# Gmsh - Copyright (C) 1997-2021 C. Geuzaine, J.-F. Remacle # # See the LICENSE.txt file for license information. Please report all # issues on https://gitlab.onelab.info/gmsh/gmsh/issues. # This file defines the Gmsh Julia API (v4.8.4). # # Do not edit it directly: it is automatically generated by `api/gen.py'. # # By design, the Gmsh Julia API is purely functional, and only uses elementary # Julia types. See `tutorial/julia' and `demos/api' for examples. """ module gmsh Top-level functions """ module gmsh const GMSH_API_VERSION = "4.8.4" const GMSH_API_VERSION_MAJOR = 4 const GMSH_API_VERSION_MINOR = 8 const GMSH_API_VERSION_PATCH = 4 const libdir = dirname(@__FILE__) const libname = Sys.iswindows() ? "gmsh-4.8.dll" : "libgmsh" import Libdl const lib = Libdl.find_library([libname], [libdir]) """ gmsh.initialize(argv = Vector{String}(), readConfigFiles = true) Initialize Gmsh API. This must be called before any call to the other functions in the API. If `argc` and `argv` (or just `argv` in Python or Julia) are provided, they will be handled in the same way as the command line arguments in the Gmsh app. If `readConfigFiles` is set, read system Gmsh configuration files (gmshrc and gmsh-options). Initializing the API sets the options "General.Terminal" to 1 and "General.AbortOnError" to 2. """ function initialize(argv = Vector{String}(), readConfigFiles = true) ierr = Ref{Cint}() ccall((:gmshInitialize, lib), Cvoid, (Cint, Ptr{Ptr{Cchar}}, Cint, Ptr{Cint}), length(argv), argv, readConfigFiles, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.finalize() Finalize the Gmsh API. This must be called when you are done using the Gmsh API. """ function finalize() ierr = Ref{Cint}() ccall((:gmshFinalize, lib), Cvoid, (Ptr{Cint},), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.open(fileName) Open a file. Equivalent to the `File->Open` menu in the Gmsh app. Handling of the file depends on its extension and/or its contents: opening a file with model data will create a new model. """ function open(fileName) ierr = Ref{Cint}() ccall((:gmshOpen, lib), Cvoid, (Ptr{Cchar}, Ptr{Cint}), fileName, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.merge(fileName) Merge a file. Equivalent to the `File->Merge` menu in the Gmsh app. Handling of the file depends on its extension and/or its contents. Merging a file with model data will add the data to the current model. """ function merge(fileName) ierr = Ref{Cint}() ccall((:gmshMerge, lib), Cvoid, (Ptr{Cchar}, Ptr{Cint}), fileName, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.write(fileName) Write a file. The export format is determined by the file extension. """ function write(fileName) ierr = Ref{Cint}() ccall((:gmshWrite, lib), Cvoid, (Ptr{Cchar}, Ptr{Cint}), fileName, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.clear() Clear all loaded models and post-processing data, and add a new empty model. """ function clear() ierr = Ref{Cint}() ccall((:gmshClear, lib), Cvoid, (Ptr{Cint},), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ module gmsh.option Option handling functions """ module option import ..gmsh """ gmsh.option.setNumber(name, value) Set a numerical option to `value`. `name` is of the form "category.option" or "category[num].option". Available categories and options are listed in the Gmsh reference manual. """ function setNumber(name, value) ierr = Ref{Cint}() ccall((:gmshOptionSetNumber, gmsh.lib), Cvoid, (Ptr{Cchar}, Cdouble, Ptr{Cint}), name, value, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_number = setNumber """ gmsh.option.getNumber(name) Get the `value` of a numerical option. `name` is of the form "category.option" or "category[num].option". Available categories and options are listed in the Gmsh reference manual. Return `value`. """ function getNumber(name) api_value_ = Ref{Cdouble}() ierr = Ref{Cint}() ccall((:gmshOptionGetNumber, gmsh.lib), Cvoid, (Ptr{Cchar}, Ptr{Cdouble}, Ptr{Cint}), name, api_value_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_value_[] end const get_number = getNumber """ gmsh.option.setString(name, value) Set a string option to `value`. `name` is of the form "category.option" or "category[num].option". Available categories and options are listed in the Gmsh reference manual. """ function setString(name, value) ierr = Ref{Cint}() ccall((:gmshOptionSetString, gmsh.lib), Cvoid, (Ptr{Cchar}, Ptr{Cchar}, Ptr{Cint}), name, value, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_string = setString """ gmsh.option.getString(name) Get the `value` of a string option. `name` is of the form "category.option" or "category[num].option". Available categories and options are listed in the Gmsh reference manual. Return `value`. """ function getString(name) api_value_ = Ref{Ptr{Cchar}}() ierr = Ref{Cint}() ccall((:gmshOptionGetString, gmsh.lib), Cvoid, (Ptr{Cchar}, Ptr{Ptr{Cchar}}, Ptr{Cint}), name, api_value_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) value = unsafe_string(api_value_[]) return value end const get_string = getString """ gmsh.option.setColor(name, r, g, b, a = 255) Set a color option to the RGBA value (`r`, `g`, `b`, `a`), where where `r`, `g`, `b` and `a` should be integers between 0 and 255. `name` is of the form "category.option" or "category[num].option". Available categories and options are listed in the Gmsh reference manual, with the "Color." middle string removed. """ function setColor(name, r, g, b, a = 255) ierr = Ref{Cint}() ccall((:gmshOptionSetColor, gmsh.lib), Cvoid, (Ptr{Cchar}, Cint, Cint, Cint, Cint, Ptr{Cint}), name, r, g, b, a, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_color = setColor """ gmsh.option.getColor(name) Get the `r`, `g`, `b`, `a` value of a color option. `name` is of the form "category.option" or "category[num].option". Available categories and options are listed in the Gmsh reference manual, with the "Color." middle string removed. Return `r`, `g`, `b`, `a`. """ function getColor(name) api_r_ = Ref{Cint}() api_g_ = Ref{Cint}() api_b_ = Ref{Cint}() api_a_ = Ref{Cint}() ierr = Ref{Cint}() ccall((:gmshOptionGetColor, gmsh.lib), Cvoid, (Ptr{Cchar}, Ptr{Cint}, Ptr{Cint}, Ptr{Cint}, Ptr{Cint}, Ptr{Cint}), name, api_r_, api_g_, api_b_, api_a_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_r_[], api_g_[], api_b_[], api_a_[] end const get_color = getColor end # end of module option """ module gmsh.model Model functions """ module model import ..gmsh """ gmsh.model.add(name) Add a new model, with name `name`, and set it as the current model. """ function add(name) ierr = Ref{Cint}() ccall((:gmshModelAdd, gmsh.lib), Cvoid, (Ptr{Cchar}, Ptr{Cint}), name, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.model.remove() Remove the current model. """ function remove() ierr = Ref{Cint}() ccall((:gmshModelRemove, gmsh.lib), Cvoid, (Ptr{Cint},), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.model.list() List the names of all models. Return `names`. """ function list() api_names_ = Ref{Ptr{Ptr{Cchar}}}() api_names_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelList, gmsh.lib), Cvoid, (Ptr{Ptr{Ptr{Cchar}}}, Ptr{Csize_t}, Ptr{Cint}), api_names_, api_names_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_names_ = unsafe_wrap(Array, api_names_[], api_names_n_[], own=true) names = [unsafe_string(tmp_api_names_[i]) for i in 1:length(tmp_api_names_) ] return names end """ gmsh.model.getCurrent() Get the name of the current model. Return `name`. """ function getCurrent() api_name_ = Ref{Ptr{Cchar}}() ierr = Ref{Cint}() ccall((:gmshModelGetCurrent, gmsh.lib), Cvoid, (Ptr{Ptr{Cchar}}, Ptr{Cint}), api_name_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) name = unsafe_string(api_name_[]) return name end const get_current = getCurrent """ gmsh.model.setCurrent(name) Set the current model to the model with name `name`. If several models have the same name, select the one that was added first. """ function setCurrent(name) ierr = Ref{Cint}() ccall((:gmshModelSetCurrent, gmsh.lib), Cvoid, (Ptr{Cchar}, Ptr{Cint}), name, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_current = setCurrent """ gmsh.model.getFileName() Get the file name (if any) associated with the current model. A file name is associated when a model is read from a file on disk. Return `fileName`. """ function getFileName() api_fileName_ = Ref{Ptr{Cchar}}() ierr = Ref{Cint}() ccall((:gmshModelGetFileName, gmsh.lib), Cvoid, (Ptr{Ptr{Cchar}}, Ptr{Cint}), api_fileName_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) fileName = unsafe_string(api_fileName_[]) return fileName end const get_file_name = getFileName """ gmsh.model.setFileName(fileName) Set the file name associated with the current model. """ function setFileName(fileName) ierr = Ref{Cint}() ccall((:gmshModelSetFileName, gmsh.lib), Cvoid, (Ptr{Cchar}, Ptr{Cint}), fileName, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_file_name = setFileName """ gmsh.model.getEntities(dim = -1) Get all the entities in the current model. If `dim` is >= 0, return only the entities of the specified dimension (e.g. points if `dim` == 0). The entities are returned as a vector of (dim, tag) integer pairs. Return `dimTags`. """ function getEntities(dim = -1) api_dimTags_ = Ref{Ptr{Cint}}() api_dimTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelGetEntities, gmsh.lib), Cvoid, (Ptr{Ptr{Cint}}, Ptr{Csize_t}, Cint, Ptr{Cint}), api_dimTags_, api_dimTags_n_, dim, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_dimTags_ = unsafe_wrap(Array, api_dimTags_[], api_dimTags_n_[], own=true) dimTags = [ (tmp_api_dimTags_[i], tmp_api_dimTags_[i+1]) for i in 1:2:length(tmp_api_dimTags_) ] return dimTags end const get_entities = getEntities """ gmsh.model.setEntityName(dim, tag, name) Set the name of the entity of dimension `dim` and tag `tag`. """ function setEntityName(dim, tag, name) ierr = Ref{Cint}() ccall((:gmshModelSetEntityName, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cchar}, Ptr{Cint}), dim, tag, name, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_entity_name = setEntityName """ gmsh.model.getEntityName(dim, tag) Get the name of the entity of dimension `dim` and tag `tag`. Return `name`. """ function getEntityName(dim, tag) api_name_ = Ref{Ptr{Cchar}}() ierr = Ref{Cint}() ccall((:gmshModelGetEntityName, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Ptr{Cchar}}, Ptr{Cint}), dim, tag, api_name_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) name = unsafe_string(api_name_[]) return name end const get_entity_name = getEntityName """ gmsh.model.getPhysicalGroups(dim = -1) Get all the physical groups in the current model. If `dim` is >= 0, return only the entities of the specified dimension (e.g. physical points if `dim` == 0). The entities are returned as a vector of (dim, tag) integer pairs. Return `dimTags`. """ function getPhysicalGroups(dim = -1) api_dimTags_ = Ref{Ptr{Cint}}() api_dimTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelGetPhysicalGroups, gmsh.lib), Cvoid, (Ptr{Ptr{Cint}}, Ptr{Csize_t}, Cint, Ptr{Cint}), api_dimTags_, api_dimTags_n_, dim, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_dimTags_ = unsafe_wrap(Array, api_dimTags_[], api_dimTags_n_[], own=true) dimTags = [ (tmp_api_dimTags_[i], tmp_api_dimTags_[i+1]) for i in 1:2:length(tmp_api_dimTags_) ] return dimTags end const get_physical_groups = getPhysicalGroups """ gmsh.model.getEntitiesForPhysicalGroup(dim, tag) Get the tags of the model entities making up the physical group of dimension `dim` and tag `tag`. Return `tags`. """ function getEntitiesForPhysicalGroup(dim, tag) api_tags_ = Ref{Ptr{Cint}}() api_tags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelGetEntitiesForPhysicalGroup, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Cint}), dim, tag, api_tags_, api_tags_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tags = unsafe_wrap(Array, api_tags_[], api_tags_n_[], own=true) return tags end const get_entities_for_physical_group = getEntitiesForPhysicalGroup """ gmsh.model.getPhysicalGroupsForEntity(dim, tag) Get the tags of the physical groups (if any) to which the model entity of dimension `dim` and tag `tag` belongs. Return `physicalTags`. """ function getPhysicalGroupsForEntity(dim, tag) api_physicalTags_ = Ref{Ptr{Cint}}() api_physicalTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelGetPhysicalGroupsForEntity, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Cint}), dim, tag, api_physicalTags_, api_physicalTags_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) physicalTags = unsafe_wrap(Array, api_physicalTags_[], api_physicalTags_n_[], own=true) return physicalTags end const get_physical_groups_for_entity = getPhysicalGroupsForEntity """ gmsh.model.addPhysicalGroup(dim, tags, tag = -1) Add a physical group of dimension `dim`, grouping the model entities with tags `tags`. Return the tag of the physical group, equal to `tag` if `tag` is positive, or a new tag if `tag` < 0. Return an integer value. """ function addPhysicalGroup(dim, tags, tag = -1) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelAddPhysicalGroup, gmsh.lib), Cint, (Cint, Ptr{Cint}, Csize_t, Cint, Ptr{Cint}), dim, convert(Vector{Cint}, tags), length(tags), tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_physical_group = addPhysicalGroup """ gmsh.model.removePhysicalGroups(dimTags = Tuple{Cint,Cint}[]) Remove the physical groups `dimTags` from the current model. If `dimTags` is empty, remove all groups. """ function removePhysicalGroups(dimTags = Tuple{Cint,Cint}[]) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelRemovePhysicalGroups, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Ptr{Cint}), api_dimTags_, api_dimTags_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const remove_physical_groups = removePhysicalGroups """ gmsh.model.setPhysicalName(dim, tag, name) Set the name of the physical group of dimension `dim` and tag `tag`. """ function setPhysicalName(dim, tag, name) ierr = Ref{Cint}() ccall((:gmshModelSetPhysicalName, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cchar}, Ptr{Cint}), dim, tag, name, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_physical_name = setPhysicalName """ gmsh.model.removePhysicalName(name) Remove the physical name `name` from the current model. """ function removePhysicalName(name) ierr = Ref{Cint}() ccall((:gmshModelRemovePhysicalName, gmsh.lib), Cvoid, (Ptr{Cchar}, Ptr{Cint}), name, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const remove_physical_name = removePhysicalName """ gmsh.model.getPhysicalName(dim, tag) Get the name of the physical group of dimension `dim` and tag `tag`. Return `name`. """ function getPhysicalName(dim, tag) api_name_ = Ref{Ptr{Cchar}}() ierr = Ref{Cint}() ccall((:gmshModelGetPhysicalName, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Ptr{Cchar}}, Ptr{Cint}), dim, tag, api_name_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) name = unsafe_string(api_name_[]) return name end const get_physical_name = getPhysicalName """ gmsh.model.getBoundary(dimTags, combined = true, oriented = true, recursive = false) Get the boundary of the model entities `dimTags`. Return in `outDimTags` the boundary of the individual entities (if `combined` is false) or the boundary of the combined geometrical shape formed by all input entities (if `combined` is true). Return tags multiplied by the sign of the boundary entity if `oriented` is true. Apply the boundary operator recursively down to dimension 0 (i.e. to points) if `recursive` is true. Return `outDimTags`. """ function getBoundary(dimTags, combined = true, oriented = true, recursive = false) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) api_outDimTags_ = Ref{Ptr{Cint}}() api_outDimTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelGetBoundary, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Cint, Cint, Cint, Ptr{Cint}), api_dimTags_, api_dimTags_n_, api_outDimTags_, api_outDimTags_n_, combined, oriented, recursive, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_outDimTags_ = unsafe_wrap(Array, api_outDimTags_[], api_outDimTags_n_[], own=true) outDimTags = [ (tmp_api_outDimTags_[i], tmp_api_outDimTags_[i+1]) for i in 1:2:length(tmp_api_outDimTags_) ] return outDimTags end const get_boundary = getBoundary """ gmsh.model.getAdjacencies(dim, tag) Get the upward and downward adjacencies of the model entity of dimension `dim` and tag `tag`. The `upward` vector returns the adjacent entities of dimension `dim` + 1; the `downward` vector returns the adjacent entities of dimension `dim` - 1. Return `upward`, `downward`. """ function getAdjacencies(dim, tag) api_upward_ = Ref{Ptr{Cint}}() api_upward_n_ = Ref{Csize_t}() api_downward_ = Ref{Ptr{Cint}}() api_downward_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelGetAdjacencies, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Cint}), dim, tag, api_upward_, api_upward_n_, api_downward_, api_downward_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) upward = unsafe_wrap(Array, api_upward_[], api_upward_n_[], own=true) downward = unsafe_wrap(Array, api_downward_[], api_downward_n_[], own=true) return upward, downward end const get_adjacencies = getAdjacencies """ gmsh.model.getEntitiesInBoundingBox(xmin, ymin, zmin, xmax, ymax, zmax, dim = -1) Get the model entities in the bounding box defined by the two points (`xmin`, `ymin`, `zmin`) and (`xmax`, `ymax`, `zmax`). If `dim` is >= 0, return only the entities of the specified dimension (e.g. points if `dim` == 0). Return `tags`. """ function getEntitiesInBoundingBox(xmin, ymin, zmin, xmax, ymax, zmax, dim = -1) api_tags_ = Ref{Ptr{Cint}}() api_tags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelGetEntitiesInBoundingBox, gmsh.lib), Cvoid, (Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Cint, Ptr{Cint}), xmin, ymin, zmin, xmax, ymax, zmax, api_tags_, api_tags_n_, dim, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_tags_ = unsafe_wrap(Array, api_tags_[], api_tags_n_[], own=true) tags = [ (tmp_api_tags_[i], tmp_api_tags_[i+1]) for i in 1:2:length(tmp_api_tags_) ] return tags end const get_entities_in_bounding_box = getEntitiesInBoundingBox """ gmsh.model.getBoundingBox(dim, tag) Get the bounding box (`xmin`, `ymin`, `zmin`), (`xmax`, `ymax`, `zmax`) of the model entity of dimension `dim` and tag `tag`. If `dim` and `tag` are negative, get the bounding box of the whole model. Return `xmin`, `ymin`, `zmin`, `xmax`, `ymax`, `zmax`. """ function getBoundingBox(dim, tag) api_xmin_ = Ref{Cdouble}() api_ymin_ = Ref{Cdouble}() api_zmin_ = Ref{Cdouble}() api_xmax_ = Ref{Cdouble}() api_ymax_ = Ref{Cdouble}() api_zmax_ = Ref{Cdouble}() ierr = Ref{Cint}() ccall((:gmshModelGetBoundingBox, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cdouble}, Ptr{Cdouble}, Ptr{Cdouble}, Ptr{Cdouble}, Ptr{Cdouble}, Ptr{Cdouble}, Ptr{Cint}), dim, tag, api_xmin_, api_ymin_, api_zmin_, api_xmax_, api_ymax_, api_zmax_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_xmin_[], api_ymin_[], api_zmin_[], api_xmax_[], api_ymax_[], api_zmax_[] end const get_bounding_box = getBoundingBox """ gmsh.model.getDimension() Get the geometrical dimension of the current model. Return an integer value. """ function getDimension() ierr = Ref{Cint}() api_result_ = ccall((:gmshModelGetDimension, gmsh.lib), Cint, (Ptr{Cint},), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const get_dimension = getDimension """ gmsh.model.addDiscreteEntity(dim, tag = -1, boundary = Cint[]) Add a discrete model entity (defined by a mesh) of dimension `dim` in the current model. Return the tag of the new discrete entity, equal to `tag` if `tag` is positive, or a new tag if `tag` < 0. `boundary` specifies the tags of the entities on the boundary of the discrete entity, if any. Specifying `boundary` allows Gmsh to construct the topology of the overall model. Return an integer value. """ function addDiscreteEntity(dim, tag = -1, boundary = Cint[]) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelAddDiscreteEntity, gmsh.lib), Cint, (Cint, Cint, Ptr{Cint}, Csize_t, Ptr{Cint}), dim, tag, convert(Vector{Cint}, boundary), length(boundary), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_discrete_entity = addDiscreteEntity """ gmsh.model.removeEntities(dimTags, recursive = false) Remove the entities `dimTags` of the current model, provided that they are not on the boundary of (or embedded in) higher-dimensional entities. If `recursive` is true, remove all the entities on their boundaries, down to dimension 0. """ function removeEntities(dimTags, recursive = false) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelRemoveEntities, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Cint, Ptr{Cint}), api_dimTags_, api_dimTags_n_, recursive, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const remove_entities = removeEntities """ gmsh.model.removeEntityName(name) Remove the entity name `name` from the current model. """ function removeEntityName(name) ierr = Ref{Cint}() ccall((:gmshModelRemoveEntityName, gmsh.lib), Cvoid, (Ptr{Cchar}, Ptr{Cint}), name, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const remove_entity_name = removeEntityName """ gmsh.model.getType(dim, tag) Get the type of the entity of dimension `dim` and tag `tag`. Return `entityType`. """ function getType(dim, tag) api_entityType_ = Ref{Ptr{Cchar}}() ierr = Ref{Cint}() ccall((:gmshModelGetType, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Ptr{Cchar}}, Ptr{Cint}), dim, tag, api_entityType_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) entityType = unsafe_string(api_entityType_[]) return entityType end const get_type = getType """ gmsh.model.getParent(dim, tag) In a partitioned model, get the parent of the entity of dimension `dim` and tag `tag`, i.e. from which the entity is a part of, if any. `parentDim` and `parentTag` are set to -1 if the entity has no parent. Return `parentDim`, `parentTag`. """ function getParent(dim, tag) api_parentDim_ = Ref{Cint}() api_parentTag_ = Ref{Cint}() ierr = Ref{Cint}() ccall((:gmshModelGetParent, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cint}, Ptr{Cint}, Ptr{Cint}), dim, tag, api_parentDim_, api_parentTag_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_parentDim_[], api_parentTag_[] end const get_parent = getParent """ gmsh.model.getPartitions(dim, tag) In a partitioned model, return the tags of the partition(s) to which the entity belongs. Return `partitions`. """ function getPartitions(dim, tag) api_partitions_ = Ref{Ptr{Cint}}() api_partitions_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelGetPartitions, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Cint}), dim, tag, api_partitions_, api_partitions_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) partitions = unsafe_wrap(Array, api_partitions_[], api_partitions_n_[], own=true) return partitions end const get_partitions = getPartitions """ gmsh.model.getValue(dim, tag, parametricCoord) Evaluate the parametrization of the entity of dimension `dim` and tag `tag` at the parametric coordinates `parametricCoord`. Only valid for `dim` equal to 0 (with empty `parametricCoord`), 1 (with `parametricCoord` containing parametric coordinates on the curve) or 2 (with `parametricCoord` containing pairs of u, v parametric coordinates on the surface, concatenated: [p1u, p1v, p2u, ...]). Return triplets of x, y, z coordinates in `coord`, concatenated: [p1x, p1y, p1z, p2x, ...]. Return `coord`. """ function getValue(dim, tag, parametricCoord) api_coord_ = Ref{Ptr{Cdouble}}() api_coord_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelGetValue, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cdouble}, Csize_t, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Cint}), dim, tag, convert(Vector{Cdouble}, parametricCoord), length(parametricCoord), api_coord_, api_coord_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) coord = unsafe_wrap(Array, api_coord_[], api_coord_n_[], own=true) return coord end const get_value = getValue """ gmsh.model.getDerivative(dim, tag, parametricCoord) Evaluate the derivative of the parametrization of the entity of dimension `dim` and tag `tag` at the parametric coordinates `parametricCoord`. Only valid for `dim` equal to 1 (with `parametricCoord` containing parametric coordinates on the curve) or 2 (with `parametricCoord` containing pairs of u, v parametric coordinates on the surface, concatenated: [p1u, p1v, p2u, ...]). For `dim` equal to 1 return the x, y, z components of the derivative with respect to u [d1ux, d1uy, d1uz, d2ux, ...]; for `dim` equal to 2 return the x, y, z components of the derivative with respect to u and v: [d1ux, d1uy, d1uz, d1vx, d1vy, d1vz, d2ux, ...]. Return `derivatives`. """ function getDerivative(dim, tag, parametricCoord) api_derivatives_ = Ref{Ptr{Cdouble}}() api_derivatives_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelGetDerivative, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cdouble}, Csize_t, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Cint}), dim, tag, convert(Vector{Cdouble}, parametricCoord), length(parametricCoord), api_derivatives_, api_derivatives_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) derivatives = unsafe_wrap(Array, api_derivatives_[], api_derivatives_n_[], own=true) return derivatives end const get_derivative = getDerivative """ gmsh.model.getSecondDerivative(dim, tag, parametricCoord) Evaluate the second derivative of the parametrization of the entity of dimension `dim` and tag `tag` at the parametric coordinates `parametricCoord`. Only valid for `dim` equal to 1 (with `parametricCoord` containing parametric coordinates on the curve) or 2 (with `parametricCoord` containing pairs of u, v parametric coordinates on the surface, concatenated: [p1u, p1v, p2u, ...]). For `dim` equal to 1 return the x, y, z components of the second derivative with respect to u [d1uux, d1uuy, d1uuz, d2uux, ...]; for `dim` equal to 2 return the x, y, z components of the second derivative with respect to u and v, and the mixed derivative with respect to u and v: [d1uux, d1uuy, d1uuz, d1vvx, d1vvy, d1vvz, d1uvx, d1uvy, d1uvz, d2uux, ...]. Return `derivatives`. """ function getSecondDerivative(dim, tag, parametricCoord) api_derivatives_ = Ref{Ptr{Cdouble}}() api_derivatives_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelGetSecondDerivative, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cdouble}, Csize_t, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Cint}), dim, tag, convert(Vector{Cdouble}, parametricCoord), length(parametricCoord), api_derivatives_, api_derivatives_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) derivatives = unsafe_wrap(Array, api_derivatives_[], api_derivatives_n_[], own=true) return derivatives end const get_second_derivative = getSecondDerivative """ gmsh.model.getCurvature(dim, tag, parametricCoord) Evaluate the (maximum) curvature of the entity of dimension `dim` and tag `tag` at the parametric coordinates `parametricCoord`. Only valid for `dim` equal to 1 (with `parametricCoord` containing parametric coordinates on the curve) or 2 (with `parametricCoord` containing pairs of u, v parametric coordinates on the surface, concatenated: [p1u, p1v, p2u, ...]). Return `curvatures`. """ function getCurvature(dim, tag, parametricCoord) api_curvatures_ = Ref{Ptr{Cdouble}}() api_curvatures_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelGetCurvature, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cdouble}, Csize_t, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Cint}), dim, tag, convert(Vector{Cdouble}, parametricCoord), length(parametricCoord), api_curvatures_, api_curvatures_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) curvatures = unsafe_wrap(Array, api_curvatures_[], api_curvatures_n_[], own=true) return curvatures end const get_curvature = getCurvature """ gmsh.model.getPrincipalCurvatures(tag, parametricCoord) Evaluate the principal curvatures of the surface with tag `tag` at the parametric coordinates `parametricCoord`, as well as their respective directions. `parametricCoord` are given by pair of u and v coordinates, concatenated: [p1u, p1v, p2u, ...]. Return `curvatureMax`, `curvatureMin`, `directionMax`, `directionMin`. """ function getPrincipalCurvatures(tag, parametricCoord) api_curvatureMax_ = Ref{Ptr{Cdouble}}() api_curvatureMax_n_ = Ref{Csize_t}() api_curvatureMin_ = Ref{Ptr{Cdouble}}() api_curvatureMin_n_ = Ref{Csize_t}() api_directionMax_ = Ref{Ptr{Cdouble}}() api_directionMax_n_ = Ref{Csize_t}() api_directionMin_ = Ref{Ptr{Cdouble}}() api_directionMin_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelGetPrincipalCurvatures, gmsh.lib), Cvoid, (Cint, Ptr{Cdouble}, Csize_t, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Cint}), tag, convert(Vector{Cdouble}, parametricCoord), length(parametricCoord), api_curvatureMax_, api_curvatureMax_n_, api_curvatureMin_, api_curvatureMin_n_, api_directionMax_, api_directionMax_n_, api_directionMin_, api_directionMin_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) curvatureMax = unsafe_wrap(Array, api_curvatureMax_[], api_curvatureMax_n_[], own=true) curvatureMin = unsafe_wrap(Array, api_curvatureMin_[], api_curvatureMin_n_[], own=true) directionMax = unsafe_wrap(Array, api_directionMax_[], api_directionMax_n_[], own=true) directionMin = unsafe_wrap(Array, api_directionMin_[], api_directionMin_n_[], own=true) return curvatureMax, curvatureMin, directionMax, directionMin end const get_principal_curvatures = getPrincipalCurvatures """ gmsh.model.getNormal(tag, parametricCoord) Get the normal to the surface with tag `tag` at the parametric coordinates `parametricCoord`. `parametricCoord` are given by pairs of u and v coordinates, concatenated: [p1u, p1v, p2u, ...]