diff --git a/__init__.pyc b/__init__.pyc
index 190aa10..6461079 100644
Binary files a/__init__.pyc and b/__init__.pyc differ
diff --git a/index.html b/index.html
index 8154b26..77b074d 100644
--- a/index.html
+++ b/index.html
@@ -207,7 +207,7 @@
│
├── docs <- A default Sphinx project; see sphinx-doc.org for details
│
-├── models <- trained and serialized models, model predictions, or model summaries
+├── models <- Trained and serialized models, model predictions, or model summaries
│
├── notebooks <- Jupyter notebooks. Naming convention is a number (for ordering),
│ the creator's initials, and a short `-` delimited description, e.g.
@@ -230,12 +230,15 @@
│ ├── features <- Scripts to turn raw data into features for modeling
│ │ └── build_features.py
│ │
-│ └── models <- scripts to train models and then use trained models to make
-│ │ predictions
-│ ├── predict_model.py
-│ └── train_model.py
+│ ├── models <- Scripts to train models and then use trained models to make
+│ │ │ predictions
+│ │ ├── predict_model.py
+│ │ └── train_model.py
+│ │
+│ └── visualization <- Scripts to create exploratory and results oriented visualizations
+│ └── visualize.py
│
-└── tox.ini <- tox file with settings for running tox; see tox.testrun.org
+└── tox.ini <- tox file with settings for running tox; see tox.testrun.org
Opinions
@@ -353,5 +356,5 @@ from preprocess.build_features import remove_invalid_data
diff --git a/mkdocs/search_index.json b/mkdocs/search_index.json
index 71e00f1..42b80ff 100644
--- a/mkdocs/search_index.json
+++ b/mkdocs/search_index.json
@@ -2,7 +2,7 @@
"docs": [
{
"location": "/",
- "text": "Cookiecutter Data Science\n\n\nA logical, reasonably standardized, but flexible project structure for doing and sharing data science work.\n\n\nWhy use this project structure?\n\n\nWe often think of data analysis as just the resulting report, insights, or visualizations. Even though these end products are generated by code, it's easy to focus on making the products \nlook nice\n and ignore the \nquality of the code that generates them\n. While these end products are generally the main event, \ncode quality is still important\n! And we're not talking about bikeshedding the aesthetics or pedantic formatting standards \u2014 it's ultimately about correctness and reproducibility.\n\n\nIt's no secret that good analyses are often the result of very scattershot and serendipitous explorations, tentative experiments, and rapidly testing what works and what doesn't. That is all part of the process for getting to the good stuff, and there is no magic bullet to turn data exploration into a simple, linear progression. That being said, once started it is not a process that lends itself to thinking carefully about the structure of your code or project layout.\n\n\nWe think it's a pretty big win all around to let someone else do that up-front thinking and setup for you. Here's why:\n\n\nOther people will thank you\n\n\n\n\nNobody sits around before creating a new Rails project to figure out where they want to put their views; they just run \nrails new\n to get a standard project skeleton like everybody else.\n\n\n\n\nA well-defined, standard project structure means that a newcomer can begin to understand an analysis without digging in to extensive documentation. Well organized code is self-documenting and provides a lot of context for your code without much overhead. People will thank you for this because they can:\n\n\n\n\nCollaborate easily with you on this analysis\n\n\nEasily learn from your analysis about the process and the domain\n\n\nFeel confident in the conclusions the analysis presents\n\n\n\n\nA consistent project structure means less random searching for what gets called where. A good example of this can be found in web development frameworks like Ruby on Rails, Django, and most others. Nobody sits around before creating a new Rails project to figure out where they want to put their views; they just run \nrails new\n to get a standard project skeleton like everybody else. And because the default project structure is \nreasonably logical\n and \nstandard across most projects\n, it takes almost no time at all for somebody who has never seen a particular project to figure out where they would find the various moving parts.\n\n\nIdeally, that's how it should be when a colleague opens up your data science project.