Graphics/SVG/1.1/DTD/svg11.dtd\">\n",
"<!-- Generated by graphviz version 13.1.2 (0)\n",
" -->\n",
"<!-- Pages: 1 -->\n",
"<svg width=\"565pt\" height=\"354pt\"\n",
" viewBox=\"0.00 0.00 565.00 354.00\" xmlns=\"http://www.w3.org/2000/svg\" xmlns:xlink=\"http://www.w3.org/1999/xlink\">\n",
"<g id=\"graph0\" class=\"graph\" transform=\"scale(1 1) rotate(0) translate(4 349.64)\">\n",
"<polygon fill=\"white\" stroke=\"none\" points=\"-4,4 -4,-349.64 561.05,-349.64 561.05,4 -4,4\"/>\n",
"<!-- page_view -->\n",
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@@ -1,114 +0,0 @@
from __future__ import annotations
import os
import random
from pathlib import Path
from types import SimpleNamespace
import pandas as pd
from lib.separability import estimate_alpha, load_artifacts, score_session
# use relative import when in package context, fallback for standalone
try:
from sim.rl.behavior_loader.models import AgentBehaviorModel
except ImportError:
import sys
sys.path.insert(0, str(Path(__file__).parent.parent.parent / "sim" / "rl" / "behavior_loader"))
from models import AgentBehaviorModel
# paths should be configurable via environment or relative to project root
PROJECT_ROOT = Path(__file__).parent.parent.parent
AGENT_DATA_DIR = Path(os.getenv('PHANTOM_AGENT_DATA_DIR', PROJECT_ROOT / "experiments" / "agents" / "collected_data"))
try:
SEPARABILITY_ARTIFACTS = load_artifacts()
except FileNotFoundError:
SEPARABILITY_ARTIFACTS = None
def remap_schema(df: pd.DataFrame, mapping: dict, on: str = "event_type") -> pd.DataFrame:
"""remap column values according to mapping dict, preserving unmapped values"""
df = df.copy()
df[on] = df[on].map(mapping).fillna(df[on])
return df
def _states_to_events(states: list[str]) -> list[SimpleNamespace]:
events: list[SimpleNamespace] = []
for idx, state in enumerate(states):
parts = state.split("|") if isinstance(state, str) else ["page", "product", str(state)]
page = f"/{parts[0]}" if parts else "/"
product = parts[1] if len(parts) > 1 else "unknown"
event_name = parts[2] if len(parts) > 2 else parts[-1]
events.append(
SimpleNamespace(
eventName=event_name,
page=page,
productId=product,
ts=float(idx),
)
)
return events
def contaminate_dataset(df: pd.DataFrame, on: str = "event_type",
contamination_rate: float = 0.1,
agent_data_dir: Path = None) -> pd.DataFrame:
"""inject synthetic agent trajectories into a dataset
contamination_rate: fraction of final dataset that should be agent data (0.1 = 10% agents)
"""
data_dir = agent_data_dir or AGENT_DATA_DIR
model = AgentBehaviorModel(str(data_dir))
model.build_MDP() # ensure MDP is built before sampling
# compute event distribution from original data
event_dist = df[on].value_counts(normalize=True).to_dict()
total = sum(event_dist.values())
event_dist = {k: v / total for k, v in event_dist.items()}
# calculate how many synthetic events to add
N = len(df)
N_final = N / (1 - contamination_rate)
N_contaminate = int(N_final - N)
# sample start states weighted by original distribution
start_events = random.choices(list(event_dist.keys()), weights=list(event_dist.values()), k=N_contaminate)
# generate synthetic trajectories
new_rows = []
alpha_estimates = []
for start_event in start_events:
# sample trajectory from agent model, using a state that contains the event type
mdp_states = model.mdp.get('states', []) if model.mdp else []
matching_starts = [s for s in mdp_states if start_event in s]
if not matching_starts:
continue # skip if no matching start state
start_state = random.choice(matching_starts)
trajectory = model.sample_traj(start_state, max_len=20)
score_payload: list[SimpleNamespace] = []
score: dict[str, float] = {}
if SEPARABILITY_ARTIFACTS:
score_payload = _states_to_events(trajectory)
score = score_session(score_payload, SEPARABILITY_ARTIFACTS)
alpha_estimates.append(
estimate_alpha(score["prob_agent"], score["delta_h"], score["delta_a"], temperature=2.0)
)
for state in trajectory:
parts = state.split('|') if isinstance(state, str) else [start_event]
new_rows.append({
on: parts[-1] if parts else start_event,
'source': 'synthetic_agent',
'prob_agent': score.get('prob_agent') if SEPARABILITY_ARTIFACTS and score_payload else None,
'delta_h': score.get('delta_h') if SEPARABILITY_ARTIFACTS and score_payload else None,
'delta_a': score.get('delta_a') if SEPARABILITY_ARTIFACTS and score_payload else None,
})
if new_rows:
contaminate_df = pd.DataFrame(new_rows)
df = pd.concat([df, contaminate_df], ignore_index=True)
if alpha_estimates:
df['estimated_alpha'] = sum(alpha_estimates) / len(alpha_estimates)
return df

