rnsf

Define and load a phase function data format
git clone git://git.meso-star.fr/rnsf.git
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commit 0b89de5bb1130f3af4f424cd10e1718c5a879b90
parent 3a54cdffad7d28f89bfc11166029b88547cb185f
Author: Vincent Forest <vincent.forest@meso-star.com>
Date:   Thu,  7 Jul 2022 11:21:34 +0200

Fix loading tests

Diffstat:

Msrc/test_rnsf_bands.c | 86++++++++++++++++++++++++++++++++++++++++----------------------------------------


Msrc/test_rnsf_wlens.c | 110++++++++++++++++++++++++++++++++++++++++----------------------------------------


2 files changed, 98 insertions(+), 98 deletions(-)

diff --git a/src/test_rnsf_bands.c b/src/test_rnsf_bands.c
@@ -34,13 +34,13 @@ test_load1(struct rnsf* rnsf)
   FILE* fp = NULL;
   const char* filename = "test_file_bands.rnsf";
   const struct rnsf_phase_fn* phase = NULL;
-  struct rnsf_phase_fn_hg hg = RNSF_PHASE_FN_HG_NULL;
+  struct rnsf_phase_fn_hg HG = RNSF_PHASE_FN_HG_NULL;
 
   CHK(fp = fopen(filename, "w+"));
   fprintf(fp, "# Comment\n");
   fprintf(fp, "bands 1\n");
   fprintf(fp, "\n");
-  fprintf(fp, "200.1 280.3 hg 0\n");
+  fprintf(fp, "200.1 280.3 HG 0\n");
   rewind(fp);
 
   CHK(rnsf_load_stream(NULL, fp, filename) == RES_BAD_ARG);
@@ -59,12 +59,12 @@ test_load1(struct rnsf* rnsf)
   CHK(phase = rnsf_get_phase_fn(rnsf, 0));
   CHK(rnsf_phase_fn_get_type(phase) == RNSF_PHASE_FN_HG);
 
-  CHK(rnsf_phase_fn_get_hg(NULL, &hg) == RES_BAD_ARG);
+  CHK(rnsf_phase_fn_get_hg(NULL, &HG) == RES_BAD_ARG);
   CHK(rnsf_phase_fn_get_hg(phase, NULL) == RES_BAD_ARG);
-  CHK(rnsf_phase_fn_get_hg(phase, &hg) == RES_OK);
-  CHK(hg.wavelengths[0] == 200.1);
-  CHK(hg.wavelengths[1] == 280.3);
-  CHK(hg.g == 0);
+  CHK(rnsf_phase_fn_get_hg(phase, &HG) == RES_OK);
+  CHK(HG.wavelengths[0] == 200.1);
+  CHK(HG.wavelengths[1] == 280.3);
+  CHK(HG.g == 0);
   CHK(fclose(fp) == 0);
 }
 
@@ -72,7 +72,7 @@ static void
 test_load2(struct rnsf* rnsf)
 {
   struct rnsf_phase_fn_discrete discrete = RNSF_PHASE_FN_DISCRETE_NULL;
-  struct rnsf_phase_fn_hg hg = RNSF_PHASE_FN_HG_NULL;
+  struct rnsf_phase_fn_hg HG = RNSF_PHASE_FN_HG_NULL;
   FILE* fp = NULL;
   const struct rnsf_phase_fn* phase = NULL;
 
@@ -85,16 +85,16 @@ test_load2(struct rnsf* rnsf)
 
