R/MsBackendMassbank.R
In michaelwitting/MsBackendMassbank: Mass Spectrometry Data Backend for MassBank record Files
Defines functions
spectraVariableMapping
MsBackendMassbank
Documented in
MsBackendMassbank
spectraVariableMapping
#' @include hidden_aliases.R
NULL
#' @title MS data backend for mgf files
#'
#' @aliases MsBackendMassbank-class
#'
#' @description
#'
#' The `MsBackendMassbank` class supports import of MS/MS spectra data from
#' MS/MS spectrum data from
#' [Massbank](https://github.com/MassBank/MassBank-data)
#' files. After initial import, the full MS data is kept in
#' memory. `MsBackendMassbank` extends the [MsBackendDataFrame()] backend
#' directly and supports thus the [applyProcessing()] function to make
#' data manipulations persistent.
#'
#' New objects are created with the `MsBackendMassbank` function. The
#' `backendInitialize` method has to be subsequently called to
#' initialize the object and import MS/MS data from (one or more) MassBank
#' files. Optional parameter `nonStop` allows to specify whether the
#' import returns with an error if one of the text files lacks required
#' data, such as `mz` and `intensity` values (default `nonStop =
#' FALSE`), or whether only affected file(s) is(are) skipped and a
#' warning is shown (`nonStop = TRUE`). Note that any other error
#' will abort import regardless of parameter `nonStop`.
#'
#' @param object Instance of `MsBackendMassbank` class.
#'
#' @param file for `export`: `character(1)` defining the output file.
#'
#' @param files `character` with the (full) file name(s) of the MassBank file(s)
#' from which MS/MS data should be imported.
#'
#' @param format for `spectraVariableMapping`: `character(1)` defining the
#' format to be used. Currently only `format = "Massbank"` is supported.
#'
#' @param mapping for `export`: named `character` vector
#' allowing to specify how fields from the Massbank file should be renamed.
#' Names are supposed to be the spectra variable name and values of the
#' vector the field names in the Massbank file. See output of
#' `spectraVariableMapping()` for the expected format.
#'
#' @param metaBlocks `data.frame` indicating which metadata shall
#' be imported. Default is [metaDataBlocks()].
#'
#' @param nonStop `logical(1)` whether import should be stopped if an
#' xml file does not contain all required fields. Defaults to
#' `nonStop = FALSE`.
#'
#' @param BPPARAM Parameter object defining the parallel processing
#' setup to import data in parallel. Defaults to `BPPARAM =
#' bpparam()`. See [bpparam()] for more information.
#'
#' @param x [Spectra()] object that should be exported.
#'
#' @param ... Currently ignored.
#'
#' @author Michael Witting
#'
#' @importClassesFrom Spectra MsBackendDataFrame
#'
#' @exportClass MsBackendMassbank
#'
#' @name MsBackendMassbank
#'
#' @return `backendInitialize` and `MsBackendMassbank` return an instance of
#' `MsBackendMassbank-class`.
#'
#' @examples
#'
#' ## Create an MsBackendMassbank backend and import data from a test file.
#' fls <- dir(system.file("extdata", package = "MsBackendMassbank"),
#' full.names = TRUE, pattern = "txt$")
#' be <- backendInitialize(MsBackendMassbank(), fls)
#' be
#'
#' be$msLevel
#' be$intensity
#' be$mz
#'
#' ## Initializing a backend reading additional metadata columns/information
#' mb <- metaDataBlocks()
#' mb
#' mb[1, 2] <- TRUE
#'
#' be <- backendInitialize(MsBackendMassbank(), fls, metaBlocks = mb)
#' spectraVariables(be)
#' be$instrument
NULL
setClass("MsBackendMassbank",
contains = "MsBackendDataFrame",
prototype = prototype(spectraData = DataFrame(),
readonly = FALSE,
version = "0.1"))
#' @importMethodsFrom Spectra backendInitialize spectraData<- $<- $
#'
#' @importFrom BiocParallel bpparam
#'
#' @importFrom S4Vectors bindROWS
#'
#' @importMethodsFrom BiocParallel bplapply
#'
#' @importFrom methods validObject
#'
#' @exportMethod backendInitialize
#'
#' @rdname MsBackendMassbank
setMethod("backendInitialize", signature = "MsBackendMassbank",
function(object, files, metaBlocks = metaDataBlocks(),
nonStop = FALSE, ..., BPPARAM = bpparam()) {
if (missing(files) || !length(files))
stop("Parameter 'files' is mandatory for ", class(object))
if (!is.character(files))
stop("Parameter 'files' is expected to be a character vector",
" with the files names from where data should be",
" imported")
suppressWarnings(files <- normalizePath(files))
if (any(!file.exists(files))) {
stop("file(s) ",
paste(files[!file.exists(files)], collapse = ", "),
" not found")