. `normals` are returned as triplets of x, y, z components, concatenated: [n1x, n1y, n1z, n2x, ...]. Return `normals`. """ function getNormal(tag, parametricCoord) api_normals_ = Ref{Ptr{Cdouble}}() api_normals_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelGetNormal, gmsh.lib), Cvoid, (Cint, Ptr{Cdouble}, Csize_t, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Cint}), tag, convert(Vector{Cdouble}, parametricCoord), length(parametricCoord), api_normals_, api_normals_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) normals = unsafe_wrap(Array, api_normals_[], api_normals_n_[], own=true) return normals end const get_normal = getNormal """ gmsh.model.getParametrization(dim, tag, coord) Get the parametric coordinates `parametricCoord` for the points `coord` on the entity of dimension `dim` and tag `tag`. `coord` are given as triplets of x, y, z coordinates, concatenated: [p1x, p1y, p1z, p2x, ...]. `parametricCoord` returns the parametric coordinates t on the curve (if `dim` = 1) or pairs of u and v coordinates concatenated on the surface (if `dim` = 2), i.e. [p1t, p2t, ...] or [p1u, p1v, p2u, ...]. Return `parametricCoord`. """ function getParametrization(dim, tag, coord) api_parametricCoord_ = Ref{Ptr{Cdouble}}() api_parametricCoord_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelGetParametrization, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cdouble}, Csize_t, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Cint}), dim, tag, convert(Vector{Cdouble}, coord), length(coord), api_parametricCoord_, api_parametricCoord_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) parametricCoord = unsafe_wrap(Array, api_parametricCoord_[], api_parametricCoord_n_[], own=true) return parametricCoord end const get_parametrization = getParametrization """ gmsh.model.getParametrizationBounds(dim, tag) Get the `min` and `max` bounds of the parametric coordinates for the entity of dimension `dim` and tag `tag`. Return `min`, `max`. """ function getParametrizationBounds(dim, tag) api_min_ = Ref{Ptr{Cdouble}}() api_min_n_ = Ref{Csize_t}() api_max_ = Ref{Ptr{Cdouble}}() api_max_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelGetParametrizationBounds, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Cint}), dim, tag, api_min_, api_min_n_, api_max_, api_max_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) min = unsafe_wrap(Array, api_min_[], api_min_n_[], own=true) max = unsafe_wrap(Array, api_max_[], api_max_n_[], own=true) return min, max end const get_parametrization_bounds = getParametrizationBounds """ gmsh.model.isInside(dim, tag, coord, parametric = true) Check if the coordinates (or the parametric coordinates if `parametric` is set) provided in `coord` correspond to points inside the entity of dimension `dim` and tag `tag`, and return the number of points inside. This feature is only available for a subset of curves and surfaces, depending on the underyling geometrical representation. Return an integer value. """ function isInside(dim, tag, coord, parametric = true) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelIsInside, gmsh.lib), Cint, (Cint, Cint, Ptr{Cdouble}, Csize_t, Cint, Ptr{Cint}), dim, tag, convert(Vector{Cdouble}, coord), length(coord), parametric, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const is_inside = isInside """ gmsh.model.getClosestPoint(dim, tag, coord) Get the points `closestCoord` on the entity of dimension `dim` and tag `tag` to the points `coord`, by orthogonal projection. `coord` and `closestCoord` are given as triplets of x, y, z coordinates, concatenated: [p1x, p1y, p1z, p2x, ...]. `parametricCoord` returns the parametric coordinates t on the curve (if `dim` = 1) or pairs of u and v coordinates concatenated on the surface (if `dim` = 2), i.e. [p1t, p2t, ...] or [p1u, p1v, p2u, ...]. Return `closestCoord`, `parametricCoord`. """ function getClosestPoint(dim, tag, coord) api_closestCoord_ = Ref{Ptr{Cdouble}}() api_closestCoord_n_ = Ref{Csize_t}() api_parametricCoord_ = Ref{Ptr{Cdouble}}() api_parametricCoord_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelGetClosestPoint, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cdouble}, Csize_t, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Cint}), dim, tag, convert(Vector{Cdouble}, coord), length(coord), api_closestCoord_, api_closestCoord_n_, api_parametricCoord_, api_parametricCoord_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) closestCoord = unsafe_wrap(Array, api_closestCoord_[], api_closestCoord_n_[], own=true) parametricCoord = unsafe_wrap(Array, api_parametricCoord_[], api_parametricCoord_n_[], own=true) return closestCoord, parametricCoord end const get_closest_point = getClosestPoint """ gmsh.model.reparametrizeOnSurface(dim, tag, parametricCoord, surfaceTag, which = 0) Reparametrize the boundary entity (point or curve, i.e. with `dim` == 0 or `dim` == 1) of tag `tag` on the surface `surfaceTag`. If `dim` == 1, reparametrize all the points corresponding to the parametric coordinates `parametricCoord`. Multiple matches in case of periodic surfaces can be selected with `which`. This feature is only available for a subset of entities, depending on the underyling geometrical representation. Return `surfaceParametricCoord`. """ function reparametrizeOnSurface(dim, tag, parametricCoord, surfaceTag, which = 0) api_surfaceParametricCoord_ = Ref{Ptr{Cdouble}}() api_surfaceParametricCoord_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelReparametrizeOnSurface, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cdouble}, Csize_t, Cint, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Cint, Ptr{Cint}), dim, tag, convert(Vector{Cdouble}, parametricCoord), length(parametricCoord), surfaceTag, api_surfaceParametricCoord_, api_surfaceParametricCoord_n_, which, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) surfaceParametricCoord = unsafe_wrap(Array, api_surfaceParametricCoord_[], api_surfaceParametricCoord_n_[], own=true) return surfaceParametricCoord end const reparametrize_on_surface = reparametrizeOnSurface """ gmsh.model.setVisibility(dimTags, value, recursive = false) Set the visibility of the model entities `dimTags` to `value`. Apply the visibility setting recursively if `recursive` is true. """ function setVisibility(dimTags, value, recursive = false) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelSetVisibility, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Cint, Cint, Ptr{Cint}), api_dimTags_, api_dimTags_n_, value, recursive, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_visibility = setVisibility """ gmsh.model.getVisibility(dim, tag) Get the visibility of the model entity of dimension `dim` and tag `tag`. Return `value`. """ function getVisibility(dim, tag) api_value_ = Ref{Cint}() ierr = Ref{Cint}() ccall((:gmshModelGetVisibility, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cint}, Ptr{Cint}), dim, tag, api_value_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_value_[] end const get_visibility = getVisibility """ gmsh.model.setVisibilityPerWindow(value, windowIndex = 0) Set the global visibility of the model per window to `value`, where `windowIndex` identifies the window in the window list. """ function setVisibilityPerWindow(value, windowIndex = 0) ierr = Ref{Cint}() ccall((:gmshModelSetVisibilityPerWindow, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cint}), value, windowIndex, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_visibility_per_window = setVisibilityPerWindow """ gmsh.model.setColor(dimTags, r, g, b, a = 255, recursive = false) Set the color of the model entities `dimTags` to the RGBA value (`r`, `g`, `b`, `a`), where `r`, `g`, `b` and `a` should be integers between 0 and 255. Apply the color setting recursively if `recursive` is true. """ function setColor(dimTags, r, g, b, a = 255, recursive = false) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelSetColor, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Cint, Cint, Cint, Cint, Cint, Ptr{Cint}), api_dimTags_, api_dimTags_n_, r, g, b, a, recursive, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_color = setColor """ gmsh.model.getColor(dim, tag) Get the color of the model entity of dimension `dim` and tag `tag`. Return `r`, `g`, `b`, `a`. """ function getColor(dim, tag) api_r_ = Ref{Cint}() api_g_ = Ref{Cint}() api_b_ = Ref{Cint}() api_a_ = Ref{Cint}() ierr = Ref{Cint}() ccall((:gmshModelGetColor, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cint}, Ptr{Cint}, Ptr{Cint}, Ptr{Cint}, Ptr{Cint}), dim, tag, api_r_, api_g_, api_b_, api_a_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_r_[], api_g_[], api_b_[], api_a_[] end const get_color = getColor """ gmsh.model.setCoordinates(tag, x, y, z) Set the `x`, `y`, `z` coordinates of a geometrical point. """ function setCoordinates(tag, x, y, z) ierr = Ref{Cint}() ccall((:gmshModelSetCoordinates, gmsh.lib), Cvoid, (Cint, Cdouble, Cdouble, Cdouble, Ptr{Cint}), tag, x, y, z, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_coordinates = setCoordinates """ module gmsh.model.mesh Mesh functions """ module mesh import ...gmsh """ gmsh.model.mesh.generate(dim = 3) Generate a mesh of the current model, up to dimension `dim` (0, 1, 2 or 3). """ function generate(dim = 3) ierr = Ref{Cint}() ccall((:gmshModelMeshGenerate, gmsh.lib), Cvoid, (Cint, Ptr{Cint}), dim, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.model.mesh.partition(numPart, elementTags = Csize_t[], partitions = Cint[]) Partition the mesh of the current model into `numPart` partitions. Optionally, `elementTags` and `partitions` can be provided to specify the partition of each element explicitly. """ function partition(numPart, elementTags = Csize_t[], partitions = Cint[]) ierr = Ref{Cint}() ccall((:gmshModelMeshPartition, gmsh.lib), Cvoid, (Cint, Ptr{Csize_t}, Csize_t, Ptr{Cint}, Csize_t, Ptr{Cint}), numPart, convert(Vector{Csize_t}, elementTags), length(elementTags), convert(Vector{Cint}, partitions), length(partitions), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.model.mesh.unpartition() Unpartition the mesh of the current model. """ function unpartition() ierr = Ref{Cint}() ccall((:gmshModelMeshUnpartition, gmsh.lib), Cvoid, (Ptr{Cint},), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.model.mesh.optimize(method, force = false, niter = 1, dimTags = Tuple{Cint,Cint}[]) Optimize the mesh of the current model using `method` (empty for default tetrahedral mesh optimizer, "Netgen" for Netgen optimizer, "HighOrder" for direct high-order mesh optimizer, "HighOrderElastic" for high-order elastic smoother, "HighOrderFastCurving" for fast curving algorithm, "Laplace2D" for Laplace smoothing, "Relocate2D" and "Relocate3D" for node relocation). If `force` is set apply the optimization also to discrete entities. If `dimTags` is given, only apply the optimizer to the given entities. """ function optimize(method, force = false, niter = 1, dimTags = Tuple{Cint,Cint}[]) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelMeshOptimize, gmsh.lib), Cvoid, (Ptr{Cchar}, Cint, Cint, Ptr{Cint}, Csize_t, Ptr{Cint}), method, force, niter, api_dimTags_, api_dimTags_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.model.mesh.recombine() Recombine the mesh of the current model. """ function recombine() ierr = Ref{Cint}() ccall((:gmshModelMeshRecombine, gmsh.lib), Cvoid, (Ptr{Cint},), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.model.mesh.refine() Refine the mesh of the current model by uniformly splitting the elements. """ function refine() ierr = Ref{Cint}() ccall((:gmshModelMeshRefine, gmsh.lib), Cvoid, (Ptr{Cint},), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.model.mesh.setOrder(order) Set the order of the elements in the mesh of the current model to `order`. """ function setOrder(order) ierr = Ref{Cint}() ccall((:gmshModelMeshSetOrder, gmsh.lib), Cvoid, (Cint, Ptr{Cint}), order, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_order = setOrder """ gmsh.model.mesh.getLastEntityError() Get the last entities (if any) where a meshing error occurred. Currently only populated by the new 3D meshing algorithms. Return `dimTags`. """ function getLastEntityError() api_dimTags_ = Ref{Ptr{Cint}}() api_dimTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetLastEntityError, gmsh.lib), Cvoid, (Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Cint}), api_dimTags_, api_dimTags_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_dimTags_ = unsafe_wrap(Array, api_dimTags_[], api_dimTags_n_[], own=true) dimTags = [ (tmp_api_dimTags_[i], tmp_api_dimTags_[i+1]) for i in 1:2:length(tmp_api_dimTags_) ] return dimTags end const get_last_entity_error = getLastEntityError """ gmsh.model.mesh.getLastNodeError() Get the last nodes (if any) where a meshing error occurred. Currently only populated by the new 3D meshing algorithms. Return `nodeTags`. """ function getLastNodeError() api_nodeTags_ = Ref{Ptr{Csize_t}}() api_nodeTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetLastNodeError, gmsh.lib), Cvoid, (Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Ptr{Cint}), api_nodeTags_, api_nodeTags_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) nodeTags = unsafe_wrap(Array, api_nodeTags_[], api_nodeTags_n_[], own=true) return nodeTags end const get_last_node_error = getLastNodeError """ gmsh.model.mesh.clear(dimTags = Tuple{Cint,Cint}[]) Clear the mesh, i.e. delete all the nodes and elements, for the entities `dimTags`. If `dimTags` is empty, clear the whole mesh. Note that the mesh of an entity can only be cleared if this entity is not on the boundary of another entity with a non-empty mesh. """ function clear(dimTags = Tuple{Cint,Cint}[]) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelMeshClear, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Ptr{Cint}), api_dimTags_, api_dimTags_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.model.mesh.reverse(dimTags = Tuple{Cint,Cint}[]) Reverse the orientation of the elements in the entities `dimTags`. If `dimTags` is empty, reverse the orientation of the elements in the whole mesh. """ function reverse(dimTags = Tuple{Cint,Cint}[]) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelMeshReverse, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Ptr{Cint}), api_dimTags_, api_dimTags_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.model.mesh.getNodes(dim = -1, tag = -1, includeBoundary = false, returnParametricCoord = true) Get the nodes classified on the entity of dimension `dim` and tag `tag`. If `tag` < 0, get the nodes for all entities of dimension `dim`. If `dim` and `tag` are negative, get all the nodes in the mesh. `nodeTags` contains the node tags (their unique, strictly positive identification numbers). `coord` is a vector of length 3 times the length of `nodeTags` that contains the x, y, z coordinates of the nodes, concatenated: [n1x, n1y, n1z, n2x, ...]. If `dim` >= 0 and `returnParamtricCoord` is set, `parametricCoord` contains the parametric coordinates ([u1, u2, ...] or [u1, v1, u2, ...]) of the nodes, if available. The length of `parametricCoord` can be 0 or `dim` times the length of `nodeTags`. If `includeBoundary` is set, also return the nodes classified on the boundary of the entity (which will be reparametrized on the entity if `dim` >= 0 in order to compute their parametric coordinates). Return `nodeTags`, `coord`, `parametricCoord`. """ function getNodes(dim = -1, tag = -1, includeBoundary = false, returnParametricCoord = true) api_nodeTags_ = Ref{Ptr{Csize_t}}() api_nodeTags_n_ = Ref{Csize_t}() api_coord_ = Ref{Ptr{Cdouble}}() api_coord_n_ = Ref{Csize_t}() api_parametricCoord_ = Ref{Ptr{Cdouble}}() api_parametricCoord_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetNodes, gmsh.lib), Cvoid, (Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Cint, Cint, Cint, Cint, Ptr{Cint}), api_nodeTags_, api_nodeTags_n_, api_coord_, api_coord_n_, api_parametricCoord_, api_parametricCoord_n_, dim, tag, includeBoundary, returnParametricCoord, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) nodeTags = unsafe_wrap(Array, api_nodeTags_[], api_nodeTags_n_[], own=true) coord = unsafe_wrap(Array, api_coord_[], api_coord_n_[], own=true) parametricCoord = unsafe_wrap(Array, api_parametricCoord_[], api_parametricCoord_n_[], own=true) return nodeTags, coord, parametricCoord end const get_nodes = getNodes """ gmsh.model.mesh.getNodesByElementType(elementType, tag = -1, returnParametricCoord = true) Get the nodes classified on the entity of tag `tag`, for all the elements of type `elementType`. The other arguments are treated as in `getNodes`. Return `nodeTags`, `coord`, `parametricCoord`. """ function getNodesByElementType(elementType, tag = -1, returnParametricCoord = true) api_nodeTags_ = Ref{Ptr{Csize_t}}() api_nodeTags_n_ = Ref{Csize_t}() api_coord_ = Ref{Ptr{Cdouble}}() api_coord_n_ = Ref{Csize_t}() api_parametricCoord_ = Ref{Ptr{Cdouble}}() api_parametricCoord_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetNodesByElementType, gmsh.lib), Cvoid, (Cint, Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Cint, Cint, Ptr{Cint}), elementType, api_nodeTags_, api_nodeTags_n_, api_coord_, api_coord_n_, api_parametricCoord_, api_parametricCoord_n_, tag, returnParametricCoord, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) nodeTags = unsafe_wrap(Array, api_nodeTags_[], api_nodeTags_n_[], own=true) coord = unsafe_wrap(Array, api_coord_[], api_coord_n_[], own=true) parametricCoord = unsafe_wrap(Array, api_parametricCoord_[], api_parametricCoord_n_[], own=true) return nodeTags, coord, parametricCoord end const get_nodes_by_element_type = getNodesByElementType """ gmsh.model.mesh.getNode(nodeTag) Get the coordinates and the parametric coordinates (if any) of the node with tag `tag`. This function relies on an internal cache (a vector in case of dense node numbering, a map otherwise); for large meshes accessing nodes in bulk is often preferable. Return `coord`, `parametricCoord`. """ function getNode(nodeTag) api_coord_ = Ref{Ptr{Cdouble}}() api_coord_n_ = Ref{Csize_t}() api_parametricCoord_ = Ref{Ptr{Cdouble}}() api_parametricCoord_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetNode, gmsh.lib), Cvoid, (Csize_t, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Cint}), nodeTag, api_coord_, api_coord_n_, api_parametricCoord_, api_parametricCoord_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) coord = unsafe_wrap(Array, api_coord_[], api_coord_n_[], own=true) parametricCoord = unsafe_wrap(Array, api_parametricCoord_[], api_parametricCoord_n_[], own=true) return coord, parametricCoord end const get_node = getNode """ gmsh.model.mesh.setNode(nodeTag, coord, parametricCoord) Set the coordinates and the parametric coordinates (if any) of the node with tag `tag`. This function relies on an internal cache (a vector in case of dense node numbering, a map otherwise); for large meshes accessing nodes in bulk is often preferable. """ function setNode(nodeTag, coord, parametricCoord) ierr = Ref{Cint}() ccall((:gmshModelMeshSetNode, gmsh.lib), Cvoid, (Csize_t, Ptr{Cdouble}, Csize_t, Ptr{Cdouble}, Csize_t, Ptr{Cint}), nodeTag, convert(Vector{Cdouble}, coord), length(coord), convert(Vector{Cdouble}, parametricCoord), length(parametricCoord), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_node = setNode """ gmsh.model.mesh.rebuildNodeCache(onlyIfNecessary = true) Rebuild the node cache. """ function rebuildNodeCache(onlyIfNecessary = true) ierr = Ref{Cint}() ccall((:gmshModelMeshRebuildNodeCache, gmsh.lib), Cvoid, (Cint, Ptr{Cint}), onlyIfNecessary, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const rebuild_node_cache = rebuildNodeCache """ gmsh.model.mesh.rebuildElementCache(onlyIfNecessary = true) Rebuild the element cache. """ function rebuildElementCache(onlyIfNecessary = true) ierr = Ref{Cint}() ccall((:gmshModelMeshRebuildElementCache, gmsh.lib), Cvoid, (Cint, Ptr{Cint}), onlyIfNecessary, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const rebuild_element_cache = rebuildElementCache """ gmsh.model.mesh.getNodesForPhysicalGroup(dim, tag) Get the nodes from all the elements belonging to the physical group of dimension `dim` and tag `tag`. `nodeTags` contains the node tags; `coord` is a vector of length 3 times the length of `nodeTags` that contains the x, y, z coordinates of the nodes, concatenated: [n1x, n1y, n1z, n2x, ...]. Return `nodeTags`, `coord`. """ function getNodesForPhysicalGroup(dim, tag) api_nodeTags_ = Ref{Ptr{Csize_t}}() api_nodeTags_n_ = Ref{Csize_t}() api_coord_ = Ref{Ptr{Cdouble}}() api_coord_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetNodesForPhysicalGroup, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Cint}), dim, tag, api_nodeTags_, api_nodeTags_n_, api_coord_, api_coord_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) nodeTags = unsafe_wrap(Array, api_nodeTags_[], api_nodeTags_n_[], own=true) coord = unsafe_wrap(Array, api_coord_[], api_coord_n_[], own=true) return nodeTags, coord end const get_nodes_for_physical_group = getNodesForPhysicalGroup """ gmsh.model.mesh.addNodes(dim, tag, nodeTags, coord, parametricCoord = Cdouble[]) Add nodes classified on the model entity of dimension `dim` and tag `tag`. `nodeTags` contains the node tags (their unique, strictly positive identification numbers). `coord` is a vector of length 3 times the length of `nodeTags` that contains the x, y, z coordinates of the nodes, concatenated: [n1x, n1y, n1z, n2x, ...]. The optional `parametricCoord` vector contains the parametric coordinates of the nodes, if any. The length of `parametricCoord` can be 0 or `dim` times the length of `nodeTags`. If the `nodeTags` vector is empty, new tags are automatically assigned to the nodes. """ function addNodes(dim, tag, nodeTags, coord, parametricCoord = Cdouble[]) ierr = Ref{Cint}() ccall((:gmshModelMeshAddNodes, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Csize_t}, Csize_t, Ptr{Cdouble}, Csize_t, Ptr{Cdouble}, Csize_t, Ptr{Cint}), dim, tag, convert(Vector{Csize_t}, nodeTags), length(nodeTags), convert(Vector{Cdouble}, coord), length(coord), convert(Vector{Cdouble}, parametricCoord), length(parametricCoord), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const add_nodes = addNodes """ gmsh.model.mesh.reclassifyNodes() Reclassify all nodes on their associated model entity, based on the elements. Can be used when importing nodes in bulk (e.g. by associating them all to a single volume), to reclassify them correctly on model surfaces, curves, etc. after the elements have been set. """ function reclassifyNodes() ierr = Ref{Cint}() ccall((:gmshModelMeshReclassifyNodes, gmsh.lib), Cvoid, (Ptr{Cint},), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const reclassify_nodes = reclassifyNodes """ gmsh.model.mesh.relocateNodes(dim = -1, tag = -1) Relocate the nodes classified on the entity of dimension `dim` and tag `tag` using their parametric coordinates. If `tag` < 0, relocate the nodes for all entities of dimension `dim`. If `dim` and `tag` are negative, relocate all the nodes in the mesh. """ function relocateNodes(dim = -1, tag = -1) ierr = Ref{Cint}() ccall((:gmshModelMeshRelocateNodes, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cint}), dim, tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const relocate_nodes = relocateNodes """ gmsh.model.mesh.getElements(dim = -1, tag = -1) Get the elements classified on the entity of dimension `dim` and tag `tag`. If `tag` < 0, get the elements for all entities of dimension `dim`. If `dim` and `tag` are negative, get all the elements in the mesh. `elementTypes` contains the MSH types of the elements (e.g. `2` for 3-node triangles: see `getElementProperties` to obtain the properties for a given element type). `elementTags` is a vector of the same length as `elementTypes`; each entry is a vector containing the tags (unique, strictly positive identifiers) of the elements of the corresponding type. `nodeTags` is also a vector of the same length as `elementTypes`; each entry is a vector of length equal to the number of elements of the given type times the number N of nodes for this type of element, that contains the node tags of all the elements of the given type, concatenated: [e1n1, e1n2, ..., e1nN, e2n1, ...]. Return `elementTypes`, `elementTags`, `nodeTags`. """ function getElements(dim = -1, tag = -1) api_elementTypes_ = Ref{Ptr{Cint}}() api_elementTypes_n_ = Ref{Csize_t}() api_elementTags_ = Ref{Ptr{Ptr{Csize_t}}}() api_elementTags_n_ = Ref{Ptr{Csize_t}}() api_elementTags_nn_ = Ref{Csize_t}() api_nodeTags_ = Ref{Ptr{Ptr{Csize_t}}}() api_nodeTags_n_ = Ref{Ptr{Csize_t}}() api_nodeTags_nn_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetElements, gmsh.lib), Cvoid, (Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Ptr{Ptr{Csize_t}}}, Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Ptr{Ptr{Ptr{Csize_t}}}, Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Cint, Cint, Ptr{Cint}), api_elementTypes_, api_elementTypes_n_, api_elementTags_, api_elementTags_n_, api_elementTags_nn_, api_nodeTags_, api_nodeTags_n_, api_nodeTags_nn_, dim, tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) elementTypes = unsafe_wrap(Array, api_elementTypes_[], api_elementTypes_n_[], own=true) tmp_api_elementTags_ = unsafe_wrap(Array, api_elementTags_[], api_elementTags_nn_[], own=true) tmp_api_elementTags_n_ = unsafe_wrap(Array, api_elementTags_n_[], api_elementTags_nn_[], own=true) elementTags = [ unsafe_wrap(Array, tmp_api_elementTags_[i], tmp_api_elementTags_n_[i], own=true) for i in 1:api_elementTags_nn_[] ] tmp_api_nodeTags_ = unsafe_wrap(Array, api_nodeTags_[], api_nodeTags_nn_[], own=true) tmp_api_nodeTags_n_ = unsafe_wrap(Array, api_nodeTags_n_[], api_nodeTags_nn_[], own=true) nodeTags = [ unsafe_wrap(Array, tmp_api_nodeTags_[i], tmp_api_nodeTags_n_[i], own=true) for i in 1:api_nodeTags_nn_[] ] return elementTypes, elementTags, nodeTags end const get_elements = getElements """ gmsh.model.mesh.getElement(elementTag) Get the type and node tags of the element with tag `tag`. This function relies on an internal cache (a vector in case of dense element numbering, a map otherwise); for large meshes accessing elements in bulk is often preferable. Return `elementType`, `nodeTags`. """ function getElement(elementTag) api_elementType_ = Ref{Cint}() api_nodeTags_ = Ref{Ptr{Csize_t}}() api_nodeTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetElement, gmsh.lib), Cvoid, (Csize_t, Ptr{Cint}, Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Ptr{Cint}), elementTag, api_elementType_, api_nodeTags_, api_nodeTags_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) nodeTags = unsafe_wrap(Array, api_nodeTags_[], api_nodeTags_n_[], own=true) return api_elementType_[], nodeTags end const get_element = getElement """ gmsh.model.mesh.getElementByCoordinates(x, y, z, dim = -1, strict = false) Search the mesh for an element located at coordinates (`x`, `y`, `z`). This function performs a search in a spatial octree. If an element is found, return its tag, type and node tags, as well as the local coordinates (`u`, `v`, `w`) within the reference element corresponding to search location. If `dim` is >= 0, only search for elements of the given dimension. If `strict` is not set, use a tolerance to find elements near the search location. Return `elementTag`, `elementType`, `nodeTags`, `u`, `v`, `w`. """ function getElementByCoordinates(x, y, z, dim = -1, strict = false) api_elementTag_ = Ref{Csize_t}() api_elementType_ = Ref{Cint}() api_nodeTags_ = Ref{Ptr{Csize_t}}() api_nodeTags_n_ = Ref{Csize_t}() api_u_ = Ref{Cdouble}() api_v_ = Ref{Cdouble}() api_w_ = Ref{Cdouble}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetElementByCoordinates, gmsh.lib), Cvoid, (Cdouble, Cdouble, Cdouble, Ptr{Csize_t}, Ptr{Cint}, Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Ptr{Cdouble}, Ptr{Cdouble}, Ptr{Cdouble}, Cint, Cint, Ptr{Cint}), x, y, z, api_elementTag_, api_elementType_, api_nodeTags_, api_nodeTags_n_, api_u_, api_v_, api_w_, dim, strict, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) nodeTags = unsafe_wrap(Array, api_nodeTags_[], api_nodeTags_n_[], own=true) return api_elementTag_[], api_elementType_[], nodeTags, api_u_[], api_v_[], api_w_[] end const get_element_by_coordinates = getElementByCoordinates """ gmsh.model.mesh.getElementsByCoordinates(x, y, z, dim = -1, strict = false) Search the mesh for element(s) located at coordinates (`x`, `y`, `z`). This function performs a search in a spatial octree. Return the tags of all found elements in `elementTags`. Additional information about the elements can be accessed through `getElement` and `getLocalCoordinatesInElement`. If `dim` is >= 0, only search for elements of the given dimension. If `strict` is not set, use a tolerance to find elements near the search location. Return `elementTags`. """ function getElementsByCoordinates(x, y, z, dim = -1, strict = false) api_elementTags_ = Ref{Ptr{Csize_t}}() api_elementTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetElementsByCoordinates, gmsh.lib), Cvoid, (Cdouble, Cdouble, Cdouble, Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Cint, Cint, Ptr{Cint}), x, y, z, api_elementTags_, api_elementTags_n_, dim, strict, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) elementTags = unsafe_wrap(Array, api_elementTags_[], api_elementTags_n_[], own=true) return elementTags end const get_elements_by_coordinates = getElementsByCoordinates """ gmsh.model.mesh.getLocalCoordinatesInElement(elementTag, x, y, z) Return the local coordinates (`u`, `v`, `w`) within the element `elementTag` corresponding to the model coordinates (`x`, `y`, `z`). This function relies on an internal cache (a vector in case of dense element numbering, a map otherwise); for large meshes accessing elements in bulk is often preferable. Return `u`, `v`, `w`. """ function getLocalCoordinatesInElement(elementTag, x, y, z) api_u_ = Ref{Cdouble}() api_v_ = Ref{Cdouble}() api_w_ = Ref{Cdouble}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetLocalCoordinatesInElement, gmsh.lib), Cvoid, (Csize_t, Cdouble, Cdouble, Cdouble, Ptr{Cdouble}, Ptr{Cdouble}, Ptr{Cdouble}, Ptr{Cint}), elementTag, x, y, z, api_u_, api_v_, api_w_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_u_[], api_v_[], api_w_[] end const get_local_coordinates_in_element = getLocalCoordinatesInElement """ gmsh.model.mesh.getElementTypes(dim = -1, tag = -1) Get the types of elements in the entity of dimension `dim` and tag `tag`. If `tag` < 0, get the types for all entities of dimension `dim`. If `dim` and `tag` are negative, get all the types in the mesh. Return `elementTypes`. """ function getElementTypes(dim = -1, tag = -1) api_elementTypes_ = Ref{Ptr{Cint}}() api_elementTypes_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetElementTypes, gmsh.lib), Cvoid, (Ptr{Ptr{Cint}}, Ptr{Csize_t}, Cint, Cint, Ptr{Cint}), api_elementTypes_, api_elementTypes_n_, dim, tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) elementTypes = unsafe_wrap(Array, api_elementTypes_[], api_elementTypes_n_[], own=true) return elementTypes end const get_element_types = getElementTypes """ gmsh.model.mesh.getElementType(familyName, order, serendip = false) Return an element type given its family name `familyName` ("Point", "Line", "Triangle", "Quadrangle", "Tetrahedron", "Pyramid", "Prism", "Hexahedron") and polynomial order `order`. If `serendip` is true, return the corresponding serendip element type (element without interior nodes). Return an integer value. """ function getElementType(familyName, order, serendip = false) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelMeshGetElementType, gmsh.lib), Cint, (Ptr{Cchar}, Cint, Cint, Ptr{Cint}), familyName, order, serendip, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const get_element_type = getElementType """ gmsh.model.mesh.getElementProperties(elementType) Get the properties of an element of type `elementType`: its name (`elementName`), dimension (`dim`), order (`order`), number of nodes (`numNodes`), local coordinates of the nodes in the reference element (`localNodeCoord` vector, of length `dim` times `numNodes`) and number of primary (first order) nodes (`numPrimaryNodes`). Return `elementName`, `dim`, `order`, `numNodes`, `localNodeCoord`, `numPrimaryNodes`. """ function getElementProperties(elementType) api_elementName_ = Ref{Ptr{Cchar}}() api_dim_ = Ref{Cint}() api_order_ = Ref{Cint}() api_numNodes_ = Ref{Cint}() api_localNodeCoord_ = Ref{Ptr{Cdouble}}() api_localNodeCoord_n_ = Ref{Csize_t}() api_numPrimaryNodes_ = Ref{Cint}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetElementProperties, gmsh.lib), Cvoid, (Cint, Ptr{Ptr{Cchar}}, Ptr{Cint}, Ptr{Cint}, Ptr{Cint}, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Cint}, Ptr{Cint}), elementType, api_elementName_, api_dim_, api_order_, api_numNodes_, api_localNodeCoord_, api_localNodeCoord_n_, api_numPrimaryNodes_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) elementName = unsafe_string(api_elementName_[]) localNodeCoord = unsafe_wrap(Array, api_localNodeCoord_[], api_localNodeCoord_n_[], own=true) return elementName, api_dim_[], api_order_[], api_numNodes_[], localNodeCoord, api_numPrimaryNodes_[] end const get_element_properties = getElementProperties """ gmsh.model.mesh.getElementsByType(elementType, tag = -1, task = 0, numTasks = 1) Get the elements of type `elementType` classified on the entity of tag `tag`. If `tag` < 0, get the elements for all entities. `elementTags` is a vector containing the tags (unique, strictly positive identifiers) of the elements of the corresponding type. `nodeTags` is a vector of length equal to the number of elements of the given type times the number N of nodes for this type of element, that contains the node tags of all the elements of the given type, concatenated: [e1n1, e1n2, ..., e1nN, e2n1, ...]. If `numTasks` > 1, only compute and return the part of the data indexed by `task`. Return `elementTags`, `nodeTags`. """ function getElementsByType(elementType, tag = -1, task = 0, numTasks = 1) api_elementTags_ = Ref{Ptr{Csize_t}}() api_elementTags_n_ = Ref{Csize_t}() api_nodeTags_ = Ref{Ptr{Csize_t}}() api_nodeTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetElementsByType, gmsh.lib), Cvoid, (Cint, Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Cint, Csize_t, Csize_t, Ptr{Cint}), elementType, api_elementTags_, api_elementTags_n_, api_nodeTags_, api_nodeTags_n_, tag, task, numTasks, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) elementTags = unsafe_wrap(Array, api_elementTags_[], api_elementTags_n_[], own=true) nodeTags = unsafe_wrap(Array, api_nodeTags_[], api_nodeTags_n_[], own=true) return elementTags, nodeTags end const get_elements_by_type = getElementsByType """ gmsh.model.mesh.addElements(dim, tag, elementTypes, elementTags, nodeTags) Add elements classified on the entity of dimension `dim` and tag `tag`. `types` contains the MSH types of the elements (e.g. `2` for 3-node triangles: see the Gmsh reference manual). `elementTags` is a vector of the same length as `types`; each entry is a vector containing the tags (unique, strictly positive identifiers) of the elements of the corresponding type. `nodeTags` is also a vector of the same length as `types`; each entry is a vector of length equal to the number of elements of the given type times the number N of nodes per element, that contains the node tags of all the elements of the given type, concatenated: [e1n1, e1n2, ..., e1nN, e2n1, ...]. """ function addElements(dim, tag, elementTypes, elementTags, nodeTags) api_elementTags_n_ = [ length(elementTags[i]) for i in 1:length(elementTags) ] api_nodeTags_n_ = [ length(nodeTags[i]) for i in 1:length(nodeTags) ] ierr = Ref{Cint}() ccall((:gmshModelMeshAddElements, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cint}, Csize_t, Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Csize_t, Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Csize_t, Ptr{Cint}), dim, tag, convert(Vector{Cint}, elementTypes), length(elementTypes), convert(Vector{Vector{Csize_t}},elementTags), api_elementTags_n_, length(elementTags), convert(Vector{Vector{Csize_t}},nodeTags), api_nodeTags_n_, length(nodeTags), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const add_elements = addElements """ gmsh.model.mesh.addElementsByType(tag, elementType, elementTags, nodeTags) Add elements of type `elementType` classified on the entity of tag `tag`. `elementTags` contains the tags (unique, strictly positive identifiers) of the elements of the corresponding type. `nodeTags` is a vector of length equal to the number of elements times the number N of nodes per element, that contains the node tags of all the elements, concatenated: [e1n1, e1n2, ..., e1nN, e2n1, ...]. If the `elementTag` vector is empty, new tags are automatically assigned to the elements. """ function addElementsByType(tag, elementType, elementTags, nodeTags) ierr = Ref{Cint}() ccall((:gmshModelMeshAddElementsByType, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Csize_t}, Csize_t, Ptr{Csize_t}, Csize_t, Ptr{Cint}), tag, elementType, convert(Vector{Csize_t}, elementTags), length(elementTags), convert(Vector{Csize_t}, nodeTags), length(nodeTags), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const add_elements_by_type = addElementsByType """ gmsh.model.mesh.getIntegrationPoints(elementType, integrationType) Get the numerical quadrature information for the given element type `elementType` and integration rule `integrationType` (e.g. "Gauss4" for a Gauss quadrature suited for integrating 4th order polynomials). `localCoord` contains the u, v, w coordinates of the G integration points in the reference element: [g1u, g1v, g1w, ..., gGu, gGv, gGw]. `weights` contains the associated weights: [g1q, ..., gGq]. Return `localCoord`, `weights`. """ function getIntegrationPoints(elementType, integrationType) api_localCoord_ = Ref{Ptr{Cdouble}}() api_localCoord_n_ = Ref{Csize_t}() api_weights_ = Ref{Ptr{Cdouble}}() api_weights_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetIntegrationPoints, gmsh.lib), Cvoid, (Cint, Ptr{Cchar}, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Cint}), elementType, integrationType, api_localCoord_, api_localCoord_n_, api_weights_, api_weights_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) localCoord = unsafe_wrap(Array, api_localCoord_[], api_localCoord_n_[], own=true) weights = unsafe_wrap(Array, api_weights_[], api_weights_n_[], own=true) return localCoord, weights end const get_integration_points = getIntegrationPoints """ gmsh.model.mesh.getJacobians(elementType, localCoord, tag = -1, task = 0, numTasks = 1) Get the Jacobians of all the elements of type `elementType` classified on the entity of tag `tag`, at the G evaluation points `localCoord` given as concatenated triplets of coordinates in the reference element [g1u, g1v, g1w, ..., gGu, gGv, gGw]. Data is returned by element, with elements in the same order as in `getElements` and `getElementsByType`. `jacobians` contains for each element the 9 entries of the 3x3 Jacobian matrix at each evaluation point. The matrix is returned by column: [e1g1Jxu, e1g1Jyu, e1g1Jzu, e1g1Jxv, ..., e1g1Jzw, e1g2Jxu, ..., e1gGJzw, e2g1Jxu, ...], with Jxu=dx/du, Jyu=dy/du, etc. `determinants` contains for each element the determinant of the Jacobian matrix at each evaluation point: [e1g1, e1g2, ... e1gG, e2g1, ...]. `coord` contains for each element the x, y, z coordinates of the evaluation points. If `tag` < 0, get the Jacobian data for all entities. If `numTasks` > 1, only compute and return the part of the data indexed by `task`. Return `jacobians`, `determinants`, `coord`. """ function getJacobians(elementType, localCoord, tag = -1, task = 0, numTasks = 1) api_jacobians_ = Ref{Ptr{Cdouble}}() api_jacobians_n_ = Ref{Csize_t}() api_determinants_ = Ref{Ptr{Cdouble}}() api_determinants_n_ = Ref{Csize_t}() api_coord_ = Ref{Ptr{Cdouble}}() api_coord_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetJacobians, gmsh.lib), Cvoid, (Cint, Ptr{Cdouble}, Csize_t, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Cint, Csize_t, Csize_t, Ptr{Cint}), elementType, convert(Vector{Cdouble}, localCoord), length(localCoord), api_jacobians_, api_jacobians_n_, api_determinants_, api_determinants_n_, api_coord_, api_coord_n_, tag, task, numTasks, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) jacobians = unsafe_wrap(Array, api_jacobians_[], api_jacobians_n_[], own=true) determinants = unsafe_wrap(Array, api_determinants_[], api_determinants_n_[], own=true) coord = unsafe_wrap(Array, api_coord_[], api_coord_n_[], own=true) return jacobians, determinants, coord end const get_jacobians = getJacobians """ gmsh.model.mesh.getJacobian(elementTag, localCoord) Get the Jacobian for a single element `elementTag`, at the G evaluation points `localCoord` given as concatenated triplets of coordinates in the reference element [g1u, g1v, g1w, ..., gGu, gGv, gGw]. `jacobians` contains the 9 entries of the 3x3 Jacobian matrix at each evaluation point. The matrix is returned by column: [e1g1Jxu, e1g1Jyu, e1g1Jzu, e1g1Jxv, ..., e1g1Jzw, e1g2Jxu, ..., e1gGJzw, e2g1Jxu, ...], with Jxu=dx/du, Jyu=dy/du, etc. `determinants` contains the determinant of the Jacobian matrix at each evaluation point. `coord` contains the x, y, z coordinates of the evaluation points. This function relies on an internal cache (a vector in case of dense element numbering, a map otherwise); for large meshes accessing Jacobians in bulk is often preferable. Return `jacobians`, `determinants`, `coord`. """ function getJacobian(elementTag, localCoord) api_jacobians_ = Ref{Ptr{Cdouble}}() api_jacobians_n_ = Ref{Csize_t}() api_determinants_ = Ref{Ptr{Cdouble}}() api_determinants_n_ = Ref{Csize_t}() api_coord_ = Ref{Ptr{Cdouble}}() api_coord_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetJacobian, gmsh.lib), Cvoid, (Csize_t, Ptr{Cdouble}, Csize_t, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Cint}), elementTag, convert(Vector{Cdouble}, localCoord), length(localCoord), api_jacobians_, api_jacobians_n_, api_determinants_, api_determinants_n_, api_coord_, api_coord_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) jacobians = unsafe_wrap(Array, api_jacobians_[], api_jacobians_n_[], own=true) determinants = unsafe_wrap(Array, api_determinants_[], api_determinants_n_[], own=true) coord = unsafe_wrap(Array, api_coord_[], api_coord_n_[], own=true) return jacobians, determinants, coord end const get_jacobian = getJacobian """ gmsh.model.mesh.getBasisFunctions(elementType, localCoord, functionSpaceType, wantedOrientations = Cint[]) Get the basis functions of the element of type `elementType` at the evaluation points `localCoord` (given as concatenated triplets of coordinates in the reference element [g1u, g1v, g1w, ..., gGu, gGv, gGw]), for the function space `functionSpaceType` (e.g. "Lagrange" or "GradLagrange" for Lagrange basis functions or their gradient, in the u, v, w coordinates of the reference element; or "H1Legendre3" or "GradH1Legendre3" for 3rd order hierarchical H1 Legendre functions). `numComponents` returns the number C of components of a basis function. `basisFunctions` returns the value of the N basis functions at the evaluation points, i.e. [g1f1, g1f2, ..., g1fN, g2f1, ...] when C == 1 or [g1f1u, g1f1v, g1f1w, g1f2u, ..., g1fNw, g2f1u, ...] when C == 3. For basis functions that depend on the orientation of the elements, all values for the first orientation are returned first, followed by values for the second, etc. `numOrientations` returns the overall number of orientations. If `wantedOrientations` is not empty, only return the values for the desired orientation indices. Return `numComponents`, `basisFunctions`, `numOrientations`. """ function getBasisFunctions(elementType, localCoord, functionSpaceType, wantedOrientations = Cint[]) api_numComponents_ = Ref{Cint}() api_basisFunctions_ = Ref{Ptr{Cdouble}}() api_basisFunctions_n_ = Ref{Csize_t}() api_numOrientations_ = Ref{Cint}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetBasisFunctions, gmsh.lib), Cvoid, (Cint, Ptr{Cdouble}, Csize_t, Ptr{Cchar}, Ptr{Cint}, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Cint}, Ptr{Cint}, Csize_t, Ptr{Cint}), elementType, convert(Vector{Cdouble}, localCoord), length(localCoord), functionSpaceType, api_numComponents_, api_basisFunctions_, api_basisFunctions_n_, api_numOrientations_, convert(Vector{Cint}, wantedOrientations), length(wantedOrientations), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) basisFunctions = unsafe_wrap(Array, api_basisFunctions_[], api_basisFunctions_n_[], own=true) return api_numComponents_[], basisFunctions, api_numOrientations_[] end const get_basis_functions = getBasisFunctions """ gmsh.model.mesh.getBasisFunctionsOrientationForElements(elementType, functionSpaceType, tag = -1, task = 0, numTasks = 1) Get the orientation index of the elements of type `elementType` in the entity of tag `tag`. The arguments have the same meaning as in `getBasisFunctions`. `basisFunctionsOrientation` is a vector giving for each element the orientation index in the values returned by `getBasisFunctions`. For Lagrange basis functions the call is superfluous as it will return a vector of zeros. Return `basisFunctionsOrientation`. """ function getBasisFunctionsOrientationForElements(elementType, functionSpaceType, tag = -1, task = 0, numTasks = 1) api_basisFunctionsOrientation_ = Ref{Ptr{Cint}}() api_basisFunctionsOrientation_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetBasisFunctionsOrientationForElements, gmsh.lib), Cvoid, (Cint, Ptr{Cchar}, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Cint, Csize_t, Csize_t, Ptr{Cint}), elementType, functionSpaceType, api_basisFunctionsOrientation_, api_basisFunctionsOrientation_n_, tag, task, numTasks, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) basisFunctionsOrientation = unsafe_wrap(Array, api_basisFunctionsOrientation_[], api_basisFunctionsOrientation_n_[], own=true) return basisFunctionsOrientation end const get_basis_functions_orientation_for_elements = getBasisFunctionsOrientationForElements """ gmsh.model.mesh.getBasisFunctionsOrientationForElement(elementTag, functionSpaceType) Get the orientation of a single element `elementTag`. Return `basisFunctionsOrientation`. """ function getBasisFunctionsOrientationForElement(elementTag, functionSpaceType) api_basisFunctionsOrientation_ = Ref{Cint}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetBasisFunctionsOrientationForElement, gmsh.lib), Cvoid, (Csize_t, Ptr{Cchar}, Ptr{Cint}, Ptr{Cint}), elementTag, functionSpaceType, api_basisFunctionsOrientation_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_basisFunctionsOrientation_[] end const get_basis_functions_orientation_for_element = getBasisFunctionsOrientationForElement """ gmsh.model.mesh.getNumberOfOrientations(elementType, functionSpaceType) Get the number of possible orientations for elements of type `elementType` and function space named `functionSpaceType`. Return an integer value. """ function getNumberOfOrientations(elementType, functionSpaceType) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelMeshGetNumberOfOrientations, gmsh.lib), Cint, (Cint, Ptr{Cchar}, Ptr{Cint}), elementType, functionSpaceType, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const get_number_of_orientations = getNumberOfOrientations """ gmsh.model.mesh.getEdges(nodeTags) Get the global unique mesh edge identifiers `edgeTags` and orientations `edgeOrientation` for an input list of node tag pairs defining these edges, concatenated in the vector `nodeTags`. Return `edgeTags`, `edgeOrientations`. """ function getEdges(nodeTags) api_edgeTags_ = Ref{Ptr{Csize_t}}() api_edgeTags_n_ = Ref{Csize_t}() api_edgeOrientations_ = Ref{Ptr{Cint}}() api_edgeOrientations_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetEdges, gmsh.lib), Cvoid, (Ptr{Csize_t}, Csize_t, Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Cint}), convert(Vector{Csize_t}, nodeTags), length(nodeTags), api_edgeTags_, api_edgeTags_n_, api_edgeOrientations_, api_edgeOrientations_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) edgeTags = unsafe_wrap(Array, api_edgeTags_[], api_edgeTags_n_[], own=true) edgeOrientations = unsafe_wrap(Array, api_edgeOrientations_[], api_edgeOrientations_n_[], own=true) return edgeTags, edgeOrientations end const get_edges = getEdges """ gmsh.model.mesh.getFaces(faceType, nodeTags) Get the global unique mesh face identifiers `faceTags` and orientations `faceOrientations` for an input list of node tag triplets (if `faceType` == 3) or quadruplets (if `faceType` == 4) defining these faces, concatenated in the vector `nodeTags`. Return `faceTags`, `faceOrientations`. """ function getFaces(faceType, nodeTags) api_faceTags_ = Ref{Ptr{Csize_t}}() api_faceTags_n_ = Ref{Csize_t}() api_faceOrientations_ = Ref{Ptr{Cint}}() api_faceOrientations_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetFaces, gmsh.lib), Cvoid, (Cint, Ptr{Csize_t}, Csize_t, Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Cint}), faceType, convert(Vector{Csize_t}, nodeTags), length(nodeTags), api_faceTags_, api_faceTags_n_, api_faceOrientations_, api_faceOrientations_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) faceTags = unsafe_wrap(Array, api_faceTags_[], api_faceTags_n_[], own=true) faceOrientations = unsafe_wrap(Array, api_faceOrientations_[], api_faceOrientations_n_[], own=true) return faceTags, faceOrientations end const get_faces = getFaces """ gmsh.model.mesh.createEdges(dimTags = Tuple{Cint,Cint}[]) Create unique mesh edges for the entities `dimTags`. """ function createEdges(dimTags = Tuple{Cint,Cint}[]) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelMeshCreateEdges, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Ptr{Cint}), api_dimTags_, api_dimTags_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const create_edges = createEdges """ gmsh.model.mesh.createFaces(dimTags = Tuple{Cint,Cint}[]) Create unique mesh faces for the entities `dimTags`. """ function createFaces(dimTags = Tuple{Cint,Cint}[]) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelMeshCreateFaces, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Ptr{Cint}), api_dimTags_, api_dimTags_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const create_faces = createFaces """ gmsh.model.mesh.getKeysForElements(elementType, functionSpaceType, tag = -1, returnCoord = true) Generate the pair of keys for the elements of type `elementType` in the entity of tag `tag`, for the `functionSpaceType` function space. Each pair (`typeKey`, `entityKey`) uniquely identifies a basis function in the function space. If `returnCoord` is set, the `coord` vector contains the x, y, z coordinates locating basis functions for sorting purposes. Warning: this is an experimental feature and will probably change in a future release. Return `typeKeys`, `entityKeys`, `coord`. """ function getKeysForElements(elementType, functionSpaceType, tag = -1, returnCoord = true) api_typeKeys_ = Ref{Ptr{Cint}}() api_typeKeys_n_ = Ref{Csize_t}() api_entityKeys_ = Ref{Ptr{Csize_t}}() api_entityKeys_n_ = Ref{Csize_t}() api_coord_ = Ref{Ptr{Cdouble}}() api_coord_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetKeysForElements, gmsh.lib), Cvoid, (Cint, Ptr{Cchar}, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Cint, Cint, Ptr{Cint}), elementType, functionSpaceType, api_typeKeys_, api_typeKeys_n_, api_entityKeys_, api_entityKeys_n_, api_coord_, api_coord_n_, tag, returnCoord, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) typeKeys = unsafe_wrap(Array, api_typeKeys_[], api_typeKeys_n_[], own=true) entityKeys = unsafe_wrap(Array, api_entityKeys_[], api_entityKeys_n_[], own=true) coord = unsafe_wrap(Array, api_coord_[], api_coord_n_[], own=true) return typeKeys, entityKeys, coord end const get_keys_for_elements = getKeysForElements """ gmsh.model.mesh.getKeysForElement(elementTag, functionSpaceType, returnCoord = true) Get the pair of keys for a single element `elementTag`. Return `typeKeys`, `entityKeys`, `coord`. """ function getKeysForElement(elementTag, functionSpaceType, returnCoord = true) api_typeKeys_ = Ref{Ptr{Cint}}() api_typeKeys_n_ = Ref{Csize_t}() api_entityKeys_ = Ref{Ptr{Csize_t}}() api_entityKeys_n_ = Ref{Csize_t}() api_coord_ = Ref{Ptr{Cdouble}}() api_coord_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetKeysForElement, gmsh.lib), Cvoid, (Csize_t, Ptr{Cchar}, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Cint, Ptr{Cint}), elementTag, functionSpaceType, api_typeKeys_, api_typeKeys_n_, api_entityKeys_, api_entityKeys_n_, api_coord_, api_coord_n_, returnCoord, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) typeKeys = unsafe_wrap(Array, api_typeKeys_[], api_typeKeys_n_[], own=true) entityKeys = unsafe_wrap(Array, api_entityKeys_[], api_entityKeys_n_[], own=true) coord = unsafe_wrap(Array, api_coord_[], api_coord_n_[], own=true) return typeKeys, entityKeys, coord end const get_keys_for_element = getKeysForElement """ gmsh.model.mesh.getNumberOfKeysForElements(elementType, functionSpaceType) Get the number of keys by elements of type `elementType` for function space named `functionSpaceType`. Return an integer value. """ function getNumberOfKeysForElements(elementType, functionSpaceType) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelMeshGetNumberOfKeysForElements, gmsh.lib), Cint, (Cint, Ptr{Cchar}, Ptr{Cint}), elementType, functionSpaceType, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const get_number_of_keys_for_elements = getNumberOfKeysForElements """ gmsh.model.mesh.getInformationForElements(typeKeys, entityKeys, elementType, functionSpaceType) Get information about the pair of `keys`. `infoKeys` returns information about the functions associated with the pairs (`typeKeys`, `entityKey`). `infoKeys[0].first` describes the type of function (0 for vertex function, 1 for edge function, 2 for face function and 3 for bubble function). `infoKeys[0].second` gives the order of the function associated with the key. Warning: this is an experimental feature and will probably change in a future release. Return `infoKeys`. """ function getInformationForElements(typeKeys, entityKeys, elementType, functionSpaceType) api_infoKeys_ = Ref{Ptr{Cint}}() api_infoKeys_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetInformationForElements, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Ptr{Csize_t}, Csize_t, Cint, Ptr{Cchar}, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Cint}), convert(Vector{Cint}, typeKeys), length(typeKeys), convert(Vector{Csize_t}, entityKeys), length(entityKeys), elementType, functionSpaceType, api_infoKeys_, api_infoKeys_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_infoKeys_ = unsafe_wrap(Array, api_infoKeys_[], api_infoKeys_n_[], own=true) infoKeys = [ (tmp_api_infoKeys_[i], tmp_api_infoKeys_[i+1]) for i in 1:2:length(tmp_api_infoKeys_) ] return infoKeys end const get_information_for_elements = getInformationForElements """ gmsh.model.mesh.getBarycenters(elementType, tag, fast, primary, task = 0, numTasks = 1) Get the barycenters of all elements of type `elementType` classified on the entity of tag `tag`. If `primary` is set, only the primary nodes of the elements are taken into account for the barycenter calculation. If `fast` is set, the function returns the sum of the primary node coordinates (without normalizing by the number of nodes). If `tag` < 0, get the barycenters for all entities. If `numTasks` > 1, only compute and return the part of the data indexed by `task`. Return `barycenters`. """ function getBarycenters(elementType, tag, fast, primary, task = 0, numTasks = 1) api_barycenters_ = Ref{Ptr{Cdouble}}() api_barycenters_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetBarycenters, gmsh.lib), Cvoid, (Cint, Cint, Cint, Cint, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Csize_t, Csize_t, Ptr{Cint}), elementType, tag, fast, primary, api_barycenters_, api_barycenters_n_, task, numTasks, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) barycenters = unsafe_wrap(Array, api_barycenters_[], api_barycenters_n_[], own=true) return barycenters end const get_barycenters = getBarycenters """ gmsh.model.mesh.getElementEdgeNodes(elementType, tag = -1, primary = false, task = 0, numTasks = 1) Get the nodes on the edges of all elements of type `elementType` classified on the entity of tag `tag`. `nodeTags` contains the node tags of the edges for all the elements: [e1a1n1, e1a1n2, e1a2n1, ...]. Data is returned by element, with elements in the same order as in `getElements` and `getElementsByType`. If `primary` is set, only the primary (begin/end) nodes of the edges are returned. If `tag` < 0, get the edge nodes for all entities. If `numTasks` > 1, only compute and return the part of the data indexed by `task`. Return `nodeTags`. """ function getElementEdgeNodes(elementType, tag = -1, primary = false, task = 0, numTasks = 1) api_nodeTags_ = Ref{Ptr{Csize_t}}() api_nodeTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetElementEdgeNodes, gmsh.lib), Cvoid, (Cint, Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Cint, Cint, Csize_t, Csize_t, Ptr{Cint}), elementType, api_nodeTags_, api_nodeTags_n_, tag, primary, task, numTasks, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) nodeTags = unsafe_wrap(Array, api_nodeTags_[], api_nodeTags_n_[], own=true) return nodeTags end const get_element_edge_nodes = getElementEdgeNodes """ gmsh.model.mesh.getElementFaceNodes(elementType, faceType, tag = -1, primary = false, task = 0, numTasks = 1) Get the nodes on the faces of type `faceType` (3 for triangular faces, 4 for quadrangular faces) of all elements of type `elementType` classified on the entity of tag `tag`. `nodeTags` contains the node tags of the faces for all elements: [e1f1n1, ..., e1f1nFaceType, e1f2n1, ...]