   CHK(fp = tmpfile());
   fprintf(fp, "bands 5\n");
-  fprintf(fp, "100 200  hg -0.3\n");
-  fprintf(fp, "200 300  hg  0.4\n");
-  fprintf(fp, "300 400  hg  0.5\n");
+  fprintf(fp, "100 200  HG -0.3\n");
+  fprintf(fp, "200 300  HG  0.4\n");
+  fprintf(fp, "300 400  HG  0.5\n");
   fprintf(fp, "850 875.123  discrete 5\n");
   fprintf(fp, " 0  0.3\n");
   fprintf(fp, " %.9g 0.3\n", PI/4.0);
   fprintf(fp, " %.9g 0.3\n", PI/2.0);
   fprintf(fp, " %.9g 0.3\n", 3*PI/4.0);
   fprintf(fp, " 3.14159 0.3\n");
-  fprintf(fp, "900 900 hg -0.1\n");
+  fprintf(fp, "900 900 HG -0.1\n");
   rewind(fp);
   CHK(rnsf_load_stream(rnsf, fp, NULL) == RES_OK);
 
@@ -103,25 +103,25 @@ test_load2(struct rnsf* rnsf)
   CHK(phase = rnsf_get_phase_fn(rnsf, 0));
   CHK(rnsf_phase_fn_get_type(phase) == RNSF_PHASE_FN_HG);
   CHK(rnsf_phase_fn_get_discrete(phase, &discrete) == RES_BAD_ARG);
-  CHK(rnsf_phase_fn_get_hg(phase, &hg) == RES_OK);
-  CHK(hg.wavelengths[0] == 100 && hg.wavelengths[1] == 200);
-  CHK(hg.g == -0.3);
+  CHK(rnsf_phase_fn_get_hg(phase, &HG) == RES_OK);
+  CHK(HG.wavelengths[0] == 100 && HG.wavelengths[1] == 200);
+  CHK(HG.g == -0.3);
 
   CHK(phase = rnsf_get_phase_fn(rnsf, 1));
   CHK(rnsf_phase_fn_get_type(phase) == RNSF_PHASE_FN_HG);
-  CHK(rnsf_phase_fn_get_hg(phase, &hg) == RES_OK);
-  CHK(hg.wavelengths[0] == 200 && hg.wavelengths[1] == 300);
-  CHK(hg.g == 0.4);
+  CHK(rnsf_phase_fn_get_hg(phase, &HG) == RES_OK);
+  CHK(HG.wavelengths[0] == 200 && HG.wavelengths[1] == 300);
+  CHK(HG.g == 0.4);
 
   CHK(phase = rnsf_get_phase_fn(rnsf, 2));
   CHK(rnsf_phase_fn_get_type(phase) == RNSF_PHASE_FN_HG);
-  CHK(rnsf_phase_fn_get_hg(phase, &hg) == RES_OK);
-  CHK(hg.wavelengths[0] == 300 && hg.wavelengths[1] == 400);
-  CHK(hg.g == 0.5);
+  CHK(rnsf_phase_fn_get_hg(phase, &HG) == RES_OK);
+  CHK(HG.wavelengths[0] == 300 && HG.wavelengths[1] == 400);
+  CHK(HG.g == 0.5);
 
   CHK(phase = rnsf_get_phase_fn(rnsf, 3));
   CHK(rnsf_phase_fn_get_type(phase) == RNSF_PHASE_FN_DISCRETE);
-  CHK(rnsf_phase_fn_get_hg(phase, &hg) == RES_BAD_ARG);
+  CHK(rnsf_phase_fn_get_hg(phase, &HG) == RES_BAD_ARG);
   CHK(rnsf_phase_fn_get_discrete(NULL, &discrete) == RES_BAD_ARG);
   CHK(rnsf_phase_fn_get_discrete(phase, NULL) == RES_BAD_ARG);
   CHK(rnsf_phase_fn_get_discrete(phase, &discrete) == RES_OK);
@@ -141,9 +141,9 @@ test_load2(struct rnsf* rnsf)
 
   CHK(phase = rnsf_get_phase_fn(rnsf, 4));
   CHK(rnsf_phase_fn_get_type(phase) == RNSF_PHASE_FN_HG);
-  CHK(rnsf_phase_fn_get_hg(phase, &hg) == RES_OK);
-  CHK(hg.wavelengths[0] == 900 && hg.wavelengths[1] == 900);
-  CHK(hg.g == -0.1);
+  CHK(rnsf_phase_fn_get_hg(phase, &HG) == RES_OK);
+  CHK(HG.wavelengths[0] == 900 && HG.wavelengths[1] == 900);
+  CHK(HG.g == -0.1);
 