View File

@@ -7,6 +7,15 @@ import pandas as pd
class PricingFunction(ABC):
"""
Abstract base for pricing functions.
Defines mapping: f(Q_t, P_t, S_t, H_t) -> P_{t+1}
Where:
Q_t ∈ R^n: demand vector at time t
P_t ∈ R^n: price vector at time t
S_t: session features (behavioral signals, interactions)
H_t = {Q_{t-k}, P_{t-k}, S_{t-k}}: historical state trajectory
Objective:
maximize E[R_T] = E[Σ P_t^T · Q_t]
subject to:
@@ -19,10 +28,10 @@ class PricingFunction(ABC):
def fit(self, *kwargs):
"""
Offline training on historical data.
This is where we can think about some maximization of expected revenue
over historical trajectories to learn parameters of the pricing function.
(This however we cover move in the RL side of things)
Args:
historical_data: DataFrame with elasticity, prices, demand signals
**kwargs: additional training parameters
"""
pass
@@ -30,18 +39,12 @@ class PricingFunction(ABC):
def predict(self, *kwargs) -> np.ndarray:
"""
Generate optimal prices given current state.
This is an abstract method that transitions from τ -> P*
which is the mapping from the trajectory to optimal prices under
some subset of session grouping (so, per sessionId)
"""
pass
@abstractmethod
def _get_features(self, *kwargs) -> np.ndarray:
"""
Extract features from trajectory for pricing decision.
Args:
state_space: StateSpace object containing Q_t, P_t, S_t, H_t
Returns:
np.ndarray of shape (n_products, n_features)
P_{t+1}: price vector in R^n
"""
pass

View File

@@ -57,13 +57,3 @@ class ElasticityBasedPricer(PricingFunction):
# enforce bounds
prices = np.clip(prices, self.price_floor, self.price_ceil)
return prices
def _get_features(self, state_space=None) -> np.ndarray:
"""Extract elasticity, demand, and demand deviation for each product"""
if state_space is None or self.elasticity is None:
n = len(self.elasticity) if self.elasticity is not None else 0
return np.zeros((n, 3))
demand = np.asarray(state_space.demand)
demand_dev = (demand - self.mean_demand) / (self.mean_demand + 1e-6)
return np.column_stack([self.elasticity, demand, demand_dev])

View File

@@ -107,36 +107,6 @@ class SessionAwarePricer(PricingFunction):
return prices
def _get_features(self, state_space=None) -> np.ndarray:
"""Extract elasticity, demand, and session features"""
if state_space is None or self.elasticity is None:
n = len(self.elasticity) if self.elasticity is not None else 0
return np.zeros((n, 5))
demand = np.asarray(state_space.demand)
n_products = len(demand)
# extract session features
velocity = 0.0
view_depth = 0.0
cart_to_view = 0.0
if not state_space.session_features.empty:
sf = state_space.session_features.iloc[0]
velocity = sf.get('interaction_velocity', 0.0)
view_depth = sf.get('product_view_depth', 0.0)
cart_to_view = sf.get('cart_to_view_ratio', 0.0)
# broadcast session features to all products
features = np.column_stack([
self.elasticity,
demand,
np.full(n_products, velocity),
np.full(n_products, view_depth),
np.full(n_products, cart_to_view)
])
return features
class ProductSpecificSessionPricer(PricingFunction):
"""
@@ -200,12 +170,3 @@ class ProductSpecificSessionPricer(PricingFunction):
prices = np.clip(base_prices, self.price_floor, self.price_ceil)
return prices
def _get_features(self, state_space=None) -> np.ndarray:
"""Extract elasticity and demand features for product-specific pricing"""
if state_space is None or self.elasticity is None:
n = len(self.elasticity) if self.elasticity is not None else 0
return np.zeros((n, 2))
demand = np.asarray(state_space.demand)
return np.column_stack([self.elasticity, demand])