}
## Import data and rbind.
message("Start data import from ", length(files), " files ... ",
appendLF = FALSE)
res <- bplapply(files, FUN = .read_massbank,
metaBlocks = metaBlocks,
nonStop = nonStop, BPPARAM = BPPARAM)
message("done")
res <- bindROWS(DataFrame(), objects = res, use.names = FALSE,
ignore.mcols = TRUE, check = FALSE)
if (nonStop && length(files) > nrow(res)) {
warning("Import failed for ", length(files) - nrow(res),
" files")
}
spectraData(object) <- res
object$dataStorage <- "<memory>"
validObject(object)
object
})
#' @rdname MsBackendMassbank
#'
#' @importFrom methods new
#'
#' @export MsBackendMassbank
MsBackendMassbank <- function() {
new("MsBackendMassbank")
}
#' @export
#'
#' @rdname MsBackendMassbank
spectraVariableMapping <- function(format = c("Massbank")) {
## In future eventually define that in a text file and import upon package
## init.
switch(match.arg(format),
"Massbank" = c(
# minimal information
accession = "ACCESSION:",
name = "CH$NAME:",
smiles = "CH$SMILES:",
exactmass = "CH$EXACT_MASS:",
formula = "CH$FORMULA:",
inchi = "CH$IUPAC:",
cas = "CH$LINK: CAS",
inchikey = "CH$LINK: INCHIKEY",
collisionEnergy = "AC$MASS_SPECTROMETRY: COLLISION_ENERGY",
precursorMz = "MS$FOCUSED_ION: PRECURSOR_M/Z",
precursorIntensity = "MS$FOCUSED_ION: PRECURSOR_INT",
adduct = "MS$FOCUSED_ION: PRECURSOR_TYPE",
rtime = "AC$CHROMATOGRAPHY: RETENTION_TIME",
polarity = "AC$MASS_SPECTROMETRY: ION_MODE",
splash = "PK$SPLASH:",
title = "RECORD_TITLE:",
# instrument information
instrument = "AC$INSTRUMENT:",
instrument_type = "AC$INSTRUMENT_TYPE:",
# ms information
ms_ms_type = "AC$MASS_SPECTROMETRY: MS_TYPE",
ms_cap_voltage = "AC$MASS_SPECTROMETRY: CAPILLARY_VOLTAGE",
ms_col_gas = "AC$MASS_SPECTROMETRY: COLLISION_GAS",
ms_desolv_gas_flow = "AC$MASS_SPECTROMETRY: DESOLVATION_GAS_FLOW",
ms_desolv_temp = "AC$MASS_SPECTROMETRY: DESOLVATION_TEMPERATURE",
ms_ionization = "AC$MASS_SPECTROMETRY: IONIZATION",
ms_ionization_energy = "AC$MASS_SPECTROMETRY: IONIZATION_ENERGY",
ms_laser = "AC$MASS_SPECTROMETRY: LASER",
ms_matrix = "AC$MASS_SPECTROMETRY: MATRIX",
ms_mass_accuracy = "AC$MASS_SPECTROMETRY: MASS_ACCURACY",
ms_mass_range = "AC$MASS_SPECTROMETRY: MASS_RANGE_MZ",
ms_reagent_gas = "AC$MASS_SPECTROMETRY: REAGENT_GAS",
ms_resolution = "AC$MASS_SPECTROMETRY: RESOLUTION",
ms_scan_setting = "AC$MASS_SPECTROMETRY: SCANNING_SETTING",
ms_source_temp = "AC$MASS_SPECTROMETRY: SOURCE_TEMPERATURE",
ms_frag_mode = "AC$MASS_SPECTROMETRY: FRAGMENTATION_MODE",
# ims information
ims_instrument_type = "AC$ION_MOBILITY: INSTRUMENT_TYPE",
ims_drift_gas = "AC$ION_MOBILITY: DRIFT_GAS",
ims_drift_time = "AC$ION_MOBILITY: DRIFT_TIME",
ims_ccs = "AC$ION_MOBILITY: CCS",
# ms information part II
focus_base_peak = "MS$FOCUSED_ION: BASE_PEAK",
focus_derivative_form = "MS$FOCUSED_ION: DERIVATIVE_FORM",