\n\n\nYou will thank you\n\n\nEver tried to reproduce an analysis that you did a few months ago or even a few years ago? You may have written the code, but it's now impossible to decipher whether you should use \nmake_figures.py.old\n, \nmake_figures_working.py\n or \nnew_make_figures01.py\n to get things done. Here are some questions we've learned to ask with a sense of existential dread:\n\n\n\n\nAre we supposed to go in and join the \"region\" column to the data before we get started or did that come from one of the notebooks?\n\n\nCome to think of it, which notebook do we have to run first before running the plotting code: was it \"process data\" or \"clean data\"?\n\n\nWhere did the shapefiles get downloaded from for the geographic plots you made?\n\n\nEt cetera, times infinity.\n\n\n\n\nThese types of questions are painful and are symptoms of a disorganized project. A good project structure encourages practices that make it easier to come back to old work, for example separation of concerns, abstracting analysis as a \nDAG\n, and engineering best practices like version control.\n\n\nGetting started\n\n\nWith this in mind, we've created a data science cookiecutter template for projects in Python. Your analysis doesn't have to be in Python, but the template does provide some Python boilerplate that you'd want to remove (in the \nsrc\n folder for example, and the Sphinx documentation skeleton in \ndocs\n).\n\n\nRequirements\n\n\n\n\nPython 2.7 or 3.5\n\n\ncookiecutter Python package\n \n= 1.4.0: \npip install cookiecutter\n\n\n\n\nStarting a new project\n\n\nStarting a new project is as easy as running this command at the command line. No need to create a directory first, the cookiecutter will do it for you.\n\n\ncookiecutter https://github.com/drivendata/cookiecutter-data-science\n\n\n\nExample\n\n\n\n\n\nDirectory structure\n\n\n\u251c\u2500\u2500 LICENSE\n\u251c\u2500\u2500 Makefile \n- Makefile with commands like `make data` or `make train`\n\u251c\u2500\u2500 README.md \n- The top-level README for developers using this project.\n\u251c\u2500\u2500 data\n\u2502\u00a0\u00a0 \u251c\u2500\u2500 external \n- Data from third party sources.\n\u2502\u00a0\u00a0 \u251c\u2500\u2500 interim \n- Intermediate data that has been transformed.\n\u2502\u00a0\u00a0 \u251c\u2500\u2500 processed \n- The final, canonical data sets for modeling.\n\u2502\u00a0\u00a0 \u2514\u2500\u2500 raw \n- The original, immutable data dump.\n\u2502\n\u251c\u2500\u2500 docs \n- A default Sphinx project; see sphinx-doc.org for details\n\u2502\n\u251c\u2500\u2500 models \n- trained and serialized models, model predictions, or model summaries\n\u2502\n\u251c\u2500\u2500 notebooks \n- Jupyter notebooks. Naming convention is a number (for ordering),\n\u2502 the creator's initials, and a short `-` delimited description, e.g.\n\u2502 `1.0-jqp-initial-data-exploration`.\n\u2502\n\u251c\u2500\u2500 references \n- Data dictionaries, manuals, and all other explanatory materials.\n\u2502\n\u251c\u2500\u2500 reports \n- Generated analysis as HTML, PDF, LaTeX, etc.\n\u2502\u00a0\u00a0 \u2514\u2500\u2500 figures \n- Generated graphics and figures to be used in reporting\n\u2502\n\u251c\u2500\u2500 requirements.txt \n- The requirements file for reproducing the analysis environment, e.g.\n\u2502 generated with `pip freeze \n requirements.txt`\n\u2502\n\u251c\u2500\u2500 src \n- Source code for use in this project.\n\u2502\u00a0\u00a0 \u251c\u2500\u2500 __init__.py \n- Makes src a Python module\n\u2502 \u2502\n\u2502\u00a0\u00a0 \u251c\u2500\u2500 data \n- Scripts to download or generate data\n\u2502\u00a0\u00a0 \u2502\u00a0\u00a0 \u2514\u2500\u2500 make_dataset.py\n\u2502 \u2502\n\u2502\u00a0\u00a0 \u251c\u2500\u2500 features \n- Scripts to turn raw data into features for modeling\n\u2502\u00a0\u00a0 \u2502\u00a0\u00a0 \u2514\u2500\u2500 build_features.py\n\u2502 \u2502\n\u2502\u00a0\u00a0 \u2514\u2500\u2500 models \n- scripts to train models and then use trained models to make\n\u2502 \u2502 predictions\n\u2502\u00a0\u00a0 \u251c\u2500\u2500 predict_model.py\n\u2502\u00a0\u00a0 \u2514\u2500\u2500 train_model.py\n\u2502\n\u2514\u2500\u2500 tox.ini \n- tox file with settings for running tox; see tox.testrun.org\n\n\n\n\nOpinions\n\n\nThere are some opinions implicit in the project structure that have grown out of our experience with what works and what doesn't when collaborating on data science projects. Some of the opinions are about workflows, and some of the opinions are about tools that make life easier. Here are some of the beliefs which this project is built on\u2014if you've got thoughts, please \ncontribute or share them\n.