   CHK(fclose(fp) == 0);
 }
@@ -170,8 +170,8 @@ test_fetch(struct rnsf* rnsf)
 
   CHK(fp = tmpfile());
   fprintf(fp, "bands 2\n");
-  fprintf(fp, "200 300 hg 0.0\n");
-  fprintf(fp, "300 400 hg 0.1\n");
+  fprintf(fp, "200 300 HG 0.0\n");
+  fprintf(fp, "300 400 HG 0.1\n");
   rewind(fp);
   CHK(rnsf_load_stream(rnsf, fp, NULL) == RES_OK);
   CHK(fclose(fp) == 0);
@@ -187,9 +187,9 @@ test_fetch(struct rnsf* rnsf)
 
   CHK(fp = tmpfile());
   fprintf(fp, "bands 4\n");
-  fprintf(fp, "100 150 hg 0\n");
-  fprintf(fp, "200 200 hg 1\n");
-  fprintf(fp, "300 400 hg -1\n");
+  fprintf(fp, "100 150 HG 0\n");
+  fprintf(fp, "200 200 HG 1\n");
+  fprintf(fp, "300 400 HG -1\n");
   fprintf(fp, "400 401 discrete 4\n");
   fprintf(fp, " 0 1\n");
   fprintf(fp, " 0.5 1\n");
@@ -223,7 +223,7 @@ test_load_fail(struct rnsf* rnsf)
   /* Invalid keyword */
   CHK(fp = tmpfile());
   fprintf(fp, "bandes 1\n");
-  fprintf(fp, "380 780 hg 0.5\n");
+  fprintf(fp, "380 780 HG 0.5\n");
   rewind(fp);
   CHK(rnsf_load_stream(rnsf, fp, NULL) == RES_BAD_ARG);
   CHK(fclose(fp) == 0);
@@ -231,7 +231,7 @@ test_load_fail(struct rnsf* rnsf)
   /* No band count */
   CHK(fp = tmpfile());
   fprintf(fp, "bands\n");
-  fprintf(fp, "380 780 hg 0.5\n");
+  fprintf(fp, "380 780 HG 0.5\n");
   rewind(fp);
   CHK(rnsf_load_stream(rnsf, fp, NULL) == RES_BAD_ARG);
   CHK(fclose(fp) == 0);
@@ -239,7 +239,7 @@ test_load_fail(struct rnsf* rnsf)
   /* Missing a band definition */
   CHK(fp = tmpfile());
   fprintf(fp, "bands 2\n");
-  fprintf(fp, "380 780 hg 0.5\n");
+  fprintf(fp, "380 780 HG 0.5\n");
   rewind(fp);
   CHK(rnsf_load_stream(rnsf, fp, NULL) == RES_BAD_ARG);
   CHK(fclose(fp) == 0);
@@ -247,7 +247,7 @@ test_load_fail(struct rnsf* rnsf)
   /* Invalid wavelengths */
   CHK(fp = tmpfile());
   fprintf(fp, "bands 1\n");
-  fprintf(fp, "-380 780 hg 0.5\n");
+  fprintf(fp, "-380 780 HG 0.5\n");
   rewind(fp);
   CHK(rnsf_load_stream(rnsf, fp, NULL) == RES_BAD_ARG);
   CHK(fclose(fp) == 0);
@@ -255,7 +255,7 @@ test_load_fail(struct rnsf* rnsf)
   /* Missing a band boundary */
   CHK(fp = tmpfile());
   fprintf(fp, "bands 1\n");
-  fprintf(fp, "380 hg 0.5\n");
+  fprintf(fp, "380 HG 0.5\n");
   rewind(fp);
   CHK(rnsf_load_stream(rnsf, fp, NULL) == RES_BAD_ARG);
   CHK(fclose(fp) == 0);
@@ -271,7 +271,7 @@ test_load_fail(struct rnsf* rnsf)