focus_derivative_mass = "MS$FOCUSED_ION: DERIVATIVE_MASS",
focus_derivative_type = "MS$FOCUSED_ION: DERIVATIVE_TYPE",
focus_ion_type = "MS$FOCUSED_ION: ION_TYPE",
# data processing information
data_processing_comment = "MS$DATA_PROCESSING: COMMENT",
data_processing_deprofile = "MS$DATA_PROCESSING: DEPROFILE",
data_processing_find = "MS$DATA_PROCESSING: FIND_PEAK",
data_processing_reanalyze = "MS$DATA_PROCESSING: REANALYZE",
data_processing_recalibrate = "MS$DATA_PROCESSING: RECALIBRATE",
data_processing_whole = "MS$DATA_PROCESSING: WHOLE",
# chromatography information
chrom_carrier_gas = "AC$CHROMATOGRAPHY: CARRIER_GAS",
chrom_column = "AC$CHROMATOGRAPHY: COLUMN_NAME",
chrom_column_temp = "AC$CHROMATOGRAPHY: COLUMN_TEMPERATURE",
chrom_column_temp_gradient =
"AC$CHROMATOGRAPHY: COLUMN_TEMPERATURE_GRADIENT",
chrom_flow_gradient = "AC$CHROMATOGRAPHY: FLOW_GRADIENT",
chrom_flow_rate = "AC$CHROMATOGRAPHY: FLOW_RATE",
chrom_inj_temp = "AC$CHROMATOGRAPHY: INJECTION_TEMPERATURE",
chrom_inj_temp_gradient =
"AC$CHROMATOGRAPHY: INJECTION_TEMPERATURE_GRADIENT",
chrom_rti_kovats = "AC$CHROMATOGRAPHY: KOVATS_RTI",
chrom_rti_lee = "AC$CHROMATOGRAPHY: LEE_RTI",
chrom_rti_naps = "AC$CHROMATOGRAPHY: NAPS_RTI",
chrom_rti_uoa = "AC$CHROMATOGRAPHY: UOA_RTI",
chrom_rti_uoa_pred = "AC$CHROMATOGRAPHY: UOA_PREDICTED_RTI",
chrom_rt = "AC$CHROMATOGRAPHY: RETENTION_TIME",
chrom_solvent = "AC$CHROMATOGRAPHY: SOLVENT",
chrom_transfer_temp = "AC$CHROMATOGRAPHY: TRANSFERLINE_TEMPERATURE",
# chemical information
compound_class = "CH$COMPOUND_CLASS:",
link_cayman = "CH$LINK: CAYMAN",
link_chebi = "CH$LINK: CHEBI",
link_chembl = "CH$LINK: CHEMBL",
link_chempdb = "CH$LINK: CHEMPDB",
link_chemspider = "CH$LINK: CHEMSPIDER",
link_comptox = "CH$LINK: COMPTOX",
link_hmdb = "CH$LINK: HMDB",
link_kappaview = "CH$LINK: KAPPAVIEW",
link_kegg = "CH$LINK: KEGG",
link_knapsack = "CH$LINK: KNAPSACK",
link_lipidbank = "CH$LINK: LIPIDBANK",
link_lipidmaps = "CH$LINK: LIPIDMAPS",
link_nikkaji = "CH$LINK: NIKKAJI",
link_pubchem = "CH$LINK: PUBCHEM",
link_zinc = "CH$LINK: ZINC",
# sample information
scientific_name = "SP$SCIENTIFIC_NAME:",
lineage = "SP$LINEAGE:",
link = "SP$LINK:",
sample = "SP$SAMPLE:",
# record information
deprecated = "DEPRECATED:",
date = "DATE:",
authors = "AUTHORS:",
license = "LICENSE:",
copyright = "COPYRIGHT:",
publication = "PUBLICATION:",
project = "PROJECT:",
# peak information
pknum = "PK$NUM_PEAK:"
)
)
}
#' @importMethodsFrom Spectra export
#'
#' @exportMethod export
#'
#' @rdname MsBackendMassbank
setMethod("export", "MsBackendMassbank",
function(object, x, file = tempfile(),
mapping = spectraVariableMapping(), ...) {
.export_massbank(x = x, con = file, mapping = mapping)
})
michaelwitting/MsBackendMassbank documentation built on March 16, 2021, 2:14 a.m.
