= '''PostGIS Raster Working Specifications for Future Versions''' = {{{ #!div style='background-color: #F4F4F4; padding: 5px; border: 1px solid gray; float: right; margin-left: 5px; width: 260px; font-size: small;' > '''Quick Links''' * [wiki:WKTRaster PostGIS Raster Home Page] * [wiki:WKTRaster/PlanningAndFunding Planning & Funding] * [wiki:WKTRaster/SpecificationWorking02 Working Specifications for PostGIS 2.0] * [wiki:WKTRaster/SpecificationFinal01 Old Final Specifications for Beta 0.1.6] }}} ---- == '''Objective FV.01 - Being able to return a JPEG, a TIFF, a PNG or any image format supported by GDAL.''' == '''ST_bytea(raster, integer) -> raster''' -- the integer parameters is the band number of the raster.[[BR]] What is does? ---- '''Open Question:''' When exporting a multiband raster to JPEG, TIFF, PNG, SVG or KML, how should we specify the band number in the exporting function. There is two options to select the band to convert from a multiband raster in all the ST_AsFormat functions. [[BR]] [[BR]] 1. Precede each call with ST_Band() to return a selected band.[[BR]] Pros: This is a general function that can be called before any function that would otherwise require a band parameter.[[BR]] Cons: This implies creating a temporary raster. This might be more elegant and general but is this too much overhead comparing with having a band parameter? 2. Add a band parameter to each ST_AsFormat function.[[BR]] Pros: Hypothetically less overhead.[[BR]] Cons: Every functions implying access to a band should then have this parameter when in most case it would be equal to 1. In many cases it makes no sence to have to specify a band parameter since it is the whole raster that we want to export, including all the bands. Pierre: More I think about it more I think that the first option is the best one... mloskot: Perhaps there is a compromise in form of two sets of functions: 1) ST_As* which always burn the whole raster (all bands) 2) ST_BandAs* which takes number of band as a parameter and return only this requested band. ---- '''ST_Band(raster, integer) -> raster''' -- the integer parameters are the band number of the rasters.[[BR]] Return a single band from a multiband raster. If "band" is greater than the value returned by ST_GetNumBands(), the function returns the last band. This function should be used to select a band before converting it to JPEG, TIFF, PNG, SVG or KML with the corresponding function. e.g. '''ST_AsTIFF(ST_Band(raster, band)) Bborie: A complete implementation of ST_Band should include the following: 1. ST_Band(rast raster, nbands int[]) -> raster nbands is an array of 1-based band indices of the bands to copy into the output raster For a raster rast with 3 bands: {{{ ST_Band(rast, ARRAY[1,3,2]) ST_Band(rast, ARRAY[3,2,1]) }}} You can rearrange the bands as above. You can also duplicate the bands: {{{ ST_Band(rast, ARRAY[1,2,3,2,1]) }}} 2. ST_Band(rast raster, nband int) -> raster nband is a single integer of the 1-based band index of the band to copy into the output raster {{{ ST_Band(rast, 1) ST_Band(rast, 3) }}} 3. ST_Band(rast raster, nbands text) -> raster nbands is a comma separated string of 1-based band indices indicating the bands to copy into the output raster {{{ ST_Band(rast, '1,2') ST_Band(rast, '1,2,3, 1, 1 , 2') }}} 4. ST_Band(rast raster, nbands text, delimiter char) -> raster nbands is a user-specified delimiter separated string of 1-based band indices indicating the bands to copy into the output raster {{{ ST_Band(rast, '1,2', ',') ST_Band(rast, '1,2,3, 1, 1 , 2', ',') }}} 5. ST_Band(rast raster) -> raster the band to extract is automatically assumed to be one. {{{ ST_Band(rast) }}} If an index is outside the valid range of band indices for a raster (less than 1 or greater than the value returned by ST_NumBands), the function will fail and return. ''' Open Question: ''' Should the function fail if an index is invalid? How should this work when providing more than one indices to the function? ---- '''ST_SummaryStats(raster, nband) -> record'''[[BR]] This is the core function that gets the summary statistics (# of values, mean, standard deviation, minimum value, maximum value) of a specified raster's band. It is this function that ST_Mean, ST_StdDev and ST_MinMax calls for their appropriate values. 1. ST_SummaryStats(rast raster, nband int, hasnodata boolean) -> record returns one record of five columns (count, mean, stddev, min, max) nband: index of band hasnodata: if FALSE, any pixel who's value is nodata is ignored {{{ ST_SummaryStats(rast, 1, FALSE) }}} 2. ST_SummaryStats(rast raster, nband int) -> record assumes hasnodata = FALSE {{{ ST_SummaryStats(rast, 2) }}} 3. ST_SummaryStats(rast raster, hasnodata boolean) -> record assumes nband = 1 {{{ ST_SummaryStats(rast, TRUE) }}} 4. ST_SummaryStats(rast raster) -> record assumes nband = 1 and hasnodata = FALSE {{{ ST_SummaryStats(rast) }}} Due to the time it may take to do on-the-fly calculation of summary stats for large rasters (say 10000 x 10000), an alternative that sacrifices accuracy for speed is required. The following functions sample a percentage of the raster in a methodical randomized manner. The algorithm used for sampling is... 1. select the larger dimension of the width and height. compute the number of pixels to sample in each "row" of the larger dimension 2. pick pixels from each "row" of the larger dimension in an incremental rolling manner where each increment is randomly determined. The set of ST_ApproxSummaryStats functions are: 1. ST_ApproxSummaryStats(rast raster, nband int, hasnodata boolean, sample_percent double precision) -> record sample_percent: a value between 0 and 1 indicating the percentage of the raster band's pixels to consider {{{ ST_ApproxSummaryStats(rast, 3, FALSE, 0.1) ST_ApproxSummaryStats(rast, 1, TRUE, 0.5) }}} 2. ST_ApproxSummaryStats(rast raster, nband int, sample_percent double precision) -> record assumes that nband = 1 {{{ ST_ApproxSummaryStats(rast, 2 0.01) ST_ApproxSummaryStats(rast, 4, 0.025) }}} 3. ST_ApproxSummaryStats(rast raster, hasnodata boolean, sample_percent double precision) -> record assumes that nband = 1 {{{ ST_ApproxSummaryStats(rast, FALSE, 0.01) ST_ApproxSummaryStats(rast, TRUE, 0.025) }}} 4. ST_ApproxSummaryStats(rast raster, sample_percent double precision) -> record assumes that nband = 1 and hasnodata = FALSE {{{ ST_ApproxSummaryStats(rast, 0.25) }}} 5. ST_ApproxSummaryStats(rast raster) -> record assumes that nband = 1, hasnodata = FALSE and sample_percent = 0.1 {{{ ST_ApproxSummaryStats(rast) }}} The situation arises where the summary statistics of a coverage table is required. As the coverage may be large (tens of gigabytes of memory or larger), the following functions are provided to permit an incremental computation of the summary statistics. 