View File

@@ -3,46 +3,6 @@ import pandas as pd
from procesing.pricers.base import PricingFunction
def session_features_to_demand(session_features: pd.DataFrame) -> float:
"""
Map session behavioral features to demand proxy.
THIS is the critical θ̂ → D transformation for rule-based pricing.
Logic:
- High velocity → agent behavior → price up (revenue recovery)
- High cart ratio → purchase intent → price up
- Low activity → discount to convert
Returns: demand proxy score (0-20 range, higher = more demand)
"""
if session_features.empty:
return 1.0
feat = session_features.iloc[0] if len(session_features) > 0 else {}
velocity = feat.get('interaction_velocity', 0)
cart_ratio = feat.get('cart_to_view_ratio', 0)
item_views = feat.get('item_views', 0)
cart_adds = feat.get('cart_adds', 0)
# baseline demand
demand = 1.0
# agent detection: high velocity → treat as high "demand" to price up
if velocity > 2.0:
demand += 10.0 # strong agent signal
# conversion intent: cart interaction → price up
if cart_ratio > 0.1 or cart_adds > 0:
demand += 5.0
# browsing depth: many views → interest signal
if item_views > 3:
demand += min(item_views, 5.0)
return min(demand, 20.0) # cap at 20
class StaticPricer(PricingFunction):
"""Static pricing: always return fixed base prices"""
@@ -65,11 +25,6 @@ class StaticPricer(PricingFunction):
raise ValueError("Must call fit() or provide base_prices in constructor")
return self.base_prices.copy()
def _get_features(self, state_space=None) -> np.ndarray:
"""Static pricer uses no features, returns empty array"""
n = len(self.base_prices) if self.base_prices is not None else 0
return np.zeros((n, 0))
class RandomPricer(PricingFunction):
"""Random pricing within bounds (for baseline comparison)"""
@@ -92,11 +47,6 @@ class RandomPricer(PricingFunction):
self.n_products = len(state_space.demand)
return self.rng.uniform(self.price_min, self.price_max, size=self.n_products)
def _get_features(self, state_space=None) -> np.ndarray:
"""Random pricer uses no features"""
n = self.n_products if self.n_products else 0
return np.zeros((n, 0))
class SimpleSurgePricer(PricingFunction):
"""
@@ -117,25 +67,21 @@ class SimpleSurgePricer(PricingFunction):
self.surge_multiplier = surge_multiplier
self.discount_multiplier = discount_multiplier
def fit(self, market_data: pd.DataFrame):
def fit(self, market_data : pd.DataFrame):
"""Extract base prices from product catalog or historical averages"""
self.base_prices = market_data['base_price'].to_numpy() if 'base_price' in market_data.columns else market_data['price'].values
return self
self.demand_history = market_data['demand'].to_numpy() if 'demand' in market_data.columns else np.zeros_like(self.base_prices)
def predict(self, state_space) -> np.ndarray:
def predict(self) -> np.ndarray:
"""
Adjust prices based on current demand using surge rules.
state_space.demand: demand proxy per product (from session features)
state_space.prices: base prices
state_space.demand: demand counts per product
state_space.prices: current prices (fallback if base_prices not set)
"""
demand = np.asarray(state_space.demand) if state_space and hasattr(state_space, 'demand') else np.array([0])
base = np.asarray(state_space.prices) if state_space and hasattr(state_space, 'prices') else self.base_prices
current_prices = self.base_prices if self.base_prices is not None else np.ones_like(demand_vector) * 99.99
demand = self.demand_history if self.demand_history is not None else np.zeros_like(current_prices)
new_prices = current_prices.copy()
if base is None:
base = np.ones(len(demand)) * 99.99
# ensure float dtype to allow multiplication by float multipliers
new_prices = base.astype(np.float64).copy()
high_mask = demand >= self.high_threshold
new_prices[high_mask] *= self.surge_multiplier
@@ -143,16 +89,3 @@ class SimpleSurgePricer(PricingFunction):
new_prices[low_mask] *= self.discount_multiplier
return new_prices
def _get_features(self, state_space=None) -> np.ndarray:
"""Extract demand and base price features for each product"""
if state_space is None:
n = len(self.base_prices) if self.base_prices is not None else 0
return np.zeros((n, 2))
demand = np.asarray(state_space.demand) if hasattr(state_space, 'demand') else np.array([0])
base = np.asarray(state_space.prices) if hasattr(state_space, 'prices') else self.base_prices
if base is None:
base = np.ones(len(demand)) * 99.99
return np.column_stack([demand, base])