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
Defines functions spectraVariableMapping MsBackendMassbank
Documented in MsBackendMassbank spectraVariableMapping
#' @include hidden_aliases.R
NULL
#' @title MS data backend for mgf files
#'
#' @aliases MsBackendMassbank-class
#'
#' @description
#'
#' The `MsBackendMassbank` class supports import of MS/MS spectra data from
#' MS/MS spectrum data from
#' [Massbank](https://github.com/MassBank/MassBank-data)
#' files. After initial import, the full MS data is kept in
#' memory. `MsBackendMassbank` extends the [MsBackendDataFrame()] backend
#' directly and supports thus the [applyProcessing()] function to make
#' data manipulations persistent.
#'
#' New objects are created with the `MsBackendMassbank` function. The
#' `backendInitialize` method has to be subsequently called to
#' initialize the object and import MS/MS data from (one or more) MassBank
#' files. Optional parameter `nonStop` allows to specify whether the
#' import returns with an error if one of the text files lacks required
#' data, such as `mz` and `intensity` values (default `nonStop =
#' FALSE`), or whether only affected file(s) is(are) skipped and a
#' warning is shown (`nonStop = TRUE`). Note that any other error
#' will abort import regardless of parameter `nonStop`.
#'
#' @param object Instance of `MsBackendMassbank` class.
#'
#' @param file for `export`: `character(1)` defining the output file.
#'
#' @param files `character` with the (full) file name(s) of the MassBank file(s)
#' from which MS/MS data should be imported.
#'
#' @param format for `spectraVariableMapping`: `character(1)` defining the
#' format to be used. Currently only `format = "Massbank"` is supported.
#'
#' @param mapping for `export`: named `character` vector
#' allowing to specify how fields from the Massbank file should be renamed.
#' Names are supposed to be the spectra variable name and values of the
#' vector the field names in the Massbank file. See output of
#' `spectraVariableMapping()` for the expected format.
#'
#' @param metaBlocks `data.frame` indicating which metadata shall
#' be imported. Default is [metaDataBlocks()].
#'
#' @param nonStop `logical(1)` whether import should be stopped if an
#' xml file does not contain all required fields. Defaults to
#' `nonStop = FALSE`.
#'
#' @param BPPARAM Parameter object defining the parallel processing
#' setup to import data in parallel. Defaults to `BPPARAM =
#' bpparam()`. See [bpparam()] for more information.
#'
#' @param x [Spectra()] object that should be exported.
#'
#' @param ... Currently ignored.
#'
#' @author Michael Witting
#'
#' @importClassesFrom Spectra MsBackendDataFrame
#'
#' @exportClass MsBackendMassbank
#'
#' @name MsBackendMassbank
#'
#' @return `backendInitialize` and `MsBackendMassbank` return an instance of
#' `MsBackendMassbank-class`.
#'
#' @examples
#'
#' ## Create an MsBackendMassbank backend and import data from a test file.
#' fls <- dir(system.file("extdata", package = "MsBackendMassbank"),
#' full.names = TRUE, pattern = "txt$")
#' be <- backendInitialize(MsBackendMassbank(), fls)
#' be
#'
#' be$msLevel
#' be$intensity
#' be$mz
#'
#' ## Initializing a backend reading additional metadata columns/information
#' mb <- metaDataBlocks()
#' mb
#' mb[1, 2] <- TRUE
#'
#' be <- backendInitialize(MsBackendMassbank(), fls, metaBlocks = mb)
#' spectraVariables(be)
#' be$instrument
NULL
setClass("MsBackendMassbank",
contains = "MsBackendDataFrame",
prototype = prototype(spectraData = DataFrame(),
readonly = FALSE,
version = "0.1"))
#' @importMethodsFrom Spectra backendInitialize spectraData<- $<- $
#'
#' @importFrom BiocParallel bpparam
#'
#' @importFrom S4Vectors bindROWS
#'
#' @importMethodsFrom BiocParallel bplapply
#'
#' @importFrom methods validObject
#'
#' @exportMethod backendInitialize
#'
#' @rdname MsBackendMassbank
setMethod("backendInitialize", signature = "MsBackendMassbank",
function(object, files, metaBlocks = metaDataBlocks(),
nonStop = FALSE, ..., BPPARAM = bpparam()) {
if (missing(files) || !length(files))
stop("Parameter 'files' is mandatory for ", class(object))
if (!is.character(files))
stop("Parameter 'files' is expected to be a character vector",
" with the files names from where data should be",
" imported")
suppressWarnings(files <- normalizePath(files))
if (any(!file.exists(files))) {
stop("file(s) ",
paste(files[!file.exists(files)], collapse = ", "),
" not found")