1. ST_SummaryStats(rastertable text, rastercolumn text, nband int, hasnodata boolean) -> record rastertable: name of table with raster column rastercolumn: name of column of data type raster {{{ ST_SummaryStats('tmax_2010', 'rast', 1, FALSE) ST_SummaryStats('precip_2011', 'rast', 1, TRUE) }}} 2. ST_SummaryStats(rastertable text, rastercolumn text, nband int) -> record hasnodata = FALSE {{{ ST_SummaryStats('tmax_2010', 'rast', 1) }}} 3. ST_SummaryStats(rastertable text, rastercolumn text, hasnodata boolean) -> record nband = 1 {{{ ST_SummaryStats('precip_2011', 'rast', TRUE) }}} 4. ST_SummaryStats(rastertable text, rastercolumn text) -> record nband = 1 and hasnodata = FALSE {{{ ST_SummaryStats('tmin_2009', 'rast') }}} Variations for ST_ApproxSummaryStats are: 1. ST_ApproxSummaryStats(rastertable text, rastercolumn text, nband int, hasnodata boolean, sample_percent double precision) -> record {{{ ST_ApproxSummaryStats('tmax_2010', 'rast', 1, FALSE, 0.5) ST_ApproxSummaryStats('precip_2011', 'rast', 1, TRUE, 0.2) }}} 2. ST_ApproxSummaryStats(rastertable text, rastercolumn text, nband int, sample_percent double precision) -> record hasnodata = FALSE {{{ ST_ApproxSummaryStats('tmax_2010', 'rast', 1, 0.5) ST_ApproxSummaryStats('precip_2011', 'rast', 1, 0.2) }}} 3. ST_ApproxSummaryStats(rastertable text, rastercolumn text, hasnodata boolean, sample_percent double precision) -> record nband = 1 {{{ ST_ApproxSummaryStats('tmax_2010', 'rast', FALSE, 0.5) ST_ApproxSummaryStats('precip_2011', 'rast', TRUE, 0.2) }}} 4. ST_ApproxSummaryStats(rastertable text, rastercolumn text, sample_percent double precision) -> record nband = 1 and hasnodata = FALSE {{{ ST_ApproxSummaryStats('tmax_2010', 'rast', 0.5) ST_ApproxSummaryStats('precip_2011', 'rast', 0.2) }}} 5. ST_ApproxSummaryStats(rastertable text, rastercolumn text) -> record nband = 1, hasnodata = FALSE and sample_percent = 0.1 {{{ ST_ApproxSummaryStats('tmax_2010', 'rast') ST_ApproxSummaryStats('precip_2011', 'rast') }}} The mean returned in the coverage functions (has rastertable and rastercolumn arguments) is a weighted mean of the means of each raster tile. The standard deviation returned is the cumulative standard deviation of all raster tiles. ---- '''ST_MinMax(raster, nband) -> record'''[[BR]] As part of the process to provide complete implementations of ST_AsJPEG and ST_AsPNG, a method is required to reclassify larger numbers unable to be contained in 8BUI (JPEG and PNG) and 16BUI (PNG). For this reclassification function, we need to get the min and max values of a band, thus ST_MinMax. This function calls upon ST_SummaryStats. 1. ST_MinMax(rast raster, nband int, hasnodata boolean) -> record returns one record of two columns (min, max) nband: index of band to process on hasnodata: if FALSE, any pixel who's value is nodata is ignored. {{{ ST_MinMax(rast, 2, TRUE) }}} 2. ST_MinMax(rast raster, nband int) -> record assumes hasnodata = FALSE {{{ ST_MinMax(rast, 2) }}} 3. ST_MinMax(rast raster, hasnodata boolean) -> record assumes band index = 1 {{{ ST_MinMax(rast, FALSE) }}} 4. ST_MinMax(rast raster) -> record assumes band index = 1 and hasnodata = FALSE {{{ ST_MinMax(rast) }}} The ST_ApproxMinMax functions are: 1. ST_ApproxMinMax(rast raster, nband int, hasnodata boolean, sample_percent double precision) -> record sample_percent: a value between 0 and 1 indicating the percentage of the raster band's pixels to consider when determining the min/max pair. {{{ ST_ApproxMinMax(rast, 3, FALSE, 0.1) ST_ApproxMinMax(rast, 1, TRUE, 0.5) }}} 2. ST_ApproxMinMax(rast raster, nband int, sample_percent double precision) -> record assumes that nband = 1 {{{ ST_ApproxMinMax(rast, 2 0.01) ST_ApproxMinMax(rast, 4, 0.025) }}} 3. ST_ApproxMinMax(rast raster, hasnodata boolean, sample_percent double precision) -> record assumes that nband = 1 {{{ ST_ApproxMinMax(rast, FALSE, 0.01) ST_ApproxMinMax(rast, TRUE, 0.025) }}} 4. ST_ApproxMinMax(rast raster, sample_percent double precision) -> record assumes that nband = 1 and hasnodata = FALSE {{{ ST_ApproxMinMax(rast, 0.25) }}} 5. ST_ApproxMinMax(rast raster) -> record assumes that nband = 1, hasnodata = FALSE and sample_percent = 0.1 {{{ ST_ApproxMinMax(rast) }}} ---- '''ST_AsJPEG(raster, quality) -> JPEG as "bytea"'''[[BR]] Return the raster as a JPEG encoded as a PostgreSQL bytea. By default quality is set to 75, but this option can be used to select other values. Values must be in the range 10-100. Low values result in higher compression ratios, but poorer image quality. Values above 95 are not meaningfully better quality but can but substantially larger. (copied from http://www.gdal.org/frmt_jpeg.html) '''Open Question:''' Is JPEG export limited to raster having 8 bit unsigned integer pixeltype (8BUI)? [http://www.gdal.org/frmt_jpeg.html See how GDAL do it]. It converts only 8 bits rasters. Should we do the same? Otherwise, how do we convert other types to 8BUI? e.g. 16BUI or 8BSI? Pierre: It might be more simple to ignore pixeltypes other than 8BUI but it would be very convenient to have a way to quickly export elevation data for example as a JPEG. It would be nice to have an elegant solution to this. Maybe something inspired from !MapServer. Proposition one (Pierre): ST_AsJPEG could simply (optionally when the pixeltype is not 8BUI) map the ST_Maximum() and ST_Minimum() value to 0-255. ST_Maximum() and ST_Minimum() are not in the spec yet but this could be on nice usage of it. They will imply caching the min and max when importing and editing. Both function should ignore the !NoDataValues. They could also be two parameters passed to ST_AsJPEG(raster, quality, min, max). Proposition two: There could also be just one parameter (string) defining a mapping method: * Method "None": No mapping. This is possible only for 8BUI. * Method "!MaxMinValue": Use the Max and the Min cached in the raster. e.g. for 16BSI (min, max) -> (-2033, 2456) -> (round((-2033 - -2033)/(2456 - -2033)*255), round((2456 - -2033)/(2456 - -2033)*255)) -> (0, 255).[[BR]] [[BR]]This is equivalent to ST_AsJPEG(raster, quality, ST_Minimum(rast), ST_Maximum(rast)) * Method "!MaxMinType": Use the Max and the Min allowed by the type. e.g. for 16BSI (min, max) -> (-2033, 2456) -> (round((-2033 - -32768)/(32767 - -32768)*255), round((2456 - -32768)/(32767 - -32768)*255)) -> (120, 137)[[BR]] [[BR]]This would be equivalent to ST_AsJPEG(raster, quality, ST_BandPixelTypeMin(rast), ST_BandPixelTypeMax(rast)). Both functions (ST_BandPixelTypeMin & ST_BandPixelTypeMax) are not yet planned and I could not find an SQL query that returns the equivalent range for a type. [http://groups.google.nl/group/microsoft.public.sqlserver.programming/browse_thread/thread/46512c2691da4607/6743f4aea485c6d1 One possible solution.] mloskot: ATM, I have no thoughts on this issue. '''Open Question:''' Is JPEG export limited to raster having 1 or 3 bands? [http://www.gdal.org/frmt_jpeg.html See how GDAL do it]. It converts only 1 or 3 band rasters. Should we do the same? In this case 1 band rasters would be exported as a greyscale JPEG having R G and B identical and 3 band rasters would be interpreted as R, G and B. Pierre: I think the answer should be yes. I don't see how we could have a 2 band raster fit into RGB. mloskot: I agree, the answer should be