\n\n\nData is immutable\n\n\nDon't ever edit your raw data, especially not manually, and especially not in Excel. Don't overwrite your raw data. Don't save multiple versions of the raw data. Treat the data (and its format) as immutable. The code you write should move the raw data through a pipeline to your final analysis. You shouldn't have to run all of the steps every time you want to make a new figure (see \nAnalysis is a DAG\n), but anyone should be able to reproduce the final products with only the code in \nsrc\n and the data in \ndata/raw\n.\n\n\nAlso, if data is immutable, it doesn't need source control in the same way that code does. Therefore, \nby default, the data folder is included in the \n.gitignore\n file.\n If you have a small amount of data that rarely changes, you may want to include the data in the repository. Github currently warns if files are over 50MB and rejects files over 100MB. Some other options for storing/syncing large data include \nAWS S3\n with a syncing tool (e.g., \ns3cmd\n), \nGit Large File Storage\n, \nGit Annex\n, and \ndat\n. Currently by default, we ask for an S3 bucket and use \ns3cmd\n to sync data in the \ndata\n folder with the server.\n\n\nNotebooks are for exploration and communication\n\n\nNotebook packages like the \nJupyter notebook\n, \nBeaker notebook\n, \nZeppelin\n, and other literate programming tools are very effective for exploratory data analysis. However, these tools can be less effective for reproducing an analysis. When we use notebooks in our work, we often subdivide the \nnotebooks\n folder. For example, \nnotebooks/exploratory\n contains initial explorations, whereas \nnotebooks/reports\n is more polished work that can be exported as html to the \nreports\n directory.\n\n\nSince notebooks are challenging objects for source control (e.g., diffs of the \njson\n are often not human-readable and merging is near impossible), we recommended not collaborating directly with others on Jupyter notebooks. There are two steps we recommend for using notebooks effectively:\n\n\n\n\n\n\nFollow a naming convention that shows the owner and the order the analysis was done in. We use the format \nstep\n-\nghuser\n-\ndescription\n.ipynb\n (e.g., \n0.3-bull-visualize-distributions.ipynb\n).\n\n\n\n\n\n\nRefactor the good parts. Don't write code to do the same task in multiple notebooks. If it's a data preprocessing task, put it in the pipeline at \nsrc/data/make_dataset.py\n and load data from \ndata/interim\n. If it's useful utility code, refactor it to \nsrc\n and import it into notebooks with a cell like the following. If updating the system path is icky to you, we'd recommend making a Python package (there is a \ncookiecutter for that\n as well) and installing that as an editable package with \npip install -e\n.\n\n\n\n\n\n\n# Load the \nautoreload\n extension\n%load_ext autoreload\n\n# always reload modules marked with \n%aimport\n\n%autoreload 1\n\nimport os\nimport sys\n\n# add the 'src' directory as one where we can import modules\nsrc_dir = os.path.join(os.getcwd(), os.pardir, 'src')\nsys.path.append(src_dir)\n\n# import my method from the source code\n%aimport preprocess.build_features\nfrom preprocess.build_features import remove_invalid_data\n\n\n\n\nAnalysis is a DAG\n\n\nOften in an analysis you have long-running steps that preprocesses data or trains models. If these steps have been run already (and you have stored the output somewhere like the \ndata/interim\n directory), you don't want to wait to rerun them every time. We prefer \nmake\n for managing steps that depend on each other, especially the long-running ones. Make is a common tool on unix platforms (and \nis available for Windows\n). Following the \nmake\n documentation\n, \nMakefile conventions\n, and \nportability guide\n will help ensure your Makefiles work effectively across systems. Here are \nsome\n \nexamples\n to \nget started\n. A number of data folks use \nmake\n as their tool of choice, including \nMike Bostock\n.\n\n\nThere are other tools for managing DAGs that are written in Python instead of a DSL (e.g., \nPaver\n, \nLuigi\n, \nAirflow\n, \nSnakemake\n, \nRuffus\n, or \nJoblib\n). Feel free to use these if they are more appropriate for your analysis.\n\n\nBuild from the environment up\n\n\nThe first step in reproducing an analysis is always reproducing the computational environment it was run in. You need the same tools, the same libraries, and the same versions to make everything play nicely together.