. Data is returned by element, with elements in the same order as in `getElements` and `getElementsByType`. If `primary` is set, only the primary (corner) nodes of the faces are returned. If `tag` < 0, get the face nodes for all entities. If `numTasks` > 1, only compute and return the part of the data indexed by `task`. Return `nodeTags`. """ function getElementFaceNodes(elementType, faceType, tag = -1, primary = false, task = 0, numTasks = 1) api_nodeTags_ = Ref{Ptr{Csize_t}}() api_nodeTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetElementFaceNodes, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Cint, Cint, Csize_t, Csize_t, Ptr{Cint}), elementType, faceType, api_nodeTags_, api_nodeTags_n_, tag, primary, task, numTasks, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) nodeTags = unsafe_wrap(Array, api_nodeTags_[], api_nodeTags_n_[], own=true) return nodeTags end const get_element_face_nodes = getElementFaceNodes """ gmsh.model.mesh.getGhostElements(dim, tag) Get the ghost elements `elementTags` and their associated `partitions` stored in the ghost entity of dimension `dim` and tag `tag`. Return `elementTags`, `partitions`. """ function getGhostElements(dim, tag) api_elementTags_ = Ref{Ptr{Csize_t}}() api_elementTags_n_ = Ref{Csize_t}() api_partitions_ = Ref{Ptr{Cint}}() api_partitions_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetGhostElements, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Cint}), dim, tag, api_elementTags_, api_elementTags_n_, api_partitions_, api_partitions_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) elementTags = unsafe_wrap(Array, api_elementTags_[], api_elementTags_n_[], own=true) partitions = unsafe_wrap(Array, api_partitions_[], api_partitions_n_[], own=true) return elementTags, partitions end const get_ghost_elements = getGhostElements """ gmsh.model.mesh.setSize(dimTags, size) Set a mesh size constraint on the model entities `dimTags`. Currently only entities of dimension 0 (points) are handled. """ function setSize(dimTags, size) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelMeshSetSize, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Cdouble, Ptr{Cint}), api_dimTags_, api_dimTags_n_, size, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_size = setSize """ gmsh.model.mesh.getSizes(dimTags) Get the mesh size constraints (if any) associated with the model entities `dimTags`. A zero entry in the output `sizes` vector indicates that no size constraint is specified on the corresponding entity. Return `sizes`. """ function getSizes(dimTags) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) api_sizes_ = Ref{Ptr{Cdouble}}() api_sizes_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetSizes, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Cint}), api_dimTags_, api_dimTags_n_, api_sizes_, api_sizes_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) sizes = unsafe_wrap(Array, api_sizes_[], api_sizes_n_[], own=true) return sizes end const get_sizes = getSizes """ gmsh.model.mesh.setSizeAtParametricPoints(dim, tag, parametricCoord, sizes) Set mesh size constraints at the given parametric points `parametricCoord` on the model entity of dimension `dim` and tag `tag`. Currently only entities of dimension 1 (lines) are handled. """ function setSizeAtParametricPoints(dim, tag, parametricCoord, sizes) ierr = Ref{Cint}() ccall((:gmshModelMeshSetSizeAtParametricPoints, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cdouble}, Csize_t, Ptr{Cdouble}, Csize_t, Ptr{Cint}), dim, tag, convert(Vector{Cdouble}, parametricCoord), length(parametricCoord), convert(Vector{Cdouble}, sizes), length(sizes), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_size_at_parametric_points = setSizeAtParametricPoints """ gmsh.model.mesh.setSizeCallback(callback) Set a mesh size callback for the current model. The callback should take 5 arguments (`dim`, `tag`, `x`, `y` and `z`) and return the value of the mesh size at coordinates (`x`, `y`, `z`). """ function setSizeCallback(callback) api_callback__(dim, tag, x, y, z, data) = callback(dim, tag, x, y, z) api_callback_ = @cfunction($api_callback__, Cdouble, (Cint, Cint, Cdouble, Cdouble, Cdouble, Ptr{Cvoid})) ierr = Ref{Cint}() ccall((:gmshModelMeshSetSizeCallback, gmsh.lib), Cvoid, (Ptr{Cvoid}, Ptr{Cvoid}, Ptr{Cint}), api_callback_, C_NULL, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_size_callback = setSizeCallback """ gmsh.model.mesh.removeSizeCallback() Remove the mesh size callback from the current model. """ function removeSizeCallback() ierr = Ref{Cint}() ccall((:gmshModelMeshRemoveSizeCallback, gmsh.lib), Cvoid, (Ptr{Cint},), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const remove_size_callback = removeSizeCallback """ gmsh.model.mesh.setTransfiniteCurve(tag, numNodes, meshType = "Progression", coef = 1.) Set a transfinite meshing constraint on the curve `tag`, with `numNodes` nodes distributed according to `meshType` and `coef`. Currently supported types are "Progression" (geometrical progression with power `coef`), "Bump" (refinement toward both extremities of the curve) and "Beta" (beta law). """ function setTransfiniteCurve(tag, numNodes, meshType = "Progression", coef = 1.) ierr = Ref{Cint}() ccall((:gmshModelMeshSetTransfiniteCurve, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cchar}, Cdouble, Ptr{Cint}), tag, numNodes, meshType, coef, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_transfinite_curve = setTransfiniteCurve """ gmsh.model.mesh.setTransfiniteSurface(tag, arrangement = "Left", cornerTags = Cint[]) Set a transfinite meshing constraint on the surface `tag`. `arrangement` describes the arrangement of the triangles when the surface is not flagged as recombined: currently supported values are "Left", "Right", "AlternateLeft" and "AlternateRight". `cornerTags` can be used to specify the (3 or 4) corners of the transfinite interpolation explicitly; specifying the corners explicitly is mandatory if the surface has more that 3 or 4 points on its boundary. """ function setTransfiniteSurface(tag, arrangement = "Left", cornerTags = Cint[]) ierr = Ref{Cint}() ccall((:gmshModelMeshSetTransfiniteSurface, gmsh.lib), Cvoid, (Cint, Ptr{Cchar}, Ptr{Cint}, Csize_t, Ptr{Cint}), tag, arrangement, convert(Vector{Cint}, cornerTags), length(cornerTags), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_transfinite_surface = setTransfiniteSurface """ gmsh.model.mesh.setTransfiniteVolume(tag, cornerTags = Cint[]) Set a transfinite meshing constraint on the surface `tag`. `cornerTags` can be used to specify the (6 or 8) corners of the transfinite interpolation explicitly. """ function setTransfiniteVolume(tag, cornerTags = Cint[]) ierr = Ref{Cint}() ccall((:gmshModelMeshSetTransfiniteVolume, gmsh.lib), Cvoid, (Cint, Ptr{Cint}, Csize_t, Ptr{Cint}), tag, convert(Vector{Cint}, cornerTags), length(cornerTags), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_transfinite_volume = setTransfiniteVolume """ gmsh.model.mesh.setTransfiniteAutomatic(dimTags = Tuple{Cint,Cint}[], cornerAngle = 2.35, recombine = true) Set transfinite meshing constraints on the model entities in `dimTag`. Transfinite meshing constraints are added to the curves of the quadrangular surfaces and to the faces of 6-sided volumes. Quadragular faces with a corner angle superior to `cornerAngle` (in radians) are ignored. The number of points is automatically determined from the sizing constraints. If `dimTag` is empty, the constraints are applied to all entities in the model. If `recombine` is true, the recombine flag is automatically set on the transfinite surfaces. """ function setTransfiniteAutomatic(dimTags = Tuple{Cint,Cint}[], cornerAngle = 2.35, recombine = true) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelMeshSetTransfiniteAutomatic, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Cdouble, Cint, Ptr{Cint}), api_dimTags_, api_dimTags_n_, cornerAngle, recombine, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_transfinite_automatic = setTransfiniteAutomatic """ gmsh.model.mesh.setRecombine(dim, tag) Set a recombination meshing constraint on the model entity of dimension `dim` and tag `tag`. Currently only entities of dimension 2 (to recombine triangles into quadrangles) are supported. """ function setRecombine(dim, tag) ierr = Ref{Cint}() ccall((:gmshModelMeshSetRecombine, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cint}), dim, tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_recombine = setRecombine """ gmsh.model.mesh.setSmoothing(dim, tag, val) Set a smoothing meshing constraint on the model entity of dimension `dim` and tag `tag`. `val` iterations of a Laplace smoother are applied. """ function setSmoothing(dim, tag, val) ierr = Ref{Cint}() ccall((:gmshModelMeshSetSmoothing, gmsh.lib), Cvoid, (Cint, Cint, Cint, Ptr{Cint}), dim, tag, val, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_smoothing = setSmoothing """ gmsh.model.mesh.setReverse(dim, tag, val = true) Set a reverse meshing constraint on the model entity of dimension `dim` and tag `tag`. If `val` is true, the mesh orientation will be reversed with respect to the natural mesh orientation (i.e. the orientation consistent with the orientation of the geometry). If `val` is false, the mesh is left as-is. """ function setReverse(dim, tag, val = true) ierr = Ref{Cint}() ccall((:gmshModelMeshSetReverse, gmsh.lib), Cvoid, (Cint, Cint, Cint, Ptr{Cint}), dim, tag, val, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_reverse = setReverse """ gmsh.model.mesh.setAlgorithm(dim, tag, val) Set the meshing algorithm on the model entity of dimension `dim` and tag `tag`. Currently only supported for `dim` == 2. """ function setAlgorithm(dim, tag, val) ierr = Ref{Cint}() ccall((:gmshModelMeshSetAlgorithm, gmsh.lib), Cvoid, (Cint, Cint, Cint, Ptr{Cint}), dim, tag, val, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_algorithm = setAlgorithm """ gmsh.model.mesh.setSizeFromBoundary(dim, tag, val) Force the mesh size to be extended from the boundary, or not, for the model entity of dimension `dim` and tag `tag`. Currently only supported for `dim` == 2. """ function setSizeFromBoundary(dim, tag, val) ierr = Ref{Cint}() ccall((:gmshModelMeshSetSizeFromBoundary, gmsh.lib), Cvoid, (Cint, Cint, Cint, Ptr{Cint}), dim, tag, val, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_size_from_boundary = setSizeFromBoundary """ gmsh.model.mesh.setCompound(dim, tags) Set a compound meshing constraint on the model entities of dimension `dim` and tags `tags`. During meshing, compound entities are treated as a single discrete entity, which is automatically reparametrized. """ function setCompound(dim, tags) ierr = Ref{Cint}() ccall((:gmshModelMeshSetCompound, gmsh.lib), Cvoid, (Cint, Ptr{Cint}, Csize_t, Ptr{Cint}), dim, convert(Vector{Cint}, tags), length(tags), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_compound = setCompound """ gmsh.model.mesh.setOutwardOrientation(tag) Set meshing constraints on the bounding surfaces of the volume of tag `tag` so that all surfaces are oriented with outward pointing normals; and if a mesh already exists, reorient it. Currently only available with the OpenCASCADE kernel, as it relies on the STL triangulation. """ function setOutwardOrientation(tag) ierr = Ref{Cint}() ccall((:gmshModelMeshSetOutwardOrientation, gmsh.lib), Cvoid, (Cint, Ptr{Cint}), tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_outward_orientation = setOutwardOrientation """ gmsh.model.mesh.removeConstraints(dimTags = Tuple{Cint,Cint}[]) Remove all meshing constraints from the model entities `dimTags`. If `dimTags` is empty, remove all constraings. """ function removeConstraints(dimTags = Tuple{Cint,Cint}[]) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelMeshRemoveConstraints, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Ptr{Cint}), api_dimTags_, api_dimTags_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const remove_constraints = removeConstraints """ gmsh.model.mesh.embed(dim, tags, inDim, inTag) Embed the model entities of dimension `dim` and tags `tags` in the (`inDim`, `inTag`) model entity. The dimension `dim` can 0, 1 or 2 and must be strictly smaller than `inDim`, which must be either 2 or 3. The embedded entities should not intersect each other or be part of the boundary of the entity `inTag`, whose mesh will conform to the mesh of the embedded entities. With the OpenCASCADE kernel, if the `fragment` operation is applied to entities of different dimensions, the lower dimensional entities will be automatically embedded in the higher dimensional entities if they are not on their boundary. """ function embed(dim, tags, inDim, inTag) ierr = Ref{Cint}() ccall((:gmshModelMeshEmbed, gmsh.lib), Cvoid, (Cint, Ptr{Cint}, Csize_t, Cint, Cint, Ptr{Cint}), dim, convert(Vector{Cint}, tags), length(tags), inDim, inTag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.model.mesh.removeEmbedded(dimTags, dim = -1) Remove embedded entities from the model entities `dimTags`. if `dim` is >= 0, only remove embedded entities of the given dimension (e.g. embedded points if `dim` == 0). """ function removeEmbedded(dimTags, dim = -1) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelMeshRemoveEmbedded, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Cint, Ptr{Cint}), api_dimTags_, api_dimTags_n_, dim, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const remove_embedded = removeEmbedded """ gmsh.model.mesh.getEmbedded(dim, tag) Get the entities (if any) embedded in the model entity of dimension `dim` and tag `tag`. Return `dimTags`. """ function getEmbedded(dim, tag) api_dimTags_ = Ref{Ptr{Cint}}() api_dimTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetEmbedded, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Cint}), dim, tag, api_dimTags_, api_dimTags_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_dimTags_ = unsafe_wrap(Array, api_dimTags_[], api_dimTags_n_[], own=true) dimTags = [ (tmp_api_dimTags_[i], tmp_api_dimTags_[i+1]) for i in 1:2:length(tmp_api_dimTags_) ] return dimTags end const get_embedded = getEmbedded """ gmsh.model.mesh.reorderElements(elementType, tag, ordering) Reorder the elements of type `elementType` classified on the entity of tag `tag` according to `ordering`. """ function reorderElements(elementType, tag, ordering) ierr = Ref{Cint}() ccall((:gmshModelMeshReorderElements, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Csize_t}, Csize_t, Ptr{Cint}), elementType, tag, convert(Vector{Csize_t}, ordering), length(ordering), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const reorder_elements = reorderElements """ gmsh.model.mesh.renumberNodes() Renumber the node tags in a continuous sequence. """ function renumberNodes() ierr = Ref{Cint}() ccall((:gmshModelMeshRenumberNodes, gmsh.lib), Cvoid, (Ptr{Cint},), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const renumber_nodes = renumberNodes """ gmsh.model.mesh.renumberElements() Renumber the element tags in a continuous sequence. """ function renumberElements() ierr = Ref{Cint}() ccall((:gmshModelMeshRenumberElements, gmsh.lib), Cvoid, (Ptr{Cint},), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const renumber_elements = renumberElements """ gmsh.model.mesh.setPeriodic(dim, tags, tagsMaster, affineTransform) Set the meshes of the entities of dimension `dim` and tag `tags` as periodic copies of the meshes of entities `tagsMaster`, using the affine transformation specified in `affineTransformation` (16 entries of a 4x4 matrix, by row). If used after meshing, generate the periodic node correspondence information assuming the meshes of entities `tags` effectively match the meshes of entities `tagsMaster` (useful for structured and extruded meshes). Currently only available for @code{dim} == 1 and @code{dim} == 2. """ function setPeriodic(dim, tags, tagsMaster, affineTransform) ierr = Ref{Cint}() ccall((:gmshModelMeshSetPeriodic, gmsh.lib), Cvoid, (Cint, Ptr{Cint}, Csize_t, Ptr{Cint}, Csize_t, Ptr{Cdouble}, Csize_t, Ptr{Cint}), dim, convert(Vector{Cint}, tags), length(tags), convert(Vector{Cint}, tagsMaster), length(tagsMaster), convert(Vector{Cdouble}, affineTransform), length(affineTransform), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_periodic = setPeriodic """ gmsh.model.mesh.getPeriodicNodes(dim, tag, includeHighOrderNodes = false) Get the master entity `tagMaster`, the node tags `nodeTags` and their corresponding master node tags `nodeTagsMaster`, and the affine transform `affineTransform` for the entity of dimension `dim` and tag `tag`. If `includeHighOrderNodes` is set, include high-order nodes in the returned data. Return `tagMaster`, `nodeTags`, `nodeTagsMaster`, `affineTransform`. """ function getPeriodicNodes(dim, tag, includeHighOrderNodes = false) api_tagMaster_ = Ref{Cint}() api_nodeTags_ = Ref{Ptr{Csize_t}}() api_nodeTags_n_ = Ref{Csize_t}() api_nodeTagsMaster_ = Ref{Ptr{Csize_t}}() api_nodeTagsMaster_n_ = Ref{Csize_t}() api_affineTransform_ = Ref{Ptr{Cdouble}}() api_affineTransform_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelMeshGetPeriodicNodes, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cint}, Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Cint, Ptr{Cint}), dim, tag, api_tagMaster_, api_nodeTags_, api_nodeTags_n_, api_nodeTagsMaster_, api_nodeTagsMaster_n_, api_affineTransform_, api_affineTransform_n_, includeHighOrderNodes, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) nodeTags = unsafe_wrap(Array, api_nodeTags_[], api_nodeTags_n_[], own=true) nodeTagsMaster = unsafe_wrap(Array, api_nodeTagsMaster_[], api_nodeTagsMaster_n_[], own=true) affineTransform = unsafe_wrap(Array, api_affineTransform_[], api_affineTransform_n_[], own=true) return api_tagMaster_[], nodeTags, nodeTagsMaster, affineTransform end const get_periodic_nodes = getPeriodicNodes """ gmsh.model.mesh.removeDuplicateNodes() Remove duplicate nodes in the mesh of the current model. """ function removeDuplicateNodes() ierr = Ref{Cint}() ccall((:gmshModelMeshRemoveDuplicateNodes, gmsh.lib), Cvoid, (Ptr{Cint},), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const remove_duplicate_nodes = removeDuplicateNodes """ gmsh.model.mesh.splitQuadrangles(quality = 1., tag = -1) Split (into two triangles) all quadrangles in surface `tag` whose quality is lower than `quality`. If `tag` < 0, split quadrangles in all surfaces. """ function splitQuadrangles(quality = 1., tag = -1) ierr = Ref{Cint}() ccall((:gmshModelMeshSplitQuadrangles, gmsh.lib), Cvoid, (Cdouble, Cint, Ptr{Cint}), quality, tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const split_quadrangles = splitQuadrangles """ gmsh.model.mesh.classifySurfaces(angle, boundary = true, forReparametrization = false, curveAngle = pi, exportDiscrete = true) Classify ("color") the surface mesh based on the angle threshold `angle` (in radians), and create new discrete surfaces, curves and points accordingly. If `boundary` is set, also create discrete curves on the boundary if the surface is open. If `forReparametrization` is set, create edges and surfaces that can be reparametrized using a single map. If `curveAngle` is less than Pi, also force curves to be split according to `curveAngle`. If `exportDiscrete` is set, clear any built-in CAD kernel entities and export the discrete entities in the built- in CAD kernel. """ function classifySurfaces(angle, boundary = true, forReparametrization = false, curveAngle = pi, exportDiscrete = true) ierr = Ref{Cint}() ccall((:gmshModelMeshClassifySurfaces, gmsh.lib), Cvoid, (Cdouble, Cint, Cint, Cdouble, Cint, Ptr{Cint}), angle, boundary, forReparametrization, curveAngle, exportDiscrete, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const classify_surfaces = classifySurfaces """ gmsh.model.mesh.createGeometry(dimTags = Tuple{Cint,Cint}[]) Create a geometry for the discrete entities `dimTags` (represented solely by a mesh, without an underlying CAD description), i.e. create a parametrization for discrete curves and surfaces, assuming that each can be parametrized with a single map. If `dimTags` is empty, create a geometry for all the discrete entities. """ function createGeometry(dimTags = Tuple{Cint,Cint}[]) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelMeshCreateGeometry, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Ptr{Cint}), api_dimTags_, api_dimTags_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const create_geometry = createGeometry """ gmsh.model.mesh.createTopology(makeSimplyConnected = true, exportDiscrete = true) Create a boundary representation from the mesh if the model does not have one (e.g. when imported from mesh file formats with no BRep representation of the underlying model). If `makeSimplyConnected` is set, enforce simply connected discrete surfaces and volumes. If `exportDiscrete` is set, clear any built-in CAD kernel entities and export the discrete entities in the built-in CAD kernel. """ function createTopology(makeSimplyConnected = true, exportDiscrete = true) ierr = Ref{Cint}() ccall((:gmshModelMeshCreateTopology, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cint}), makeSimplyConnected, exportDiscrete, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const create_topology = createTopology """ gmsh.model.mesh.computeHomology(domainTags = Cint[], subdomainTags = Cint[], dims = Cint[]) Compute a basis representation for homology spaces after a mesh has been generated. The computation domain is given in a list of physical group tags `domainTags`; if empty, the whole mesh is the domain. The computation subdomain for relative homology computation is given in a list of physical group tags `subdomainTags`; if empty, absolute homology is computed. The dimensions homology bases to be computed are given in the list `dim`; if empty, all bases are computed. Resulting basis representation chains are stored as physical groups in the mesh. """ function computeHomology(domainTags = Cint[], subdomainTags = Cint[], dims = Cint[]) ierr = Ref{Cint}() ccall((:gmshModelMeshComputeHomology, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Ptr{Cint}, Csize_t, Ptr{Cint}, Csize_t, Ptr{Cint}), convert(Vector{Cint}, domainTags), length(domainTags), convert(Vector{Cint}, subdomainTags), length(subdomainTags), convert(Vector{Cint}, dims), length(dims), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const compute_homology = computeHomology """ gmsh.model.mesh.computeCohomology(domainTags = Cint[], subdomainTags = Cint[], dims = Cint[]) Compute a basis representation for cohomology spaces after a mesh has been generated. The computation domain is given in a list of physical group tags `domainTags`; if empty, the whole mesh is the domain. The computation subdomain for relative cohomology computation is given in a list of physical group tags `subdomainTags`; if empty, absolute cohomology is computed. The dimensions homology bases to be computed are given in the list `dim`; if empty, all bases are computed. Resulting basis representation cochains are stored as physical groups in the mesh. """ function computeCohomology(domainTags = Cint[], subdomainTags = Cint[], dims = Cint[]) ierr = Ref{Cint}() ccall((:gmshModelMeshComputeCohomology, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Ptr{Cint}, Csize_t, Ptr{Cint}, Csize_t, Ptr{Cint}), convert(Vector{Cint}, domainTags), length(domainTags), convert(Vector{Cint}, subdomainTags), length(subdomainTags), convert(Vector{Cint}, dims), length(dims), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const compute_cohomology = computeCohomology """ gmsh.model.mesh.computeCrossField() Compute a cross field for the current mesh. The function creates 3 views: the H function, the Theta function and cross directions. Return the tags of the views. Return `viewTags`. """ function computeCrossField() api_viewTags_ = Ref{Ptr{Cint}}() api_viewTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelMeshComputeCrossField, gmsh.lib), Cvoid, (Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Cint}), api_viewTags_, api_viewTags_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) viewTags = unsafe_wrap(Array, api_viewTags_[], api_viewTags_n_[], own=true) return viewTags end const compute_cross_field = computeCrossField """ gmsh.model.mesh.triangulate(coord) Triangulate the points given in the `coord` vector as pairs of u, v coordinates, and return the node tags (with numbering starting at 1) of the resulting triangles in `tri`. Return `tri`. """ function triangulate(coord) api_tri_ = Ref{Ptr{Csize_t}}() api_tri_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelMeshTriangulate, gmsh.lib), Cvoid, (Ptr{Cdouble}, Csize_t, Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Ptr{Cint}), convert(Vector{Cdouble}, coord), length(coord), api_tri_, api_tri_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tri = unsafe_wrap(Array, api_tri_[], api_tri_n_[], own=true) return tri end """ gmsh.model.mesh.tetrahedralize(coord) Tetrahedralize the points given in the `coord` vector as triplets of x, y, z coordinates, and return the node tags (with numbering starting at 1) of the resulting tetrahedra in `tetra`. Return `tetra`. """ function tetrahedralize(coord) api_tetra_ = Ref{Ptr{Csize_t}}() api_tetra_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelMeshTetrahedralize, gmsh.lib), Cvoid, (Ptr{Cdouble}, Csize_t, Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Ptr{Cint}), convert(Vector{Cdouble}, coord), length(coord), api_tetra_, api_tetra_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tetra = unsafe_wrap(Array, api_tetra_[], api_tetra_n_[], own=true) return tetra end """ module gmsh.model.mesh.field Mesh size field functions """ module field import ....gmsh """ gmsh.model.mesh.field.add(fieldType, tag = -1) Add a new mesh size field of type `fieldType`. If `tag` is positive, assign the tag explicitly; otherwise a new tag is assigned automatically. Return the field tag. Return an integer value. """ function add(fieldType, tag = -1) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelMeshFieldAdd, gmsh.lib), Cint, (Ptr{Cchar}, Cint, Ptr{Cint}), fieldType, tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end """ gmsh.model.mesh.field.remove(tag) Remove the field with tag `tag`. """ function remove(tag) ierr = Ref{Cint}() ccall((:gmshModelMeshFieldRemove, gmsh.lib), Cvoid, (Cint, Ptr{Cint}), tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.model.mesh.field.setNumber(tag, option, value) Set the numerical option `option` to value `value` for field `tag`. """ function setNumber(tag, option, value) ierr = Ref{Cint}() ccall((:gmshModelMeshFieldSetNumber, gmsh.lib), Cvoid, (Cint, Ptr{Cchar}, Cdouble, Ptr{Cint}), tag, option, value, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_number = setNumber """ gmsh.model.mesh.field.setString(tag, option, value) Set the string option `option` to value `value` for field `tag`. """ function setString(tag, option, value) ierr = Ref{Cint}() ccall((:gmshModelMeshFieldSetString, gmsh.lib), Cvoid, (Cint, Ptr{Cchar}, Ptr{Cchar}, Ptr{Cint}), tag, option, value, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_string = setString """ gmsh.model.mesh.field.setNumbers(tag, option, value) Set the numerical list option `option` to value `value` for field `tag`. """ function setNumbers(tag, option, value) ierr = Ref{Cint}() ccall((:gmshModelMeshFieldSetNumbers, gmsh.lib), Cvoid, (Cint, Ptr{Cchar}, Ptr{Cdouble}, Csize_t, Ptr{Cint}), tag, option, convert(Vector{Cdouble}, value), length(value), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_numbers = setNumbers """ gmsh.model.mesh.field.setAsBackgroundMesh(tag) Set the field `tag` as the background mesh size field. """ function setAsBackgroundMesh(tag) ierr = Ref{Cint}() ccall((:gmshModelMeshFieldSetAsBackgroundMesh, gmsh.lib), Cvoid, (Cint, Ptr{Cint}), tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_as_background_mesh = setAsBackgroundMesh """ gmsh.model.mesh.field.setAsBoundaryLayer(tag) Set the field `tag` as a boundary layer size field. """ function setAsBoundaryLayer(tag) ierr = Ref{Cint}() ccall((:gmshModelMeshFieldSetAsBoundaryLayer, gmsh.lib), Cvoid, (Cint, Ptr{Cint}), tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_as_boundary_layer = setAsBoundaryLayer end # end of module field end # end of module mesh """ module gmsh.model.geo Built-in CAD kernel functions """ module geo import ...gmsh """ gmsh.model.geo.addPoint(x, y, z, meshSize = 0., tag = -1) Add a geometrical point in the built-in CAD representation, at coordinates (`x`, `y`, `z`). If `meshSize` is > 0, add a meshing constraint at that point. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Return the tag of the point. (Note that the point will be added in the current model only after `synchronize` is called. This behavior holds for all the entities added in the geo module.) Return an integer value. """ function addPoint(x, y, z, meshSize = 0., tag = -1) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelGeoAddPoint, gmsh.lib), Cint, (Cdouble, Cdouble, Cdouble, Cdouble, Cint, Ptr{Cint}), x, y, z, meshSize, tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_point = addPoint """ gmsh.model.geo.addLine(startTag, endTag, tag = -1) Add a straight line segment in the built-in CAD representation, between the two points with tags `startTag` and `endTag`. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Return the tag of the line. Return an integer value. """ function addLine(startTag, endTag, tag = -1) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelGeoAddLine, gmsh.lib), Cint, (Cint, Cint, Cint, Ptr{Cint}), startTag, endTag, tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_line = addLine """ gmsh.model.geo.addCircleArc(startTag, centerTag, endTag, tag = -1, nx = 0., ny = 0., nz = 0.) Add a circle arc (strictly smaller than Pi) in the built-in CAD representation, between the two points with tags `startTag` and `endTag`, and with center `centerTag`. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. If (`nx`, `ny`, `nz`) != (0, 0, 0), explicitly set the plane of the circle arc. Return the tag of the circle arc. Return an integer value. """ function addCircleArc(startTag, centerTag, endTag, tag = -1, nx = 0., ny = 0., nz = 0.) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelGeoAddCircleArc, gmsh.lib), Cint, (Cint, Cint, Cint, Cint, Cdouble, Cdouble, Cdouble, Ptr{Cint}), startTag, centerTag, endTag, tag, nx, ny, nz, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_circle_arc = addCircleArc """ gmsh.model.geo.addEllipseArc(startTag, centerTag, majorTag, endTag, tag = -1, nx = 0., ny = 0., nz = 0.) Add an ellipse arc (strictly smaller than Pi) in the built-in CAD representation, between the two points `startTag` and `endTag`, and with center `centerTag` and major axis point `majorTag`. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. If (`nx`, `ny`, `nz`) != (0, 0, 0), explicitly set the plane of the circle arc. Return the tag of the ellipse arc. Return an integer value. """ function addEllipseArc(startTag, centerTag, majorTag, endTag, tag = -1, nx = 0., ny = 0., nz = 0.) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelGeoAddEllipseArc, gmsh.lib), Cint, (Cint, Cint, Cint, Cint, Cint, Cdouble, Cdouble, Cdouble, Ptr{Cint}), startTag, centerTag, majorTag, endTag, tag, nx, ny, nz, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_ellipse_arc = addEllipseArc """ gmsh.model.geo.addSpline(pointTags, tag = -1) Add a spline (Catmull-Rom) curve in the built-in CAD representation, going through the points `pointTags`. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Create a periodic curve if the first and last points are the same. Return the tag of the spline curve. Return an integer value. """ function addSpline(pointTags, tag = -1) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelGeoAddSpline, gmsh.lib), Cint, (Ptr{Cint}, Csize_t, Cint, Ptr{Cint}), convert(Vector{Cint}, pointTags), length(pointTags), tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_spline = addSpline """ gmsh.model.geo.addBSpline(pointTags, tag = -1) Add a cubic b-spline curve in the built-in CAD representation, with `pointTags` control points. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Creates a periodic curve if the first and last points are the same. Return the tag of the b-spline curve. Return an integer value. """ function addBSpline(pointTags, tag = -1) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelGeoAddBSpline, gmsh.lib), Cint, (Ptr{Cint}, Csize_t, Cint, Ptr{Cint}), convert(Vector{Cint}, pointTags), length(pointTags), tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_bspline = addBSpline """ gmsh.model.geo.addBezier(pointTags, tag = -1) Add a Bezier curve in the built-in CAD representation, with `pointTags` control points. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Return the tag of the Bezier curve. Return an integer value. """ function addBezier(pointTags, tag = -1) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelGeoAddBezier, gmsh.lib), Cint, (Ptr{Cint}, Csize_t, Cint, Ptr{Cint}), convert(Vector{Cint}, pointTags), length(pointTags), tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_bezier = addBezier """ gmsh.model.geo.addPolyline(pointTags, tag = -1) Add a polyline curve in the built-in CAD representation, going through the points `pointTags`. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Create a periodic curve if the first and last points are the same. Return the tag of the polyline curve. Return an integer value. """ function addPolyline(pointTags, tag = -1) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelGeoAddPolyline, gmsh.lib), Cint, (Ptr{Cint}, Csize_t, Cint, Ptr{Cint}), convert(Vector{Cint}, pointTags), length(pointTags), tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_polyline = addPolyline """ gmsh.model.geo.addCompoundSpline(curveTags, numIntervals = 5, tag = -1) Add a spline (Catmull-Rom) curve in the built-in CAD representation, going through points sampling the curves in `curveTags`. The density of sampling points on each curve is governed by `numIntervals`. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Return the tag of the spline. Return an integer value. """ function addCompoundSpline(curveTags, numIntervals = 5, tag = -1) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelGeoAddCompoundSpline, gmsh.lib), Cint, (Ptr{Cint}, Csize_t, Cint, Cint, Ptr{Cint}), convert(Vector{Cint}, curveTags), length(curveTags), numIntervals, tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_compound_spline = addCompoundSpline """ gmsh.model.geo.addCompoundBSpline(curveTags, numIntervals = 20, tag = -1) Add a b-spline curve in the built-in CAD representation, with control points sampling the curves in `curveTags`. The density of sampling points on each curve is governed by `numIntervals`. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Return the tag of the b-spline. Return an integer value. """ function addCompoundBSpline(curveTags, numIntervals = 20, tag = -1) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelGeoAddCompoundBSpline, gmsh.lib), Cint, (Ptr{Cint}, Csize_t, Cint, Cint, Ptr{Cint}), convert(Vector{Cint}, curveTags), length(curveTags), numIntervals, tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_compound_bspline = addCompoundBSpline """ gmsh.model.geo.addCurveLoop(curveTags, tag = -1, reorient = false) Add a curve loop (a closed wire) in the built-in CAD representation, formed by the curves `curveTags`. `curveTags` should contain (signed) tags of model entities of dimension 1 forming a closed loop: a negative tag signifies that the underlying curve is considered with reversed orientation. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. If `reorient` is set, automatically reorient the curves if necessary. Return the tag of the curve loop. Return an integer value. """ function addCurveLoop(curveTags, tag = -1, reorient = false) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelGeoAddCurveLoop, gmsh.lib), Cint, (Ptr{Cint}, Csize_t, Cint, Cint, Ptr{Cint}), convert(Vector{Cint}, curveTags), length(curveTags), tag, reorient, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_curve_loop = addCurveLoop """ gmsh.model.geo.addCurveLoops(curveTags) Add curve loops in the built-in CAD representation based on the curves `curveTags`. Return the `tags` of found curve loops, if any. Return `tags`. """ function addCurveLoops(curveTags) api_tags_ = Ref{Ptr{Cint}}() api_tags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelGeoAddCurveLoops, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Cint}), convert(Vector{Cint}, curveTags), length(curveTags), api_tags_, api_tags_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tags = unsafe_wrap(Array, api_tags_[], api_tags_n_[], own=true) return tags end const add_curve_loops = addCurveLoops """ gmsh.model.geo.addPlaneSurface(wireTags, tag = -1) Add a plane surface in the built-in CAD representation, defined by one or more curve loops `wireTags`. The first curve loop defines the exterior contour; additional curve loop define holes. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Return the tag of the surface. Return an integer value. """ function addPlaneSurface(wireTags, tag = -1) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelGeoAddPlaneSurface, gmsh.lib), Cint, (Ptr{Cint}, Csize_t, Cint, Ptr{Cint}), convert(Vector{Cint}, wireTags), length(wireTags), tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_plane_surface = addPlaneSurface """ gmsh.model.geo.addSurfaceFilling(wireTags, tag = -1, sphereCenterTag = -1) Add a surface in the built-in CAD representation, filling the curve loops in `wireTags` using transfinite interpolation. Currently only a single curve loop is supported; this curve loop should be composed by 3 or 4 curves only. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Return the tag of the surface. Return an integer value. """ function addSurfaceFilling(wireTags, tag = -1, sphereCenterTag = -1) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelGeoAddSurfaceFilling, gmsh.lib), Cint, (Ptr{Cint}, Csize_t, Cint, Cint, Ptr{Cint}), convert(Vector{Cint}, wireTags), length(wireTags), tag, sphereCenterTag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_surface_filling = addSurfaceFilling """ gmsh.model.geo.addSurfaceLoop(surfaceTags, tag = -1) Add a surface loop (a closed shell) formed by `surfaceTags` in the built-in CAD representation. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Return the tag of the shell. Return an integer value. """ function addSurfaceLoop(surfaceTags, tag = -1) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelGeoAddSurfaceLoop, gmsh.lib), Cint, (Ptr{Cint}, Csize_t, Cint, Ptr{Cint}), convert(Vector{Cint}, surfaceTags), length(surfaceTags), tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_surface_loop = addSurfaceLoop """ gmsh.model.geo.addVolume(shellTags, tag = -1) Add a volume (a region) in the built-in CAD representation, defined by one or more shells `shellTags`. The first surface loop defines the exterior boundary; additional surface loop define holes. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Return the tag of the volume. Return an integer value. """ function addVolume(shellTags, tag = -1) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelGeoAddVolume, gmsh.lib), Cint, (Ptr{Cint}, Csize_t, Cint, Ptr{Cint}), convert(Vector{Cint}, shellTags), length(shellTags), tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_volume = addVolume """ gmsh.model.geo.extrude(dimTags, dx, dy, dz, numElements = Cint[], heights = Cdouble[], recombine = false) Extrude the entities `dimTags` in the built-in CAD representation, using a translation along (`dx`, `dy`, `dz`). Return extruded entities in `outDimTags`. If `numElements` is not empty, also extrude the mesh: the entries in `numElements` give the number of elements in each layer. If `height` is not empty, it provides the (cumulative) height of the different layers, normalized to 1. If `recombine` is set, recombine the mesh in the layers. Return `outDimTags`. """ function extrude(dimTags, dx, dy, dz, numElements = Cint[], heights = Cdouble[], recombine = false) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) api_outDimTags_ = Ref{Ptr{Cint}}() api_outDimTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelGeoExtrude, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Cdouble, Cdouble, Cdouble, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Cint}, Csize_t, Ptr{Cdouble}, Csize_t, Cint, Ptr{Cint}), api_dimTags_, api_dimTags_n_, dx, dy, dz, api_outDimTags_, api_outDimTags_n_, convert(Vector{Cint}, numElements), length(numElements), convert(Vector{Cdouble}, heights), length(heights), recombine, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_outDimTags_ = unsafe_wrap(Array, api_outDimTags_[], api_outDimTags_n_[], own=true) outDimTags = [ (tmp_api_outDimTags_[i], tmp_api_outDimTags_[i+1]) for i in 1:2:length(tmp_api_outDimTags_) ] return outDimTags end """ gmsh.model.geo.revolve(dimTags, x, y, z, ax, ay, az, angle, numElements = Cint[], heights = Cdouble[], recombine = false) Extrude the entities `dimTags` in the built-in CAD representation, using a rotation of `angle` radians around the axis of revolution defined by the point (`x`, `y`, `z`) and the direction (`ax`, `ay`, `az`). The angle should be strictly smaller than Pi. Return extruded entities in `outDimTags`. If `numElements` is not empty, also extrude the mesh: the entries in `numElements` give the number of elements in each layer. If `height` is not empty, it provides the (cumulative) height of the different layers, normalized to 1. If `recombine` is set, recombine the mesh in the layers. Return `outDimTags`. """ function revolve(dimTags, x, y, z, ax, ay, az, angle, numElements = Cint[], heights = Cdouble[], recombine = false) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) api_outDimTags_ = Ref{Ptr{Cint}}() api_outDimTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelGeoRevolve, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Cint}, Csize_t, Ptr{Cdouble}, Csize_t, Cint, Ptr{Cint}), api_dimTags_, api_dimTags_n_, x, y, z, ax, ay, az, angle, api_outDimTags_, api_outDimTags_n_, convert(Vector{Cint}, numElements), length(numElements), convert(Vector{Cdouble}, heights), length(heights), recombine, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_outDimTags_ = unsafe_wrap(Array, api_outDimTags_[], api_outDimTags_n_[], own=true) outDimTags = [ (tmp_api_outDimTags_[i], tmp_api_outDimTags_[i+1]) for i in 1:2:length(tmp_api_outDimTags_) ] return outDimTags end """ gmsh.model.geo.twist(dimTags, x, y, z, dx, dy, dz, ax, ay, az, angle, numElements = Cint[], heights = Cdouble[], recombine = false) Extrude the entities `dimTags` in the built-in CAD representation, using a combined translation and rotation of `angle` radians, along (`dx`, `dy`, `dz`) and around the axis of revolution defined by the point (`x`, `y`, `z`) and the direction (`ax`, `ay`, `az`). The angle should be strictly smaller than Pi. Return extruded entities in `outDimTags`. If `numElements` is not empty, also extrude the mesh: the entries in `numElements` give the number of elements in each layer. If `height` is not empty, it provides the (cumulative) height of the different layers, normalized to 1. If `recombine` is set, recombine the mesh in the layers. Return `outDimTags`. """ function twist(dimTags, x, y, z, dx, dy, dz, ax, ay, az, angle, numElements = Cint[], heights = Cdouble[], recombine = false) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) api_outDimTags_ = Ref{Ptr{Cint}}() api_outDimTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelGeoTwist, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Cint}, Csize_t, Ptr{Cdouble}, Csize_t, Cint, Ptr{Cint}), api_dimTags_, api_dimTags_n_, x, y, z, dx, dy, dz, ax, ay, az, angle, api_outDimTags_, api_outDimTags_n_, convert(Vector{Cint}, numElements), length(numElements), convert(Vector{Cdouble}, heights), length(heights), recombine, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_outDimTags_ = unsafe_wrap(Array, api_outDimTags_[], api_outDimTags_n_[], own=true) outDimTags = [ (tmp_api_outDimTags_[i], tmp_api_outDimTags_[i+1]) for i in 1:2:length(tmp_api_outDimTags_) ] return outDimTags end """ gmsh.model.geo.extrudeBoundaryLayer(dimTags, numElements = [1], heights = Cdouble[], recombine = false, second = false, viewIndex = -1) Extrude the entities `dimTags` in the built-in CAD representation along the normals of the mesh, creating discrete boundary layer entities. Return extruded entities in `outDimTags`. The entries in `numElements` give the number of elements in each layer. If `height` is not empty, it provides the height of the different layers. If `recombine` is set, recombine the mesh in the layers. A second boundary layer can be created from the same entities if `second` is set. If `viewIndex` is >= 0, use the corresponding view to either specify the normals (if the view contains a vector field) or scale the normals (if the view is scalar). Return `outDimTags`. """ function extrudeBoundaryLayer(dimTags, numElements = [1], heights = Cdouble[], recombine = false, second = false, viewIndex = -1) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) api_outDimTags_ = Ref{Ptr{Cint}}() api_outDimTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelGeoExtrudeBoundaryLayer, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Cint}, Csize_t, Ptr{Cdouble}, Csize_t, Cint, Cint, Cint, Ptr{Cint}), api_dimTags_, api_dimTags_n_, api_outDimTags_, api_outDimTags_n_, convert(Vector{Cint}, numElements), length(numElements), convert(Vector{Cdouble}, heights), length(heights), recombine, second, viewIndex, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_outDimTags_ = unsafe_wrap(Array, api_outDimTags_[], api_outDimTags_n_[], own=true) outDimTags = [ (tmp_api_outDimTags_[i], tmp_api_outDimTags_[i+1]) for i in 1:2:length(tmp_api_outDimTags_) ] return outDimTags end const extrude_boundary_layer = extrudeBoundaryLayer """ gmsh.model.geo.translate(dimTags, dx, dy, dz) Translate the entities `dimTags` in the built-in CAD representation along (`dx`, `dy`, `dz`). """ function translate(dimTags, dx, dy, dz) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelGeoTranslate, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Cdouble, Cdouble, Cdouble, Ptr{Cint}), api_dimTags_, api_dimTags_n_, dx, dy, dz, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.model.geo.rotate(dimTags, x, y, z, ax, ay, az, angle) Rotate the entities `dimTags` in the built-in CAD representation by `angle` radians around the axis of revolution defined by the point (`x`, `y`, `z`) and the direction (`ax`, `ay`, `az`). """ function rotate(dimTags, x, y, z, ax, ay, az, angle) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelGeoRotate, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Ptr{Cint}), api_dimTags_, api_dimTags_n_, x, y, z, ax, ay, az, angle, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.model.geo.dilate(dimTags, x, y, z, a, b, c) Scale the entities `dimTag` in the built-in CAD representation by factors `a`, `b` and `c` along the three coordinate axes; use (`x`, `y`, `z`) as the center of the homothetic transformation. """ function dilate(dimTags, x, y, z, a, b, c) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelGeoDilate, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Ptr{Cint}), api_dimTags_, api_dimTags_n_, x, y, z, a, b, c, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.model.geo.mirror(dimTags, a, b, c, d) Mirror the entities `dimTag` in the built-in CAD representation, with respect to the plane of equation `a` * x + `b` * y + `c` * z + `d` = 0. """ function mirror(dimTags, a, b, c, d) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelGeoMirror, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Cdouble, Cdouble, Cdouble, Cdouble, Ptr{Cint}), api_dimTags_, api_dimTags_n_, a, b, c, d, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.model.geo.symmetrize(dimTags, a, b, c, d) Mirror the entities `dimTag` in the built-in CAD representation, with respect to the plane of equation `a` * x + `b` * y + `c` * z + `d` = 0. (This is a synonym for `mirror`, which will be deprecated in a future release.) """ function symmetrize(dimTags, a, b, c, d) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelGeoSymmetrize, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Cdouble, Cdouble, Cdouble, Cdouble, Ptr{Cint}), api_dimTags_, api_dimTags_n_, a, b, c, d, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.model.geo.copy(dimTags) Copy the entities `dimTags` in the built-in CAD representation; the new entities are returned in `outDimTags`. Return `outDimTags`. """ function copy(dimTags) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) api_outDimTags_ = Ref{Ptr{Cint}}() api_outDimTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelGeoCopy, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Cint}), api_dimTags_, api_dimTags_n_, api_outDimTags_, api_outDimTags_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_outDimTags_ = unsafe_wrap(Array, api_outDimTags_[], api_outDimTags_n_[], own=true) outDimTags = [ (tmp_api_outDimTags_[i], tmp_api_outDimTags_[i+1]) for i in 1:2:length(tmp_api_outDimTags_) ] return outDimTags end """ gmsh.model.geo.remove(dimTags, recursive = false) Remove the entities `dimTags` in the built-in CAD representation, provided that they are not on the boundary of higher-dimensional entities. If `recursive` is true, remove all the entities on their boundaries, down to dimension 0. """ function remove(dimTags, recursive = false) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelGeoRemove, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Cint, Ptr{Cint}), api_dimTags_, api_dimTags_n_, recursive, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.model.geo.removeAllDuplicates() Remove all duplicate entities in the built-in CAD representation (different entities at the same geometrical location). """ function removeAllDuplicates() ierr = Ref{Cint}() ccall((:gmshModelGeoRemoveAllDuplicates, gmsh.lib), Cvoid, (Ptr{Cint},), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const remove_all_duplicates = removeAllDuplicates """ gmsh.model.geo.splitCurve(tag, pointTags) Split the curve of tag `tag` in the built-in CAD representation, on the control points `pointTags`. Return the tags `curveTags` of the newly created curves. Return `curveTags`. """ function splitCurve(tag, pointTags) api_curveTags_ = Ref{Ptr{Cint}}() api_curveTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelGeoSplitCurve, gmsh.lib), Cvoid, (Cint, Ptr{Cint}, Csize_t, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Cint}), tag, convert(Vector{Cint}, pointTags), length(pointTags), api_curveTags_, api_curveTags_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) curveTags = unsafe_wrap(Array, api_curveTags_[], api_curveTags_n_[], own=true) return curveTags end const split_curve = splitCurve """ gmsh.model.geo.getMaxTag(dim) Get the maximum tag of entities of dimension `dim` in the built-in CAD representation. Return an integer value. """ function getMaxTag(dim) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelGeoGetMaxTag, gmsh.lib), Cint, (Cint, Ptr{Cint}), dim, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const get_max_tag = getMaxTag """ gmsh.model.geo.setMaxTag(dim, maxTag) Set the maximum tag `maxTag` for entities of dimension `dim` in the built-in CAD representation. """ function setMaxTag(dim, maxTag) ierr = Ref{Cint}() ccall((:gmshModelGeoSetMaxTag, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cint}), dim, maxTag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_max_tag = setMaxTag """ gmsh.model.geo.addPhysicalGroup(dim, tags, tag = -1) Add a physical group of dimension `dim`, grouping the entities with tags `tags` in the built-in CAD representation. Return the tag of the physical group, equal to `tag` if `tag` is positive, or a new tag if `tag` < 0. Return an integer value. """ function addPhysicalGroup(dim, tags, tag = -1) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelGeoAddPhysicalGroup, gmsh.lib), Cint, (Cint, Ptr{Cint}, Csize_t, Cint, Ptr{Cint}), dim, convert(Vector{Cint}, tags), length(tags), tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_physical_group = addPhysicalGroup """ gmsh.model.geo.removePhysicalGroups(dimTags = Tuple{Cint,Cint}[]) Remove the physical groups `dimTags` from the built-in CAD representation. If `dimTags` is empty, remove all groups. """ function removePhysicalGroups(dimTags = Tuple{Cint,Cint}[]) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelGeoRemovePhysicalGroups, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Ptr{Cint}), api_dimTags_, api_dimTags_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const remove_physical_groups = removePhysicalGroups """ gmsh.model.geo.synchronize() Synchronize the built-in CAD representation with the current Gmsh model. This can be called at any time, but since it involves a non trivial amount of processing, the number of synchronization points should normally be minimized. Without synchronization the entities in the built-in CAD representation are not available to any function outside of the built-in CAD kernel functions. """ function synchronize() ierr = Ref{Cint}() ccall((:gmshModelGeoSynchronize, gmsh.lib), Cvoid, (Ptr{Cint},), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ module gmsh.model.geo.mesh Built-in CAD kernel meshing constraints """ module mesh import ....gmsh """ gmsh.model.geo.mesh.setSize(dimTags, size) Set a mesh size constraint on the entities `dimTags` in the built-in CAD kernel representation. Currently only entities of dimension 0 (points) are handled. """ function setSize(dimTags, size) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelGeoMeshSetSize, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Cdouble, Ptr{Cint}), api_dimTags_, api_dimTags_n_, size, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_size = setSize """ gmsh.model.geo.mesh.setTransfiniteCurve(tag, nPoints, meshType = "Progression", coef = 1.) Set a transfinite meshing constraint on the curve `tag` in the built-in CAD kernel representation, with `numNodes` nodes distributed according to `meshType` and `coef`. Currently supported types are "Progression" (geometrical progression with power `coef`) and "Bump" (refinement toward both extremities of the curve). """ function setTransfiniteCurve(tag, nPoints, meshType = "Progression", coef = 1.) ierr = Ref{Cint}() ccall((:gmshModelGeoMeshSetTransfiniteCurve, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cchar}, Cdouble, Ptr{Cint}), tag, nPoints, meshType, coef, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_transfinite_curve = setTransfiniteCurve """ gmsh.model.geo.mesh.setTransfiniteSurface(tag, arrangement = "Left", cornerTags = Cint[]) Set a transfinite meshing constraint on the surface `tag` in the built-in CAD kernel representation. `arrangement` describes the arrangement of the triangles when the surface is not flagged as recombined: currently supported values are "Left", "Right", "AlternateLeft" and "AlternateRight". `cornerTags` can be used to specify the (3 or 4) corners of the transfinite interpolation explicitly; specifying the corners explicitly is mandatory if the surface has more that 3 or 4 points on its boundary. """ function setTransfiniteSurface(tag, arrangement = "Left", cornerTags = Cint[]) ierr = Ref{Cint}() ccall((:gmshModelGeoMeshSetTransfiniteSurface, gmsh.lib), Cvoid, (Cint, Ptr{Cchar}, Ptr{Cint}, Csize_t, Ptr{Cint}), tag, arrangement, convert(Vector{Cint}, cornerTags), length(cornerTags), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_transfinite_surface = setTransfiniteSurface """ gmsh.model.geo.mesh.setTransfiniteVolume(tag, cornerTags = Cint[]) Set a transfinite meshing constraint on the surface `tag` in the built-in CAD kernel representation. `cornerTags` can be used to specify the (6 or 8) corners of the transfinite interpolation explicitly. """ function setTransfiniteVolume(tag, cornerTags = Cint[]) ierr = Ref{Cint}() ccall((:gmshModelGeoMeshSetTransfiniteVolume, gmsh.lib), Cvoid, (Cint, Ptr{Cint}, Csize_t, Ptr{Cint}), tag, convert(Vector{Cint}, cornerTags), length(cornerTags), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_transfinite_volume = setTransfiniteVolume """ gmsh.model.geo.mesh.setRecombine(dim, tag, angle = 45.) Set a recombination meshing constraint on the entity of dimension `dim` and tag `tag` in the built-in CAD kernel representation. Currently only entities of dimension 2 (to recombine triangles into quadrangles) are supported. """ function setRecombine(dim, tag, angle = 45.) ierr = Ref{Cint}() ccall((:gmshModelGeoMeshSetRecombine, gmsh.lib), Cvoid, (Cint, Cint, Cdouble, Ptr{Cint}), dim, tag, angle, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_recombine = setRecombine """ gmsh.model.geo.mesh.setSmoothing(dim, tag, val) Set a smoothing meshing constraint on the entity of dimension `dim` and tag `tag` in the built-in CAD kernel representation. `val` iterations of a Laplace smoother are applied. """ function setSmoothing(dim, tag, val) ierr = Ref{Cint}() ccall((:gmshModelGeoMeshSetSmoothing, gmsh.lib), Cvoid, (Cint, Cint, Cint, Ptr{Cint}), dim, tag, val, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_smoothing = setSmoothing """ gmsh.model.geo.mesh.setReverse(dim, tag, val = true) Set a reverse meshing constraint on the entity of dimension `dim` and tag `tag` in the built-in CAD kernel representation. If `val` is true, the mesh orientation will be reversed with respect to the natural mesh orientation (i.e. the orientation consistent with the orientation of the geometry). If `val` is false, the mesh is left as-is. """ function setReverse(dim, tag, val = true) ierr = Ref{Cint}() ccall((:gmshModelGeoMeshSetReverse, gmsh.lib), Cvoid, (Cint, Cint, Cint, Ptr{Cint}), dim, tag, val, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_reverse = setReverse """ gmsh.model.geo.mesh.setAlgorithm(dim, tag, val) Set the meshing algorithm on the entity of dimension `dim` and tag `tag` in the built-in CAD kernel representation. Currently only supported for `dim` == 2. """ function setAlgorithm(dim, tag, val) ierr = Ref{Cint}() ccall((:gmshModelGeoMeshSetAlgorithm, gmsh.lib), Cvoid, (Cint, Cint, Cint, Ptr{Cint}), dim, tag, val, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_algorithm = setAlgorithm """ gmsh.model.geo.mesh.setSizeFromBoundary(dim, tag, val) Force the mesh size to be extended from the boundary, or not, for the entity of dimension `dim` and tag `tag` in the built-in CAD kernel representation. Currently only supported for `dim` == 2. """ function setSizeFromBoundary(dim, tag, val) ierr = Ref{Cint}() ccall((:gmshModelGeoMeshSetSizeFromBoundary, gmsh.lib), Cvoid, (Cint, Cint, Cint, Ptr{Cint}), dim, tag, val, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_size_from_boundary = setSizeFromBoundary end # end of module mesh end # end of module geo """ module gmsh.model.occ OpenCASCADE CAD kernel functions """ module occ import ...gmsh """ gmsh.model.occ.addPoint(x, y, z, meshSize = 0., tag = -1) Add a geometrical point in the OpenCASCADE CAD representation, at coordinates (`x`, `y`, `z`). If `meshSize` is > 0, add a meshing constraint at that point. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Return the tag of the point. (Note that the point will be added in the current model only after `synchronize` is called. This behavior holds for all the entities added in the occ module.) Return an integer value. """ function addPoint(x, y, z, meshSize = 0., tag = -1) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelOccAddPoint, gmsh.lib), Cint, (Cdouble, Cdouble, Cdouble, Cdouble, Cint, Ptr{Cint}), x, y, z, meshSize, tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_point = addPoint """ gmsh.model.occ.addLine(startTag, endTag, tag = -1) Add a straight line segment in the OpenCASCADE CAD representation, between the two points with tags `startTag` and `endTag`. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Return the tag of the line. Return an integer value. """ function addLine(startTag, endTag, tag = -1) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelOccAddLine, gmsh.lib), Cint, (Cint, Cint, Cint, Ptr{Cint}), startTag, endTag, tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_line = addLine """ gmsh.model.occ.addCircleArc(startTag, centerTag, endTag, tag = -1) Add a circle arc in the OpenCASCADE CAD representation, between the two points with tags `startTag` and `endTag`, with center `centerTag`. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Return the tag of the circle arc. Return an integer value. """ function addCircleArc(startTag, centerTag, endTag, tag = -1) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelOccAddCircleArc, gmsh.lib), Cint, (Cint, Cint, Cint, Cint, Ptr{Cint}), startTag, centerTag, endTag, tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_circle_arc = addCircleArc """ gmsh.model.occ.addCircle(x, y, z, r, tag = -1, angle1 = 0., angle2 = 2*pi) Add a circle of center (`x`, `y`, `z`) and radius `r` in the OpenCASCADE CAD representation. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. If `angle1` and `angle2` are specified, create a circle arc between the two angles. Return the tag of the circle. Return an integer value. """ function addCircle(x, y, z, r, tag = -1, angle1 = 0., angle2 = 2*pi) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelOccAddCircle, gmsh.lib), Cint, (Cdouble, Cdouble, Cdouble, Cdouble, Cint, Cdouble, Cdouble, Ptr{Cint}), x, y, z, r, tag, angle1, angle2, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_circle = addCircle """ gmsh.model.occ.addEllipseArc(startTag, centerTag, majorTag, endTag, tag = -1) Add an ellipse arc in the OpenCASCADE CAD representation, between the two points `startTag` and `endTag`, and with center `centerTag` and major axis point `majorTag`. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Return the tag of the ellipse arc. Note that OpenCASCADE does not allow creating ellipse arcs with the major radius smaller than the minor radius. Return an integer value. """ function addEllipseArc(startTag, centerTag, majorTag, endTag, tag = -1) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelOccAddEllipseArc, gmsh.lib), Cint, (Cint, Cint, Cint, Cint, Cint, Ptr{Cint}), startTag, centerTag, majorTag, endTag, tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_ellipse_arc = addEllipseArc """ gmsh.model.occ.addEllipse(x, y, z, r1, r2, tag = -1, angle1 = 0., angle2 = 2*pi) Add an ellipse of center (`x`, `y`, `z`) and radii `r1` and `r2` along the x- and y-axes, respectively, in the OpenCASCADE CAD representation. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. If `angle1` and `angle2` are specified, create an ellipse arc between the two angles. Return the tag of the ellipse. Note that OpenCASCADE does not allow creating ellipses with the major radius (along the x-axis) smaller than or equal to the minor radius (along the y-axis): rotate the shape or use `addCircle` in such cases. Return an integer value. """ function addEllipse(x, y, z, r1, r2, tag = -1, angle1 = 0., angle2 = 2*pi) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelOccAddEllipse, gmsh.lib), Cint, (Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cint, Cdouble, Cdouble, Ptr{Cint}), x, y, z, r1, r2, tag, angle1, angle2, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_ellipse = addEllipse """ gmsh.model.occ.addSpline(pointTags, tag = -1) Add a spline (C2 b-spline) curve in the OpenCASCADE CAD representation, going through the points `pointTags`. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Create a periodic curve if the first and last points are the same. Return the tag of the spline curve. Return an integer value. """ function addSpline(pointTags, tag = -1) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelOccAddSpline, gmsh.lib), Cint, (Ptr{Cint}, Csize_t, Cint, Ptr{Cint}), convert(Vector{Cint}, pointTags), length(pointTags), tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_spline = addSpline """ gmsh.model.occ.addBSpline(pointTags, tag = -1, degree = 3, weights = Cdouble[], knots = Cdouble[], multiplicities = Cint[]) Add a b-spline curve of degree `degree` in the OpenCASCADE CAD representation, with `pointTags` control points. If `weights`, `knots` or `multiplicities` are not provided, default parameters are computed automatically. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Create a periodic curve if the first and last points are the same. Return the tag of the b-spline curve. Return an integer value. """ function addBSpline(pointTags, tag = -1, degree = 3, weights = Cdouble[], knots = Cdouble[], multiplicities = Cint[]) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelOccAddBSpline, gmsh.lib), Cint, (Ptr{Cint}, Csize_t, Cint, Cint, Ptr{Cdouble}, Csize_t, Ptr{Cdouble}, Csize_t, Ptr{Cint}, Csize_t, Ptr{Cint}), convert(Vector{Cint}, pointTags), length(pointTags), tag, degree, convert(Vector{Cdouble}, weights), length(weights), convert(Vector{Cdouble}, knots), length(knots), convert(Vector{Cint}, multiplicities), length(multiplicities), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_bspline = addBSpline """ gmsh.model.occ.addBezier(pointTags, tag = -1) Add a Bezier curve in the OpenCASCADE CAD representation, with `pointTags` control points. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Return the tag of the Bezier curve. Return an integer value. """ function addBezier(pointTags, tag = -1) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelOccAddBezier, gmsh.lib), Cint, (Ptr{Cint}, Csize_t, Cint, Ptr{Cint}), convert(Vector{Cint}, pointTags), length(pointTags), tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_bezier = addBezier """ gmsh.model.occ.addWire(curveTags, tag = -1, checkClosed = false) Add a wire (open or closed) in the OpenCASCADE CAD representation, formed by the curves `curveTags`. Note that an OpenCASCADE wire can be made of curves that share geometrically identical (but topologically different) points. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Return the tag of the wire. Return an integer value. """ function addWire(curveTags, tag = -1, checkClosed = false) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelOccAddWire, gmsh.lib), Cint, (Ptr{Cint}, Csize_t, Cint, Cint, Ptr{Cint}), convert(Vector{Cint}, curveTags), length(curveTags), tag, checkClosed, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_wire = addWire """ gmsh.model.occ.addCurveLoop(curveTags, tag = -1) Add a curve loop (a closed wire) in the OpenCASCADE CAD representation, formed by the curves `curveTags`. `curveTags` should contain tags of curves forming a closed loop. Note that an OpenCASCADE curve loop can be made of curves that share geometrically identical (but topologically different) points. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Return the tag of the curve loop. Return an integer value. """ function addCurveLoop(curveTags, tag = -1) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelOccAddCurveLoop, gmsh.lib), Cint, (Ptr{Cint}, Csize_t, Cint, Ptr{Cint}), convert(Vector{Cint}, curveTags), length(curveTags), tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_curve_loop = addCurveLoop """ gmsh.model.occ.addRectangle(x, y, z, dx, dy, tag = -1, roundedRadius = 0.) Add a rectangle in the OpenCASCADE CAD representation, with lower left corner at (`x`, `y`, `z`) and upper right corner at (`x` + `dx`, `y` + `dy`, `z`). If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Round the corners if `roundedRadius` is nonzero. Return the tag of the rectangle. Return an integer value. """ function addRectangle(x, y, z, dx, dy, tag = -1, roundedRadius = 0.) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelOccAddRectangle, gmsh.lib), Cint, (Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cint, Cdouble, Ptr{Cint}), x, y, z, dx, dy, tag, roundedRadius, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_rectangle = addRectangle """ gmsh.model.occ.addDisk(xc, yc, zc, rx, ry, tag = -1) Add a disk in the OpenCASCADE CAD representation, with center (`xc`, `yc`, `zc`) and radius `rx` along the x-axis and `ry` along the y-axis. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Return the tag of the disk. Return an integer value. """ function addDisk(xc, yc, zc, rx, ry, tag = -1) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelOccAddDisk, gmsh.lib), Cint, (Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cint, Ptr{Cint}), xc, yc, zc, rx, ry, tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_disk = addDisk """ gmsh.model.occ.addPlaneSurface(wireTags, tag = -1) Add a plane surface in the OpenCASCADE CAD representation, defined by one or more curve loops (or closed wires) `wireTags`. The first curve loop defines the exterior contour; additional curve loop define holes. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Return the tag of the surface. Return an integer value. """ function addPlaneSurface(wireTags, tag = -1) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelOccAddPlaneSurface, gmsh.lib), Cint, (Ptr{Cint}, Csize_t, Cint, Ptr{Cint}), convert(Vector{Cint}, wireTags), length(wireTags), tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_plane_surface = addPlaneSurface """ gmsh.model.occ.addSurfaceFilling(wireTag, tag = -1, pointTags = Cint[]) Add a surface in the OpenCASCADE CAD representation, filling the curve loop `wireTag`. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Return the tag of the surface. If `pointTags` are provided, force the surface to pass through the given points. Return an integer value. """ function addSurfaceFilling(wireTag, tag = -1, pointTags = Cint[]) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelOccAddSurfaceFilling, gmsh.lib), Cint, (Cint, Cint, Ptr{Cint}, Csize_t, Ptr{Cint}), wireTag, tag, convert(Vector{Cint}, pointTags), length(pointTags), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_surface_filling = addSurfaceFilling """ gmsh.model.occ.addBSplineFilling(wireTag, tag = -1, type = "") Add a BSpline surface in the OpenCASCADE CAD representation, filling the curve loop `wireTag`. The curve loop should be made of 2, 3 or 4 BSpline curves. The optional `type` argument specifies the type of filling: "Stretch" creates the flattest patch, "Curved" (the default) creates the most rounded patch, and "Coons" creates a rounded patch with less depth than "Curved". If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Return the tag of the surface. Return an integer value. """ function addBSplineFilling(wireTag, tag = -1, type = "") ierr = Ref{Cint}() api_result_ = ccall((:gmshModelOccAddBSplineFilling, gmsh.lib), Cint, (Cint, Cint, Ptr{Cchar}, Ptr{Cint}), wireTag, tag, type, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_bspline_filling = addBSplineFilling """ gmsh.model.occ.addBezierFilling(wireTag, tag = -1, type = "") Add a Bezier surface in the OpenCASCADE CAD representation, filling the curve loop `wireTag`. The curve loop should be made of 2, 3 or 4 Bezier curves. The optional `type` argument specifies the type of filling: "Stretch" creates the flattest patch, "Curved" (the default) creates the most rounded patch, and "Coons" creates a rounded patch with less depth than "Curved". If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Return the tag of the surface. Return an integer value. """ function addBezierFilling(wireTag, tag = -1, type = "") ierr = Ref{Cint}() api_result_ = ccall((:gmshModelOccAddBezierFilling, gmsh.lib), Cint, (Cint, Cint, Ptr{Cchar}, Ptr{Cint}), wireTag, tag, type, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_bezier_filling = addBezierFilling """ gmsh.model.occ.addBSplineSurface(pointTags, numPointsU, tag = -1, degreeU = 3, degreeV = 3, weights = Cdouble[], knotsU = Cdouble[], knotsV = Cdouble[], multiplicitiesU = Cint[], multiplicitiesV = Cint[], wireTags = Cint[], wire3D = false) Add a b-spline surface of degree `degreeU` x `degreeV` in the OpenCASCADE CAD representation, with `pointTags` control points given as a single vector [Pu1v1, ... Pu`numPointsU`v1, Pu1v2, ...]. If `weights`, `knotsU`, `knotsV`, `multiplicitiesU` or `multiplicitiesV` are not provided, default parameters are computed automatically. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. If `wireTags` is provided, trim the b-spline patch using the provided wires: the first wire defines the external contour, the others define holes. If `wire3D` is set, consider wire curves as 3D curves and project them on the b-spline surface; otherwise consider the wire curves as defined in the parametric space of the surface. Return the tag of the b-spline surface. Return an integer value. """ function addBSplineSurface(pointTags, numPointsU, tag = -1, degreeU = 3, degreeV = 3, weights = Cdouble[], knotsU = Cdouble[], knotsV = Cdouble[], multiplicitiesU = Cint[], multiplicitiesV = Cint[], wireTags = Cint[], wire3D = false) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelOccAddBSplineSurface, gmsh.lib), Cint, (Ptr{Cint}, Csize_t, Cint, Cint, Cint, Cint, Ptr{Cdouble}, Csize_t, Ptr{Cdouble}, Csize_t, Ptr{Cdouble}, Csize_t, Ptr{Cint}, Csize_t, Ptr{Cint}, Csize_t, Ptr{Cint}, Csize_t, Cint, Ptr{Cint}), convert(Vector{Cint}, pointTags), length(pointTags), numPointsU, tag, degreeU, degreeV, convert(Vector{Cdouble}, weights), length(weights), convert(Vector{Cdouble}, knotsU), length(knotsU), convert(Vector{Cdouble}, knotsV), length(knotsV), convert(Vector{Cint}, multiplicitiesU), length(multiplicitiesU), convert(Vector{Cint}, multiplicitiesV), length(multiplicitiesV), convert(Vector{Cint}, wireTags), length(wireTags), wire3D, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_bspline_surface = addBSplineSurface """ gmsh.model.occ.addBezierSurface(pointTags, numPointsU, tag = -1, wireTags = Cint[], wire3D = false) Add a Bezier surface in the OpenCASCADE CAD representation, with `pointTags` control points given as a single vector [Pu1v1, ... Pu`numPointsU`v1, Pu1v2, ...]. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. If `wireTags` is provided, trim the Bezier patch using the provided wires: the first wire defines the external contour, the others define holes. If `wire3D` is set, consider wire curves as 3D curves and project them on the Bezier surface; otherwise consider the wire curves as defined in the parametric space of the surface. Return the tag of the Bezier surface. Return an integer value. """ function addBezierSurface(pointTags, numPointsU, tag = -1, wireTags = Cint[], wire3D = false) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelOccAddBezierSurface, gmsh.lib), Cint, (Ptr{Cint}, Csize_t, Cint, Cint, Ptr{Cint}, Csize_t, Cint, Ptr{Cint}), convert(Vector{Cint}, pointTags), length(pointTags), numPointsU, tag, convert(Vector{Cint}, wireTags), length(wireTags), wire3D, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_bezier_surface = addBezierSurface """ gmsh.model.occ.addTrimmedSurface(surfaceTag, wireTags = Cint[], wire3D = false, tag = -1) Trim the surface `surfaceTag` with the wires `wireTags`, replacing any existing trimming curves. The first wire defines the external contour, the others define holes. If `wire3D` is set, consider wire curves as 3D curves and project them on the surface; otherwise consider the wire curves as defined in the parametric space of the surface. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Return the tag of the trimmed surface. Return an integer value. """ function addTrimmedSurface(surfaceTag, wireTags = Cint[], wire3D = false, tag = -1) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelOccAddTrimmedSurface, gmsh.lib), Cint, (Cint, Ptr{Cint}, Csize_t, Cint, Cint, Ptr{Cint}), surfaceTag, convert(Vector{Cint}, wireTags), length(wireTags), wire3D, tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_trimmed_surface = addTrimmedSurface """ gmsh.model.occ.addSurfaceLoop(surfaceTags, tag = -1, sewing = false) Add a surface loop (a closed shell) in the OpenCASCADE CAD representation, formed by `surfaceTags`. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Return the tag of the surface loop. Setting `sewing` allows one to build a shell made of surfaces that share geometrically identical (but topologically different) curves. Return an integer value. """ function addSurfaceLoop(surfaceTags, tag = -1, sewing = false) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelOccAddSurfaceLoop, gmsh.lib), Cint, (Ptr{Cint}, Csize_t, Cint, Cint, Ptr{Cint}), convert(Vector{Cint}, surfaceTags), length(surfaceTags), tag, sewing, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_surface_loop = addSurfaceLoop """ gmsh.model.occ.addVolume(shellTags, tag = -1) Add a volume (a region) in the OpenCASCADE CAD representation, defined by one or more surface loops `shellTags`. The first surface loop defines the exterior boundary; additional surface loop define holes. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Return the tag of the volume. Return an integer value. """ function addVolume(shellTags, tag = -1) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelOccAddVolume, gmsh.lib), Cint, (Ptr{Cint}, Csize_t, Cint, Ptr{Cint}), convert(Vector{Cint}, shellTags), length(shellTags), tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_volume = addVolume """ gmsh.model.occ.addSphere(xc, yc, zc, radius, tag = -1, angle1 = -pi/2, angle2 = pi/2, angle3 = 2*pi) Add a sphere of center (`xc`, `yc`, `zc`) and radius `r` in the OpenCASCADE CAD representation. The optional `angle1` and `angle2` arguments define the polar angle opening (from -Pi/2 to Pi/2). The optional `angle3` argument defines the azimuthal opening (from 0 to 2*Pi). If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Return the tag of the sphere. Return an integer value. """ function addSphere(xc, yc, zc, radius, tag = -1, angle1 = -pi/2, angle2 = pi/2, angle3 = 2*pi) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelOccAddSphere, gmsh.lib), Cint, (Cdouble, Cdouble, Cdouble, Cdouble, Cint, Cdouble, Cdouble, Cdouble, Ptr{Cint}), xc, yc, zc, radius, tag, angle1, angle2, angle3, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_sphere = addSphere """ gmsh.model.occ.addBox(x, y, z, dx, dy, dz, tag = -1) Add a parallelepipedic box in the OpenCASCADE CAD representation, defined by a point (`x`, `y`, `z`) and the extents along the x-, y- and z-axes. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Return the tag of the box. Return an integer value. """ function addBox(x, y, z, dx, dy, dz, tag = -1) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelOccAddBox, gmsh.lib), Cint, (Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cint, Ptr{Cint}), x, y, z, dx, dy, dz, tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_box = addBox """ gmsh.model.occ.addCylinder(x, y, z, dx, dy, dz, r, tag = -1, angle = 2*pi) Add a cylinder in the OpenCASCADE CAD representation, defined by the center (`x`, `y`, `z`) of its first circular face, the 3 components (`dx`, `dy`, `dz`) of the vector defining its axis and its radius `r`. The optional `angle` argument defines the angular opening (from 0 to 2*Pi). If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Return the tag of the cylinder. Return an integer value. """ function addCylinder(x, y, z, dx, dy, dz, r, tag = -1, angle = 2*pi) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelOccAddCylinder, gmsh.lib), Cint, (Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cint, Cdouble, Ptr{Cint}), x, y, z, dx, dy, dz, r, tag, angle, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_cylinder = addCylinder """ gmsh.model.occ.addCone(x, y, z, dx, dy, dz, r1, r2, tag = -1, angle = 2*pi) Add a cone in the OpenCASCADE CAD representation, defined by the center (`x`, `y`, `z`) of its first circular face, the 3 components of the vector (`dx`, `dy`, `dz`) defining its axis and the two radii `r1` and `r2` of the faces (these radii can be zero). If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. `angle` defines the optional angular opening (from 0 to 2*Pi). Return the tag of the cone. Return an integer value. """ function addCone(x, y, z, dx, dy, dz, r1, r2, tag = -1, angle = 2*pi) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelOccAddCone, gmsh.lib), Cint, (Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cint, Cdouble, Ptr{Cint}), x, y, z, dx, dy, dz, r1, r2, tag, angle, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_cone = addCone """ gmsh.model.occ.addWedge(x, y, z, dx, dy, dz, tag = -1, ltx = 0.) Add a right angular wedge in the OpenCASCADE CAD representation, defined by the right-angle point (`x`, `y`, `z`) and the 3 extends along the x-, y- and z-axes (`dx`, `dy`, `dz`). If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. The optional argument `ltx` defines the top extent along the x-axis. Return the tag of the wedge. Return an integer value. """ function addWedge(x, y, z, dx, dy, dz, tag = -1, ltx = 0.) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelOccAddWedge, gmsh.lib), Cint, (Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cint, Cdouble, Ptr{Cint}), x, y, z, dx, dy, dz, tag, ltx, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_wedge = addWedge """ gmsh.model.occ.addTorus(x, y, z, r1, r2, tag = -1, angle = 2*pi) Add a torus in the OpenCASCADE CAD representation, defined by its center (`x`, `y`, `z`) and its 2 radii `r` and `r2`. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. The optional argument `angle` defines the angular opening (from 0 to 2*Pi). Return the tag of the wedge. Return an integer value. """ function addTorus(x, y, z, r1, r2, tag = -1, angle = 2*pi) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelOccAddTorus, gmsh.lib), Cint, (Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cint, Cdouble, Ptr{Cint}), x, y, z, r1, r2, tag, angle, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_torus = addTorus """ gmsh.model.occ.addThruSections(wireTags, tag = -1, makeSolid = true, makeRuled = false, maxDegree = -1) Add a volume (if the optional argument `makeSolid` is set) or surfaces in the OpenCASCADE CAD representation, defined through the open or closed wires `wireTags`. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. The new entities are returned in `outDimTags`. If the optional argument `makeRuled` is set, the surfaces created on the boundary are forced to be ruled surfaces. If `maxDegree` is positive, set the maximal degree of resulting surface. Return `outDimTags`. """ function addThruSections(wireTags, tag = -1, makeSolid = true, makeRuled = false, maxDegree = -1) api_outDimTags_ = Ref{Ptr{Cint}}() api_outDimTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelOccAddThruSections, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Cint, Cint, Cint, Cint, Ptr{Cint}), convert(Vector{Cint}, wireTags), length(wireTags), api_outDimTags_, api_outDimTags_n_, tag, makeSolid, makeRuled, maxDegree, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_outDimTags_ = unsafe_wrap(Array, api_outDimTags_[], api_outDimTags_n_[], own=true) outDimTags = [ (tmp_api_outDimTags_[i], tmp_api_outDimTags_[i+1]) for i in 1:2:length(tmp_api_outDimTags_) ] return outDimTags end const add_thru_sections = addThruSections """ gmsh.model.occ.addThickSolid(volumeTag, excludeSurfaceTags, offset, tag = -1) Add a hollowed volume in the OpenCASCADE CAD representation, built from an initial volume `volumeTag` and a set of faces from this volume `excludeSurfaceTags`, which are to be removed. The remaining faces of the volume become the walls of the hollowed solid, with thickness `offset`. If `tag` is positive, set the tag explicitly; otherwise a new tag is selected automatically. Return `outDimTags`. """ function addThickSolid(volumeTag, excludeSurfaceTags, offset, tag = -1) api_outDimTags_ = Ref{Ptr{Cint}}() api_outDimTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelOccAddThickSolid, gmsh.lib), Cvoid, (Cint, Ptr{Cint}, Csize_t, Cdouble, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Cint, Ptr{Cint}), volumeTag, convert(Vector{Cint}, excludeSurfaceTags), length(excludeSurfaceTags), offset, api_outDimTags_, api_outDimTags_n_, tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_outDimTags_ = unsafe_wrap(Array, api_outDimTags_[], api_outDimTags_n_[], own=true) outDimTags = [ (tmp_api_outDimTags_[i], tmp_api_outDimTags_[i+1]) for i in 1:2:length(tmp_api_outDimTags_) ] return outDimTags end const add_thick_solid = addThickSolid """ gmsh.model.occ.extrude(dimTags, dx, dy, dz, numElements = Cint[], heights = Cdouble[], recombine = false) Extrude the entities `dimTags` in the OpenCASCADE CAD representation, using a translation along (`dx`, `dy`, `dz`). Return extruded entities in `outDimTags`. If `numElements` is not empty, also extrude the mesh: the entries in `numElements` give the number of elements in each layer. If `height` is not empty, it provides the (cumulative) height of the different layers, normalized to 1. If `recombine` is set, recombine the mesh in the layers. Return `outDimTags`. """ function extrude(dimTags, dx, dy, dz, numElements = Cint[], heights = Cdouble[], recombine = false) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) api_outDimTags_ = Ref{Ptr{Cint}}() api_outDimTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelOccExtrude, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Cdouble, Cdouble, Cdouble, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Cint}, Csize_t, Ptr{Cdouble}, Csize_t, Cint, Ptr{Cint}), api_dimTags_, api_dimTags_n_, dx, dy, dz, api_outDimTags_, api_outDimTags_n_, convert(Vector{Cint}, numElements), length(numElements), convert(Vector{Cdouble}, heights), length(heights), recombine, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_outDimTags_ = unsafe_wrap(Array, api_outDimTags_[], api_outDimTags_n_[], own=true) outDimTags = [ (tmp_api_outDimTags_[i], tmp_api_outDimTags_[i+1]) for i in 1:2:length(tmp_api_outDimTags_) ] return outDimTags end """ gmsh.model.occ.revolve(dimTags, x, y, z, ax, ay, az, angle, numElements = Cint[], heights = Cdouble[], recombine = false) Extrude the entities `dimTags` in the OpenCASCADE CAD representation, using a rotation of `angle` radians around the axis of revolution defined by the point (`x`, `y`, `z`) and the direction (`ax`, `ay`, `az`). Return extruded entities in `outDimTags`. If `numElements` is not empty, also extrude the mesh: the entries in `numElements` give the number of elements in each layer. If `height` is not empty, it provides the (cumulative) height of the different layers, normalized to 1. When the mesh is extruded the angle should be strictly smaller than 2*Pi. If `recombine` is set, recombine the mesh in the layers. Return `outDimTags`. """ function revolve(dimTags, x, y, z, ax, ay, az, angle, numElements = Cint[], heights = Cdouble[], recombine = false) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) api_outDimTags_ = Ref{Ptr{Cint}}() api_outDimTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelOccRevolve, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Cint}, Csize_t, Ptr{Cdouble}, Csize_t, Cint, Ptr{Cint}), api_dimTags_, api_dimTags_n_, x, y, z, ax, ay, az, angle, api_outDimTags_, api_outDimTags_n_, convert(Vector{Cint}, numElements), length(numElements), convert(Vector{Cdouble}, heights), length(heights), recombine, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_outDimTags_ = unsafe_wrap(Array, api_outDimTags_[], api_outDimTags_n_[], own=true) outDimTags = [ (tmp_api_outDimTags_[i], tmp_api_outDimTags_[i+1]) for i in 1:2:length(tmp_api_outDimTags_) ] return outDimTags end """ gmsh.model.occ.addPipe(dimTags, wireTag, trihedron = "") Add a pipe in the OpenCASCADE CAD representation, by extruding the entities `dimTags` along the wire `wireTag`. The type of sweep can be specified with `trihedron` (possible values: "DiscreteTrihedron", "CorrectedFrenet", "Fixed", "Frenet", "ConstantNormal", "Darboux", "GuideAC", "GuidePlan", "GuideACWithContact", "GuidePlanWithContact"). If `trihedron` is not provided, "DiscreteTrihedron" is assumed. Return the pipe in `outDimTags`. Return `outDimTags`. """ function addPipe(dimTags, wireTag, trihedron = "") api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) api_outDimTags_ = Ref{Ptr{Cint}}() api_outDimTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelOccAddPipe, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Cint, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Cchar}, Ptr{Cint}), api_dimTags_, api_dimTags_n_, wireTag, api_outDimTags_, api_outDimTags_n_, trihedron, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_outDimTags_ = unsafe_wrap(Array, api_outDimTags_[], api_outDimTags_n_[], own=true) outDimTags = [ (tmp_api_outDimTags_[i], tmp_api_outDimTags_[i+1]) for i in 1:2:length(tmp_api_outDimTags_) ] return outDimTags end const add_pipe = addPipe """ gmsh.model.occ.fillet(volumeTags, curveTags, radii, removeVolume = true) Fillet the volumes `volumeTags` on the curves `curveTags` with radii `radii`. The `radii` vector can either contain a single radius, as many radii as `curveTags`, or twice as many as `curveTags` (in which case different radii are provided