}
## Import data and rbind.
message("Start data import from ", length(files), " files ... ",
appendLF = FALSE)
res <- bplapply(files, FUN = .read_massbank,
metaBlocks = metaBlocks,
nonStop = nonStop, BPPARAM = BPPARAM)
message("done")
res <- bindROWS(DataFrame(), objects = res, use.names = FALSE,
ignore.mcols = TRUE, check = FALSE)
if (nonStop && length(files) > nrow(res)) {
warning("Import failed for ", length(files) - nrow(res),
" files")
}
spectraData(object) <- res
object$dataStorage <- "<memory>"
validObject(object)
object
})
#' @rdname MsBackendMassbank
#'
#' @importFrom methods new
#'
#' @export MsBackendMassbank
MsBackendMassbank <- function() {
new("MsBackendMassbank")
}
#' @export
#'
#' @rdname MsBackendMassbank
spectraVariableMapping <- function(format = c("Massbank")) {
## In future eventually define that in a text file and import upon package
## init.
switch(match.arg(format),
"Massbank" = c(
# minimal information
accession = "ACCESSION:",
name = "CH$NAME:",
smiles = "CH$SMILES:",
exactmass = "CH$EXACT_MASS:",
formula = "CH$FORMULA:",
inchi = "CH$IUPAC:",
cas = "CH$LINK: CAS",
inchikey = "CH$LINK: INCHIKEY",
collisionEnergy = "AC$MASS_SPECTROMETRY: COLLISION_ENERGY",
precursorMz = "MS$FOCUSED_ION: PRECURSOR_M/Z",
precursorIntensity = "MS$FOCUSED_ION: PRECURSOR_INT",
adduct = "MS$FOCUSED_ION: PRECURSOR_TYPE",
rtime = "AC$CHROMATOGRAPHY: RETENTION_TIME",
polarity = "AC$MASS_SPECTROMETRY: ION_MODE",
splash = "PK$SPLASH:",
title = "RECORD_TITLE:",
# instrument information
instrument = "AC$INSTRUMENT:",
instrument_type = "AC$INSTRUMENT_TYPE:",
# ms information
ms_ms_type = "AC$MASS_SPECTROMETRY: MS_TYPE",
ms_cap_voltage = "AC$MASS_SPECTROMETRY: CAPILLARY_VOLTAGE",
ms_col_gas = "AC$MASS_SPECTROMETRY: COLLISION_GAS",
ms_desolv_gas_flow = "AC$MASS_SPECTROMETRY: DESOLVATION_GAS_FLOW",
ms_desolv_temp = "AC$MASS_SPECTROMETRY: DESOLVATION_TEMPERATURE",
ms_ionization = "AC$MASS_SPECTROMETRY: IONIZATION",
ms_ionization_energy = "AC$MASS_SPECTROMETRY: IONIZATION_ENERGY",
ms_laser = "AC$MASS_SPECTROMETRY: LASER",
ms_matrix = "AC$MASS_SPECTROMETRY: MATRIX",
ms_mass_accuracy = "AC$MASS_SPECTROMETRY: MASS_ACCURACY",
ms_mass_range = "AC$MASS_SPECTROMETRY: MASS_RANGE_MZ",
ms_reagent_gas = "AC$MASS_SPECTROMETRY: REAGENT_GAS",
ms_resolution = "AC$MASS_SPECTROMETRY: RESOLUTION",
ms_scan_setting = "AC$MASS_SPECTROMETRY: SCANNING_SETTING",
ms_source_temp = "AC$MASS_SPECTROMETRY: SOURCE_TEMPERATURE",
ms_frag_mode = "AC$MASS_SPECTROMETRY: FRAGMENTATION_MODE",
# ims information
ims_instrument_type = "AC$ION_MOBILITY: INSTRUMENT_TYPE",
ims_drift_gas = "AC$ION_MOBILITY: DRIFT_GAS",
ims_drift_time = "AC$ION_MOBILITY: DRIFT_TIME",
ims_ccs = "AC$ION_MOBILITY: CCS",
# ms information part II
focus_base_peak = "MS$FOCUSED_ION: BASE_PEAK",
focus_derivative_form = "MS$FOCUSED_ION: DERIVATIVE_FORM",
focus_derivative_mass = "MS$FOCUSED_ION: DERIVATIVE_MASS",