View File

@@ -135,7 +135,6 @@ class ExtractSessionFeaturesStep(BaseContextStep):
Vectorized session feature extraction - replaces O(n^2) per-row loop.
Input: interactions_df
Output: session-level feature matrix
THIS is our main mapping from tau (trajectory) to some features vector theta - we need to do this very well. This is what will go into demand esimation.
"""
def transform(self, X: pd.DataFrame) -> pd.DataFrame:

View File

@@ -6,7 +6,6 @@ from procesing.steps import (
)
def test_compute_demand(pipeline_context):
random.seed(42) # deterministic test
step = ComputeDemandStep(context=pipeline_context)
# Test with normal interaction data
@@ -27,7 +26,6 @@ def test_compute_demand(pipeline_context):
def test_compute_demand_skewed(pipeline_context):
random.seed(42) # deterministic test
step = ComputeDemandStep(context=pipeline_context)
# Test with normal interaction data

View File

@@ -1,165 +0,0 @@
import pytest
import pandas as pd
import numpy as np
from procesing.steps.session import (
TemporalFeatureStep,
BehavioralFeatureStep,
ProductFeatureStep,
UserAgentFeatureStep,
ExtractSessionFeaturesStep,
JoinLabelsStep,
ValidateDataStep,
)
# TemporalFeatureStep tests
def test_temporal_empty(pipeline_context):
result = TemporalFeatureStep(pipeline_context).transform(pd.DataFrame())
assert 'sessionId' in result.columns
assert result.empty
def test_temporal_basic(pipeline_context, session_interactions):
result = TemporalFeatureStep(pipeline_context).transform(session_interactions)
assert 'session_duration_sec' in result.columns
assert 'interaction_velocity' in result.columns
assert 'max_velocity_5min' in result.columns
assert result['total_interactions'].sum() == len(session_interactions)
def test_temporal_timeout(pipeline_context):
df = pd.DataFrame({
'sessionId': ['s1', 's1'],
'ts': ['2025-01-01T10:00:00Z', '2025-01-01T11:00:00Z'], # 1 hour gap
})
result = TemporalFeatureStep(pipeline_context, timeout_sec=900).transform(df)
assert result.iloc[0]['session_duration_sec'] == 0 # gap exceeds timeout
# BehavioralFeatureStep tests
def test_behavioral_empty(pipeline_context):
result = BehavioralFeatureStep(pipeline_context).transform(pd.DataFrame())
assert 'sessionId' in result.columns
def test_behavioral_counts(pipeline_context, session_interactions):
result = BehavioralFeatureStep(pipeline_context).transform(session_interactions)
assert 'page_views' in result.columns
assert 'item_views' in result.columns
assert 'hover_events' in result.columns
assert result['total_events'].sum() == len(session_interactions)
def test_behavioral_hover_prefix(pipeline_context):
df = pd.DataFrame({
'sessionId': ['s1', 's1'],
'eventName': ['hover_over_custom', 'hover_over_button'],
'page': ['/products', '/products'],
})
result = BehavioralFeatureStep(pipeline_context).transform(df)
assert result.iloc[0]['hover_events'] == 2
# ProductFeatureStep tests
def test_product_empty(pipeline_context):
result = ProductFeatureStep(pipeline_context).transform(pd.DataFrame())
assert 'sessionId' in result.columns
def test_product_features(pipeline_context, session_interactions):
result = ProductFeatureStep(pipeline_context).transform(session_interactions)
assert 'unique_products_viewed' in result.columns
assert 'price_range' in result.columns
assert result['unique_products_viewed'].sum() > 0
# UserAgentFeatureStep tests
def test_ua_empty(pipeline_context):
result = UserAgentFeatureStep(pipeline_context).transform(pd.DataFrame())
assert 'sessionId' in result.columns
def test_ua_headless_detection(pipeline_context):
df = pd.DataFrame({
'sessionId': ['s1', 's2'],
'userAgent': ['Mozilla/5.0 Chrome/120', 'HeadlessChrome/120'],
})
result = UserAgentFeatureStep(pipeline_context).transform(df)
assert 'is_headless' in result.columns
headless = dict(zip(result['sessionId'], result['is_headless']))
assert headless['s1'] == False
assert headless['s2'] == True
def test_ua_browser_family(pipeline_context):
df = pd.DataFrame({
'sessionId': ['s1', 's2', 's3'],
'userAgent': ['Mozilla/5.0 Firefox/120', 'Safari/605.1.15', 'Unknown'],
})
result = UserAgentFeatureStep(pipeline_context).transform(df)
browsers = dict(zip(result['sessionId'], result['browser_family']))
assert browsers['s1'] == 'Firefox'
assert browsers['s2'] == 'Safari'
assert browsers['s3'] == 'Other'
def test_ua_automation_detection(pipeline_context):
df = pd.DataFrame({
'sessionId': ['s1', 's2'],
'userAgent': ['Selenium WebDriver', 'Normal Chrome/120'],
})
result = UserAgentFeatureStep(pipeline_context).transform(df)
auto = dict(zip(result['sessionId'], result['is_automation']))
assert auto['s1'] == True
assert auto['s2'] == False
# ExtractSessionFeaturesStep tests
def test_extract_empty(pipeline_context):
result = ExtractSessionFeaturesStep(pipeline_context).transform(pd.DataFrame())
assert result.empty
def test_extract_merges_all(pipeline_context, session_interactions):
result = ExtractSessionFeaturesStep(pipeline_context).transform(session_interactions)
expected = ['session_duration_sec', 'total_events', 'unique_products_viewed', 'is_headless']
for col in expected:
assert col in result.columns
assert 'experimentId' in result.columns
# JoinLabelsStep tests
def test_join_labels_tuple_input(pipeline_context):
features = pd.DataFrame({'sessionId': ['s1'], 'experimentId': ['exp1'], 'total_events': [5]})
experiments = pd.DataFrame({'id': ['exp1'], 'xp_human_only': [True]})
result = JoinLabelsStep(pipeline_context).transform((features, experiments))
assert 'is_agent' in result.columns
assert result.iloc[0]['is_agent'] == False
def test_join_labels_empty_experiments(pipeline_context):
features = pd.DataFrame({'sessionId': ['s1'], 'experimentId': ['exp1']})
result = JoinLabelsStep(pipeline_context).transform((features, pd.DataFrame()))
assert pd.isna(result.iloc[0]['is_agent'])
# ValidateDataStep tests
def test_validate_empty(pipeline_context):
ValidateDataStep(pipeline_context).transform(pd.DataFrame())
report = pipeline_context.get_cached('validation_report')
assert report['status'] == 'empty'
def test_validate_missing_cols(pipeline_context):
df = pd.DataFrame({'sessionId': ['s1'], 'ts': ['2025-01-01']})
ValidateDataStep(pipeline_context).transform(df)
report = pipeline_context.get_cached('validation_report')
assert report['status'] == 'invalid'
assert 'eventName' in report['missing_cols']
def test_validate_valid(pipeline_context, session_interactions):
ValidateDataStep(pipeline_context).transform(session_interactions)
report = pipeline_context.get_cached('validation_report')
assert report['status'] == 'valid'
assert report['sessions'] > 0

