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Browse files- requirements.txt +1 -1
- run.ipynb +1 -1
- run.py +2 -2
requirements.txt
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https://gradio-builds.s3.amazonaws.com/
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vega_datasets
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pandas
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https://gradio-builds.s3.amazonaws.com/da05e59a53bbad15e5755a47f46685da18e1031e/gradio-3.44.4-py3-none-any.whl
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vega_datasets
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pandas
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run.ipynb
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{"cells": [{"cell_type": "markdown", "id": 302934307671667531413257853548643485645, "metadata": {}, "source": ["# Gradio Demo: scatter_plot"]}, {"cell_type": "code", "execution_count": null, "id": 272996653310673477252411125948039410165, "metadata": {}, "outputs": [], "source": ["!pip install -q gradio vega_datasets pandas"]}, {"cell_type": "code", "execution_count": null, "id": 288918539441861185822528903084949547379, "metadata": {}, "outputs": [], "source": ["import gradio as gr\n", "from vega_datasets import data\n", "\n", "cars = data.cars()\n", "iris = data.iris()\n", "\n", "# # Or generate your own fake data\n", "\n", "# import pandas as pd\n", "# import random\n", "\n", "# cars_data = {\n", "# \"Name\": [\"car name \" + f\" {int(i/10)}\" for i in range(400)],\n", "# \"Miles_per_Gallon\": [random.randint(10, 30) for _ in range(400)],\n", "# \"Origin\": [random.choice([\"USA\", \"Europe\", \"Japan\"]) for _ in range(400)],\n", "# \"Horsepower\": [random.randint(50, 250) for _ in range(400)],\n", "# }\n", "\n", "# iris_data = {\n", "# \"petalWidth\": [round(random.uniform(0, 2.5), 2) for _ in range(150)],\n", "# \"petalLength\": [round(random.uniform(0, 7), 2) for _ in range(150)],\n", "# \"species\": [\n", "# random.choice([\"setosa\", \"versicolor\", \"virginica\"]) for _ in range(150)\n", "# ],\n", "# }\n", "\n", "# cars = pd.DataFrame(cars_data)\n", "# iris = pd.DataFrame(iris_data)\n", "\n", "\n", "def scatter_plot_fn(dataset):\n", " if dataset == \"iris\":\n", " return gr.ScatterPlot
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{"cells": [{"cell_type": "markdown", "id": 302934307671667531413257853548643485645, "metadata": {}, "source": ["# Gradio Demo: scatter_plot"]}, {"cell_type": "code", "execution_count": null, "id": 272996653310673477252411125948039410165, "metadata": {}, "outputs": [], "source": ["!pip install -q gradio vega_datasets pandas"]}, {"cell_type": "code", "execution_count": null, "id": 288918539441861185822528903084949547379, "metadata": {}, "outputs": [], "source": ["import gradio as gr\n", "from vega_datasets import data\n", "\n", "cars = data.cars()\n", "iris = data.iris()\n", "\n", "# # Or generate your own fake data\n", "\n", "# import pandas as pd\n", "# import random\n", "\n", "# cars_data = {\n", "# \"Name\": [\"car name \" + f\" {int(i/10)}\" for i in range(400)],\n", "# \"Miles_per_Gallon\": [random.randint(10, 30) for _ in range(400)],\n", "# \"Origin\": [random.choice([\"USA\", \"Europe\", \"Japan\"]) for _ in range(400)],\n", "# \"Horsepower\": [random.randint(50, 250) for _ in range(400)],\n", "# }\n", "\n", "# iris_data = {\n", "# \"petalWidth\": [round(random.uniform(0, 2.5), 2) for _ in range(150)],\n", "# \"petalLength\": [round(random.uniform(0, 7), 2) for _ in range(150)],\n", "# \"species\": [\n", "# random.choice([\"setosa\", \"versicolor\", \"virginica\"]) for _ in range(150)\n", "# ],\n", "# }\n", "\n", "# cars = pd.DataFrame(cars_data)\n", "# iris = pd.DataFrame(iris_data)\n", "\n", "\n", "def scatter_plot_fn(dataset):\n", " if dataset == \"iris\":\n", " return gr.ScatterPlot(\n", " value=iris,\n", " x=\"petalWidth\",\n", " y=\"petalLength\",\n", " color=\"species\",\n", " title=\"Iris Dataset\",\n", " color_legend_title=\"Species\",\n", " x_title=\"Petal Width\",\n", " y_title=\"Petal Length\",\n", " tooltip=[\"petalWidth\", \"petalLength\", \"species\"],\n", " caption=\"\",\n", " )\n", " else:\n", " return gr.ScatterPlot(\n", " value=cars,\n", " x=\"Horsepower\",\n", " y=\"Miles_per_Gallon\",\n", " color=\"Origin\",\n", " tooltip=\"Name\",\n", " title=\"Car Data\",\n", " y_title=\"Miles per Gallon\",\n", " color_legend_title=\"Origin of Car\",\n", " caption=\"MPG vs Horsepower of various cars\",\n", " )\n", "\n", "\n", "with gr.Blocks() as scatter_plot:\n", " with gr.Row():\n", " with gr.Column():\n", " dataset = gr.Dropdown(choices=[\"cars\", \"iris\"], value=\"cars\")\n", " with gr.Column():\n", " plot = gr.ScatterPlot()\n", " dataset.change(scatter_plot_fn, inputs=dataset, outputs=plot)\n", " scatter_plot.load(fn=scatter_plot_fn, inputs=dataset, outputs=plot)\n", "\n", "if __name__ == \"__main__\":\n", " scatter_plot.launch()\n"]}], "metadata": {}, "nbformat": 4, "nbformat_minor": 5}
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run.py
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@@ -30,7 +30,7 @@ iris = data.iris()
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def scatter_plot_fn(dataset):
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if dataset == "iris":
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return gr.ScatterPlot
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value=iris,
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x="petalWidth",
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y="petalLength",
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caption="",
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)
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else:
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return gr.ScatterPlot
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value=cars,
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x="Horsepower",
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y="Miles_per_Gallon",
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def scatter_plot_fn(dataset):
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if dataset == "iris":
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return gr.ScatterPlot(
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value=iris,
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x="petalWidth",
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y="petalLength",
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caption="",
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)
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else:
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return gr.ScatterPlot(
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value=cars,
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x="Horsepower",
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y="Miles_per_Gallon",
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