\n\n\nOne effective approach to this is use \nvirtualenv\n (we recommend \nvirtualenvwrapper\n for managing virtualenvs). By listing all of your requirements in the repository (we include a \nrequirements.txt\n file) you can easily track the packages needed to recreate the analysis. Here is a good workflow:\n\n\n\n\nRun \nmkvirtualenv\n when creating a new project\n\n\npip install\n the packages that your analysis needs\n\n\nRun \npip freeze \n requirements.txt\n to pin the exact package versions used to recreate the analysis\n\n\nIf you find you need to install another package, run \npip freeze \n requirements.txt\n again and commit the changes to version control.\n\n\n\n\nIf you have more complex requirements for recreating your environment, consider a virtual machine based approach such as \nDocker\n or \nVagrant\n. Both of these tools use text-based formats (Dockerfile and Vagrantfile respectively) you can easily add to source control to describe how to create a virtual machine with the requirements you need.\n\n\nKeep secrets out of version control\n\n\nYou \nreally\n don't want to leak your AWS secret key or Postgres username and password on Github. Enough said, mostly \u2014 see the \nTwelve Factor App\n principles on this point. We generally use a \n.env\n file that, thanks to the \n.gitignore\n, never makes it into the repository (secrets should be shared via other means with contributors). The \n.env\n file defines secrets as environment variables, and is read in automatically by a package like \ndotenv\n in Python.\n\n\nContributing\n\n\nThe Cookiecutter Data Science project is opinionated, but not afraid to be wrong. Best practices change, tools evolve, and lessons are learned. \nThe goal of this project is to make it easier to start, structure, and share an analysis.\n \nPull requests\n and \nfiling issues\n is encouraged. We'd love to hear what works for you, and what doesn't.\n\n\nIf you use the Cookiecutter Data Science project, link back to this page or \ngive us a holler\n and \nlet us know\n!\n\n\nLinks to related projects and references\n\n\nProject structure and reproducibility is talked about more in the R research community. Here are some projects and blog posts if you're working in R that may help you out.\n\n\n\n\nProject Template\n - An R data analysis template\n\n\n\"\nDesigning projects\n\" on Nice R Code\n\n\n\"\nMy research workflow\n\" on Carlboettifer.info\n\n\n\"\nA Quick Guide to Organizing Computational Biology Projects\n\" in PLOS Computational Biology\n\n\n\n\nFinally, a huge thanks to the \nCookiecutter\n project (\ngithub\n), which is helping us all spend less time thinking about and writing boilerplate and more time getting things done.",
+ "text": "Cookiecutter Data Science\n\n\nA logical, reasonably standardized, but flexible project structure for doing and sharing data science work.\n\n\nWhy use this project structure?\n\n\nWe often think of data analysis as just the resulting report, insights, or visualizations. Even though these end products are generated by code, it's easy to focus on making the products \nlook nice\n and ignore the \nquality of the code that generates them\n. While these end products are generally the main event, \ncode quality is still important\n! And we're not talking about bikeshedding the aesthetics or pedantic formatting standards \u2014 it's ultimately about correctness and reproducibility.\n\n\nIt's no secret that good analyses are often the result of very scattershot and serendipitous explorations, tentative experiments, and rapidly testing what works and what doesn't. That is all part of the process for getting to the good stuff, and there is no magic bullet to turn data exploration into a simple, linear progression. That being said, once started it is not a process that lends itself to thinking carefully about the structure of your code or project layout.\n\n\nWe think it's a pretty big win all around to let someone else do that up-front thinking and setup for you. Here's why:\n\n\nOther people will thank you\n\n\n\n\nNobody sits around before creating a new Rails project to figure out where they want to put their views; they just run \nrails new\n to get a standard project skeleton like everybody else.