Skip to main content

Simulação de escoamento multifásico permanente e transiente.

Project description

drawing


Marlim3 is a 1D multiphase flow simulator developed by Petrobras.

Core capabilities (steady-state and transient)

  • Production wells
  • Injection wells: Water or gas injection wells, both single-phase and multiphase
  • Networks
    • Production networks
    • Injection networks
    • Gas lift loops
  • Artificial Lift models: gas lift valves, pumps

Advanced modeling

  • Natural convection: 2D solutions for natural convection analysis in confined spaces (single-phase or two-phase), such as pipeline cross-sections during production shutdowns
  • Compositional fluid model library
  • Near wellbore model: radial and 2D models to consider phenomena such as water coning
  • Thermal diffusion: 2D and 3D coupled to the 1D flow model

Installation

Option 1: Install via pip

Install Marlim3 as a Python package:

pip install marlim3

Option 2: Use the executable directly

You can download the Marlim3 executable for Linux, Windows or Mac from the Releases section on GitHub. This standalone executable allows you to run simulations directly from the terminal, without the need to install the Python package. Detailed instructions are provided below.

Option 3: Developer setup (uv)

For development, use uv to manage the Python environment and dependencies.

Step 1 — Install dependencies and the Python package:

uv sync --locked --group dev

This creates a .venv with Python 3.12+, installs all dev tools (pytest, flake8, jupyter, etc.), and installs marlim3 in editable mode. After this step you can already use import marlim3 in your scripts:

uv run python -c "import marlim3; print(marlim3.__version__)"

Step 2 — Build and register the C++/Fortran executable (required to run simulations):

See Compilation below. The CMake build automatically copies the executable into marlim3/ after each successful build (via a POST_BUILD step), so no manual copy is needed. Then run:

MARLIM3_SKIP_BUILD=1 uv sync --locked

MARLIM3_SKIP_BUILD=1 skips local CMake compilation. Set MARLIM3_SKIP_EXECUTABLE_RESOLUTION=1 only when an import must not resolve or download the executable.

Usage

Option 1: Python Package

Use Marlim3 as a Python library in your scripts:

import marlim3

# Build a model in English
branch = marlim3.Branch()
branch.system = "PROD"
branch.productionFluid = [{"id": 0, "api": 30, "gor": 100, "gasDensity": 0.7, "bsw": 0.0}]
branch.simulate()

The Python API is fully bilingual — you can use Portuguese or English interchangeably:

import marlim3

# Build a model entirely in Portuguese
tramo = marlim3.Tramo()
tramo.sistema = "PROD"
tramo.fluidosProducao = [{"id": 0, "api": 30, "rgo": 100, "densidadeGas": 0.7, "bsw": 0.0}]
tramo.secaoTransversal = [{"id": 0, "diametroInterno": 0.254, "rugosidade": 1.83e-4,
                           "camadas": [{"idMaterial": 0, "tipoMedicaoCamada": "ESPESSURA", "espessura": 0.0254}]}]

# Nested access also works in both languages
tramo.fluidosProducao[0]["densidadeGas"]  # → 0.7
tramo.productionFluid[0]["gasDensity"]    # → 0.7 (same data)

# Export in Portuguese
tramo.to_json("modelo", language='pt')

See Bilingual Support for details. For examples, refer to the tutorials in docs/.

Option 2: Command-Line Executable

Run Marlim3 directly from the terminal using the compiled executable available in the Releases section on GitHub.

Available Commands

There are four simulation types available:

1. Simple Production System

./executable_name -d directory_name -i input_file

2. Simple Injection System

./executable_name -d directory_name -i input_file -s INJETOR

3. Flow Network

./executable_name -d directory_name -i input_file -s REDE

4. Natural Convection in Cross-Section

./executable_name -d directory_name -i input_file -s CONVECNAT

Command-Line Arguments

  • -d directory_name: Output directory for simulation results
  • -i input_file: Input file name (JSON format)
  • -s SIMULATION_TYPE: Simulation type (INJETOR, REDE, or CONVECNAT)

Platform-Specific Notes

Linux/macOS:

./Marlim3 -d ./output -i simulation.json -s REDE

Windows:

Marlim3.exe -d .\output -i simulation.json -s REDE

Tip: To export results to the current working directory, use ./ (Linux/macOS) or .\ (Windows) as the directory name.