View File

@@ -1,41 +0,0 @@
"""PHANTOM shared library
Exports unified utilities for features, state, config, kafka, and model registry
"""
from .config import (
PROJECT_ROOT, DATA_DIR, EXPERIMENTS_DIR,
AGENT_DATA_DIR, HUMAN_DATA_DIR, SIM_RUNS_DIR, MODEL_REGISTRY_DIR,
COLLECTED_DATA_DIR, NOTEBOOK_OUTPUT_DIR,
ensure_dir, get_data_path, get_experiments_path, get_sim_path,
KAFKA_HOST, KAFKA_PORT, KAFKA_BROKER,
REDIS_HOST, REDIS_PORT,
SUPABASE_URL, SUPABASE_ANON_KEY,
BACKEND_PORT, PROVIDER_PORT
)
from .state import (
make_state_repr, event_to_state, parse_state,
get_event_name, get_timestamp,
create_state_fn, create_event_name_fn, create_timestamp_fn
)
from .features import (
transition_histogram, temporal_signature, state_coverage, transition_entropy,
event_type_distribution, featurize_trajectory, parse_timestamp
)
__all__ = [
# config
'PROJECT_ROOT', 'DATA_DIR', 'EXPERIMENTS_DIR',
'AGENT_DATA_DIR', 'HUMAN_DATA_DIR', 'SIM_RUNS_DIR', 'MODEL_REGISTRY_DIR',
'COLLECTED_DATA_DIR', 'NOTEBOOK_OUTPUT_DIR',
'ensure_dir', 'get_data_path', 'get_experiments_path', 'get_sim_path',
'KAFKA_HOST', 'KAFKA_PORT', 'KAFKA_BROKER',
'REDIS_HOST', 'REDIS_PORT',
'SUPABASE_URL', 'SUPABASE_ANON_KEY',
'BACKEND_PORT', 'PROVIDER_PORT',
# state
'make_state_repr', 'event_to_state', 'parse_state',
'get_event_name', 'get_timestamp',
'create_state_fn', 'create_event_name_fn', 'create_timestamp_fn',
# features
'transition_histogram', 'temporal_signature', 'state_coverage', 'transition_entropy',
'event_type_distribution', 'featurize_trajectory', 'parse_timestamp',
]