yes. '''Here is an attempt to define the different versions of the function:''' The most minimalistic versions of the function should assume band 1, 2 and 3 as being r, g, b and the quality equal to 75: ST_AsJPEG(raster) -quality = 75 A variant allow specifying the quality: ST_AsJPEG(raster, integer) Another variant should enable us to specify which band correspond to the r, the g and the b: ST_AsJPEG(raster, integer, integer, integer) - raster, rband, gband, bband, quality=75 ST_AsJPEG(raster, integer, integer, integer, integer) - raster, rband, gband, bband, quality Another version should be designed to be used with a future ST_Band(raster) function. In this case there is no attempt to extract r, g or b band from any passed raster: ST_AsJPEG(raster, raster, raster) ST_AsJPEG(raster, raster, raster, integer) -with the quality param Another series should allow converting 1 band raster with pixel of type 8BUI to a grayscale JPEG (Carefull study of the GDAL behavior when converting a single band to JPEG should be done before confirming these functions): ST_AsJPEG(raster, "GRAYSCALE") - convert only band 1 with quality = 75 ST_AsJPEG(raster, "GRAYSCALE", integer) - convert only band 1 with specified quality ST_AsJPEG(raster, integer, "GRAYSCALE") - allow specifying the band number to convert ST_AsJPEG(raster, integer, "GRAYSCALE", integer) - allow specifying the band number to convert and the quality Another series should allow converting 1 band raster of ANY pixel type to a grayscale JPEG. Pixel types different than 8BUI should be mapped according to specified min, max values and a mapping mode: "!MaxMinValue" (default) or "!MaxMinType". ST_AsJPEG(raster, "GRAYSCALE", min, max, text) - convert only band 1 with quality = 75 ST_AsJPEG(raster, "GRAYSCALE", integer, min, max, text) - convert only band 1 with specified quality ST_AsJPEG(raster, integer, "GRAYSCALE", min, max, text) - allow specifying the band number to convert ST_AsJPEG(raster, integer, "GRAYSCALE", integer, min, max, text) - allow specifying the band number to convert and the quality Bborie: The JPEG format has several limitations: 1. JPEG only allows 1 (greyscale) or 3 (RGB) bands of data 2. JPEG only supports 8BUI pixeltype 3. JPEG cannot embed spatial reference information within the file but can have an associated world file To address the limitations: 1. Use ST_Band to specify which band(s) should be passed to the ST_AsJPEG function. Variations of ST_AsJPEG are made available that allows specifying a band index. If a raster whose number of specified bands does not equal 1 or 3 is provided, a warning is raised and the first or the first three bands are used. 2. Throw an exception if any of the specified bands is not 8BUI. The user should use ST_Reclass to convert any non-8BUI bands to 8BUI. 3. Nothing can be done. A proposed set of variations of the ST_AsJPEG function: 1. ST_AsJPEG(rast raster, options text[]) rast: the raster with one or three bands in 8BUI pixel type to generate a JPEG image from options: array of creation options to pass to the GDAL JPEG driver {{{ ST_AsJPEG(rast, ARRAY['QUALITY=90', 'PROGRESSIVE=ON']) }}} 2. ST_AsJPEG(rast raster) Like !#1 above but use the driver's default creation options 3. ST_AsJPEG(rast raster, nbands int[], options text[]) nbands: an integer array specifying the band indices of the raster to include in the JPEG file {{{ ST_AsJPEG(rast, ARRAY[1,3,6], ARRAY['QUALITY=50']) }}} 4. ST_AsJPEG(rast raster, nbands int[]) Like !#3, but use the default creation options {{{ ST_AsJPEG(rast, ARRAY[1,3,6]) }}} 5. ST_AsJPEG(rast raster, nbands int[], quality int) quality: number between 10 and 100 indicating image quality {{{ ST_AsJPEG(rast, ARRAY[1,2,3], 90) }}} 6. ST_AsJPEG(rast raster, nband int, options text[]) nband: index of the band to include {{{ ST_AsJPEG(rast, 2, ARRAY['QUALITY=25']) }}} 7. ST_AsJPEG(rast raster, nband int, quality int) {{{ ST_AsJPEG(rast, 5, 75) }}} 8. ST_AsJPEG(rast raster, nband int) {{{ ST_AsJPEG(rast, 4) }}} ---- '''ST_AsTIFF(raster, compression) -> TIFF as "bytea"'''[[BR]] Return the raster as a JPEG encoded as a PostgreSQL bytea. If raster is a multiband raster and no band were selected with ST_Band() every band are written to the resulting TIFF. compression=[JPEG/LZW/PACKBITS/DEFLATE/CCITTRLE/CCITTFAX3/CCITTFAX4/NONE]: Set the type of compression to use. None is the default. The CCITT compression should only be used with 1bit (NBITS=1) data. JPEG should only be used with Byte data. When using JPEG add a number specifying the quality. 75 is the default. e.g. ST_AsTIFF(raster, "JPEG60") (copied from http://www.gdal.org/frmt_gtiff.html) Bborie: A proposed implementation of the ST_AsTIFF functions. The TIFF format is probably the most robust available for converting rasters to GDAL rasters. Not only does it support all PostGIS Raster pixel types, it also provides plenty of creation options and possibly no issues with the number of bands. The only limitation found is that there can only be one NODATA value for all bands. ''If the compression parameter/option is specified to JPEG, all bands must be of pixel type 8BUI. If the compression parameter/option is specified to one of the CCITT options, all bands must be of pixel type 1BB. If any band violates the restriction, an exception is raised.'' The next three functions are the most basic of the ST_AsTIFF functions. 1. ST_AsTIFF(rast raster, options text[], srs text) -> bytea The most generic version of this function. All other ST_AsTIFF functions call this function. This function will check that all bands of the raster to be converted has the same NODATA value. If there are more than one possible NODATA values, a WARNING will be raised and the output TIFF will use the NODATA value of the first band with a NODATA value. options: the GDAL creation options found in the Creation Options section of the GDAL TIFF driver srs: the user-specified OGC WKT or the proj4 text for a spatial reference to embed in the GDAL raster. TIFF is one of the formats that supports embedding the spatial reference within the image file. {{{ ST_AsTIFF(rast, ARRAY['COMPRESS=DEFLATE', 'ZLEVEL=9'], '+proj=aea +lat_1=34 +lat_2=40.5 +lat_0=0 +lon_0=-120 +x_0=0 +y_0=-4000000 +ellps=GRS80 +datum=NAD83 +units=m +no_defs') ST_AsTIFF(rast, ARRAY['COMPRESS=DEFLATE', 'ZLEVEL=9'], 'PROJCS["NAD83 / California Albers",GEOGCS["NAD83",DATUM["North_American_Datum_1983",SPHEROID["GRS 1980",6378137,298.257222101,AUTHORITY["EPSG","7019"]],AUTHORITY["EPSG","6269"]],PRIMEM["Greenwich",0,AUTHORITY["EPSG","8901"]],UNIT["degree",0.01745329251994328,AUTHORITY["EPSG","9122"]],AUTHORITY["EPSG","4269"]],UNIT["metre",1,AUTHORITY["EPSG","9001"]],PROJECTION["Albers_Conic_Equal_Area"],PARAMETER["standard_parallel_1",34],PARAMETER["standard_parallel_2",40.5],PARAMETER["latitude_of_center",0],PARAMETER["longitude_of_center",-120],PARAMETER["false_easting",0],PARAMETER["false_northing",-4000000],AUTHORITY["EPSG","3310"],AXIS["X",EAST],AXIS["Y",NORTH]]') }}} 2. ST_AsTIFF(rast raster, options text[]) -> bytea This one