for the begin and end points of the curves). Return the filleted entities in `outDimTags`. Remove the original volume if `removeVolume` is set. Return `outDimTags`. """ function fillet(volumeTags, curveTags, radii, removeVolume = true) api_outDimTags_ = Ref{Ptr{Cint}}() api_outDimTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelOccFillet, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Ptr{Cint}, Csize_t, Ptr{Cdouble}, Csize_t, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Cint, Ptr{Cint}), convert(Vector{Cint}, volumeTags), length(volumeTags), convert(Vector{Cint}, curveTags), length(curveTags), convert(Vector{Cdouble}, radii), length(radii), api_outDimTags_, api_outDimTags_n_, removeVolume, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_outDimTags_ = unsafe_wrap(Array, api_outDimTags_[], api_outDimTags_n_[], own=true) outDimTags = [ (tmp_api_outDimTags_[i], tmp_api_outDimTags_[i+1]) for i in 1:2:length(tmp_api_outDimTags_) ] return outDimTags end """ gmsh.model.occ.chamfer(volumeTags, curveTags, surfaceTags, distances, removeVolume = true) Chamfer the volumes `volumeTags` on the curves `curveTags` with distances `distances` measured on surfaces `surfaceTags`. The `distances` vector can either contain a single distance, as many distances as `curveTags` and `surfaceTags`, or twice as many as `curveTags` and `surfaceTags` (in which case the first in each pair is measured on the corresponding surface in `surfaceTags`, the other on the other adjacent surface). Return the chamfered entities in `outDimTags`. Remove the original volume if `removeVolume` is set. Return `outDimTags`. """ function chamfer(volumeTags, curveTags, surfaceTags, distances, removeVolume = true) api_outDimTags_ = Ref{Ptr{Cint}}() api_outDimTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelOccChamfer, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Ptr{Cint}, Csize_t, Ptr{Cint}, Csize_t, Ptr{Cdouble}, Csize_t, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Cint, Ptr{Cint}), convert(Vector{Cint}, volumeTags), length(volumeTags), convert(Vector{Cint}, curveTags), length(curveTags), convert(Vector{Cint}, surfaceTags), length(surfaceTags), convert(Vector{Cdouble}, distances), length(distances), api_outDimTags_, api_outDimTags_n_, removeVolume, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_outDimTags_ = unsafe_wrap(Array, api_outDimTags_[], api_outDimTags_n_[], own=true) outDimTags = [ (tmp_api_outDimTags_[i], tmp_api_outDimTags_[i+1]) for i in 1:2:length(tmp_api_outDimTags_) ] return outDimTags end """ gmsh.model.occ.fuse(objectDimTags, toolDimTags, tag = -1, removeObject = true, removeTool = true) Compute the boolean union (the fusion) of the entities `objectDimTags` and `toolDimTags` in the OpenCASCADE CAD representation. Return the resulting entities in `outDimTags`. If `tag` is positive, try to set the tag explicitly (only valid if the boolean operation results in a single entity). Remove the object if `removeObject` is set. Remove the tool if `removeTool` is set. Return `outDimTags`, `outDimTagsMap`. """ function fuse(objectDimTags, toolDimTags, tag = -1, removeObject = true, removeTool = true) api_objectDimTags_ = collect(Cint, Iterators.flatten(objectDimTags)) api_objectDimTags_n_ = length(api_objectDimTags_) api_toolDimTags_ = collect(Cint, Iterators.flatten(toolDimTags)) api_toolDimTags_n_ = length(api_toolDimTags_) api_outDimTags_ = Ref{Ptr{Cint}}() api_outDimTags_n_ = Ref{Csize_t}() api_outDimTagsMap_ = Ref{Ptr{Ptr{Cint}}}() api_outDimTagsMap_n_ = Ref{Ptr{Csize_t}}() api_outDimTagsMap_nn_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelOccFuse, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Ptr{Cint}, Csize_t, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Ptr{Ptr{Cint}}}, Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Cint, Cint, Cint, Ptr{Cint}), api_objectDimTags_, api_objectDimTags_n_, api_toolDimTags_, api_toolDimTags_n_, api_outDimTags_, api_outDimTags_n_, api_outDimTagsMap_, api_outDimTagsMap_n_, api_outDimTagsMap_nn_, tag, removeObject, removeTool, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_outDimTags_ = unsafe_wrap(Array, api_outDimTags_[], api_outDimTags_n_[], own=true) outDimTags = [ (tmp_api_outDimTags_[i], tmp_api_outDimTags_[i+1]) for i in 1:2:length(tmp_api_outDimTags_) ] tmp_api_outDimTagsMap_ = unsafe_wrap(Array, api_outDimTagsMap_[], api_outDimTagsMap_nn_[], own=true) tmp_api_outDimTagsMap_n_ = unsafe_wrap(Array, api_outDimTagsMap_n_[], api_outDimTagsMap_nn_[], own=true) outDimTagsMap = Vector{Tuple{Cint,Cint}}[] resize!(outDimTagsMap, api_outDimTagsMap_nn_[]) for i in 1:api_outDimTagsMap_nn_[] tmp = unsafe_wrap(Array, tmp_api_outDimTagsMap_[i], tmp_api_outDimTagsMap_n_[i], own=true) outDimTagsMap[i] = [(tmp[i], tmp[i+1]) for i in 1:2:length(tmp)] end return outDimTags, outDimTagsMap end """ gmsh.model.occ.intersect(objectDimTags, toolDimTags, tag = -1, removeObject = true, removeTool = true) Compute the boolean intersection (the common parts) of the entities `objectDimTags` and `toolDimTags` in the OpenCASCADE CAD representation. Return the resulting entities in `outDimTags`. If `tag` is positive, try to set the tag explicitly (only valid if the boolean operation results in a single entity). Remove the object if `removeObject` is set. Remove the tool if `removeTool` is set. Return `outDimTags`, `outDimTagsMap`. """ function intersect(objectDimTags, toolDimTags, tag = -1, removeObject = true, removeTool = true) api_objectDimTags_ = collect(Cint, Iterators.flatten(objectDimTags)) api_objectDimTags_n_ = length(api_objectDimTags_) api_toolDimTags_ = collect(Cint, Iterators.flatten(toolDimTags)) api_toolDimTags_n_ = length(api_toolDimTags_) api_outDimTags_ = Ref{Ptr{Cint}}() api_outDimTags_n_ = Ref{Csize_t}() api_outDimTagsMap_ = Ref{Ptr{Ptr{Cint}}}() api_outDimTagsMap_n_ = Ref{Ptr{Csize_t}}() api_outDimTagsMap_nn_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelOccIntersect, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Ptr{Cint}, Csize_t, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Ptr{Ptr{Cint}}}, Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Cint, Cint, Cint, Ptr{Cint}), api_objectDimTags_, api_objectDimTags_n_, api_toolDimTags_, api_toolDimTags_n_, api_outDimTags_, api_outDimTags_n_, api_outDimTagsMap_, api_outDimTagsMap_n_, api_outDimTagsMap_nn_, tag, removeObject, removeTool, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_outDimTags_ = unsafe_wrap(Array, api_outDimTags_[], api_outDimTags_n_[], own=true) outDimTags = [ (tmp_api_outDimTags_[i], tmp_api_outDimTags_[i+1]) for i in 1:2:length(tmp_api_outDimTags_) ] tmp_api_outDimTagsMap_ = unsafe_wrap(Array, api_outDimTagsMap_[], api_outDimTagsMap_nn_[], own=true) tmp_api_outDimTagsMap_n_ = unsafe_wrap(Array, api_outDimTagsMap_n_[], api_outDimTagsMap_nn_[], own=true) outDimTagsMap = Vector{Tuple{Cint,Cint}}[] resize!(outDimTagsMap, api_outDimTagsMap_nn_[]) for i in 1:api_outDimTagsMap_nn_[] tmp = unsafe_wrap(Array, tmp_api_outDimTagsMap_[i], tmp_api_outDimTagsMap_n_[i], own=true) outDimTagsMap[i] = [(tmp[i], tmp[i+1]) for i in 1:2:length(tmp)] end return outDimTags, outDimTagsMap end """ gmsh.model.occ.cut(objectDimTags, toolDimTags, tag = -1, removeObject = true, removeTool = true) Compute the boolean difference between the entities `objectDimTags` and `toolDimTags` in the OpenCASCADE CAD representation. Return the resulting entities in `outDimTags`. If `tag` is positive, try to set the tag explicitly (only valid if the boolean operation results in a single entity). Remove the object if `removeObject` is set. Remove the tool if `removeTool` is set. Return `outDimTags`, `outDimTagsMap`. """ function cut(objectDimTags, toolDimTags, tag = -1, removeObject = true, removeTool = true) api_objectDimTags_ = collect(Cint, Iterators.flatten(objectDimTags)) api_objectDimTags_n_ = length(api_objectDimTags_) api_toolDimTags_ = collect(Cint, Iterators.flatten(toolDimTags)) api_toolDimTags_n_ = length(api_toolDimTags_) api_outDimTags_ = Ref{Ptr{Cint}}() api_outDimTags_n_ = Ref{Csize_t}() api_outDimTagsMap_ = Ref{Ptr{Ptr{Cint}}}() api_outDimTagsMap_n_ = Ref{Ptr{Csize_t}}() api_outDimTagsMap_nn_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelOccCut, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Ptr{Cint}, Csize_t, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Ptr{Ptr{Cint}}}, Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Cint, Cint, Cint, Ptr{Cint}), api_objectDimTags_, api_objectDimTags_n_, api_toolDimTags_, api_toolDimTags_n_, api_outDimTags_, api_outDimTags_n_, api_outDimTagsMap_, api_outDimTagsMap_n_, api_outDimTagsMap_nn_, tag, removeObject, removeTool, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_outDimTags_ = unsafe_wrap(Array, api_outDimTags_[], api_outDimTags_n_[], own=true) outDimTags = [ (tmp_api_outDimTags_[i], tmp_api_outDimTags_[i+1]) for i in 1:2:length(tmp_api_outDimTags_) ] tmp_api_outDimTagsMap_ = unsafe_wrap(Array, api_outDimTagsMap_[], api_outDimTagsMap_nn_[], own=true) tmp_api_outDimTagsMap_n_ = unsafe_wrap(Array, api_outDimTagsMap_n_[], api_outDimTagsMap_nn_[], own=true) outDimTagsMap = Vector{Tuple{Cint,Cint}}[] resize!(outDimTagsMap, api_outDimTagsMap_nn_[]) for i in 1:api_outDimTagsMap_nn_[] tmp = unsafe_wrap(Array, tmp_api_outDimTagsMap_[i], tmp_api_outDimTagsMap_n_[i], own=true) outDimTagsMap[i] = [(tmp[i], tmp[i+1]) for i in 1:2:length(tmp)] end return outDimTags, outDimTagsMap end """ gmsh.model.occ.fragment(objectDimTags, toolDimTags, tag = -1, removeObject = true, removeTool = true) Compute the boolean fragments (general fuse) resulting from the intersection of the entities `objectDimTags` and `toolDimTags` in the OpenCASCADE CAD representation, making all iterfaces conformal. When applied to entities of different dimensions, the lower dimensional entities will be automatically embedded in the higher dimensional entities if they are not on their boundary. Return the resulting entities in `outDimTags`. If `tag` is positive, try to set the tag explicitly (only valid if the boolean operation results in a single entity). Remove the object if `removeObject` is set. Remove the tool if `removeTool` is set. Return `outDimTags`, `outDimTagsMap`. """ function fragment(objectDimTags, toolDimTags, tag = -1, removeObject = true, removeTool = true) api_objectDimTags_ = collect(Cint, Iterators.flatten(objectDimTags)) api_objectDimTags_n_ = length(api_objectDimTags_) api_toolDimTags_ = collect(Cint, Iterators.flatten(toolDimTags)) api_toolDimTags_n_ = length(api_toolDimTags_) api_outDimTags_ = Ref{Ptr{Cint}}() api_outDimTags_n_ = Ref{Csize_t}() api_outDimTagsMap_ = Ref{Ptr{Ptr{Cint}}}() api_outDimTagsMap_n_ = Ref{Ptr{Csize_t}}() api_outDimTagsMap_nn_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelOccFragment, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Ptr{Cint}, Csize_t, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Ptr{Ptr{Cint}}}, Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Cint, Cint, Cint, Ptr{Cint}), api_objectDimTags_, api_objectDimTags_n_, api_toolDimTags_, api_toolDimTags_n_, api_outDimTags_, api_outDimTags_n_, api_outDimTagsMap_, api_outDimTagsMap_n_, api_outDimTagsMap_nn_, tag, removeObject, removeTool, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_outDimTags_ = unsafe_wrap(Array, api_outDimTags_[], api_outDimTags_n_[], own=true) outDimTags = [ (tmp_api_outDimTags_[i], tmp_api_outDimTags_[i+1]) for i in 1:2:length(tmp_api_outDimTags_) ] tmp_api_outDimTagsMap_ = unsafe_wrap(Array, api_outDimTagsMap_[], api_outDimTagsMap_nn_[], own=true) tmp_api_outDimTagsMap_n_ = unsafe_wrap(Array, api_outDimTagsMap_n_[], api_outDimTagsMap_nn_[], own=true) outDimTagsMap = Vector{Tuple{Cint,Cint}}[] resize!(outDimTagsMap, api_outDimTagsMap_nn_[]) for i in 1:api_outDimTagsMap_nn_[] tmp = unsafe_wrap(Array, tmp_api_outDimTagsMap_[i], tmp_api_outDimTagsMap_n_[i], own=true) outDimTagsMap[i] = [(tmp[i], tmp[i+1]) for i in 1:2:length(tmp)] end return outDimTags, outDimTagsMap end """ gmsh.model.occ.translate(dimTags, dx, dy, dz) Translate the entities `dimTags` in the OpenCASCADE CAD representation along (`dx`, `dy`, `dz`). """ function translate(dimTags, dx, dy, dz) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelOccTranslate, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Cdouble, Cdouble, Cdouble, Ptr{Cint}), api_dimTags_, api_dimTags_n_, dx, dy, dz, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.model.occ.rotate(dimTags, x, y, z, ax, ay, az, angle) Rotate the entities `dimTags` in the OpenCASCADE CAD representation by `angle` radians around the axis of revolution defined by the point (`x`, `y`, `z`) and the direction (`ax`, `ay`, `az`). """ function rotate(dimTags, x, y, z, ax, ay, az, angle) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelOccRotate, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Ptr{Cint}), api_dimTags_, api_dimTags_n_, x, y, z, ax, ay, az, angle, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.model.occ.dilate(dimTags, x, y, z, a, b, c) Scale the entities `dimTags` in the OpenCASCADE CAD representation by factors `a`, `b` and `c` along the three coordinate axes; use (`x`, `y`, `z`) as the center of the homothetic transformation. """ function dilate(dimTags, x, y, z, a, b, c) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelOccDilate, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Ptr{Cint}), api_dimTags_, api_dimTags_n_, x, y, z, a, b, c, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.model.occ.mirror(dimTags, a, b, c, d) Mirror the entities `dimTags` in the OpenCASCADE CAD representation, with respect to the plane of equation `a` * x + `b` * y + `c` * z + `d` = 0. """ function mirror(dimTags, a, b, c, d) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelOccMirror, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Cdouble, Cdouble, Cdouble, Cdouble, Ptr{Cint}), api_dimTags_, api_dimTags_n_, a, b, c, d, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.model.occ.symmetrize(dimTags, a, b, c, d) Mirror the entities `dimTags` in the OpenCASCADE CAD representation, with respect to the plane of equation `a` * x + `b` * y + `c` * z + `d` = 0. (This is a synonym for `mirror`, which will be deprecated in a future release.) """ function symmetrize(dimTags, a, b, c, d) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelOccSymmetrize, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Cdouble, Cdouble, Cdouble, Cdouble, Ptr{Cint}), api_dimTags_, api_dimTags_n_, a, b, c, d, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.model.occ.affineTransform(dimTags, a) Apply a general affine transformation matrix `a` (16 entries of a 4x4 matrix, by row; only the 12 first can be provided for convenience) to the entities `dimTags` in the OpenCASCADE CAD representation. """ function affineTransform(dimTags, a) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelOccAffineTransform, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Ptr{Cdouble}, Csize_t, Ptr{Cint}), api_dimTags_, api_dimTags_n_, convert(Vector{Cdouble}, a), length(a), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const affine_transform = affineTransform """ gmsh.model.occ.copy(dimTags) Copy the entities `dimTags` in the OpenCASCADE CAD representation; the new entities are returned in `outDimTags`. Return `outDimTags`. """ function copy(dimTags) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) api_outDimTags_ = Ref{Ptr{Cint}}() api_outDimTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelOccCopy, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Cint}), api_dimTags_, api_dimTags_n_, api_outDimTags_, api_outDimTags_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_outDimTags_ = unsafe_wrap(Array, api_outDimTags_[], api_outDimTags_n_[], own=true) outDimTags = [ (tmp_api_outDimTags_[i], tmp_api_outDimTags_[i+1]) for i in 1:2:length(tmp_api_outDimTags_) ] return outDimTags end """ gmsh.model.occ.remove(dimTags, recursive = false) Remove the entities `dimTags` in the OpenCASCADE CAD representation, provided that they are not on the boundary of higher-dimensional entities. If `recursive` is true, remove all the entities on their boundaries, down to dimension 0. """ function remove(dimTags, recursive = false) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelOccRemove, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Cint, Ptr{Cint}), api_dimTags_, api_dimTags_n_, recursive, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.model.occ.removeAllDuplicates() Remove all duplicate entities in the OpenCASCADE CAD representation (different entities at the same geometrical location) after intersecting (using boolean fragments) all highest dimensional entities. """ function removeAllDuplicates() ierr = Ref{Cint}() ccall((:gmshModelOccRemoveAllDuplicates, gmsh.lib), Cvoid, (Ptr{Cint},), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const remove_all_duplicates = removeAllDuplicates """ gmsh.model.occ.healShapes(dimTags = Tuple{Cint,Cint}[], tolerance = 1e-8, fixDegenerated = true, fixSmallEdges = true, fixSmallFaces = true, sewFaces = true, makeSolids = true) Apply various healing procedures to the entities `dimTags` (or to all the entities in the model if `dimTags` is empty) in the OpenCASCADE CAD representation. Return the healed entities in `outDimTags`. Available healing options are listed in the Gmsh reference manual. Return `outDimTags`. """ function healShapes(dimTags = Tuple{Cint,Cint}[], tolerance = 1e-8, fixDegenerated = true, fixSmallEdges = true, fixSmallFaces = true, sewFaces = true, makeSolids = true) api_outDimTags_ = Ref{Ptr{Cint}}() api_outDimTags_n_ = Ref{Csize_t}() api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelOccHealShapes, gmsh.lib), Cvoid, (Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Cint}, Csize_t, Cdouble, Cint, Cint, Cint, Cint, Cint, Ptr{Cint}), api_outDimTags_, api_outDimTags_n_, api_dimTags_, api_dimTags_n_, tolerance, fixDegenerated, fixSmallEdges, fixSmallFaces, sewFaces, makeSolids, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_outDimTags_ = unsafe_wrap(Array, api_outDimTags_[], api_outDimTags_n_[], own=true) outDimTags = [ (tmp_api_outDimTags_[i], tmp_api_outDimTags_[i+1]) for i in 1:2:length(tmp_api_outDimTags_) ] return outDimTags end const heal_shapes = healShapes """ gmsh.model.occ.importShapes(fileName, highestDimOnly = true, format = "") Import BREP, STEP or IGES shapes from the file `fileName` in the OpenCASCADE CAD representation. The imported entities are returned in `outDimTags`. If the optional argument `highestDimOnly` is set, only import the highest dimensional entities in the file. The optional argument `format` can be used to force the format of the file (currently "brep", "step" or "iges"). Return `outDimTags`. """ function importShapes(fileName, highestDimOnly = true, format = "") api_outDimTags_ = Ref{Ptr{Cint}}() api_outDimTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelOccImportShapes, gmsh.lib), Cvoid, (Ptr{Cchar}, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Cint, Ptr{Cchar}, Ptr{Cint}), fileName, api_outDimTags_, api_outDimTags_n_, highestDimOnly, format, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_outDimTags_ = unsafe_wrap(Array, api_outDimTags_[], api_outDimTags_n_[], own=true) outDimTags = [ (tmp_api_outDimTags_[i], tmp_api_outDimTags_[i+1]) for i in 1:2:length(tmp_api_outDimTags_) ] return outDimTags end const import_shapes = importShapes """ gmsh.model.occ.getEntities(dim = -1) Get all the OpenCASCADE entities. If `dim` is >= 0, return only the entities of the specified dimension (e.g. points if `dim` == 0). The entities are returned as a vector of (dim, tag) integer pairs. Return `dimTags`. """ function getEntities(dim = -1) api_dimTags_ = Ref{Ptr{Cint}}() api_dimTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelOccGetEntities, gmsh.lib), Cvoid, (Ptr{Ptr{Cint}}, Ptr{Csize_t}, Cint, Ptr{Cint}), api_dimTags_, api_dimTags_n_, dim, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_dimTags_ = unsafe_wrap(Array, api_dimTags_[], api_dimTags_n_[], own=true) dimTags = [ (tmp_api_dimTags_[i], tmp_api_dimTags_[i+1]) for i in 1:2:length(tmp_api_dimTags_) ] return dimTags end const get_entities = getEntities """ gmsh.model.occ.getEntitiesInBoundingBox(xmin, ymin, zmin, xmax, ymax, zmax, dim = -1) Get the OpenCASCADE entities in the bounding box defined by the two points (`xmin`, `ymin`, `zmin`) and (`xmax`, `ymax`, `zmax`). If `dim` is >= 0, return only the entities of the specified dimension (e.g. points if `dim` == 0). Return `tags`. """ function getEntitiesInBoundingBox(xmin, ymin, zmin, xmax, ymax, zmax, dim = -1) api_tags_ = Ref{Ptr{Cint}}() api_tags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelOccGetEntitiesInBoundingBox, gmsh.lib), Cvoid, (Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Cdouble, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Cint, Ptr{Cint}), xmin, ymin, zmin, xmax, ymax, zmax, api_tags_, api_tags_n_, dim, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_tags_ = unsafe_wrap(Array, api_tags_[], api_tags_n_[], own=true) tags = [ (tmp_api_tags_[i], tmp_api_tags_[i+1]) for i in 1:2:length(tmp_api_tags_) ] return tags end const get_entities_in_bounding_box = getEntitiesInBoundingBox """ gmsh.model.occ.getBoundingBox(dim, tag) Get the bounding box (`xmin`, `ymin`, `zmin`), (`xmax`, `ymax`, `zmax`) of the OpenCASCADE entity of dimension `dim` and tag `tag`. Return `xmin`, `ymin`, `zmin`, `xmax`, `ymax`, `zmax`. """ function getBoundingBox(dim, tag) api_xmin_ = Ref{Cdouble}() api_ymin_ = Ref{Cdouble}() api_zmin_ = Ref{Cdouble}() api_xmax_ = Ref{Cdouble}() api_ymax_ = Ref{Cdouble}() api_zmax_ = Ref{Cdouble}() ierr = Ref{Cint}() ccall((:gmshModelOccGetBoundingBox, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cdouble}, Ptr{Cdouble}, Ptr{Cdouble}, Ptr{Cdouble}, Ptr{Cdouble}, Ptr{Cdouble}, Ptr{Cint}), dim, tag, api_xmin_, api_ymin_, api_zmin_, api_xmax_, api_ymax_, api_zmax_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_xmin_[], api_ymin_[], api_zmin_[], api_xmax_[], api_ymax_[], api_zmax_[] end const get_bounding_box = getBoundingBox """ gmsh.model.occ.getMass(dim, tag) Get the mass of the OpenCASCADE entity of dimension `dim` and tag `tag`. Return `mass`. """ function getMass(dim, tag) api_mass_ = Ref{Cdouble}() ierr = Ref{Cint}() ccall((:gmshModelOccGetMass, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cdouble}, Ptr{Cint}), dim, tag, api_mass_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_mass_[] end const get_mass = getMass """ gmsh.model.occ.getCenterOfMass(dim, tag) Get the center of mass of the OpenCASCADE entity of dimension `dim` and tag `tag`. Return `x`, `y`, `z`. """ function getCenterOfMass(dim, tag) api_x_ = Ref{Cdouble}() api_y_ = Ref{Cdouble}() api_z_ = Ref{Cdouble}() ierr = Ref{Cint}() ccall((:gmshModelOccGetCenterOfMass, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cdouble}, Ptr{Cdouble}, Ptr{Cdouble}, Ptr{Cint}), dim, tag, api_x_, api_y_, api_z_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_x_[], api_y_[], api_z_[] end const get_center_of_mass = getCenterOfMass """ gmsh.model.occ.getMatrixOfInertia(dim, tag) Get the matrix of inertia (by row) of the OpenCASCADE entity of dimension `dim` and tag `tag`. Return `mat`. """ function getMatrixOfInertia(dim, tag) api_mat_ = Ref{Ptr{Cdouble}}() api_mat_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshModelOccGetMatrixOfInertia, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Cint}), dim, tag, api_mat_, api_mat_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) mat = unsafe_wrap(Array, api_mat_[], api_mat_n_[], own=true) return mat end const get_matrix_of_inertia = getMatrixOfInertia """ gmsh.model.occ.getMaxTag(dim) Get the maximum tag of entities of dimension `dim` in the OpenCASCADE CAD representation. Return an integer value. """ function getMaxTag(dim) ierr = Ref{Cint}() api_result_ = ccall((:gmshModelOccGetMaxTag, gmsh.lib), Cint, (Cint, Ptr{Cint}), dim, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const get_max_tag = getMaxTag """ gmsh.model.occ.setMaxTag(dim, maxTag) Set the maximum tag `maxTag` for entities of dimension `dim` in the OpenCASCADE CAD representation. """ function setMaxTag(dim, maxTag) ierr = Ref{Cint}() ccall((:gmshModelOccSetMaxTag, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cint}), dim, maxTag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_max_tag = setMaxTag """ gmsh.model.occ.synchronize() Synchronize the OpenCASCADE CAD representation with the current Gmsh model. This can be called at any time, but since it involves a non trivial amount of processing, the number of synchronization points should normally be minimized. Without synchronization the entities in the OpenCASCADE CAD representation are not available to any function outside of the OpenCASCADE CAD kernel functions. """ function synchronize() ierr = Ref{Cint}() ccall((:gmshModelOccSynchronize, gmsh.lib), Cvoid, (Ptr{Cint},), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ module gmsh.model.occ.mesh OpenCASCADE CAD kernel meshing constraints """ module mesh import ....gmsh """ gmsh.model.occ.mesh.setSize(dimTags, size) Set a mesh size constraint on the entities `dimTags` in the OpenCASCADE CAD representation. Currently only entities of dimension 0 (points) are handled. """ function setSize(dimTags, size) api_dimTags_ = collect(Cint, Iterators.flatten(dimTags)) api_dimTags_n_ = length(api_dimTags_) ierr = Ref{Cint}() ccall((:gmshModelOccMeshSetSize, gmsh.lib), Cvoid, (Ptr{Cint}, Csize_t, Cdouble, Ptr{Cint}), api_dimTags_, api_dimTags_n_, size, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_size = setSize end # end of module mesh end # end of module occ end # end of module model """ module gmsh.view Post-processing view functions """ module view import ..gmsh """ gmsh.view.add(name, tag = -1) Add a new post-processing view, with name `name`. If `tag` is positive use it (and remove the view with that tag if it already exists), otherwise associate a new tag. Return the view tag. Return an integer value. """ function add(name, tag = -1) ierr = Ref{Cint}() api_result_ = ccall((:gmshViewAdd, gmsh.lib), Cint, (Ptr{Cchar}, Cint, Ptr{Cint}), name, tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end """ gmsh.view.remove(tag) Remove the view with tag `tag`. """ function remove(tag) ierr = Ref{Cint}() ccall((:gmshViewRemove, gmsh.lib), Cvoid, (Cint, Ptr{Cint}), tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.view.getIndex(tag) Get the index of the view with tag `tag` in the list of currently loaded views. This dynamic index (it can change when views are removed) is used to access view options. Return an integer value. """ function getIndex(tag) ierr = Ref{Cint}() api_result_ = ccall((:gmshViewGetIndex, gmsh.lib), Cint, (Cint, Ptr{Cint}), tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const get_index = getIndex """ gmsh.view.getTags() Get the tags of all views. Return `tags`. """ function getTags() api_tags_ = Ref{Ptr{Cint}}() api_tags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshViewGetTags, gmsh.lib), Cvoid, (Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Cint}), api_tags_, api_tags_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tags = unsafe_wrap(Array, api_tags_[], api_tags_n_[], own=true) return tags end const get_tags = getTags """ gmsh.view.addModelData(tag, step, modelName, dataType, tags, data, time = 0., numComponents = -1, partition = 0) Add model-based post-processing data to the view with tag `tag`. `modelName` identifies the model the data is attached to. `dataType` specifies the type of data, currently either "NodeData", "ElementData" or "ElementNodeData". `step` specifies the identifier (>= 0) of the data in a sequence. `tags` gives the tags of the nodes or elements in the mesh to which the data is associated. `data` is a vector of the same length as `tags`: each entry is the vector of double precision numbers representing the data associated with the corresponding tag. The optional `time` argument associate a time value with the data. `numComponents` gives the number of data components (1 for scalar data, 3 for vector data, etc.) per entity; if negative, it is automatically inferred (when possible) from the input data. `partition` allows one to specify data in several sub-sets. """ function addModelData(tag, step, modelName, dataType, tags, data, time = 0., numComponents = -1, partition = 0) api_data_n_ = [ length(data[i]) for i in 1:length(data) ] ierr = Ref{Cint}() ccall((:gmshViewAddModelData, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cchar}, Ptr{Cchar}, Ptr{Csize_t}, Csize_t, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Csize_t, Cdouble, Cint, Cint, Ptr{Cint}), tag, step, modelName, dataType, convert(Vector{Csize_t}, tags), length(tags), convert(Vector{Vector{Cdouble}},data), api_data_n_, length(data), time, numComponents, partition, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const add_model_data = addModelData """ gmsh.view.addHomogeneousModelData(tag, step, modelName, dataType, tags, data, time = 0., numComponents = -1, partition = 0) Add homogeneous model-based post-processing data to the view with tag `tag`. The arguments have the same meaning as in `addModelData`, except that `data` is supposed to be homogeneous and is thus flattened in a single vector. For data types that can lead to different data sizes per tag (like "ElementNodeData"), the data should be padded. """ function addHomogeneousModelData(tag, step, modelName, dataType, tags, data, time = 0., numComponents = -1, partition = 0) ierr = Ref{Cint}() ccall((:gmshViewAddHomogeneousModelData, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cchar}, Ptr{Cchar}, Ptr{Csize_t}, Csize_t, Ptr{Cdouble}, Csize_t, Cdouble, Cint, Cint, Ptr{Cint}), tag, step, modelName, dataType, convert(Vector{Csize_t}, tags), length(tags), convert(Vector{Cdouble}, data), length(data), time, numComponents, partition, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const add_homogeneous_model_data = addHomogeneousModelData """ gmsh.view.getModelData(tag, step) Get model-based post-processing data from the view with tag `tag` at step `step`. Return the `data` associated to the nodes or the elements with tags `tags`, as well as the `dataType` and the number of components `numComponents`. Return `dataType`, `tags`, `data`, `time`, `numComponents`. """ function getModelData(tag, step) api_dataType_ = Ref{Ptr{Cchar}}() api_tags_ = Ref{Ptr{Csize_t}}() api_tags_n_ = Ref{Csize_t}() api_data_ = Ref{Ptr{Ptr{Cdouble}}}() api_data_n_ = Ref{Ptr{Csize_t}}() api_data_nn_ = Ref{Csize_t}() api_time_ = Ref{Cdouble}() api_numComponents_ = Ref{Cint}() ierr = Ref{Cint}() ccall((:gmshViewGetModelData, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Ptr{Cchar}}, Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Ptr{Ptr{Ptr{Cdouble}}}, Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Ptr{Cdouble}, Ptr{Cint}, Ptr{Cint}), tag, step, api_dataType_, api_tags_, api_tags_n_, api_data_, api_data_n_, api_data_nn_, api_time_, api_numComponents_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) dataType = unsafe_string(api_dataType_[]) tags = unsafe_wrap(Array, api_tags_[], api_tags_n_[], own=true) tmp_api_data_ = unsafe_wrap(Array, api_data_[], api_data_nn_[], own=true) tmp_api_data_n_ = unsafe_wrap(Array, api_data_n_[], api_data_nn_[], own=true) data = [ unsafe_wrap(Array, tmp_api_data_[i], tmp_api_data_n_[i], own=true) for i in 1:api_data_nn_[] ] return dataType, tags, data, api_time_[], api_numComponents_[] end const get_model_data = getModelData """ gmsh.view.getHomogeneousModelData(tag, step) Get homogeneous model-based post-processing data from the view with tag `tag` at step `step`. The arguments have the same meaning as in `getModelData`, except that `data` is returned flattened in a single vector, with the appropriate padding if necessary. Return `dataType`, `tags`, `data`, `time`, `numComponents`. """ function getHomogeneousModelData(tag, step) api_dataType_ = Ref{Ptr{Cchar}}() api_tags_ = Ref{Ptr{Csize_t}}() api_tags_n_ = Ref{Csize_t}() api_data_ = Ref{Ptr{Cdouble}}() api_data_n_ = Ref{Csize_t}() api_time_ = Ref{Cdouble}() api_numComponents_ = Ref{Cint}() ierr = Ref{Cint}() ccall((:gmshViewGetHomogeneousModelData, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Ptr{Cchar}}, Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Cdouble}, Ptr{Cint}, Ptr{Cint}), tag, step, api_dataType_, api_tags_, api_tags_n_, api_data_, api_data_n_, api_time_, api_numComponents_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) dataType = unsafe_string(api_dataType_[]) tags = unsafe_wrap(Array, api_tags_[], api_tags_n_[], own=true) data = unsafe_wrap(Array, api_data_[], api_data_n_[], own=true) return dataType, tags, data, api_time_[], api_numComponents_[] end const get_homogeneous_model_data = getHomogeneousModelData """ gmsh.view.addListData(tag, dataType, numEle, data) Add list-based post-processing data to the view with tag `tag`. List-based datasets are independent from any model and any mesh. `dataType` identifies the data by concatenating the field type ("S" for scalar, "V" for vector, "T" for tensor) and the element type ("P" for point, "L" for line, "T" for triangle, "S" for tetrahedron, "I" for prism, "H" for hexaHedron, "Y" for pyramid). For example `dataType` should be "ST" for a scalar field on triangles. `numEle` gives the number of elements in the data. `data` contains the data for the `numEle` elements, concatenated, with node coordinates followed by values per node, repeated for each step: [e1x1, ..., e1xn, e1y1, ..., e1yn, e1z1, ..., e1zn, e1v1..., e1vN, e2x1, ...]