View File

@@ -1,79 +0,0 @@
"""Unified path configuration for PHANTOM project
All hardcoded paths should reference this module
Paths can be overridden via environment variables
"""
import os
from pathlib import Path
# project root (directory containing lib/, experiments/, sim/, web/, backend/)
PROJECT_ROOT = Path(__file__).parent.parent.resolve()
# data directories
DATA_DIR = Path(os.getenv("PHANTOM_DATA_DIR", PROJECT_ROOT / "data"))
EXPERIMENTS_DIR = Path(
os.getenv("PHANTOM_EXPERIMENTS_DIR", PROJECT_ROOT / "experiments")
)
# agent/human interaction data
AGENT_DATA_DIR = Path(os.getenv("PHANTOM_AGENT_DATA_DIR", DATA_DIR / "agents"))
HUMAN_DATA_DIR = Path(os.getenv("PHANTOM_HUMAN_DATA_DIR", DATA_DIR / "humans"))
# RL simulation runs
SIM_RUNS_DIR = Path(
os.getenv("PHANTOM_SIM_RUNS_DIR", PROJECT_ROOT / "sim" / "rl" / "runs")
)
# model artifacts
MODEL_REGISTRY_DIR = Path(os.getenv("PHANTOM_MODEL_REGISTRY_DIR", DATA_DIR / "models"))
# collected experiment data
COLLECTED_DATA_DIR = Path(
os.getenv(
"PHANTOM_COLLECTED_DATA_DIR", EXPERIMENTS_DIR / "agents" / "collected_data"
)
)
# notebook outputs
NOTEBOOK_OUTPUT_DIR = Path(
os.getenv("PHANTOM_NOTEBOOK_OUTPUT_DIR", EXPERIMENTS_DIR / "notebooks" / "outputs")
)
def ensure_dir(path: Path) -> Path:
"""ensure directory exists, create if needed"""
path.mkdir(parents=True, exist_ok=True)
return path
def get_data_path(*parts: str) -> Path:
"""construct path relative to DATA_DIR"""
return DATA_DIR.joinpath(*parts)
def get_experiments_path(*parts: str) -> Path:
"""construct path relative to EXPERIMENTS_DIR"""
return EXPERIMENTS_DIR.joinpath(*parts)
def get_sim_path(*parts: str) -> Path:
"""construct path relative to SIM_RUNS_DIR"""
return SIM_RUNS_DIR.joinpath(*parts)
# service configuration (from .env)
KAFKA_HOST = os.getenv("KAFKA_HOST", "localhost")
KAFKA_PORT = os.getenv("KAFKA_PORT", "9092")
KAFKA_BROKER = f"{KAFKA_HOST}:{KAFKA_PORT}"
REDIS_HOST = os.getenv("REDIS_HOST", "localhost")
REDIS_PORT = int(os.getenv("REDIS_PORT", "6379"))
SUPABASE_URL = os.getenv("NEXT_PUBLIC_SUPABASE_URL", "")
SUPABASE_ANON_KEY = os.getenv("NEXT_PUBLIC_SUPABASE_ANON_KEY", "")
BACKEND_PORT = int(os.getenv("BACKEND_PORT", "5000"))
PROVIDER_PORT = int(os.getenv("PROVIDER_PORT", "5001"))
# huggingface dataset repo for collected behavioral data
HF_DATASET_REPO = os.getenv("HF_DATASET_REPO", "velocitatem/phantom-collected-data")

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