\n\n\n\n\nA well-defined, standard project structure means that a newcomer can begin to understand an analysis without digging in to extensive documentation. Well organized code is self-documenting and provides a lot of context for your code without much overhead. People will thank you for this because they can:\n\n\n\n\nCollaborate easily with you on this analysis\n\n\nEasily learn from your analysis about the process and the domain\n\n\nFeel confident in the conclusions the analysis presents\n\n\n\n\nA consistent project structure means less random searching for what gets called where. A good example of this can be found in web development frameworks like Ruby on Rails, Django, and most others. Nobody sits around before creating a new Rails project to figure out where they want to put their views; they just run \nrails new\n to get a standard project skeleton like everybody else. And because the default project structure is \nreasonably logical\n and \nstandard across most projects\n, it takes almost no time at all for somebody who has never seen a particular project to figure out where they would find the various moving parts.\n\n\nIdeally, that's how it should be when a colleague opens up your data science project.\n\n\nYou will thank you\n\n\nEver tried to reproduce an analysis that you did a few months ago or even a few years ago? You may have written the code, but it's now impossible to decipher whether you should use \nmake_figures.py.old\n, \nmake_figures_working.py\n or \nnew_make_figures01.py\n to get things done. Here are some questions we've learned to ask with a sense of existential dread:\n\n\n\n\nAre we supposed to go in and join the \"region\" column to the data before we get started or did that come from one of the notebooks?\n\n\nCome to think of it, which notebook do we have to run first before running the plotting code: was it \"process data\" or \"clean data\"?\n\n\nWhere did the shapefiles get downloaded from for the geographic plots you made?\n\n\nEt cetera, times infinity.\n\n\n\n\nThese types of questions are painful and are symptoms of a disorganized project. A good project structure encourages practices that make it easier to come back to old work, for example separation of concerns, abstracting analysis as a \nDAG\n, and engineering best practices like version control.\n\n\nGetting started\n\n\nWith this in mind, we've created a data science cookiecutter template for projects in Python. Your analysis doesn't have to be in Python, but the template does provide some Python boilerplate that you'd want to remove (in the \nsrc\n folder for example, and the Sphinx documentation skeleton in \ndocs\n).\n\n\nRequirements\n\n\n\n\nPython 2.7 or 3.5\n\n\ncookiecutter Python package\n \n= 1.4.0: \npip install cookiecutter\n\n\n\n\nStarting a new project\n\n\nStarting a new project is as easy as running this command at the command line. No need to create a directory first, the cookiecutter will do it for you.\n\n\ncookiecutter https://github.com/drivendata/cookiecutter-data-science\n\n\n\nExample\n\n\n\n\n\nDirectory structure\n\n\n\u251c\u2500\u2500 LICENSE\n\u251c\u2500\u2500 Makefile \n- Makefile with commands like `make data` or `make train`\n\u251c\u2500\u2500 README.md \n- The top-level README for developers using this project.\n\u251c\u2500\u2500 data\n\u2502\u00a0\u00a0 \u251c\u2500\u2500 external \n- Data from third party sources.\n\u2502\u00a0\u00a0 \u251c\u2500\u2500 interim \n- Intermediate data that has been transformed.\n\u2502\u00a0\u00a0 \u251c\u2500\u2500 processed \n- The final, canonical data sets for modeling.\n\u2502\u00a0\u00a0 \u2514\u2500\u2500 raw \n- The original, immutable data dump.\n\u2502\n\u251c\u2500\u2500 docs \n- A default Sphinx project; see sphinx-doc.org for details\n\u2502\n\u251c\u2500\u2500 models \n- Trained and serialized models, model predictions, or model summaries\n\u2502\n\u251c\u2500\u2500 notebooks \n- Jupyter notebooks. Naming convention is a number (for ordering),\n\u2502 the creator's initials, and a short `-` delimited description, e.g.\n\u2502 `1.0-jqp-initial-data-exploration`.\n\u2502\n\u251c\u2500\u2500 references \n- Data dictionaries, manuals, and all other explanatory materials.\n\u2502\n\u251c\u2500\u2500 reports \n- Generated analysis as HTML, PDF, LaTeX, etc.\n\u2502\u00a0\u00a0 \u2514\u2500\u2500 figures \n- Generated graphics and figures to be used in reporting\n\u2502\n\u251c\u2500\u2500 requirements.txt \n- The requirements file for reproducing the analysis environment, e.g.\n\u2502 generated with `pip freeze \n requirements.txt`\n\u2502\n\u251c\u2500\u2500 src \n- Source code for use in this project.