. """ function addListData(tag, dataType, numEle, data) ierr = Ref{Cint}() ccall((:gmshViewAddListData, gmsh.lib), Cvoid, (Cint, Ptr{Cchar}, Cint, Ptr{Cdouble}, Csize_t, Ptr{Cint}), tag, dataType, numEle, convert(Vector{Cdouble}, data), length(data), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const add_list_data = addListData """ gmsh.view.getListData(tag) Get list-based post-processing data from the view with tag `tag`. Return the types `dataTypes`, the number of elements `numElements` for each data type and the `data` for each data type. Return `dataType`, `numElements`, `data`. """ function getListData(tag) api_dataType_ = Ref{Ptr{Ptr{Cchar}}}() api_dataType_n_ = Ref{Csize_t}() api_numElements_ = Ref{Ptr{Cint}}() api_numElements_n_ = Ref{Csize_t}() api_data_ = Ref{Ptr{Ptr{Cdouble}}}() api_data_n_ = Ref{Ptr{Csize_t}}() api_data_nn_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshViewGetListData, gmsh.lib), Cvoid, (Cint, Ptr{Ptr{Ptr{Cchar}}}, Ptr{Csize_t}, Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Ptr{Ptr{Cdouble}}}, Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Ptr{Cint}), tag, api_dataType_, api_dataType_n_, api_numElements_, api_numElements_n_, api_data_, api_data_n_, api_data_nn_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_dataType_ = unsafe_wrap(Array, api_dataType_[], api_dataType_n_[], own=true) dataType = [unsafe_string(tmp_api_dataType_[i]) for i in 1:length(tmp_api_dataType_) ] numElements = unsafe_wrap(Array, api_numElements_[], api_numElements_n_[], own=true) tmp_api_data_ = unsafe_wrap(Array, api_data_[], api_data_nn_[], own=true) tmp_api_data_n_ = unsafe_wrap(Array, api_data_n_[], api_data_nn_[], own=true) data = [ unsafe_wrap(Array, tmp_api_data_[i], tmp_api_data_n_[i], own=true) for i in 1:api_data_nn_[] ] return dataType, numElements, data end const get_list_data = getListData """ gmsh.view.addListDataString(tag, coord, data, style = []) Add a string to a list-based post-processing view with tag `tag`. If `coord` contains 3 coordinates the string is positioned in the 3D model space ("3D string"); if it contains 2 coordinates it is positioned in the 2D graphics viewport ("2D string"). `data` contains one or more (for multistep views) strings. `style` contains key-value pairs of styling parameters, concatenated. Available keys are "Font" (possible values: "Times-Roman", "Times-Bold", "Times- Italic", "Times-BoldItalic", "Helvetica", "Helvetica-Bold", "Helvetica-Oblique", "Helvetica-BoldOblique", "Courier", "Courier-Bold", "Courier-Oblique", "Courier- BoldOblique", "Symbol", "ZapfDingbats", "Screen"), "FontSize" and "Align" (possible values: "Left" or "BottomLeft", "Center" or "BottomCenter", "Right" or "BottomRight", "TopLeft", "TopCenter", "TopRight", "CenterLeft", "CenterCenter", "CenterRight"). """ function addListDataString(tag, coord, data, style = []) ierr = Ref{Cint}() ccall((:gmshViewAddListDataString, gmsh.lib), Cvoid, (Cint, Ptr{Cdouble}, Csize_t, Ptr{Ptr{Cchar}}, Csize_t, Ptr{Ptr{Cchar}}, Csize_t, Ptr{Cint}), tag, convert(Vector{Cdouble}, coord), length(coord), data, length(data), style, length(style), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const add_list_data_string = addListDataString """ gmsh.view.getListDataStrings(tag, dim) Get list-based post-processing data strings (2D strings if `dim` = 2, 3D strings if `dim` = 3) from the view with tag `tag`. Return the coordinates in `coord`, the strings in `data` and the styles in `style`. Return `coord`, `data`, `style`. """ function getListDataStrings(tag, dim) api_coord_ = Ref{Ptr{Cdouble}}() api_coord_n_ = Ref{Csize_t}() api_data_ = Ref{Ptr{Ptr{Cchar}}}() api_data_n_ = Ref{Csize_t}() api_style_ = Ref{Ptr{Ptr{Cchar}}}() api_style_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshViewGetListDataStrings, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Ptr{Ptr{Cchar}}}, Ptr{Csize_t}, Ptr{Ptr{Ptr{Cchar}}}, Ptr{Csize_t}, Ptr{Cint}), tag, dim, api_coord_, api_coord_n_, api_data_, api_data_n_, api_style_, api_style_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) coord = unsafe_wrap(Array, api_coord_[], api_coord_n_[], own=true) tmp_api_data_ = unsafe_wrap(Array, api_data_[], api_data_n_[], own=true) data = [unsafe_string(tmp_api_data_[i]) for i in 1:length(tmp_api_data_) ] tmp_api_style_ = unsafe_wrap(Array, api_style_[], api_style_n_[], own=true) style = [unsafe_string(tmp_api_style_[i]) for i in 1:length(tmp_api_style_) ] return coord, data, style end const get_list_data_strings = getListDataStrings """ gmsh.view.setInterpolationMatrices(tag, type, d, coef, exp, dGeo = 0, coefGeo = Cdouble[], expGeo = Cdouble[]) Set interpolation matrices for the element family `type` ("Line", "Triangle", "Quadrangle", "Tetrahedron", "Hexahedron", "Prism", "Pyramid") in the view `tag`. The approximation of the values over an element is written as a linear combination of `d` basis functions f_i(u, v, w) = sum_(j = 0, ..., `d` - 1) `coef`[i][j] u^`exp`[j][0] v^`exp`[j][1] w^`exp`[j][2], i = 0, ..., `d`-1, with u, v, w the coordinates in the reference element. The `coef` matrix (of size `d` x `d`) and the `exp` matrix (of size `d` x 3) are stored as vectors, by row. If `dGeo` is positive, use `coefGeo` and `expGeo` to define the interpolation of the x, y, z coordinates of the element in terms of the u, v, w coordinates, in exactly the same way. If `d` < 0, remove the interpolation matrices. """ function setInterpolationMatrices(tag, type, d, coef, exp, dGeo = 0, coefGeo = Cdouble[], expGeo = Cdouble[]) ierr = Ref{Cint}() ccall((:gmshViewSetInterpolationMatrices, gmsh.lib), Cvoid, (Cint, Ptr{Cchar}, Cint, Ptr{Cdouble}, Csize_t, Ptr{Cdouble}, Csize_t, Cint, Ptr{Cdouble}, Csize_t, Ptr{Cdouble}, Csize_t, Ptr{Cint}), tag, type, d, convert(Vector{Cdouble}, coef), length(coef), convert(Vector{Cdouble}, exp), length(exp), dGeo, convert(Vector{Cdouble}, coefGeo), length(coefGeo), convert(Vector{Cdouble}, expGeo), length(expGeo), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_interpolation_matrices = setInterpolationMatrices """ gmsh.view.addAlias(refTag, copyOptions = false, tag = -1) Add a post-processing view as an `alias` of the reference view with tag `refTag`. If `copyOptions` is set, copy the options of the reference view. If `tag` is positive use it (and remove the view with that tag if it already exists), otherwise associate a new tag. Return the view tag. Return an integer value. """ function addAlias(refTag, copyOptions = false, tag = -1) ierr = Ref{Cint}() api_result_ = ccall((:gmshViewAddAlias, gmsh.lib), Cint, (Cint, Cint, Cint, Ptr{Cint}), refTag, copyOptions, tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const add_alias = addAlias """ gmsh.view.copyOptions(refTag, tag) Copy the options from the view with tag `refTag` to the view with tag `tag`. """ function copyOptions(refTag, tag) ierr = Ref{Cint}() ccall((:gmshViewCopyOptions, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cint}), refTag, tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const copy_options = copyOptions """ gmsh.view.combine(what, how, remove = true, copyOptions = true) Combine elements (if `what` == "elements") or steps (if `what` == "steps") of all views (`how` == "all"), all visible views (`how` == "visible") or all views having the same name (`how` == "name"). Remove original views if `remove` is set. """ function combine(what, how, remove = true, copyOptions = true) ierr = Ref{Cint}() ccall((:gmshViewCombine, gmsh.lib), Cvoid, (Ptr{Cchar}, Ptr{Cchar}, Cint, Cint, Ptr{Cint}), what, how, remove, copyOptions, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.view.probe(tag, x, y, z, step = -1, numComp = -1, gradient = false, tolerance = 0., xElemCoord = Cdouble[], yElemCoord = Cdouble[], zElemCoord = Cdouble[], dim = -1) Probe the view `tag` for its `value` at point (`x`, `y`, `z`). Return only the value at step `step` is `step` is positive. Return only values with `numComp` if `numComp` is positive. Return the gradient of the `value` if `gradient` is set. Probes with a geometrical tolerance (in the reference unit cube) of `tolerance` if `tolerance` is not zero. Return the result from the element described by its coordinates if `xElementCoord`, `yElementCoord` and `zElementCoord` are provided. If `dim` is >= 0, return only elements of the specified dimension. Return `value`. """ function probe(tag, x, y, z, step = -1, numComp = -1, gradient = false, tolerance = 0., xElemCoord = Cdouble[], yElemCoord = Cdouble[], zElemCoord = Cdouble[], dim = -1) api_value_ = Ref{Ptr{Cdouble}}() api_value_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshViewProbe, gmsh.lib), Cvoid, (Cint, Cdouble, Cdouble, Cdouble, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Cint, Cint, Cint, Cdouble, Ptr{Cdouble}, Csize_t, Ptr{Cdouble}, Csize_t, Ptr{Cdouble}, Csize_t, Cint, Ptr{Cint}), tag, x, y, z, api_value_, api_value_n_, step, numComp, gradient, tolerance, convert(Vector{Cdouble}, xElemCoord), length(xElemCoord), convert(Vector{Cdouble}, yElemCoord), length(yElemCoord), convert(Vector{Cdouble}, zElemCoord), length(zElemCoord), dim, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) value = unsafe_wrap(Array, api_value_[], api_value_n_[], own=true) return value end """ gmsh.view.write(tag, fileName, append = false) Write the view to a file `fileName`. The export format is determined by the file extension. Append to the file if `append` is set. """ function write(tag, fileName, append = false) ierr = Ref{Cint}() ccall((:gmshViewWrite, gmsh.lib), Cvoid, (Cint, Ptr{Cchar}, Cint, Ptr{Cint}), tag, fileName, append, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.view.setVisibilityPerWindow(tag, value, windowIndex = 0) Set the global visibility of the view `tag` per window to `value`, where `windowIndex` identifies the window in the window list. """ function setVisibilityPerWindow(tag, value, windowIndex = 0) ierr = Ref{Cint}() ccall((:gmshViewSetVisibilityPerWindow, gmsh.lib), Cvoid, (Cint, Cint, Cint, Ptr{Cint}), tag, value, windowIndex, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_visibility_per_window = setVisibilityPerWindow end # end of module view """ module gmsh.plugin Plugin functions """ module plugin import ..gmsh """ gmsh.plugin.setNumber(name, option, value) Set the numerical option `option` to the value `value` for plugin `name`. """ function setNumber(name, option, value) ierr = Ref{Cint}() ccall((:gmshPluginSetNumber, gmsh.lib), Cvoid, (Ptr{Cchar}, Ptr{Cchar}, Cdouble, Ptr{Cint}), name, option, value, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_number = setNumber """ gmsh.plugin.setString(name, option, value) Set the string option `option` to the value `value` for plugin `name`. """ function setString(name, option, value) ierr = Ref{Cint}() ccall((:gmshPluginSetString, gmsh.lib), Cvoid, (Ptr{Cchar}, Ptr{Cchar}, Ptr{Cchar}, Ptr{Cint}), name, option, value, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_string = setString """ gmsh.plugin.run(name) Run the plugin `name`. """ function run(name) ierr = Ref{Cint}() ccall((:gmshPluginRun, gmsh.lib), Cvoid, (Ptr{Cchar}, Ptr{Cint}), name, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end end # end of module plugin """ module gmsh.graphics Graphics functions """ module graphics import ..gmsh """ gmsh.graphics.draw() Draw all the OpenGL scenes. """ function draw() ierr = Ref{Cint}() ccall((:gmshGraphicsDraw, gmsh.lib), Cvoid, (Ptr{Cint},), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end end # end of module graphics """ module gmsh.fltk FLTK graphical user interface functions """ module fltk import ..gmsh """ gmsh.fltk.initialize() Create the FLTK graphical user interface. Can only be called in the main thread. """ function initialize() ierr = Ref{Cint}() ccall((:gmshFltkInitialize, gmsh.lib), Cvoid, (Ptr{Cint},), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.fltk.wait(time = -1.) Wait at most `time` seconds for user interface events and return. If `time` < 0, wait indefinitely. First automatically create the user interface if it has not yet been initialized. Can only be called in the main thread. """ function wait(time = -1.) ierr = Ref{Cint}() ccall((:gmshFltkWait, gmsh.lib), Cvoid, (Cdouble, Ptr{Cint}), time, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.fltk.update() Update the user interface (potentially creating new widgets and windows). First automatically create the user interface if it has not yet been initialized. Can only be called in the main thread: use `awake("update")` to trigger an update of the user interface from another thread. """ function update() ierr = Ref{Cint}() ccall((:gmshFltkUpdate, gmsh.lib), Cvoid, (Ptr{Cint},), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.fltk.awake(action = "") Awake the main user interface thread and process pending events, and optionally perform an action (currently the only `action` allowed is "update"). """ function awake(action = "") ierr = Ref{Cint}() ccall((:gmshFltkAwake, gmsh.lib), Cvoid, (Ptr{Cchar}, Ptr{Cint}), action, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.fltk.lock() Block the current thread until it can safely modify the user interface. """ function lock() ierr = Ref{Cint}() ccall((:gmshFltkLock, gmsh.lib), Cvoid, (Ptr{Cint},), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.fltk.unlock() Release the lock that was set using lock. """ function unlock() ierr = Ref{Cint}() ccall((:gmshFltkUnlock, gmsh.lib), Cvoid, (Ptr{Cint},), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.fltk.run() Run the event loop of the graphical user interface, i.e. repeatedly call `wait()`. First automatically create the user interface if it has not yet been initialized. Can only be called in the main thread. """ function run() ierr = Ref{Cint}() ccall((:gmshFltkRun, gmsh.lib), Cvoid, (Ptr{Cint},), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.fltk.isAvailable() Check if the user interface is available (e.g. to detect if it has been closed). Return an integer value. """ function isAvailable() ierr = Ref{Cint}() api_result_ = ccall((:gmshFltkIsAvailable, gmsh.lib), Cint, (Ptr{Cint},), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const is_available = isAvailable """ gmsh.fltk.selectEntities(dim = -1) Select entities in the user interface. If `dim` is >= 0, return only the entities of the specified dimension (e.g. points if `dim` == 0). Return an integer value, `dimTags`. """ function selectEntities(dim = -1) api_dimTags_ = Ref{Ptr{Cint}}() api_dimTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() api_result_ = ccall((:gmshFltkSelectEntities, gmsh.lib), Cint, (Ptr{Ptr{Cint}}, Ptr{Csize_t}, Cint, Ptr{Cint}), api_dimTags_, api_dimTags_n_, dim, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_dimTags_ = unsafe_wrap(Array, api_dimTags_[], api_dimTags_n_[], own=true) dimTags = [ (tmp_api_dimTags_[i], tmp_api_dimTags_[i+1]) for i in 1:2:length(tmp_api_dimTags_) ] return api_result_, dimTags end const select_entities = selectEntities """ gmsh.fltk.selectElements() Select elements in the user interface. Return an integer value, `elementTags`. """ function selectElements() api_elementTags_ = Ref{Ptr{Csize_t}}() api_elementTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() api_result_ = ccall((:gmshFltkSelectElements, gmsh.lib), Cint, (Ptr{Ptr{Csize_t}}, Ptr{Csize_t}, Ptr{Cint}), api_elementTags_, api_elementTags_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) elementTags = unsafe_wrap(Array, api_elementTags_[], api_elementTags_n_[], own=true) return api_result_, elementTags end const select_elements = selectElements """ gmsh.fltk.selectViews() Select views in the user interface. Return an integer value, `viewTags`. """ function selectViews() api_viewTags_ = Ref{Ptr{Cint}}() api_viewTags_n_ = Ref{Csize_t}() ierr = Ref{Cint}() api_result_ = ccall((:gmshFltkSelectViews, gmsh.lib), Cint, (Ptr{Ptr{Cint}}, Ptr{Csize_t}, Ptr{Cint}), api_viewTags_, api_viewTags_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) viewTags = unsafe_wrap(Array, api_viewTags_[], api_viewTags_n_[], own=true) return api_result_, viewTags end const select_views = selectViews """ gmsh.fltk.splitCurrentWindow(how = "v", ratio = 0.5) Split the current window horizontally (if `how` = "h") or vertically (if `how` = "v"), using ratio `ratio`. If `how` = "u", restore a single window. """ function splitCurrentWindow(how = "v", ratio = 0.5) ierr = Ref{Cint}() ccall((:gmshFltkSplitCurrentWindow, gmsh.lib), Cvoid, (Ptr{Cchar}, Cdouble, Ptr{Cint}), how, ratio, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const split_current_window = splitCurrentWindow """ gmsh.fltk.setCurrentWindow(windowIndex = 0) Set the current window by speficying its index (starting at 0) in the list of all windows. When new windows are created by splits, new windows are appended at the end of the list. """ function setCurrentWindow(windowIndex = 0) ierr = Ref{Cint}() ccall((:gmshFltkSetCurrentWindow, gmsh.lib), Cvoid, (Cint, Ptr{Cint}), windowIndex, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_current_window = setCurrentWindow """ gmsh.fltk.setStatusMessage(message, graphics = false) Set a status message in the current window. If `graphics` is set, display the message inside the graphic window instead of the status bar. """ function setStatusMessage(message, graphics = false) ierr = Ref{Cint}() ccall((:gmshFltkSetStatusMessage, gmsh.lib), Cvoid, (Ptr{Cchar}, Cint, Ptr{Cint}), message, graphics, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_status_message = setStatusMessage """ gmsh.fltk.showContextWindow(dim, tag) Show context window for the entity of dimension `dim` and tag `tag`. """ function showContextWindow(dim, tag) ierr = Ref{Cint}() ccall((:gmshFltkShowContextWindow, gmsh.lib), Cvoid, (Cint, Cint, Ptr{Cint}), dim, tag, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const show_context_window = showContextWindow """ gmsh.fltk.openTreeItem(name) Open the `name` item in the menu tree. """ function openTreeItem(name) ierr = Ref{Cint}() ccall((:gmshFltkOpenTreeItem, gmsh.lib), Cvoid, (Ptr{Cchar}, Ptr{Cint}), name, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const open_tree_item = openTreeItem """ gmsh.fltk.closeTreeItem(name) Close the `name` item in the menu tree. """ function closeTreeItem(name) ierr = Ref{Cint}() ccall((:gmshFltkCloseTreeItem, gmsh.lib), Cvoid, (Ptr{Cchar}, Ptr{Cint}), name, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const close_tree_item = closeTreeItem end # end of module fltk """ module gmsh.onelab ONELAB server functions """ module onelab import ..gmsh """ gmsh.onelab.set(data, format = "json") Set one or more parameters in the ONELAB database, encoded in `format`. """ function set(data, format = "json") ierr = Ref{Cint}() ccall((:gmshOnelabSet, gmsh.lib), Cvoid, (Ptr{Cchar}, Ptr{Cchar}, Ptr{Cint}), data, format, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.onelab.get(name = "", format = "json") Get all the parameters (or a single one if `name` is specified) from the ONELAB database, encoded in `format`. Return `data`. """ function get(name = "", format = "json") api_data_ = Ref{Ptr{Cchar}}() ierr = Ref{Cint}() ccall((:gmshOnelabGet, gmsh.lib), Cvoid, (Ptr{Ptr{Cchar}}, Ptr{Cchar}, Ptr{Cchar}, Ptr{Cint}), api_data_, name, format, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) data = unsafe_string(api_data_[]) return data end """ gmsh.onelab.getNames(search = "") Get the names of the parameters in the ONELAB database matching the `search` regular expression. If `search` is empty, return all the names. Return `names`. """ function getNames(search = "") api_names_ = Ref{Ptr{Ptr{Cchar}}}() api_names_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshOnelabGetNames, gmsh.lib), Cvoid, (Ptr{Ptr{Ptr{Cchar}}}, Ptr{Csize_t}, Ptr{Cchar}, Ptr{Cint}), api_names_, api_names_n_, search, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_names_ = unsafe_wrap(Array, api_names_[], api_names_n_[], own=true) names = [unsafe_string(tmp_api_names_[i]) for i in 1:length(tmp_api_names_) ] return names end const get_names = getNames """ gmsh.onelab.setNumber(name, value) Set the value of the number parameter `name` in the ONELAB database. Create the parameter if it does not exist; update the value if the parameter exists. """ function setNumber(name, value) ierr = Ref{Cint}() ccall((:gmshOnelabSetNumber, gmsh.lib), Cvoid, (Ptr{Cchar}, Ptr{Cdouble}, Csize_t, Ptr{Cint}), name, convert(Vector{Cdouble}, value), length(value), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_number = setNumber """ gmsh.onelab.setString(name, value) Set the value of the string parameter `name` in the ONELAB database. Create the parameter if it does not exist; update the value if the parameter exists. """ function setString(name, value) ierr = Ref{Cint}() ccall((:gmshOnelabSetString, gmsh.lib), Cvoid, (Ptr{Cchar}, Ptr{Ptr{Cchar}}, Csize_t, Ptr{Cint}), name, value, length(value), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end const set_string = setString """ gmsh.onelab.getNumber(name) Get the value of the number parameter `name` from the ONELAB database. Return an empty vector if the parameter does not exist. Return `value`. """ function getNumber(name) api_value_ = Ref{Ptr{Cdouble}}() api_value_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshOnelabGetNumber, gmsh.lib), Cvoid, (Ptr{Cchar}, Ptr{Ptr{Cdouble}}, Ptr{Csize_t}, Ptr{Cint}), name, api_value_, api_value_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) value = unsafe_wrap(Array, api_value_[], api_value_n_[], own=true) return value end const get_number = getNumber """ gmsh.onelab.getString(name) Get the value of the string parameter `name` from the ONELAB database. Return an empty vector if the parameter does not exist. Return `value`. """ function getString(name) api_value_ = Ref{Ptr{Ptr{Cchar}}}() api_value_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshOnelabGetString, gmsh.lib), Cvoid, (Ptr{Cchar}, Ptr{Ptr{Ptr{Cchar}}}, Ptr{Csize_t}, Ptr{Cint}), name, api_value_, api_value_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_value_ = unsafe_wrap(Array, api_value_[], api_value_n_[], own=true) value = [unsafe_string(tmp_api_value_[i]) for i in 1:length(tmp_api_value_) ] return value end const get_string = getString """ gmsh.onelab.clear(name = "") Clear the ONELAB database, or remove a single parameter if `name` is given. """ function clear(name = "") ierr = Ref{Cint}() ccall((:gmshOnelabClear, gmsh.lib), Cvoid, (Ptr{Cchar}, Ptr{Cint}), name, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.onelab.run(name = "", command = "") Run a ONELAB client. If `name` is provided, create a new ONELAB client with name `name` and executes `command`. If not, try to run a client that might be linked to the processed input files. """ function run(name = "", command = "") ierr = Ref{Cint}() ccall((:gmshOnelabRun, gmsh.lib), Cvoid, (Ptr{Cchar}, Ptr{Cchar}, Ptr{Cint}), name, command, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end end # end of module onelab """ module gmsh.logger Information logging functions """ module logger import ..gmsh """ gmsh.logger.write(message, level = "info") Write a `message`. `level` can be "info", "warning" or "error". """ function write(message, level = "info") ierr = Ref{Cint}() ccall((:gmshLoggerWrite, gmsh.lib), Cvoid, (Ptr{Cchar}, Ptr{Cchar}, Ptr{Cint}), message, level, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.logger.start() Start logging messages. """ function start() ierr = Ref{Cint}() ccall((:gmshLoggerStart, gmsh.lib), Cvoid, (Ptr{Cint},), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.logger.get() Get logged messages. Return `log`. """ function get() api_log_ = Ref{Ptr{Ptr{Cchar}}}() api_log_n_ = Ref{Csize_t}() ierr = Ref{Cint}() ccall((:gmshLoggerGet, gmsh.lib), Cvoid, (Ptr{Ptr{Ptr{Cchar}}}, Ptr{Csize_t}, Ptr{Cint}), api_log_, api_log_n_, ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) tmp_api_log_ = unsafe_wrap(Array, api_log_[], api_log_n_[], own=true) log = [unsafe_string(tmp_api_log_[i]) for i in 1:length(tmp_api_log_) ] return log end """ gmsh.logger.stop() Stop logging messages. """ function stop() ierr = Ref{Cint}() ccall((:gmshLoggerStop, gmsh.lib), Cvoid, (Ptr{Cint},), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return nothing end """ gmsh.logger.getWallTime() Return wall clock time. Return a floating point value. """ function getWallTime() ierr = Ref{Cint}() api_result_ = ccall((:gmshLoggerGetWallTime, gmsh.lib), Cdouble, (Ptr{Cint},), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const get_wall_time = getWallTime """ gmsh.logger.getCpuTime() Return CPU time. Return a floating point value. """ function getCpuTime() ierr = Ref{Cint}() api_result_ = ccall((:gmshLoggerGetCpuTime, gmsh.lib), Cdouble, (Ptr{Cint},), ierr) ierr[] != 0 && error(gmsh.logger.getLastError()) return api_result_ end const get_cpu_time = getCpuTime """ gmsh.logger.getLastError() Return last error message, if any. Return `error`. """ function getLastError() api_error_ = Ref{Ptr{Cchar}}() ierr = Ref{Cint}() ccall((:gmshLoggerGetLastError, gmsh.lib), Cvoid, (Ptr{Ptr{Cchar}}, Ptr{Cint}), api_error_, ierr) ierr[] != 0 && error("Could not get last error") error = unsafe_string(api_error_[]) return error end const get_last_error = getLastError end # end of module logger end # end of module gmsh