removes the user-specified srs argument. The output TIFF's spatial reference will be set to the same as the input raster, if possible. {{{ ST_AsTIFF(rast, ARRAY['COMPRESS=DEFLATE', 'ZLEVEL=9']) }}} 3. ST_AsTIFF(rast raster) -> bytea The simplest implementation of this function. Since the options argument has been removed, the output TIFF will be created with default options. Like the prior function, the spatial reference of the TIFF will be set to the same as the input raster. {{{ ST_AsTIFF(rast) }}} The next three functions add a band index argument to filter the raster's bands before generating the output TIFF. 4. ST_AsTIFF(rast raster, nbands int[], options text[], srs text) -> bytea {{{ ST_AsTIFF(rast, ARRAY[3,1,2], ARRAY['COMPRESS=DEFLATE', 'ZLEVEL=9'], '+proj=aea +lat_1=34 +lat_2=40.5 +lat_0=0 +lon_0=-120 +x_0=0 +y_0=-4000000 +ellps=GRS80 +datum=NAD83 +units=m +no_defs') }}} 5. ST_AsTIFF(rast raster, nbands int[], options text[]) -> bytea This one removes the user-specified srs argument. The output TIFF's spatial reference will be set to the same as the input raster, if possible. {{{ ST_AsTIFF(rast, ARRAY[3,1,2], ARRAY['COMPRESS=DEFLATE', 'ZLEVEL=9']) }}} 6. ST_AsTIFF(rast raster, nbands int[]) -> bytea Since the options argument has been removed, the output TIFF will be created with default options. Like the prior function, the spatial reference of the TIFF will be set to the same as the input raster. {{{ ST_AsTIFF(rast, ARRAY[3,1,2]) }}} The next two functions add a compression argument. If the compression desired is JPEG or DEFLATE, the user can specify a quality as part of the compression string. Examples are: {{{ JPEG90 JPEG DEFLATE8 DEFLATE }}} 7. ST_AsTIFF(rast raster, compression text, srs text) -> bytea This function will parse the compression string for the compression type and the compression quality. It will also inspect to make sure that the pixel types of the raster's bands are appropriate for the compression type. This is primarily for JPEG and CCITT compression types, which only support 8BUI and 1BB respectively. {{{ ST_AsTIFF(rast, 'JPEG90', '+proj=aea +lat_1=34 +lat_2=40.5 +lat_0=0 +lon_0=-120 +x_0=0 +y_0=-4000000 +ellps=GRS80 +datum=NAD83 +units=m +no_defs') ST_AsTIFF(rast, 'JPEG', '+proj=aea +lat_1=34 +lat_2=40.5 +lat_0=0 +lon_0=-120 +x_0=0 +y_0=-4000000 +ellps=GRS80 +datum=NAD83 +units=m +no_defs') ST_AsTIFF(rast, 'LZMA', '+proj=aea +lat_1=34 +lat_2=40.5 +lat_0=0 +lon_0=-120 +x_0=0 +y_0=-4000000 +ellps=GRS80 +datum=NAD83 +units=m +no_defs') }}} 8. ST_AsTIFF(rast raster, compression text) -> bytea The output TIFF will be created with default options. Like the prior function, the spatial reference of the TIFF will be set to the same as the input raster. {{{ ST_AsTIFF(rast, 'LZMA') }}} The next two functions include band index and compression arguments 9. ST_AsTIFF(rast raster, nbands int[], compression text, srs text) -> bytea {{{ ST_AsTIFF(rast, ARRAY[2], 'JPEG90', ARRAY['BIGTIFF=IF_NEEDED'], '+proj=aea +lat_1=34 +lat_2=40.5 +lat_0=0 +lon_0=-120 +x_0=0 +y_0=-4000000 +ellps=GRS80 +datum=NAD83 +units=m +no_defs') ST_AsTIFF(rast, ARRAY[1,3], 'JPEG', ARRAY['BIGTIFF=IF_NEEDED'], '+proj=aea +lat_1=34 +lat_2=40.5 +lat_0=0 +lon_0=-120 +x_0=0 +y_0=-4000000 +ellps=GRS80 +datum=NAD83 +units=m +no_defs') ST_AsTIFF(rast, ARRAY[3,1,2], 'LZMA', ARRAY['BIGTIFF=IF_NEEDED'], '+proj=aea +lat_1=34 +lat_2=40.5 +lat_0=0 +lon_0=-120 +x_0=0 +y_0=-4000000 +ellps=GRS80 +datum=NAD83 +units=m +no_defs') }}} 10. ST_AsTIFF(rast raster, nbands int[], compression text) -> bytea {{{ ST_AsTIFF(rast, ARRAY[3,2], 'DEFLATE9') }}} The output TIFF will be created with default options. The spatial reference of the TIFF will be set to the same as the input raster. ---- '''Open Question:''' What if we want to export only the first two band of a three band layer? Maybe we need a ST_RasterFromBands(band1, band2, etc...) to reconstitute a multiband raster from multiple sources (having the same width, height, pixelsize, etc...) mloskot: or ST_RasterFromBands(bands) where bands is ARRAY[int]. For instance, ST_RasterFromBands(ARRAY[1,3]) will burn new raster from 1 and 3 bands of input raster. ---- '''ST_AsPNG(raster, band) -> PNG as "bytea"''' Bborie: Like the JPEG raster format, the PNG format has limitations: 1. PNG only allows 1 (greyscale) or 3 (RGB) bands of data 2. PNG only supports 8BUI and 16BUI pixeltypes. Any other pixeltype will be written as 8BUI, though the results are probably useless 3. PNG cannot embed spatial reference information within the file but can have an associated world file Like JPEG, the limitations can be resolved: 1. Use ST_Band to specify which band(s) should be passed to the ST_AsPNG function. If a raster whose number of specified bands does not equal 1 or 3 is provided, a warning is raised and the first or the first three bands are used. 2. Throw an exception if any of the specified bands is not 8BUI or 16BUI. The user should use ST_Reclass to convert any non-8BUI or 16BUI bands to 8BUI or 16BUI. 3. Nothing can be done within this function. ST_Georeference() can be used to the contents of the associated world file A proposed set of variations of the ST_AsPNG function: 1. ST_AsPNG(rast raster, options text[]) rast: the raster with one or three bands in 8BUI or 16BUI pixel type to generate a PNG image from options: array of creation options to pass to the GDAL PNG driver {{{ ST_AsPNG(rast, ARRAY['ZLEVEL=9']) }}} 2. ST_AsPNG(rast raster) Like !#1 above but use the driver's default creation options 3. ST_AsPNG(rast raster, nbands int[], options text[]) nbands: an integer array specifying the band indices of the raster to include in the PNG file {{{ ST_AsPNG(rast, ARRAY[3,1,2], ARRAY['ZLEVEL=9']) }}} 4. ST_AsPNG(rast raster, nbands int[]) Like !#3, but use the default creation options {{{ ST_AsPNG(rast, ARRAY[3]) }}} 5. ST_AsPNG(rast raster, nbands int[], compression int) compression: number between 1 and 9 indicating the amount of time to spend on compression. 1 is fastest with least compression. 