focus_derivative_type = "MS$FOCUSED_ION: DERIVATIVE_TYPE",
focus_ion_type = "MS$FOCUSED_ION: ION_TYPE",
# data processing information
data_processing_comment = "MS$DATA_PROCESSING: COMMENT",
data_processing_deprofile = "MS$DATA_PROCESSING: DEPROFILE",
data_processing_find = "MS$DATA_PROCESSING: FIND_PEAK",
data_processing_reanalyze = "MS$DATA_PROCESSING: REANALYZE",
data_processing_recalibrate = "MS$DATA_PROCESSING: RECALIBRATE",
data_processing_whole = "MS$DATA_PROCESSING: WHOLE",
# chromatography information
chrom_carrier_gas = "AC$CHROMATOGRAPHY: CARRIER_GAS",
chrom_column = "AC$CHROMATOGRAPHY: COLUMN_NAME",
chrom_column_temp = "AC$CHROMATOGRAPHY: COLUMN_TEMPERATURE",
chrom_column_temp_gradient =
"AC$CHROMATOGRAPHY: COLUMN_TEMPERATURE_GRADIENT",
chrom_flow_gradient = "AC$CHROMATOGRAPHY: FLOW_GRADIENT",
chrom_flow_rate = "AC$CHROMATOGRAPHY: FLOW_RATE",
chrom_inj_temp = "AC$CHROMATOGRAPHY: INJECTION_TEMPERATURE",
chrom_inj_temp_gradient =
"AC$CHROMATOGRAPHY: INJECTION_TEMPERATURE_GRADIENT",
chrom_rti_kovats = "AC$CHROMATOGRAPHY: KOVATS_RTI",
chrom_rti_lee = "AC$CHROMATOGRAPHY: LEE_RTI",
chrom_rti_naps = "AC$CHROMATOGRAPHY: NAPS_RTI",
chrom_rti_uoa = "AC$CHROMATOGRAPHY: UOA_RTI",
chrom_rti_uoa_pred = "AC$CHROMATOGRAPHY: UOA_PREDICTED_RTI",
chrom_rt = "AC$CHROMATOGRAPHY: RETENTION_TIME",
chrom_solvent = "AC$CHROMATOGRAPHY: SOLVENT",
chrom_transfer_temp = "AC$CHROMATOGRAPHY: TRANSFERLINE_TEMPERATURE",
# chemical information
compound_class = "CH$COMPOUND_CLASS:",
link_cayman = "CH$LINK: CAYMAN",
link_chebi = "CH$LINK: CHEBI",
link_chembl = "CH$LINK: CHEMBL",
link_chempdb = "CH$LINK: CHEMPDB",
link_chemspider = "CH$LINK: CHEMSPIDER",
link_comptox = "CH$LINK: COMPTOX",
link_hmdb = "CH$LINK: HMDB",
link_kappaview = "CH$LINK: KAPPAVIEW",
link_kegg = "CH$LINK: KEGG",
link_knapsack = "CH$LINK: KNAPSACK",
link_lipidbank = "CH$LINK: LIPIDBANK",
link_lipidmaps = "CH$LINK: LIPIDMAPS",
link_nikkaji = "CH$LINK: NIKKAJI",
link_pubchem = "CH$LINK: PUBCHEM",
link_zinc = "CH$LINK: ZINC",
# sample information
scientific_name = "SP$SCIENTIFIC_NAME:",
lineage = "SP$LINEAGE:",
link = "SP$LINK:",
sample = "SP$SAMPLE:",
# record information
deprecated = "DEPRECATED:",
date = "DATE:",
authors = "AUTHORS:",
license = "LICENSE:",
copyright = "COPYRIGHT:",
publication = "PUBLICATION:",
project = "PROJECT:",
# peak information
pknum = "PK$NUM_PEAK:"
)
)
}
#' @importMethodsFrom Spectra export
#'
#' @exportMethod export
#'
#' @rdname MsBackendMassbank
setMethod("export", "MsBackendMassbank",
function(object, x, file = tempfile(),
mapping = spectraVariableMapping(), ...) {
.export_massbank(x = x, con = file, mapping = mapping)
})
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
Embedding an R snippet on your website
Add the following code to your website.
For more information on customizing the embed code, read Embedding Snippets.