\n\u2502\u00a0\u00a0 \u251c\u2500\u2500 __init__.py \n- Makes src a Python module\n\u2502 \u2502\n\u2502\u00a0\u00a0 \u251c\u2500\u2500 data \n- Scripts to download or generate data\n\u2502\u00a0\u00a0 \u2502\u00a0\u00a0 \u2514\u2500\u2500 make_dataset.py\n\u2502 \u2502\n\u2502\u00a0\u00a0 \u251c\u2500\u2500 features \n- Scripts to turn raw data into features for modeling\n\u2502\u00a0\u00a0 \u2502\u00a0\u00a0 \u2514\u2500\u2500 build_features.py\n\u2502 \u2502\n\u2502\u00a0\u00a0 \u251c\u2500\u2500 models \n- Scripts to train models and then use trained models to make\n\u2502 \u2502 \u2502 predictions\n\u2502\u00a0\u00a0 \u2502\u00a0\u00a0 \u251c\u2500\u2500 predict_model.py\n\u2502\u00a0\u00a0 \u2502\u00a0\u00a0 \u2514\u2500\u2500 train_model.py\n\u2502 \u2502\n\u2502\u00a0\u00a0 \u2514\u2500\u2500 visualization \n- Scripts to create exploratory and results oriented visualizations\n\u2502\u00a0\u00a0 \u2514\u2500\u2500 visualize.py\n\u2502\n\u2514\u2500\u2500 tox.ini \n- tox file with settings for running tox; see tox.testrun.org\n\n\n\n\nOpinions\n\n\nThere are some opinions implicit in the project structure that have grown out of our experience with what works and what doesn't when collaborating on data science projects. Some of the opinions are about workflows, and some of the opinions are about tools that make life easier. Here are some of the beliefs which this project is built on\u2014if you've got thoughts, please \ncontribute or share them\n.\n\n\nData is immutable\n\n\nDon't ever edit your raw data, especially not manually, and especially not in Excel. Don't overwrite your raw data. Don't save multiple versions of the raw data. Treat the data (and its format) as immutable. The code you write should move the raw data through a pipeline to your final analysis. You shouldn't have to run all of the steps every time you want to make a new figure (see \nAnalysis is a DAG\n), but anyone should be able to reproduce the final products with only the code in \nsrc\n and the data in \ndata/raw\n.\n\n\nAlso, if data is immutable, it doesn't need source control in the same way that code does. Therefore, \nby default, the data folder is included in the \n.gitignore\n file.\n If you have a small amount of data that rarely changes, you may want to include the data in the repository. Github currently warns if files are over 50MB and rejects files over 100MB. Some other options for storing/syncing large data include \nAWS S3\n with a syncing tool (e.g., \ns3cmd\n), \nGit Large File Storage\n, \nGit Annex\n, and \ndat\n. Currently by default, we ask for an S3 bucket and use \ns3cmd\n to sync data in the \ndata\n folder with the server.\n\n\nNotebooks are for exploration and communication\n\n\nNotebook packages like the \nJupyter notebook\n, \nBeaker notebook\n, \nZeppelin\n, and other literate programming tools are very effective for exploratory data analysis. However, these tools can be less effective for reproducing an analysis. When we use notebooks in our work, we often subdivide the \nnotebooks\n folder. For example, \nnotebooks/exploratory\n contains initial explorations, whereas \nnotebooks/reports\n is more polished work that can be exported as html to the \nreports\n directory.\n\n\nSince notebooks are challenging objects for source control (e.g., diffs of the \njson\n are often not human-readable and merging is near impossible), we recommended not collaborating directly with others on Jupyter notebooks. There are two steps we recommend for using notebooks effectively:\n\n\n\n\n\n\nFollow a naming convention that shows the owner and the order the analysis was done in. We use the format \nstep\n-\nghuser\n-\ndescription\n.ipynb\n (e.g., \n0.3-bull-visualize-distributions.ipynb\n).\n\n\n\n\n\n\nRefactor the good parts. Don't write code to do the same task in multiple notebooks. If it's a data preprocessing task, put it in the pipeline at \nsrc/data/make_dataset.py\n and load data from \ndata/interim\n. If it's useful utility code, refactor it to \nsrc\n and import it into notebooks with a cell like the following. If updating the system path is icky to you, we'd recommend making a Python package (there is a \ncookiecutter for that\n as well) and installing that as an editable package with \npip install -e\n.