9 is slowest with best compression {{{ ST_AsPNG(rast, ARRAY[2,1,3], 3) }}} 6. ST_AsPNG(rast raster, nband int, options text[]) nband: index of the band to include {{{ ST_AsPNG(rast, 2, ARRAY['ZLEVEL=5']) }}} 7. ST_AsPNG(rast raster, nband int, compression int) {{{ ST_AsPNG(rast, 1, 8) }}} 8. ST_AsPNG(rast raster, nband int) {{{ ST_AsPNG(rast, 1) }}} ---- '''ST_AsGDALRaster(raster, band int, type text, options text) -> bytea''' Use GDAL to convert the raster into one of the format suported by GDAL. Bborie: this is a generic interface to outputting a supported and installed GDAL raster: 1. ST_AsGDALRaster(rast raster, format text, options text[], srs text) -> bytea This is the most generic and GDAL-specific method to convert a raster to a GDAL raster. All other version of ST_AsGDALRaster and other format specific functions (ST_AsJPEG, ST_AsTIFF and ST_AsPNG) are all wrappers around this function. Reference information for the format and options arguments of a particular format are specified at: http://gdal.org/formats_list.html. The arguments specified are: format: the GDAL format code. e.g. GTiff, JPEG, PNG options: the GDAL creation options found in the '''Creation Options''' section of a specified format. e.g. COMPRESS=JPEG, JPEG_QUALITY=90 srs: the user-specified OGC WKT or the proj4 text for a spatial reference to embed in the GDAL raster. Not all formats support embedding this information. e.g. the non-empty value for the srtext or proj4text column from the spatial_ref_sys table. {{{ ST_AsGDALRaster(rast, 'GTiff', ARRAY['COMPRESS=JPEG', 'JPEG_QUALITY=90'], '+proj=aea +lat_1=34 +lat_2=40.5 +lat_0=0 +lon_0=-120 +x_0=0 +y_0=-4000000 +ellps=GRS80 +datum=NAD83 +units=m +no_defs') ST_AsGDALRaster(rast, 'GTiff', ARRAY['COMPRESS=JPEG', 'JPEG_QUALITY=90'], 'PROJCS["NAD83 / California Albers",GEOGCS["NAD83",DATUM["North_American_Datum_1983",SPHEROID["GRS 1980",6378137,298.257222101,AUTHORITY["EPSG","7019"]],AUTHORITY["EPSG","6269"]],PRIMEM["Greenwich",0,AUTHORITY["EPSG","8901"]],UNIT["degree",0.01745329251994328,AUTHORITY["EPSG","9122"]],AUTHORITY["EPSG","4269"]],UNIT["metre",1,AUTHORITY["EPSG","9001"]],PROJECTION["Albers_Conic_Equal_Area"],PARAMETER["standard_parallel_1",34],PARAMETER["standard_parallel_2",40.5],PARAMETER["latitude_of_center",0],PARAMETER["longitude_of_center",-120],PARAMETER["false_easting",0],PARAMETER["false_northing",-4000000],AUTHORITY["EPSG","3310"],AXIS["X",EAST],AXIS["Y",NORTH]]') }}} 2. ST_AsGDALRaster(rast raster, format text, options text[]) -> bytea This one removes the user-specified srs argument. The output GDAL raster's spatial reference will be set to the same as the input raster, if possible. {{{ ST_AsGDALRaster(rast, 'JPEG', ARRAY['QUALITY=50']) ST_AsGDALRaster(rast, 'PNG', ARRAY['ZLEVEL=7']) }}} 3. ST_AsGDALRaster(rast raster, format text) -> bytea The simplest implementation of this function. Since the options argument has been removed, the output GDAL raster will be created with default options. Like the prior function, the spatial reference of the GDAL raster will be set to the same as the input raster. {{{ ST_AsGDALRaster(rast, 'JPEG') }}} ---- '''ST_GDALDrivers() -> set of record''' As each GDAL installation may be different and ST_AsGDALRaster can be used to support formats other than GTiff, JPEG and PNG, a method is needed to expose to the end user the possible GDAL formats capable of being exported. This function will output the following columns. idx: the internal GDAL index number short_name: the GDAL format code. This is the value to pass to the format paramenter of ST_AsGDALRaster long_name: the full name of the GDAL format create_options: the creation options available for the format as an XML string. The formats outputted from ST_getGDALDrivers have been filtered to only those that the GDAL capabilities !CreateCopy and Virtual IO support. '''Open Question:''' Should the GDAL raster process be capable of supporting the GDAL capability Create? As the GDAL raster process writes nothing to a file in the filesystem (via Virtual IO), should there be support for writing the output GDAL raster temporarily to the filesystem? If so, how is it done in other PostgreSQL extensions in a secure manner? ---- '''ST_srtext(rast raster) -> text''' A helper function to get the value of column srtext or proj4text for a raster with an SRID. By default, the srtext is returned. If srtext is not available but proj4text is, the proj4text is returned. This function may be removed based upon the capabilities of SPI. It may not be possible to remove this function as the srs function argument of ST_AsGDALRaster can be NULL, thereby instructing the function to not embed any spatial reference information into the output GDAL raster. ---- '''ST_Reclass(rast raster, VARIADIC argset reclassarg[]) -> raster''' Due to limitations in the JPEG (8BUI) and PNG (8BUI and 16BUI) raster formats regarding supported pixel/data types, a method must be provided that can convert a band of a larger data type to 8BUI, amongst other uses. ST_Reclass allows raster's band pixel values to be remapped from one range of numbers to another as well as between pixel types, e.g. 32BF to 8BUI. ST_Reclass returns a duplicate of the submitted raster with the bands specified to be reclassed being processed. This means that if a raster with 5 bands are submitted and band 1 is to be reclassed, the output raster will have 5 bands with band 1 reclassified. The other four bands will not be touched. 1. ST_Reclass(rast raster, VARIADIC argset reclassarg[]) -> raster rast: the raster whose specified bands are to be reclassified reclassarg: a new custom type defining the parameters required for reclassifying a band's pixel values. {{{ CREATE TYPE reclassarg AS ( nband int, reclassexpr text, pixeltype text, nodata double ); }}} nband: index of the band to reclass (1-based) reclassexpr: reclassification expression indicating the ranges to convert from and to. More than one expression can be provided by separating the expression with a comma (,). The values provided can be of any valid numeric type. ''rangefrom:rangeto[, rangefrom:rangeto]'' {{{ 0-100:0-10 0-100:0-10, 101-1000:11-100 0-100:0-10, 101-1000:11-100, 1001-10000:101-1000 }}} In the last example above, the default evaluation of the ranges is {{{ 0 <= x < 100 reclassified to 0 <= y <= 10 101 <= x < 1000 reclassified to 11 <= y <= 100 1001 <= x < 10000 reclassified to 101 <= y <= 1000 }}} To change the evaluation of rangefrom, use square brackets and parentheses. {{{ 1. [a-b] = a <= x <= b 2. (a-b] = a < x <= b 3. [a-b) = a <= x < b 4. (a-b) = a < x < b }}} !#3 above is the default evaluation of x in the range a-b. The use of square brackets and parentheses are optional, so the examples below would be permitted. Missing notations substitute the appropriate notation from #3 above. {{{ [a-b = a <= x < b (a-b = a < x < b a-b] = a <= x <= b a-b) = a <= x < b }}} Two special cases are also available for use when x may be outside the range of a-b. This situation is possible if your range is based upon an approximation, such as from ST_ApproxMinMax. {{{ ]a-b or )a-b = x < a, rule matches a-b[ or a-b( = x >= b, rule matches }}} pixeltype: the reclassified band's pixel type, e.g. 8BUI, 16BUI, 32BF nodata: the nodata value of the reclassified band. If the source band has a nodata value, all source pixel value equal to the source nodata value will be converted to the reclassified band's nodata value. If set to NULL, the reclassified band will NOT have a nodata value specified. {{{ ST_Reclass(rast, ROW(1, '0-100:0-10, 101-1000:11-100, 1001-10000:101-1000', '16BUI', NULL)); ST_Reclass(rast, ROW(1, '0-100:0-10, 101-1000:11-100, 1001-10000:101-1000', '16BUI', 1001)); ST_Reclass(rast, ROW(1, '0-100:0-10, 101-1000:11-100, 1001-10000:101-1000', '16BUI', 1001), ROW(2, '0-100:0-10, 101-1000:11-100, 1001-10000:101-1000', '16BUI', 1001), ROW(3, '0-100:0-10, 101-1000:11-100, 1001-10000:101-1000', '16BUI', 1001), ROW(5, '0-100:0-10, 101-1000:11-100, 1001-10000:101-1000', '16BUI', 1001) ) }}} An expanded example {{{ SELECT