Compilation

Compilation is only necessary if you need to rebuild the executable from source.

Requirements

  • GCC/G++ >= 9.0
  • GFortran >= 9.0
  • CMake >= 3.16

Build the executable

The project uses CMake presets. Available presets:

Preset Platform Description
gcc-release / gcc-debug Linux / macOS GCC portable build with GNU runtime linking configured by CMake
mingw-release / mingw-debug Windows MinGW portable build with full static linking
clang-release / clang-debug Linux / macOS Clang 20 + GFortran portable build

Release assets are built and tested for Linux x64, Windows x64, and macOS ARM64. Linux, Windows, and macOS ARM64 release executables are built so end users do not need GCC runtime libraries installed.

Linux

cmake --preset gcc-release
cmake --build --preset gcc-release -j$(nproc)

MacOS - Apple

On macOS, install Homebrew GCC and CMake before building locally:

brew install gcc cmake
cmake --preset gcc-release
cmake --build --preset gcc-release -j$(sysctl -n hw.ncpu)

Windows (MSYS2 / MinGW64)

Ensure g++ and gfortran are in your PATH (e.g., via MSYS2 with the mingw-w64-x86_64-gcc and mingw-w64-x86_64-gcc-fortran packages).

cmake --preset mingw-release
cmake --build --preset mingw-release -j%NUMBER_OF_PROCESSORS%

The resulting build/Marlim3.exe is fully statically linked and does not require external DLLs.

The compiled executable is placed at build/Marlim3.

A CMake POST_BUILD step automatically copies the executable to marlim3/ after each successful build, so the Python package always picks up the latest binary. No manual copy is needed.

Then activate the package locally (skipping recompilation):

MARLIM3_SKIP_BUILD=1 uv sync --locked

MARLIM3_SKIP_BUILD=1 skips local CMake compilation; installed packages can still download the release executable on import.

Run tests

uv run pytest tests/ -v

Run the GUI

uv sync --group gui
uv run streamlit run gui/app.py

The GUI auto-detects the executable from build/Marlim3.

Note

Several resources and portions of the source code are currently written in Portuguese. We plan to gradually translate all content into English.

The Python API is fully bilingual (EN/PT) — see docs/translations.md.

Project details


Download files

Download the file for your platform. If you're not sure which to choose, learn more about installing packages.

Source Distribution

marlim3-3.7.1.tar.gz (104.2 kB view details)

Uploaded Source

Built Distribution

If you're not sure about the file name format, learn more about wheel file names.

marlim3-3.7.1-py3-none-any.whl (93.3 kB view details)

Uploaded Python 3

File details

Details for the file marlim3-3.7.1.tar.gz.

File metadata

  • Download URL: marlim3-3.7.1.tar.gz
  • Upload date:
  • Size: 104.2 kB
  • Tags: Source
  • Uploaded using Trusted Publishing? No
  • Uploaded via: twine/6.1.0 CPython/3.13.12

File hashes

Hashes for marlim3-3.7.1.tar.gz
Algorithm Hash digest
SHA256 3158286973ab47aaf8a52e27ce0d9679223397c56f1b51cbefd7458fe3188a75
MD5 fe153d9c5eb1b3a2761fca3ae6d29ced
BLAKE2b-256 0869267f9d7b67f145b3ddea928226b67867e956f082d1c95a3d65dcfcc6bb17

See more details on using hashes here.

File details

Details for the file marlim3-3.7.1-py3-none-any.whl.

File metadata

  • Download URL: marlim3-3.7.1-py3-none-any.whl
  • Upload date:
  • Size: 93.3 kB
  • Tags: Python 3
  • Uploaded using Trusted Publishing? No
  • Uploaded via: twine/6.1.0 CPython/3.13.12

File hashes

Hashes for marlim3-3.7.1-py3-none-any.whl
Algorithm Hash digest
SHA256 6d8c17520b777230b11dcfe3aa67db44335f0121cb735a9aeabf03b79c5fbea7
MD5 64f8e468c644d04356b05346cc2ee6a6
BLAKE2b-256 5731415629769193c059a3d38e361f0b4af274561d954b896110b661302274b9

See more details on using hashes here.

Supported by

AWS Cloud computing and Security Sponsor Datadog Monitoring Depot Continuous Integration Fastly CDN Google Download Analytics Pingdom Monitoring Sentry Error logging StatusPage Status page