\n\n\n\n\n\n\n# Load the \nautoreload\n extension\n%load_ext autoreload\n\n# always reload modules marked with \n%aimport\n\n%autoreload 1\n\nimport os\nimport sys\n\n# add the 'src' directory as one where we can import modules\nsrc_dir = os.path.join(os.getcwd(), os.pardir, 'src')\nsys.path.append(src_dir)\n\n# import my method from the source code\n%aimport preprocess.build_features\nfrom preprocess.build_features import remove_invalid_data\n\n\n\n\nAnalysis is a DAG\n\n\nOften in an analysis you have long-running steps that preprocesses data or trains models. If these steps have been run already (and you have stored the output somewhere like the \ndata/interim\n directory), you don't want to wait to rerun them every time. We prefer \nmake\n for managing steps that depend on each other, especially the long-running ones. Make is a common tool on unix platforms (and \nis available for Windows\n). Following the \nmake\n documentation\n, \nMakefile conventions\n, and \nportability guide\n will help ensure your Makefiles work effectively across systems. Here are \nsome\n \nexamples\n to \nget started\n. A number of data folks use \nmake\n as their tool of choice, including \nMike Bostock\n.\n\n\nThere are other tools for managing DAGs that are written in Python instead of a DSL (e.g., \nPaver\n, \nLuigi\n, \nAirflow\n, \nSnakemake\n, \nRuffus\n, or \nJoblib\n). Feel free to use these if they are more appropriate for your analysis.\n\n\nBuild from the environment up\n\n\nThe first step in reproducing an analysis is always reproducing the computational environment it was run in. You need the same tools, the same libraries, and the same versions to make everything play nicely together.\n\n\nOne effective approach to this is use \nvirtualenv\n (we recommend \nvirtualenvwrapper\n for managing virtualenvs). By listing all of your requirements in the repository (we include a \nrequirements.txt\n file) you can easily track the packages needed to recreate the analysis. Here is a good workflow:\n\n\n\n\nRun \nmkvirtualenv\n when creating a new project\n\n\npip install\n the packages that your analysis needs\n\n\nRun \npip freeze \n requirements.txt\n to pin the exact package versions used to recreate the analysis\n\n\nIf you find you need to install another package, run \npip freeze \n requirements.txt\n again and commit the changes to version control.\n\n\n\n\nIf you have more complex requirements for recreating your environment, consider a virtual machine based approach such as \nDocker\n or \nVagrant\n. Both of these tools use text-based formats (Dockerfile and Vagrantfile respectively) you can easily add to source control to describe how to create a virtual machine with the requirements you need.\n\n\nKeep secrets out of version control\n\n\nYou \nreally\n don't want to leak your AWS secret key or Postgres username and password on Github. Enough said, mostly \u2014 see the \nTwelve Factor App\n principles on this point. We generally use a \n.env\n file that, thanks to the \n.gitignore\n, never makes it into the repository (secrets should be shared via other means with contributors). The \n.env\n file defines secrets as environment variables, and is read in automatically by a package like \ndotenv\n in Python.\n\n\nContributing\n\n\nThe Cookiecutter Data Science project is opinionated, but not afraid to be wrong. Best practices change, tools evolve, and lessons are learned. \nThe goal of this project is to make it easier to start, structure, and share an analysis.\n \nPull requests\n and \nfiling issues\n is encouraged. We'd love to hear what works for you, and what doesn't.\n\n\nIf you use the Cookiecutter Data Science project, link back to this page or \ngive us a holler\n and \nlet us know\n!\n\n\nLinks to related projects and references\n\n\nProject structure and reproducibility is talked about more in the R research community. Here are some projects and blog posts if you're working in R that may help you out.\n\n\n\n\nProject Template\n - An R data analysis template\n\n\n\"\nDesigning projects\n\" on Nice R Code\n\n\n\"\nMy research workflow\n\" on Carlboettifer.info\n\n\n\"\nA Quick Guide to Organizing Computational Biology Projects\n\" in PLOS Computational Biology\n\n\n\n\nFinally, a huge thanks to the \nCookiecutter\n project (\ngithub\n), which is helping us all spend less time thinking about and writing boilerplate and more time getting things done.",
"title": "Home"
},
{
@@ -47,7 +47,7 @@
},
{
"location": "/#directory-structure",