   /* Invalid asymmetric param  */
   CHK(fp = tmpfile());
   fprintf(fp, "bands 1\n");
-  fprintf(fp, "380 780 hg 1.01\n");
+  fprintf(fp, "380 780 HG 1.01\n");
   rewind(fp);
   CHK(rnsf_load_stream(rnsf, fp, NULL) == RES_BAD_ARG);
   CHK(fclose(fp) == 0);
@@ -279,7 +279,7 @@ test_load_fail(struct rnsf* rnsf)
   /* Additional parameters. Print a warning */
   CHK(fp = tmpfile());
   fprintf(fp, "bands 1 additional_text\n");
-  fprintf(fp, "380 780 hg 1.0\n");
+  fprintf(fp, "380 780 HG 1.0\n");
   rewind(fp);
   CHK(rnsf_load_stream(rnsf, fp, NULL) == RES_OK);
   CHK(fclose(fp) == 0);
@@ -287,8 +287,8 @@ test_load_fail(struct rnsf* rnsf)
   /* Unsorted phase functions */
   CHK(fp = tmpfile());
   fprintf(fp, "bands 2\n");
-  fprintf(fp, "380 400 hg 1.0\n");
-  fprintf(fp, "280 300 hg 0.0\n");
+  fprintf(fp, "380 400 HG 1.0\n");
+  fprintf(fp, "280 300 HG 0.0\n");
   rewind(fp);
   CHK(rnsf_load_stream(rnsf, fp, NULL) == RES_BAD_ARG);
   CHK(fclose(fp) == 0);
@@ -296,8 +296,8 @@ test_load_fail(struct rnsf* rnsf)
   /* Phase functions overlap */
   CHK(fp = tmpfile());
   fprintf(fp, "bands 2\n");
-  fprintf(fp, "280 400 hg 1.0\n");
-  fprintf(fp, "300 480 hg 0.0\n");
+  fprintf(fp, "280 400 HG 1.0\n");
+  fprintf(fp, "300 480 HG 0.0\n");
   rewind(fp);
   CHK(rnsf_load_stream(rnsf, fp, NULL) == RES_BAD_ARG);
   CHK(fclose(fp) == 0);
@@ -305,8 +305,8 @@ test_load_fail(struct rnsf* rnsf)
   /* Phase functions overlap */
   CHK(fp = tmpfile());
   fprintf(fp, "bands 2\n");
-  fprintf(fp, "280 280 hg 1.0\n");
-  fprintf(fp, "280 280 hg 0.0\n");
+  fprintf(fp, "280 280 HG 1.0\n");
+  fprintf(fp, "280 280 HG 0.0\n");
   rewind(fp);
   CHK(rnsf_load_stream(rnsf, fp, NULL) == RES_BAD_ARG);
   CHK(fclose(fp) == 0);
diff --git a/src/test_rnsf_wlens.c b/src/test_rnsf_wlens.c
@@ -32,7 +32,7 @@ static void
 test_load(struct rnsf* rnsf)
 {
   struct rnsf_phase_fn_discrete discrete = RNSF_PHASE_FN_DISCRETE_NULL;
-  struct rnsf_phase_fn_hg hg = RNSF_PHASE_FN_HG_NULL;
+  struct rnsf_phase_fn_hg HG = RNSF_PHASE_FN_HG_NULL;
   const struct rnsf_phase_fn* phase = NULL;
   FILE* fp = NULL;
 
@@ -47,7 +47,7 @@ test_load(struct rnsf* rnsf)
   fprintf(fp, "# Comment\n");
   fprintf(fp, "wavelengths 1\n");
   fprintf(fp, "\n");
-  fprintf(fp, "200.1 hg 0\n");
+  fprintf(fp, "200.1 HG 0\n");
   rewind(fp);
 