ST_Reclass( ST_Band(rast, ARRAY[1,1,1]), ROW(1, LEAST(covmin, 0)::text || '-0:0,0-' || GREATEST(covmax, 0)::text || ':0-255', '8BUI'), ROW(2, LEAST(covmin, 0)::text || '-0:200,0-' || GREATEST(covmax, 0)::text' || ':0-255','8BUI'), ROW(3, LEAST(covmin, 0)::text || '-0:255,0-' || (GREATEST(covmax, 0)/2)::text' || ':0,' || (GREATEST(covmax, 0)/2)::text' || ':' || GREATEST(covmax, 0)::text || ':0-255', '8BUI') ) FROM mycoverage }}} 2. ST_Reclass(rast raster, nband int, reclassexpr text, pixeltype text, nodata double) -> raster provides a method to process just one band of a raster {{{ ST_Reclass(rast, 1, '0-100:0-10', '8BUI', 11) }}} 3. ST_Reclass(rast raster, nband int, reclassexpr text, pixeltype text) -> raster nodata parameter removed so reclassified band will NOT have a nodata value set {{{ ST_Reclass(rast, 1, '0-100:0-10', '8BUI') }}} 4. ST_Reclass(rast raster, reclassexpr text, pixeltype text) -> raster nband parameter removed so reclassified band is assumed to be 1. nodata parameter removed so reclassified band has NO nodata value. {{{ ST_Reclass(rast, '0-100:0-10', '8BUI') }}} 5. ST_Reclass(rast raster, reclassexpr text, pixeltype text, nodata double) -> raster nband parameter removed so reclassified band is assumed to be 1 {{{ ST_Reclass(rast, '0-100:0-10', '8BUI', 11) }}} ---- == '''Objective FV.02 - Being able to intersect vector and raster to produce raster.''' == '''ST_Intersects(raster, raster)'''[[BR]] '''ST_AsRaster(geometry, pixelsize) -> raster'''[[BR]] '''ST_Intersection(geometry, val, raster, band) -> raster''' The first series of variant return a raster having the same extent as the provided raster. Variant 1: ST_Intersection(geometry, val, raster, band, pixeltype, nodatavalue) -> raster Variant 2: ST_Intersection(raster, band, geometry, val, pixeltype, nodatavalue) -> raster Variant 3: ST_Intersection(geometry, val, raster, pixeltype, nodatavalue) -> raster Variant 4: ST_Intersection(raster, geometry, val, pixeltype, nodatavalue) -> raster The second series of variant return a raster having the minimal extent. Variant 5: ST_Intersection(geometry, val, raster, band, pixeltype, nodatavalue, 'TRIM') -> raster Variant 6: ST_Intersection(raster, band, geometry, val, pixeltype, nodatavalue, 'TRIM') -> raster Variant 7: ST_Intersection(geometry, val, raster, pixeltype, nodatavalue, 'TRIM') -> raster Variant 8: ST_Intersection(raster, geometry, val, pixeltype, nodatavalue, 'TRIM') -> raster Returns a two bands raster the first band containing only the pixels from the provided raster intersecting with the geometry and the second band containing the same area filled with the provided value. The second band gets its pixeltype and nodatavalue from the parameters. Non intersecting pixels are filled with nodata values. Variant 1 return a raster having the same extent as the provided raster. Variant 3, 4, 7 and 8 defaults the band number to 1. Variant 5 to 8 "trim" or "crop" the raster to the withvalue extent (removing extra nodata value pixels surrounding the extent of the resulting withvalue extent). '''Open question''' PR: Shoud we return one raster per raster/geometry couple or split the raster into as many small rasters as there are areas sharing a same value? The second behavior seems more coherent with the present behavior of ST_Intersection(raster, geometry) -> geometry even if this would produce tons of small two bands rasters. '''Implementation details''' Rasterize the geometry as a new raster (ST_AsRaster(geometry, pixeltype, val, nodataval, raster)) and then copy only pixels for which both raster bands have a value. Should be implemented as a wrapper around ST_MapAlgebra after rasterizing the geometry to a raster having the same alignment as the raster. ---- == '''Objective FV.03 - Implement all the necessary versions of ST_MapAlgebra''' == Different versions of ST_MapAlgebra are planned... One raster versions: 1) '''ST_MapAlgebraExpr() -''' A one raster version taking an '''expression''' of one pixel at a time. Already implemented... 2) '''ST_MapAlgebraFct() -''' A one raster version taking a '''user defined function''' (with optional parameters) of one pixel at a time. The function is a user defined PL/pgSQL function taking a float8 value and returning a value. Code was developped by David Zwarg, needs to be integrated in the source tree. This version is much faster than 1) but requires the user to write a PL/pgSQL function. 3) '''ST_MapAlgebraFctNgb() -''' A one raster version taking a '''user defined function''' (with optional parameters) of the set of first, second, etc... '''neighbours''' of a pixel. The function is a user defined PL/pgSQL function taking a matrix containing the neighbour values and returning one value. Code do not exist yet but will be very much similar to 2). Out of bound pixels values are set to NULL. This version requires the user to write a PL/pgSQL function. Many predefined function should be delivered. 4) '''ST_MapAlgebraFctNgb() -''' A one raster version taking a '''table name and a raster column name''' (in order to work on a '''tiled coverage''') and a '''user defined function''' (with optional parameters) of the set of first, second, etc... '''neighbours''' of a pixel. The passed matrix should include values for out of bound pixels taken from neighbour tiles. Two rasters versions. These versions must take into account different alignment, different extents, nodata and non-existent values. 5) '''ST_MapAlgebraExpr() -''' A two rasters version taking an expression of two pixels at a time, one from each rasters. 6) '''ST_MapAlgebraExpr() -''' A two rasters version taking a '''table name and a raster column name''' (in order to work on a '''tiled coverage''') and an expression of two pixels at a time, one from each rasters. 7) '''ST_MapAlgebraFct() -''' A two rasters version taking a '''user defined function''' (with optional parameters) of two pixels at a time, one from each rasters. The function is a user defined PL/pgSQL function taking two float8 values and returning one value. 