- "text": "\u251c\u2500\u2500 LICENSE\n\u251c\u2500\u2500 Makefile - Makefile with commands like `make data` or `make train`\n\u251c\u2500\u2500 README.md - The top-level README for developers using this project.\n\u251c\u2500\u2500 data\n\u2502\u00a0\u00a0 \u251c\u2500\u2500 external - Data from third party sources.\n\u2502\u00a0\u00a0 \u251c\u2500\u2500 interim - Intermediate data that has been transformed.\n\u2502\u00a0\u00a0 \u251c\u2500\u2500 processed - The final, canonical data sets for modeling.\n\u2502\u00a0\u00a0 \u2514\u2500\u2500 raw - The original, immutable data dump.\n\u2502\n\u251c\u2500\u2500 docs - A default Sphinx project; see sphinx-doc.org for details\n\u2502\n\u251c\u2500\u2500 models - trained and serialized models, model predictions, or model summaries\n\u2502\n\u251c\u2500\u2500 notebooks - Jupyter notebooks. Naming convention is a number (for ordering),\n\u2502 the creator's initials, and a short `-` delimited description, e.g.\n\u2502 `1.0-jqp-initial-data-exploration`.\n\u2502\n\u251c\u2500\u2500 references - Data dictionaries, manuals, and all other explanatory materials.\n\u2502\n\u251c\u2500\u2500 reports - Generated analysis as HTML, PDF, LaTeX, etc.\n\u2502\u00a0\u00a0 \u2514\u2500\u2500 figures - Generated graphics and figures to be used in reporting\n\u2502\n\u251c\u2500\u2500 requirements.txt - The requirements file for reproducing the analysis environment, e.g.\n\u2502 generated with `pip freeze requirements.txt`\n\u2502\n\u251c\u2500\u2500 src - Source code for use in this project.\n\u2502\u00a0\u00a0 \u251c\u2500\u2500 __init__.py - Makes src a Python module\n\u2502 \u2502\n\u2502\u00a0\u00a0 \u251c\u2500\u2500 data - Scripts to download or generate data\n\u2502\u00a0\u00a0 \u2502\u00a0\u00a0 \u2514\u2500\u2500 make_dataset.py\n\u2502 \u2502\n\u2502\u00a0\u00a0 \u251c\u2500\u2500 features - Scripts to turn raw data into features for modeling\n\u2502\u00a0\u00a0 \u2502\u00a0\u00a0 \u2514\u2500\u2500 build_features.py\n\u2502 \u2502\n\u2502\u00a0\u00a0 \u2514\u2500\u2500 models - scripts to train models and then use trained models to make\n\u2502 \u2502 predictions\n\u2502\u00a0\u00a0 \u251c\u2500\u2500 predict_model.py\n\u2502\u00a0\u00a0 \u2514\u2500\u2500 train_model.py\n\u2502\n\u2514\u2500\u2500 tox.ini - tox file with settings for running tox; see tox.testrun.org",
+ "text": "\u251c\u2500\u2500 LICENSE\n\u251c\u2500\u2500 Makefile - Makefile with commands like `make data` or `make train`\n\u251c\u2500\u2500 README.md - The top-level README for developers using this project.\n\u251c\u2500\u2500 data\n\u2502\u00a0\u00a0 \u251c\u2500\u2500 external - Data from third party sources.\n\u2502\u00a0\u00a0 \u251c\u2500\u2500 interim - Intermediate data that has been transformed.\n\u2502\u00a0\u00a0 \u251c\u2500\u2500 processed - The final, canonical data sets for modeling.\n\u2502\u00a0\u00a0 \u2514\u2500\u2500 raw - The original, immutable data dump.\n\u2502\n\u251c\u2500\u2500 docs - A default Sphinx project; see sphinx-doc.org for details\n\u2502\n\u251c\u2500\u2500 models - Trained and serialized models, model predictions, or model summaries\n\u2502\n\u251c\u2500\u2500 notebooks - Jupyter notebooks. Naming convention is a number (for ordering),\n\u2502 the creator's initials, and a short `-` delimited description, e.g.\n\u2502 `1.0-jqp-initial-data-exploration`.\n\u2502\n\u251c\u2500\u2500 references - Data dictionaries, manuals, and all other explanatory materials.\n\u2502\n\u251c\u2500\u2500 reports - Generated analysis as HTML, PDF, LaTeX, etc.\n\u2502\u00a0\u00a0 \u2514\u2500\u2500 figures - Generated graphics and figures to be used in reporting\n\u2502\n\u251c\u2500\u2500 requirements.txt - The requirements file for reproducing the analysis environment, e.g.\n\u2502 generated with `pip freeze requirements.txt`\n\u2502\n\u251c\u2500\u2500 src - Source code for use in this project.\n\u2502\u00a0\u00a0 \u251c\u2500\u2500 __init__.py - Makes src a Python module\n\u2502 \u2502\n\u2502\u00a0\u00a0 \u251c\u2500\u2500 data - Scripts to download or generate data\n\u2502\u00a0\u00a0 \u2502\u00a0\u00a0 \u2514\u2500\u2500 make_dataset.py\n\u2502 \u2502\n\u2502\u00a0\u00a0 \u251c\u2500\u2500 features - Scripts to turn raw data into features for modeling\n\u2502\u00a0\u00a0 \u2502\u00a0\u00a0 \u2514\u2500\u2500 build_features.py\n\u2502 \u2502\n\u2502\u00a0\u00a0 \u251c\u2500\u2500 models - Scripts to train models and then use trained models to make\n\u2502 \u2502 \u2502 predictions\n\u2502\u00a0\u00a0 \u2502\u00a0\u00a0 \u251c\u2500\u2500 predict_model.py\n\u2502\u00a0\u00a0 \u2502\u00a0\u00a0 \u2514\u2500\u2500 train_model.py\n\u2502 \u2502\n\u2502\u00a0\u00a0 \u2514\u2500\u2500 visualization - Scripts to create exploratory and results oriented visualizations\n\u2502\u00a0\u00a0 \u2514\u2500\u2500 visualize.py\n\u2502\n\u2514\u2500\u2500 tox.ini - tox file with settings for running tox; see tox.testrun.org",
"title": "Directory structure"
},
{
diff --git a/sitemap.xml b/sitemap.xml
index 98851a6..fa6ef6b 100644
--- a/sitemap.xml
+++ b/sitemap.xml
@@ -4,7 +4,7 @@
None/
- 2016-04-25
+ 2016-04-27
daily