   CHK(rnsf_load_stream(rnsf, fp, NULL) == RES_OK);
@@ -56,10 +56,10 @@ test_load(struct rnsf* rnsf)
   CHK(phase = rnsf_get_phase_fn(rnsf, 0));
   CHK(rnsf_phase_fn_get_type(phase) == RNSF_PHASE_FN_HG);
 
-  CHK(rnsf_phase_fn_get_hg(phase, &hg) == RES_OK);
-  CHK(hg.wavelengths[0] == 200.1);
-  CHK(hg.wavelengths[1] == 200.1);
-  CHK(hg.g == 0);
+  CHK(rnsf_phase_fn_get_hg(phase, &HG) == RES_OK);
+  CHK(HG.wavelengths[0] == 200.1);
+  CHK(HG.wavelengths[1] == 200.1);
+  CHK(HG.g == 0);
   CHK(fclose(fp) == 0);
 
   CHK(fp = tmpfile());
@@ -86,13 +86,13 @@ test_load(struct rnsf* rnsf)
   fprintf(fp, "  %g %.9g\n", PI, 1.0/(4.0*PI));
   fprintf(fp, "\n");
   fprintf(fp, "# Long waves\n");
-  fprintf(fp, "1100    hg   -0.1\n");
-  fprintf(fp, "1300    hg    0.57\n");
-  fprintf(fp, "1400    hg    0.4\n");
-  fprintf(fp, "2100    hg    0.3\n");
-  fprintf(fp, "2500    hg   -0.9\n");
-  fprintf(fp, "2900    hg   -0.4\n");
-  fprintf(fp, "100000  hg    0.0\n");
+  fprintf(fp, "1100    HG   -0.1\n");
+  fprintf(fp, "1300    HG    0.57\n");
+  fprintf(fp, "1400    HG    0.4\n");
+  fprintf(fp, "2100    HG    0.3\n");
+  fprintf(fp, "2500    HG   -0.9\n");
+  fprintf(fp, "2900    HG   -0.4\n");
+  fprintf(fp, "100000  HG    0.0\n");
   rewind(fp);
 
   CHK(rnsf_load_stream(rnsf, fp, NULL) == RES_OK);
@@ -141,52 +141,52 @@ test_load(struct rnsf* rnsf)
 
   CHK(phase = rnsf_get_phase_fn(rnsf, 3));
   CHK(rnsf_phase_fn_get_type(phase) == RNSF_PHASE_FN_HG);
-  CHK(rnsf_phase_fn_get_hg(phase, &hg) == RES_OK);
-  CHK(hg.wavelengths[0] == 1100);
-  CHK(hg.wavelengths[1] == 1100);
-  CHK(hg.g == -0.1);
+  CHK(rnsf_phase_fn_get_hg(phase, &HG) == RES_OK);
+  CHK(HG.wavelengths[0] == 1100);
+  CHK(HG.wavelengths[1] == 1100);
+  CHK(HG.g == -0.1);
 
   CHK(phase = rnsf_get_phase_fn(rnsf, 4));
   CHK(rnsf_phase_fn_get_type(phase) == RNSF_PHASE_FN_HG);
-  CHK(rnsf_phase_fn_get_hg(phase, &hg) == RES_OK);
-  CHK(hg.wavelengths[0] == 1300);
-  CHK(hg.wavelengths[1] == 1300);
-  CHK(hg.g == 0.57);
+  CHK(rnsf_phase_fn_get_hg(phase, &HG) == RES_OK);
+  CHK(HG.wavelengths[0] == 1300);
+  CHK(HG.wavelengths[1] == 1300);
+  CHK(HG.g == 0.57);
 