8) '''ST_MapAlgebraFct() -''' A two rasters version taking a '''table name and a raster column name''' (in order to work on a '''tiled coverage''') and a '''user defined function''' (with optional parameters) of two pixels at a time, one from each rasters. The function is a user defined PL/pgSQL function taking two float8 values and returning one value. Non-existent values are found in the neighbour tiles when possible. '''Details for 3) ST_MapAlgebraFctNgb()''' For now ST_MapAlgebra expressions refer only to the pixel being computed. e.g. "rast * 100". The original plan was to allow refering to neighbour pixels using two coordinated relative to the pixel being computed. e.g. "rast[-1,0] * 100" where rast[-1,0] refer to the value of the pixel one pixel to the left of the pixel being computed. However this syntax might prove to be hard to use when many neighbours are to be used. An alternative syntax would involve another function name (e.g. ST_MapAlgebraNgb or ST_MovingWindow) and a way to define a neighbour rectangular region around the computed pixel (e.g.: "2,2" meaning a rectangle encompassing the two neighbour pixels in each direction) and a function to call with this matrix of pixel values. A complete example might look like: SELECT ST_MapAlgebraNgb(rast, band, pixeltype, "ST_Mean", 2, 2, "ignore") So this would mean "for each pixel, compute the average of all the 1 + 8 + 16 = 25 pixels surrounding the current pixel and "ignore" pixels with nodata values." The "ST_Mean" summarizing function should accept three parameters: an array of float8 values, a X and a Y dimension, and optionnally a "what to do with nodata values". The possible value for this last parameter could be: * "NULL": If any value is a nodata value, return NULL. * "ignore": Ignore any nodata value so that if 4 pixels on 25 are nodata values, do the computation with the 21 remaining. This is the default. * "value": Replace any nodata value with the value of the pixel being computed. * a value: Replace any nodata value with this value and compute. Any remaining parameters to ST_MapAlgebraNgb could be passed to the summarizing functions for its own need (e.g. "round" to specify that only the pixel forming a circle should be used in the computing). A number of predefined summarizing function could be delivered: ST_Max, ST_Min, ST_Sum, ST_Distinct, ST_Mean, ST_STD, ST_Range, ST_Quantile, ST_Median, ST_Majority, ST_Minority, ST_Slope, ST_Aspect, and more... Users could write their own map algebra summarizing functions. A more sophisticated version would pass a georeferenced raster instead of just a value matrix so that summarizing function could use this geoereference (e.g. to determine a value from the whole coverage (with ST_Value) when the neighbours are out of the bound of the raster). Passing a raster would allow existing raster functions (like the summarizing function which are to come). Only the optional "what to do with nodata values" could be needed and some additional parameters. In this case the example become: SELECT ST_MapAlgebraNgb(rast, band, pixeltype, 2, 2, "ST_Mean", "ignore") and the dimensions do not have to be passed to the summarizing functions since it could deduce them from ST_Width & ST_Height. An even more sophisticated version should get a raster table and a raster column as parameters and try to search for neighbour in the whole raster coverage when out of bound pixels are part of the neighbourhood. e.g.: SELECT ST_MapAlgebraNgb("mycoveragetable", "myrastercolumn", band, pixeltype, 2, 2, "ST_Mean", "ignore") Three difficulties must be solved to implement this function: * The construction of the matrix must to be passed to the summarizing functions must be optimized when passing from one pixel to the other. * We must see how it is possible to call a PL/pgSQL function from a C function * We must see how to pass a variable number of parameter to a PL/pgSQL function See also: [wiki:WKTRaster/MapAlgebra Notes taken by David Zwarg during the Montreal Code Sprint 2011] and http://trac.osgeo.org/postgis/ticket/860 '''Details for 5) to 8) Two rasters versions''' These function must first determine if a resampling of one raster is necessary: '''ST_SameAlignment(raster, raster)''' This function returns true if both rasters' grids are aligned. Two rasters grid are aligned if: -They share the same pixel scales and skews -At least one of any of the four corner of any pixel of one raster fall on any corner of the grid of the other raster. Alignment is not the same concept as georeference. Two rasters can be aligned but not have the same georeference. Rotation is important here since two rasters grid might look perfectly aligned but are not if their rotated are different. Knowing if two rasters share the same alignment is useful when it is time to decide if one of them must be resampled before doing other operations (like ST_MapAlgebra on two rasters). '''Variants''' 1) ST_SameAlignment(ulx1, uly1, scalex1, scaley1, skewx1, skewy1, ulx2, uly2, scalex2, scaley2, skewx2, skewy2) 2) ST_SameAlignment(rast1 raster, rast2 raster) The first variant is useful to PL/pgSQL function which have already get the values of the parameters. '''Implementation Details''' Only the first variant should be implemented in C. The second one is a PL/pgSQL variants. The C implementation should follow the PL/pgSQL version implemented in http://trac.osgeo.org/postgis/browser/trunk/raster/scripts/plpgsql/st_mapalgebra.sql It is not clear if this PL/pgSQL implementation works when raster are rotated. To verify. See discussion in http://trac.osgeo.org/postgis/ticket/589 '''ST_MapAlgebra on two rasters''' Specifications of ST_MapAlgebra on two rasters are still in progress as a new optimised version, filling large areas of same value more quickly, is planned. See http://trac.osgeo.org/postgis/browser/trunk/raster/scripts/plpgsql/st_mapalgebra_optimized.sql See discussion in http://trac.osgeo.org/postgis/ticket/590 ---- == '''Objective FV.04 - Being able to use "group by" to accumulate tiles to form a new raster.''' == '''ST_Union(raster|geometry, raster|geometry, ‘raster’|’geometry’) -> raster/geometry'''[[BR]] '''ST_Accum(raster set|geometry set, ‘raster’|’geometry’) -> raster/geometry''' ---- == '''Objective FV.05 - Being able to reproject a raster.''' == '''ST_Transform(raster|geometry, SRID) -> same type as input''' ---- == '''Objective FV.06 - Being able to do some base raster operations.''' == '''ST_Area(raster|geometry) -> double'''[[BR]] '''ST_Count(raster, value) -> integer'''[[BR]] '''ST_Resample(raster, method, originx, originy, pixelsizex, pixelsizey) -> raster''' '''Variant''' 1) ST_Resample(raster, method, raster) -> raster Recompute a raster in order to change its pixel size and/or the position of its upper left corner. The second parameter is the resampling method performed when computing new pixel values: 1) 'NEAREST NEIGHBOR'[[BR]] 2) 'LINEAR'[[BR]] 3) 'BICUBIC' The 3rd or 3rd-6th parameters define the pixel size of the resampling operation. For the 3rd parameter variant, the pixel size is taken from the pixel size of the raster parameter. For the 3rd-6th parameter variant, the pixel origin and dimensions are explicitly defined. '''ST_SelectByValue(raster|geometry, ‘expression’) -> same type as first argument'''[[BR]] '''ST_Reclass(raster|geometry,string) -> same type as first argument'''[[BR]] Bborie: Implementation has been moved to FV.01 above. '''ST_MapAlgebra(raster|geometry, [raster|geometry,…] ‘mathematical expression’, ‘raster’ |’geometry’) -> raster/geometry''' Variant 1: ST_MapAlgebra(raster|geometry, [raster|geometry,…] ‘mathematical expression’, ‘raster’ |’geometry’, originx, originy, pixelsizex, pixelsizey) -> raster/geometry Variant 2: ST_MapAlgebra(raster|geometry, [raster|geometry,…] 'mathematical expression', 'raster' |'geometry', integer) ->raster/geometry Variant 3: ST_MapAlgebra(raster|geometry, [raster|geometry,…] 'mathematical expression', 'raster' |'geometry', raster) ->raster/geometry ST_MapAlgebra performs the specified mathematical expression on the input rasters, returning a raster or geometry. Both rasters must have the same SRID. If both rasters do not have the same SRID, ST_MapAlgebra will return an error: ERROR: Operation on two geometries with different SRIDs The first raster passed to ST_MapAlgebra is the 'master' raster, unless either: 1 additional parameter specifies the index (in the parameter list) of the 'master' raster.