   CHK(phase = rnsf_get_phase_fn(rnsf, 5));
   CHK(rnsf_phase_fn_get_type(phase) == RNSF_PHASE_FN_HG);
-  CHK(rnsf_phase_fn_get_hg(phase, &hg) == RES_OK);
-  CHK(hg.wavelengths[0] == 1400);
-  CHK(hg.wavelengths[1] == 1400);
-  CHK(hg.g == 0.4);
+  CHK(rnsf_phase_fn_get_hg(phase, &HG) == RES_OK);
+  CHK(HG.wavelengths[0] == 1400);
+  CHK(HG.wavelengths[1] == 1400);
+  CHK(HG.g == 0.4);
 
   CHK(phase = rnsf_get_phase_fn(rnsf, 6));
   CHK(rnsf_phase_fn_get_type(phase) == RNSF_PHASE_FN_HG);
-  CHK(rnsf_phase_fn_get_hg(phase, &hg) == RES_OK);
-  CHK(hg.wavelengths[0] == 2100);
-  CHK(hg.wavelengths[1] == 2100);
-  CHK(hg.g == 0.3);
+  CHK(rnsf_phase_fn_get_hg(phase, &HG) == RES_OK);
+  CHK(HG.wavelengths[0] == 2100);
+  CHK(HG.wavelengths[1] == 2100);
+  CHK(HG.g == 0.3);
 
   CHK(phase = rnsf_get_phase_fn(rnsf, 7));
   CHK(rnsf_phase_fn_get_type(phase) == RNSF_PHASE_FN_HG);
-  CHK(rnsf_phase_fn_get_hg(phase, &hg) == RES_OK);
-  CHK(hg.wavelengths[0] == 2500);
-  CHK(hg.wavelengths[1] == 2500);
-  CHK(hg.g == -0.9);
+  CHK(rnsf_phase_fn_get_hg(phase, &HG) == RES_OK);
+  CHK(HG.wavelengths[0] == 2500);
+  CHK(HG.wavelengths[1] == 2500);
+  CHK(HG.g == -0.9);
 
   CHK(phase = rnsf_get_phase_fn(rnsf, 8));
   CHK(rnsf_phase_fn_get_type(phase) == RNSF_PHASE_FN_HG);
-  CHK(rnsf_phase_fn_get_hg(phase, &hg) == RES_OK);
-  CHK(hg.wavelengths[0] == 2900);
-  CHK(hg.wavelengths[1] == 2900);
-  CHK(hg.g == -0.4);
+  CHK(rnsf_phase_fn_get_hg(phase, &HG) == RES_OK);
+  CHK(HG.wavelengths[0] == 2900);
+  CHK(HG.wavelengths[1] == 2900);
+  CHK(HG.g == -0.4);
 
   CHK(phase = rnsf_get_phase_fn(rnsf, 9));
   CHK(rnsf_phase_fn_get_type(phase) == RNSF_PHASE_FN_HG);
-  CHK(rnsf_phase_fn_get_hg(phase, &hg) == RES_OK);
-  CHK(hg.wavelengths[0] == 100000);
-  CHK(hg.wavelengths[1] == 100000);
-  CHK(hg.g == 0);
+  CHK(rnsf_phase_fn_get_hg(phase, &HG) == RES_OK);
+  CHK(HG.wavelengths[0] == 100000);
+  CHK(HG.wavelengths[1] == 100000);
+  CHK(HG.g == 0);
 
   CHK(fclose(fp) == 0);
 }
@@ -207,8 +207,8 @@ test_fetch(struct rnsf* rnsf)
 
   CHK(fp = tmpfile());
   fprintf(fp, "wavelengths 2\n");
-  fprintf(fp, "200 hg 0\n");
-  fprintf(fp, "300 hg 0\n");
+  fprintf(fp, "200 HG 0\n");
+  fprintf(fp, "300 HG 0\n");
   rewind(fp);
   CHK(rnsf_load_stream(rnsf, fp, NULL) == RES_OK);
   CHK(fclose(fp) == 0);
@@ -230,9 +230,9 @@ test_fetch(struct rnsf* rnsf)
 