[[BR]] 1 additional parameter specifies a raster whose origin and cell size should be used to compute the output raster.[[BR]] 4 additional parameters are passed specifying the origin, cell size, and raster rotation. This function implicitly calls ST_Intersects(raster|geometry, [raster|geometry,…]) to detect if the rasters are overlapping before performing any computation. Additionally, the resulting raster will have the same extent as the result of ST_Intersection(raster, integer, geometry). One of the implications of the ST_Intersects inclusion is that: SELECT ST_MapAlgebra(rast1, rast2, mathExpr) FROM mytable WHERE ST_Intersects(rast1, rast2) will be faster than: SELECT ST_MapAlgebra(rast1, rast2, mathExpr) FROM mytable '''Open Question:''' DZ: Should ST_MapAlgebra resample rasters internally, or produce a raster that can be processed by ST_Resample? If so, variant 1 and variant 3 can be removed, and all ST_MapAlgebra results can be processed through ST_Resample, like: ST_Resample(ST_MapAlgebra(raster, [raster,…] 'mathematical expression', integer), originx, originy, pixelsizex, pixelsizey)[[BR]] ST_Resample(ST_MapAlgebra(raster, [raster,…] 'mathematical expression', integer), rastergrid) PR: I think this would greatly contribute to simplify the API. '''ST_Clip(raster|geometry,geometry) -> same type as first argument'''[[BR]] '''ST_Flip(raster|geometry, ’vertical’|’horizontal’) -> same type as first argument''' ---- == '''Objective FV.07 - Being able to convert a raster to standards formats.''' == '''ST_AsKML(raster|geometry) -> string'''[[BR]] '''ST_AsSVG(raster|geometry) -> string''' ---- == '''Objective FV.08 - Being able to control the validity of a raster.''' == '''ST_IsEmpty(raster|geometry) -> boolean'''[[BR]] '''ST_mem_size(raster|geometry) -> integer'''[[BR]] '''ST_isvalid(raster|geometry) -> boolean''' ---- == '''Objective FV.09 - Being able to use other major topological operators''' == '''ST_Within(raster|geometry A, raster|geometry B)'''[[BR]] '''ST_Contains(raster|geometry A, raster|geometry B)'''[[BR]] '''ST_Overlaps(raster|geometry, raster|geometry)''' ---- == '''Objective FV.10 - Being able to derive a raster layer from vector layer.''' == '''ST_Interpolate(points, pixelsize, method) -> raster''' ---- == '''Objective FV.11 - Being able to do on rasters most operations available on geometries''' == '''ST_Centroid(raster|geometry) -> point geometry'''[[BR]] '''ST_PointOnSurface(raster|geometry) -> point geometry'''[[BR]] '''ST_Buffer(raster|geometry, double) -> same type as first arg.'''[[BR]] '''ST_Difference(raster|geometry A, raster|geometry B) -> same type as first argument'''[[BR]] '''ST_SymDifference(raster|geometry,raster|geometry,‘raster’|’geometry’) -> raster/geometry''' ---- == '''Objective FV.12 - Being able to use all the other topological operators''' == '''ST_Equals(raster|geometry, raster|geometry)'''[[BR]] '''ST_Disjoint(raster|geometry, raster|geometry)'''[[BR]] '''ST_Touches(raster|geometry, raster|geometry)'''[[BR]] '''ST_Crosses(raster|geometry, raster|geometry)'''[[BR]] '''ST_Covers(raster|geometry A, raster|geometry B)'''[[BR]] '''ST_IsCoveredBy(raster|geometry A, raster|geometry B)'''[[BR]] '''ST_Relate(raster|geometry, raster|geometry, intersectionPatternMatrix )''' ---- == '''Objective FV.13 - Being able to edit a raster''' == '''ST_Affine(raster|geometry,…) -> same type as input'''[[BR]] '''ST_Translate(raster|geometry,…) -> same type as input'''[[BR]] '''ST_Scale(raster|geometry,…) -> same type as input'''[[BR]] '''ST_TransScale(raster|geometry,…) -> same type as input'''[[BR]] '''ST_RotateZ,Y,Z(raster|geometry, float8) -> same type as input''' ---- == '''Objective FV.14 - Being able to intersect two rasters to get a raster.''' == '''ST_Intersection(raster, integer, raster, integer) -> raster''' - Returns a two bands raster with values only in the intersecting areas of both rasters. Integer parameters are the band number of the raster. '''Variants''' 1) ST_Intersection(raster, integer, raster, integer) -> raster -- the integer parameters are the band number of the rasters[[BR]] 2) ST_Intersection(raster, raster, integer) -> raster -- default first raster to band # 1[[BR]] 3) ST_Intersection(raster, integer, raster) -> raster -- default second raster to band # 1[[BR]] 4) ST_Intersection(raster, raster) -> raster -- default both rasters to band # 1 ---- == '''Objective FV.15 - Being able to intersect two rasters to get a geometry.''' == '''ST_Intersection(raster, integer, raster, integer, 'geometry') -> geometry''' - Returns a two bands raster with values only in the intersecting areas of both rasters. Integer parameters are the band number of the raster. '''Variants''' 1) ST_Intersection(raster, integer, raster, integer, 'geometry') -> geometry[[BR]] 2) ST_Intersection(raster, raster, integer, 'geometry') -> geometry -- default first raster to band # 1[[BR]] 3) ST_Intersection(raster, integer, raster, 'geometry') -> geometry -- default second raster to band # 1[[BR]] 4) ST_Intersection(raster, raster, 'geometry') -> geometry -- default both raster to band # 1 ---- == '''Objective FV.16 - Being able to quickly get raster statistics.''' == '''Add cached basic raster statistic to the base raster WKB format. Statistics to be cached should include: min/max[[BR]] mean[[BR]] standard deviation[[BR]] histogram[[BR]] build parameters of stats (sample rate, method used to determine # of bins in histogram?)[[BR]] How are the statistics to be kept fresh? Automatically using some method to see how much of the raster has changed since the last stats calculation? Or let the user decide? ---- == '''Objective FV.17 - Being able to refer to band by textual name.''' == '''Add 8 digit string to each band in the base raster WKB format. '''Adjust gdal2wktraster.py to be able to give names to each band when importing. '''Adjust/overlaod every function to be able to refer to raster band by name. ---- == '''Objective FV.18 - Being able to load rasters from SQL''' == The idea is to change the rt_band_get_data core function so it load filesystem registered raster data using GDAL into the data base. This allow us to create a list of raster with a new ST_MakeRegisteredRaster("c:/temp/mytiff/*.tif") and to convert them witinot a CREATE TABLE with a ST_MakeBandInDB(rast, band) '''Changes to the rt_band_get_data core function'''[[BR]] '''ST_MakeRegisteredRaster(wildcardPath)'''[[BR]] '''ST_SetPath(raster, band, string)'''[[BR]] '''ST_MakeBandInDB(rast, band)''' ---- == '''Other functions''' == '''ST_AsBinary(raster, compression)'''[[BR]] '''ST_RasterFromWKB(raster, [])'''[[BR]] '''ST_RasterFromText(string, [])'''[[BR]] '''ST_AsText(raster)'''