   CHK(fp = tmpfile());
   fprintf(fp, "wavelengths 4\n");
-  fprintf(fp, "100 hg 0\n");
-  fprintf(fp, "200 hg 1\n");
-  fprintf(fp, "300 hg -1\n");
+  fprintf(fp, "100 HG 0\n");
+  fprintf(fp, "200 HG 1\n");
+  fprintf(fp, "300 HG -1\n");
   fprintf(fp, "400 discrete 4\n");
   fprintf(fp, " 0 1\n");
   fprintf(fp, " 0.5 1\n");
@@ -264,7 +264,7 @@ test_load_failure(struct rnsf* rnsf)
   /* No wavelength count */
   CHK(fp = tmpfile());
   fprintf(fp, "wavelengths\n");
-  fprintf(fp, "380 hg 0.5\n");
+  fprintf(fp, "380 HG 0.5\n");
   rewind(fp);
   CHK(rnsf_load_stream(rnsf, fp, NULL) == RES_BAD_ARG);
   CHK(fclose(fp) == 0);
@@ -272,7 +272,7 @@ test_load_failure(struct rnsf* rnsf)
   /* Missing a phase function */
   CHK(fp = tmpfile());
   fprintf(fp, "wavelengths 2\n");
-  fprintf(fp, "380 hg 0.5\n");
+  fprintf(fp, "380 HG 0.5\n");
   rewind(fp);
   CHK(rnsf_load_stream(rnsf, fp, NULL) == RES_BAD_ARG);
   CHK(fclose(fp) == 0);
@@ -280,7 +280,7 @@ test_load_failure(struct rnsf* rnsf)
   /* Invalid wavelength */
   CHK(fp = tmpfile());
   fprintf(fp, "wavelengths 1\n");
-  fprintf(fp, "-380 hg 0.5\n");
+  fprintf(fp, "-380 HG 0.5\n");
   rewind(fp);
   CHK(rnsf_load_stream(rnsf, fp, NULL) == RES_BAD_ARG);
   CHK(fclose(fp) == 0);
@@ -288,8 +288,8 @@ test_load_failure(struct rnsf* rnsf)
   /* Unsorted phase functions */
   CHK(fp = tmpfile());
   fprintf(fp, "wavelengths 2\n");
-  fprintf(fp, "380 hg 0.5\n");
-  fprintf(fp, "280 hg 0.0\n");
+  fprintf(fp, "380 HG 0.5\n");
+  fprintf(fp, "280 HG 0.0\n");
   rewind(fp);
   CHK(rnsf_load_stream(rnsf, fp, NULL) == RES_BAD_ARG);
   CHK(fclose(fp) == 0);
@@ -297,8 +297,8 @@ test_load_failure(struct rnsf* rnsf)
   /* Phase functions overlap */
   CHK(fp = tmpfile());
   fprintf(fp, "wavelengths 2\n");
-  fprintf(fp, "280 hg 0.5\n");
-  fprintf(fp, "280 hg 0.0\n");
+  fprintf(fp, "280 HG 0.5\n");
+  fprintf(fp, "280 HG 0.0\n");
   rewind(fp);
   CHK(rnsf_load_stream(rnsf, fp, NULL) == RES_BAD_ARG);
   CHK(fclose(fp) == 0);
@@ -306,8 +306,8 @@ test_load_failure(struct rnsf* rnsf)
   /* Additional text. Print a warning */
   CHK(fp = tmpfile());
   fprintf(fp, "wavelengths 2 additional_text\n");
-  fprintf(fp, "280 hg 0.5\n");
-  fprintf(fp, "380 hg 0.0\n");
+  fprintf(fp, "280 HG 0.5\n");
+  fprintf(fp, "380 HG 0.0\n");
   rewind(fp);
   CHK(rnsf_load_stream(rnsf, fp, NULL) == RES_OK);
   CHK(fclose(fp) == 0);